netbsd32_netbsd.c revision 1.19.2.2
1 1.19.2.2 bouyer /* $NetBSD: netbsd32_netbsd.c,v 1.19.2.2 2000/12/08 09:08:34 bouyer Exp $ */ 2 1.1 mrg 3 1.1 mrg /* 4 1.1 mrg * Copyright (c) 1998 Matthew R. Green 5 1.1 mrg * All rights reserved. 6 1.1 mrg * 7 1.1 mrg * Redistribution and use in source and binary forms, with or without 8 1.1 mrg * modification, are permitted provided that the following conditions 9 1.1 mrg * are met: 10 1.1 mrg * 1. Redistributions of source code must retain the above copyright 11 1.1 mrg * notice, this list of conditions and the following disclaimer. 12 1.1 mrg * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 mrg * notice, this list of conditions and the following disclaimer in the 14 1.1 mrg * documentation and/or other materials provided with the distribution. 15 1.1 mrg * 3. The name of the author may not be used to endorse or promote products 16 1.1 mrg * derived from this software without specific prior written permission. 17 1.1 mrg * 18 1.1 mrg * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 19 1.1 mrg * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 20 1.1 mrg * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 21 1.1 mrg * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 22 1.1 mrg * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 23 1.1 mrg * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 24 1.1 mrg * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 25 1.1 mrg * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 26 1.1 mrg * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 27 1.1 mrg * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 28 1.1 mrg * SUCH DAMAGE. 29 1.1 mrg */ 30 1.1 mrg 31 1.19.2.2 bouyer #if defined(_KERNEL) && !defined(_LKM) 32 1.19.2.1 bouyer #include "opt_ddb.h" 33 1.4 eeh #include "opt_ktrace.h" 34 1.6 eeh #include "opt_ntp.h" 35 1.19.2.1 bouyer #include "opt_compat_netbsd.h" 36 1.7 drochner #include "opt_compat_43.h" 37 1.19.2.1 bouyer #include "opt_sysv.h" 38 1.7 drochner 39 1.6 eeh #include "fs_lfs.h" 40 1.6 eeh #include "fs_nfs.h" 41 1.19.2.2 bouyer #endif 42 1.19.2.2 bouyer 43 1.19.2.2 bouyer /* 44 1.19.2.2 bouyer * Though COMPAT_OLDSOCK is needed only for COMPAT_43, SunOS, Linux, 45 1.19.2.2 bouyer * HP-UX, FreeBSD, Ultrix, OSF1, we define it unconditionally so that 46 1.19.2.2 bouyer * this would be LKM-safe. 47 1.19.2.2 bouyer */ 48 1.19.2.2 bouyer #define COMPAT_OLDSOCK /* used by <sys/socket.h> */ 49 1.4 eeh 50 1.1 mrg #include <sys/param.h> 51 1.1 mrg #include <sys/systm.h> 52 1.19.2.1 bouyer #include <sys/filedesc.h> 53 1.6 eeh #include <sys/kernel.h> 54 1.1 mrg #include <sys/ipc.h> 55 1.1 mrg #include <sys/msg.h> 56 1.19 eeh #define msg __msg /* Don't ask me! */ 57 1.1 mrg #include <sys/sem.h> 58 1.1 mrg #include <sys/shm.h> 59 1.1 mrg #include <sys/malloc.h> 60 1.1 mrg #include <sys/mount.h> 61 1.1 mrg #include <sys/socket.h> 62 1.1 mrg #include <sys/sockio.h> 63 1.6 eeh #include <sys/socketvar.h> 64 1.6 eeh #include <sys/mbuf.h> 65 1.1 mrg #include <sys/stat.h> 66 1.1 mrg #include <sys/time.h> 67 1.1 mrg #include <sys/timex.h> 68 1.4 eeh #include <sys/signalvar.h> 69 1.6 eeh #include <sys/wait.h> 70 1.6 eeh #include <sys/ptrace.h> 71 1.6 eeh #include <sys/ktrace.h> 72 1.6 eeh #include <sys/trace.h> 73 1.6 eeh #include <sys/resourcevar.h> 74 1.6 eeh #include <sys/pool.h> 75 1.6 eeh #include <sys/vnode.h> 76 1.6 eeh #include <sys/file.h> 77 1.6 eeh #include <sys/filedesc.h> 78 1.6 eeh #include <sys/namei.h> 79 1.1 mrg 80 1.19.2.1 bouyer #include <uvm/uvm_extern.h> 81 1.19.2.1 bouyer 82 1.1 mrg #include <sys/syscallargs.h> 83 1.6 eeh #include <sys/proc.h> 84 1.19.2.1 bouyer #include <sys/acct.h> 85 1.19.2.1 bouyer #include <sys/exec.h> 86 1.19.2.1 bouyer #define __SYSCTL_PRIVATE 87 1.6 eeh #include <sys/sysctl.h> 88 1.1 mrg 89 1.1 mrg #include <net/if.h> 90 1.1 mrg 91 1.10 mrg #include <compat/netbsd32/netbsd32.h> 92 1.19.2.2 bouyer #include <compat/netbsd32/netbsd32_syscall.h> 93 1.10 mrg #include <compat/netbsd32/netbsd32_syscallargs.h> 94 1.1 mrg 95 1.4 eeh #include <machine/frame.h> 96 1.4 eeh 97 1.19.2.1 bouyer #if defined(DDB) 98 1.19.2.1 bouyer #include <ddb/ddbvar.h> 99 1.19.2.1 bouyer #endif 100 1.19.2.1 bouyer 101 1.19.2.2 bouyer /* this is provided by kern/kern_exec.c */ 102 1.19.2.2 bouyer extern int exec_maxhdrsz; 103 1.19.2.2 bouyer 104 1.10 mrg static __inline void netbsd32_from_timeval __P((struct timeval *, struct netbsd32_timeval *)); 105 1.10 mrg static __inline void netbsd32_to_timeval __P((struct netbsd32_timeval *, struct timeval *)); 106 1.10 mrg static __inline void netbsd32_from_itimerval __P((struct itimerval *, struct netbsd32_itimerval *)); 107 1.10 mrg static __inline void netbsd32_to_itimerval __P((struct netbsd32_itimerval *, struct itimerval *)); 108 1.10 mrg static __inline void netbsd32_to_timespec __P((struct netbsd32_timespec *, struct timespec *)); 109 1.10 mrg static __inline void netbsd32_from_timespec __P((struct timespec *, struct netbsd32_timespec *)); 110 1.10 mrg static __inline void netbsd32_from_rusage __P((struct rusage *, struct netbsd32_rusage *)); 111 1.10 mrg static __inline void netbsd32_to_rusage __P((struct netbsd32_rusage *, struct rusage *)); 112 1.10 mrg static __inline int netbsd32_to_iovecin __P((struct netbsd32_iovec *, struct iovec *, int)); 113 1.10 mrg static __inline void netbsd32_to_msghdr __P((struct netbsd32_msghdr *, struct msghdr *)); 114 1.10 mrg static __inline void netbsd32_from_msghdr __P((struct netbsd32_msghdr *, struct msghdr *)); 115 1.10 mrg static __inline void netbsd32_from_statfs __P((struct statfs *, struct netbsd32_statfs *)); 116 1.10 mrg static __inline void netbsd32_from_timex __P((struct timex *, struct netbsd32_timex *)); 117 1.10 mrg static __inline void netbsd32_to_timex __P((struct netbsd32_timex *, struct timex *)); 118 1.10 mrg static __inline void netbsd32_from___stat13 __P((struct stat *, struct netbsd32_stat *)); 119 1.10 mrg static __inline void netbsd32_to_ipc_perm __P((struct netbsd32_ipc_perm *, struct ipc_perm *)); 120 1.10 mrg static __inline void netbsd32_from_ipc_perm __P((struct ipc_perm *, struct netbsd32_ipc_perm *)); 121 1.10 mrg static __inline void netbsd32_to_msg __P((struct netbsd32_msg *, struct msg *)); 122 1.10 mrg static __inline void netbsd32_from_msg __P((struct msg *, struct netbsd32_msg *)); 123 1.10 mrg static __inline void netbsd32_to_msqid_ds __P((struct netbsd32_msqid_ds *, struct msqid_ds *)); 124 1.10 mrg static __inline void netbsd32_from_msqid_ds __P((struct msqid_ds *, struct netbsd32_msqid_ds *)); 125 1.10 mrg static __inline void netbsd32_to_shmid_ds __P((struct netbsd32_shmid_ds *, struct shmid_ds *)); 126 1.10 mrg static __inline void netbsd32_from_shmid_ds __P((struct shmid_ds *, struct netbsd32_shmid_ds *)); 127 1.10 mrg static __inline void netbsd32_to_semid_ds __P((struct netbsd32_semid_ds *, struct semid_ds *)); 128 1.10 mrg static __inline void netbsd32_from_semid_ds __P((struct semid_ds *, struct netbsd32_semid_ds *)); 129 1.4 eeh 130 1.6 eeh 131 1.10 mrg static int recvit32 __P((struct proc *, int, struct netbsd32_msghdr *, struct iovec *, caddr_t, 132 1.6 eeh register_t *)); 133 1.10 mrg static int dofilereadv32 __P((struct proc *, int, struct file *, struct netbsd32_iovec *, 134 1.6 eeh int, off_t *, int, register_t *)); 135 1.10 mrg static int dofilewritev32 __P((struct proc *, int, struct file *, struct netbsd32_iovec *, 136 1.6 eeh int, off_t *, int, register_t *)); 137 1.6 eeh static int change_utimes32 __P((struct vnode *, struct timeval *, struct proc *)); 138 1.6 eeh 139 1.19.2.2 bouyer extern char netbsd32_sigcode[], netbsd32_esigcode[]; 140 1.19.2.2 bouyer extern struct sysent netbsd32_sysent[]; 141 1.19.2.2 bouyer #ifdef SYSCALL_DEBUG 142 1.19.2.2 bouyer extern const char * const netbsd32_syscallnames[]; 143 1.19.2.2 bouyer #endif 144 1.19.2.2 bouyer 145 1.19.2.2 bouyer const struct emul emul_netbsd32 = { 146 1.19.2.2 bouyer "netbsd32", 147 1.19.2.2 bouyer "/emul/netbsd32", 148 1.19.2.2 bouyer NULL, 149 1.19.2.2 bouyer netbsd32_sendsig, 150 1.19.2.2 bouyer netbsd32_SYS_syscall, 151 1.19.2.2 bouyer netbsd32_SYS_MAXSYSCALL, 152 1.19.2.2 bouyer netbsd32_sysent, 153 1.19.2.2 bouyer #ifdef SYSCALL_DEBUG 154 1.19.2.2 bouyer netbsd32_syscallnames, 155 1.19.2.2 bouyer #else 156 1.19.2.2 bouyer NULL, 157 1.19.2.2 bouyer #endif 158 1.19.2.2 bouyer netbsd32_sigcode, 159 1.19.2.2 bouyer netbsd32_esigcode, 160 1.19.2.2 bouyer }; 161 1.19.2.2 bouyer 162 1.1 mrg /* converters for structures that we need */ 163 1.1 mrg static __inline void 164 1.10 mrg netbsd32_from_timeval(tv, tv32) 165 1.1 mrg struct timeval *tv; 166 1.10 mrg struct netbsd32_timeval *tv32; 167 1.1 mrg { 168 1.1 mrg 169 1.10 mrg tv32->tv_sec = (netbsd32_long)tv->tv_sec; 170 1.10 mrg tv32->tv_usec = (netbsd32_long)tv->tv_usec; 171 1.1 mrg } 172 1.1 mrg 173 1.1 mrg static __inline void 174 1.10 mrg netbsd32_to_timeval(tv32, tv) 175 1.10 mrg struct netbsd32_timeval *tv32; 176 1.1 mrg struct timeval *tv; 177 1.1 mrg { 178 1.1 mrg 179 1.1 mrg tv->tv_sec = (long)tv32->tv_sec; 180 1.1 mrg tv->tv_usec = (long)tv32->tv_usec; 181 1.1 mrg } 182 1.1 mrg 183 1.1 mrg static __inline void 184 1.10 mrg netbsd32_from_itimerval(itv, itv32) 185 1.1 mrg struct itimerval *itv; 186 1.10 mrg struct netbsd32_itimerval *itv32; 187 1.1 mrg { 188 1.1 mrg 189 1.10 mrg netbsd32_from_timeval(&itv->it_interval, 190 1.6 eeh &itv32->it_interval); 191 1.10 mrg netbsd32_from_timeval(&itv->it_value, 192 1.6 eeh &itv32->it_value); 193 1.1 mrg } 194 1.1 mrg 195 1.1 mrg static __inline void 196 1.10 mrg netbsd32_to_itimerval(itv32, itv) 197 1.10 mrg struct netbsd32_itimerval *itv32; 198 1.1 mrg struct itimerval *itv; 199 1.1 mrg { 200 1.1 mrg 201 1.10 mrg netbsd32_to_timeval(&itv32->it_interval, &itv->it_interval); 202 1.10 mrg netbsd32_to_timeval(&itv32->it_value, &itv->it_value); 203 1.1 mrg } 204 1.1 mrg 205 1.1 mrg static __inline void 206 1.10 mrg netbsd32_to_timespec(s32p, p) 207 1.10 mrg struct netbsd32_timespec *s32p; 208 1.2 mrg struct timespec *p; 209 1.2 mrg { 210 1.2 mrg 211 1.19.2.1 bouyer p->tv_sec = (time_t)s32p->tv_sec; 212 1.2 mrg p->tv_nsec = (long)s32p->tv_nsec; 213 1.2 mrg } 214 1.2 mrg 215 1.2 mrg static __inline void 216 1.10 mrg netbsd32_from_timespec(p, s32p) 217 1.2 mrg struct timespec *p; 218 1.10 mrg struct netbsd32_timespec *s32p; 219 1.2 mrg { 220 1.2 mrg 221 1.19.2.1 bouyer s32p->tv_sec = (netbsd32_time_t)p->tv_sec; 222 1.10 mrg s32p->tv_nsec = (netbsd32_long)p->tv_nsec; 223 1.2 mrg } 224 1.2 mrg 225 1.2 mrg static __inline void 226 1.10 mrg netbsd32_from_rusage(rup, ru32p) 227 1.1 mrg struct rusage *rup; 228 1.10 mrg struct netbsd32_rusage *ru32p; 229 1.1 mrg { 230 1.1 mrg 231 1.10 mrg netbsd32_from_timeval(&rup->ru_utime, &ru32p->ru_utime); 232 1.10 mrg netbsd32_from_timeval(&rup->ru_stime, &ru32p->ru_stime); 233 1.10 mrg #define C(var) ru32p->var = (netbsd32_long)rup->var 234 1.1 mrg C(ru_maxrss); 235 1.1 mrg C(ru_ixrss); 236 1.1 mrg C(ru_idrss); 237 1.1 mrg C(ru_isrss); 238 1.1 mrg C(ru_minflt); 239 1.1 mrg C(ru_majflt); 240 1.1 mrg C(ru_nswap); 241 1.1 mrg C(ru_inblock); 242 1.1 mrg C(ru_oublock); 243 1.1 mrg C(ru_msgsnd); 244 1.1 mrg C(ru_msgrcv); 245 1.1 mrg C(ru_nsignals); 246 1.1 mrg C(ru_nvcsw); 247 1.1 mrg C(ru_nivcsw); 248 1.1 mrg #undef C 249 1.1 mrg } 250 1.1 mrg 251 1.1 mrg static __inline void 252 1.10 mrg netbsd32_to_rusage(ru32p, rup) 253 1.10 mrg struct netbsd32_rusage *ru32p; 254 1.1 mrg struct rusage *rup; 255 1.1 mrg { 256 1.1 mrg 257 1.10 mrg netbsd32_to_timeval(&ru32p->ru_utime, &rup->ru_utime); 258 1.10 