compat/netbsd32/netbsd32_netbsd.c

1.23       eeh /*	$NetBSD: netbsd32_netbsd.c,v 1.23 2000/02/06 16:45:56 eeh Exp $	*/
 1.1       mrg
 1.1       mrg /*
 1.1       mrg  * Copyright (c) 1998 Matthew R. Green
 1.1       mrg  * All rights reserved.
 1.1       mrg  *
 1.1       mrg  * Redistribution and use in source and binary forms, with or without
 1.1       mrg  * modification, are permitted provided that the following conditions
 1.1       mrg  * are met:
 1.1       mrg  * 1. Redistributions of source code must retain the above copyright
 1.1       mrg  *    notice, this list of conditions and the following disclaimer.
 1.1       mrg  * 2. Redistributions in binary form must reproduce the above copyright
 1.1       mrg  *    notice, this list of conditions and the following disclaimer in the
 1.1       mrg  *    documentation and/or other materials provided with the distribution.
 1.1       mrg  * 3. The name of the author may not be used to endorse or promote products
 1.1       mrg  *    derived from this software without specific prior written permission.
 1.1       mrg  *
 1.1       mrg  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
 1.1       mrg  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
 1.1       mrg  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
 1.1       mrg  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
 1.1       mrg  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
 1.1       mrg  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 1.1       mrg  * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
 1.1       mrg  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
 1.1       mrg  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1       mrg  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1       mrg  * SUCH DAMAGE.
 1.1       mrg  */
 1.1       mrg
 1.4       eeh #include "opt_ktrace.h"
 1.6       eeh #include "opt_ntp.h"
1.20       eeh #include "opt_compat_netbsd.h"
 1.7  drochner #include "opt_compat_freebsd.h"
 1.7  drochner #include "opt_compat_linux.h"
 1.7  drochner #include "opt_compat_sunos.h"
 1.7  drochner #include "opt_compat_43.h"
1.20       eeh #include "opt_sysv.h"
 1.7  drochner #if defined(COMPAT_43) || defined(COMPAT_SUNOS) || defined(COMPAT_LINUX) || \
 1.7  drochner     defined(COMPAT_FREEBSD)
 1.7  drochner #define COMPAT_OLDSOCK /* used by <sys/socket.h> */
 1.7  drochner #endif
 1.7  drochner
 1.6       eeh #include "fs_lfs.h"
 1.6       eeh #include "fs_nfs.h"
 1.4       eeh
 1.1       mrg #include <sys/param.h>
 1.1       mrg #include <sys/systm.h>
1.20       eeh #include <sys/filedesc.h>
 1.6       eeh #include <sys/kernel.h>
 1.1       mrg #include <sys/ipc.h>
 1.1       mrg #include <sys/msg.h>
1.19       eeh #define msg __msg /* Don't ask me! */
 1.1       mrg #include <sys/sem.h>
 1.1       mrg #include <sys/shm.h>
 1.1       mrg #include <sys/malloc.h>
 1.1       mrg #include <sys/mount.h>
 1.1       mrg #include <sys/socket.h>
 1.1       mrg #include <sys/sockio.h>
 1.6       eeh #include <sys/socketvar.h>
 1.6       eeh #include <sys/mbuf.h>
 1.1       mrg #include <sys/stat.h>
 1.1       mrg #include <sys/time.h>
 1.1       mrg #include <sys/timex.h>
 1.4       eeh #include <sys/signalvar.h>
 1.6       eeh #include <sys/wait.h>
 1.6       eeh #include <sys/ptrace.h>
 1.6       eeh #include <sys/ktrace.h>
 1.6       eeh #include <sys/trace.h>
 1.6       eeh #include <sys/resourcevar.h>
 1.6       eeh #include <sys/pool.h>
 1.6       eeh #include <sys/vnode.h>
 1.6       eeh #include <sys/file.h>
 1.6       eeh #include <sys/filedesc.h>
 1.6       eeh #include <sys/namei.h>
 1.1       mrg
 1.1       mrg #include <vm/vm.h>
1.20       eeh #include <vm/vm_kern.h>
 1.1       mrg #include <sys/syscallargs.h>
 1.6       eeh #include <sys/proc.h>
1.20       eeh #include <sys/acct.h>
1.20       eeh #include <sys/exec.h>
 1.6       eeh #include <sys/sysctl.h>
 1.1       mrg
 1.1       mrg #include <net/if.h>
 1.1       mrg
1.10       mrg #include <compat/netbsd32/netbsd32.h>
1.10       mrg #include <compat/netbsd32/netbsd32_syscallargs.h>
 1.1       mrg
 1.4       eeh #include <machine/frame.h>
 1.4       eeh
1.10       mrg static __inline void netbsd32_from_timeval __P((struct timeval *, struct netbsd32_timeval *));
1.10       mrg static __inline void netbsd32_to_timeval __P((struct netbsd32_timeval *, struct timeval *));
1.10       mrg static __inline void netbsd32_from_itimerval __P((struct itimerval *, struct netbsd32_itimerval *));
1.10       mrg static __inline void netbsd32_to_itimerval __P((struct netbsd32_itimerval *, struct itimerval *));
1.10       mrg static __inline void netbsd32_to_timespec __P((struct netbsd32_timespec *, struct timespec *));
1.10       mrg static __inline void netbsd32_from_timespec __P((struct timespec *, struct netbsd32_timespec *));
1.10       mrg static __inline void netbsd32_from_rusage __P((struct rusage *, struct netbsd32_rusage *));
1.10       mrg static __inline void netbsd32_to_rusage __P((struct netbsd32_rusage *, struct rusage *));
1.10       mrg static __inline int netbsd32_to_iovecin __P((struct netbsd32_iovec *, struct iovec *, int));
1.10       mrg static __inline void netbsd32_to_msghdr __P((struct netbsd32_msghdr *, struct msghdr *));
1.10       mrg static __inline void netbsd32_from_msghdr __P((struct netbsd32_msghdr *, struct msghdr *));
1.10       mrg static __inline void netbsd32_from_statfs __P((struct statfs *, struct netbsd32_statfs *));
1.10       mrg static __inline void netbsd32_from_timex __P((struct timex *, struct netbsd32_timex *));
1.10       mrg static __inline void netbsd32_to_timex __P((struct netbsd32_timex *, struct timex *));
1.10       mrg static __inline void netbsd32_from___stat13 __P((struct stat *, struct netbsd32_stat *));
1.10       mrg static __inline void netbsd32_to_ipc_perm __P((struct netbsd32_ipc_perm *, struct ipc_perm *));
1.10       mrg static __inline void netbsd32_from_ipc_perm __P((struct ipc_perm *, struct netbsd32_ipc_perm *));
1.10       mrg static __inline void netbsd32_to_msg __P((struct netbsd32_msg *, struct msg *));
1.10       mrg static __inline void netbsd32_from_msg __P((struct msg *, struct netbsd32_msg *));
1.10       mrg static __inline void netbsd32_to_msqid_ds __P((struct netbsd32_msqid_ds *, struct msqid_ds *));
1.10       mrg static __inline void netbsd32_from_msqid_ds __P((struct msqid_ds *, struct netbsd32_msqid_ds *));
1.10       mrg static __inline void netbsd32_to_shmid_ds __P((struct netbsd32_shmid_ds *, struct shmid_ds *));
1.10       mrg static __inline void netbsd32_from_shmid_ds __P((struct shmid_ds *, struct netbsd32_shmid_ds *));
1.10       mrg static __inline void netbsd32_to_semid_ds __P((struct  netbsd32_semid_ds *, struct  semid_ds *));
1.10       mrg static __inline void netbsd32_from_semid_ds __P((struct  semid_ds *, struct  netbsd32_semid_ds *));
 1.4       eeh
 1.6       eeh
1.10       mrg static int recvit32 __P((struct proc *, int, struct netbsd32_msghdr *, struct iovec *, caddr_t,
 1.6       eeh 			 register_t *));
1.10       mrg static int dofilereadv32 __P((struct proc *, int, struct file *, struct netbsd32_iovec *,
 1.6       eeh 			      int, off_t *, int, register_t *));
1.10       mrg static int dofilewritev32 __P((struct proc *, int, struct file *, struct netbsd32_iovec *,
 1.6       eeh 			       int,  off_t *, int, register_t *));
 1.6       eeh static int change_utimes32 __P((struct vnode *, struct timeval *, struct proc *));
 1.6       eeh
 1.1       mrg /* converters for structures that we need */
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_timeval(tv, tv32)
 1.1       mrg 	struct timeval *tv;
1.10       mrg 	struct netbsd32_timeval *tv32;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	tv32->tv_sec = (netbsd32_long)tv->tv_sec;
1.10       mrg 	tv32->tv_usec = (netbsd32_long)tv->tv_usec;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_timeval(tv32, tv)
1.10       mrg 	struct netbsd32_timeval *tv32;
 1.1       mrg 	struct timeval *tv;
 1.1       mrg {
 1.1       mrg
 1.1       mrg 	tv->tv_sec = (long)tv32->tv_sec;
 1.1       mrg 	tv->tv_usec = (long)tv32->tv_usec;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_itimerval(itv, itv32)
 1.1       mrg 	struct itimerval *itv;
1.10       mrg 	struct netbsd32_itimerval *itv32;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_from_timeval(&itv->it_interval,
 1.6       eeh 			     &itv32->it_interval);
1.10       mrg 	netbsd32_from_timeval(&itv->it_value,
 1.6       eeh 			     &itv32->it_value);
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_itimerval(itv32, itv)
1.10       mrg 	struct netbsd32_itimerval *itv32;
 1.1       mrg 	struct itimerval *itv;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_to_timeval(&itv32->it_interval, &itv->it_interval);
1.10       mrg 	netbsd32_to_timeval(&itv32->it_value, &itv->it_value);
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_timespec(s32p, p)
1.10       mrg 	struct netbsd32_timespec *s32p;
 1.2       mrg 	struct timespec *p;
 1.2       mrg {
 1.2       mrg
1.20       eeh 	p->tv_sec = (time_t)s32p->tv_sec;
 1.2       mrg 	p->tv_nsec = (long)s32p->tv_nsec;
 1.2       mrg }
 1.2       mrg
 1.2       mrg static __inline void
1.10       mrg netbsd32_from_timespec(p, s32p)
 1.2       mrg 	struct timespec *p;
1.10       mrg 	struct netbsd32_timespec *s32p;
 1.2       mrg {
 1.2       mrg
1.20       eeh 	s32p->tv_sec = (netbsd32_time_t)p->tv_sec;
1.10       mrg 	s32p->tv_nsec = (netbsd32_long)p->tv_nsec;
 1.2       mrg }
 1.2       mrg
 1.2       mrg static __inline void
1.10       mrg netbsd32_from_rusage(rup, ru32p)
 1.1       mrg 	struct rusage *rup;
1.10       mrg 	struct netbsd32_rusage *ru32p;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_from_timeval(&rup->ru_utime, &ru32p->ru_utime);
1.10       mrg 	netbsd32_from_timeval(&rup->ru_stime, &ru32p->ru_stime);
1.10       mrg #define C(var)	ru32p->var = (netbsd32_long)rup->var
 1.1       mrg 	C(ru_maxrss);
 1.1       mrg 	C(ru_ixrss);
 1.1       mrg 	C(ru_idrss);
 1.1       mrg 	C(ru_isrss);
 1.1       mrg 	C(ru_minflt);
 1.1       mrg 	C(ru_majflt);
 1.1       mrg 	C(ru_nswap);
 1.1       mrg 	C(ru_inblock);
 1.1       mrg 	C(ru_oublock);
 1.1       mrg 	C(ru_msgsnd);
 1.1       mrg 	C(ru_msgrcv);
 1.1       mrg 	C(ru_nsignals);
 1.1       mrg 	C(ru_nvcsw);
 1.1       mrg 	C(ru_nivcsw);
 1.1       mrg #undef C
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_rusage(ru32p, rup)
1.10       mrg 	struct netbsd32_rusage *ru32p;
 1.1       mrg 	struct rusage *rup;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_to_timeval(&ru32p->ru_utime, &rup->ru_utime);
1.10       mrg 	netbsd32_to_timeval(&ru32p->ru_stime, &rup->ru_stime);
 1.1       mrg #define C(var)	rup->var = (long)ru32p->var
 1.1       mrg 	C(ru_maxrss);
 1.1       mrg 	C(ru_ixrss);
 1.1       mrg 	C(ru_idrss);
 1.1       mrg 	C(ru_isrss);
 1.1       mrg 	C(ru_minflt);
 1.1       mrg 	C(ru_majflt);
 1.1       mrg 	C(ru_nswap);
 1.1       mrg 	C(ru_inblock);
 1.1       mrg 	C(ru_oublock);
 1.1       mrg 	C(ru_msgsnd);
 1.1       mrg 	C(ru_msgrcv);
 1.1       mrg 	C(ru_nsignals);
 1.1       mrg 	C(ru_nvcsw);
 1.1       mrg 	C(ru_nivcsw);
 1.1       mrg #undef C
 1.1       mrg }
 1.1       mrg
 1.6       eeh static __inline int
1.10       mrg netbsd32_to_iovecin(iov32p, iovp, len)
1.10       mrg 	struct netbsd32_iovec *iov32p;
 1.1       mrg 	struct iovec *iovp;
 1.1       mrg 	int len;
 1.1       mrg {
 1.6       eeh 	int i, error=0;
 1.6       eeh 	u_int32_t iov_base;
 1.6       eeh 	u_int32_t iov_len;
 1.6       eeh 	/*
 1.6       eeh 	 * We could allocate an iov32p, do a copyin, and translate
 1.6       eeh 	 * each field and then free it all up, or we could copyin
 1.6       eeh 	 * each field separately.  I'm doing the latter to reduce
 1.6       eeh 	 * the number of MALLOC()s.
 1.6       eeh 	 */
 1.1       mrg 	for (i = 0; i < len; i++, iovp++, iov32p++) {
 1.6       eeh 		if ((error = copyin((caddr_t)&iov32p->iov_base, &iov_base, sizeof(iov_base))))
 1.6       eeh 		    return (error);
 1.6       eeh 		if ((error = copyin((caddr_t)&iov32p->iov_len, &iov_len, sizeof(iov_len))))
 1.6       eeh 		    return (error);
 1.6       eeh 		iovp->iov_base = (void *)(u_long)iov_base;
 1.6       eeh 		iovp->iov_len = (size_t)iov_len;
 1.1       mrg 	}
 1.1       mrg }
 1.1       mrg
 1.6       eeh /* msg_iov must be done separately */
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_msghdr(mhp32, mhp)
1.10       mrg 	struct netbsd32_msghdr *mhp32;
 1.1       mrg 	struct msghdr *mhp;
 1.1       mrg {
 1.1       mrg
 1.1       mrg 	mhp->msg_name = (caddr_t)(u_long)mhp32->msg_name;
 1.1       mrg 	mhp->msg_namelen = mhp32->msg_namelen;
 1.1       mrg 	mhp->msg_iovlen = (size_t)mhp32->msg_iovlen;
 1.1       mrg 	mhp->msg_control = (caddr_t)(u_long)mhp32->msg_control;
 1.1       mrg 	mhp->msg_controllen = mhp32->msg_controllen;
 1.1       mrg 	mhp->msg_flags = mhp32->msg_flags;
 1.6       eeh }
 1.6       eeh
 1.6       eeh /* msg_iov must be done separately */
 1.6       eeh static __inline void
1.10       mrg netbsd32_from_msghdr(mhp32, mhp)
1.10       mrg 	struct netbsd32_msghdr *mhp32;
 1.6       eeh 	struct msghdr *mhp;
 1.6       eeh {
 1.6       eeh
 1.6       eeh 	mhp32->msg_name = mhp32->msg_name;
 1.6       eeh 	mhp32->msg_namelen = mhp32->msg_namelen;
 1.6       eeh 	mhp32->msg_iovlen = mhp32->msg_iovlen;
 1.6       eeh 	mhp32->msg_control = mhp32->msg_control;
 1.6       eeh 	mhp32->msg_controllen = mhp->msg_controllen;
 1.6       eeh 	mhp32->msg_flags = mhp->msg_flags;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_statfs(sbp, sb32p)
 1.1       mrg 	struct statfs *sbp;
1.10       mrg 	struct netbsd32_statfs *sb32p;
 1.1       mrg {
 1.1       mrg 	sb32p->f_type = sbp->f_type;
 1.1       mrg 	sb32p->f_flags = sbp->f_flags;
1.10       mrg 	sb32p->f_bsize = (netbsd32_long)sbp->f_bsize;
1.10       mrg 	sb32p->f_iosize = (netbsd32_long)sbp->f_iosize;
1.10       mrg 	sb32p->f_blocks = (netbsd32_long)sbp->f_blocks;
1.10       mrg 	sb32p->f_bfree = (netbsd32_long)sbp->f_bfree;
1.10       mrg 	sb32p->f_bavail = (netbsd32_long)sbp->f_bavail;
1.10       mrg 	sb32p->f_files = (netbsd32_long)sbp->f_files;
1.10       mrg 	sb32p->f_ffree = (netbsd32_long)sbp->f_ffree;
 1.1       mrg 	sb32p->f_fsid = sbp->f_fsid;
 1.1       mrg 	sb32p->f_owner = sbp->f_owner;
 1.6       eeh 	sb32p->f_spare[0] = 0;
 1.6       eeh 	sb32p->f_spare[1] = 0;
 1.6       eeh 	sb32p->f_spare[2] = 0;
 1.6       eeh 	sb32p->f_spare[3] = 0;
 1.6       eeh #if 1
 1.6       eeh 	/* May as well do the whole batch in one go */
 1.6       eeh 	memcpy(sb32p->f_fstypename, sbp->f_fstypename, MFSNAMELEN+MNAMELEN+MNAMELEN);
 1.6       eeh #else
 1.6       eeh 	/* If we want to be careful */
 1.6       eeh 	memcpy(sb32p->f_fstypename, sbp->f_fstypename, MFSNAMELEN);
 1.6       eeh 	memcpy(sb32p->f_mntonname, sbp->f_mntonname, MNAMELEN);
 1.6       eeh 	memcpy(sb32p->f_mntfromname, sbp->f_mntfromname, MNAMELEN);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_timex(txp, tx32p)
 1.1       mrg 	struct timex *txp;
1.10       mrg 	struct netbsd32_timex *tx32p;
 1.1       mrg {
 1.1       mrg
 1.1       mrg 	tx32p->modes = txp->modes;
1.10       mrg 	tx32p->offset = (netbsd32_long)txp->offset;
1.10       mrg 	tx32p->freq = (netbsd32_long)txp->freq;
1.10       mrg 	tx32p->maxerror = (netbsd32_long)txp->maxerror;
1.10       mrg 	tx32p->esterror = (netbsd32_long)txp->esterror;
 1.1       mrg 	tx32p->status = txp->status;
1.10       mrg 	tx32p->constant = (netbsd32_long)txp->constant;
1.10       mrg 	tx32p->precision = (netbsd32_long)txp->precision;
1.10       mrg 	tx32p->tolerance = (netbsd32_long)txp->tolerance;
1.10       mrg 	tx32p->ppsfreq = (netbsd32_long)txp->ppsfreq;
1.10       mrg 	tx32p->jitter = (netbsd32_long)txp->jitter;
 1.1       mrg 	tx32p->shift = txp->shift;
1.10       mrg 	tx32p->stabil = (netbsd32_long)txp->stabil;
1.10       mrg 	tx32p->jitcnt = (netbsd32_long)txp->jitcnt;
1.10       mrg 	tx32p->calcnt = (netbsd32_long)txp->calcnt;
1.10       mrg 	tx32p->errcnt = (netbsd32_long)txp->errcnt;
1.10       mrg 	tx32p->stbcnt = (netbsd32_long)txp->stbcnt;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_timex(tx32p, txp)
1.10       mrg 	struct netbsd32_timex *tx32p;
 1.1       mrg 	struct timex *txp;
 1.1       mrg {
 1.1       mrg
 1.1       mrg 	txp->modes = tx32p->modes;
 1.1       mrg 	txp->offset = (long)tx32p->offset;
 1.1       mrg 	txp->freq = (long)tx32p->freq;
 1.1       mrg 	txp->maxerror = (long)tx32p->maxerror;
 1.1       mrg 	txp->esterror = (long)tx32p->esterror;
 1.1       mrg 	txp->status = tx32p->status;
 1.1       mrg 	txp->constant = (long)tx32p->constant;
 1.1       mrg 	txp->precision = (long)tx32p->precision;
 1.1       mrg 	txp->tolerance = (long)tx32p->tolerance;
 1.1       mrg 	txp->ppsfreq = (long)tx32p->ppsfreq;
 1.1       mrg 	txp->jitter = (long)tx32p->jitter;
 1.1       mrg 	txp->shift = tx32p->shift;
 1.1       mrg 	txp->stabil = (long)tx32p->stabil;
 1.1       mrg 	txp->jitcnt = (long)tx32p->jitcnt;
 1.1       mrg 	txp->calcnt = (long)tx32p->calcnt;
 1.1       mrg 	txp->errcnt = (long)tx32p->errcnt;
 1.1       mrg 	txp->stbcnt = (long)tx32p->stbcnt;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from___stat13(sbp, sb32p)
 1.1       mrg 	struct stat *sbp;
1.10       mrg 	struct netbsd32_stat *sb32p;
 1.1       mrg {
 1.1       mrg 	sb32p->st_dev = sbp->st_dev;
 1.1       mrg 	sb32p->st_ino = sbp->st_ino;
 1.1       mrg 	sb32p->st_mode = sbp->st_mode;
 1.1       mrg 	sb32p->st_nlink = sbp->st_nlink;
 1.1       mrg 	sb32p->st_uid = sbp->st_uid;
 1.1       mrg 	sb32p->st_gid = sbp->st_gid;
 1.1       mrg 	sb32p->st_rdev = sbp->st_rdev;
 1.1       mrg 	if (sbp->st_size < (quad_t)1 << 32)
 1.1       mrg 		sb32p->st_size = sbp->st_size;
 1.1       mrg 	else
 1.1       mrg 		sb32p->st_size = -2;
1.20       eeh 	sb32p->st_atimespec.tv_sec = (netbsd32_time_t)sbp->st_atimespec.tv_sec;
1.10       mrg 	sb32p->st_atimespec.tv_nsec = (netbsd32_long)sbp->st_atimespec.tv_nsec;
1.20       eeh 	sb32p->st_mtimespec.tv_sec = (netbsd32_time_t)sbp->st_mtimespec.tv_sec;
1.10       mrg 	sb32p->st_mtimespec.tv_nsec = (netbsd32_long)sbp->st_mtimespec.tv_nsec;
1.20       eeh 	sb32p->st_ctimespec.tv_sec = (netbsd32_time_t)sbp->st_ctimespec.tv_sec;
1.10       mrg 	sb32p->st_ctimespec.tv_nsec = (netbsd32_long)sbp->st_ctimespec.tv_nsec;
 1.1       mrg 	sb32p->st_blksize = sbp->st_blksize;
 1.1       mrg 	sb32p->st_blocks = sbp->st_blocks;
 1.1       mrg 	sb32p->st_flags = sbp->st_flags;
 1.1       mrg 	sb32p->st_gen = sbp->st_gen;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_ipc_perm(ip32p, ipp)
1.10       mrg 	struct netbsd32_ipc_perm *ip32p;
 1.1       mrg 	struct ipc_perm *ipp;
 1.1       mrg {
 1.1       mrg
 1.1       mrg 	ipp->cuid = ip32p->cuid;
 1.1       mrg 	ipp->cgid = ip32p->cgid;
 1.1       mrg 	ipp->uid = ip32p->uid;
 1.1       mrg 	ipp->gid = ip32p->gid;
 1.1       mrg 	ipp->mode = ip32p->mode;
1.19       eeh 	ipp->_seq = ip32p->_seq;
1.19       eeh 	ipp->_key = (key_t)ip32p->_key;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_ipc_perm(ipp, ip32p)
 1.1       mrg 	struct ipc_perm *ipp;
1.10       mrg 	struct netbsd32_ipc_perm *ip32p;
 1.1       mrg {
 1.1       mrg
 1.1       mrg 	ip32p->cuid = ipp->cuid;
 1.1       mrg 	ip32p->cgid = ipp->cgid;
 1.1       mrg 	ip32p->uid = ipp->uid;
 1.1       mrg 	ip32p->gid = ipp->gid;
 1.1       mrg 	ip32p->mode = ipp->mode;
1.19       eeh 	ip32p->_seq = ipp->_seq;
1.19       eeh 	ip32p->_key = (netbsd32_key_t)ipp->_key;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_msg(m32p, mp)
1.10       mrg 	struct netbsd32_msg *m32p;
 1.1       mrg 	struct msg *mp;
 1.1       mrg {
 1.1       mrg
 1.1       mrg 	mp->msg_next = (struct msg *)(u_long)m32p->msg_next;
 1.1       mrg 	mp->msg_type = (long)m32p->msg_type;
 1.1       mrg 	mp->msg_ts = m32p->msg_ts;
 1.1       mrg 	mp->msg_spot = m32p->msg_spot;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_msg(mp, m32p)
 1.1       mrg 	struct msg *mp;
1.10       mrg 	struct netbsd32_msg *m32p;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	m32p->msg_next = (netbsd32_msgp_t)(u_long)mp->msg_next;
1.10       mrg 	m32p->msg_type = (netbsd32_long)mp->msg_type;
 1.1       mrg 	m32p->msg_ts = mp->msg_ts;
 1.1       mrg 	m32p->msg_spot = mp->msg_spot;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_msqid_ds(ds32p, dsp)
1.10       mrg 	struct netbsd32_msqid_ds *ds32p;
 1.1       mrg 	struct msqid_ds *dsp;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_to_ipc_perm(&ds32p->msg_perm, &dsp->msg_perm);
1.19       eeh 	netbsd32_to_msg((struct netbsd32_msg *)(u_long)ds32p->_msg_first, dsp->_msg_first);
1.19       eeh 	netbsd32_to_msg((struct netbsd32_msg *)(u_long)ds32p->_msg_last, dsp->_msg_last);
1.19       eeh 	dsp->_msg_cbytes = (u_long)ds32p->_msg_cbytes;
 1.1       mrg 	dsp->msg_qnum = (u_long)ds32p->msg_qnum;
 1.1       mrg 	dsp->msg_qbytes = (u_long)ds32p->msg_qbytes;
 1.1       mrg 	dsp->msg_lspid = ds32p->msg_lspid;
 1.1       mrg 	dsp->msg_lrpid = ds32p->msg_lrpid;
 1.1       mrg 	dsp->msg_rtime = (time_t)ds32p->msg_rtime;
 1.1       mrg 	dsp->msg_stime = (time_t)ds32p->msg_stime;
 1.1       mrg 	dsp->msg_ctime = (time_t)ds32p->msg_ctime;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_msqid_ds(dsp, ds32p)
 1.1       mrg 	struct msqid_ds *dsp;
1.10       mrg 	struct netbsd32_msqid_ds *ds32p;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_from_ipc_perm(&dsp->msg_perm, &ds32p->msg_perm);
1.19       eeh 	netbsd32_from_msg(dsp->_msg_first, (struct netbsd32_msg *)(u_long)ds32p->_msg_first);
1.19       eeh 	netbsd32_from_msg(dsp->_msg_last, (struct netbsd32_msg *)(u_long)ds32p->_msg_last);
1.19       eeh 	ds32p->_msg_cbytes = (netbsd32_u_long)dsp->_msg_cbytes;
1.10       mrg 	ds32p->msg_qnum = (netbsd32_u_long)dsp->msg_qnum;
1.10       mrg 	ds32p->msg_qbytes = (netbsd32_u_long)dsp->msg_qbytes;
 1.1       mrg 	ds32p->msg_lspid = dsp->msg_lspid;
 1.1       mrg 	ds32p->msg_lrpid = dsp->msg_lrpid;
 1.1       mrg 	ds32p->msg_rtime = dsp->msg_rtime;
 1.1       mrg 	ds32p->msg_stime = dsp->msg_stime;
 1.1       mrg 	ds32p->msg_ctime = dsp->msg_ctime;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_shmid_ds(ds32p, dsp)
1.10       mrg 	struct netbsd32_shmid_ds *ds32p;
 1.1       mrg 	struct shmid_ds *dsp;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_to_ipc_perm(&ds32p->shm_perm, &dsp->shm_perm);
 1.1       mrg 	dsp->shm_segsz = ds32p->shm_segsz;
 1.1       mrg 	dsp->shm_lpid = ds32p->shm_lpid;
 1.1       mrg 	dsp->shm_cpid = ds32p->shm_cpid;
 1.1       mrg 	dsp->shm_nattch = ds32p->shm_nattch;
 1.1       mrg 	dsp->shm_atime = (long)ds32p->shm_atime;
 1.1       mrg 	dsp->shm_dtime = (long)ds32p->shm_dtime;
 1.1       mrg 	dsp->shm_ctime = (long)ds32p->shm_ctime;
1.19       eeh 	dsp->_shm_internal = (void *)(u_long)ds32p->_shm_internal;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_from_shmid_ds(dsp, ds32p)
 1.1       mrg 	struct shmid_ds *dsp;
1.10       mrg 	struct netbsd32_shmid_ds *ds32p;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_from_ipc_perm(&dsp->shm_perm, &ds32p->shm_perm);
 1.1       mrg 	ds32p->shm_segsz = dsp->shm_segsz;
 1.1       mrg 	ds32p->shm_lpid = dsp->shm_lpid;
 1.1       mrg 	ds32p->shm_cpid = dsp->shm_cpid;
 1.1       mrg 	ds32p->shm_nattch = dsp->shm_nattch;
1.10       mrg 	ds32p->shm_atime = (netbsd32_long)dsp->shm_atime;
1.10       mrg 	ds32p->shm_dtime = (netbsd32_long)dsp->shm_dtime;
1.10       mrg 	ds32p->shm_ctime = (netbsd32_long)dsp->shm_ctime;
1.19       eeh 	ds32p->_shm_internal = (netbsd32_voidp)(u_long)dsp->_shm_internal;
 1.1       mrg }
 1.1       mrg
 1.1       mrg static __inline void
1.10       mrg netbsd32_to_semid_ds(s32dsp, dsp)
1.10       mrg 	struct  netbsd32_semid_ds *s32dsp;
 1.1       mrg 	struct  semid_ds *dsp;
 1.1       mrg {
 1.1       mrg
1.10       mrg 	netbsd32_from_ipc_perm(&dsp->sem_perm, &s32dsp->sem_perm);
1.19       eeh 	dsp->_sem_base = (struct __sem *)(u_long)s32dsp->_sem_base;
 1.1       mrg 	dsp->sem_nsems = s32dsp->sem_nsems;
 1.1       mrg 	dsp->sem_otime = s32dsp->sem_otime;
 1.1       mrg 	dsp->sem_ctime = s32dsp->sem_ctime;
 1.1       mrg }
 1.1       mrg
 1.2       mrg static __inline void
1.10       mrg netbsd32_from_semid_ds(dsp, s32dsp)
 1.2       mrg 	struct  semid_ds *dsp;
1.10       mrg 	struct  netbsd32_semid_ds *s32dsp;
 1.2       mrg {
 1.2       mrg
1.10       mrg 	netbsd32_to_ipc_perm(&s32dsp->sem_perm, &dsp->sem_perm);
1.19       eeh 	s32dsp->_sem_base = (netbsd32_semp_t)(u_long)dsp->_sem_base;
 1.2       mrg 	s32dsp->sem_nsems = dsp->sem_nsems;
 1.2       mrg 	s32dsp->sem_otime = dsp->sem_otime;
 1.2       mrg 	s32dsp->sem_ctime = dsp->sem_ctime;
 1.2       mrg }
 1.2       mrg
 1.1       mrg /*
 1.1       mrg  * below are all the standard NetBSD system calls, in the 32bit
 1.1       mrg  * environment, witht he necessary conversions to 64bit before
 1.1       mrg  * calling the real syscall.
 1.1       mrg  */
 1.1       mrg
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_exit(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_exit_args /* {
 1.6       eeh 		syscallarg(int) rval;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_exit_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(rval);
 1.6       eeh 	sys_exit(p, &ua, retval);
 1.6       eeh }
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32_read(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_read_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(netbsd32_voidp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) nbyte;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_read_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TOP_UAP(buf, void *);
1.11       mrg 	NETBSD32TOX_UAP(nbyte, size_t);
 1.6       eeh 	return sys_read(p, &ua, retval);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_write(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_write_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(const netbsd32_voidp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) nbyte;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_write_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TOP_UAP(buf, void *);
1.11       mrg 	NETBSD32TOX_UAP(nbyte, size_t);
 1.6       eeh 	return sys_write(p, &ua, retval);
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_close(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_close_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_close_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.21       eeh 	return sys_close(p, &ua, retval);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_open(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_open_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 		syscallarg(mode_t) mode;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_open_args ua;
 1.1       mrg 	caddr_t sg;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(flags);
1.11       mrg 	NETBSD32TO64_UAP(mode);
 1.1       mrg 	sg = stackgap_init(p->p_emul);
1.11       mrg 	NETBSD32_CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path));
 1.1       mrg
 1.1       mrg 	return (sys_open(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_wait4(q, v, retval)
 1.6       eeh 	struct proc *q;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_wait4_args /* {
 1.1       mrg 		syscallarg(int) pid;
1.10       mrg 		syscallarg(netbsd32_intp) status;
 1.1       mrg 		syscallarg(int) options;
1.10       mrg 		syscallarg(netbsd32_rusagep_t) rusage;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_rusage ru32;
 1.6       eeh 	register int nfound;
 1.6       eeh 	register struct proc *p, *t;
 1.6       eeh 	int status, error;
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, pid) == 0)
 1.6       eeh 		SCARG(uap, pid) = -q->p_pgid;
 1.6       eeh 	if (SCARG(uap, options) &~ (WUNTRACED|WNOHANG))
 1.6       eeh 		return (EINVAL);
 1.1       mrg
 1.6       eeh loop:
 1.6       eeh 	nfound = 0;
 1.6       eeh 	for (p = q->p_children.lh_first; p != 0; p = p->p_sibling.le_next) {
 1.6       eeh 		if (SCARG(uap, pid) != WAIT_ANY &&
 1.6       eeh 		    p->p_pid != SCARG(uap, pid) &&
 1.6       eeh 		    p->p_pgid != -SCARG(uap, pid))
 1.6       eeh 			continue;
 1.6       eeh 		nfound++;
 1.6       eeh 		if (p->p_stat == SZOMB) {
 1.6       eeh 			retval[0] = p->p_pid;
 1.6       eeh
 1.6       eeh 			if (SCARG(uap, status)) {
 1.6       eeh 				status = p->p_xstat;	/* convert to int */
 1.6       eeh 				error = copyout((caddr_t)&status,
 1.6       eeh 						(caddr_t)(u_long)SCARG(uap, status),
 1.6       eeh 						sizeof(status));
 1.6       eeh 				if (error)
 1.6       eeh 					return (error);
 1.6       eeh 			}
 1.6       eeh 			if (SCARG(uap, rusage)) {
1.10       mrg 				netbsd32_from_rusage(p->p_ru, &ru32);
 1.6       eeh 				if ((error = copyout((caddr_t)&ru32,
 1.6       eeh 						     (caddr_t)(u_long)SCARG(uap, rusage),
1.10       mrg 						     sizeof(struct netbsd32_rusage))))
 1.6       eeh 					return (error);
 1.6       eeh 			}
 1.6       eeh 			/*
 1.6       eeh 			 * If we got the child via ptrace(2) or procfs, and
 1.6       eeh 			 * the parent is different (meaning the process was
 1.6       eeh 			 * attached, rather than run as a child), then we need
 1.6       eeh 			 * to give it back to the old parent, and send the
 1.6       eeh 			 * parent a SIGCHLD.  The rest of the cleanup will be
 1.6       eeh 			 * done when the old parent waits on the child.
 1.6       eeh 			 */
 1.6       eeh 			if ((p->p_flag & P_TRACED) &&
 1.6       eeh 			    p->p_oppid != p->p_pptr->p_pid) {
 1.6       eeh 				t = pfind(p->p_oppid);
 1.6       eeh 				proc_reparent(p, t ? t : initproc);
 1.6       eeh 				p->p_oppid = 0;
 1.6       eeh 				p->p_flag &= ~(P_TRACED|P_WAITED|P_FSTRACE);
 1.6       eeh 				psignal(p->p_pptr, SIGCHLD);
 1.6       eeh 				wakeup((caddr_t)p->p_pptr);
 1.6       eeh 				return (0);
 1.6       eeh 			}
 1.6       eeh 			p->p_xstat = 0;
 1.6       eeh 			ruadd(&q->p_stats->p_cru, p->p_ru);
 1.6       eeh 			pool_put(&rusage_pool, p->p_ru);
 1.6       eeh
 1.6       eeh 			/*
 1.6       eeh 			 * Finally finished with old proc entry.
 1.6       eeh 			 * Unlink it from its process group and free it.
 1.6       eeh 			 */
 1.6       eeh 			leavepgrp(p);
 1.6       eeh
 1.6       eeh 			LIST_REMOVE(p, p_list);	/* off zombproc */
 1.6       eeh
 1.6       eeh 			LIST_REMOVE(p, p_sibling);
 1.6       eeh
 1.6       eeh 			/*
 1.6       eeh 			 * Decrement the count of procs running with this uid.
 1.6       eeh 			 */
 1.6       eeh 			(void)chgproccnt(p->p_cred->p_ruid, -1);
 1.6       eeh
 1.6       eeh 			/*
 1.6       eeh 			 * Free up credentials.
 1.6       eeh 			 */
 1.6       eeh 			if (--p->p_cred->p_refcnt == 0) {
 1.6       eeh 				crfree(p->p_cred->pc_ucred);
 1.6       eeh 				pool_put(&pcred_pool, p->p_cred);
 1.6       eeh 			}
 1.6       eeh
 1.6       eeh 			/*
 1.6       eeh 			 * Release reference to text vnode
 1.6       eeh 			 */
 1.6       eeh 			if (p->p_textvp)
 1.6       eeh 				vrele(p->p_textvp);
 1.6       eeh
 1.6       eeh 			pool_put(&proc_pool, p);
 1.6       eeh 			nprocs--;
 1.6       eeh 			return (0);
 1.6       eeh 		}
 1.6       eeh 		if (p->p_stat == SSTOP && (p->p_flag & P_WAITED) == 0 &&
 1.6       eeh 		    (p->p_flag & P_TRACED || SCARG(uap, options) & WUNTRACED)) {
 1.6       eeh 			p->p_flag |= P_WAITED;
 1.6       eeh 			retval[0] = p->p_pid;
 1.6       eeh
 1.6       eeh 			if (SCARG(uap, status)) {
 1.6       eeh 				status = W_STOPCODE(p->p_xstat);
 1.6       eeh 				error = copyout((caddr_t)&status,
 1.6       eeh 				    (caddr_t)(u_long)SCARG(uap, status),
 1.6       eeh 				    sizeof(status));
 1.6       eeh 			} else
 1.6       eeh 				error = 0;
 1.6       eeh 			return (error);
 1.6       eeh 		}
 1.6       eeh 	}
 1.6       eeh 	if (nfound == 0)
 1.6       eeh 		return (ECHILD);
 1.6       eeh 	if (SCARG(uap, options) & WNOHANG) {
 1.6       eeh 		retval[0] = 0;
 1.6       eeh 		return (0);
 1.5       eeh 	}
 1.6       eeh 	if ((error = tsleep((caddr_t)q, PWAIT | PCATCH, "wait", 0)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh 	goto loop;
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_link(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_link_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(const netbsd32_charp) link;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_link_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TOP_UAP(link, const char);
 1.1       mrg 	return (sys_link(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_unlink(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_unlink_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_unlink_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
 1.1       mrg
 1.1       mrg 	return (sys_unlink(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_chdir(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_chdir_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_chdir_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
 1.1       mrg
 1.1       mrg 	return (sys_chdir(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_fchdir(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_fchdir_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_fchdir_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
 1.6       eeh
 1.6       eeh 	return (sys_fchdir(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_mknod(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mknod_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(mode_t) mode;
 1.1       mrg 		syscallarg(dev_t) dev;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mknod_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(dev);
1.11       mrg 	NETBSD32TO64_UAP(mode);
 1.1       mrg
 1.1       mrg 	return (sys_mknod(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_chmod(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_chmod_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(mode_t) mode;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_chmod_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(mode);
 1.1       mrg
 1.1       mrg 	return (sys_chmod(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_chown(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_chown_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(uid_t) uid;
 1.1       mrg 		syscallarg(gid_t) gid;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_chown_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(uid);
1.11       mrg 	NETBSD32TO64_UAP(gid);
 1.1       mrg
 1.1       mrg 	return (sys_chown(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_break(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_break_args /* {
1.10       mrg 		syscallarg(netbsd32_charp) nsize;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_obreak_args ua;
 1.1       mrg
 1.1       mrg 	SCARG(&ua, nsize) = (char *)(u_long)SCARG(uap, nsize);
1.11       mrg 	NETBSD32TOP_UAP(nsize, char);
 1.1       mrg 	return (sys_obreak(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getfsstat(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getfsstat_args /* {
1.10       mrg 		syscallarg(netbsd32_statfsp_t) buf;
1.10       mrg 		syscallarg(netbsd32_long) bufsize;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 	} */ *uap = v;
1.21       eeh 	register struct mount *mp, *nmp;
1.21       eeh 	register struct statfs *sp;
1.21       eeh 	struct netbsd32_statfs sb32;
1.21       eeh 	caddr_t sfsp;
1.21       eeh 	long count, maxcount, error;
1.21       eeh
1.21       eeh 	maxcount = SCARG(uap, bufsize) / sizeof(struct netbsd32_statfs);
1.21       eeh 	sfsp = (caddr_t)SCARG(uap, buf);
1.21       eeh 	simple_lock(&mountlist_slock);
1.21       eeh 	count = 0;
1.21       eeh 	for (mp = mountlist.cqh_first; mp != (void *)&mountlist; mp = nmp) {
1.21       eeh 		if (vfs_busy(mp, LK_NOWAIT, &mountlist_slock)) {
1.21       eeh 			nmp = mp->mnt_list.cqe_next;
1.21       eeh 			continue;
1.21       eeh 		}
1.21       eeh 		if (sfsp && count < maxcount) {
1.21       eeh 			sp = &mp->mnt_stat;
1.21       eeh 			/*
1.21       eeh 			 * If MNT_NOWAIT or MNT_LAZY is specified, do not
1.21       eeh 			 * refresh the fsstat cache. MNT_WAIT or MNT_LAXY
1.21       eeh 			 * overrides MNT_NOWAIT.
1.21       eeh 			 */
1.21       eeh 			if (SCARG(uap, flags) != MNT_NOWAIT &&
1.21       eeh 			    SCARG(uap, flags) != MNT_LAZY &&
1.21       eeh 			    (SCARG(uap, flags) == MNT_WAIT ||
1.21       eeh 			     SCARG(uap, flags) == 0) &&
1.21       eeh 			    (error = VFS_STATFS(mp, sp, p)) != 0) {
1.21       eeh 				simple_lock(&mountlist_slock);
1.21       eeh 				nmp = mp->mnt_list.cqe_next;
1.21       eeh 				vfs_unbusy(mp);
1.21       eeh 				continue;
1.21       eeh 			}
1.21       eeh 			sp->f_flags = mp->mnt_flag & MNT_VISFLAGMASK;
1.21       eeh 			sp->f_oflags = sp->f_flags & 0xffff;
1.21       eeh 			netbsd32_from_statfs(sp, &sb32);
1.21       eeh 			error = copyout(&sb32, sfsp, sizeof(sb32));
1.21       eeh 			if (error) {
1.21       eeh 				vfs_unbusy(mp);
1.21       eeh 				return (error);
1.21       eeh 			}
1.21       eeh 			sfsp += sizeof(sb32);
1.21       eeh 		}
1.21       eeh 		count++;
1.21       eeh 		simple_lock(&mountlist_slock);
1.21       eeh 		nmp = mp->mnt_list.cqe_next;
1.21       eeh 		vfs_unbusy(mp);
1.21       eeh 	}
1.21       eeh 	simple_unlock(&mountlist_slock);
1.21       eeh 	if (sfsp && count > maxcount)
1.21       eeh 		*retval = maxcount;
 1.1       mrg 	else
1.21       eeh 		*retval = count;
 1.1       mrg 	return (0);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_mount(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mount_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) type;
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(int) flags;
1.10       mrg 		syscallarg(netbsd32_voidp) data;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mount_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(type, const char);
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(flags);
1.11       mrg 	NETBSD32TOP_UAP(data, void);
 1.1       mrg 	return (sys_mount(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_unmount(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_unmount_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_unmount_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(flags);
 1.1       mrg 	return (sys_unmount(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_setuid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_setuid_args /* {
 1.6       eeh 		syscallarg(uid_t) uid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_setuid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(uid);
 1.6       eeh 	return (sys_setuid(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_ptrace(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_ptrace_args /* {
 1.1       mrg 		syscallarg(int) req;
 1.1       mrg 		syscallarg(pid_t) pid;
1.10       mrg 		syscallarg(netbsd32_caddr_t) addr;
 1.1       mrg 		syscallarg(int) data;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_ptrace_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(req);
1.11       mrg 	NETBSD32TO64_UAP(pid);
1.11       mrg 	NETBSD32TOX64_UAP(addr, caddr_t);
1.11       mrg 	NETBSD32TO64_UAP(data);
 1.1       mrg 	return (sys_ptrace(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_recvmsg(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_recvmsg_args /* {
 1.1       mrg 		syscallarg(int) s;
1.10       mrg 		syscallarg(netbsd32_msghdrp_t) msg;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_msghdr msg;
 1.6       eeh 	struct iovec aiov[UIO_SMALLIOV], *uiov, *iov;
 1.6       eeh 	register int error;
 1.6       eeh
 1.6       eeh 	error = copyin((caddr_t)(u_long)SCARG(uap, msg), (caddr_t)&msg,
 1.6       eeh 		       sizeof(msg));
1.10       mrg 		/* netbsd32_msghdr needs the iov pre-allocated */
 1.6       eeh 	if (error)
 1.6       eeh 		return (error);
 1.6       eeh 	if ((u_int)msg.msg_iovlen > UIO_SMALLIOV) {
 1.6       eeh 		if ((u_int)msg.msg_iovlen > IOV_MAX)
 1.6       eeh 			return (EMSGSIZE);
 1.6       eeh 		MALLOC(iov, struct iovec *,
 1.6       eeh 		       sizeof(struct iovec) * (u_int)msg.msg_iovlen, M_IOV,
 1.6       eeh 		       M_WAITOK);
 1.6       eeh 	} else if ((u_int)msg.msg_iovlen > 0)
 1.6       eeh 		iov = aiov;
 1.6       eeh 	else
 1.6       eeh 		return (EMSGSIZE);
 1.6       eeh #ifdef COMPAT_OLDSOCK
 1.6       eeh 	msg.msg_flags = SCARG(uap, flags) &~ MSG_COMPAT;
 1.6       eeh #else
 1.6       eeh 	msg.msg_flags = SCARG(uap, flags);
 1.6       eeh #endif
 1.6       eeh 	uiov = (struct iovec *)(u_long)msg.msg_iov;
1.10       mrg 	error = netbsd32_to_iovecin((struct netbsd32_iovec *)uiov,
 1.6       eeh 				   iov, msg.msg_iovlen);
 1.6       eeh 	if (error)
 1.6       eeh 		goto done;
 1.6       eeh 	if ((error = recvit32(p, SCARG(uap, s), &msg, iov, (caddr_t)0, retval)) == 0) {
 1.6       eeh 		error = copyout((caddr_t)&msg, (caddr_t)(u_long)SCARG(uap, msg),
 1.6       eeh 		    sizeof(msg));
 1.6       eeh 	}
 1.6       eeh done:
 1.6       eeh 	if (iov != aiov)
 1.6       eeh 		FREE(iov, M_IOV);
 1.6       eeh 	return (error);
 1.6       eeh }
 1.1       mrg
 1.6       eeh int
 1.6       eeh recvit32(p, s, mp, iov, namelenp, retsize)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	int s;
1.10       mrg 	struct netbsd32_msghdr *mp;
 1.6       eeh 	struct iovec *iov;
 1.6       eeh 	caddr_t namelenp;
 1.6       eeh 	register_t *retsize;
 1.6       eeh {
 1.6       eeh 	struct file *fp;
 1.6       eeh 	struct uio auio;
 1.6       eeh 	register int i;
 1.6       eeh 	int len, error;
 1.6       eeh 	struct mbuf *from = 0, *control = 0;
 1.6       eeh 	struct socket *so;
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	struct iovec *ktriov = NULL;
 1.6       eeh #endif
 1.6       eeh
1.12   thorpej 	/* getsock() will use the descriptor for us */
 1.6       eeh 	if ((error = getsock(p->p_fd, s, &fp)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh 	auio.uio_iov = (struct iovec *)(u_long)mp->msg_iov;
 1.6       eeh 	auio.uio_iovcnt = mp->msg_iovlen;
 1.6       eeh 	auio.uio_segflg = UIO_USERSPACE;
 1.6       eeh 	auio.uio_rw = UIO_READ;
 1.6       eeh 	auio.uio_procp = p;
 1.6       eeh 	auio.uio_offset = 0;			/* XXX */
 1.6       eeh 	auio.uio_resid = 0;
 1.6       eeh 	for (i = 0; i < mp->msg_iovlen; i++, iov++) {
 1.6       eeh #if 0
 1.6       eeh 		/* cannot happen iov_len is unsigned */
1.12   thorpej 		if (iov->iov_len < 0) {
1.12   thorpej 			error = EINVAL;
1.12   thorpej 			goto out1;
1.12   thorpej 		}
 1.6       eeh #endif
 1.6       eeh 		/*
 1.6       eeh 		 * Reads return ssize_t because -1 is returned on error.
 1.6       eeh 		 * Therefore we must restrict the length to SSIZE_MAX to
 1.6       eeh 		 * avoid garbage return values.
 1.6       eeh 		 */
 1.6       eeh 		auio.uio_resid += iov->iov_len;
1.12   thorpej 		if (iov->iov_len > SSIZE_MAX || auio.uio_resid > SSIZE_MAX) {
1.12   thorpej 			error = EINVAL;
1.12   thorpej 			goto out1;
1.12   thorpej 		}
 1.6       eeh 	}
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	if (KTRPOINT(p, KTR_GENIO)) {
 1.6       eeh 		int iovlen = auio.uio_iovcnt * sizeof(struct iovec);
 1.1       mrg
 1.6       eeh 		MALLOC(ktriov, struct iovec *, iovlen, M_TEMP, M_WAITOK);
 1.6       eeh 		memcpy((caddr_t)ktriov, (caddr_t)auio.uio_iov, iovlen);
 1.6       eeh 	}
 1.6       eeh #endif
 1.6       eeh 	len = auio.uio_resid;
 1.6       eeh 	so = (struct socket *)fp->f_data;
 1.6       eeh 	error = (*so->so_receive)(so, &from, &auio, NULL,
 1.6       eeh 			  mp->msg_control ? &control : NULL, &mp->msg_flags);
 1.6       eeh 	if (error) {
 1.6       eeh 		if (auio.uio_resid != len && (error == ERESTART ||
 1.6       eeh 		    error == EINTR || error == EWOULDBLOCK))
 1.6       eeh 			error = 0;
 1.6       eeh 	}
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	if (ktriov != NULL) {
 1.6       eeh 		if (error == 0)
 1.6       eeh 			ktrgenio(p->p_tracep, s, UIO_READ,
 1.6       eeh 				ktriov, len - auio.uio_resid, error);
 1.6       eeh 		FREE(ktriov, M_TEMP);
 1.6       eeh 	}
 1.6       eeh #endif
 1.6       eeh 	if (error)
 1.6       eeh 		goto out;
 1.6       eeh 	*retsize = len - auio.uio_resid;
 1.6       eeh 	if (mp->msg_name) {
 1.6       eeh 		len = mp->msg_namelen;
 1.6       eeh 		if (len <= 0 || from == 0)
 1.6       eeh 			len = 0;
 1.6       eeh 		else {
 1.6       eeh #ifdef COMPAT_OLDSOCK
 1.6       eeh 			if (mp->msg_flags & MSG_COMPAT)
 1.6       eeh 				mtod(from, struct osockaddr *)->sa_family =
 1.6       eeh 				    mtod(from, struct sockaddr *)->sa_family;
 1.6       eeh #endif
 1.6       eeh 			if (len > from->m_len)
 1.6       eeh 				len = from->m_len;
 1.6       eeh 			/* else if len < from->m_len ??? */
 1.6       eeh 			error = copyout(mtod(from, caddr_t),
 1.6       eeh 					(caddr_t)(u_long)mp->msg_name, (unsigned)len);
 1.6       eeh 			if (error)
 1.6       eeh 				goto out;
 1.6       eeh 		}
 1.6       eeh 		mp->msg_namelen = len;
 1.6       eeh 		if (namelenp &&
 1.6       eeh 		    (error = copyout((caddr_t)&len, namelenp, sizeof(int)))) {
 1.6       eeh #ifdef COMPAT_OLDSOCK
 1.6       eeh 			if (mp->msg_flags & MSG_COMPAT)
 1.6       eeh 				error = 0;	/* old recvfrom didn't check */
 1.6       eeh 			else
 1.6       eeh #endif
 1.6       eeh 			goto out;
 1.6       eeh 		}
 1.6       eeh 	}
 1.6       eeh 	if (mp->msg_control) {
 1.6       eeh #ifdef COMPAT_OLDSOCK
 1.6       eeh 		/*
 1.6       eeh 		 * We assume that old recvmsg calls won't receive access
 1.6       eeh 		 * rights and other control info, esp. as control info
 1.6       eeh 		 * is always optional and those options didn't exist in 4.3.