mrg netbsd32_to_timeval(&ru32p->ru_stime, &rup->ru_stime); 259 1.1 mrg #define C(var) rup->var = (long)ru32p->var 260 1.1 mrg C(ru_maxrss); 261 1.1 mrg C(ru_ixrss); 262 1.1 mrg C(ru_idrss); 263 1.1 mrg C(ru_isrss); 264 1.1 mrg C(ru_minflt); 265 1.1 mrg C(ru_majflt); 266 1.1 mrg C(ru_nswap); 267 1.1 mrg C(ru_inblock); 268 1.1 mrg C(ru_oublock); 269 1.1 mrg C(ru_msgsnd); 270 1.1 mrg C(ru_msgrcv); 271 1.1 mrg C(ru_nsignals); 272 1.1 mrg C(ru_nvcsw); 273 1.1 mrg C(ru_nivcsw); 274 1.1 mrg #undef C 275 1.1 mrg } 276 1.1 mrg 277 1.6 eeh static __inline int 278 1.10 mrg netbsd32_to_iovecin(iov32p, iovp, len) 279 1.10 mrg struct netbsd32_iovec *iov32p; 280 1.1 mrg struct iovec *iovp; 281 1.1 mrg int len; 282 1.1 mrg { 283 1.6 eeh int i, error=0; 284 1.6 eeh u_int32_t iov_base; 285 1.6 eeh u_int32_t iov_len; 286 1.6 eeh /* 287 1.6 eeh * We could allocate an iov32p, do a copyin, and translate 288 1.6 eeh * each field and then free it all up, or we could copyin 289 1.6 eeh * each field separately. I'm doing the latter to reduce 290 1.6 eeh * the number of MALLOC()s. 291 1.6 eeh */ 292 1.1 mrg for (i = 0; i < len; i++, iovp++, iov32p++) { 293 1.6 eeh if ((error = copyin((caddr_t)&iov32p->iov_base, &iov_base, sizeof(iov_base)))) 294 1.6 eeh return (error); 295 1.6 eeh if ((error = copyin((caddr_t)&iov32p->iov_len, &iov_len, sizeof(iov_len)))) 296 1.6 eeh return (error); 297 1.6 eeh iovp->iov_base = (void *)(u_long)iov_base; 298 1.6 eeh iovp->iov_len = (size_t)iov_len; 299 1.1 mrg } 300 1.19.2.2 bouyer return error; 301 1.1 mrg } 302 1.1 mrg 303 1.6 eeh /* msg_iov must be done separately */ 304 1.1 mrg static __inline void 305 1.10 mrg netbsd32_to_msghdr(mhp32, mhp) 306 1.10 mrg struct netbsd32_msghdr *mhp32; 307 1.1 mrg struct msghdr *mhp; 308 1.1 mrg { 309 1.1 mrg 310 1.1 mrg mhp->msg_name = (caddr_t)(u_long)mhp32->msg_name; 311 1.1 mrg mhp->msg_namelen = mhp32->msg_namelen; 312 1.1 mrg mhp->msg_iovlen = (size_t)mhp32->msg_iovlen; 313 1.1 mrg mhp->msg_control = (caddr_t)(u_long)mhp32->msg_control; 314 1.1 mrg mhp->msg_controllen = mhp32->msg_controllen; 315 1.1 mrg mhp->msg_flags = mhp32->msg_flags; 316 1.6 eeh } 317 1.6 eeh 318 1.6 eeh /* msg_iov must be done separately */ 319 1.6 eeh static __inline void 320 1.10 mrg netbsd32_from_msghdr(mhp32, mhp) 321 1.10 mrg struct netbsd32_msghdr *mhp32; 322 1.6 eeh struct msghdr *mhp; 323 1.6 eeh { 324 1.6 eeh 325 1.6 eeh mhp32->msg_name = mhp32->msg_name; 326 1.6 eeh mhp32->msg_namelen = mhp32->msg_namelen; 327 1.6 eeh mhp32->msg_iovlen = mhp32->msg_iovlen; 328 1.6 eeh mhp32->msg_control = mhp32->msg_control; 329 1.6 eeh mhp32->msg_controllen = mhp->msg_controllen; 330 1.6 eeh mhp32->msg_flags = mhp->msg_flags; 331 1.1 mrg } 332 1.1 mrg 333 1.1 mrg static __inline void 334 1.10 mrg netbsd32_from_statfs(sbp, sb32p) 335 1.1 mrg struct statfs *sbp; 336 1.10 mrg struct netbsd32_statfs *sb32p; 337 1.1 mrg { 338 1.1 mrg sb32p->f_type = sbp->f_type; 339 1.1 mrg sb32p->f_flags = sbp->f_flags; 340 1.10 mrg sb32p->f_bsize = (netbsd32_long)sbp->f_bsize; 341 1.10 mrg sb32p->f_iosize = (netbsd32_long)sbp->f_iosize; 342 1.10 mrg sb32p->f_blocks = (netbsd32_long)sbp->f_blocks; 343 1.10 mrg sb32p->f_bfree = (netbsd32_long)sbp->f_bfree; 344 1.10 mrg sb32p->f_bavail = (netbsd32_long)sbp->f_bavail; 345 1.10 mrg sb32p->f_files = (netbsd32_long)sbp->f_files; 346 1.10 mrg sb32p->f_ffree = (netbsd32_long)sbp->f_ffree; 347 1.1 mrg sb32p->f_fsid = sbp->f_fsid; 348 1.1 mrg sb32p->f_owner = sbp->f_owner; 349 1.6 eeh sb32p->f_spare[0] = 0; 350 1.6 eeh sb32p->f_spare[1] = 0; 351 1.6 eeh sb32p->f_spare[2] = 0; 352 1.6 eeh sb32p->f_spare[3] = 0; 353 1.6 eeh #if 1 354 1.6 eeh /* May as well do the whole batch in one go */ 355 1.6 eeh memcpy(sb32p->f_fstypename, sbp->f_fstypename, MFSNAMELEN+MNAMELEN+MNAMELEN); 356 1.6 eeh #else 357 1.6 eeh /* If we want to be careful */ 358 1.6 eeh memcpy(sb32p->f_fstypename, sbp->f_fstypename, MFSNAMELEN); 359 1.6 eeh memcpy(sb32p->f_mntonname, sbp->f_mntonname, MNAMELEN); 360 1.6 eeh memcpy(sb32p->f_mntfromname, sbp->f_mntfromname, MNAMELEN); 361 1.6 eeh #endif 362 1.1 mrg } 363 1.1 mrg 364 1.1 mrg static __inline void 365 1.10 mrg netbsd32_from_timex(txp, tx32p) 366 1.1 mrg struct timex *txp; 367 1.10 mrg struct netbsd32_timex *tx32p; 368 1.1 mrg { 369 1.1 mrg 370 1.1 mrg tx32p->modes = txp->modes; 371 1.10 mrg tx32p->offset = (netbsd32_long)txp->offset; 372 1.10 mrg tx32p->freq = (netbsd32_long)txp->freq; 373 1.10 mrg tx32p->maxerror = (netbsd32_long)txp->maxerror; 374 1.10 mrg tx32p->esterror = (netbsd32_long)txp->esterror; 375 1.1 mrg tx32p->status = txp->status; 376 1.10 mrg tx32p->constant = (netbsd32_long)txp->constant; 377 1.10 mrg tx32p->precision = (netbsd32_long)txp->precision; 378 1.10 mrg tx32p->tolerance = (netbsd32_long)txp->tolerance; 379 1.10 mrg tx32p->ppsfreq = (netbsd32_long)txp->ppsfreq; 380 1.10 mrg tx32p->jitter = (netbsd32_long)txp->jitter; 381 1.1 mrg tx32p->shift = txp->shift; 382 1.10 mrg tx32p->stabil = (netbsd32_long)txp->stabil; 383 1.10 mrg tx32p->jitcnt = (netbsd32_long)txp->jitcnt; 384 1.10 mrg tx32p->calcnt = (netbsd32_long)txp->calcnt; 385 1.10 mrg tx32p->errcnt = (netbsd32_long)txp->errcnt; 386 1.10 mrg tx32p->stbcnt = (netbsd32_long)txp->stbcnt; 387 1.1 mrg } 388 1.1 mrg 389 1.1 mrg static __inline void 390 1.10 mrg netbsd32_to_timex(tx32p, txp) 391 1.10 mrg struct netbsd32_timex *tx32p; 392 1.1 mrg struct timex *txp; 393 1.1 mrg { 394 1.1 mrg 395 1.1 mrg txp->modes = tx32p->modes; 396 1.1 mrg txp->offset = (long)tx32p->offset; 397 1.1 mrg txp->freq = (long)tx32p->freq; 398 1.1 mrg txp->maxerror = (long)tx32p->maxerror; 399 1.1 mrg txp->esterror = (long)tx32p->esterror; 400 1.1 mrg txp->status = tx32p->status; 401 1.1 mrg txp->constant = (long)tx32p->constant; 402 1.1 mrg txp->precision = (long)tx32p->precision; 403 1.1 mrg txp->tolerance = (long)tx32p->tolerance; 404 1.1 mrg txp->ppsfreq = (long)tx32p->ppsfreq; 405 1.1 mrg txp->jitter = (long)tx32p->jitter; 406 1.1 mrg txp->shift = tx32p->shift; 407 1.1 mrg txp->stabil = (long)tx32p->stabil; 408 1.1 mrg txp->jitcnt = (long)tx32p->jitcnt; 409 1.1 mrg txp->calcnt = (long)tx32p->calcnt; 410 1.1 mrg txp->errcnt = (long)tx32p->errcnt; 411 1.1 mrg txp->stbcnt = (long)tx32p->stbcnt; 412 1.1 mrg } 413 1.1 mrg 414 1.1 mrg static __inline void 415 1.10 mrg netbsd32_from___stat13(sbp, sb32p) 416 1.1 mrg struct stat *sbp; 417 1.10 mrg struct netbsd32_stat *sb32p; 418 1.1 mrg { 419 1.1 mrg sb32p->st_dev = sbp->st_dev; 420 1.1 mrg sb32p->st_ino = sbp->st_ino; 421 1.1 mrg sb32p->st_mode = sbp->st_mode; 422 1.1 mrg sb32p->st_nlink = sbp->st_nlink; 423 1.1 mrg sb32p->st_uid = sbp->st_uid; 424 1.1 mrg sb32p->st_gid = sbp->st_gid; 425 1.1 mrg sb32p->st_rdev = sbp->st_rdev; 426 1.1 mrg if (sbp->st_size < (quad_t)1 << 32) 427 1.1 mrg sb32p->st_size = sbp->st_size; 428 1.1 mrg else 429 1.1 mrg sb32p->st_size = -2; 430 1.19.2.1 bouyer sb32p->st_atimespec.tv_sec = (netbsd32_time_t)sbp->st_atimespec.tv_sec; 431 1.10 mrg sb32p->st_atimespec.tv_nsec = (netbsd32_long)sbp->st_atimespec.tv_nsec; 432 1.19.2.1 bouyer sb32p->st_mtimespec.tv_sec = (netbsd32_time_t)sbp->st_mtimespec.tv_sec; 433 1.10 mrg sb32p->st_mtimespec.tv_nsec = (netbsd32_long)sbp->st_mtimespec.tv_nsec; 434 1.19.2.1 bouyer sb32p->st_ctimespec.tv_sec = (netbsd32_time_t)sbp->st_ctimespec.tv_sec; 435 1.10 mrg sb32p->st_ctimespec.tv_nsec = (netbsd32_long)sbp->st_ctimespec.tv_nsec; 436 1.1 mrg sb32p->st_blksize = sbp->st_blksize; 437 1.1 mrg sb32p->st_blocks = sbp->st_blocks; 438 1.1 mrg sb32p->st_flags = sbp->st_flags; 439 1.1 mrg sb32p->st_gen = sbp->st_gen; 440 1.1 mrg } 441 1.1 mrg 442 1.1 mrg static __inline void 443 1.10 mrg netbsd32_to_ipc_perm(ip32p, ipp) 444 1.10 mrg struct netbsd32_ipc_perm *ip32p; 445 1.1 mrg struct ipc_perm *ipp; 446 1.1 mrg { 447 1.1 mrg 448 1.1 mrg ipp->cuid = ip32p->cuid; 449 1.1 mrg ipp->cgid = ip32p->cgid; 450 1.1 mrg ipp->uid = ip32p->uid; 451 1.1 mrg ipp->gid = ip32p->gid; 452 1.1 mrg ipp->mode = ip32p->mode; 453 1.19 eeh ipp->_seq = ip32p->_seq; 454 1.19 eeh ipp->_key = (key_t)ip32p->_key; 455 1.1 mrg } 456 1.1 mrg 457 1.1 mrg static __inline void 458 1.10 mrg netbsd32_from_ipc_perm(ipp, ip32p) 459 1.1 mrg struct ipc_perm *ipp; 460 1.10 mrg struct netbsd32_ipc_perm *ip32p; 461 1.1 mrg { 462 1.1 mrg 463 1.1 mrg ip32p->cuid = ipp->cuid; 464 1.1 mrg ip32p->cgid = ipp->cgid; 465 1.1 mrg ip32p->uid = ipp->uid; 466 1.1 mrg ip32p->gid = ipp->gid; 467 1.1 mrg ip32p->mode = ipp->mode; 468 1.19 eeh ip32p->_seq = ipp->_seq; 469 1.19 eeh ip32p->_key = (netbsd32_key_t)ipp->_key; 470 1.1 mrg } 471 1.1 mrg 472 1.1 mrg static __inline void 473 1.10 mrg netbsd32_to_msg(m32p, mp) 474 1.10 mrg struct netbsd32_msg *m32p; 475 1.1 mrg struct msg *mp; 476 1.1 mrg { 477 1.1 mrg 478 1.1 mrg mp->msg_next = (struct msg *)(u_long)m32p->msg_next; 479 1.1 mrg mp->msg_type = (long)m32p->msg_type; 480 1.1 mrg mp->msg_ts = m32p->msg_ts; 481 1.1 mrg mp->msg_spot = m32p->msg_spot; 482 1.1 mrg } 483 1.1 mrg 484 1.1 mrg static __inline void 485 1.10 mrg netbsd32_from_msg(mp, m32p) 486 1.1 mrg struct msg *mp; 487 1.10 mrg struct netbsd32_msg *m32p; 488 1.1 mrg { 489 1.1 mrg 490 1.10 mrg m32p->msg_next = (netbsd32_msgp_t)(u_long)mp->msg_next; 491 1.10 mrg m32p->msg_type = (netbsd32_long)mp->msg_type; 492 1.1 mrg m32p->msg_ts = mp->msg_ts; 493 1.1 mrg m32p->msg_spot = mp->msg_spot; 494 1.1 mrg } 495 1.1 mrg 496 1.1 mrg static __inline void 497 1.10 mrg netbsd32_to_msqid_ds(ds32p, dsp) 498 1.10 mrg struct netbsd32_msqid_ds *ds32p; 499 1.1 mrg struct msqid_ds *dsp; 500 1.1 mrg { 501 1.1 mrg 502 1.10 mrg netbsd32_to_ipc_perm(&ds32p->msg_perm, &dsp->msg_perm); 503 1.19 eeh netbsd32_to_msg((struct netbsd32_msg *)(u_long)ds32p->_msg_first, dsp->_msg_first); 504 1.19 eeh netbsd32_to_msg((struct netbsd32_msg *)(u_long)ds32p->_msg_last, dsp->_msg_last); 505 1.19 eeh dsp->_msg_cbytes = (u_long)ds32p->_msg_cbytes; 506 1.1 mrg dsp->msg_qnum = (u_long)ds32p->msg_qnum; 507 1.1 mrg dsp->msg_qbytes = (u_long)ds32p->msg_qbytes; 508 1.1 mrg dsp->msg_lspid = ds32p->msg_lspid; 509 1.1 mrg dsp->msg_lrpid = ds32p->msg_lrpid; 510 1.1 mrg dsp->msg_rtime = (time_t)ds32p->msg_rtime; 511 1.1 mrg dsp->msg_stime = (time_t)ds32p->msg_stime; 512 1.1 mrg dsp->msg_ctime = (time_t)ds32p->msg_ctime; 513 1.1 mrg } 514 1.1 mrg 515 1.1 mrg static __inline void 516 1.10 mrg netbsd32_from_msqid_ds(dsp, ds32p) 517 1.1 mrg struct msqid_ds *dsp; 518 1.10 mrg struct netbsd32_msqid_ds *ds32p; 519 1.1 mrg { 520 1.1 mrg 521 1.10 mrg netbsd32_from_ipc_perm(&dsp->msg_perm, &ds32p->msg_perm); 522 1.19 eeh netbsd32_from_msg(dsp->_msg_first, (struct netbsd32_msg *)(u_long)ds32p->_msg_first); 523 1.19 eeh netbsd32_from_msg(dsp->_msg_last, (struct netbsd32_msg *)(u_long)ds32p->_msg_last); 524 1.19 eeh ds32p->_msg_cbytes = (netbsd32_u_long)dsp->_msg_cbytes; 525 1.10 mrg ds32p->msg_qnum = (netbsd32_u_long)dsp->msg_qnum; 526 1.10 mrg ds32p->msg_qbytes = (netbsd32_u_long)dsp->msg_qbytes; 527 1.1 mrg ds32p->msg_lspid = dsp->msg_lspid; 528 1.1 mrg ds32p->msg_lrpid = dsp->msg_lrpid; 529 1.1 mrg ds32p->msg_rtime = dsp->msg_rtime; 530 1.1 mrg ds32p->msg_stime = dsp->msg_stime; 531 1.1 mrg ds32p->msg_ctime = dsp->msg_ctime; 532 1.1 mrg } 533 1.1 mrg 534 1.1 mrg static __inline void 535 1.10 mrg netbsd32_to_shmid_ds(ds32p, dsp) 536 1.10 mrg struct netbsd32_shmid_ds *ds32p; 537 1.1 mrg struct shmid_ds *dsp; 538 1.1 mrg { 539 1.1 mrg 540 1.10 mrg netbsd32_to_ipc_perm(&ds32p->shm_perm, &dsp->shm_perm); 541 1.1 mrg dsp->shm_segsz = ds32p->shm_segsz; 542 1.1 mrg dsp->shm_lpid = ds32p->shm_lpid; 543 1.1 mrg dsp->shm_cpid = ds32p->shm_cpid; 544 1.1 mrg