 1.6       eeh 		 * If we receive rights, trim the cmsghdr; anything else
 1.6       eeh 		 * is tossed.
 1.6       eeh 		 */
 1.6       eeh 		if (control && mp->msg_flags & MSG_COMPAT) {
 1.6       eeh 			if (mtod(control, struct cmsghdr *)->cmsg_level !=
 1.6       eeh 			    SOL_SOCKET ||
 1.6       eeh 			    mtod(control, struct cmsghdr *)->cmsg_type !=
 1.6       eeh 			    SCM_RIGHTS) {
 1.6       eeh 				mp->msg_controllen = 0;
 1.6       eeh 				goto out;
 1.6       eeh 			}
 1.6       eeh 			control->m_len -= sizeof(struct cmsghdr);
 1.6       eeh 			control->m_data += sizeof(struct cmsghdr);
 1.6       eeh 		}
 1.6       eeh #endif
 1.6       eeh 		len = mp->msg_controllen;
 1.6       eeh 		if (len <= 0 || control == 0)
 1.6       eeh 			len = 0;
 1.6       eeh 		else {
 1.6       eeh 			struct mbuf *m = control;
 1.6       eeh 			caddr_t p = (caddr_t)(u_long)mp->msg_control;
 1.6       eeh
 1.6       eeh 			do {
 1.6       eeh 				i = m->m_len;
 1.6       eeh 				if (len < i) {
 1.6       eeh 					mp->msg_flags |= MSG_CTRUNC;
 1.6       eeh 					i = len;
 1.6       eeh 				}
 1.6       eeh 				error = copyout(mtod(m, caddr_t), p,
 1.6       eeh 				    (unsigned)i);
 1.6       eeh 				if (m->m_next)
 1.6       eeh 					i = ALIGN(i);
 1.6       eeh 				p += i;
 1.6       eeh 				len -= i;
 1.6       eeh 				if (error != 0 || len <= 0)
 1.6       eeh 					break;
 1.6       eeh 			} while ((m = m->m_next) != NULL);
 1.6       eeh 			len = p - (caddr_t)(u_long)mp->msg_control;
 1.6       eeh 		}
 1.6       eeh 		mp->msg_controllen = len;
 1.6       eeh 	}
1.12   thorpej  out:
 1.6       eeh 	if (from)
 1.6       eeh 		m_freem(from);
 1.6       eeh 	if (control)
 1.6       eeh 		m_freem(control);
1.12   thorpej  out1:
1.19       eeh 	FILE_UNUSE(fp, p);
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32_sendmsg(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_sendmsg_args /* {
 1.1       mrg 		syscallarg(int) s;
1.10       mrg 		syscallarg(const netbsd32_msghdrp_t) msg;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct msghdr msg;
1.10       mrg 	struct netbsd32_msghdr msg32;
 1.6       eeh 	struct iovec aiov[UIO_SMALLIOV], *iov;
 1.1       mrg 	int error;
 1.1       mrg
 1.6       eeh 	error = copyin((caddr_t)(u_long)SCARG(uap, msg),
 1.6       eeh 		       (caddr_t)&msg32, sizeof(msg32));
 1.6       eeh 	if (error)
 1.6       eeh 		return (error);
1.10       mrg 	netbsd32_to_msghdr(&msg32, &msg);
 1.6       eeh 	if ((u_int)msg.msg_iovlen > UIO_SMALLIOV) {
 1.6       eeh 		if ((u_int)msg.msg_iovlen > IOV_MAX)
 1.6       eeh 			return (EMSGSIZE);
 1.6       eeh 		MALLOC(iov, struct iovec *,
 1.6       eeh 		       sizeof(struct iovec) * (u_int)msg.msg_iovlen, M_IOV,
 1.6       eeh 		       M_WAITOK);
 1.6       eeh 	} else if ((u_int)msg.msg_iovlen > 0)
 1.6       eeh 		iov = aiov;
 1.6       eeh 	else
 1.6       eeh 		return (EMSGSIZE);
1.10       mrg 	error = netbsd32_to_iovecin((struct netbsd32_iovec *)msg.msg_iov,
 1.6       eeh 				   iov, msg.msg_iovlen);
 1.6       eeh 	if (error)
 1.6       eeh 		goto done;
 1.6       eeh 	msg.msg_iov = iov;
 1.6       eeh #ifdef COMPAT_OLDSOCK
 1.6       eeh 	msg.msg_flags = 0;
 1.6       eeh #endif
 1.6       eeh 	/* Luckily we can use this directly */
 1.6       eeh 	error = sendit(p, SCARG(uap, s), &msg, SCARG(uap, flags), retval);
 1.6       eeh done:
 1.6       eeh 	if (iov != aiov)
 1.6       eeh 		FREE(iov, M_IOV);
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_recvfrom(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_recvfrom_args /* {
 1.1       mrg 		syscallarg(int) s;
1.10       mrg 		syscallarg(netbsd32_voidp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 		syscallarg(int) flags;
1.10       mrg 		syscallarg(netbsd32_sockaddrp_t) from;
1.10       mrg 		syscallarg(netbsd32_intp) fromlenaddr;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_msghdr msg;
 1.6       eeh 	struct iovec aiov;
 1.1       mrg 	int error;
 1.1       mrg
 1.6       eeh 	if (SCARG(uap, fromlenaddr)) {
 1.6       eeh 		error = copyin((caddr_t)(u_long)SCARG(uap, fromlenaddr),
 1.6       eeh 			       (caddr_t)&msg.msg_namelen,
 1.6       eeh 			       sizeof(msg.msg_namelen));
 1.6       eeh 		if (error)
 1.6       eeh 			return (error);
 1.6       eeh 	} else
 1.6       eeh 		msg.msg_namelen = 0;
 1.6       eeh 	msg.msg_name = SCARG(uap, from);
 1.6       eeh 	msg.msg_iov = NULL; /* We can't store a real pointer here */
 1.6       eeh 	msg.msg_iovlen = 1;
 1.6       eeh 	aiov.iov_base = (caddr_t)(u_long)SCARG(uap, buf);
 1.6       eeh 	aiov.iov_len = (u_long)SCARG(uap, len);
 1.6       eeh 	msg.msg_control = 0;
 1.6       eeh 	msg.msg_flags = SCARG(uap, flags);
 1.6       eeh 	return (recvit32(p, SCARG(uap, s), &msg, &aiov,
 1.6       eeh 		       (caddr_t)(u_long)SCARG(uap, fromlenaddr), retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_sendto(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_sendto_args /* {
 1.1       mrg 		syscallarg(int) s;
1.10       mrg 		syscallarg(const netbsd32_voidp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 		syscallarg(int) flags;
1.10       mrg 		syscallarg(const netbsd32_sockaddrp_t) to;
 1.1       mrg 		syscallarg(int) tolen;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct msghdr msg;
 1.6       eeh 	struct iovec aiov;
 1.1       mrg
 1.6       eeh 	msg.msg_name = (caddr_t)(u_long)SCARG(uap, to);		/* XXX kills const */
 1.6       eeh 	msg.msg_namelen = SCARG(uap, tolen);
 1.6       eeh 	msg.msg_iov = &aiov;
 1.6       eeh 	msg.msg_iovlen = 1;
 1.6       eeh 	msg.msg_control = 0;
 1.6       eeh #ifdef COMPAT_OLDSOCK
 1.6       eeh 	msg.msg_flags = 0;
 1.6       eeh #endif
 1.6       eeh 	aiov.iov_base = (char *)(u_long)SCARG(uap, buf);	/* XXX kills const */
 1.6       eeh 	aiov.iov_len = SCARG(uap, len);
 1.6       eeh 	return (sendit(p, SCARG(uap, s), &msg, SCARG(uap, flags), retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_accept(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_accept_args /* {
 1.1       mrg 		syscallarg(int) s;
1.10       mrg 		syscallarg(netbsd32_sockaddrp_t) name;
1.10       mrg 		syscallarg(netbsd32_intp) anamelen;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_accept_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(s);
1.11       mrg 	NETBSD32TOP_UAP(name, struct sockaddr);
1.11       mrg 	NETBSD32TOP_UAP(anamelen, int);
 1.1       mrg 	return (sys_accept(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getpeername(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getpeername_args /* {
 1.1       mrg 		syscallarg(int) fdes;
1.10       mrg 		syscallarg(netbsd32_sockaddrp_t) asa;
1.10       mrg 		syscallarg(netbsd32_intp) alen;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_getpeername_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fdes);
1.11       mrg 	NETBSD32TOP_UAP(asa, struct sockaddr);
1.11       mrg 	NETBSD32TOP_UAP(alen, int);
 1.6       eeh /* NB: do the protocol specific sockaddrs need to be converted? */
 1.1       mrg 	return (sys_getpeername(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getsockname(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getsockname_args /* {
 1.1       mrg 		syscallarg(int) fdes;
1.10       mrg 		syscallarg(netbsd32_sockaddrp_t) asa;
1.10       mrg 		syscallarg(netbsd32_intp) alen;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_getsockname_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fdes);
1.11       mrg 	NETBSD32TOP_UAP(asa, struct sockaddr);
1.11       mrg 	NETBSD32TOP_UAP(alen, int);
 1.1       mrg 	return (sys_getsockname(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_access(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_access_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_access_args ua;
 1.1       mrg 	caddr_t sg;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(flags);
 1.1       mrg 	sg = stackgap_init(p->p_emul);
1.11       mrg 	NETBSD32_CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path));
 1.1       mrg
 1.1       mrg 	return (sys_access(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_chflags(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_chflags_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(netbsd32_u_long) flags;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_chflags_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(flags);
 1.1       mrg
 1.1       mrg 	return (sys_chflags(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_fchflags(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_fchflags_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(netbsd32_u_long) flags;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_fchflags_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(flags);
 1.1       mrg
 1.1       mrg 	return (sys_fchflags(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_kill(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_kill_args /* {
 1.6       eeh 		syscallarg(int) pid;
 1.6       eeh 		syscallarg(int) signum;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_kill_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(pid);
1.11       mrg 	NETBSD32TO64_UAP(signum);
 1.6       eeh
 1.6       eeh 	return (sys_kill(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_dup(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_dup_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_dup_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
 1.6       eeh
 1.6       eeh 	return (sys_dup(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_profil(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_profil_args /* {
1.10       mrg 		syscallarg(netbsd32_caddr_t) samples;
1.10       mrg 		syscallarg(netbsd32_size_t) size;
1.10       mrg 		syscallarg(netbsd32_u_long) offset;
 1.1       mrg 		syscallarg(u_int) scale;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_profil_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOX64_UAP(samples, caddr_t);
1.11       mrg 	NETBSD32TOX_UAP(size, size_t);
1.11       mrg 	NETBSD32TOX_UAP(offset, u_long);
1.11       mrg 	NETBSD32TO64_UAP(scale);
 1.1       mrg 	return (sys_profil(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_ktrace(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_ktrace_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) fname;
 1.1       mrg 		syscallarg(int) ops;
 1.1       mrg 		syscallarg(int) facs;
 1.1       mrg 		syscallarg(int) pid;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_ktrace_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(fname, const char);
1.11       mrg 	NETBSD32TO64_UAP(ops);
1.11       mrg 	NETBSD32TO64_UAP(facs);
1.11       mrg 	NETBSD32TO64_UAP(pid);
 1.1       mrg 	return (sys_ktrace(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_sigaction(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_sigaction_args /* {
 1.1       mrg 		syscallarg(int) signum;
1.10       mrg 		syscallarg(const netbsd32_sigactionp_t) nsa;
1.10       mrg 		syscallarg(netbsd32_sigactionp_t) osa;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sigaction nsa, osa;
1.10       mrg 	struct netbsd32_sigaction *sa32p, sa32;
 1.1       mrg 	int error;
 1.1       mrg
 1.1       mrg 	if (SCARG(uap, nsa)) {
1.10       mrg 		sa32p = (struct netbsd32_sigaction *)(u_long)SCARG(uap, nsa);
 1.5       eeh 		if (copyin(sa32p, &sa32, sizeof(sa32)))
 1.5       eeh 			return EFAULT;
 1.5       eeh 		nsa.sa_handler = (void *)(u_long)sa32.sa_handler;
 1.5       eeh 		nsa.sa_mask = sa32.sa_mask;
 1.5       eeh 		nsa.sa_flags = sa32.sa_flags;
 1.6       eeh 	}
 1.6       eeh 	error = sigaction1(p, SCARG(uap, signum),
 1.6       eeh 			   SCARG(uap, nsa) ? &nsa : 0,
 1.6       eeh 			   SCARG(uap, osa) ? &osa : 0);
 1.6       eeh
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
 1.1       mrg
 1.1       mrg 	if (SCARG(uap, osa)) {
1.10       mrg 		sa32.sa_handler = (netbsd32_sigactionp_t)(u_long)osa.sa_handler;
 1.5       eeh 		sa32.sa_mask = osa.sa_mask;
 1.5       eeh 		sa32.sa_flags = osa.sa_flags;
1.10       mrg 		sa32p = (struct netbsd32_sigaction *)(u_long)SCARG(uap, osa);
 1.5       eeh 		if (copyout(&sa32, sa32p, sizeof(sa32)))
 1.5       eeh 			return EFAULT;
 1.1       mrg 	}
 1.1       mrg
 1.1       mrg 	return (0);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___getlogin(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___getlogin_args /* {
1.10       mrg 		syscallarg(netbsd32_charp) namebuf;
 1.1       mrg 		syscallarg(u_int) namelen;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys___getlogin_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(namebuf, char);
1.11       mrg 	NETBSD32TO64_UAP(namelen);
 1.1       mrg 	return (sys___getlogin(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_setlogin(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_setlogin_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) namebuf;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_setlogin_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(namebuf, char);
 1.1       mrg 	return (sys_setlogin(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_acct(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_acct_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_acct_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
 1.1       mrg 	return (sys_acct(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_revoke(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_revoke_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_revoke_args ua;
 1.1       mrg 	caddr_t sg;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
 1.1       mrg 	sg = stackgap_init(p->p_emul);
1.11       mrg 	NETBSD32_CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path));
 1.1       mrg
 1.1       mrg 	return (sys_revoke(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_symlink(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_symlink_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(const netbsd32_charp) link;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_symlink_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TOP_UAP(link, const char);
 1.1       mrg
 1.1       mrg 	return (sys_symlink(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_readlink(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_readlink_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(netbsd32_charp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) count;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_readlink_args ua;
 1.1       mrg 	caddr_t sg;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TOP_UAP(buf, char);
1.11       mrg 	NETBSD32TOX_UAP(count, size_t);
 1.1       mrg 	sg = stackgap_init(p->p_emul);
1.11       mrg 	NETBSD32_CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path));
 1.1       mrg
 1.1       mrg 	return (sys_readlink(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
1.20       eeh /*
1.20       eeh  * Need to completly reimplement this syscall due to argument copying.
1.20       eeh  */
 1.1       mrg int
1.19       eeh netbsd32_execve(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_execve_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(netbsd32_charpp) argp;
1.10       mrg 		syscallarg(netbsd32_charpp) envp;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_execve_args ua;
 1.1       mrg 	caddr_t sg;
1.20       eeh 	/* Function args */
1.20       eeh 	int error, i;
1.20       eeh 	struct exec_package pack;
1.20       eeh 	struct nameidata nid;
1.20       eeh 	struct vattr attr;
1.20       eeh 	struct ucred *cred = p->p_ucred;
1.20       eeh 	char *argp;
1.20       eeh 	netbsd32_charp const *cpp;
1.20       eeh 	char *dp;
1.20       eeh 	netbsd32_charp sp;
1.20       eeh 	long argc, envc;
1.20       eeh 	size_t len;
1.20       eeh 	char *stack;
1.20       eeh 	struct ps_strings arginfo;
1.20       eeh 	struct vmspace *vm;
1.20       eeh 	char **tmpfap;
1.20       eeh 	int szsigcode;
1.20       eeh 	extern struct emul emul_netbsd;
1.20       eeh
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TOP_UAP(argp, char *);
1.11       mrg 	NETBSD32TOP_UAP(envp, char *);
 1.1       mrg 	sg = stackgap_init(p->p_emul);
1.11       mrg 	NETBSD32_CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path));
 1.1       mrg
1.20       eeh 	/*
1.20       eeh 	 * figure out the maximum size of an exec header, if necessary.
1.20       eeh 	 * XXX should be able to keep LKM code from modifying exec switch
1.20       eeh 	 * when we're still using it, but...
1.20       eeh 	 */
1.20       eeh 	if (exec_maxhdrsz == 0) {
1.20       eeh 		for (i = 0; i < nexecs; i++)
1.20       eeh 			if (execsw[i].es_check != NULL
1.20       eeh 			    && execsw[i].es_hdrsz > exec_maxhdrsz)
1.20       eeh 				exec_maxhdrsz = execsw[i].es_hdrsz;
1.20       eeh 	}
1.20       eeh
1.20       eeh 	/* init the namei data to point the file user's program name */
1.20       eeh 	/* XXX cgd 960926: why do this here?  most will be clobbered. */
1.20       eeh 	NDINIT(&nid, LOOKUP, NOFOLLOW, UIO_USERSPACE, SCARG(&ua, path), p);
1.20       eeh
1.20       eeh 	/*
1.20       eeh 	 * initialize the fields of the exec package.
1.20       eeh 	 */
1.20       eeh 	pack.ep_name = SCARG(&ua, path);
1.20       eeh 	MALLOC(pack.ep_hdr, void *, exec_maxhdrsz, M_EXEC, M_WAITOK);
1.20       eeh 	pack.ep_hdrlen = exec_maxhdrsz;
1.20       eeh 	pack.ep_hdrvalid = 0;
1.20       eeh 	pack.ep_ndp = &nid;
1.20       eeh 	pack.ep_emul_arg = NULL;
1.20       eeh 	pack.ep_vmcmds.evs_cnt = 0;
1.20       eeh 	pack.ep_vmcmds.evs_used = 0;
1.20       eeh 	pack.ep_vap = &attr;
1.20       eeh 	pack.ep_emul = &emul_netbsd;
1.20       eeh 	pack.ep_flags = 0;
1.20       eeh
1.20       eeh 	/* see if we can run it. */
1.20       eeh 	if ((error = check_exec(p, &pack)) != 0)
1.20       eeh 		goto freehdr;
1.20       eeh
1.20       eeh 	/* XXX -- THE FOLLOWING SECTION NEEDS MAJOR CLEANUP */
1.20       eeh
1.20       eeh 	/* allocate an argument buffer */
1.20       eeh 	argp = (char *) uvm_km_valloc_wait(exec_map, NCARGS);
1.20       eeh #ifdef DIAGNOSTIC
1.20       eeh 	if (argp == (vaddr_t) 0)
1.20       eeh 		panic("execve: argp == NULL");
1.20       eeh #endif
1.20       eeh 	dp = argp;
1.20       eeh 	argc = 0;
1.20       eeh
1.20       eeh 	/* copy the fake args list, if there's one, freeing it as we go */
1.20       eeh 	if (pack.ep_flags & EXEC_HASARGL) {
1.20       eeh 		tmpfap = pack.ep_fa;
1.20       eeh 		while (*tmpfap != NULL) {
1.20       eeh 			char *cp;
1.20       eeh
1.20       eeh 			cp = *tmpfap;
1.20       eeh 			while (*cp)
1.20       eeh 				*dp++ = *cp++;
1.20       eeh 			dp++;
1.20       eeh
1.20       eeh 			FREE(*tmpfap, M_EXEC);
1.20       eeh 			tmpfap++; argc++;
1.20       eeh 		}
1.20       eeh 		FREE(pack.ep_fa, M_EXEC);
1.20       eeh 		pack.ep_flags &= ~EXEC_HASARGL;
1.20       eeh 	}
1.20       eeh
1.20       eeh 	/* Now get argv & environment */
1.20       eeh 	if (!(cpp = (netbsd32_charp *)SCARG(&ua, argp))) {
1.20       eeh 		error = EINVAL;
1.20       eeh 		goto bad;
1.20       eeh 	}
1.20       eeh
1.20       eeh 	if (pack.ep_flags & EXEC_SKIPARG)
1.20       eeh 		cpp++;
1.20       eeh
1.20       eeh 	while (1) {
1.20       eeh 		len = argp + ARG_MAX - dp;
1.20       eeh 		if ((error = copyin(cpp, &sp, sizeof(sp))) != 0)
1.20       eeh 			goto bad;
1.20       eeh 		if (!sp)
1.20       eeh 			break;
1.20       eeh 		if ((error = copyinstr((char *)(u_long)sp, dp,
1.20       eeh 				       len, &len)) != 0) {
1.20       eeh 			if (error == ENAMETOOLONG)
1.20       eeh 				error = E2BIG;
1.20       eeh 			goto bad;
1.20       eeh 		}
1.20       eeh 		dp += len;
1.20       eeh 		cpp++;
1.20       eeh 		argc++;
1.20       eeh 	}
1.20       eeh
1.20       eeh 	envc = 0;
1.20       eeh 	/* environment need not be there */
1.20       eeh 	if ((cpp = (netbsd32_charp *)SCARG(&ua, envp)) != NULL ) {
1.20       eeh 		while (1) {
1.20       eeh 			len = argp + ARG_MAX - dp;
1.20       eeh 			if ((error = copyin(cpp, &sp, sizeof(sp))) != 0)
1.20       eeh 				goto bad;
1.20       eeh 			if (!sp)
1.20       eeh 				break;
1.20       eeh 			if ((error = copyinstr((char *)(u_long)sp,
1.20       eeh 					       dp, len, &len)) != 0) {
1.20       eeh 				if (error == ENAMETOOLONG)
1.20       eeh 					error = E2BIG;
1.20       eeh 				goto bad;
1.20       eeh 			}
1.20       eeh 			dp += len;
1.20       eeh 			cpp++;
1.20       eeh 			envc++;
1.20       eeh 		}
1.20       eeh 	}
1.20       eeh
1.20       eeh 	dp = (char *) ALIGN(dp);
1.20       eeh
1.20       eeh 	szsigcode = pack.ep_emul->e_esigcode - pack.ep_emul->e_sigcode;
1.20       eeh
1.20       eeh 	/* Now check if args & environ fit into new stack */
1.20       eeh 	if (pack.ep_flags & EXEC_32)
1.23       eeh 		len = ((argc + envc + 2 + pack.ep_emul->e_arglen) * sizeof(int) +
1.20       eeh 		       sizeof(int) + dp + STACKGAPLEN + szsigcode +
1.20       eeh 		       sizeof(struct ps_strings)) - argp;
1.20       eeh 	else
1.23       eeh 		len = ((argc + envc + 2 + pack.ep_emul->e_arglen) * sizeof(char *) +
1.20       eeh 		       sizeof(int) + dp + STACKGAPLEN + szsigcode +
1.20       eeh 		       sizeof(struct ps_strings)) - argp;
1.20       eeh
1.20       eeh 	len = ALIGN(len);	/* make the stack "safely" aligned */
1.20       eeh
1.20       eeh 	if (len > pack.ep_ssize) { /* in effect, compare to initial limit */
1.20       eeh 		error = ENOMEM;
1.20       eeh 		goto bad;
1.20       eeh 	}
1.20       eeh
1.20       eeh 	/* adjust "active stack depth" for process VSZ */
1.20       eeh 	pack.ep_ssize = len;	/* maybe should go elsewhere, but... */
1.20       eeh
1.20       eeh 	/*
1.20       eeh 	 * Do whatever is necessary to prepare the address space
1.20       eeh 	 * for remapping.  Note that this might replace the current
1.20       eeh 	 * vmspace with another!
1.20       eeh 	 */
1.20       eeh 	uvmspace_exec(p);
1.20       eeh
1.20       eeh 	/* Now map address space */
1.20       eeh 	vm = p->p_vmspace;
1.20       eeh 	vm->vm_taddr = (char *) pack.ep_taddr;
1.20       eeh 	vm->vm_tsize = btoc(pack.ep_tsize);
1.20       eeh 	vm->vm_daddr = (char *) pack.ep_daddr;
1.20       eeh 	vm->vm_dsize = btoc(pack.ep_dsize);
1.20       eeh 	vm->vm_ssize = btoc(pack.ep_ssize);
1.20       eeh 	vm->vm_maxsaddr = (char *) pack.ep_maxsaddr;
1.20       eeh
1.20       eeh 	/* create the new process's VM space by running the vmcmds */
1.20       eeh #ifdef DIAGNOSTIC
1.20       eeh 	if (pack.ep_vmcmds.evs_used == 0)
1.20       eeh 		panic("execve: no vmcmds");
1.20       eeh #endif
1.20       eeh 	for (i = 0; i < pack.ep_vmcmds.evs_used && !error; i++) {
1.20       eeh 		struct exec_vmcmd *vcp;
1.20       eeh
1.20       eeh 		vcp = &pack.ep_vmcmds.evs_cmds[i];
1.20       eeh 		error = (*vcp->ev_proc)(p, vcp);
1.20       eeh 	}
1.20       eeh
1.20       eeh 	/* free the vmspace-creation commands, and release their references */
1.20       eeh 	kill_vmcmds(&pack.ep_vmcmds);
1.20       eeh
1.20       eeh 	/* if an error happened, deallocate and punt */
1.20       eeh 	if (error)
1.20       eeh 		goto exec_abort;
1.20       eeh
1.20       eeh 	/* remember information about the process */
1.20       eeh 	arginfo.ps_nargvstr = argc;
1.20       eeh 	arginfo.ps_nenvstr = envc;
1.20       eeh
1.20       eeh 	stack = (char *) (USRSTACK - len);
1.20       eeh 	/* Now copy argc, args & environ to new stack */
1.20       eeh 	if (!(*pack.ep_emul->e_copyargs)(&pack, &arginfo, stack, argp))
1.20       eeh 		goto exec_abort;
1.20       eeh
1.20       eeh 	/* copy out the process's ps_strings structure */
1.20       eeh 	if (copyout(&arginfo, (char *) PS_STRINGS, sizeof(arginfo)))
1.20       eeh 		goto exec_abort;
1.20       eeh
1.20       eeh 	/* copy out the process's signal trapoline code */
1.20       eeh 	if (szsigcode) {
1.20       eeh 		if (copyout((char *)pack.ep_emul->e_sigcode,
1.20       eeh 		    p->p_sigacts->ps_sigcode = (char *)PS_STRINGS - szsigcode,
1.20       eeh 		    szsigcode))
1.20       eeh 			goto exec_abort;
1.20       eeh #ifdef PMAP_NEED_PROCWR
1.20       eeh 		/* This is code. Let the pmap do what is needed. */
1.20       eeh 		pmap_procwr(p, (vaddr_t)p->p_sigacts->ps_sigcode, szsigcode);
1.20       eeh #endif
1.20       eeh 	}
1.20       eeh
1.20       eeh 	stopprofclock(p);	/* stop profiling */
1.20       eeh 	fdcloseexec(p);		/* handle close on exec */
1.20       eeh 	execsigs(p);		/* reset catched signals */
1.20       eeh 	p->p_ctxlink = NULL;	/* reset ucontext link */
1.20       eeh
1.20       eeh 	/* set command name & other accounting info */
1.20       eeh 	len = min(nid.ni_cnd.cn_namelen, MAXCOMLEN);
1.20       eeh 	memcpy(p->p_comm, nid.ni_cnd.cn_nameptr, len);
1.20       eeh 	p->p_comm[len] = 0;
1.20       eeh 	p->p_acflag &= ~AFORK;
1.20       eeh
1.20       eeh 	/* record proc's vnode, for use by procfs and others */
1.20       eeh         if (p->p_textvp)
1.20       eeh                 vrele(p->p_textvp);
1.20       eeh 	VREF(pack.ep_vp);
1.20       eeh 	p->p_textvp = pack.ep_vp;
1.20       eeh
1.20       eeh 	p->p_flag |= P_EXEC;
1.20       eeh 	if (p->p_flag & P_PPWAIT) {
1.20       eeh 		p->p_flag &= ~P_PPWAIT;
1.20       eeh 		wakeup((caddr_t) p->p_pptr);
1.20       eeh 	}
1.20       eeh
1.20       eeh 	/*
1.20       eeh 	 * deal with set[ug]id.
1.20       eeh 	 * MNT_NOSUID and P_TRACED have already been used to disable s[ug]id.
1.20       eeh 	 */
1.20       eeh 	if (((attr.va_mode & S_ISUID) != 0 && p->p_ucred->cr_uid != attr.va_uid)
1.20       eeh 	 || ((attr.va_mode & S_ISGID) != 0 && p->p_ucred->cr_gid != attr.va_gid)){
1.20       eeh 		p->p_ucred = crcopy(cred);
1.20       eeh #ifdef KTRACE
1.20       eeh 		/*
1.20       eeh 		 * If process is being ktraced, turn off - unless
1.20       eeh 		 * root set it.
1.20       eeh 		 */
1.20       eeh 		if (p->p_tracep && !(p->p_traceflag & KTRFAC_ROOT))
1.20       eeh 			ktrderef(p);
1.20       eeh #endif
1.20       eeh 		if (attr.va_mode & S_ISUID)
1.20       eeh 			p->p_ucred->cr_uid = attr.va_uid;
1.20       eeh 		if (attr.va_mode & S_ISGID)
1.20       eeh 			p->p_ucred->cr_gid = attr.va_gid;
1.20       eeh 		p_sugid(p);
1.20       eeh 	} else
1.20       eeh 		p->p_flag &= ~P_SUGID;
1.20       eeh 	p->p_cred->p_svuid = p->p_ucred->cr_uid;
1.20       eeh 	p->p_cred->p_svgid = p->p_ucred->cr_gid;
1.20       eeh
1.20       eeh 	uvm_km_free_wakeup(exec_map, (vaddr_t) argp, NCARGS);
1.20       eeh
1.20       eeh 	FREE(nid.ni_cnd.cn_pnbuf, M_NAMEI);
1.20       eeh 	vn_lock(pack.ep_vp, LK_EXCLUSIVE | LK_RETRY);
1.20       eeh 	VOP_CLOSE(pack.ep_vp, FREAD, cred, p);
1.20       eeh 	vput(pack.ep_vp);
1.20       eeh
1.20       eeh 	/* setup new registers and do misc. setup. */
1.20       eeh 	(*pack.ep_emul->e_setregs)(p, &pack, (u_long) stack);
1.20       eeh
1.20       eeh 	if (p->p_flag & P_TRACED)
1.20       eeh 		psignal(p, SIGTRAP);
1.20       eeh
1.20       eeh 	p->p_emul = pack.ep_emul;
1.20       eeh 	FREE(pack.ep_hdr, M_EXEC);
1.20       eeh
1.20       eeh #ifdef KTRACE
1.20       eeh 	if (KTRPOINT(p, KTR_EMUL))
1.20       eeh 		ktremul(p->p_tracep, p, p->p_emul->e_name);
1.20       eeh #endif
1.20       eeh
1.20       eeh 	return (EJUSTRETURN);
1.20       eeh
1.20       eeh bad:
1.20       eeh 	/* free the vmspace-creation commands, and release their references */
1.20       eeh 	kill_vmcmds(&pack.ep_vmcmds);
1.20       eeh 	/* kill any opened file descriptor, if necessary */
1.20       eeh 	if (pack.ep_flags & EXEC_HASFD) {
1.20       eeh 		pack.ep_flags &= ~EXEC_HASFD;
1.20       eeh 		(void) fdrelease(p, pack.ep_fd);
1.20       eeh 	}
1.20       eeh 	/* close and put the exec'd file */
1.20       eeh 	vn_lock(pack.ep_vp, LK_EXCLUSIVE | LK_RETRY);
1.20       eeh 	VOP_CLOSE(pack.ep_vp, FREAD, cred, p);
1.20       eeh 	vput(pack.ep_vp);
1.20       eeh 	FREE(nid.ni_cnd.cn_pnbuf, M_NAMEI);
1.20       eeh 	uvm_km_free_wakeup(exec_map, (vaddr_t) argp, NCARGS);
1.20       eeh
1.20       eeh freehdr:
1.20       eeh 	FREE(pack.ep_hdr, M_EXEC);
1.20       eeh 	return error;
1.20       eeh
1.20       eeh exec_abort:
1.20       eeh 	/*
1.20       eeh 	 * the old process doesn't exist anymore.  exit gracefully.
1.20       eeh 	 * get rid of the (new) address space we have created, if any, get rid
1.20       eeh 	 * of our namei data and vnode, and exit noting failure
1.20       eeh 	 */
1.20       eeh 	uvm_deallocate(&vm->vm_map, VM_MIN_ADDRESS,
1.20       eeh 		VM_MAXUSER_ADDRESS - VM_MIN_ADDRESS);
1.20       eeh 	if (pack.ep_emul_arg)
1.20       eeh 		FREE(pack.ep_emul_arg, M_TEMP);
1.20       eeh 	FREE(nid.ni_cnd.cn_pnbuf, M_NAMEI);
1.20       eeh 	vn_lock(pack.ep_vp, LK_EXCLUSIVE | LK_RETRY);
1.20       eeh 	VOP_CLOSE(pack.ep_vp, FREAD, cred, p);
1.20       eeh 	vput(pack.ep_vp);
1.20       eeh 	uvm_km_free_wakeup(exec_map, (vaddr_t) argp, NCARGS);
1.20       eeh 	FREE(pack.ep_hdr, M_EXEC);
1.20       eeh 	exit1(p, W_EXITCODE(0, SIGABRT));
1.20       eeh 	exit1(p, -1);
1.20       eeh
1.20       eeh 	/* NOTREACHED */
1.20       eeh 	return 0;
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_umask(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_umask_args /* {
 1.6       eeh 		syscallarg(mode_t) newmask;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_umask_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(newmask);
 1.6       eeh 	return (sys_umask(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_chroot(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_chroot_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_chroot_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
 1.1       mrg 	return (sys_chroot(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_sbrk(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_sbrk_args /* {
 1.6       eeh 		syscallarg(int) incr;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_sbrk_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(incr);
 1.6       eeh 	return (sys_sbrk(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_sstk(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_sstk_args /* {
 1.6       eeh 		syscallarg(int) incr;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_sstk_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(incr);
 1.6       eeh 	return (sys_sstk(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_munmap(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_munmap_args /* {
1.10       mrg 		syscallarg(netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_munmap_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, void);
1.11       mrg 	NETBSD32TOX_UAP(len, size_t);
 1.1       mrg 	return (sys_munmap(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_mprotect(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mprotect_args /* {
1.10       mrg 		syscallarg(netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 		syscallarg(int) prot;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mprotect_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, void);
1.11       mrg 	NETBSD32TOX_UAP(len, size_t);
1.11       mrg 	NETBSD32TO64_UAP(prot);
 1.1       mrg 	return (sys_mprotect(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_madvise(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_madvise_args /* {
1.10       mrg 		syscallarg(netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 		syscallarg(int) behav;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_madvise_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, void);
1.11       mrg 	NETBSD32TOX_UAP(len, size_t);
1.11       mrg 	NETBSD32TO64_UAP(behav);
 1.1       mrg 	return (sys_madvise(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_mincore(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mincore_args /* {
1.10       mrg 		syscallarg(netbsd32_caddr_t) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
1.10       mrg 		syscallarg(netbsd32_charp) vec;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mincore_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOX64_UAP(addr, caddr_t);
1.11       mrg 	NETBSD32TOX_UAP(len, size_t);
1.11       mrg 	NETBSD32TOP_UAP(vec, char);
 1.1       mrg 	return (sys_mincore(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getgroups(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getgroups_args /* {
 1.1       mrg 		syscallarg(int) gidsetsize;
1.10       mrg 		syscallarg(netbsd32_gid_tp) gidset;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	register struct pcred *pc = p->p_cred;
 1.6       eeh 	register int ngrp;
 1.6       eeh 	int error;
 1.1       mrg
 1.6       eeh 	ngrp = SCARG(uap, gidsetsize);
 1.6       eeh 	if (ngrp == 0) {
 1.6       eeh 		*retval = pc->pc_ucred->cr_ngroups;
 1.6       eeh 		return (0);
 1.6       eeh 	}
 1.6       eeh 	if (ngrp < pc->pc_ucred->cr_ngroups)
 1.6       eeh 		return (EINVAL);
 1.6       eeh 	ngrp = pc->pc_ucred->cr_ngroups;
1.10       mrg 	/* Should convert gid_t to netbsd32_gid_t, but they're the same */
 1.6       eeh 	error = copyout((caddr_t)pc->pc_ucred->cr_groups,
 1.6       eeh 			(caddr_t)(u_long)SCARG(uap, gidset),
 1.6       eeh 			ngrp * sizeof(gid_t));
 1.6       eeh 	if (error)
 1.6       eeh 		return (error);
 1.6       eeh 	*retval = ngrp;
 1.6       eeh 	return (0);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_setgroups(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_setgroups_args /* {
 1.1       mrg 		syscallarg(int) gidsetsize;
1.10       mrg 		syscallarg(const netbsd32_gid_tp) gidset;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_setgroups_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(gidsetsize);
1.11       mrg 	NETBSD32TOP_UAP(gidset, gid_t);
 1.1       mrg 	return (sys_setgroups(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_setpgid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_setpgid_args /* {
 1.6       eeh 		syscallarg(int) pid;
 1.6       eeh 		syscallarg(int) pgid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_setpgid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(pid);
1.11       mrg 	NETBSD32TO64_UAP(pgid);
 1.6       eeh 	return (sys_setpgid(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_setitimer(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_setitimer_args /* {
 1.1       mrg 		syscallarg(int) which;
1.10       mrg 		syscallarg(const netbsd32_itimervalp_t) itv;
1.10       mrg 		syscallarg(netbsd32_itimervalp_t) oitv;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_itimerval s32it, *itvp;
 1.6       eeh 	int which = SCARG(uap, which);
1.19       eeh 	struct netbsd32_getitimer_args getargs;
 1.6       eeh 	struct itimerval aitv;
 1.6       eeh 	int s, error;
 1.1       mrg
 1.6       eeh 	if ((u_int)which > ITIMER_PROF)
 1.6       eeh 		return (EINVAL);
1.10       mrg 	itvp = (struct netbsd32_itimerval *)(u_long)SCARG(uap, itv);
 1.6       eeh 	if (itvp && (error = copyin(itvp, &s32it, sizeof(s32it))))
 1.6       eeh 		return (error);
1.10       mrg 	netbsd32_to_itimerval(&s32it, &aitv);
 1.6       eeh 	if (SCARG(uap, oitv) != NULL) {
 1.6       eeh 		SCARG(&getargs, which) = which;
 1.6       eeh 		SCARG(&getargs, itv) = SCARG(uap, oitv);
1.19       eeh 		if ((error = netbsd32_getitimer(p, &getargs, retval)) != 0)
 1.6       eeh 			return (error);
 1.6       eeh 	}
 1.6       eeh 	if (itvp == 0)
 1.6       eeh 		return (0);
 1.6       eeh 	if (itimerfix(&aitv.it_value) || itimerfix(&aitv.it_interval))
 1.6       eeh 		return (EINVAL);
 1.6       eeh 	s = splclock();
 1.6       eeh 	if (which == ITIMER_REAL) {
 1.6       eeh 		untimeout(realitexpire, p);
 1.6       eeh 		if (timerisset(&aitv.it_value)) {
 1.6       eeh 			timeradd(&aitv.it_value, &time, &aitv.it_value);
 1.6       eeh 			timeout(realitexpire, p, hzto(&aitv.it_value));
 1.6       eeh 		}
 1.6       eeh 		p->p_realtimer = aitv;
 1.1       mrg 	} else
 1.6       eeh 		p->p_stats->p_timer[which] = aitv;
 1.6       eeh 	splx(s);
 1.6       eeh 	return (0);
 1.6       eeh }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getitimer(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getitimer_args /* {
 1.1       mrg 		syscallarg(int) which;
1.10       mrg 		syscallarg(netbsd32_itimervalp_t) itv;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int which = SCARG(uap, which);
1.10       mrg 	struct netbsd32_itimerval s32it;
 1.6       eeh 	struct itimerval aitv;
 1.6       eeh 	int s;
 1.1       mrg
 1.6       eeh 	if ((u_int)which > ITIMER_PROF)
 1.6       eeh 		return (EINVAL);
 1.6       eeh 	s = splclock();
 1.6       eeh 	if (which == ITIMER_REAL) {
 1.6       eeh 		/*
 1.6       eeh 		 * Convert from absolute to relative time in .it_value
 1.6       eeh 		 * part of real time timer.  If time for real time timer
 1.6       eeh 		 * has passed return 0, else return difference between
 1.6       eeh 		 * current time and time for the timer to go off.
 1.6       eeh 		 */
 1.6       eeh 		aitv = p->p_realtimer;
 1.6       eeh 		if (timerisset(&aitv.it_value)) {
 1.6       eeh 			if (timercmp(&aitv.it_value, &time, <))
 1.6       eeh 				timerclear(&aitv.it_value);
 1.6       eeh 			else
 1.6       eeh 				timersub(&aitv.it_value, &time, &aitv.it_value);
 1.6       eeh 		}
 1.6       eeh 	} else
 1.6       eeh 		aitv = p->p_stats->p_timer[which];
 1.6       eeh 	splx(s);
1.10       mrg 	netbsd32_from_itimerval(&aitv, &s32it);
 1.6       eeh 	return (copyout(&s32it, (caddr_t)(u_long)SCARG(uap, itv), sizeof(s32it)));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_fcntl(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_fcntl_args /* {
 1.1       mrg 		syscallarg(int) fd;
 1.1       mrg 		syscallarg(int) cmd;
1.10       mrg 		syscallarg(netbsd32_voidp) arg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_fcntl_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(cmd);
1.11       mrg 	NETBSD32TOP_UAP(arg, void);
 1.6       eeh 	/* XXXX we can do this 'cause flock doesn't change */
 1.1       mrg 	return (sys_fcntl(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_dup2(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_dup2_args /* {
 1.6       eeh 		syscallarg(int) from;
 1.6       eeh 		syscallarg(int) to;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_dup2_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(from);
1.11       mrg 	NETBSD32TO64_UAP(to);
 1.6       eeh 	return (sys_dup2(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_select(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_select_args /* {
 1.1       mrg 		syscallarg(int) nd;
1.10       mrg 		syscallarg(netbsd32_fd_setp_t) in;
1.10       mrg 		syscallarg(netbsd32_fd_setp_t) ou;
1.10       mrg 		syscallarg(netbsd32_fd_setp_t) ex;
1.10       mrg 		syscallarg(netbsd32_timevalp_t) tv;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh /* This one must be done in-line 'cause of the timeval */
1.10       mrg 	struct netbsd32_timeval tv32;
 1.6       eeh 	caddr_t bits;
 1.6       eeh 	char smallbits[howmany(FD_SETSIZE, NFDBITS) * sizeof(fd_mask) * 6];
 1.6       eeh 	struct timeval atv;
 1.6       eeh 	int s, ncoll, error = 0, timo;
 1.6       eeh 	size_t ni;
 1.6       eeh 	extern int	selwait, nselcoll;
 1.6       eeh 	extern int selscan __P((struct proc *, fd_mask *, fd_mask *, int, register_t *));
 1.1       mrg
 1.6       eeh 	if (SCARG(uap, nd) < 0)
 1.6       eeh 		return (EINVAL);
 1.6       eeh 	if (SCARG(uap, nd) > p->p_fd->fd_nfiles) {
 1.6       eeh 		/* forgiving; slightly wrong */
 1.6       eeh 		SCARG(uap, nd) = p->p_fd->fd_nfiles;
 1.5       eeh 	}
 1.6       eeh 	ni = howmany(SCARG(uap, nd), NFDBITS) * sizeof(fd_mask);
 1.6       eeh 	if (ni * 6 > sizeof(smallbits))
 1.6       eeh 		bits = malloc(ni * 6, M_TEMP, M_WAITOK);
 1.6       eeh 	else
 1.6       eeh 		bits = smallbits;
 1.1       mrg
 1.6       eeh #define	getbits(name, x) \
 1.6       eeh 	if (SCARG(uap, name)) { \
 1.6       eeh 		error = copyin((caddr_t)(u_long)SCARG(uap, name), bits + ni * x, ni); \
 1.6       eeh 		if (error) \
 1.6       eeh 			goto done; \
 1.6       eeh 	} else \
 1.6       eeh 		memset(bits + ni * x, 0, ni);
 1.6       eeh 	getbits(in, 0);
 1.6       eeh 	getbits(ou, 1);
 1.6       eeh 	getbits(ex, 2);
 1.6       eeh #undef	getbits
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, tv)) {
 1.6       eeh 		error = copyin((caddr_t)(u_long)SCARG(uap, tv), (caddr_t)&tv32,
 1.6       eeh 			sizeof(tv32));
 1.6       eeh 		if (error)
 1.6       eeh 			goto done;
1.10       mrg 		netbsd32_to_timeval(&tv32, &atv);
 1.6       eeh 		if (itimerfix(&atv)) {
 1.6       eeh 			error = EINVAL;
 1.6       eeh 			goto done;
 1.6       eeh 		}
 1.6       eeh 		s = splclock();
 1.6       eeh 		timeradd(&atv, &time, &atv);
 1.6       eeh 		timo = hzto(&atv);
 1.6       eeh 		/*
 1.6       eeh 		 * Avoid inadvertently sleeping forever.
 1.6       eeh 		 */
 1.6       eeh 		if (timo == 0)
 1.6       eeh 			timo = 1;
 1.6       eeh 		splx(s);
 1.6       eeh 	} else
 1.6       eeh 		timo = 0;
 1.6       eeh retry:
 1.6       eeh 	ncoll = nselcoll;
 1.6       eeh 	p->p_flag |= P_SELECT;
 1.6       eeh 	error = selscan(p, (fd_mask *)(bits + ni * 0),
 1.6       eeh 			   (fd_mask *)(bits + ni * 3), SCARG(uap, nd), retval);
 1.6       eeh 	if (error || *retval)
 1.6       eeh 		goto done;
 1.6       eeh 	s = splhigh();
 1.6       eeh 	if (timo && timercmp(&time, &atv, >=)) {
 1.6       eeh 		splx(s);
 1.6       eeh 		goto done;
 1.6       eeh 	}
 1.6       eeh 	if ((p->p_flag & P_SELECT) == 0 || nselcoll != ncoll) {
 1.6       eeh 		splx(s);
 1.6       eeh 		goto retry;
 1.6       eeh 	}
 1.6       eeh 	p->p_flag &= ~P_SELECT;
 1.6       eeh 	error = tsleep((caddr_t)&selwait, PSOCK | PCATCH, "select", timo);
 1.6       eeh 	splx(s);
 1.6       eeh 	if (error == 0)
 1.6       eeh 		goto retry;
 1.6       eeh done:
 1.6       eeh 	p->p_flag &= ~P_SELECT;
 1.6       eeh 	/* select is not restarted after signals... */
 1.6       eeh 	if (error == ERESTART)
 1.6       eeh 		error = EINTR;
 1.6       eeh 	if (error == EWOULDBLOCK)
 1.6       eeh 		error = 0;
 1.6       eeh 	if (error == 0) {
 1.6       eeh #define	putbits(name, x) \
 1.6       eeh 		if (SCARG(uap, name)) { \
 1.6       eeh 			error = copyout(bits + ni * x, (caddr_t)(u_long)SCARG(uap, name), ni); \
 1.6       eeh 			if (error) \
 1.6       eeh 				goto out; \
 1.6       eeh 		}
 1.6       eeh 		putbits(in, 3);
 1.6       eeh 		putbits(ou, 4);
 1.6       eeh 		putbits(ex, 5);
 1.6       eeh #undef putbits
 1.5       eeh 	}
 1.6       eeh out:
 1.6       eeh 	if (ni * 6 > sizeof(smallbits))
 1.6       eeh 		free(bits, M_TEMP);
 1.6       eeh 	return (error);
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_fsync(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_fsync_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_fsync_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
 1.6       eeh 	return (sys_fsync(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_setpriority(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_setpriority_args /* {
 1.6       eeh 		syscallarg(int) which;
 1.6       eeh 		syscallarg(int) who;
 1.6       eeh 		syscallarg(int) prio;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_setpriority_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(which);
1.11       mrg 	NETBSD32TO64_UAP(who);
1.11       mrg 	NETBSD32TO64_UAP(prio);
 1.6       eeh 	return (sys_setpriority(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_socket(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_socket_args /* {
 1.6       eeh 		syscallarg(int) domain;
 1.6       eeh 		syscallarg(int) type;
 1.6       eeh 		syscallarg(int) protocol;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_socket_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(domain);
1.11       mrg 	NETBSD32TO64_UAP(type);
1.11       mrg 	NETBSD32TO64_UAP(protocol);
 1.6       eeh 	return (sys_socket(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_connect(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_connect_args /* {
 1.1       mrg 		syscallarg(int) s;
1.10       mrg 		syscallarg(const netbsd32_sockaddrp_t) name;
 1.1       mrg 		syscallarg(int) namelen;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_connect_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(s);
1.11       mrg 	NETBSD32TOP_UAP(name, struct sockaddr);
1.11       mrg 	NETBSD32TO64_UAP(namelen);
 1.1       mrg 	return (sys_connect(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.6       eeh int
1.19       eeh netbsd32_getpriority(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_getpriority_args /* {
 1.6       eeh 		syscallarg(int) which;
 1.6       eeh 		syscallarg(int) who;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_getpriority_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(which);
1.11       mrg 	NETBSD32TO64_UAP(who);
 1.6       eeh 	return (sys_getpriority(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32_bind(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_bind_args /* {
 1.1       mrg 		syscallarg(int) s;
1.10       mrg 		syscallarg(const netbsd32_sockaddrp_t) name;
 1.1       mrg 		syscallarg(int) namelen;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct sys_bind_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(s);
1.11       mrg 	NETBSD32TOP_UAP(name, struct sockaddr);
1.11       mrg 	NETBSD32TO64_UAP(namelen);
 1.6       eeh 	return (sys_bind(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_setsockopt(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_setsockopt_args /* {
 1.1       mrg 		syscallarg(int) s;
 1.1       mrg 		syscallarg(int) level;
 1.1       mrg 		syscallarg(int) name;
1.10       mrg 		syscallarg(const netbsd32_voidp) val;
 1.1       mrg 		syscallarg(int) valsize;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_setsockopt_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(s);
1.11       mrg 	NETBSD32TO64_UAP(level);
1.11       mrg 	NETBSD32TO64_UAP(name);
1.11       mrg 	NETBSD32TOP_UAP(val, void);
1.11       mrg 	NETBSD32TO64_UAP(valsize);
 1.6       eeh 	/* may be more efficient to do this inline. */
 1.1       mrg 	return (sys_setsockopt(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_listen(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_listen_args /* {
 1.6       eeh 		syscallarg(int) s;
 1.6       eeh 		syscallarg(int) backlog;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_listen_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(s);
1.11       mrg 	NETBSD32TO64_UAP(backlog);
 1.6       eeh 	return (sys_listen(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_gettimeofday(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_gettimeofday_args /* {
1.10       mrg 		syscallarg(netbsd32_timevalp_t) tp;
1.10       mrg 		syscallarg(netbsd32_timezonep_t) tzp;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct timeval atv;
1.10       mrg 	struct netbsd32_timeval tv32;
 1.6       eeh 	int error = 0;
1.10       mrg 	struct netbsd32_timezone tzfake;
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, tp)) {
 1.6       eeh 		microtime(&atv);
1.10       mrg 		netbsd32_from_timeval(&atv, &tv32);
 1.6       eeh 		error = copyout(&tv32, (caddr_t)(u_long)SCARG(uap, tp), sizeof(tv32));
 1.6       eeh 		if (error)
 1.6       eeh 			return (error);
 1.6       eeh 	}
 1.6       eeh 	if (SCARG(uap, tzp)) {
 1.6       eeh 		/*
 1.6       eeh 		 * NetBSD has no kernel notion of time zone, so we just
 1.6       eeh 		 * fake up a timezone struct and return it if demanded.