dsp->shm_nattch = ds32p->shm_nattch; 545 1.1 mrg dsp->shm_atime = (long)ds32p->shm_atime; 546 1.1 mrg dsp->shm_dtime = (long)ds32p->shm_dtime; 547 1.1 mrg dsp->shm_ctime = (long)ds32p->shm_ctime; 548 1.19 eeh dsp->_shm_internal = (void *)(u_long)ds32p->_shm_internal; 549 1.1 mrg } 550 1.1 mrg 551 1.1 mrg static __inline void 552 1.10 mrg netbsd32_from_shmid_ds(dsp, ds32p) 553 1.1 mrg struct shmid_ds *dsp; 554 1.10 mrg struct netbsd32_shmid_ds *ds32p; 555 1.1 mrg { 556 1.1 mrg 557 1.10 mrg netbsd32_from_ipc_perm(&dsp->shm_perm, &ds32p->shm_perm); 558 1.1 mrg ds32p->shm_segsz = dsp->shm_segsz; 559 1.1 mrg ds32p->shm_lpid = dsp->shm_lpid; 560 1.1 mrg ds32p->shm_cpid = dsp->shm_cpid; 561 1.1 mrg ds32p->shm_nattch = dsp->shm_nattch; 562 1.10 mrg ds32p->shm_atime = (netbsd32_long)dsp->shm_atime; 563 1.10 mrg ds32p->shm_dtime = (netbsd32_long)dsp->shm_dtime; 564 1.10 mrg ds32p->shm_ctime = (netbsd32_long)dsp->shm_ctime; 565 1.19 eeh ds32p->_shm_internal = (netbsd32_voidp)(u_long)dsp->_shm_internal; 566 1.1 mrg } 567 1.1 mrg 568 1.1 mrg static __inline void 569 1.10 mrg netbsd32_to_semid_ds(s32dsp, dsp) 570 1.10 mrg struct netbsd32_semid_ds *s32dsp; 571 1.1 mrg struct semid_ds *dsp; 572 1.1 mrg { 573 1.1 mrg 574 1.10 mrg netbsd32_from_ipc_perm(&dsp->sem_perm, &s32dsp->sem_perm); 575 1.19 eeh dsp->_sem_base = (struct __sem *)(u_long)s32dsp->_sem_base; 576 1.1 mrg dsp->sem_nsems = s32dsp->sem_nsems; 577 1.1 mrg dsp->sem_otime = s32dsp->sem_otime; 578 1.1 mrg dsp->sem_ctime = s32dsp->sem_ctime; 579 1.1 mrg } 580 1.1 mrg 581 1.2 mrg static __inline void 582 1.10 mrg netbsd32_from_semid_ds(dsp, s32dsp) 583 1.2 mrg struct semid_ds *dsp; 584 1.10 mrg struct netbsd32_semid_ds *s32dsp; 585 1.2 mrg { 586 1.2 mrg 587 1.10 mrg netbsd32_to_ipc_perm(&s32dsp->sem_perm, &dsp->sem_perm); 588 1.19 eeh s32dsp->_sem_base = (netbsd32_semp_t)(u_long)dsp->_sem_base; 589 1.2 mrg s32dsp->sem_nsems = dsp->sem_nsems; 590 1.2 mrg s32dsp->sem_otime = dsp->sem_otime; 591 1.2 mrg s32dsp->sem_ctime = dsp->sem_ctime; 592 1.2 mrg } 593 1.2 mrg 594 1.1 mrg /* 595 1.1 mrg * below are all the standard NetBSD system calls, in the 32bit 596 1.19.2.1 bouyer * environment, with the necessary conversions to 64bit before 597 1.19.2.1 bouyer * calling the real syscall, unless we need to inline the whole 598 1.19.2.1 bouyer * syscall here, sigh. 599 1.1 mrg */ 600 1.1 mrg 601 1.6 eeh int 602 1.19 eeh netbsd32_exit(p, v, retval) 603 1.6 eeh struct proc *p; 604 1.6 eeh void *v; 605 1.6 eeh register_t *retval; 606 1.6 eeh { 607 1.19 eeh struct netbsd32_exit_args /* { 608 1.6 eeh syscallarg(int) rval; 609 1.6 eeh } */ *uap = v; 610 1.6 eeh struct sys_exit_args ua; 611 1.6 eeh 612 1.11 mrg NETBSD32TO64_UAP(rval); 613 1.19.2.2 bouyer return sys_exit(p, &ua, retval); 614 1.6 eeh } 615 1.6 eeh 616 1.1 mrg int 617 1.19 eeh netbsd32_read(p, v, retval) 618 1.1 mrg struct proc *p; 619 1.1 mrg void *v; 620 1.1 mrg register_t *retval; 621 1.1 mrg { 622 1.19 eeh struct netbsd32_read_args /* { 623 1.1 mrg syscallarg(int) fd; 624 1.10 mrg syscallarg(netbsd32_voidp) buf; 625 1.10 mrg syscallarg(netbsd32_size_t) nbyte; 626 1.1 mrg } */ *uap = v; 627 1.1 mrg struct sys_read_args ua; 628 1.1 mrg 629 1.11 mrg NETBSD32TO64_UAP(fd); 630 1.11 mrg NETBSD32TOP_UAP(buf, void *); 631 1.11 mrg NETBSD32TOX_UAP(nbyte, size_t); 632 1.6 eeh return sys_read(p, &ua, retval); 633 1.1 mrg } 634 1.1 mrg 635 1.1 mrg int 636 1.19 eeh netbsd32_write(p, v, retval) 637 1.1 mrg struct proc *p; 638 1.1 mrg void *v; 639 1.1 mrg register_t *retval; 640 1.1 mrg { 641 1.19 eeh struct netbsd32_write_args /* { 642 1.1 mrg syscallarg(int) fd; 643 1.10 mrg syscallarg(const netbsd32_voidp) buf; 644 1.10 mrg syscallarg(netbsd32_size_t) nbyte; 645 1.1 mrg } */ *uap = v; 646 1.1 mrg struct sys_write_args ua; 647 1.1 mrg 648 1.11 mrg NETBSD32TO64_UAP(fd); 649 1.11 mrg NETBSD32TOP_UAP(buf, void *); 650 1.11 mrg NETBSD32TOX_UAP(nbyte, size_t); 651 1.6 eeh return sys_write(p, &ua, retval); 652 1.6 eeh } 653 1.6 eeh 654 1.6 eeh int 655 1.19 eeh netbsd32_close(p, v, retval) 656 1.6 eeh struct proc *p; 657 1.6 eeh void *v; 658 1.6 eeh register_t *retval; 659 1.6 eeh { 660 1.19 eeh struct netbsd32_close_args /* { 661 1.6 eeh syscallarg(int) fd; 662 1.6 eeh } */ *uap = v; 663 1.6 eeh struct sys_close_args ua; 664 1.1 mrg 665 1.11 mrg NETBSD32TO64_UAP(fd); 666 1.19.2.1 bouyer return sys_close(p, &ua, retval); 667 1.1 mrg } 668 1.1 mrg 669 1.1 mrg int 670 1.19 eeh netbsd32_open(p, v, retval) 671 1.1 mrg struct proc *p; 672 1.1 mrg void *v; 673 1.1 mrg register_t *retval; 674 1.1 mrg { 675 1.19 eeh struct netbsd32_open_args /* { 676 1.10 mrg syscallarg(const netbsd32_charp) path; 677 1.1 mrg syscallarg(int) flags; 678 1.1 mrg syscallarg(mode_t) mode; 679 1.1 mrg } */ *uap = v; 680 1.1 mrg struct sys_open_args ua; 681 1.1 mrg caddr_t sg; 682 1.1 mrg 683 1.11 mrg NETBSD32TOP_UAP(path, const char); 684 1.11 mrg NETBSD32TO64_UAP(flags); 685 1.11 mrg NETBSD32TO64_UAP(mode); 686 1.1 mrg sg = stackgap_init(p->p_emul); 687 1.19.2.2 bouyer CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path)); 688 1.1 mrg 689 1.1 mrg return (sys_open(p, &ua, retval)); 690 1.1 mrg } 691 1.1 mrg 692 1.1 mrg int 693 1.19 eeh netbsd32_wait4(q, v, retval) 694 1.6 eeh struct proc *q; 695 1.1 mrg void *v; 696 1.1 mrg register_t *retval; 697 1.1 mrg { 698 1.19 eeh struct netbsd32_wait4_args /* { 699 1.1 mrg syscallarg(int) pid; 700 1.10 mrg syscallarg(netbsd32_intp) status; 701 1.1 mrg syscallarg(int) options; 702 1.10 mrg syscallarg(netbsd32_rusagep_t) rusage; 703 1.1 mrg } */ *uap = v; 704 1.10 mrg struct netbsd32_rusage ru32; 705 1.19.2.1 bouyer int nfound; 706 1.19.2.1 bouyer struct proc *p, *t; 707 1.6 eeh int status, error; 708 1.6 eeh 709 1.6 eeh if (SCARG(uap, pid) == 0) 710 1.6 eeh SCARG(uap, pid) = -q->p_pgid; 711 1.6 eeh if (SCARG(uap, options) &~ (WUNTRACED|WNOHANG)) 712 1.6 eeh return (EINVAL); 713 1.1 mrg 714 1.6 eeh loop: 715 1.6 eeh nfound = 0; 716 1.6 eeh for (p = q->p_children.lh_first; p != 0; p = p->p_sibling.le_next) { 717 1.6 eeh if (SCARG(uap, pid) != WAIT_ANY && 718 1.6 eeh p->p_pid != SCARG(uap, pid) && 719 1.6 eeh p->p_pgid != -SCARG(uap, pid)) 720 1.6 eeh continue; 721 1.6 eeh nfound++; 722 1.6 eeh if (p->p_stat == SZOMB) { 723 1.6 eeh retval[0] = p->p_pid; 724 1.6 eeh 725 1.6 eeh if (SCARG(uap, status)) { 726 1.6 eeh status = p->p_xstat; /* convert to int */ 727 1.6 eeh error = copyout((caddr_t)&status, 728 1.6 eeh (caddr_t)(u_long)SCARG(uap, status), 729 1.6 eeh sizeof(status)); 730 1.6 eeh if (error) 731 1.6 eeh return (error); 732 1.6 eeh } 733 1.6 eeh if (SCARG(uap, rusage)) { 734 1.10 mrg netbsd32_from_rusage(p->p_ru, &ru32); 735 1.6 eeh if ((error = copyout((caddr_t)&ru32, 736 1.6 eeh (caddr_t)(u_long)SCARG(uap, rusage), 737 1.10 mrg sizeof(struct netbsd32_rusage)))) 738 1.6 eeh return (error); 739 1.6 eeh } 740 1.6 eeh /* 741 1.6 eeh * If we got the child via ptrace(2) or procfs, and 742 1.6 eeh * the parent is different (meaning the process was 743 1.6 eeh * attached, rather than run as a child), then we need 744 1.6 eeh * to give it back to the old parent, and send the 745 1.6 eeh * parent a SIGCHLD. The rest of the cleanup will be 746 1.6 eeh * done when the old parent waits on the child. 747 1.6 eeh */ 748 1.6 eeh if ((p->p_flag & P_TRACED) && 749 1.6 eeh p->p_oppid != p->p_pptr->p_pid) { 750 1.6 eeh t = pfind(p->p_oppid); 751 1.6 eeh proc_reparent(p, t ? t : initproc); 752 1.6 eeh p->p_oppid = 0; 753 1.6 eeh p->p_flag &= ~(P_TRACED|P_WAITED|P_FSTRACE); 754 1.6 eeh psignal(p->p_pptr, SIGCHLD); 755 1.6 eeh wakeup((caddr_t)p->p_pptr); 756 1.6 eeh return (0); 757 1.6 eeh } 758 1.6 eeh p->p_xstat = 0; 759 1.6 eeh ruadd(&q->p_stats->p_cru, p->p_ru); 760 1.6 eeh pool_put(&rusage_pool, p->p_ru); 761 1.6 eeh 762 1.6 eeh /* 763 1.6 eeh * Finally finished with old proc entry. 764 1.6 eeh * Unlink it from its process group and free it. 765 1.6 eeh */ 766 1.6 eeh leavepgrp(p); 767 1.6 eeh 768 1.6 eeh LIST_REMOVE(p, p_list); /* off zombproc */ 769 1.6 eeh 770 1.6 eeh LIST_REMOVE(p, p_sibling); 771 1.6 eeh 772 1.6 eeh /* 773 1.6 eeh * Decrement the count of procs running with this uid. 774 1.6 eeh */ 775 1.6 eeh (void)chgproccnt(p->p_cred->p_ruid, -1); 776 1.6 eeh 777 1.6 eeh /* 778 1.6 eeh * Free up credentials. 779 1.6 eeh */ 780 1.6 eeh if (--p->p_cred->p_refcnt == 0) { 781 1.6 eeh crfree(p->p_cred->pc_ucred); 782 1.6 eeh pool_put(&pcred_pool, p->p_cred); 783 1.6 eeh } 784 1.6 eeh 785 1.6 eeh /* 786 1.6 eeh * Release reference to text vnode 787 1.6 eeh */ 788 1.6 eeh if (p->p_textvp) 789 1.6 eeh vrele(p->p_textvp); 790 1.6 eeh 791 1.6 eeh pool_put(&proc_pool, p); 792 1.6 eeh nprocs--; 793 1.6 eeh return (0); 794 1.6 eeh } 795 1.6 eeh if (p->p_stat == SSTOP && (p->p_flag & P_WAITED) == 0 && 796 1.6 eeh (p->p_flag & P_TRACED || SCARG(uap, options) & WUNTRACED)) { 797 1.6 eeh p->p_flag |= P_WAITED; 798 1.6 eeh retval[0] = p->p_pid; 799 1.6 eeh 800 1.6 eeh if (SCARG(uap, status)) { 801 1.6 eeh status = W_STOPCODE(p->p_xstat); 802 1.6 eeh error = copyout((caddr_t)&status, 803 1.6 eeh (caddr_t)(u_long)SCARG(uap, status), 804 1.6 eeh sizeof(status)); 805 1.6 eeh } else 806 1.6 eeh error = 0; 807 1.6 eeh return (error); 808 1.6 eeh } 809 1.6 eeh } 810 1.6 eeh if (nfound == 0) 811 1.6 eeh return (ECHILD); 812 1.6 eeh if (SCARG(uap, options) & WNOHANG) { 813 1.6 eeh retval[0] = 0; 814 1.6 eeh return (0); 815 1.5 eeh } 816 1.6 eeh if ((error = tsleep((caddr_t)q, PWAIT | PCATCH, "wait", 0)) != 0) 817 1.6 eeh return (error); 818 1.6 eeh goto loop; 819 1.1 mrg } 820 1.1 mrg 821 1.1 mrg int 822 1.19 eeh netbsd32_link(p, v, retval) 823 1.1 mrg struct proc *p; 824 1.1 mrg void *v; 825 1.1 mrg register_t *retval; 826 1.1 mrg { 827 1.19 eeh struct netbsd32_link_args /* { 828 1.10 mrg syscallarg(const netbsd32_charp) path; 829 1.10 mrg syscallarg(const netbsd32_charp) link; 830 1.1 mrg } */ *uap = v; 831 1.1 mrg struct sys_link_args ua; 832 1.1 mrg 833 1.11 mrg NETBSD32TOP_UAP(path, const char); 834 1.11 mrg NETBSD32TOP_UAP(link, const char); 835 1.1 mrg return (sys_link(p, &ua, retval)); 836 1.1 mrg } 837 1.1 mrg 838 1.1 mrg int 839 1.19 eeh netbsd32_unlink(p, v, retval) 840 1.1 mrg struct proc *p; 841 1.1 mrg void *v; 842 1.1 mrg register_t *retval; 843 1.1 mrg { 844 1.19 eeh struct netbsd32_unlink_args /* { 845 1.10 mrg syscallarg(const netbsd32_charp) path; 846 1.1 mrg } */ *uap = v; 847 1.1 mrg struct sys_unlink_args ua; 848 1.1 mrg 849 1.11 mrg NETBSD32TOP_UAP(path, const char); 850 1.1 mrg 851 1.1 mrg return (sys_unlink(p, &ua, retval)); 852 1.1 mrg } 853 1.1 mrg 854 1.1 mrg int 855 1.19 eeh netbsd32_chdir(p, v, retval) 856 1.1 mrg struct proc *p; 857 1.1 mrg void *v; 858 1.1 mrg register_t *retval; 859 1.1 mrg { 860 1.19 eeh struct netbsd32_chdir_args /* { 861 1.10 mrg syscallarg(const netbsd32_charp) path; 862 1.1 mrg } */ *uap = v; 863 1.1 mrg struct sys_chdir_args ua; 864 1.1 mrg 865 1.11 mrg NETBSD32TOP_UAP(path, const char); 866 1.1 mrg 867 1.1 mrg return (sys_chdir(p, &ua, retval)); 868 1.1 mrg } 869 1.1 mrg 870 1.1 mrg int 871 1.19 eeh netbsd32_fchdir(p, v, retval) 872 1.6 eeh struct proc *p; 873 1.6 eeh void *v; 874 1.6 eeh register_t *retval; 875 1.6 eeh { 876 1.19 eeh struct netbsd32_fchdir_args /* { 877 1.6 eeh syscallarg(int) fd; 878 1.6 eeh } */ *uap = v; 879 1.6 eeh struct sys_fchdir_args ua; 880 1.6 eeh 881 1.11 mrg NETBSD32TO64_UAP(fd); 882 1.6 eeh 883 1.6 eeh return (sys_fchdir(p, &ua, retval)); 884 1.6 eeh } 885 1.6 eeh 886 1.6 eeh int 887 1.19 eeh netbsd32_mknod(p, v, retval) 888 1.1 mrg struct proc *p; 889 1.1 mrg void *v; 890 1.1 mrg register_t *retval; 891 1.1 mrg { 892 1.19 eeh struct netbsd32_mknod_args /* { 893 1.10 mrg syscallarg(const netbsd32_charp) path; 894 1.1 mrg syscallarg(mode_t) mode; 895 1.1 mrg syscallarg(dev_t) dev; 896 1.1 mrg } */ *uap = v; 897 1.1 mrg struct sys_mknod_args ua; 898 1.1 mrg 899 1.11 mrg NETBSD32TOP_UAP(path, const char); 900 1.11 mrg NETBSD32TO64_UAP(dev); 901 1.11 mrg NETBSD32TO64_UAP(mode); 902 1.1 mrg 903 1.1 mrg return (sys_mknod(p, &ua, retval)); 904 1.1 mrg } 905 1.1 mrg 906 1.1 mrg int 907 1.19 eeh netbsd32_chmod(p, v, retval) 908 1.1 mrg struct proc *p; 909 1.1 mrg void *v; 910 1.1 mrg register_t *retval; 911 1.1 mrg { 912 1.19 eeh struct netbsd32_chmod_args /* { 913 1.10 mrg syscallarg(const netbsd32_charp) path; 914 1.1 mrg syscallarg(mode_t) mode; 915 1.1 mrg } */ *uap = v; 916 1.1 mrg struct sys_chmod_args ua; 917 1.1 mrg 918 1.11 mrg NETBSD32TOP_UAP(path, const char); 919 1.11 mrg NETBSD32TO64_UAP(mode); 920 1.1 mrg 921 1.1 mrg return (sys_chmod(p, &ua, retval)); 922 1.1 mrg } 923 1.1 mrg 924 1.1 mrg int 925 1.19 eeh netbsd32_chown(p, v, retval) 926 1.1 mrg struct proc *p; 927 1.1 mrg void *v; 928 1.1 mrg register_t *retval; 929 1.1 mrg { 930 1.19 eeh struct netbsd32_chown_args /* { 931 1.10 mrg syscallarg(const netbsd32_charp) path; 932 1.1 mrg syscallarg(uid_t) uid; 933 1.1 mrg syscallarg(gid_t) gid; 934 1.1 mrg } */ *uap = v; 935 1.1 mrg struct sys_chown_args ua; 936 1.1 mrg 937 1.11 mrg NETBSD32TOP_UAP(path, const char); 938 1.11 mrg NETBSD32TO64_UAP(uid); 939 1.11 mrg NETBSD32TO64_UAP(gid); 940 1.1 mrg 941 1.1 mrg return (sys_chown(p, &ua, retval)); 942 1.1 mrg } 943 1.1 mrg 944 1.1 mrg int 945 1.19 eeh netbsd32_break(p, v, retval) 946 1.1 mrg struct proc *p; 947 1.1 mrg void *v; 948 1.1 mrg register_t *retval; 949 1.1 mrg { 950 1.19 eeh struct netbsd32_break_args /* { 951 1.10 mrg syscallarg(netbsd32_charp) nsize; 952 1.1 mrg } */ *uap = v; 953 1.1 mrg struct sys_obreak_args ua; 954 1.1 mrg 955 1.1 mrg SCARG(&ua, nsize) = (char *)(u_long)SCARG(uap, nsize); 956 1.11 mrg NETBSD32TOP_UAP(nsize, char); 957 1.1 mrg return (sys_obreak(p, &ua, retval)); 958 1.1 mrg } 959 1.1 mrg 960 1.1 mrg int 961 1.19 eeh netbsd32_getfsstat(p, v, retval) 962 1.1 mrg struct proc *p; 963 1.1 mrg void *v; 964 1.1 mrg register_t *retval; 965 1.1 mrg { 966 1.19 eeh struct netbsd32_getfsstat_args /* { 967 1.10 mrg syscallarg(netbsd32_statfsp_t) buf; 968 1.10 mrg syscallarg(netbsd32_long) bufsize; 969 1.1 mrg syscallarg(int) flags; 970 1.1 mrg } */ *uap = v; 971 1.19.2.1 bouyer struct mount *mp, *nmp; 972 1.19.2.1 bouyer struct statfs *sp; 973 1.19.2.1 bouyer struct netbsd32_statfs sb32; 974 1.19.2.1 bouyer caddr_t sfsp; 975 1.19.2.1 bouyer long count, maxcount, error; 976 1.19.2.1 bouyer 977 1.19.2.1 bouyer maxcount = SCARG(uap, bufsize) / sizeof(struct netbsd32_statfs); 978 1.19.2.1 bouyer sfsp = (caddr_t)(u_long)SCARG(uap, buf); 979 1.19.2.1 bouyer simple_lock(&mountlist_slock); 980 1.19.2.1 bouyer count = 0; 981 1.19.2.1 bouyer for (mp = mountlist.cqh_first; mp != (void *)&mountlist; mp = nmp) { 982 1.19.2.1 bouyer if (vfs_busy(mp, LK_NOWAIT, &mountlist_slock)) { 983 1.19.2.1 bouyer nmp = mp->mnt_list.cqe_next; 984 1.19.2.1 bouyer continue; 985 1.19.2.1 bouyer } 986 1.19.2.1 bouyer if (sfsp && count < maxcount) { 987 1.19.2.1 bouyer sp = &mp->mnt_stat; 988 1.19.2.1 bouyer /* 989 1.19.2.1 bouyer * If MNT_NOWAIT or MNT_LAZY is specified, do not 990 1.19.2.1 bouyer * refresh the fsstat cache. MNT_WAIT or MNT_LAXY 991 1.19.2.1 bouyer * overrides MNT_NOWAIT. 992 1.19.2.1 bouyer */ 993 1.19.2.1 bouyer if (SCARG(uap, flags) != MNT_NOWAIT && 994 1.19.2.1 bouyer SCARG(uap, flags) != MNT_LAZY && 995 1.19.2.1 bouyer (SCARG(uap, flags) == MNT_WAIT || 996 1.19.2.1 bouyer SCARG(uap, flags) == 0) && 997 1.19.2.1 bouyer (error = VFS_STATFS(mp, sp, p)) != 0) { 998 1.19.2.1 bouyer simple_lock(&mountlist_slock); 999 1.19.2.1 bouyer nmp = mp->mnt_list.cqe_next; 1000 1.19.2.1 bouyer vfs_unbusy(mp); 1001 1.19.2.1 bouyer continue; 1002 1.19.2.1 bouyer } 1003 1.19.2.1 bouyer sp->f_flags = mp->mnt_flag & MNT_VISFLAGMASK; 1004 1.19.2.1 bouyer sp->f_oflags = sp->f_flags & 0xffff; 1005 1.19.2.1 bouyer netbsd32_from_statfs(sp, &sb32); 1006 1.19.2.1 bouyer error = copyout(&sb32, sfsp, sizeof(sb32)); 1007 1.19.2.1 bouyer if (error) { 1008 1.19.2.1 bouyer vfs_unbusy(mp); 1009 1.19.2.1 bouyer return (error); 1010 1.19.2.1 bouyer } 1011 1.19.2.1 bouyer sfsp += sizeof(sb32); 1012 1.19.2.1 bouyer } 1013 1.19.2.1 bouyer count++; 1014 1.19.2.1 bouyer simple_lock(&mountlist_slock); 1015 1.19.2.1 bouyer nmp = mp->mnt_list.cqe_next; 1016 1.19.2.1 bouyer vfs_unbusy(mp); 1017 1.19.2.1 bouyer } 1018 1.19.2.1 bouyer simple_unlock(&mountlist_slock); 1019 1.19.2.1 bouyer if (sfsp && count > maxcount) 1020 1.19.2.1 bouyer *retval = maxcount; 1021 1.1 mrg else 1022 1.19.2.1 bouyer *retval = count; 1023 1.1 mrg return (0); 1024 1.1 mrg } 1025 1.1 mrg 1026 1.1 mrg int 1027 1.19 eeh netbsd32_mount(p, v, retval) 1028 1.1 mrg struct proc *p; 1029 1.1 mrg void *v; 1030 1.1 mrg register_t *retval; 1031 1.1 mrg { 1032 1.19 eeh struct netbsd32_mount_args /* { 1033 1.10 mrg syscallarg(const netbsd32_charp) type; 1034 1.10 mrg syscallarg(const netbsd32_charp) path; 1035 1.1 mrg syscallarg(int) flags; 1036 1.10 mrg syscallarg(netbsd32_voidp) data; 1037 1.1 mrg } */ *uap = v; 1038 1.1 mrg struct sys_mount_args ua; 1039 1.1 mrg 1040 1.11 mrg NETBSD32TOP_UAP(type, const char); 1041 1.11 mrg NETBSD32TOP_UAP(path, const char); 1042 1.11 mrg NETBSD32TO64_UAP(flags); 1043 1.11 mrg NETBSD32TOP_UAP(data, void); 1044 1.1 mrg return (sys_mount(p, &ua, retval)); 1045 1.1 mrg } 1046 1.1 mrg 1047 1.1 mrg int 1048 1.19 eeh netbsd32_unmount(p, v, retval) 1049 1.1 mrg struct proc *p; 1050 1.1 mrg void *v; 1051 1.1 mrg register_t *retval; 1052 1.1 mrg { 1053 1.19 eeh struct netbsd32_unmount_args /* { 1054 1.10 mrg syscallarg(const netbsd32_charp) path; 1055 1.1 mrg syscallarg(int) flags; 1056 1.1 mrg } */ *uap = v; 1057 1.1 mrg struct sys_unmount_args ua; 1058 1.1 mrg 1059 1.11 mrg NETBSD32TOP_UAP(path, const char); 1060 1.11 mrg NETBSD32TO64_UAP(flags); 1061 1.1 mrg return (sys_unmount(p, &ua, retval)); 1062 1.1 mrg } 1063 1.1 mrg 1064 1.1 mrg int 1065 1.19 eeh netbsd32_setuid(p, v, retval) 1066 1.6 eeh struct proc *p; 1067 1.6 eeh void *v; 1068 1.6 eeh register_t *retval; 1069 1.6 eeh { 1070 1.19 eeh struct netbsd32_setuid_args /* { 1071 1.6 eeh syscallarg(uid_t) uid; 1072 1.6 eeh } */ *uap = v; 1073 1.6 eeh struct sys_setuid_args ua; 1074 1.6 eeh 1075 1.11 mrg NETBSD32TO64_UAP(uid); 1076 1.6 eeh return (sys_setuid(p, &ua, retval)); 1077 1.6 eeh } 1078 1.6 eeh 1079 1.6 eeh int 1080 1.19 eeh netbsd32_ptrace(p, v, retval) 1081 1.1 mrg struct proc *p; 1082 1.1 mrg void *v; 1083 1.1 mrg register_t *retval; 1084 1.1 mrg { 1085 1.19 eeh struct netbsd32_ptrace_args /* { 1086 1.1 mrg syscallarg(int) req; 1087 1.1 mrg syscallarg(pid_t) pid; 1088 1.10 mrg syscallarg(netbsd32_caddr_t) addr; 1089 1.1 mrg syscallarg(int) data; 1090 1.1 mrg } */ *uap = v; 1091 1.1 mrg struct sys_ptrace_args ua; 1092 1.1 mrg 1093 1.11 mrg NETBSD32TO64_UAP(req); 1094 1.11 mrg NETBSD32TO64_UAP(pid); 1095 1.11 mrg NETBSD32TOX64_UAP(addr, caddr_t); 1096 1.11 mrg NETBSD32TO64_UAP(data); 1097 1.1 mrg return (sys_ptrace(p, &ua, retval)); 1098 1.1 mrg } 1099 1.1 mrg 1100 1.1 mrg int 1101 1.19 eeh netbsd32_recvmsg(p, v, retval) 1102 1.1 mrg struct proc *p; 1103 1.1 mrg void *v; 1104 1.1 mrg register_t *retval; 1105 1.1 mrg { 1106 1.19 eeh struct netbsd32_recvmsg_args /* { 1107 1.1 mrg syscallarg(int) s; 1108 1.10 mrg syscallarg(netbsd32_msghdrp_t) msg; 1109 1.1 mrg syscallarg(int) flags; 1110 1.1 mrg } */ *uap = v; 1111 1.10 mrg struct netbsd32_msghdr msg; 1112 1.6 eeh struct iovec aiov[UIO_SMALLIOV], *uiov, *iov; 1113 1.19.2.1 bouyer int error; 1114 1.6 eeh 1115 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, msg), (caddr_t)&msg, 1116 1.6 eeh sizeof(msg)); 1117 1.10 mrg /* netbsd32_msghdr needs the iov pre-allocated */ 1118 1.6 eeh if (error) 1119 1.6 eeh return (error); 1120 1.6 eeh if ((u_int)msg.msg_iovlen > UIO_SMALLIOV) { 1121 1.6 eeh if ((u_int)msg.msg_iovlen > IOV_MAX) 1122 1.6 eeh return (EMSGSIZE); 1123 1.6 eeh MALLOC(iov, struct iovec *, 1124 1.6 eeh sizeof(struct iovec) * (u_int)msg.msg_iovlen, M_IOV, 1125 1.6 eeh M_WAITOK); 1126 1.6 eeh } else if ((u_int)msg.msg_iovlen > 0) 1127 1.6 eeh iov = aiov; 1128 1.6 eeh else 1129 1.6 eeh return (EMSGSIZE); 1130 1.6 eeh #ifdef COMPAT_OLDSOCK 1131 1.6 eeh msg.msg_flags = SCARG(uap, flags) &~ MSG_COMPAT; 1132 1.6 eeh #else 1133 1.6 eeh msg.msg_flags = SCARG(uap, flags); 1134 1.6 eeh #endif 1135 1.6 eeh uiov = (struct iovec *)(u_long)msg.msg_iov; 1136 1.10 mrg error = netbsd32_to_iovecin((struct netbsd32_iovec *)uiov, 1137 1.6 eeh iov, msg.msg_iovlen); 1138 1.6 eeh if (error) 1139 1.6 eeh goto done; 1140 1.6 eeh if ((error = recvit32(p, SCARG(uap, s), &msg, iov, (caddr_t)0, retval)) == 0) { 1141 1.6 eeh error = copyout((caddr_t)&msg, (caddr_t)(u_long)SCARG(uap, msg), 1142 1.6 eeh sizeof(msg)); 1143 1.6 eeh } 1144 1.6 eeh done: 1145 1.6 eeh if (iov != aiov) 1146 1.6 eeh FREE(iov, M_IOV); 1147 1.6 eeh return (error); 1148 1.6 eeh } 1149 1.1 mrg 1150 1.6 eeh int 1151 1.6 eeh recvit32(p, s, mp, iov, namelenp, retsize) 1152 1.6 eeh struct proc *p; 1153 1.6 eeh int s; 1154 1.10 mrg struct netbsd32_msghdr *mp; 1155 1.6 eeh struct iovec *iov; 1156 1.6 eeh caddr_t namelenp; 1157 1.6 eeh register_t *retsize; 1158 1.6 eeh { 1159 1.6 eeh struct file *fp; 1160 1.6 eeh struct uio auio; 1161 1.19.2.1 bouyer int i; 1162 1.6 eeh int len, error; 1163 1.6 eeh struct mbuf *from = 0, *control = 0; 1164 1.6 eeh struct socket *so; 1165 1.6 eeh #ifdef KTRACE 1166 1.6 eeh struct iovec *ktriov = NULL; 1167 1.6 eeh #endif 1168 1.6 eeh 1169 1.12 thorpej /* getsock() will use the descriptor for us */ 1170 1.6 eeh if ((error = getsock(p->p_fd, s, &fp)) != 0) 1171 1.6 eeh return (error); 1172 1.6 eeh auio.uio_iov = (struct iovec *)(u_long)mp->msg_iov; 1173 1.6 eeh auio.uio_iovcnt = mp->msg_iovlen; 1174 1.6 eeh auio.uio_segflg = UIO_USERSPACE; 1175 1.6 eeh auio.uio_rw = UIO_READ; 1176 1.6 eeh auio.uio_procp = p; 1177 1.6 eeh auio.uio_offset = 0; /* XXX */ 1178 1.6 eeh auio.uio_resid = 0; 1179 1.6 eeh for (i = 0; i < mp->msg_iovlen; i++, iov++) { 1180 1.6 eeh #if 0 1181 1.6 eeh /* cannot happen iov_len is unsigned */ 1182 1.12 thorpej if (iov->iov_len < 0) { 1183 1.12 thorpej error = EINVAL; 1184 1.12 thorpej goto out1; 1185 1.12 thorpej } 1186 1.6 eeh #endif 1187 1.6 eeh /* 1188 1.6 eeh * Reads return ssize_t because -1 is returned on error. 1189 1.6 eeh * Therefore we must restrict the length to SSIZE_MAX to 1190 1.6 eeh * avoid garbage return values. 