 1.6       eeh 		 */
 1.6       eeh 		tzfake.tz_minuteswest = 0;
 1.6       eeh 		tzfake.tz_dsttime = 0;
 1.6       eeh 		error = copyout(&tzfake, (caddr_t)(u_long)SCARG(uap, tzp), sizeof(tzfake));
 1.6       eeh 	}
 1.6       eeh 	return (error);
 1.6       eeh }
 1.1       mrg
1.20       eeh #if 0
1.20       eeh static int settime32 __P((struct timeval *));
 1.6       eeh /* This function is used by clock_settime and settimeofday */
 1.6       eeh static int
1.20       eeh settime32(tv)
 1.6       eeh 	struct timeval *tv;
 1.6       eeh {
 1.6       eeh 	struct timeval delta;
 1.6       eeh 	int s;
 1.1       mrg
 1.6       eeh 	/* WHAT DO WE DO ABOUT PENDING REAL-TIME TIMEOUTS??? */
 1.6       eeh 	s = splclock();
 1.6       eeh 	timersub(tv, &time, &delta);
 1.6       eeh 	if ((delta.tv_sec < 0 || delta.tv_usec < 0) && securelevel > 1)
 1.6       eeh 		return (EPERM);
 1.6       eeh #ifdef notyet
 1.6       eeh 	if ((delta.tv_sec < 86400) && securelevel > 0)
 1.6       eeh 		return (EPERM);
 1.6       eeh #endif
 1.6       eeh 	time = *tv;
1.17   thorpej 	(void) spllowersoftclock();
 1.6       eeh 	timeradd(&boottime, &delta, &boottime);
 1.6       eeh 	timeradd(&runtime, &delta, &runtime);
 1.6       eeh #	if defined(NFS) || defined(NFSSERVER)
1.20       eeh 	{
1.20       eeh 		extern void	nqnfs_lease_updatetime __P((int));
1.20       eeh
 1.6       eeh 		nqnfs_lease_updatetime(delta.tv_sec);
1.20       eeh 	}
 1.6       eeh #	endif
 1.6       eeh 	splx(s);
 1.6       eeh 	resettodr();
 1.1       mrg 	return (0);
 1.1       mrg }
1.20       eeh #endif
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32_settimeofday(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_settimeofday_args /* {
1.10       mrg 		syscallarg(const netbsd32_timevalp_t) tv;
1.10       mrg 		syscallarg(const netbsd32_timezonep_t) tzp;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_timeval atv32;
 1.6       eeh 	struct timeval atv;
1.10       mrg 	struct netbsd32_timezone atz;
 1.1       mrg 	int error;
 1.1       mrg
 1.6       eeh 	if ((error = suser(p->p_ucred, &p->p_acflag)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh 	/* Verify all parameters before changing time. */
 1.6       eeh 	if (SCARG(uap, tv) && (error = copyin((caddr_t)(u_long)SCARG(uap, tv),
 1.6       eeh 	    &atv32, sizeof(atv32))))
 1.6       eeh 		return (error);
1.10       mrg 	netbsd32_to_timeval(&atv32, &atv);
 1.6       eeh 	/* XXX since we don't use tz, probably no point in doing copyin. */
 1.6       eeh 	if (SCARG(uap, tzp) && (error = copyin((caddr_t)(u_long)SCARG(uap, tzp),
 1.6       eeh 	    &atz, sizeof(atz))))
 1.1       mrg 		return (error);
 1.6       eeh 	if (SCARG(uap, tv))
 1.6       eeh 		if ((error = settime(&atv)))
 1.6       eeh 			return (error);
 1.6       eeh 	/*
 1.6       eeh 	 * NetBSD has no kernel notion of time zone, and only an
 1.6       eeh 	 * obsolete program would try to set it, so we log a warning.
 1.6       eeh 	 */
 1.6       eeh 	if (SCARG(uap, tzp))
 1.6       eeh 		printf("pid %d attempted to set the "
 1.6       eeh 		    "(obsolete) kernel time zone\n", p->p_pid);
 1.6       eeh 	return (0);
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_fchown(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_fchown_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 		syscallarg(uid_t) uid;
 1.6       eeh 		syscallarg(gid_t) gid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_fchown_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(uid);
1.11       mrg 	NETBSD32TO64_UAP(gid);
 1.6       eeh 	return (sys_fchown(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_fchmod(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_fchmod_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 		syscallarg(mode_t) mode;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_fchmod_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(mode);
 1.6       eeh 	return (sys_fchmod(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_setreuid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_setreuid_args /* {
 1.6       eeh 		syscallarg(uid_t) ruid;
 1.6       eeh 		syscallarg(uid_t) euid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_setreuid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(ruid);
1.11       mrg 	NETBSD32TO64_UAP(euid);
 1.6       eeh 	return (sys_setreuid(p, &ua, retval));
 1.6       eeh }
 1.1       mrg
 1.6       eeh int
1.19       eeh netbsd32_setregid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_setregid_args /* {
 1.6       eeh 		syscallarg(gid_t) rgid;
 1.6       eeh 		syscallarg(gid_t) egid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_setregid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(rgid);
1.11       mrg 	NETBSD32TO64_UAP(egid);
 1.6       eeh 	return (sys_setregid(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getrusage(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getrusage_args /* {
 1.1       mrg 		syscallarg(int) who;
1.10       mrg 		syscallarg(netbsd32_rusagep_t) rusage;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct rusage *rup;
1.10       mrg 	struct netbsd32_rusage ru;
 1.6       eeh
 1.6       eeh 	switch (SCARG(uap, who)) {
 1.1       mrg
 1.6       eeh 	case RUSAGE_SELF:
 1.6       eeh 		rup = &p->p_stats->p_ru;
 1.6       eeh 		calcru(p, &rup->ru_utime, &rup->ru_stime, NULL);
 1.6       eeh 		break;
 1.1       mrg
 1.6       eeh 	case RUSAGE_CHILDREN:
 1.6       eeh 		rup = &p->p_stats->p_cru;
 1.6       eeh 		break;
 1.1       mrg
 1.6       eeh 	default:
 1.6       eeh 		return (EINVAL);
 1.6       eeh 	}
1.10       mrg 	netbsd32_from_rusage(rup, &ru);
 1.6       eeh 	return (copyout(&ru, (caddr_t)(u_long)SCARG(uap, rusage), sizeof(ru)));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getsockopt(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getsockopt_args /* {
 1.1       mrg 		syscallarg(int) s;
 1.1       mrg 		syscallarg(int) level;
 1.1       mrg 		syscallarg(int) name;
1.10       mrg 		syscallarg(netbsd32_voidp) val;
1.10       mrg 		syscallarg(netbsd32_intp) avalsize;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_getsockopt_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(s);
1.11       mrg 	NETBSD32TO64_UAP(level);
1.11       mrg 	NETBSD32TO64_UAP(name);
1.11       mrg 	NETBSD32TOP_UAP(val, void);
1.11       mrg 	NETBSD32TOP_UAP(avalsize, int);
 1.1       mrg 	return (sys_getsockopt(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_readv(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_readv_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(const netbsd32_iovecp_t) iovp;
 1.1       mrg 		syscallarg(int) iovcnt;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int fd = SCARG(uap, fd);
 1.6       eeh 	register struct file *fp;
 1.6       eeh 	register struct filedesc *fdp = p->p_fd;
 1.6       eeh
 1.6       eeh 	if ((u_int)fd >= fdp->fd_nfiles ||
 1.6       eeh 	    (fp = fdp->fd_ofiles[fd]) == NULL ||
 1.6       eeh 	    (fp->f_flag & FREAD) == 0)
 1.6       eeh 		return (EBADF);
 1.6       eeh
1.10       mrg 	return (dofilereadv32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp),
 1.6       eeh 			      SCARG(uap, iovcnt), &fp->f_offset, FOF_UPDATE_OFFSET, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh /* Damn thing copies in the iovec! */
 1.6       eeh int
 1.6       eeh dofilereadv32(p, fd, fp, iovp, iovcnt, offset, flags, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	int fd;
 1.6       eeh 	struct file *fp;
1.10       mrg 	struct netbsd32_iovec *iovp;
 1.6       eeh 	int iovcnt;
 1.6       eeh 	off_t *offset;
 1.6       eeh 	int flags;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
 1.6       eeh 	struct uio auio;
 1.6       eeh 	register struct iovec *iov;
 1.6       eeh 	struct iovec *needfree;
 1.6       eeh 	struct iovec aiov[UIO_SMALLIOV];
 1.6       eeh 	long i, cnt, error = 0;
 1.6       eeh 	u_int iovlen;
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	struct iovec *ktriov = NULL;
 1.6       eeh #endif
 1.1       mrg
 1.6       eeh 	/* note: can't use iovlen until iovcnt is validated */
 1.6       eeh 	iovlen = iovcnt * sizeof(struct iovec);
 1.6       eeh 	if ((u_int)iovcnt > UIO_SMALLIOV) {
 1.6       eeh 		if ((u_int)iovcnt > IOV_MAX)
 1.6       eeh 			return (EINVAL);
 1.6       eeh 		MALLOC(iov, struct iovec *, iovlen, M_IOV, M_WAITOK);
 1.6       eeh 		needfree = iov;
 1.6       eeh 	} else if ((u_int)iovcnt > 0) {
 1.6       eeh 		iov = aiov;
 1.6       eeh 		needfree = NULL;
 1.6       eeh 	} else
 1.6       eeh 		return (EINVAL);
 1.1       mrg
 1.6       eeh 	auio.uio_iov = iov;
 1.6       eeh 	auio.uio_iovcnt = iovcnt;
 1.6       eeh 	auio.uio_rw = UIO_READ;
 1.6       eeh 	auio.uio_segflg = UIO_USERSPACE;
 1.6       eeh 	auio.uio_procp = p;
1.10       mrg 	error = netbsd32_to_iovecin(iovp, iov, iovcnt);
 1.6       eeh 	if (error)
 1.6       eeh 		goto done;
 1.6       eeh 	auio.uio_resid = 0;
 1.6       eeh 	for (i = 0; i < iovcnt; i++) {
 1.6       eeh 		auio.uio_resid += iov->iov_len;
 1.6       eeh 		/*
 1.6       eeh 		 * Reads return ssize_t because -1 is returned on error.
 1.6       eeh 		 * Therefore we must restrict the length to SSIZE_MAX to
 1.6       eeh 		 * avoid garbage return values.
 1.6       eeh 		 */
 1.6       eeh 		if (iov->iov_len > SSIZE_MAX || auio.uio_resid > SSIZE_MAX) {
 1.6       eeh 			error = EINVAL;
 1.6       eeh 			goto done;
 1.6       eeh 		}
 1.6       eeh 		iov++;
 1.6       eeh 	}
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	/*
 1.6       eeh 	 * if tracing, save a copy of iovec
 1.6       eeh 	 */
 1.6       eeh 	if (KTRPOINT(p, KTR_GENIO))  {
 1.6       eeh 		MALLOC(ktriov, struct iovec *, iovlen, M_TEMP, M_WAITOK);
 1.6       eeh 		memcpy((caddr_t)ktriov, (caddr_t)auio.uio_iov, iovlen);
 1.6       eeh 	}
 1.6       eeh #endif
 1.6       eeh 	cnt = auio.uio_resid;
 1.6       eeh 	error = (*fp->f_ops->fo_read)(fp, offset, &auio, fp->f_cred, flags);
 1.6       eeh 	if (error)
 1.6       eeh 		if (auio.uio_resid != cnt && (error == ERESTART ||
 1.6       eeh 		    error == EINTR || error == EWOULDBLOCK))
 1.6       eeh 			error = 0;
 1.6       eeh 	cnt -= auio.uio_resid;
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	if (KTRPOINT(p, KTR_GENIO))
 1.6       eeh 		if (error == 0) {
 1.6       eeh 			ktrgenio(p->p_tracep, fd, UIO_READ, ktriov, cnt,
 1.6       eeh 			    error);
 1.6       eeh 		FREE(ktriov, M_TEMP);
 1.6       eeh 	}
 1.6       eeh #endif
 1.6       eeh 	*retval = cnt;
 1.6       eeh done:
 1.6       eeh 	if (needfree)
 1.6       eeh 		FREE(needfree, M_IOV);
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32_writev(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_writev_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(const netbsd32_iovecp_t) iovp;
 1.1       mrg 		syscallarg(int) iovcnt;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int fd = SCARG(uap, fd);
 1.6       eeh 	register struct file *fp;
 1.6       eeh 	register struct filedesc *fdp = p->p_fd;
 1.6       eeh
 1.6       eeh 	if ((u_int)fd >= fdp->fd_nfiles ||
 1.6       eeh 	    (fp = fdp->fd_ofiles[fd]) == NULL ||
 1.6       eeh 	    (fp->f_flag & FWRITE) == 0)
 1.6       eeh 		return (EBADF);
 1.6       eeh
1.10       mrg 	return (dofilewritev32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp),
 1.6       eeh 			       SCARG(uap, iovcnt), &fp->f_offset, FOF_UPDATE_OFFSET, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
 1.6       eeh dofilewritev32(p, fd, fp, iovp, iovcnt, offset, flags, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	int fd;
 1.6       eeh 	struct file *fp;
1.10       mrg 	struct netbsd32_iovec *iovp;
 1.6       eeh 	int iovcnt;
 1.6       eeh 	off_t *offset;
 1.6       eeh 	int flags;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
 1.6       eeh 	struct uio auio;
 1.6       eeh 	register struct iovec *iov;
 1.6       eeh 	struct iovec *needfree;
 1.6       eeh 	struct iovec aiov[UIO_SMALLIOV];
 1.6       eeh 	long i, cnt, error = 0;
 1.6       eeh 	u_int iovlen;
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	struct iovec *ktriov = NULL;
 1.6       eeh #endif
 1.1       mrg
 1.6       eeh 	/* note: can't use iovlen until iovcnt is validated */
 1.6       eeh 	iovlen = iovcnt * sizeof(struct iovec);
 1.6       eeh 	if ((u_int)iovcnt > UIO_SMALLIOV) {
 1.6       eeh 		if ((u_int)iovcnt > IOV_MAX)
 1.6       eeh 			return (EINVAL);
 1.6       eeh 		MALLOC(iov, struct iovec *, iovlen, M_IOV, M_WAITOK);
 1.6       eeh 		needfree = iov;
 1.6       eeh 	} else if ((u_int)iovcnt > 0) {
 1.6       eeh 		iov = aiov;
 1.6       eeh 		needfree = NULL;
 1.6       eeh 	} else
 1.6       eeh 		return (EINVAL);
 1.1       mrg
 1.6       eeh 	auio.uio_iov = iov;
 1.6       eeh 	auio.uio_iovcnt = iovcnt;
 1.6       eeh 	auio.uio_rw = UIO_WRITE;
 1.6       eeh 	auio.uio_segflg = UIO_USERSPACE;
 1.6       eeh 	auio.uio_procp = p;
1.10       mrg 	error = netbsd32_to_iovecin(iovp, iov, iovcnt);
 1.6       eeh 	if (error)
 1.6       eeh 		goto done;
 1.6       eeh 	auio.uio_resid = 0;
 1.6       eeh 	for (i = 0; i < iovcnt; i++) {
 1.6       eeh 		auio.uio_resid += iov->iov_len;
 1.6       eeh 		/*
 1.6       eeh 		 * Writes return ssize_t because -1 is returned on error.
 1.6       eeh 		 * Therefore we must restrict the length to SSIZE_MAX to
 1.6       eeh 		 * avoid garbage return values.
 1.6       eeh 		 */
 1.6       eeh 		if (iov->iov_len > SSIZE_MAX || auio.uio_resid > SSIZE_MAX) {
 1.6       eeh 			error = EINVAL;
 1.6       eeh 			goto done;
 1.6       eeh 		}
 1.6       eeh 		iov++;
 1.6       eeh 	}
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	/*
 1.6       eeh 	 * if tracing, save a copy of iovec
 1.6       eeh 	 */
 1.6       eeh 	if (KTRPOINT(p, KTR_GENIO))  {
 1.6       eeh 		MALLOC(ktriov, struct iovec *, iovlen, M_TEMP, M_WAITOK);
 1.6       eeh 		memcpy((caddr_t)ktriov, (caddr_t)auio.uio_iov, iovlen);
 1.6       eeh 	}
 1.6       eeh #endif
 1.6       eeh 	cnt = auio.uio_resid;
 1.6       eeh 	error = (*fp->f_ops->fo_write)(fp, offset, &auio, fp->f_cred, flags);
 1.6       eeh 	if (error) {
 1.6       eeh 		if (auio.uio_resid != cnt && (error == ERESTART ||
 1.6       eeh 		    error == EINTR || error == EWOULDBLOCK))
 1.6       eeh 			error = 0;
 1.6       eeh 		if (error == EPIPE)
 1.6       eeh 			psignal(p, SIGPIPE);
 1.6       eeh 	}
 1.6       eeh 	cnt -= auio.uio_resid;
 1.6       eeh #ifdef KTRACE
 1.6       eeh 	if (KTRPOINT(p, KTR_GENIO))
 1.6       eeh 		if (error == 0) {
 1.6       eeh 			ktrgenio(p->p_tracep, fd, UIO_WRITE, ktriov, cnt,
 1.6       eeh 			    error);
 1.6       eeh 		FREE(ktriov, M_TEMP);
 1.6       eeh 	}
 1.6       eeh #endif
 1.6       eeh 	*retval = cnt;
 1.6       eeh done:
 1.6       eeh 	if (needfree)
 1.6       eeh 		FREE(needfree, M_IOV);
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32_rename(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_rename_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) from;
1.10       mrg 		syscallarg(const netbsd32_charp) to;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_rename_args ua;
 1.1       mrg
1.20       eeh 	NETBSD32TOP_UAP(from, const char);
1.20       eeh 	NETBSD32TOP_UAP(to, const char)
 1.6       eeh
 1.1       mrg 	return (sys_rename(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_flock(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_flock_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 		syscallarg(int) how;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_flock_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(how)
 1.6       eeh
 1.6       eeh 	return (sys_flock(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_mkfifo(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mkfifo_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(mode_t) mode;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mkfifo_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char)
1.11       mrg 	NETBSD32TO64_UAP(mode);
 1.1       mrg 	return (sys_mkfifo(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_shutdown(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_shutdown_args /* {
 1.6       eeh 		syscallarg(int) s;
 1.6       eeh 		syscallarg(int) how;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_shutdown_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(s)
1.11       mrg 	NETBSD32TO64_UAP(how);
 1.6       eeh 	return (sys_shutdown(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_socketpair(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_socketpair_args /* {
 1.6       eeh 		syscallarg(int) domain;
 1.6       eeh 		syscallarg(int) type;
 1.6       eeh 		syscallarg(int) protocol;
1.10       mrg 		syscallarg(netbsd32_intp) rsv;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_socketpair_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(domain);
1.11       mrg 	NETBSD32TO64_UAP(type);
1.11       mrg 	NETBSD32TO64_UAP(protocol);
1.11       mrg 	NETBSD32TOP_UAP(rsv, int);
 1.6       eeh 	/* Since we're just copying out two `int's we can do this */
 1.6       eeh 	return (sys_socketpair(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_mkdir(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mkdir_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(mode_t) mode;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mkdir_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char)
1.11       mrg 	NETBSD32TO64_UAP(mode);
 1.1       mrg 	return (sys_mkdir(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_rmdir(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_rmdir_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_rmdir_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
 1.1       mrg 	return (sys_rmdir(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_utimes(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_utimes_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(const netbsd32_timevalp_t) tptr;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int error;
 1.6       eeh 	struct nameidata nd;
 1.6       eeh
 1.6       eeh 	NDINIT(&nd, LOOKUP, FOLLOW, UIO_USERSPACE, (char *)(u_long)SCARG(uap, path), p);
 1.6       eeh 	if ((error = namei(&nd)) != 0)
 1.6       eeh 		return (error);
 1.1       mrg
 1.6       eeh 	error = change_utimes32(nd.ni_vp, (struct timeval *)(u_long)SCARG(uap, tptr), p);
 1.1       mrg
 1.6       eeh 	vrele(nd.ni_vp);
 1.6       eeh 	return (error);
 1.6       eeh }
 1.6       eeh
 1.6       eeh /*
 1.6       eeh  * Common routine to set access and modification times given a vnode.
 1.6       eeh  */
 1.6       eeh static int
 1.6       eeh change_utimes32(vp, tptr, p)
 1.6       eeh 	struct vnode *vp;
 1.6       eeh 	struct timeval *tptr;
 1.6       eeh 	struct proc *p;
 1.6       eeh {
1.10       mrg 	struct netbsd32_timeval tv32[2];
 1.6       eeh 	struct timeval tv[2];
 1.6       eeh 	struct vattr vattr;
 1.6       eeh 	int error;
 1.6       eeh
 1.6       eeh 	VATTR_NULL(&vattr);
 1.6       eeh 	if (tptr == NULL) {
 1.6       eeh 		microtime(&tv[0]);
 1.6       eeh 		tv[1] = tv[0];
 1.6       eeh 		vattr.va_vaflags |= VA_UTIMES_NULL;
 1.6       eeh 	} else {
 1.6       eeh 		error = copyin(tptr, tv, sizeof(tv));
 1.6       eeh 		if (error)
 1.6       eeh 			return (error);
 1.6       eeh 	}
1.10       mrg 	netbsd32_to_timeval(&tv32[0], &tv[0]);
1.10       mrg 	netbsd32_to_timeval(&tv32[1], &tv[1]);
 1.6       eeh 	VOP_LEASE(vp, p, p->p_ucred, LEASE_WRITE);
 1.6       eeh 	vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
 1.6       eeh 	vattr.va_atime.tv_sec = tv[0].tv_sec;
 1.6       eeh 	vattr.va_atime.tv_nsec = tv[0].tv_usec * 1000;
 1.6       eeh 	vattr.va_mtime.tv_sec = tv[1].tv_sec;
 1.6       eeh 	vattr.va_mtime.tv_nsec = tv[1].tv_usec * 1000;
 1.6       eeh 	error = VOP_SETATTR(vp, &vattr, p->p_ucred, p);
 1.6       eeh 	VOP_UNLOCK(vp, 0);
 1.6       eeh 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_adjtime(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_adjtime_args /* {
1.10       mrg 		syscallarg(const netbsd32_timevalp_t) delta;
1.10       mrg 		syscallarg(netbsd32_timevalp_t) olddelta;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_timeval atv;
 1.6       eeh 	int32_t ndelta, ntickdelta, odelta;
 1.6       eeh 	int s, error;
 1.6       eeh 	extern long bigadj, timedelta;
 1.6       eeh 	extern int tickdelta;
 1.1       mrg
 1.6       eeh 	if ((error = suser(p->p_ucred, &p->p_acflag)) != 0)
 1.6       eeh 		return (error);
 1.1       mrg
 1.6       eeh 	error = copyin((caddr_t)(u_long)SCARG(uap, delta), &atv, sizeof(struct timeval));
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
 1.6       eeh 	/*
 1.6       eeh 	 * Compute the total correction and the rate at which to apply it.
 1.6       eeh 	 * Round the adjustment down to a whole multiple of the per-tick
 1.6       eeh 	 * delta, so that after some number of incremental changes in
 1.6       eeh 	 * hardclock(), tickdelta will become zero, lest the correction
 1.6       eeh 	 * overshoot and start taking us away from the desired final time.
 1.6       eeh 	 */
 1.6       eeh 	ndelta = atv.tv_sec * 1000000 + atv.tv_usec;
 1.6       eeh 	if (ndelta > bigadj)
 1.6       eeh 		ntickdelta = 10 * tickadj;
 1.6       eeh 	else
 1.6       eeh 		ntickdelta = tickadj;
 1.6       eeh 	if (ndelta % ntickdelta)
 1.6       eeh 		ndelta = ndelta / ntickdelta * ntickdelta;
 1.1       mrg
 1.6       eeh 	/*
 1.6       eeh 	 * To make hardclock()'s job easier, make the per-tick delta negative
 1.6       eeh 	 * if we want time to run slower; then hardclock can simply compute
 1.6       eeh 	 * tick + tickdelta, and subtract tickdelta from timedelta.
 1.6       eeh 	 */
 1.6       eeh 	if (ndelta < 0)
 1.6       eeh 		ntickdelta = -ntickdelta;
 1.6       eeh 	s = splclock();
 1.6       eeh 	odelta = timedelta;
 1.6       eeh 	timedelta = ndelta;
 1.6       eeh 	tickdelta = ntickdelta;
 1.6       eeh 	splx(s);
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, olddelta)) {
 1.6       eeh 		atv.tv_sec = odelta / 1000000;
 1.6       eeh 		atv.tv_usec = odelta % 1000000;
 1.6       eeh 		(void) copyout(&atv, (caddr_t)(u_long)SCARG(uap, olddelta),
 1.6       eeh 		    sizeof(struct timeval));
 1.6       eeh 	}
 1.1       mrg 	return (0);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_quotactl(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_quotactl_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(int) cmd;
 1.1       mrg 		syscallarg(int) uid;
1.10       mrg 		syscallarg(netbsd32_caddr_t) arg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_quotactl_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(cmd);
1.11       mrg 	NETBSD32TO64_UAP(uid);
1.11       mrg 	NETBSD32TOX64_UAP(arg, caddr_t);
 1.1       mrg 	return (sys_quotactl(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.6       eeh #if defined(NFS) || defined(NFSSERVER)
 1.1       mrg int
1.19       eeh netbsd32_nfssvc(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_nfssvc_args /* {
 1.1       mrg 		syscallarg(int) flag;
1.10       mrg 		syscallarg(netbsd32_voidp) argp;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_nfssvc_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(flag);
1.11       mrg 	NETBSD32TOP_UAP(argp, void);
 1.1       mrg 	return (sys_nfssvc(p, &ua, retval));
 1.6       eeh #else
 1.6       eeh 	/* Why would we want to support a 32-bit nfsd? */
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.6       eeh #endif
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_statfs(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_statfs_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(netbsd32_statfsp_t) buf;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	register struct mount *mp;
 1.6       eeh 	register struct statfs *sp;
1.10       mrg 	struct netbsd32_statfs s32;
 1.1       mrg 	int error;
 1.6       eeh 	struct nameidata nd;
 1.1       mrg
 1.6       eeh 	NDINIT(&nd, LOOKUP, FOLLOW, UIO_USERSPACE, (char *)(u_long)SCARG(uap, path), p);
 1.6       eeh 	if ((error = namei(&nd)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh 	mp = nd.ni_vp->v_mount;
 1.6       eeh 	sp = &mp->mnt_stat;
 1.6       eeh 	vrele(nd.ni_vp);
 1.6       eeh 	if ((error = VFS_STATFS(mp, sp, p)) != 0)
 1.1       mrg 		return (error);
 1.6       eeh 	sp->f_flags = mp->mnt_flag & MNT_VISFLAGMASK;
1.10       mrg 	netbsd32_from_statfs(sp, &s32);
 1.6       eeh 	return (copyout(&s32, (caddr_t)(u_long)SCARG(uap, buf), sizeof(s32)));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_fstatfs(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_fstatfs_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(netbsd32_statfsp_t) buf;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct file *fp;
 1.6       eeh 	register struct mount *mp;
 1.6       eeh 	register struct statfs *sp;
1.10       mrg 	struct netbsd32_statfs s32;
 1.1       mrg 	int error;
 1.1       mrg
1.12   thorpej 	/* getvnode() will use the descriptor for us */
 1.6       eeh 	if ((error = getvnode(p->p_fd, SCARG(uap, fd), &fp)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh 	mp = ((struct vnode *)fp->f_data)->v_mount;
 1.6       eeh 	sp = &mp->mnt_stat;
 1.6       eeh 	if ((error = VFS_STATFS(mp, sp, p)) != 0)
1.12   thorpej 		goto out;
 1.6       eeh 	sp->f_flags = mp->mnt_flag & MNT_VISFLAGMASK;
1.10       mrg 	netbsd32_from_statfs(sp, &s32);
1.12   thorpej 	error = copyout(&s32, (caddr_t)(u_long)SCARG(uap, buf), sizeof(s32));
1.12   thorpej  out:
1.19       eeh 	FILE_UNUSE(fp, p);
1.12   thorpej 	return (error);
 1.1       mrg }
 1.1       mrg
 1.6       eeh #if defined(NFS) || defined(NFSSERVER)
 1.1       mrg int
1.19       eeh netbsd32_getfh(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getfh_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) fname;
1.10       mrg 		syscallarg(netbsd32_fhandlep_t) fhp;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_getfh_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(fname, const char);
1.11       mrg 	NETBSD32TOP_UAP(fhp, struct fhandle);
 1.6       eeh 	/* Lucky for us a fhandlep_t doesn't change sizes */
 1.1       mrg 	return (sys_getfh(p, &ua, retval));
 1.1       mrg }
 1.6       eeh #endif
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_sysarch(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_sysarch_args /* {
 1.1       mrg 		syscallarg(int) op;
1.10       mrg 		syscallarg(netbsd32_voidp) parms;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg
 1.6       eeh 	switch (SCARG(uap, op)) {
 1.6       eeh 	default:
1.19       eeh 		printf("(sparc64) netbsd32_sysarch(%d)\n", SCARG(uap, op));
 1.6       eeh 		return EINVAL;
 1.6       eeh 	}
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_pread(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_pread_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(netbsd32_voidp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) nbyte;
 1.1       mrg 		syscallarg(int) pad;
 1.1       mrg 		syscallarg(off_t) offset;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_pread_args ua;
 1.1       mrg 	ssize_t rt;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TOP_UAP(buf, void);
1.11       mrg 	NETBSD32TOX_UAP(nbyte, size_t);
1.11       mrg 	NETBSD32TO64_UAP(pad);
1.11       mrg 	NETBSD32TO64_UAP(offset);
 1.1       mrg 	error = sys_pread(p, &ua, (register_t *)&rt);
1.10       mrg 	*(netbsd32_ssize_t *)retval = rt;
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_pwrite(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_pwrite_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(const netbsd32_voidp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) nbyte;
 1.1       mrg 		syscallarg(int) pad;
 1.1       mrg 		syscallarg(off_t) offset;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_pwrite_args ua;
 1.1       mrg 	ssize_t rt;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TOP_UAP(buf, void);
1.11       mrg 	NETBSD32TOX_UAP(nbyte, size_t);
1.11       mrg 	NETBSD32TO64_UAP(pad);
1.11       mrg 	NETBSD32TO64_UAP(offset);
 1.1       mrg 	error = sys_pwrite(p, &ua, (register_t *)&rt);
1.10       mrg 	*(netbsd32_ssize_t *)retval = rt;
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.6       eeh #ifdef NTP
 1.1       mrg int
1.19       eeh netbsd32_ntp_gettime(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_ntp_gettime_args /* {
1.10       mrg 		syscallarg(netbsd32_ntptimevalp_t) ntvp;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_ntptimeval ntv32;
 1.6       eeh 	struct timeval atv;
 1.1       mrg 	struct ntptimeval ntv;
 1.6       eeh 	int error = 0;
 1.6       eeh 	int s;
 1.1       mrg
 1.6       eeh 	/* The following are NTP variables */
 1.6       eeh 	extern long time_maxerror;
 1.6       eeh 	extern long time_esterror;
 1.6       eeh 	extern int time_status;
 1.6       eeh 	extern int time_state;	/* clock state */
 1.6       eeh 	extern int time_status;	/* clock status bits */
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, ntvp)) {
 1.6       eeh 		s = splclock();
 1.6       eeh #ifdef EXT_CLOCK
 1.6       eeh 		/*
 1.6       eeh 		 * The microtime() external clock routine returns a
 1.6       eeh 		 * status code. If less than zero, we declare an error
 1.6       eeh 		 * in the clock status word and return the kernel
 1.6       eeh 		 * (software) time variable. While there are other
 1.6       eeh 		 * places that call microtime(), this is the only place
 1.6       eeh 		 * that matters from an application point of view.
 1.6       eeh 		 */
 1.6       eeh 		if (microtime(&atv) < 0) {
 1.6       eeh 			time_status |= STA_CLOCKERR;
 1.6       eeh 			ntv.time = time;
 1.6       eeh 		} else
 1.6       eeh 			time_status &= ~STA_CLOCKERR;
 1.6       eeh #else /* EXT_CLOCK */
 1.6       eeh 		microtime(&atv);
 1.6       eeh #endif /* EXT_CLOCK */
 1.6       eeh 		ntv.time = atv;
 1.6       eeh 		ntv.maxerror = time_maxerror;
 1.6       eeh 		ntv.esterror = time_esterror;
 1.6       eeh 		(void) splx(s);
 1.1       mrg
1.10       mrg 		netbsd32_from_timeval(&ntv.time, &ntv32.time);
1.10       mrg 		ntv32.maxerror = (netbsd32_long)ntv.maxerror;
1.10       mrg 		ntv32.esterror = (netbsd32_long)ntv.esterror;
 1.6       eeh 		error = copyout((caddr_t)&ntv32, (caddr_t)(u_long)SCARG(uap, ntvp),
 1.6       eeh 		    sizeof(ntv32));
 1.6       eeh 	}
 1.6       eeh 	if (!error) {
 1.6       eeh
 1.6       eeh 		/*
 1.6       eeh 		 * Status word error decode. If any of these conditions
 1.6       eeh 		 * occur, an error is returned, instead of the status
 1.6       eeh 		 * word. Most applications will care only about the fact
 1.6       eeh 		 * the system clock may not be trusted, not about the
 1.6       eeh 		 * details.
 1.6       eeh 		 *
 1.6       eeh 		 * Hardware or software error
 1.6       eeh 		 */
 1.6       eeh 		if ((time_status & (STA_UNSYNC | STA_CLOCKERR)) ||
 1.6       eeh
 1.6       eeh 		/*
 1.6       eeh 		 * PPS signal lost when either time or frequency
 1.6       eeh 		 * synchronization requested
 1.6       eeh 		 */
 1.6       eeh 		    (time_status & (STA_PPSFREQ | STA_PPSTIME) &&
 1.6       eeh 		    !(time_status & STA_PPSSIGNAL)) ||
 1.6       eeh
 1.6       eeh 		/*
 1.6       eeh 		 * PPS jitter exceeded when time synchronization
 1.6       eeh 		 * requested
 1.6       eeh 		 */
 1.6       eeh 		    (time_status & STA_PPSTIME &&
 1.6       eeh 		    time_status & STA_PPSJITTER) ||
 1.6       eeh
 1.6       eeh 		/*
 1.6       eeh 		 * PPS wander exceeded or calibration error when
 1.6       eeh 		 * frequency synchronization requested
 1.6       eeh 		 */
 1.6       eeh 		    (time_status & STA_PPSFREQ &&
 1.6       eeh 		    time_status & (STA_PPSWANDER | STA_PPSERROR)))
 1.6       eeh 			*retval = TIME_ERROR;
 1.6       eeh 		else
 1.6       eeh 			*retval = (register_t)time_state;
 1.1       mrg 	}
 1.6       eeh 	return(error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_ntp_adjtime(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_ntp_adjtime_args /* {
1.10       mrg 		syscallarg(netbsd32_timexp_t) tp;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_timex ntv32;
 1.6       eeh 	struct timex ntv;
 1.6       eeh 	int error = 0;
 1.6       eeh 	int modes;
 1.6       eeh 	int s;
 1.6       eeh 	extern long time_freq;		/* frequency offset (scaled ppm) */
 1.6       eeh 	extern long time_maxerror;
 1.6       eeh 	extern long time_esterror;
 1.6       eeh 	extern int time_state;	/* clock state */
 1.6       eeh 	extern int time_status;	/* clock status bits */
 1.6       eeh 	extern long time_constant;		/* pll time constant */
 1.6       eeh 	extern long time_offset;		/* time offset (us) */
 1.6       eeh 	extern long time_tolerance;	/* frequency tolerance (scaled ppm) */
 1.6       eeh 	extern long time_precision;	/* clock precision (us) */
 1.6       eeh
 1.6       eeh 	if ((error = copyin((caddr_t)(u_long)SCARG(uap, tp), (caddr_t)&ntv32,
 1.6       eeh 			sizeof(ntv32))))
 1.6       eeh 		return (error);
1.10       mrg 	netbsd32_to_timex(&ntv32, &ntv);
 1.1       mrg
 1.6       eeh 	/*
 1.6       eeh 	 * Update selected clock variables - only the superuser can
 1.6       eeh 	 * change anything. Note that there is no error checking here on
 1.6       eeh 	 * the assumption the superuser should know what it is doing.
 1.6       eeh 	 */
 1.6       eeh 	modes = ntv.modes;
 1.6       eeh 	if (modes != 0 && (error = suser(p->p_ucred, &p->p_acflag)))
 1.1       mrg 		return (error);
 1.1       mrg
 1.6       eeh 	s = splclock();
 1.6       eeh 	if (modes & MOD_FREQUENCY)
 1.6       eeh #ifdef PPS_SYNC
 1.6       eeh 		time_freq = ntv.freq - pps_freq;
 1.6       eeh #else /* PPS_SYNC */
 1.6       eeh 		time_freq = ntv.freq;
 1.6       eeh #endif /* PPS_SYNC */
 1.6       eeh 	if (modes & MOD_MAXERROR)
 1.6       eeh 		time_maxerror = ntv.maxerror;
 1.6       eeh 	if (modes & MOD_ESTERROR)
 1.6       eeh 		time_esterror = ntv.esterror;
 1.6       eeh 	if (modes & MOD_STATUS) {
 1.6       eeh 		time_status &= STA_RONLY;
 1.6       eeh 		time_status |= ntv.status & ~STA_RONLY;
 1.6       eeh 	}
 1.6       eeh 	if (modes & MOD_TIMECONST)
 1.6       eeh 		time_constant = ntv.constant;
 1.6       eeh 	if (modes & MOD_OFFSET)
 1.6       eeh 		hardupdate(ntv.offset);
 1.6       eeh
 1.6       eeh 	/*
 1.6       eeh 	 * Retrieve all clock variables
 1.6       eeh 	 */
 1.6       eeh 	if (time_offset < 0)
 1.6       eeh 		ntv.offset = -(-time_offset >> SHIFT_UPDATE);
 1.6       eeh 	else
 1.6       eeh 		ntv.offset = time_offset >> SHIFT_UPDATE;
 1.6       eeh #ifdef PPS_SYNC
 1.6       eeh 	ntv.freq = time_freq + pps_freq;
 1.6       eeh #else /* PPS_SYNC */
 1.6       eeh 	ntv.freq = time_freq;
 1.6       eeh #endif /* PPS_SYNC */
 1.6       eeh 	ntv.maxerror = time_maxerror;
 1.6       eeh 	ntv.esterror = time_esterror;
 1.6       eeh 	ntv.status = time_status;
 1.6       eeh 	ntv.constant = time_constant;
 1.6       eeh 	ntv.precision = time_precision;
 1.6       eeh 	ntv.tolerance = time_tolerance;
 1.6       eeh #ifdef PPS_SYNC
 1.6       eeh 	ntv.shift = pps_shift;
 1.6       eeh 	ntv.ppsfreq = pps_freq;
 1.6       eeh 	ntv.jitter = pps_jitter >> PPS_AVG;
 1.6       eeh 	ntv.stabil = pps_stabil;
 1.6       eeh 	ntv.calcnt = pps_calcnt;
 1.6       eeh 	ntv.errcnt = pps_errcnt;
 1.6       eeh 	ntv.jitcnt = pps_jitcnt;
 1.6       eeh 	ntv.stbcnt = pps_stbcnt;
 1.6       eeh #endif /* PPS_SYNC */
 1.6       eeh 	(void)splx(s);
 1.6       eeh
1.10       mrg 	netbsd32_from_timeval(&ntv, &ntv32);
 1.6       eeh 	error = copyout((caddr_t)&ntv32, (caddr_t)SCARG(uap, tp), sizeof(ntv32));
 1.6       eeh 	if (!error) {
 1.6       eeh
 1.6       eeh 		/*
 1.6       eeh 		 * Status word error decode. See comments in
 1.6       eeh 		 * ntp_gettime() routine.
 1.6       eeh 		 */
 1.6       eeh 		if ((time_status & (STA_UNSYNC | STA_CLOCKERR)) ||
 1.6       eeh 		    (time_status & (STA_PPSFREQ | STA_PPSTIME) &&
 1.6       eeh 		    !(time_status & STA_PPSSIGNAL)) ||
 1.6       eeh 		    (time_status & STA_PPSTIME &&
 1.6       eeh 		    time_status & STA_PPSJITTER) ||
 1.6       eeh 		    (time_status & STA_PPSFREQ &&
 1.6       eeh 		    time_status & (STA_PPSWANDER | STA_PPSERROR)))
 1.6       eeh 			*retval = TIME_ERROR;
 1.6       eeh 		else
 1.6       eeh 			*retval = (register_t)time_state;
 1.6       eeh 	}
 1.6       eeh 	return error;
 1.6       eeh }
 1.6       eeh #endif
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_setgid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_setgid_args /* {
 1.6       eeh 		syscallarg(gid_t) gid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_setgid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(gid);
 1.6       eeh 	return (sys_setgid(p, v, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_setegid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_setegid_args /* {
 1.6       eeh 		syscallarg(gid_t) egid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_setegid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(egid);
 1.6       eeh 	return (sys_setegid(p, v, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_seteuid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_seteuid_args /* {
 1.6       eeh 		syscallarg(gid_t) euid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_seteuid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(euid);
 1.6       eeh 	return (sys_seteuid(p, v, retval));
 1.1       mrg }
 1.1       mrg
 1.6       eeh #ifdef LFS
 1.1       mrg int
1.20       eeh netbsd32_sys_lfs_bmapv(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_lfs_bmapv_args /* {
1.10       mrg 		syscallarg(netbsd32_fsid_tp_t) fsidp;
1.10       mrg 		syscallarg(netbsd32_block_infop_t) blkiov;
 1.1       mrg 		syscallarg(int) blkcnt;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_lfs_bmapv_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(fdidp, struct fsid);
1.11       mrg 	NETBSD32TO64_UAP(blkcnt);
 1.1       mrg 	/* XXX finish me */
 1.1       mrg #else
 1.1       mrg
 1.1       mrg 	return (ENOSYS);	/* XXX */
 1.1       mrg #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.20       eeh netbsd32_sys_lfs_markv(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.20       eeh #if 0
1.19       eeh 	struct netbsd32_lfs_markv_args /* {
1.10       mrg 		syscallarg(netbsd32_fsid_tp_t) fsidp;
1.10       mrg 		syscallarg(netbsd32_block_infop_t) blkiov;
 1.1       mrg 		syscallarg(int) blkcnt;
 1.1       mrg 	} */ *uap = v;
1.20       eeh #endif
 1.1       mrg
 1.1       mrg 	return (ENOSYS);	/* XXX */
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.20       eeh netbsd32_sys_lfs_segclean(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.20       eeh #if 0
1.19       eeh 	struct netbsd32_lfs_segclean_args /* {
1.10       mrg 		syscallarg(netbsd32_fsid_tp_t) fsidp;
1.10       mrg 		syscallarg(netbsd32_u_long) segment;
 1.1       mrg 	} */ *uap = v;
1.20       eeh #endif
1.20       eeh
 1.1       mrg 	return (ENOSYS);	/* XXX */
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.20       eeh netbsd32_sys_lfs_segwait(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.20       eeh #if 0
1.19       eeh 	struct netbsd32_lfs_segwait_args /* {
1.10       mrg 		syscallarg(netbsd32_fsid_tp_t) fsidp;
1.10       mrg 		syscallarg(netbsd32_timevalp_t) tv;
 1.1       mrg 	} */ *uap = v;
1.20       eeh #endif
1.20       eeh
 1.1       mrg 	return (ENOSYS);	/* XXX */
 1.1       mrg }
 1.6       eeh #endif
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_pathconf(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_pathconf_args /* {
 1.1       mrg 		syscallarg(int) fd;
 1.1       mrg 		syscallarg(int) name;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_pathconf_args ua;
 1.1       mrg 	long rt;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(name);
 1.1       mrg 	error = sys_pathconf(p, &ua, (register_t *)&rt);
1.10       mrg 	*(netbsd32_long *)retval = (netbsd32_long)rt;
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_fpathconf(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_fpathconf_args /* {
 1.1       mrg 		syscallarg(int) fd;
 1.1       mrg 		syscallarg(int) name;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_fpathconf_args ua;
 1.1       mrg 	long rt;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(name);
 1.1       mrg 	error = sys_fpathconf(p, &ua, (register_t *)&rt);
1.10       mrg 	*(netbsd32_long *)retval = (netbsd32_long)rt;
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getrlimit(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getrlimit_args /* {
 1.1       mrg 		syscallarg(int) which;
1.10       mrg 		syscallarg(netbsd32_rlimitp_t) rlp;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int which = SCARG(uap, which);
 1.1       mrg
 1.6       eeh 	if ((u_int)which >= RLIM_NLIMITS)
 1.6       eeh 		return (EINVAL);
 1.6       eeh 	return (copyout(&p->p_rlimit[which], (caddr_t)(u_long)SCARG(uap, rlp),
 1.6       eeh 	    sizeof(struct rlimit)));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_setrlimit(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_setrlimit_args /* {
 1.1       mrg 		syscallarg(int) which;
1.10       mrg 		syscallarg(const netbsd32_rlimitp_t) rlp;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 		int which = SCARG(uap, which);
 1.6       eeh 	struct rlimit alim;
 1.6       eeh 	int error;
 1.1       mrg
 1.6       eeh 	error = copyin((caddr_t)(u_long)SCARG(uap, rlp), &alim, sizeof(struct rlimit));
 1.6       eeh 	if (error)
 1.6       eeh 		return (error);
1.18    bouyer 	return (dosetrlimit(p, p->p_cred, which, &alim));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_mmap(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mmap_args /* {
1.10       mrg 		syscallarg(netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 		syscallarg(int) prot;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(netbsd32_long) pad;
 1.1       mrg 		syscallarg(off_t) pos;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mmap_args ua;
 1.1       mrg 	void *rt;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, void);
1.11       mrg 	NETBSD32TOX_UAP(len, size_t);
1.11       mrg 	NETBSD32TO64_UAP(prot);
1.11       mrg 	NETBSD32TO64_UAP(flags);
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TOX_UAP(pad, long);
1.11       mrg 	NETBSD32TOX_UAP(pos, off_t);
 1.1       mrg 	error = sys_mmap(p, &ua, (register_t *)&rt);
 1.1       mrg 	if ((long)rt > (long)UINT_MAX)
1.19       eeh 		printf("netbsd32_mmap: retval out of range: 0x%qx",
 1.1       mrg 		    rt);
1.10       mrg 	*retval = (netbsd32_voidp)(u_long)rt;
 1.1       mrg 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_lseek(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_lseek_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 		syscallarg(int) pad;
 1.6       eeh 		syscallarg(off_t) offset;
 1.6       eeh 		syscallarg(int) whence;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_lseek_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(pad);
1.11       mrg 	NETBSD32TO64_UAP(offset);
1.11       mrg 	NETBSD32TO64_UAP(whence);
 1.6       eeh 	return (sys_lseek(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_truncate(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_truncate_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(int) pad;
 1.1       mrg 		syscallarg(off_t) length;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_truncate_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(pad);
1.11       mrg 	NETBSD32TO64_UAP(length);
 1.1       mrg 	return (sys_truncate(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_ftruncate(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_ftruncate_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 		syscallarg(int) pad;
 1.6       eeh 		syscallarg(off_t) length;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_ftruncate_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(pad);
1.11       mrg 	NETBSD32TO64_UAP(length);
 1.6       eeh 	return (sys_ftruncate(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32___sysctl(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___sysctl_args /* {
1.10       mrg 		syscallarg(netbsd32_intp) name;
 1.1       mrg 		syscallarg(u_int) namelen;
1.10       mrg 		syscallarg(netbsd32_voidp) old;
1.10       mrg 		syscallarg(netbsd32_size_tp) oldlenp;
1.10       mrg 		syscallarg(netbsd32_voidp) new;
1.10       mrg 		syscallarg(netbsd32_size_t) newlen;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int error, dolock = 1;
1.10       mrg 	netbsd32_size_t savelen = 0;
 1.6       eeh 	size_t oldlen = 0;
 1.6       eeh 	sysctlfn *fn;
 1.6       eeh 	int name[CTL_MAXNAME];
 1.6       eeh
 1.6       eeh /*
 1.6       eeh  * Some of these sysctl functions do their own copyin/copyout.
 1.6       eeh  * We need to disable or emulate the ones that need their
 1.6       eeh  * arguments converted.
 1.6       eeh  */
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, new) != NULL &&
 1.6       eeh 	    (error = suser(p->p_ucred, &p->p_acflag)))
 1.6       eeh 		return (error);
 1.6       eeh 	/*
 1.6       eeh 	 * all top-level sysctl names are non-terminal
 1.6       eeh 	 */
 1.6       eeh 	if (SCARG(uap, namelen) > CTL_MAXNAME || SCARG(uap, namelen) < 2)
 1.6       eeh 		return (EINVAL);
 1.6       eeh 	error = copyin((caddr_t)(u_long)SCARG(uap, name), &name,
 1.6       eeh 		       SCARG(uap, namelen) * sizeof(int));
 1.6       eeh 	if (error)
 1.6       eeh 		return (error);
 1.6       eeh
 1.6       eeh 	switch (name[0]) {
 1.6       eeh 	case CTL_KERN:
 1.6       eeh 		fn = kern_sysctl;
 1.6       eeh 		if (name[2] != KERN_VNODE)	/* XXX */
 1.6       eeh 			dolock = 0;
 1.6       eeh 		break;
 1.6       eeh 	case CTL_HW:
 1.6       eeh 		fn = hw_sysctl;
 1.6       eeh 		break;
 1.6       eeh 	case CTL_VM:
 1.6       eeh 		fn = uvm_sysctl;
 1.6       eeh 		break;
 1.6       eeh 	case CTL_NET:
 1.6       eeh 		fn = net_sysctl;
 1.6       eeh 		break;
 1.6       eeh 	case CTL_VFS:
 1.6       eeh 		fn = vfs_sysctl;
 1.6       eeh 		break;
 1.6       eeh 	case CTL_MACHDEP:
 1.6       eeh 		fn = cpu_sysctl;
 1.6       eeh 		break;
 1.6       eeh #ifdef DEBUG
 1.6       eeh 	case CTL_DEBUG:
 1.6       eeh 		fn = debug_sysctl;
 1.6       eeh 		break;
 1.6       eeh #endif
 1.6       eeh #ifdef DDB
 1.6       eeh 	case CTL_DDB:
 1.6       eeh 		fn = ddb_sysctl;
 1.6       eeh 		break;
 1.6       eeh #endif
 1.6       eeh 	default:
 1.6       eeh 		return (EOPNOTSUPP);
 1.6       eeh 	}
 1.1       mrg
 1.6       eeh 	if (SCARG(uap, oldlenp) &&
 1.6       eeh 	    (error = copyin((caddr_t)(u_long)SCARG(uap, oldlenp), &savelen, sizeof(savelen))))
 1.6       eeh 		return (error);
 1.6       eeh 	if (SCARG(uap, old) != NULL) {
 1.6       eeh 		if (!uvm_useracc((caddr_t)(u_long)SCARG(uap, old), savelen, B_WRITE))
 1.6       eeh 			return (EFAULT);
 1.6       eeh #if 0 /* XXXXXXXX */
 1.6       eeh 		while (memlock.sl_lock) {
 1.6       eeh 			memlock.sl_want = 1;
 1.6       eeh 			sleep((caddr_t)&memlock, PRIBIO+1);
 1.6       eeh 			memlock.sl_locked++;
 1.6       eeh 		}
 1.6       eeh 		memlock.sl_lock = 1;
 1.6       eeh #endif /* XXXXXXXX */
1.13   thorpej 		if (dolock) {
1.13   thorpej 			/*
1.13   thorpej 			 * XXX Um, this is kind of evil.  What should
1.13   thorpej 			 * XXX we be passing here?