1191 1.6 eeh */ 1192 1.6 eeh auio.uio_resid += iov->iov_len; 1193 1.12 thorpej if (iov->iov_len > SSIZE_MAX || auio.uio_resid > SSIZE_MAX) { 1194 1.12 thorpej error = EINVAL; 1195 1.12 thorpej goto out1; 1196 1.12 thorpej } 1197 1.6 eeh } 1198 1.6 eeh #ifdef KTRACE 1199 1.6 eeh if (KTRPOINT(p, KTR_GENIO)) { 1200 1.6 eeh int iovlen = auio.uio_iovcnt * sizeof(struct iovec); 1201 1.1 mrg 1202 1.6 eeh MALLOC(ktriov, struct iovec *, iovlen, M_TEMP, M_WAITOK); 1203 1.6 eeh memcpy((caddr_t)ktriov, (caddr_t)auio.uio_iov, iovlen); 1204 1.6 eeh } 1205 1.6 eeh #endif 1206 1.6 eeh len = auio.uio_resid; 1207 1.6 eeh so = (struct socket *)fp->f_data; 1208 1.6 eeh error = (*so->so_receive)(so, &from, &auio, NULL, 1209 1.6 eeh mp->msg_control ? &control : NULL, &mp->msg_flags); 1210 1.6 eeh if (error) { 1211 1.6 eeh if (auio.uio_resid != len && (error == ERESTART || 1212 1.6 eeh error == EINTR || error == EWOULDBLOCK)) 1213 1.6 eeh error = 0; 1214 1.6 eeh } 1215 1.6 eeh #ifdef KTRACE 1216 1.6 eeh if (ktriov != NULL) { 1217 1.6 eeh if (error == 0) 1218 1.19.2.1 bouyer ktrgenio(p, s, UIO_READ, ktriov, 1219 1.19.2.1 bouyer len - auio.uio_resid, error); 1220 1.6 eeh FREE(ktriov, M_TEMP); 1221 1.6 eeh } 1222 1.6 eeh #endif 1223 1.6 eeh if (error) 1224 1.6 eeh goto out; 1225 1.6 eeh *retsize = len - auio.uio_resid; 1226 1.6 eeh if (mp->msg_name) { 1227 1.6 eeh len = mp->msg_namelen; 1228 1.6 eeh if (len <= 0 || from == 0) 1229 1.6 eeh len = 0; 1230 1.6 eeh else { 1231 1.6 eeh #ifdef COMPAT_OLDSOCK 1232 1.6 eeh if (mp->msg_flags & MSG_COMPAT) 1233 1.6 eeh mtod(from, struct osockaddr *)->sa_family = 1234 1.6 eeh mtod(from, struct sockaddr *)->sa_family; 1235 1.6 eeh #endif 1236 1.6 eeh if (len > from->m_len) 1237 1.6 eeh len = from->m_len; 1238 1.6 eeh /* else if len < from->m_len ??? */ 1239 1.6 eeh error = copyout(mtod(from, caddr_t), 1240 1.6 eeh (caddr_t)(u_long)mp->msg_name, (unsigned)len); 1241 1.6 eeh if (error) 1242 1.6 eeh goto out; 1243 1.6 eeh } 1244 1.6 eeh mp->msg_namelen = len; 1245 1.6 eeh if (namelenp && 1246 1.6 eeh (error = copyout((caddr_t)&len, namelenp, sizeof(int)))) { 1247 1.6 eeh #ifdef COMPAT_OLDSOCK 1248 1.6 eeh if (mp->msg_flags & MSG_COMPAT) 1249 1.6 eeh error = 0; /* old recvfrom didn't check */ 1250 1.6 eeh else 1251 1.6 eeh #endif 1252 1.6 eeh goto out; 1253 1.6 eeh } 1254 1.6 eeh } 1255 1.6 eeh if (mp->msg_control) { 1256 1.6 eeh #ifdef COMPAT_OLDSOCK 1257 1.6 eeh /* 1258 1.6 eeh * We assume that old recvmsg calls won't receive access 1259 1.6 eeh * rights and other control info, esp. as control info 1260 1.6 eeh * is always optional and those options didn't exist in 4.3. 1261 1.6 eeh * If we receive rights, trim the cmsghdr; anything else 1262 1.6 eeh * is tossed. 1263 1.6 eeh */ 1264 1.6 eeh if (control && mp->msg_flags & MSG_COMPAT) { 1265 1.6 eeh if (mtod(control, struct cmsghdr *)->cmsg_level != 1266 1.6 eeh SOL_SOCKET || 1267 1.6 eeh mtod(control, struct cmsghdr *)->cmsg_type != 1268 1.6 eeh SCM_RIGHTS) { 1269 1.6 eeh mp->msg_controllen = 0; 1270 1.6 eeh goto out; 1271 1.6 eeh } 1272 1.6 eeh control->m_len -= sizeof(struct cmsghdr); 1273 1.6 eeh control->m_data += sizeof(struct cmsghdr); 1274 1.6 eeh } 1275 1.6 eeh #endif 1276 1.6 eeh len = mp->msg_controllen; 1277 1.6 eeh if (len <= 0 || control == 0) 1278 1.6 eeh len = 0; 1279 1.6 eeh else { 1280 1.6 eeh struct mbuf *m = control; 1281 1.6 eeh caddr_t p = (caddr_t)(u_long)mp->msg_control; 1282 1.6 eeh 1283 1.6 eeh do { 1284 1.6 eeh i = m->m_len; 1285 1.6 eeh if (len < i) { 1286 1.6 eeh mp->msg_flags |= MSG_CTRUNC; 1287 1.6 eeh i = len; 1288 1.6 eeh } 1289 1.6 eeh error = copyout(mtod(m, caddr_t), p, 1290 1.6 eeh (unsigned)i); 1291 1.6 eeh if (m->m_next) 1292 1.6 eeh i = ALIGN(i); 1293 1.6 eeh p += i; 1294 1.6 eeh len -= i; 1295 1.6 eeh if (error != 0 || len <= 0) 1296 1.6 eeh break; 1297 1.6 eeh } while ((m = m->m_next) != NULL); 1298 1.6 eeh len = p - (caddr_t)(u_long)mp->msg_control; 1299 1.6 eeh } 1300 1.6 eeh mp->msg_controllen = len; 1301 1.6 eeh } 1302 1.12 thorpej out: 1303 1.6 eeh if (from) 1304 1.6 eeh m_freem(from); 1305 1.6 eeh if (control) 1306 1.6 eeh m_freem(control); 1307 1.12 thorpej out1: 1308 1.19 eeh FILE_UNUSE(fp, p); 1309 1.1 mrg return (error); 1310 1.1 mrg } 1311 1.1 mrg 1312 1.6 eeh 1313 1.1 mrg int 1314 1.19 eeh netbsd32_sendmsg(p, v, retval) 1315 1.1 mrg struct proc *p; 1316 1.1 mrg void *v; 1317 1.1 mrg register_t *retval; 1318 1.1 mrg { 1319 1.19 eeh struct netbsd32_sendmsg_args /* { 1320 1.1 mrg syscallarg(int) s; 1321 1.10 mrg syscallarg(const netbsd32_msghdrp_t) msg; 1322 1.1 mrg syscallarg(int) flags; 1323 1.1 mrg } */ *uap = v; 1324 1.6 eeh struct msghdr msg; 1325 1.10 mrg struct netbsd32_msghdr msg32; 1326 1.6 eeh struct iovec aiov[UIO_SMALLIOV], *iov; 1327 1.1 mrg int error; 1328 1.1 mrg 1329 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, msg), 1330 1.6 eeh (caddr_t)&msg32, sizeof(msg32)); 1331 1.6 eeh if (error) 1332 1.6 eeh return (error); 1333 1.10 mrg netbsd32_to_msghdr(&msg32, &msg); 1334 1.6 eeh if ((u_int)msg.msg_iovlen > UIO_SMALLIOV) { 1335 1.6 eeh if ((u_int)msg.msg_iovlen > IOV_MAX) 1336 1.6 eeh return (EMSGSIZE); 1337 1.6 eeh MALLOC(iov, struct iovec *, 1338 1.6 eeh sizeof(struct iovec) * (u_int)msg.msg_iovlen, M_IOV, 1339 1.6 eeh M_WAITOK); 1340 1.6 eeh } else if ((u_int)msg.msg_iovlen > 0) 1341 1.6 eeh iov = aiov; 1342 1.6 eeh else 1343 1.6 eeh return (EMSGSIZE); 1344 1.10 mrg error = netbsd32_to_iovecin((struct netbsd32_iovec *)msg.msg_iov, 1345 1.6 eeh iov, msg.msg_iovlen); 1346 1.6 eeh if (error) 1347 1.6 eeh goto done; 1348 1.6 eeh msg.msg_iov = iov; 1349 1.6 eeh #ifdef COMPAT_OLDSOCK 1350 1.6 eeh msg.msg_flags = 0; 1351 1.6 eeh #endif 1352 1.6 eeh /* Luckily we can use this directly */ 1353 1.6 eeh error = sendit(p, SCARG(uap, s), &msg, SCARG(uap, flags), retval); 1354 1.6 eeh done: 1355 1.6 eeh if (iov != aiov) 1356 1.6 eeh FREE(iov, M_IOV); 1357 1.1 mrg return (error); 1358 1.1 mrg } 1359 1.1 mrg 1360 1.1 mrg int 1361 1.19 eeh netbsd32_recvfrom(p, v, retval) 1362 1.1 mrg struct proc *p; 1363 1.1 mrg void *v; 1364 1.1 mrg register_t *retval; 1365 1.1 mrg { 1366 1.19 eeh struct netbsd32_recvfrom_args /* { 1367 1.1 mrg syscallarg(int) s; 1368 1.10 mrg syscallarg(netbsd32_voidp) buf; 1369 1.10 mrg syscallarg(netbsd32_size_t) len; 1370 1.1 mrg syscallarg(int) flags; 1371 1.10 mrg syscallarg(netbsd32_sockaddrp_t) from; 1372 1.10 mrg syscallarg(netbsd32_intp) fromlenaddr; 1373 1.1 mrg } */ *uap = v; 1374 1.10 mrg struct netbsd32_msghdr msg; 1375 1.6 eeh struct iovec aiov; 1376 1.1 mrg int error; 1377 1.1 mrg 1378 1.6 eeh if (SCARG(uap, fromlenaddr)) { 1379 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, fromlenaddr), 1380 1.6 eeh (caddr_t)&msg.msg_namelen, 1381 1.6 eeh sizeof(msg.msg_namelen)); 1382 1.6 eeh if (error) 1383 1.6 eeh return (error); 1384 1.6 eeh } else 1385 1.6 eeh msg.msg_namelen = 0; 1386 1.6 eeh msg.msg_name = SCARG(uap, from); 1387 1.6 eeh msg.msg_iov = NULL; /* We can't store a real pointer here */ 1388 1.6 eeh msg.msg_iovlen = 1; 1389 1.6 eeh aiov.iov_base = (caddr_t)(u_long)SCARG(uap, buf); 1390 1.6 eeh aiov.iov_len = (u_long)SCARG(uap, len); 1391 1.6 eeh msg.msg_control = 0; 1392 1.6 eeh msg.msg_flags = SCARG(uap, flags); 1393 1.6 eeh return (recvit32(p, SCARG(uap, s), &msg, &aiov, 1394 1.6 eeh (caddr_t)(u_long)SCARG(uap, fromlenaddr), retval)); 1395 1.1 mrg } 1396 1.1 mrg 1397 1.1 mrg int 1398 1.19 eeh netbsd32_sendto(p, v, retval) 1399 1.1 mrg struct proc *p; 1400 1.1 mrg void *v; 1401 1.1 mrg register_t *retval; 1402 1.1 mrg { 1403 1.19 eeh struct netbsd32_sendto_args /* { 1404 1.1 mrg syscallarg(int) s; 1405 1.10 mrg syscallarg(const netbsd32_voidp) buf; 1406 1.10 mrg syscallarg(netbsd32_size_t) len; 1407 1.1 mrg syscallarg(int) flags; 1408 1.10 mrg syscallarg(const netbsd32_sockaddrp_t) to; 1409 1.1 mrg syscallarg(int) tolen; 1410 1.1 mrg } */ *uap = v; 1411 1.6 eeh struct msghdr msg; 1412 1.6 eeh struct iovec aiov; 1413 1.1 mrg 1414 1.6 eeh msg.msg_name = (caddr_t)(u_long)SCARG(uap, to); /* XXX kills const */ 1415 1.6 eeh msg.msg_namelen = SCARG(uap, tolen); 1416 1.6 eeh msg.msg_iov = &aiov; 1417 1.6 eeh msg.msg_iovlen = 1; 1418 1.6 eeh msg.msg_control = 0; 1419 1.6 eeh #ifdef COMPAT_OLDSOCK 1420 1.6 eeh msg.msg_flags = 0; 1421 1.6 eeh #endif 1422 1.6 eeh aiov.iov_base = (char *)(u_long)SCARG(uap, buf); /* XXX kills const */ 1423 1.6 eeh aiov.iov_len = SCARG(uap, len); 1424 1.6 eeh return (sendit(p, SCARG(uap, s), &msg, SCARG(uap, flags), retval)); 1425 1.1 mrg } 1426 1.1 mrg 1427 1.1 mrg int 1428 1.19 eeh netbsd32_accept(p, v, retval) 1429 1.1 mrg struct proc *p; 1430 1.1 mrg void *v; 1431 1.1 mrg register_t *retval; 1432 1.1 mrg { 1433 1.19 eeh struct netbsd32_accept_args /* { 1434 1.1 mrg syscallarg(int) s; 1435 1.10 mrg syscallarg(netbsd32_sockaddrp_t) name; 1436 1.10 mrg syscallarg(netbsd32_intp) anamelen; 1437 1.1 mrg } */ *uap = v; 1438 1.1 mrg struct sys_accept_args ua; 1439 1.1 mrg 1440 1.11 mrg NETBSD32TO64_UAP(s); 1441 1.11 mrg NETBSD32TOP_UAP(name, struct sockaddr); 1442 1.11 mrg NETBSD32TOP_UAP(anamelen, int); 1443 1.1 mrg return (sys_accept(p, &ua, retval)); 1444 1.1 mrg } 1445 1.1 mrg 1446 1.1 mrg int 1447 1.19 eeh netbsd32_getpeername(p, v, retval) 1448 1.1 mrg struct proc *p; 1449 1.1 mrg void *v; 1450 1.1 mrg register_t *retval; 1451 1.1 mrg { 1452 1.19 eeh struct netbsd32_getpeername_args /* { 1453 1.1 mrg syscallarg(int) fdes; 1454 1.10 mrg syscallarg(netbsd32_sockaddrp_t) asa; 1455 1.10 mrg syscallarg(netbsd32_intp) alen; 1456 1.1 mrg } */ *uap = v; 1457 1.1 mrg struct sys_getpeername_args ua; 1458 1.1 mrg 1459 1.11 mrg NETBSD32TO64_UAP(fdes); 1460 1.11 mrg NETBSD32TOP_UAP(asa, struct sockaddr); 1461 1.11 mrg NETBSD32TOP_UAP(alen, int); 1462 1.6 eeh /* NB: do the protocol specific sockaddrs need to be converted? */ 1463 1.1 mrg return (sys_getpeername(p, &ua, retval)); 1464 1.1 mrg } 1465 1.1 mrg 1466 1.1 mrg int 1467 1.19 eeh netbsd32_getsockname(p, v, retval) 1468 1.1 mrg struct proc *p; 1469 1.1 mrg void *v; 1470 1.1 mrg register_t *retval; 1471 1.1 mrg { 1472 1.19 eeh struct netbsd32_getsockname_args /* { 1473 1.1 mrg syscallarg(int) fdes; 1474 1.10 mrg syscallarg(netbsd32_sockaddrp_t) asa; 1475 1.10 mrg syscallarg(netbsd32_intp) alen; 1476 1.1 mrg } */ *uap = v; 1477 1.1 mrg struct sys_getsockname_args ua; 1478 1.1 mrg 1479 1.11 mrg NETBSD32TO64_UAP(fdes); 1480 1.11 mrg NETBSD32TOP_UAP(asa, struct sockaddr); 1481 1.11 mrg NETBSD32TOP_UAP(alen, int); 1482 1.1 mrg return (sys_getsockname(p, &ua, retval)); 1483 1.1 mrg } 1484 1.1 mrg 1485 1.1 mrg int 1486 1.19 eeh netbsd32_access(p, v, retval) 1487 1.1 mrg struct proc *p; 1488 1.1 mrg void *v; 1489 1.1 mrg register_t *retval; 1490 1.1 mrg { 1491 1.19 eeh struct netbsd32_access_args /* { 1492 1.10 mrg syscallarg(const netbsd32_charp) path; 1493 1.1 mrg syscallarg(int) flags; 1494 1.1 mrg } */ *uap = v; 1495 1.1 mrg struct sys_access_args ua; 1496 1.1 mrg caddr_t sg; 1497 1.1 mrg 1498 1.11 mrg NETBSD32TOP_UAP(path, const char); 1499 1.11 mrg NETBSD32TO64_UAP(flags); 1500 1.1 mrg sg = stackgap_init(p->p_emul); 1501 1.19.2.2 bouyer CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path)); 1502 1.1 mrg 1503 1.1 mrg return (sys_access(p, &ua, retval)); 1504 1.1 mrg } 1505 1.1 mrg 1506 1.1 mrg int 1507 1.19 eeh netbsd32_chflags(p, v, retval) 1508 1.1 mrg struct proc *p; 1509 1.1 mrg void *v; 1510 1.1 mrg register_t *retval; 1511 1.1 mrg { 1512 1.19 eeh struct netbsd32_chflags_args /* { 1513 1.10 mrg syscallarg(const netbsd32_charp) path; 1514 1.10 mrg syscallarg(netbsd32_u_long) flags; 1515 1.1 mrg } */ *uap = v; 1516 1.1 mrg struct sys_chflags_args ua; 1517 1.1 mrg 1518 1.11 mrg NETBSD32TOP_UAP(path, const char); 1519 1.11 mrg NETBSD32TO64_UAP(flags); 1520 1.1 mrg 1521 1.1 mrg return (sys_chflags(p, &ua, retval)); 1522 1.1 mrg } 1523 1.1 mrg 1524 1.1 mrg int 1525 1.19 eeh netbsd32_fchflags(p, v, retval) 1526 1.1 mrg struct proc *p; 1527 1.1 mrg void *v; 1528 1.1 mrg register_t *retval; 1529 1.1 mrg { 1530 1.19 eeh struct netbsd32_fchflags_args /* { 1531 1.1 mrg syscallarg(int) fd; 1532 1.10 mrg syscallarg(netbsd32_u_long) flags; 1533 1.1 mrg } */ *uap = v; 1534 1.1 mrg struct sys_fchflags_args ua; 1535 1.1 mrg 1536 1.11 mrg NETBSD32TO64_UAP(fd); 1537 1.11 mrg NETBSD32TO64_UAP(flags); 1538 1.1 mrg 1539 1.1 mrg return (sys_fchflags(p, &ua, retval)); 1540 1.1 mrg } 1541 1.1 mrg 1542 1.1 mrg int 1543 1.19 eeh netbsd32_kill(p, v, retval) 1544 1.6 eeh struct proc *p; 1545 1.6 eeh void *v; 1546 1.6 