1.13   thorpej 			 */
1.20       eeh 			if (uvm_vslock(p, (void *)(u_long)SCARG(uap, old), savelen,
1.15   thorpej 			    VM_PROT_NONE) != KERN_SUCCESS) {
1.15   thorpej #if 0 /* XXXXXXXX */
1.15   thorpej 				memlock.sl_lock = 0;
1.15   thorpej 				if (memlock.sl_want) {
1.15   thorpej 					memlock.sl_want = 0;
1.15   thorpej 					wakeup((caddr_t)&memlock);
1.15   thorpej 				}
1.15   thorpej #endif /* XXXXXXXX */
1.15   thorpej 				return (EFAULT);
1.15   thorpej 			}
1.13   thorpej 		}
 1.6       eeh 		oldlen = savelen;
 1.6       eeh 	}
1.20       eeh 	error = (*fn)(name + 1, SCARG(uap, namelen) - 1,
1.20       eeh 		      (void *)(u_long)SCARG(uap, old), &oldlen,
1.20       eeh 		      (void *)(u_long)SCARG(uap, new), SCARG(uap, newlen), p);
 1.6       eeh 	if (SCARG(uap, old) != NULL) {
 1.6       eeh 		if (dolock)
1.20       eeh 			uvm_vsunlock(p, (void *)(u_long)SCARG(uap, old), savelen);
 1.6       eeh #if 0 /* XXXXXXXXXXX */
 1.6       eeh 		memlock.sl_lock = 0;
 1.6       eeh 		if (memlock.sl_want) {
 1.6       eeh 			memlock.sl_want = 0;
 1.6       eeh 			wakeup((caddr_t)&memlock);
 1.6       eeh 		}
 1.6       eeh #endif /* XXXXXXXXX */
 1.6       eeh 	}
 1.6       eeh 	savelen = oldlen;
 1.6       eeh 	if (error)
 1.6       eeh 		return (error);
 1.6       eeh 	if (SCARG(uap, oldlenp))
 1.6       eeh 		error = copyout(&savelen, (caddr_t)(u_long)SCARG(uap, oldlenp), sizeof(savelen));
 1.6       eeh 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_mlock(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_mlock_args /* {
1.10       mrg 		syscallarg(const netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_mlock_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, const void);
1.11       mrg 	NETBSD32TO64_UAP(len);
 1.1       mrg 	return (sys_mlock(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_munlock(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_munlock_args /* {
1.10       mrg 		syscallarg(const netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_munlock_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, const void);
1.11       mrg 	NETBSD32TO64_UAP(len);
 1.1       mrg 	return (sys_munlock(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_undelete(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_undelete_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_undelete_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
 1.1       mrg 	return (sys_undelete(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_futimes(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_futimes_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(const netbsd32_timevalp_t) tptr;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int error;
 1.6       eeh 	struct file *fp;
 1.6       eeh
1.12   thorpej 	/* getvnode() will use the descriptor for us */
 1.6       eeh 	if ((error = getvnode(p->p_fd, SCARG(uap, fd), &fp)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh
1.12   thorpej 	error = change_utimes32((struct vnode *)fp->f_data,
1.12   thorpej 				(struct timeval *)(u_long)SCARG(uap, tptr), p);
1.19       eeh 	FILE_UNUSE(fp, p);
1.12   thorpej 	return (error);
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_getpgid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_getpgid_args /* {
 1.6       eeh 		syscallarg(pid_t) pid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_getpgid_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(pid);
 1.6       eeh 	return (sys_getpgid(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_reboot(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_reboot_args /* {
 1.1       mrg 		syscallarg(int) opt;
1.10       mrg 		syscallarg(netbsd32_charp) bootstr;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_reboot_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(opt);
1.11       mrg 	NETBSD32TOP_UAP(bootstr, char);
 1.1       mrg 	return (sys_reboot(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_poll(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_poll_args /* {
1.10       mrg 		syscallarg(netbsd32_pollfdp_t) fds;
 1.1       mrg 		syscallarg(u_int) nfds;
 1.1       mrg 		syscallarg(int) timeout;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_poll_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(fds, struct pollfd);
1.11       mrg 	NETBSD32TO64_UAP(nfds);
1.11       mrg 	NETBSD32TO64_UAP(timeout);
 1.1       mrg 	return (sys_poll(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
1.20       eeh #if defined(SYSVSEM)
 1.6       eeh /*
 1.6       eeh  * XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
 1.6       eeh  *
 1.6       eeh  * This is BSD.  We won't support System V IPC.
 1.6       eeh  * Too much work.
 1.6       eeh  *
 1.6       eeh  * XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
 1.6       eeh  */
 1.1       mrg int
1.22  christos netbsd32___semctl14(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32___semctl_args /* {
 1.1       mrg 		syscallarg(int) semid;
 1.1       mrg 		syscallarg(int) semnum;
 1.1       mrg 		syscallarg(int) cmd;
1.22  christos 		syscallarg(netbsd32_semunu_t *) arg;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	union netbsd32_semun sem32;
 1.6       eeh 	int semid = SCARG(uap, semid);
 1.6       eeh 	int semnum = SCARG(uap, semnum);
 1.6       eeh 	int cmd = SCARG(uap, cmd);
1.10       mrg 	union netbsd32_semun *arg = (void*)(u_long)SCARG(uap, arg);
1.10       mrg 	union netbsd32_semun real_arg;
 1.6       eeh 	struct ucred *cred = p->p_ucred;
 1.6       eeh 	int i, rval, eval;
1.10       mrg 	struct netbsd32_semid_ds sbuf;
 1.6       eeh 	register struct semid_ds *semaptr;
 1.6       eeh
 1.6       eeh 	semlock(p);
 1.6       eeh
 1.6       eeh 	semid = IPCID_TO_IX(semid);
 1.6       eeh 	if (semid < 0 || semid >= seminfo.semmsl)
 1.6       eeh 		return(EINVAL);
 1.6       eeh
 1.6       eeh 	semaptr = &sema[semid];
 1.6       eeh 	if ((semaptr->sem_perm.mode & SEM_ALLOC) == 0 ||
 1.6       eeh 	    semaptr->sem_perm.seq != IPCID_TO_SEQ(SCARG(uap, semid)))
 1.6       eeh 		return(EINVAL);
 1.6       eeh
 1.6       eeh 	eval = 0;
 1.6       eeh 	rval = 0;
 1.6       eeh
 1.6       eeh 	switch (cmd) {
 1.6       eeh 	case IPC_RMID:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_M)) != 0)
 1.6       eeh 			return(eval);
 1.6       eeh 		semaptr->sem_perm.cuid = cred->cr_uid;
 1.6       eeh 		semaptr->sem_perm.uid = cred->cr_uid;
 1.6       eeh 		semtot -= semaptr->sem_nsems;
1.19       eeh 		for (i = semaptr->_sem_base - sem; i < semtot; i++)
 1.6       eeh 			sem[i] = sem[i + semaptr->sem_nsems];
 1.6       eeh 		for (i = 0; i < seminfo.semmni; i++) {
 1.6       eeh 			if ((sema[i].sem_perm.mode & SEM_ALLOC) &&
1.19       eeh 			    sema[i]._sem_base > semaptr->_sem_base)
1.19       eeh 				sema[i]._sem_base -= semaptr->sem_nsems;
 1.6       eeh 		}
 1.6       eeh 		semaptr->sem_perm.mode = 0;
 1.6       eeh 		semundo_clear(semid, -1);
 1.6       eeh 		wakeup((caddr_t)semaptr);
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case IPC_SET:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_M)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0)
 1.6       eeh 			return(eval);
 1.6       eeh 		if ((eval = copyin((caddr_t)(u_long)real_arg.buf, (caddr_t)&sbuf,
 1.6       eeh 		    sizeof(sbuf))) != 0)
 1.6       eeh 			return(eval);
 1.6       eeh 		semaptr->sem_perm.uid = sbuf.sem_perm.uid;
 1.6       eeh 		semaptr->sem_perm.gid = sbuf.sem_perm.gid;
 1.6       eeh 		semaptr->sem_perm.mode = (semaptr->sem_perm.mode & ~0777) |
 1.6       eeh 		    (sbuf.sem_perm.mode & 0777);
 1.6       eeh 		semaptr->sem_ctime = time.tv_sec;
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case IPC_STAT:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0)
 1.6       eeh 			return(eval);
 1.6       eeh 		eval = copyout((caddr_t)semaptr, (caddr_t)(u_long)real_arg.buf,
 1.6       eeh 		    sizeof(struct semid_ds));
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case GETNCNT:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if (semnum < 0 || semnum >= semaptr->sem_nsems)
 1.6       eeh 			return(EINVAL);
1.19       eeh 		rval = semaptr->_sem_base[semnum].semncnt;
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case GETPID:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if (semnum < 0 || semnum >= semaptr->sem_nsems)
 1.6       eeh 			return(EINVAL);
1.19       eeh 		rval = semaptr->_sem_base[semnum].sempid;
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case GETVAL:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if (semnum < 0 || semnum >= semaptr->sem_nsems)
 1.6       eeh 			return(EINVAL);
1.19       eeh 		rval = semaptr->_sem_base[semnum].semval;
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case GETALL:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0)
 1.6       eeh 			return(eval);
 1.6       eeh 		for (i = 0; i < semaptr->sem_nsems; i++) {
1.19       eeh 			eval = copyout((caddr_t)&semaptr->_sem_base[i].semval,
 1.6       eeh 			    &real_arg.array[i], sizeof(real_arg.array[0]));
 1.6       eeh 			if (eval != 0)
 1.6       eeh 				break;
 1.6       eeh 		}
 1.6       eeh 		break;
 1.1       mrg
 1.6       eeh 	case GETZCNT:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if (semnum < 0 || semnum >= semaptr->sem_nsems)
 1.6       eeh 			return(EINVAL);
1.19       eeh 		rval = semaptr->_sem_base[semnum].semzcnt;
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case SETVAL:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_W)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if (semnum < 0 || semnum >= semaptr->sem_nsems)
 1.6       eeh 			return(EINVAL);
 1.6       eeh 		if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0)
 1.6       eeh 			return(eval);
1.19       eeh 		semaptr->_sem_base[semnum].semval = real_arg.val;
 1.6       eeh 		semundo_clear(semid, semnum);
 1.6       eeh 		wakeup((caddr_t)semaptr);
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case SETALL:
 1.6       eeh 		if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_W)))
 1.6       eeh 			return(eval);
 1.6       eeh 		if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0)
 1.6       eeh 			return(eval);
 1.6       eeh 		for (i = 0; i < semaptr->sem_nsems; i++) {
 1.6       eeh 			eval = copyin(&real_arg.array[i],
1.19       eeh 			    (caddr_t)&semaptr->_sem_base[i].semval,
 1.6       eeh 			    sizeof(real_arg.array[0]));
 1.6       eeh 			if (eval != 0)
 1.6       eeh 				break;
 1.1       mrg 		}
 1.6       eeh 		semundo_clear(semid, -1);
 1.6       eeh 		wakeup((caddr_t)semaptr);
 1.6       eeh 		break;
 1.1       mrg
 1.6       eeh 	default:
 1.6       eeh 		return(EINVAL);
 1.6       eeh 	}
 1.1       mrg
 1.6       eeh 	if (eval == 0)
 1.6       eeh 		*retval = rval;
 1.6       eeh 	return(eval);
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_semget(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_semget_args /* {
1.10       mrg 		syscallarg(netbsd32_key_t) key;
 1.1       mrg 		syscallarg(int) nsems;
 1.1       mrg 		syscallarg(int) semflg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_semget_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOX_UAP(key, key_t);
1.11       mrg 	NETBSD32TO64_UAP(nsems);
1.11       mrg 	NETBSD32TO64_UAP(semflg);
 1.1       mrg 	return (sys_semget(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_semop(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_semop_args /* {
 1.1       mrg 		syscallarg(int) semid;
1.10       mrg 		syscallarg(netbsd32_sembufp_t) sops;
1.10       mrg 		syscallarg(netbsd32_size_t) nsops;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_semop_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(semid);
1.11       mrg 	NETBSD32TOP_UAP(sops, struct sembuf);
1.11       mrg 	NETBSD32TOX_UAP(nsops, size_t);
 1.2       mrg 	return (sys_semop(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_semconfig(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_semconfig_args /* {
 1.6       eeh 		syscallarg(int) flag;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_semconfig_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(flag);
 1.6       eeh 	return (sys_semconfig(p, &ua, retval));
 1.6       eeh }
1.20       eeh #endif /* SYSVSEM */
1.20       eeh
1.20       eeh #if defined(SYSVMSG)
 1.6       eeh
 1.6       eeh int
1.20       eeh netbsd32___msgctl13(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_msgctl_args /* {
 1.1       mrg 		syscallarg(int) msqid;
 1.1       mrg 		syscallarg(int) cmd;
1.10       mrg 		syscallarg(netbsd32_msqid_dsp_t) buf;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_msgctl_args ua;
 1.1       mrg 	struct msqid_ds ds;
1.10       mrg 	struct netbsd32_msqid_ds *ds32p;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(msqid);
1.11       mrg 	NETBSD32TO64_UAP(cmd);
1.10       mrg 	ds32p = (struct netbsd32_msqid_ds *)(u_long)SCARG(uap, buf);
 1.1       mrg 	if (ds32p) {
 1.1       mrg 		SCARG(&ua, buf) = NULL;
1.10       mrg 		netbsd32_to_msqid_ds(ds32p, &ds);
 1.1       mrg 	} else
 1.1       mrg 		SCARG(&ua, buf) = NULL;
 1.1       mrg 	error = sys_msgctl(p, &ua, retval);
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
 1.1       mrg
 1.1       mrg 	if (ds32p)
1.10       mrg 		netbsd32_from_msqid_ds(&ds, ds32p);
 1.1       mrg 	return (0);
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_msgget(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_msgget_args /* {
1.10       mrg 		syscallarg(netbsd32_key_t) key;
 1.1       mrg 		syscallarg(int) msgflg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_msgget_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOX_UAP(key, key_t);
1.11       mrg 	NETBSD32TO64_UAP(msgflg);
 1.1       mrg 	return (sys_msgget(p, &ua, retval));
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_msgsnd(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_msgsnd_args /* {
 1.1       mrg 		syscallarg(int) msqid;
1.10       mrg 		syscallarg(const netbsd32_voidp) msgp;
1.10       mrg 		syscallarg(netbsd32_size_t) msgsz;
 1.1       mrg 		syscallarg(int) msgflg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_msgsnd_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(msqid);
1.11       mrg 	NETBSD32TOP_UAP(msgp, void);
1.11       mrg 	NETBSD32TOX_UAP(msgsz, size_t);
1.11       mrg 	NETBSD32TO64_UAP(msgflg);
 1.1       mrg 	return (sys_msgsnd(p, &ua, retval));
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_msgrcv(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_msgrcv_args /* {
 1.1       mrg 		syscallarg(int) msqid;
1.10       mrg 		syscallarg(netbsd32_voidp) msgp;
1.10       mrg 		syscallarg(netbsd32_size_t) msgsz;
1.10       mrg 		syscallarg(netbsd32_long) msgtyp;
 1.1       mrg 		syscallarg(int) msgflg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_msgrcv_args ua;
 1.1       mrg 	ssize_t rt;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(msqid);
1.11       mrg 	NETBSD32TOP_UAP(msgp, void);
1.11       mrg 	NETBSD32TOX_UAP(msgsz, size_t);
1.11       mrg 	NETBSD32TOX_UAP(msgtyp, long);
1.11       mrg 	NETBSD32TO64_UAP(msgflg);
 1.1       mrg 	error = sys_msgrcv(p, &ua, (register_t *)&rt);
1.10       mrg 	*(netbsd32_ssize_t *)retval = rt;
 1.1       mrg 	return (error);
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
1.20       eeh #endif /* SYSVMSG */
1.20       eeh
1.20       eeh #if defined(SYSVSHM)
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_shmat(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_shmat_args /* {
 1.1       mrg 		syscallarg(int) shmid;
1.10       mrg 		syscallarg(const netbsd32_voidp) shmaddr;
 1.1       mrg 		syscallarg(int) shmflg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_shmat_args ua;
 1.1       mrg 	void *rt;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(shmid);
1.11       mrg 	NETBSD32TOP_UAP(shmaddr, void);
1.11       mrg 	NETBSD32TO64_UAP(shmflg);
 1.1       mrg 	error = sys_shmat(p, &ua, (register_t *)&rt);
1.10       mrg 	*retval = (netbsd32_voidp)(u_long)rt;
 1.1       mrg 	return (error);
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.20       eeh netbsd32___shmctl13(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_shmctl_args /* {
 1.1       mrg 		syscallarg(int) shmid;
 1.1       mrg 		syscallarg(int) cmd;
1.10       mrg 		syscallarg(netbsd32_shmid_dsp_t) buf;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_shmctl_args ua;
 1.1       mrg 	struct shmid_ds ds;
1.10       mrg 	struct netbsd32_shmid_ds *ds32p;
 1.1       mrg 	int error;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(shmid);
1.11       mrg 	NETBSD32TO64_UAP(cmd);
1.10       mrg 	ds32p = (struct netbsd32_shmid_ds *)(u_long)SCARG(uap, buf);
 1.1       mrg 	if (ds32p) {
 1.1       mrg 		SCARG(&ua, buf) = NULL;
1.10       mrg 		netbsd32_to_shmid_ds(ds32p, &ds);
 1.1       mrg 	} else
 1.1       mrg 		SCARG(&ua, buf) = NULL;
 1.1       mrg 	error = sys_shmctl(p, &ua, retval);
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
 1.1       mrg
 1.1       mrg 	if (ds32p)
1.10       mrg 		netbsd32_from_shmid_ds(&ds, ds32p);
 1.1       mrg 	return (0);
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_shmdt(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_shmdt_args /* {
1.10       mrg 		syscallarg(const netbsd32_voidp) shmaddr;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_shmdt_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(shmaddr, const char);
 1.1       mrg 	return (sys_shmdt(p, &ua, retval));
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_shmget(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
 1.6       eeh #if 0
1.19       eeh 	struct netbsd32_shmget_args /* {
1.10       mrg 		syscallarg(netbsd32_key_t) key;
1.10       mrg 		syscallarg(netbsd32_size_t) size;
 1.1       mrg 		syscallarg(int) shmflg;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_shmget_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOX_UAP(key, key_t)
1.11       mrg 	NETBSD32TOX_UAP(size, size_t)
1.11       mrg 	NETBSD32TO64_UAP(shmflg);
 1.1       mrg 	return (sys_shmget(p, &ua, retval));
 1.6       eeh #else
 1.6       eeh 	return (ENOSYS);
 1.6       eeh #endif
 1.1       mrg }
1.20       eeh #endif /* SYSVSHM */
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_clock_gettime(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_clock_gettime_args /* {
1.10       mrg 		syscallarg(netbsd32_clockid_t) clock_id;
1.10       mrg 		syscallarg(netbsd32_timespecp_t) tp;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	clockid_t clock_id;
 1.6       eeh 	struct timeval atv;
 1.6       eeh 	struct timespec ats;
1.10       mrg 	struct netbsd32_timespec ts32;
 1.6       eeh
 1.6       eeh 	clock_id = SCARG(uap, clock_id);
 1.6       eeh 	if (clock_id != CLOCK_REALTIME)
 1.6       eeh 		return (EINVAL);
 1.1       mrg
 1.6       eeh 	microtime(&atv);
 1.6       eeh 	TIMEVAL_TO_TIMESPEC(&atv,&ats);
1.10       mrg 	netbsd32_from_timespec(&ats, &ts32);
 1.1       mrg
 1.6       eeh 	return copyout(&ts32, (caddr_t)(u_long)SCARG(uap, tp), sizeof(ts32));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_clock_settime(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_clock_settime_args /* {
1.10       mrg 		syscallarg(netbsd32_clockid_t) clock_id;
1.10       mrg 		syscallarg(const netbsd32_timespecp_t) tp;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_timespec ts32;
 1.6       eeh 	clockid_t clock_id;
 1.6       eeh 	struct timeval atv;
 1.6       eeh 	struct timespec ats;
 1.6       eeh 	int error;
 1.6       eeh
 1.6       eeh 	if ((error = suser(p->p_ucred, &p->p_acflag)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh
 1.6       eeh 	clock_id = SCARG(uap, clock_id);
 1.6       eeh 	if (clock_id != CLOCK_REALTIME)
 1.6       eeh 		return (EINVAL);
 1.6       eeh
 1.6       eeh 	if ((error = copyin((caddr_t)(u_long)SCARG(uap, tp), &ts32, sizeof(ts32))) != 0)
 1.6       eeh 		return (error);
 1.6       eeh
1.10       mrg 	netbsd32_to_timespec(&ts32, &ats);
 1.6       eeh 	TIMESPEC_TO_TIMEVAL(&atv,&ats);
 1.6       eeh 	if ((error = settime(&atv)))
 1.6       eeh 		return (error);
 1.1       mrg
 1.6       eeh 	return 0;
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_clock_getres(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_clock_getres_args /* {
1.10       mrg 		syscallarg(netbsd32_clockid_t) clock_id;
1.10       mrg 		syscallarg(netbsd32_timespecp_t) tp;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_timespec ts32;
 1.6       eeh 	clockid_t clock_id;
 1.1       mrg 	struct timespec ts;
 1.6       eeh 	int error = 0;
 1.6       eeh
 1.6       eeh 	clock_id = SCARG(uap, clock_id);
 1.6       eeh 	if (clock_id != CLOCK_REALTIME)
 1.6       eeh 		return (EINVAL);
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, tp)) {
 1.6       eeh 		ts.tv_sec = 0;
 1.6       eeh 		ts.tv_nsec = 1000000000 / hz;
 1.1       mrg
1.10       mrg 		netbsd32_from_timespec(&ts, &ts32);
 1.6       eeh 		error = copyout(&ts, (caddr_t)(u_long)SCARG(uap, tp), sizeof(ts));
 1.6       eeh 	}
 1.1       mrg
 1.6       eeh 	return error;
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_nanosleep(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_nanosleep_args /* {
1.10       mrg 		syscallarg(const netbsd32_timespecp_t) rqtp;
1.10       mrg 		syscallarg(netbsd32_timespecp_t) rmtp;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	static int nanowait;
1.10       mrg 	struct netbsd32_timespec ts32;
 1.6       eeh 	struct timespec rqt;
 1.6       eeh 	struct timespec rmt;
 1.6       eeh 	struct timeval atv, utv;
 1.6       eeh 	int error, s, timo;
 1.6       eeh
 1.6       eeh 	error = copyin((caddr_t)(u_long)SCARG(uap, rqtp), (caddr_t)&ts32,
 1.6       eeh 		       sizeof(ts32));
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
 1.1       mrg
1.10       mrg 	netbsd32_to_timespec(&ts32, &rqt);
 1.6       eeh 	TIMESPEC_TO_TIMEVAL(&atv,&rqt)
 1.6       eeh 	if (itimerfix(&atv))
 1.6       eeh 		return (EINVAL);
 1.6       eeh
 1.6       eeh 	s = splclock();
 1.6       eeh 	timeradd(&atv,&time,&atv);
 1.6       eeh 	timo = hzto(&atv);
 1.6       eeh 	/*
 1.6       eeh 	 * Avoid inadvertantly sleeping forever
 1.6       eeh 	 */
 1.6       eeh 	if (timo == 0)
 1.6       eeh 		timo = 1;
 1.6       eeh 	splx(s);
 1.6       eeh
 1.6       eeh 	error = tsleep(&nanowait, PWAIT | PCATCH, "nanosleep", timo);
 1.6       eeh 	if (error == ERESTART)
 1.6       eeh 		error = EINTR;
 1.6       eeh 	if (error == EWOULDBLOCK)
 1.6       eeh 		error = 0;
 1.6       eeh
 1.6       eeh 	if (SCARG(uap, rmtp)) {
 1.6       eeh 		int error;
 1.6       eeh
 1.6       eeh 		s = splclock();
 1.6       eeh 		utv = time;
 1.6       eeh 		splx(s);
 1.6       eeh
 1.6       eeh 		timersub(&atv, &utv, &utv);
 1.6       eeh 		if (utv.tv_sec < 0)
 1.6       eeh 			timerclear(&utv);
 1.6       eeh
 1.6       eeh 		TIMEVAL_TO_TIMESPEC(&utv,&rmt);
1.10       mrg 		netbsd32_from_timespec(&rmt, &ts32);
 1.6       eeh 		error = copyout((caddr_t)&ts32, (caddr_t)(u_long)SCARG(uap,rmtp),
 1.6       eeh 			sizeof(ts32));
 1.6       eeh 		if (error)
 1.6       eeh 			return (error);
 1.6       eeh 	}
 1.6       eeh
 1.6       eeh 	return error;
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_fdatasync(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_fdatasync_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_fdatasync_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
 1.6       eeh
 1.6       eeh 	return (sys_fdatasync(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___posix_rename(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___posix_rename_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) from;
1.10       mrg 		syscallarg(const netbsd32_charp) to;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys___posix_rename_args ua;
 1.1       mrg
1.20       eeh 	NETBSD32TOP_UAP(from, const char);
1.20       eeh 	NETBSD32TOP_UAP(to, const char);
 1.6       eeh
 1.1       mrg 	return (sys___posix_rename(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_swapctl(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_swapctl_args /* {
 1.1       mrg 		syscallarg(int) cmd;
1.10       mrg 		syscallarg(const netbsd32_voidp) arg;
 1.1       mrg 		syscallarg(int) misc;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_swapctl_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TO64_UAP(cmd);
1.11       mrg 	NETBSD32TOP_UAP(arg, const void);
1.11       mrg 	NETBSD32TO64_UAP(misc);
 1.1       mrg 	return (sys_swapctl(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getdents(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_getdents_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(netbsd32_charp) buf;
1.10       mrg 		syscallarg(netbsd32_size_t) count;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct file *fp;
 1.6       eeh 	int error, done;
 1.1       mrg
1.12   thorpej 	/* getvnode() will use the descriptor for us */
 1.6       eeh 	if ((error = getvnode(p->p_fd, SCARG(uap, fd), &fp)) != 0)
 1.6       eeh 		return (error);
1.12   thorpej 	if ((fp->f_flag & FREAD) == 0) {
1.12   thorpej 		error = EBADF;
1.12   thorpej 		goto out;
1.12   thorpej 	}
 1.6       eeh 	error = vn_readdir(fp, (caddr_t)(u_long)SCARG(uap, buf), UIO_USERSPACE,
 1.6       eeh 			SCARG(uap, count), &done, p, 0, 0);
 1.6       eeh 	*retval = done;
1.12   thorpej  out:
1.19       eeh 	FILE_UNUSE(fp, p);
 1.6       eeh 	return (error);
 1.1       mrg }
 1.1       mrg
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32_minherit(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_minherit_args /* {
1.10       mrg 		syscallarg(netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 		syscallarg(int) inherit;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_minherit_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, void);
1.11       mrg 	NETBSD32TOX_UAP(len, size_t);
1.11       mrg 	NETBSD32TO64_UAP(inherit);
 1.1       mrg 	return (sys_minherit(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_lchmod(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_lchmod_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(mode_t) mode;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_lchmod_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(mode);
 1.1       mrg 	return (sys_lchmod(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_lchown(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_lchown_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(uid_t) uid;
 1.1       mrg 		syscallarg(gid_t) gid;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys_lchown_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(uid);
1.11       mrg 	NETBSD32TO64_UAP(gid);
 1.1       mrg 	return (sys_lchown(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_lutimes(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_lutimes_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(const netbsd32_timevalp_t) tptr;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int error;
 1.6       eeh 	struct nameidata nd;
 1.1       mrg
 1.6       eeh 	NDINIT(&nd, LOOKUP, NOFOLLOW, UIO_USERSPACE, (caddr_t)(u_long)SCARG(uap, path), p);
 1.6       eeh 	if ((error = namei(&nd)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh
 1.6       eeh 	error = change_utimes32(nd.ni_vp, (struct timeval *)(u_long)SCARG(uap, tptr), p);
 1.6       eeh
 1.6       eeh 	vrele(nd.ni_vp);
 1.6       eeh 	return (error);
 1.1       mrg }
 1.1       mrg
 1.6       eeh
 1.1       mrg int
1.19       eeh netbsd32___msync13(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___msync13_args /* {
1.10       mrg 		syscallarg(netbsd32_voidp) addr;
1.10       mrg 		syscallarg(netbsd32_size_t) len;
 1.1       mrg 		syscallarg(int) flags;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys___msync13_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(addr, void);
1.11       mrg 	NETBSD32TOX_UAP(len, size_t);
1.11       mrg 	NETBSD32TO64_UAP(flags);
 1.1       mrg 	return (sys___msync13(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___stat13(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___stat13_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(netbsd32_statp_t) ub;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_stat sb32;
 1.1       mrg 	struct stat sb;
 1.1       mrg 	int error;
 1.6       eeh 	struct nameidata nd;
 1.1       mrg
 1.6       eeh 	NDINIT(&nd, LOOKUP, FOLLOW | LOCKLEAF, UIO_USERSPACE,
 1.6       eeh 	    (caddr_t)(u_long)SCARG(uap, path), p);
 1.6       eeh 	if ((error = namei(&nd)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh 	error = vn_stat(nd.ni_vp, &sb, p);
 1.6       eeh 	vput(nd.ni_vp);
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
1.10       mrg 	netbsd32_from___stat13(&sb, &sb32);
 1.6       eeh 	error = copyout(&sb32, (caddr_t)(u_long)SCARG(uap, ub), sizeof(sb32));
 1.6       eeh 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___fstat13(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___fstat13_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(netbsd32_statp_t) sb;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	int fd = SCARG(uap, fd);
 1.6       eeh 	register struct filedesc *fdp = p->p_fd;
 1.6       eeh 	register struct file *fp;
1.10       mrg 	struct netbsd32_stat sb32;
 1.6       eeh 	struct stat ub;
 1.6       eeh 	int error = 0;
 1.6       eeh
 1.6       eeh 	if ((u_int)fd >= fdp->fd_nfiles ||
 1.6       eeh 	    (fp = fdp->fd_ofiles[fd]) == NULL)
 1.6       eeh 		return (EBADF);
 1.6       eeh 	switch (fp->f_type) {
 1.6       eeh
 1.6       eeh 	case DTYPE_VNODE:
 1.6       eeh 		error = vn_stat((struct vnode *)fp->f_data, &ub, p);
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	case DTYPE_SOCKET:
 1.6       eeh 		error = soo_stat((struct socket *)fp->f_data, &ub);
 1.6       eeh 		break;
 1.6       eeh
 1.6       eeh 	default:
 1.6       eeh 		panic("fstat");
 1.6       eeh 		/*NOTREACHED*/
 1.6       eeh 	}
 1.6       eeh 	if (error == 0) {
1.10       mrg 		netbsd32_from___stat13(&ub, &sb32);
 1.6       eeh 		error = copyout(&sb32, (caddr_t)(u_long)SCARG(uap, sb), sizeof(sb32));
 1.6       eeh 	}
 1.6       eeh 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___lstat13(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___lstat13_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
1.10       mrg 		syscallarg(netbsd32_statp_t) ub;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_stat sb32;
 1.1       mrg 	struct stat sb;
 1.1       mrg 	int error;
 1.6       eeh 	struct nameidata nd;
 1.1       mrg
 1.6       eeh 	NDINIT(&nd, LOOKUP, NOFOLLOW | LOCKLEAF, UIO_USERSPACE,
 1.6       eeh 	    (caddr_t)(u_long)SCARG(uap, path), p);
 1.6       eeh 	if ((error = namei(&nd)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh 	error = vn_stat(nd.ni_vp, &sb, p);
 1.6       eeh 	vput(nd.ni_vp);
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
1.10       mrg 	netbsd32_from___stat13(&sb, &sb32);
 1.6       eeh 	error = copyout(&sb32, (caddr_t)(u_long)SCARG(uap, ub), sizeof(sb32));
 1.6       eeh 	return (error);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___sigaltstack14(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___sigaltstack14_args /* {
1.10       mrg 		syscallarg(const netbsd32_sigaltstackp_t) nss;
1.10       mrg 		syscallarg(netbsd32_sigaltstackp_t) oss;
 1.1       mrg 	} */ *uap = v;
1.10       mrg 	struct netbsd32_sigaltstack s32;
 1.1       mrg 	struct sigaltstack nss, oss;
 1.1       mrg 	int error;
 1.1       mrg
 1.6       eeh 	if (SCARG(uap, nss)) {
 1.6       eeh 		error = copyin((caddr_t)(u_long)SCARG(uap, nss), &s32, sizeof(s32));
 1.6       eeh 		if (error)
 1.6       eeh 			return (error);
 1.6       eeh 		nss.ss_sp = (void *)(u_long)s32.ss_sp;
 1.6       eeh 		nss.ss_size = (size_t)s32.ss_size;
 1.6       eeh 		nss.ss_flags = s32.ss_flags;
 1.6       eeh 	}
 1.6       eeh 	error = sigaltstack1(p,
 1.6       eeh 	    SCARG(uap, nss) ? &nss : 0, SCARG(uap, oss) ? &oss : 0);
 1.1       mrg 	if (error)
 1.1       mrg 		return (error);
 1.6       eeh 	if (SCARG(uap, oss)) {
1.10       mrg 		s32.ss_sp = (netbsd32_voidp)(u_long)oss.ss_sp;
1.10       mrg 		s32.ss_size = (netbsd32_size_t)oss.ss_size;
 1.6       eeh 		s32.ss_flags = oss.ss_flags;
 1.6       eeh 		error = copyout(&s32, (caddr_t)(u_long)SCARG(uap, oss), sizeof(s32));
 1.6       eeh 		if (error)
 1.6       eeh 			return (error);
 1.1       mrg 	}
 1.1       mrg 	return (0);
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___posix_chown(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___posix_chown_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(uid_t) uid;
 1.1       mrg 		syscallarg(gid_t) gid;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys___posix_chown_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(uid);
1.11       mrg 	NETBSD32TO64_UAP(gid);
 1.1       mrg 	return (sys___posix_chown(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32___posix_fchown(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32___posix_fchown_args /* {
 1.6       eeh 		syscallarg(int) fd;
 1.6       eeh 		syscallarg(uid_t) uid;
 1.6       eeh 		syscallarg(gid_t) gid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys___posix_fchown_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(fd);
1.11       mrg 	NETBSD32TO64_UAP(uid);
1.11       mrg 	NETBSD32TO64_UAP(gid);
 1.6       eeh 	return (sys___posix_fchown(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32___posix_lchown(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32___posix_lchown_args /* {
1.10       mrg 		syscallarg(const netbsd32_charp) path;
 1.1       mrg 		syscallarg(uid_t) uid;
 1.1       mrg 		syscallarg(gid_t) gid;
 1.1       mrg 	} */ *uap = v;
 1.1       mrg 	struct sys___posix_lchown_args ua;
 1.1       mrg
1.11       mrg 	NETBSD32TOP_UAP(path, const char);
1.11       mrg 	NETBSD32TO64_UAP(uid);
1.11       mrg 	NETBSD32TO64_UAP(gid);
 1.1       mrg 	return (sys___posix_lchown(p, &ua, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_getsid(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_getsid_args /* {
 1.6       eeh 		syscallarg(pid_t) pid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_getsid_args ua;
 1.6       eeh
1.11       mrg 	NETBSD32TO64_UAP(pid);
 1.6       eeh 	return (sys_getsid(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_fktrace(p, v, retval)
 1.6       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.19       eeh 	struct netbsd32_fktrace_args /* {
 1.6       eeh 		syscallarg(const int) fd;
 1.6       eeh 		syscallarg(int) ops;
 1.6       eeh 		syscallarg(int) facs;
 1.6       eeh 		syscallarg(int) pid;
 1.6       eeh 	} */ *uap = v;
 1.6       eeh 	struct sys_fktrace_args ua;
 1.6       eeh
1.20       eeh 	NETBSD32TOX_UAP(fd, const int);
1.11       mrg 	NETBSD32TO64_UAP(ops);
1.11       mrg 	NETBSD32TO64_UAP(facs);
1.11       mrg 	NETBSD32TO64_UAP(pid);
 1.6       eeh 	return (sys_fktrace(p, &ua, retval));
 1.6       eeh }
 1.6       eeh
 1.6       eeh int
1.19       eeh netbsd32_preadv(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_preadv_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(const netbsd32_iovecp_t) iovp;
 1.1       mrg 		syscallarg(int) iovcnt;
 1.1       mrg 		syscallarg(int) pad;
 1.1       mrg 		syscallarg(off_t) offset;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct filedesc *fdp = p->p_fd;
 1.6       eeh 	struct file *fp;
 1.6       eeh 	struct vnode *vp;
 1.6       eeh 	off_t offset;
 1.6       eeh 	int error, fd = SCARG(uap, fd);
 1.6       eeh
 1.6       eeh 	if ((u_int)fd >= fdp->fd_nfiles ||
 1.6       eeh 	    (fp = fdp->fd_ofiles[fd]) == NULL ||
 1.6       eeh 	    (fp->f_flag & FREAD) == 0)
 1.6       eeh 		return (EBADF);
 1.6       eeh
 1.6       eeh 	vp = (struct vnode *)fp->f_data;
 1.6       eeh 	if (fp->f_type != DTYPE_VNODE
 1.6       eeh 	    || vp->v_type == VFIFO)
 1.6       eeh 		return (ESPIPE);
 1.6       eeh
 1.6       eeh 	offset = SCARG(uap, offset);
 1.1       mrg
 1.6       eeh 	/*
 1.6       eeh 	 * XXX This works because no file systems actually
 1.6       eeh 	 * XXX take any action on the seek operation.
 1.6       eeh 	 */
 1.6       eeh 	if ((error = VOP_SEEK(vp, fp->f_offset, offset, fp->f_cred)) != 0)
 1.6       eeh 		return (error);
 1.1       mrg
1.10       mrg 	return (dofilereadv32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp), SCARG(uap, iovcnt),
 1.6       eeh 	    &offset, 0, retval));
 1.1       mrg }
 1.1       mrg
 1.1       mrg int
1.19       eeh netbsd32_pwritev(p, v, retval)
 1.1       mrg 	struct proc *p;
 1.1       mrg 	void *v;
 1.1       mrg 	register_t *retval;
 1.1       mrg {
1.19       eeh 	struct netbsd32_pwritev_args /* {
 1.1       mrg 		syscallarg(int) fd;
1.10       mrg 		syscallarg(const netbsd32_iovecp_t) iovp;
 1.1       mrg 		syscallarg(int) iovcnt;
 1.1       mrg 		syscallarg(int) pad;
 1.1       mrg 		syscallarg(off_t) offset;
 1.1       mrg 	} */ *uap = v;
 1.6       eeh 	struct filedesc *fdp = p->p_fd;
 1.6       eeh 	struct file *fp;
 1.6       eeh 	struct vnode *vp;
 1.6       eeh 	off_t offset;
 1.6       eeh 	int error, fd = SCARG(uap, fd);
 1.6       eeh
 1.6       eeh 	if ((u_int)fd >= fdp->fd_nfiles ||
 1.6       eeh 	    (fp = fdp->fd_ofiles[fd]) == NULL ||
 1.6       eeh 	    (fp->f_flag & FWRITE) == 0)
 1.6       eeh 		return (EBADF);
 1.6       eeh
 1.6       eeh 	vp = (struct vnode *)fp->f_data;
 1.6       eeh 	if (fp->f_type != DTYPE_VNODE
 1.6       eeh 	    || vp->v_type == VFIFO)
 1.6       eeh 		return (ESPIPE);
 1.6       eeh
 1.6       eeh 	offset = SCARG(uap, offset);
 1.6       eeh
 1.6       eeh 	/*
 1.6       eeh 	 * XXX This works because no file systems actually
 1.6       eeh 	 * XXX take any action on the seek operation.
 1.6       eeh 	 */
 1.6       eeh 	if ((error = VOP_SEEK(vp, fp->f_offset, offset, fp->f_cred)) != 0)
 1.6       eeh 		return (error);
 1.6       eeh
1.10       mrg 	return (dofilewritev32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp), SCARG(uap, iovcnt),
 1.6       eeh 	    &offset, 0, retval));
 1.6       eeh }
 1.6       eeh
1.20       eeh /* ARGSUSED */
 1.6       eeh int
1.20       eeh netbsd32___sigaction14(p, v, retval)
1.20       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.20       eeh 	register struct netbsd32___sigaction14_args /* {
1.20       eeh 		syscallarg(int) signum;
1.20       eeh 		syscallarg(const struct sigaction *) nsa;
1.20       eeh 		syscallarg(struct sigaction *) osa;
 1.6       eeh 	} */ *uap = v;
1.20       eeh 	struct netbsd32_sigaction sa32;
1.20       eeh 	struct sigaction nsa, osa;
 1.1       mrg 	int error;
 1.1       mrg
1.20       eeh 	if (SCARG(uap, nsa)) {
1.20       eeh 		error = copyin((caddr_t)(u_long)SCARG(uap, nsa),
1.20       eeh 			       &sa32, sizeof(sa32));
1.20       eeh 		if (error)
1.20       eeh 			return (error);
1.20       eeh 		nsa.sa_handler = (void *)(u_long)sa32.sa_handler;
1.20       eeh 		nsa.sa_mask = sa32.sa_mask;
1.20       eeh 		nsa.sa_flags = sa32.sa_flags;
1.20       eeh 	}
1.20       eeh 	error = sigaction1(p, SCARG(uap, signum),
1.20       eeh 	    SCARG(uap, nsa) ? &nsa : 0, SCARG(uap, osa) ? &osa : 0);
 1.6       eeh 	if (error)
 1.6       eeh 		return (error);
1.20       eeh 	if (SCARG(uap, osa)) {
1.20       eeh 		sa32.sa_handler = (netbsd32_voidp)(u_long)osa.sa_handler;
1.20       eeh 		sa32.sa_mask = osa.sa_mask;
1.20       eeh 		sa32.sa_flags = osa.sa_flags;
1.20       eeh 		error = copyout(&sa32, (caddr_t)(u_long)SCARG(uap, osa), sizeof(sa32));
1.20       eeh 		if (error)
1.20       eeh 			return (error);
1.20       eeh 	}
 1.6       eeh 	return (0);
 1.6       eeh }
 1.6       eeh
1.20       eeh int netbsd32___sigpending14(p, v, retval)
1.20       eeh 	struct proc *p;
1.20       eeh 	void   *v;
1.20       eeh 	register_t *retval;
1.20       eeh {
1.20       eeh 	register struct netbsd32___sigpending14_args /* {
1.20       eeh 		syscallarg(sigset_t *) set;
1.20       eeh 	} */ *uap = v;
1.20       eeh 	struct sys___sigpending14_args ua;
1.20       eeh
1.20       eeh 	NETBSD32TOP_UAP(set, sigset_t);
1.20       eeh 	return (sys___sigpending14(p, &ua, retval));
1.20       eeh }
1.20       eeh
1.20       eeh int netbsd32___sigprocmask14(p, v, retval)
1.20       eeh 	struct proc *p;
1.20       eeh 	void   *v;
1.20       eeh 	register_t *retval;
1.20       eeh {
1.20       eeh 	register struct netbsd32___sigprocmask14_args /* {
1.20       eeh 		syscallarg(int) how;
1.20       eeh 		syscallarg(const sigset_t *) set;
1.20       eeh 		syscallarg(sigset_t *) oset;
1.20       eeh 	} */ *uap = v;
1.20       eeh 	struct sys___sigprocmask14_args ua;
1.20       eeh
1.20       eeh 	NETBSD32TO64_UAP(how);
1.20       eeh 	NETBSD32TOP_UAP(set, sigset_t);
1.20       eeh 	NETBSD32TOP_UAP(oset, sigset_t);
1.20       eeh 	return (sys___sigprocmask14(p, &ua, retval));
1.20       eeh }
1.20       eeh
1.20       eeh int netbsd32___sigsuspend14(p, v, retval)
1.20       eeh 	struct proc *p;
1.20       eeh 	void   *v;
1.20       eeh 	register_t *retval;
1.20       eeh {
1.20       eeh 	struct netbsd32___sigsuspend14_args /* {
1.20       eeh 		syscallarg(const sigset_t *) set;
1.20       eeh 	} */ *uap = v;
1.20       eeh 	struct sys___sigsuspend14_args ua;
1.20       eeh
1.20       eeh 	NETBSD32TOP_UAP(set, sigset_t);
1.20       eeh 	return (sys___sigsuspend14(p, &ua, retval));
1.20       eeh };
1.20       eeh
1.20       eeh
1.20       eeh /*
1.20       eeh  * Find pathname of process's current directory.
1.20       eeh  *
1.20       eeh  * Use vfs vnode-to-name reverse cache; if that fails, fall back
1.20       eeh  * to reading directory contents.
1.20       eeh  */
1.20       eeh int
1.20       eeh getcwd_common __P((struct vnode *, struct vnode *,
1.20       eeh 		   char **, char *, int, int, struct proc *));
1.20       eeh
1.20       eeh int netbsd32___getcwd(p, v, retval)
1.20       eeh 	struct proc *p;
1.20       eeh 	void   *v;
1.20       eeh 	register_t *retval;
1.20       eeh {
1.20       eeh 	register struct netbsd32___getcwd_args /* {
1.20       eeh 		syscallarg(char *) bufp;
1.20       eeh 		syscallarg(size_t) length;
1.20       eeh 	} */ *uap = v;
1.20       eeh
1.20       eeh 	int     error;
1.20       eeh 	char   *path;
1.20       eeh 	char   *bp, *bend;
1.20       eeh 	int     len = (int)SCARG(uap, length);
1.20       eeh 	int	lenused;
1.20       eeh
1.20       eeh 	if (len > MAXPATHLEN*4)
1.20       eeh 		len = MAXPATHLEN*4;
1.20       eeh 	else if (len < 2)
1.20       eeh 		return ERANGE;
1.20       eeh
1.20       eeh 	path = (char *)malloc(len, M_TEMP, M_WAITOK);
1.20       eeh 	if (!path)
1.20       eeh 		return ENOMEM;
1.20       eeh
1.20       eeh 	bp = &path[len];
1.20       eeh 	bend = bp;
1.20       eeh 	*(--bp) = '\0';
1.20       eeh
1.20       eeh 	/*
1.20       eeh 	 * 5th argument here is "max number of vnodes to traverse".
1.20       eeh 	 * Since each entry takes up at least 2 bytes in the output buffer,
1.20       eeh 	 * limit it to N/2 vnodes for an N byte buffer.
1.20       eeh 	 */
1.20       eeh #define GETCWD_CHECK_ACCESS 0x0001
1.20       eeh 	error = getcwd_common (p->p_cwdi->cwdi_cdir, NULL, &bp, path, len/2,
1.20       eeh 			       GETCWD_CHECK_ACCESS, p);
1.20       eeh
1.20       eeh 	if (error)
1.20       eeh 		goto out;
1.20       eeh 	lenused = bend - bp;
1.20       eeh 	*retval = lenused;
1.20       eeh 	/* put the result into user buffer */
1.20       eeh 	error = copyout(bp, (caddr_t)(u_long)SCARG(uap, bufp), lenused);
1.20       eeh
1.20       eeh out:
1.20       eeh 	free(path, M_TEMP);
1.20       eeh 	return error;
1.20       eeh }
1.20       eeh
1.20       eeh int netbsd32_fchroot(p, v, retval)
1.20       eeh 	struct proc *p;
1.20       eeh 	void *v;
1.20       eeh 	register_t *retval;
1.20       eeh {
1.20       eeh 	register struct netbsd32_fchroot_args /* {
1.20       eeh 		syscallarg(int) fd;
1.20       eeh 	} */ *uap = v;
1.20       eeh 	struct sys_fchroot_args ua;
1.20       eeh
1.20       eeh 	NETBSD32TO64_UAP(fd);
1.20       eeh 	return (sys_fchroot(p, &ua, retval));
1.20       eeh }
1.20       eeh
1.20       eeh /*
1.20       eeh  * Open a file given a file handle.
1.20       eeh  *
1.20       eeh  * Check permissions, allocate an open file structure,
1.20       eeh  * and call the device open routine if any.
1.20       eeh  */
 1.6       eeh int
1.20       eeh netbsd32_fhopen(p, v, retval)
1.20       eeh 	struct proc *p;
1.20       eeh 	void *v;
1.20       eeh 	register_t *retval;
1.20       eeh {
1.20       eeh 	register struct netbsd32_fhopen_args /* {
1.20       eeh 		syscallarg(const fhandle_t *) fhp;
1.20       eeh 		syscallarg(int) flags;
1.20       eeh 	} */ *uap = v;
1.20       eeh 	struct sys_fhopen_args ua;
1.20       eeh
1.20       eeh 	NETBSD32TOP_UAP(fhp, fhandle_t);
1.20       eeh 	NETBSD32TO64_UAP(flags);
1.20       eeh 	return (sys_fhopen(p, &ua, retval));
1.20       eeh }
1.20       eeh
1.20       eeh int netbsd32_fhstat(p, v, retval)
1.20       eeh 	struct proc *p;
1.20       eeh 	void *v;
1.20       eeh 	register_t *retval;
1.20       eeh {
1.20       eeh 	register struct netbsd32_fhstat_args /* {
1.20       eeh 		syscallarg(const netbsd32_fhandlep_t) fhp;
1.20       eeh 		syscallarg(struct stat *) sb;
1.20       eeh 	} */ *uap = v;
1.20       eeh 	struct sys_fhstat_args ua;
1.20       eeh
1.20       eeh 	NETBSD32TOP_UAP(fhp, const fhandle_t);
1.20       eeh 	NETBSD32TOP_UAP(sb, struct stat);
1.20       eeh 	return (sys_fhstat(p, &ua, retval));
1.20       eeh }
1.20       eeh
1.20       eeh int netbsd32_fhstatfs(p, v, retval)
1.20       eeh 	struct proc *p;
 1.6       eeh 	void *v;
 1.6       eeh 	register_t *retval;
 1.6       eeh {
1.20       eeh 	register struct netbsd32_fhstatfs_args /* {
1.20       eeh 		syscallarg(const netbsd32_fhandlep_t) fhp;
1.20       eeh 		syscallarg(struct statfs *) buf;
 1.6       eeh 	} */ *uap = v;
1.20       eeh 	struct sys_fhstatfs_args ua;
 1.1       mrg
1.20       eeh 	NETBSD32TOP_UAP(fhp, const fhandle_t);
1.20       eeh 	NETBSD32TOP_UAP(buf, struct statfs);
1.20       eeh 	return (sys_fhstatfs(p, &ua, retval));
 1.1       mrg }