eeh register_t *retval; 1547 1.6 eeh { 1548 1.19 eeh struct netbsd32_kill_args /* { 1549 1.6 eeh syscallarg(int) pid; 1550 1.6 eeh syscallarg(int) signum; 1551 1.6 eeh } */ *uap = v; 1552 1.6 eeh struct sys_kill_args ua; 1553 1.6 eeh 1554 1.11 mrg NETBSD32TO64_UAP(pid); 1555 1.11 mrg NETBSD32TO64_UAP(signum); 1556 1.6 eeh 1557 1.6 eeh return (sys_kill(p, &ua, retval)); 1558 1.6 eeh } 1559 1.6 eeh 1560 1.6 eeh int 1561 1.19 eeh netbsd32_dup(p, v, retval) 1562 1.6 eeh struct proc *p; 1563 1.6 eeh void *v; 1564 1.6 eeh register_t *retval; 1565 1.6 eeh { 1566 1.19 eeh struct netbsd32_dup_args /* { 1567 1.6 eeh syscallarg(int) fd; 1568 1.6 eeh } */ *uap = v; 1569 1.6 eeh struct sys_dup_args ua; 1570 1.6 eeh 1571 1.11 mrg NETBSD32TO64_UAP(fd); 1572 1.6 eeh 1573 1.6 eeh return (sys_dup(p, &ua, retval)); 1574 1.6 eeh } 1575 1.6 eeh 1576 1.6 eeh int 1577 1.19 eeh netbsd32_profil(p, v, retval) 1578 1.1 mrg struct proc *p; 1579 1.1 mrg void *v; 1580 1.1 mrg register_t *retval; 1581 1.1 mrg { 1582 1.19 eeh struct netbsd32_profil_args /* { 1583 1.10 mrg syscallarg(netbsd32_caddr_t) samples; 1584 1.10 mrg syscallarg(netbsd32_size_t) size; 1585 1.10 mrg syscallarg(netbsd32_u_long) offset; 1586 1.1 mrg syscallarg(u_int) scale; 1587 1.1 mrg } */ *uap = v; 1588 1.1 mrg struct sys_profil_args ua; 1589 1.1 mrg 1590 1.11 mrg NETBSD32TOX64_UAP(samples, caddr_t); 1591 1.11 mrg NETBSD32TOX_UAP(size, size_t); 1592 1.11 mrg NETBSD32TOX_UAP(offset, u_long); 1593 1.11 mrg NETBSD32TO64_UAP(scale); 1594 1.1 mrg return (sys_profil(p, &ua, retval)); 1595 1.1 mrg } 1596 1.1 mrg 1597 1.19.2.2 bouyer #ifdef KTRACE 1598 1.1 mrg int 1599 1.19 eeh netbsd32_ktrace(p, v, retval) 1600 1.1 mrg struct proc *p; 1601 1.1 mrg void *v; 1602 1.1 mrg register_t *retval; 1603 1.1 mrg { 1604 1.19 eeh struct netbsd32_ktrace_args /* { 1605 1.10 mrg syscallarg(const netbsd32_charp) fname; 1606 1.1 mrg syscallarg(int) ops; 1607 1.1 mrg syscallarg(int) facs; 1608 1.1 mrg syscallarg(int) pid; 1609 1.1 mrg } */ *uap = v; 1610 1.1 mrg struct sys_ktrace_args ua; 1611 1.1 mrg 1612 1.11 mrg NETBSD32TOP_UAP(fname, const char); 1613 1.11 mrg NETBSD32TO64_UAP(ops); 1614 1.11 mrg NETBSD32TO64_UAP(facs); 1615 1.11 mrg NETBSD32TO64_UAP(pid); 1616 1.1 mrg return (sys_ktrace(p, &ua, retval)); 1617 1.1 mrg } 1618 1.19.2.2 bouyer #endif /* KTRACE */ 1619 1.1 mrg 1620 1.1 mrg int 1621 1.19 eeh netbsd32_sigaction(p, v, retval) 1622 1.1 mrg struct proc *p; 1623 1.1 mrg void *v; 1624 1.1 mrg register_t *retval; 1625 1.1 mrg { 1626 1.19 eeh struct netbsd32_sigaction_args /* { 1627 1.1 mrg syscallarg(int) signum; 1628 1.10 mrg syscallarg(const netbsd32_sigactionp_t) nsa; 1629 1.10 mrg syscallarg(netbsd32_sigactionp_t) osa; 1630 1.1 mrg } */ *uap = v; 1631 1.1 mrg struct sigaction nsa, osa; 1632 1.10 mrg struct netbsd32_sigaction *sa32p, sa32; 1633 1.1 mrg int error; 1634 1.1 mrg 1635 1.1 mrg if (SCARG(uap, nsa)) { 1636 1.10 mrg sa32p = (struct netbsd32_sigaction *)(u_long)SCARG(uap, nsa); 1637 1.5 eeh if (copyin(sa32p, &sa32, sizeof(sa32))) 1638 1.5 eeh return EFAULT; 1639 1.5 eeh nsa.sa_handler = (void *)(u_long)sa32.sa_handler; 1640 1.5 eeh nsa.sa_mask = sa32.sa_mask; 1641 1.5 eeh nsa.sa_flags = sa32.sa_flags; 1642 1.6 eeh } 1643 1.6 eeh error = sigaction1(p, SCARG(uap, signum), 1644 1.6 eeh SCARG(uap, nsa) ? &nsa : 0, 1645 1.6 eeh SCARG(uap, osa) ? &osa : 0); 1646 1.6 eeh 1647 1.1 mrg if (error) 1648 1.1 mrg return (error); 1649 1.1 mrg 1650 1.1 mrg if (SCARG(uap, osa)) { 1651 1.10 mrg sa32.sa_handler = (netbsd32_sigactionp_t)(u_long)osa.sa_handler; 1652 1.5 eeh sa32.sa_mask = osa.sa_mask; 1653 1.5 eeh sa32.sa_flags = osa.sa_flags; 1654 1.10 mrg sa32p = (struct netbsd32_sigaction *)(u_long)SCARG(uap, osa); 1655 1.5 eeh if (copyout(&sa32, sa32p, sizeof(sa32))) 1656 1.5 eeh return EFAULT; 1657 1.1 mrg } 1658 1.1 mrg 1659 1.1 mrg return (0); 1660 1.1 mrg } 1661 1.1 mrg 1662 1.1 mrg int 1663 1.19 eeh netbsd32___getlogin(p, v, retval) 1664 1.1 mrg struct proc *p; 1665 1.1 mrg void *v; 1666 1.1 mrg register_t *retval; 1667 1.1 mrg { 1668 1.19 eeh struct netbsd32___getlogin_args /* { 1669 1.10 mrg syscallarg(netbsd32_charp) namebuf; 1670 1.1 mrg syscallarg(u_int) namelen; 1671 1.1 mrg } */ *uap = v; 1672 1.1 mrg struct sys___getlogin_args ua; 1673 1.1 mrg 1674 1.11 mrg NETBSD32TOP_UAP(namebuf, char); 1675 1.11 mrg NETBSD32TO64_UAP(namelen); 1676 1.1 mrg return (sys___getlogin(p, &ua, retval)); 1677 1.1 mrg } 1678 1.1 mrg 1679 1.1 mrg int 1680 1.19 eeh netbsd32_setlogin(p, v, retval) 1681 1.1 mrg struct proc *p; 1682 1.1 mrg void *v; 1683 1.1 mrg register_t *retval; 1684 1.1 mrg { 1685 1.19 eeh struct netbsd32_setlogin_args /* { 1686 1.10 mrg syscallarg(const netbsd32_charp) namebuf; 1687 1.1 mrg } */ *uap = v; 1688 1.1 mrg struct sys_setlogin_args ua; 1689 1.1 mrg 1690 1.11 mrg NETBSD32TOP_UAP(namebuf, char); 1691 1.1 mrg return (sys_setlogin(p, &ua, retval)); 1692 1.1 mrg } 1693 1.1 mrg 1694 1.1 mrg int 1695 1.19 eeh netbsd32_acct(p, v, retval) 1696 1.1 mrg struct proc *p; 1697 1.1 mrg void *v; 1698 1.1 mrg register_t *retval; 1699 1.1 mrg { 1700 1.19 eeh struct netbsd32_acct_args /* { 1701 1.10 mrg syscallarg(const netbsd32_charp) path; 1702 1.1 mrg } */ *uap = v; 1703 1.1 mrg struct sys_acct_args ua; 1704 1.1 mrg 1705 1.11 mrg NETBSD32TOP_UAP(path, const char); 1706 1.1 mrg return (sys_acct(p, &ua, retval)); 1707 1.1 mrg } 1708 1.1 mrg 1709 1.1 mrg int 1710 1.19 eeh netbsd32_revoke(p, v, retval) 1711 1.1 mrg struct proc *p; 1712 1.1 mrg void *v; 1713 1.1 mrg register_t *retval; 1714 1.1 mrg { 1715 1.19 eeh struct netbsd32_revoke_args /* { 1716 1.10 mrg syscallarg(const netbsd32_charp) path; 1717 1.1 mrg } */ *uap = v; 1718 1.1 mrg struct sys_revoke_args ua; 1719 1.1 mrg caddr_t sg; 1720 1.1 mrg 1721 1.11 mrg NETBSD32TOP_UAP(path, const char); 1722 1.1 mrg sg = stackgap_init(p->p_emul); 1723 1.19.2.2 bouyer CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path)); 1724 1.1 mrg 1725 1.1 mrg return (sys_revoke(p, &ua, retval)); 1726 1.1 mrg } 1727 1.1 mrg 1728 1.1 mrg int 1729 1.19 eeh netbsd32_symlink(p, v, retval) 1730 1.1 mrg struct proc *p; 1731 1.1 mrg void *v; 1732 1.1 mrg register_t *retval; 1733 1.1 mrg { 1734 1.19 eeh struct netbsd32_symlink_args /* { 1735 1.10 mrg syscallarg(const netbsd32_charp) path; 1736 1.10 mrg syscallarg(const netbsd32_charp) link; 1737 1.1 mrg } */ *uap = v; 1738 1.1 mrg struct sys_symlink_args ua; 1739 1.1 mrg 1740 1.11 mrg NETBSD32TOP_UAP(path, const char); 1741 1.11 mrg NETBSD32TOP_UAP(link, const char); 1742 1.1 mrg 1743 1.1 mrg return (sys_symlink(p, &ua, retval)); 1744 1.1 mrg } 1745 1.1 mrg 1746 1.1 mrg int 1747 1.19 eeh netbsd32_readlink(p, v, retval) 1748 1.1 mrg struct proc *p; 1749 1.1 mrg void *v; 1750 1.1 mrg register_t *retval; 1751 1.1 mrg { 1752 1.19 eeh struct netbsd32_readlink_args /* { 1753 1.10 mrg syscallarg(const netbsd32_charp) path; 1754 1.10 mrg syscallarg(netbsd32_charp) buf; 1755 1.10 mrg syscallarg(netbsd32_size_t) count; 1756 1.1 mrg } */ *uap = v; 1757 1.1 mrg struct sys_readlink_args ua; 1758 1.1 mrg caddr_t sg; 1759 1.1 mrg 1760 1.11 mrg NETBSD32TOP_UAP(path, const char); 1761 1.11 mrg NETBSD32TOP_UAP(buf, char); 1762 1.11 mrg NETBSD32TOX_UAP(count, size_t); 1763 1.1 mrg sg = stackgap_init(p->p_emul); 1764 1.19.2.2 bouyer CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path)); 1765 1.1 mrg 1766 1.1 mrg return (sys_readlink(p, &ua, retval)); 1767 1.1 mrg } 1768 1.1 mrg 1769 1.19.2.1 bouyer /* 1770 1.19.2.1 bouyer * Need to completly reimplement this syscall due to argument copying. 1771 1.19.2.1 bouyer */ 1772 1.19.2.2 bouyer /* ARGSUSED */ 1773 1.1 mrg int 1774 1.19 eeh netbsd32_execve(p, v, retval) 1775 1.1 mrg struct proc *p; 1776 1.1 mrg void *v; 1777 1.1 mrg register_t *retval; 1778 1.1 mrg { 1779 1.19 eeh struct netbsd32_execve_args /* { 1780 1.10 mrg syscallarg(const netbsd32_charp) path; 1781 1.10 mrg syscallarg(netbsd32_charpp) argp; 1782 1.10 mrg syscallarg(netbsd32_charpp) envp; 1783 1.1 mrg } */ *uap = v; 1784 1.1 mrg struct sys_execve_args ua; 1785 1.1 mrg caddr_t sg; 1786 1.19.2.1 bouyer /* Function args */ 1787 1.19.2.1 bouyer int error, i; 1788 1.19.2.1 bouyer struct exec_package pack; 1789 1.19.2.1 bouyer struct nameidata nid; 1790 1.19.2.1 bouyer struct vattr attr; 1791 1.19.2.1 bouyer struct ucred *cred = p->p_ucred; 1792 1.19.2.1 bouyer char *argp; 1793 1.19.2.1 bouyer netbsd32_charp const *cpp; 1794 1.19.2.1 bouyer char *dp; 1795 1.19.2.1 bouyer netbsd32_charp sp; 1796 1.19.2.1 bouyer long argc, envc; 1797 1.19.2.1 bouyer size_t len; 1798 1.19.2.1 bouyer char *stack; 1799 1.19.2.1 bouyer struct ps_strings arginfo; 1800 1.19.2.1 bouyer struct vmspace *vm; 1801 1.19.2.1 bouyer char **tmpfap; 1802 1.19.2.1 bouyer int szsigcode; 1803 1.19.2.2 bouyer struct exec_vmcmd *base_vcp = NULL; 1804 1.1 mrg 1805 1.11 mrg NETBSD32TOP_UAP(path, const char); 1806 1.11 mrg NETBSD32TOP_UAP(argp, char *); 1807 1.11 mrg NETBSD32TOP_UAP(envp, char *); 1808 1.1 mrg sg = stackgap_init(p->p_emul); 1809 1.19.2.2 bouyer CHECK_ALT_EXIST(p, &sg, SCARG(&ua, path)); 1810 1.1 mrg 1811 1.19.2.1 bouyer /* 1812 1.19.2.1 bouyer * figure out the maximum size of an exec header, if necessary. 1813 1.19.2.1 bouyer * XXX should be able to keep LKM code from modifying exec switch 1814 1.19.2.1 bouyer * when we're still using it, but... 1815 1.19.2.1 bouyer */ 1816 1.19.2.1 bouyer if (exec_maxhdrsz == 0) { 1817 1.19.2.1 bouyer for (i = 0; i < nexecs; i++) 1818 1.19.2.1 bouyer if (execsw[i].es_check != NULL 1819 1.19.2.1 bouyer && execsw[i].es_hdrsz > exec_maxhdrsz) 1820 1.19.2.1 bouyer exec_maxhdrsz = execsw[i].es_hdrsz; 1821 1.19.2.1 bouyer } 1822 1.19.2.1 bouyer 1823 1.19.2.1 bouyer /* init the namei data to point the file user's program name */ 1824 1.19.2.1 bouyer /* XXX cgd 960926: why do this here? most will be clobbered. */ 1825 1.19.2.1 bouyer NDINIT(&nid, LOOKUP, NOFOLLOW, UIO_USERSPACE, SCARG(&ua, path), p); 1826 1.19.2.1 bouyer 1827 1.19.2.1 bouyer /* 1828 1.19.2.1 bouyer * initialize the fields of the exec package. 1829 1.19.2.1 bouyer */ 1830 1.19.2.1 bouyer pack.ep_name = SCARG(&ua, path); 1831 1.19.2.2 bouyer pack.ep_hdr = malloc(exec_maxhdrsz, M_EXEC, M_WAITOK); 1832 1.19.2.1 bouyer pack.ep_hdrlen = exec_maxhdrsz; 1833 1.19.2.1 bouyer pack.ep_hdrvalid = 0; 1834 1.19.2.1 bouyer pack.ep_ndp = &nid; 1835 1.19.2.1 bouyer pack.ep_emul_arg = NULL; 1836 1.19.2.1 bouyer pack.ep_vmcmds.evs_cnt = 0; 1837 1.19.2.1 bouyer pack.ep_vmcmds.evs_used = 0; 1838 1.19.2.1 bouyer pack.ep_vap = &attr; 1839 1.19.2.1 bouyer pack.ep_flags = 0; 1840 1.19.2.1 bouyer 1841 1.19.2.1 bouyer /* see if we can run it. */ 1842 1.19.2.1 bouyer if ((error = check_exec(p, &pack)) != 0) 1843 1.19.2.1 bouyer goto freehdr; 1844 1.19.2.1 bouyer 1845 1.19.2.1 bouyer /* XXX -- THE FOLLOWING SECTION NEEDS MAJOR CLEANUP */ 1846 1.19.2.1 bouyer 1847 1.19.2.1 bouyer /* allocate an argument buffer */ 1848 1.19.2.1 bouyer argp = (char *) uvm_km_valloc_wait(exec_map, NCARGS); 1849 1.19.2.1 bouyer #ifdef DIAGNOSTIC 1850 1.19.2.1 bouyer if (argp == (vaddr_t) 0) 1851 1.19.2.1 bouyer panic("execve: argp == NULL"); 1852 1.19.2.1 bouyer #endif 1853 1.19.2.1 bouyer dp = argp; 1854 1.19.2.1 bouyer argc = 0; 1855 1.19.2.1 bouyer 1856 1.19.2.1 bouyer /* copy the fake args list, if there's one, freeing it as we go */ 1857 1.19.2.1 bouyer if (pack.ep_flags & EXEC_HASARGL) { 1858 1.19.2.1 bouyer tmpfap = pack.ep_fa; 1859 1.19.2.1 bouyer while (*tmpfap != NULL) { 1860 1.19.2.1 bouyer char *cp; 1861 1.19.2.1 bouyer 1862 1.19.2.1 bouyer cp = *tmpfap; 1863 1.19.2.1 bouyer while (*cp) 1864 1.19.2.1 bouyer *dp++ = *cp++; 1865 1.19.2.1 bouyer dp++; 1866 1.19.2.1 bouyer 1867 1.19.2.1 bouyer FREE(*tmpfap, M_EXEC); 1868 1.19.2.1 bouyer tmpfap++; argc++; 1869 1.19.2.1 bouyer } 1870 1.19.2.1 bouyer FREE(pack.ep_fa, M_EXEC); 1871 1.19.2.1 bouyer pack.ep_flags &= ~EXEC_HASARGL; 1872 1.19.2.1 bouyer } 1873 1.19.2.1 bouyer 1874 1.19.2.1 bouyer /* Now get argv & environment */ 1875 1.19.2.1 bouyer if (!(cpp = (netbsd32_charp *)SCARG(&ua, argp))) { 1876 1.19.2.1 bouyer error = EINVAL; 1877 1.19.2.1 bouyer goto bad; 1878 1.19.2.1 bouyer } 1879 1.19.2.1 bouyer 1880 1.19.2.1 bouyer if (pack.ep_flags & EXEC_SKIPARG) 1881 1.19.2.1 bouyer cpp++; 1882 1.19.2.1 bouyer 1883 1.19.2.1 bouyer while (1) { 1884 1.19.2.1 bouyer len = argp + ARG_MAX - dp; 1885 1.19.2.1 bouyer if ((error = copyin(cpp, &sp, sizeof(sp))) != 0) 1886 1.19.2.1 bouyer goto bad; 1887 1.19.2.1 bouyer if (!sp) 1888 1.19.2.1 bouyer break; 1889 1.19.2.1 bouyer if ((error = copyinstr((char *)(u_long)sp, dp, 1890 1.19.2.1 bouyer len, &len)) != 0) { 1891 1.19.2.1 bouyer if (error == ENAMETOOLONG) 1892 1.19.2.1 bouyer error = E2BIG; 1893 1.19.2.1 bouyer goto bad; 1894 1.19.2.1 bouyer } 1895 1.19.2.1 bouyer dp += len; 1896 1.19.2.1 bouyer cpp++; 1897 1.19.2.1 bouyer argc++; 1898 1.19.2.1 bouyer } 1899 1.19.2.1 bouyer 1900 1.19.2.1 bouyer envc = 0; 1901 1.19.2.1 bouyer /* environment need not be there */ 1902 1.19.2.1 bouyer if ((cpp = (netbsd32_charp *)SCARG(&ua, envp)) != NULL ) { 1903 1.19.2.1 bouyer while (1) { 1904 1.19.2.1 bouyer len = argp + ARG_MAX - dp; 1905 1.19.2.1 bouyer if ((error = copyin(cpp, &sp, sizeof(sp))) != 0) 1906 1.19.2.1 bouyer goto bad; 1907 1.19.2.1 bouyer if (!sp) 1908 1.19.2.1 bouyer break; 1909 1.19.2.1 bouyer if ((error = copyinstr((char *)(u_long)sp, 1910 1.19.2.1 bouyer dp, len, &len)) != 0) { 1911 1.19.2.1 bouyer if (error == ENAMETOOLONG) 1912 1.19.2.1 bouyer error = E2BIG; 1913 1.19.2.1 bouyer goto bad; 1914 1.19.2.1 bouyer } 1915 1.19.2.1 bouyer dp += len; 1916 1.19.2.1 bouyer cpp++; 1917 1.19.2.1 bouyer envc++; 1918 1.19.2.1 bouyer } 1919 1.19.2.1 bouyer } 1920 1.19.2.1 bouyer 1921 1.19.2.1 bouyer dp = (char *) ALIGN(dp); 1922 1.19.2.1 bouyer 1923 1.19.2.2 bouyer szsigcode = pack.ep_es->es_emul->e_esigcode - 1924 1.19.2.2 bouyer pack.ep_es->es_emul->e_sigcode; 1925 1.19.2.1 bouyer 1926 1.19.2.1 bouyer /* Now check if args & environ fit into new stack */ 1927 1.19.2.1 bouyer if (pack.ep_flags & EXEC_32) 1928 1.19.2.2 bouyer len = ((argc + envc + 2 + pack.ep_es->es_arglen) * 1929 1.19.2.2 bouyer sizeof(int) + sizeof(int) + dp + STACKGAPLEN + 1930 1.19.2.2 bouyer szsigcode + sizeof(struct ps_strings)) - argp; 1931 1.19.2.1 bouyer else 1932 1.19.2.2 bouyer len = ((argc + envc + 2 + pack.ep_es->es_arglen) * 1933 1.19.2.2 bouyer sizeof(char *) + sizeof(int) + dp + STACKGAPLEN + 1934 1.19.2.2 bouyer szsigcode + sizeof(struct ps_strings)) - argp; 1935 1.19.2.1 bouyer 1936 1.19.2.1 bouyer len = ALIGN(len); /* make the stack "safely" aligned */ 1937 1.19.2.1 bouyer 1938 1.19.2.1 bouyer if (len > pack.ep_ssize) { /* in effect, compare to initial limit */ 1939 1.19.2.1 bouyer error = ENOMEM; 1940 1.19.2.1 bouyer goto bad; 1941 1.19.2.1 bouyer } 1942 1.19.2.1 bouyer 1943 1.19.2.1 bouyer /* adjust "active stack depth" for process VSZ */ 1944 1.19.2.1 bouyer pack.ep_ssize = len; /* maybe should go elsewhere, but... */ 1945 1.19.2.1 bouyer 1946 1.19.2.1 bouyer /* 1947 1.19.2.1 bouyer * Do whatever is necessary to prepare the address space 1948 1.19.2.1 bouyer * for remapping. Note that this might replace the current 1949 1.19.2.1 bouyer * vmspace with another! 1950 1.19.2.1 bouyer */ 1951 1.19.2.1 bouyer uvmspace_exec(p); 1952 1.19.2.1 bouyer 1953 1.19.2.1 bouyer /* Now map address space */ 1954 1.19.2.1 bouyer vm = p->p_vmspace; 1955 1.19.2.1 bouyer vm->vm_taddr = (char *) pack.ep_taddr; 1956 1.19.2.1 bouyer vm->vm_tsize = btoc(pack.ep_tsize); 1957 1.19.2.1 bouyer vm->vm_daddr = (char *) pack.ep_daddr; 1958 1.19.2.1 bouyer vm->vm_dsize = btoc(pack.ep_dsize); 1959 1.19.2.1 bouyer vm->vm_ssize = btoc(pack.ep_ssize); 1960 1.19.2.1 bouyer vm->vm_maxsaddr = (char *) pack.ep_maxsaddr; 1961 1.19.2.1 bouyer vm->vm_minsaddr = (char *) pack.ep_minsaddr; 1962 1.19.2.1 bouyer 1963 1.19.2.1 bouyer /* create the new process's VM space by running the vmcmds */ 1964 1.19.2.1 bouyer #ifdef DIAGNOSTIC 1965 1.19.2.1 bouyer if (pack.ep_vmcmds.evs_used == 0) 1966 1.19.2.1 bouyer panic("execve: no vmcmds"); 1967 1.19.2.1 bouyer #endif 1968 1.19.2.1 bouyer for (i = 0; i < pack.ep_vmcmds.evs_used && !error; i++) { 1969 1.19.2.1 bouyer struct exec_vmcmd *vcp; 1970 1.19.2.1 bouyer 1971 1.19.2.1 bouyer vcp = &pack.ep_vmcmds.evs_cmds[i]; 1972 1.19.2.2 bouyer if (vcp->ev_flags & VMCMD_RELATIVE) { 1973 1.19.2.2 bouyer #ifdef DIAGNOSTIC 1974 1.19.2.2 bouyer if (base_vcp == NULL) 1975 1.19.2.2 bouyer panic("execve: relative vmcmd with no base"); 1976 1.19.2.2 bouyer if (vcp->ev_flags & VMCMD_BASE) 1977 1.19.2.2 bouyer panic("execve: illegal base & relative vmcmd"); 1978 1.19.2.2 bouyer #endif 1979 1.19.2.2 bouyer vcp->ev_addr += base_vcp->ev_addr; 1980 1.19.2.2 bouyer } 1981 1.19.2.1 bouyer error = (*vcp->ev_proc)(p, vcp); 1982 1.19.2.2 bouyer #ifdef DEBUG 1983 1.19.2.2 bouyer if (error) { 1984 1.19.2.2 bouyer if (i > 0) 1985 1.19.2.2 bouyer printf("vmcmd[%d] = %#lx/%#lx @ %#lx\n", i-1, 1986 1.19.2.2 bouyer vcp[-1].ev_addr, vcp[-1].ev_len, 1987 1.19.2.2 bouyer vcp[-1].ev_offset); 1988 1.19.2.2 bouyer printf("vmcmd[%d] = %#lx/%#lx @ %#lx\n", i, 1989 1.19.2.2 bouyer vcp->ev_addr, vcp->ev_len, vcp->ev_offset); 1990 1.19.2.2 bouyer } 1991 1.19.2.2 bouyer #endif 1992 1.19.2.2 bouyer if (vcp->ev_flags & VMCMD_BASE) 1993 1.19.2.2 bouyer base_vcp = vcp; 1994 1.19.2.1 bouyer } 1995 1.19.2.1 bouyer 1996 1.19.2.1 bouyer /* free the vmspace-creation commands, and release their references */ 1997 1.19.2.1 bouyer kill_vmcmds(&pack.ep_vmcmds); 1998 1.19.2.1 bouyer 1999 1.19.2.1 bouyer /* if an error happened, deallocate and punt */ 2000 1.19.2.2 bouyer if (error) { 2001 1.19.2.2 bouyer #ifdef DEBUG 2002 1.19.2.2 bouyer printf("execve: vmcmd %i failed: %d\n", i-1, error); 2003 1.19.2.2 bouyer #endif 2004 1.19.2.1 bouyer goto exec_abort; 2005 1.19.2.2 bouyer } 2006 1.19.2.1 bouyer 2007 1.19.2.1 bouyer /* remember information about the process */ 2008 1.19.2.1 bouyer arginfo.ps_nargvstr = argc; 2009 1.19.2.1 bouyer arginfo.ps_nenvstr = envc; 2010 1.19.2.1 bouyer 2011 1.19.2.1 bouyer stack = (char *) (vm->vm_minsaddr - len); 2012 1.19.2.1 bouyer /* Now copy argc, args & environ to new stack */ 2013 1.19.2.2 bouyer if (!(*pack.ep_es->es_copyargs)(&pack, &arginfo, stack, argp)) { 2014 1.19.2.2 bouyer #ifdef DEBUG 2015 1.19.2.2 bouyer printf("execve: copyargs failed\n"); 2016 1.19.2.2 bouyer #endif 2017 1.19.2.1 bouyer goto exec_abort; 2018 1.19.2.2 bouyer } 2019 1.19.2.1 bouyer 2020 1.19.2.1 bouyer /* fill process ps_strings info */ 2021 1.19.2.1 bouyer p->p_psstr = (struct ps_strings *)(stack - sizeof(struct ps_strings)); 2022 1.19.2.1 bouyer p->p_psargv = offsetof(struct ps_strings, ps_argvstr); 2023 1.19.2.1 bouyer p->p_psnargv = offsetof(struct ps_strings, ps_nargvstr); 2024 1.19.2.1 bouyer p->p_psenv = offsetof(struct ps_strings, ps_envstr); 2025 1.19.2.1 bouyer p->p_psnenv = offsetof(struct ps_strings, ps_nenvstr); 2026 1.19.2.1 bouyer 2027 1.19.2.1 bouyer /* copy out the process's ps_strings structure */ 2028 1.19.2.2 bouyer if (copyout(&arginfo, (char *)p->p_psstr, sizeof(arginfo))) { 2029 1.19.2.2 bouyer #ifdef DEBUG 2030 1.19.2.2 bouyer printf("execve: ps_strings copyout failed\n"); 2031 1.19.2.2 bouyer #endif 2032 1.19.2.1 bouyer goto exec_abort; 2033 1.19.2.2 bouyer } 2034 1.19.2.1 bouyer 2035 1.19.2.1 bouyer /* copy out the process's signal trapoline code */ 2036 1.19.2.1 bouyer if (szsigcode) { 2037 1.19.2.2 bouyer if (copyout((char *)pack.ep_es->es_emul->e_sigcode, 2038 1.19.2.1 bouyer p->p_sigacts->ps_sigcode = (char *)p->p_psstr - szsigcode, 2039 1.19.2.2 bouyer szsigcode)) { 2040 1.19.2.2 bouyer #ifdef DEBUG 2041 1.19.2.2 bouyer printf("execve: sig trampoline copyout failed\n"); 2042 1.19.2.2 bouyer #endif 2043 1.19.2.1 bouyer goto exec_abort; 2044 1.19.2.2 bouyer } 2045 1.19.2.1 bouyer #ifdef PMAP_NEED_PROCWR 2046 1.19.2.1 bouyer /* This is code. Let the pmap do what is needed. */ 2047 1.19.2.1 bouyer pmap_procwr(p, (vaddr_t)p->p_sigacts->ps_sigcode, szsigcode); 2048 1.19.2.1 bouyer #endif 2049 1.19.2.1 bouyer } 2050 1.19.2.1 bouyer 2051 1.19.2.1 bouyer stopprofclock(p); /* stop profiling */ 2052 1.19.2.1 bouyer fdcloseexec(p); /* handle close on exec */ 2053 1.19.2.1 bouyer execsigs(p); /* reset catched signals */ 2054 1.19.2.1 bouyer p->p_ctxlink = NULL; /* reset ucontext link */ 2055 1.19.2.1 bouyer 2056 1.19.2.1 bouyer /* set command name & other accounting info */ 2057 1.19.2.1 bouyer len = min(nid.ni_cnd.cn_namelen, MAXCOMLEN); 2058 1.19.2.1 bouyer memcpy(p->p_comm, nid.ni_cnd.cn_nameptr, len); 2059 1.19.2.1 bouyer p->p_comm[len] = 0; 2060 1.19.2.1 bouyer p->p_acflag &= ~AFORK; 2061 1.19.2.1 bouyer 2062 1.19.2.1 bouyer /* record proc's vnode, for use by procfs and others */ 2063 1.19.2.1 bouyer if (p->p_textvp) 2064 1.19.2.1 bouyer vrele(p->p_textvp); 2065 1.19.2.1 bouyer VREF(pack.ep_vp); 2066 1.19.2.1 bouyer p->p_textvp = pack.ep_vp; 2067 1.19.2.1 bouyer 2068 1.19.2.1 bouyer p->p_flag |= P_EXEC; 2069 1.19.2.1 bouyer if (p->p_flag & P_PPWAIT) { 2070 1.19.2.1 bouyer p->p_flag &= ~P_PPWAIT; 2071 1.19.2.1 bouyer wakeup((caddr_t) p->p_pptr); 2072 1.19.2.1 bouyer } 2073 1.19.2.1 bouyer 2074 1.19.2.1 bouyer /* 2075 1.19.2.1 bouyer * deal with set[ug]id. 2076 1.19.2.1 bouyer * MNT_NOSUID and P_TRACED have already been used to disable s[ug]id. 2077 1.19.2.1 bouyer */ 2078 1.19.2.1 bouyer if (((attr.va_mode & S_ISUID) != 0 && p->p_ucred->cr_uid != attr.va_uid) 2079 1.19.2.1 bouyer || ((attr.va_mode & S_ISGID) != 0 && p->p_ucred->cr_gid != attr.va_gid)){ 2080 1.19.2.1 bouyer p->p_ucred = crcopy(cred); 2081 1.19.2.1 bouyer #ifdef KTRACE 2082 1.19.2.1 bouyer /* 2083 1.19.2.1 bouyer * If process is being ktraced, turn off - unless 2084 1.19.2.1 bouyer * root set it. 2085 1.19.2.1 bouyer */ 2086 1.19.2.1 bouyer if (p->p_tracep && !(p->p_traceflag & KTRFAC_ROOT)) 2087 1.19.2.1 bouyer ktrderef(p); 2088 1.19.2.1 bouyer #endif 2089 1.19.2.1 bouyer if (attr.va_mode & S_ISUID) 2090 1.19.2.1 bouyer p->p_ucred->cr_uid = attr.va_uid; 2091 1.19.2.1 bouyer if (attr.va_mode & S_ISGID) 2092 1.19.2.1 bouyer p->p_ucred->cr_gid = attr.va_gid; 2093 1.19.2.1 bouyer p_sugid(p); 2094 1.19.2.1 bouyer } else 2095 1.19.2.1 bouyer p->p_flag &= ~P_SUGID; 2096 1.19.2.1 bouyer p->p_cred->p_svuid = p->p_ucred->cr_uid; 2097 1.19.2.1 bouyer p->p_cred->p_svgid = p->p_ucred->cr_gid; 2098 1.19.2.1 bouyer 2099 1.19.2.2 bouyer doexechooks(p); 2100 1.19.2.2 bouyer 2101 1.19.2.1 bouyer uvm_km_free_wakeup(exec_map, (vaddr_t) argp, NCARGS); 2102 1.19.2.1 bouyer 2103 1.19.2.1 bouyer PNBUF_PUT(nid.ni_cnd.cn_pnbuf); 2104 1.19.2.1 bouyer vn_lock(pack.ep_vp, LK_EXCLUSIVE | LK_RETRY); 2105 1.19.2.1 bouyer VOP_CLOSE(pack.ep_vp, FREAD, cred, p); 2106 1.19.2.1 bouyer vput(pack.ep_vp); 2107 1.19.2.1 bouyer 2108 1.19.2.1 bouyer /* setup new registers and do misc. setup. */ 2109 1.19.2.2 bouyer (*pack.ep_es->es_setregs)(p, &pack, (u_long) stack); 2110 1.19.2.1 bouyer 2111 1.19.2.1 bouyer if (p->p_flag & P_TRACED) 2112 1.19.2.1 bouyer psignal(p, SIGTRAP); 2113 1.19.2.1 bouyer 2114 1.19.2.2 bouyer free(pack.ep_hdr, M_EXEC); 2115 1.19.2.2 bouyer 2116 1.19.2.2 bouyer /* 2117 1.19.2.2 bouyer * Call emulation specific exec hook. This can setup setup per-process 2118 1.19.2.2 bouyer * p->p_emuldata or do any other per-process stuff an emulation needs. 2119 1.19.2.2 bouyer * 2120 1.19.2.2 bouyer * If we are executing process of different emulation than the 2121 1.19.2.2 bouyer * original forked process, call e_proc_exit() of the old emulation 2122 1.19.2.2 bouyer * first, then e_proc_exec() of new emulation. If the emulation is 2123 1.19.2.2 bouyer * same, the exec hook code should deallocate any old emulation 2124 1.19.2.2 bouyer * resources held previously by this process. 2125 1.19.2.2 bouyer */ 2126 1.19.2.2 bouyer if (p->p_emul && p->p_emul->e_proc_exit 2127 1.19.2.2 bouyer && p->p_emul != pack.ep_es->es_emul) 2128 1.19.2.2 bouyer (*p->p_emul->e_proc_exit)(p); 2129 1.19.2.2 bouyer 2130 1.19.2.2 bouyer /* 2131 1.19.2.2 bouyer * Call exec hook. Emulation code may NOT store reference to anything 2132 1.19.2.2 bouyer * from &pack. 2133 1.19.2.2 bouyer */ 2134 1.19.2.2 bouyer if (pack.ep_es->es_emul->e_proc_exec) 2135 1.19.2.2 bouyer (*pack.ep_es->es_emul->e_proc_exec)(p, &pack); 2136 1.19.2.2 bouyer 2137 1.19.2.2 bouyer /* update p_emul, the old value is no longer needed */ 2138 1.19.2.2 bouyer p->p_emul = pack.ep_es->es_emul; 2139 1.19.2.1 bouyer 2140 1.19.2.1 bouyer #ifdef KTRACE 2141 1.19.2.1 bouyer if (KTRPOINT(p, KTR_EMUL)) 2142 1.19.2.1 bouyer ktremul(p); 2143 1.19.2.1 bouyer #endif 2144 1.19.2.1 bouyer 2145 1.19.2.1 bouyer return (EJUSTRETURN); 2146 1.19.2.1 bouyer 2147 1.19.2.1 bouyer bad: 2148 1.19.2.1 bouyer /* free the vmspace-creation commands, and release their references */ 2149 1.19.2.1 bouyer kill_vmcmds(&pack.ep_vmcmds); 2150 1.19.2.1 bouyer /* kill any opened file descriptor, if necessary */ 2151 1.19.2.1 bouyer if (pack.ep_flags & EXEC_HASFD) { 2152 1.19.2.1 bouyer pack.ep_flags &= ~EXEC_HASFD; 2153 1.19.2.1 bouyer (void) fdrelease(p, pack.ep_fd); 2154 1.19.2.1 bouyer } 2155 1.19.2.1 bouyer /* close and put the exec'd file */ 2156 1.19.2.1 bouyer vn_lock(pack.ep_vp, LK_EXCLUSIVE | LK_RETRY); 2157 1.19.2.1 bouyer VOP_CLOSE(pack.ep_vp, FREAD, cred, p); 2158 1.19.2.1 bouyer vput(pack.ep_vp); 2159 1.19.2.1 bouyer PNBUF_PUT(nid.ni_cnd.cn_pnbuf); 2160 1.19.2.1 bouyer uvm_km_free_wakeup(exec_map, (vaddr_t) argp, NCARGS); 2161 1.19.2.1 bouyer 2162 1.19.2.1 bouyer freehdr: 2163 1.19.2.2 bouyer free(pack.ep_hdr, M_EXEC); 2164 1.19.2.1 bouyer return error; 2165 1.19.2.1 bouyer 2166 1.19.2.1 bouyer exec_abort: 2167 1.19.2.1 bouyer /* 2168 1.19.2.1 bouyer * the old process doesn't exist anymore. exit gracefully. 2169 1.19.2.1 bouyer * get rid of the (new) address space we have created, if any, get rid 2170 1.19.2.1 bouyer * of our namei data and vnode, and exit noting failure 2171 1.19.2.1 bouyer */ 2172 1.19.2.1 bouyer uvm_deallocate(&vm->vm_map, VM_MIN_ADDRESS, 2173 1.19.2.1 bouyer VM_MAXUSER_ADDRESS - VM_MIN_ADDRESS); 2174 1.19.2.1 bouyer if (pack.ep_emul_arg) 2175 1.19.2.1 bouyer FREE(pack.ep_emul_arg, M_TEMP); 2176 1.19.2.1 bouyer PNBUF_PUT(nid.ni_cnd.cn_pnbuf); 2177 1.19.2.1 bouyer vn_lock(pack.ep_vp, LK_EXCLUSIVE | LK_RETRY); 2178 1.19.2.1 bouyer VOP_CLOSE(pack.ep_vp, FREAD, cred, p); 2179 1.19.2.1 bouyer vput(pack.ep_vp); 2180 1.19.2.1 bouyer uvm_km_free_wakeup(exec_map, (vaddr_t) argp, NCARGS); 2181 1.19.2.2 bouyer free(pack.ep_hdr, M_EXEC); 2182 1.19.2.1 bouyer exit1(p, W_EXITCODE(0, SIGABRT)); 2183 1.19.2.1 bouyer exit1(p, -1); 2184 1.19.2.1 bouyer 2185 1.19.2.1 bouyer /* NOTREACHED */ 2186 1.19.2.1 bouyer return 0; 2187 1.1 mrg } 2188 1.1 mrg 2189 1.1 mrg int 2190 1.19 eeh netbsd32_umask(p, v, retval) 2191 1.6 eeh struct proc *p; 2192 1.6 eeh void *v; 2193 1.6 eeh register_t *retval; 2194 1.6 eeh { 2195 1.19 eeh struct netbsd32_umask_args /* { 2196 1.6 eeh syscallarg(mode_t) newmask; 2197 1.6 eeh } */ *uap = v; 2198 1.6 eeh struct sys_umask_args ua; 2199 1.6 eeh 2200 1.11 mrg NETBSD32TO64_UAP(newmask); 2201 1.6 eeh return (sys_umask(p, &ua, retval)); 2202 1.6 eeh } 2203 1.6 eeh 2204 1.6 eeh int 2205 1.19 eeh netbsd32_chroot(p, v, retval) 2206 1.1 mrg struct proc *p; 2207 1.1 mrg void *v; 2208 1.1 mrg register_t *retval; 2209 1.1 mrg { 2210 1.19 eeh struct netbsd32_chroot_args /* { 2211 1.10 mrg syscallarg(const netbsd32_charp) path; 2212 1.1 mrg } */ *uap = v; 2213 1.1 mrg struct sys_chroot_args ua; 2214 1.1 mrg 2215 1.11 mrg NETBSD32TOP_UAP(path, const char); 2216 1.1 mrg return (sys_chroot(p, &ua, retval)); 2217 1.1 mrg } 2218 1.1 mrg 2219 1.1 mrg int 2220 1.19 eeh netbsd32_sbrk(p, v, retval) 2221 1.6 eeh struct proc *p; 2222 1.6 eeh void *v; 2223 1.6 eeh register_t *retval; 2224 1.6 eeh { 2225 1.19 eeh struct netbsd32_sbrk_args /* { 2226 1.6 eeh syscallarg(int) incr; 2227 1.6 eeh } */ *uap = v; 2228 1.6 eeh struct sys_sbrk_args ua; 2229 1.6 eeh 2230 1.11 mrg NETBSD32TO64_UAP(incr); 2231 1.6 eeh return (sys_sbrk(p, &ua, retval)); 2232 1.6 eeh } 2233 1.6 eeh 2234 1.6 eeh int 2235 1.19 eeh netbsd32_sstk(p, v, retval) 2236 1.6 eeh struct proc *p; 2237 1.6 eeh void *v; 2238 1.6 eeh register_t *retval; 2239 1.6 eeh { 2240 1.19 eeh struct netbsd32_sstk_args /* { 2241 1.6 eeh syscallarg(int) incr; 2242 1.6 eeh } */ *uap = v; 2243 1.6 eeh struct sys_sstk_args ua; 2244 1.6 eeh 2245 1.11 mrg NETBSD32TO64_UAP(incr); 2246 1.6 eeh return (sys_sstk(p, &ua, retval)); 2247 1.6 eeh } 2248 1.6 eeh 2249 1.6 eeh int 2250 1.19 eeh netbsd32_munmap(p, v, retval) 2251 1.1 mrg struct proc *p; 2252 1.1 mrg void *v; 2253 1.1 mrg register_t *retval; 2254 1.1 mrg { 2255 1.19 eeh struct netbsd32_munmap_args /* { 2256 1.10 mrg syscallarg(netbsd32_voidp) addr; 2257 1.10 mrg syscallarg(netbsd32_size_t) len; 2258 1.1 mrg } */ *uap = v; 2259 1.1 mrg struct sys_munmap_args ua; 2260 1.1 mrg 2261 1.11 mrg NETBSD32TOP_UAP(addr, void); 2262 1.11 mrg NETBSD32TOX_UAP(len, size_t); 2263 1.1 mrg return (sys_munmap(p, &ua, retval)); 2264 1.1 mrg } 2265 1.1 mrg 2266 1.1 mrg int 2267 1.19 eeh netbsd32_mprotect(p, v, retval) 2268 1.1 mrg struct proc *p; 2269 1.1 mrg void *v; 2270 1.1 mrg register_t *retval; 2271 1.1 mrg { 2272 1.19 eeh struct netbsd32_mprotect_args /* { 2273 1.10 mrg syscallarg(netbsd32_voidp) addr; 2274 1.10 mrg syscallarg(netbsd32_size_t) len; 2275 1.1 mrg syscallarg(int) prot; 2276 1.1 mrg } */ *uap = v; 2277 1.1 mrg struct sys_mprotect_args ua; 2278 1.1 mrg 2279 1.11 mrg NETBSD32TOP_UAP(addr, void); 2280 1.11 mrg NETBSD32TOX_UAP(len, size_t); 2281 1.11 mrg NETBSD32TO64_UAP(prot); 2282 1.1 mrg return (sys_mprotect(p, &ua, retval)); 2283 1.1 mrg } 2284 1.1 mrg 2285 1.1 mrg int 2286 1.19 eeh netbsd32_madvise(p, v, retval) 2287 1.1 mrg struct proc *p; 2288 1.1 mrg void *v; 2289 1.1 mrg register_t *retval; 2290 1.1 mrg { 2291 1.19 eeh struct netbsd32_madvise_args /* { 2292 1.10 mrg syscallarg(netbsd32_voidp) addr; 2293 1.10 mrg syscallarg(netbsd32_size_t) len; 2294 1.1 mrg syscallarg(int) behav; 2295 1.1 mrg } */ *uap = v; 2296 1.1 mrg struct sys_madvise_args ua; 2297 1.1 mrg 2298 1.11 mrg NETBSD32TOP_UAP(addr, void); 2299 1.11 mrg NETBSD32TOX_UAP(len, size_t); 2300 1.11 mrg NETBSD32TO64_UAP(behav); 2301 1.1 mrg return (sys_madvise(p, &ua, retval)); 2302 1.1 mrg } 2303 1.1 mrg 2304 1.1 mrg int 2305 1.19 eeh netbsd32_mincore(p, v, retval) 2306 1.1 mrg struct proc *p; 2307 1.1 mrg void *v; 2308 1.1 mrg register_t *retval; 2309 1.1 mrg { 2310 1.19 eeh struct netbsd32_mincore_args /* { 2311 1.10 mrg syscallarg(netbsd32_caddr_t) addr; 2312 1.10 mrg syscallarg(netbsd32_size_t) len; 2313 1.10 mrg syscallarg(netbsd32_charp) vec; 2314 1.1 mrg } */ *uap = v; 2315 1.1 mrg struct sys_mincore_args ua; 2316 1.1 mrg 2317 1.11 mrg NETBSD32TOX64_UAP(addr, caddr_t); 2318 1.11 mrg NETBSD32TOX_UAP(len, size_t); 2319 1.11 mrg NETBSD32TOP_UAP(vec, char); 2320 1.1 mrg return (sys_mincore(p, &ua, retval)); 2321 1.1 mrg } 2322 1.1 mrg 2323 1.1 mrg int 2324 1.19 eeh netbsd32_getgroups(p, v, retval) 2325 1.1 mrg struct proc *p; 2326 1.1 mrg void *v; 2327 1.1 mrg register_t *retval; 2328 1.1 mrg { 2329 1.19 eeh struct netbsd32_getgroups_args /* { 2330 1.1 mrg syscallarg(int) gidsetsize; 2331 1.10 mrg syscallarg(netbsd32_gid_tp) gidset; 2332 1.1 mrg } */ *uap = v; 2333 1.19.2.1 bouyer struct pcred *pc = p->p_cred; 2334 1.19.2.1 bouyer int ngrp; 2335 1.6 eeh int error; 2336 1.1 mrg 2337 1.6 eeh ngrp = SCARG(uap, gidsetsize); 2338 1.6 eeh if (ngrp == 0) { 2339 1.6 eeh *retval = pc->pc_ucred->cr_ngroups; 2340 1.6 eeh return (0); 2341 1.6 eeh } 2342 1.6 eeh if (ngrp < pc->pc_ucred->cr_ngroups) 2343 1.6 eeh return (EINVAL); 2344 1.6 eeh ngrp = pc->pc_ucred->cr_ngroups; 2345 1.10 mrg /* Should convert gid_t to netbsd32_gid_t, but they're the same */ 2346 1.6 eeh error = copyout((caddr_t)pc->pc_ucred->cr_groups, 2347 1.6 eeh (caddr_t)(u_long)SCARG(uap, gidset), 2348 1.6 eeh ngrp * sizeof(gid_t)); 2349 1.6 eeh if (error) 2350 1.6 eeh return (error); 2351 1.6 eeh *retval = ngrp; 2352 1.6 eeh return (0); 2353 1.1 mrg } 2354 1.1 mrg 2355 1.1 mrg int 2356 1.19 eeh netbsd32_setgroups(p, v, retval) 2357 1.1 mrg struct proc *p; 2358 1.1 mrg void *v; 2359 1.1 mrg register_t *retval; 2360 1.1 mrg { 2361 1.19 eeh struct netbsd32_setgroups_args /* { 2362 1.1 mrg syscallarg(int) gidsetsize; 2363 1.10 mrg syscallarg(const netbsd32_gid_tp) gidset; 2364 1.1 mrg } */ *uap = v; 2365 1.1 mrg struct sys_setgroups_args ua; 2366 1.1 mrg 2367 1.11 mrg NETBSD32TO64_UAP(gidsetsize); 2368 1.11 mrg NETBSD32TOP_UAP(gidset, gid_t); 2369 1.1 mrg return (sys_setgroups(p, &ua, retval)); 2370 1.1 mrg } 2371 1.1 mrg 2372 1.1 mrg int 2373 1.19 eeh netbsd32_setpgid(p, v, retval) 2374 1.6 eeh struct proc *p; 2375 1.6 eeh void *v; 2376 1.6 eeh register_t *retval; 2377 1.6 eeh { 2378 1.19 eeh struct netbsd32_setpgid_args /* { 2379 1.6 eeh syscallarg(int) pid; 2380 1.6 eeh syscallarg(int) pgid; 2381 1.6 eeh } */ *uap = v; 2382 1.6 eeh struct sys_setpgid_args ua; 2383 1.6 eeh 2384 1.11 mrg NETBSD32TO64_UAP(pid); 2385 1.11 mrg NETBSD32TO64_UAP(pgid); 2386 1.6 eeh return (sys_setpgid(p, &ua, retval)); 2387 1.6 eeh } 2388 1.6 eeh 2389 1.6 eeh int 2390 1.19 eeh netbsd32_setitimer(p, v, retval) 2391 1.1 mrg struct proc *p; 2392 1.1 mrg void *v; 2393 1.1 mrg register_t *retval; 2394 1.1 mrg { 2395 1.19 eeh struct netbsd32_setitimer_args /* { 2396 1.1 mrg syscallarg(int) which; 2397 1.10 mrg syscallarg(const netbsd32_itimervalp_t) itv; 2398 1.10 mrg syscallarg(netbsd32_itimervalp_t) oitv; 2399 1.1 mrg } */ *uap = v; 2400 1.10 mrg struct netbsd32_itimerval s32it, *itvp; 2401 1.6 eeh int which = SCARG(uap, which); 2402 1.19 eeh struct netbsd32_getitimer_args getargs; 2403 1.6 eeh struct itimerval aitv; 2404 1.6 eeh int s, error; 2405 1.1 mrg 2406 1.6 eeh if ((u_int)which > ITIMER_PROF) 2407 1.6 eeh return (EINVAL); 2408 1.10 mrg itvp = (struct netbsd32_itimerval *)(u_long)SCARG(uap, itv); 2409 1.6 eeh if (itvp && (error = copyin(itvp, &s32it, sizeof(s32it)))) 2410 1.6 eeh return (error); 2411 1.10 mrg netbsd32_to_itimerval(&s32it, &aitv); 2412 1.6 eeh if (SCARG(uap, oitv) != NULL) { 2413 1.6 eeh SCARG(&getargs, which) = which; 2414 1.6 eeh SCARG(&getargs, itv) = SCARG(uap, oitv); 2415 1.19 eeh if ((error = netbsd32_getitimer(p, &getargs, retval)) != 0) 2416 1.6 eeh return (error); 2417 1.6 eeh } 2418 1.6 eeh if (itvp == 0) 2419 1.6 eeh return (0); 2420 1.6 eeh if (itimerfix(&aitv.it_value) || itimerfix(&aitv.it_interval)) 2421 1.6 eeh return (EINVAL); 2422 1.6 eeh s = splclock(); 2423 1.6 eeh if (which == ITIMER_REAL) { 2424 1.19.2.1 bouyer callout_stop(&p->p_realit_ch); 2425 1.6 eeh if (timerisset(&aitv.it_value)) { 2426 1.19.2.1 bouyer /* 2427 1.19.2.1 bouyer * Don't need to check hzto() return value, here. 2428 1.19.2.1 bouyer * callout_reset() does it for us. 2429 1.19.2.1 bouyer */ 2430 1.6 eeh timeradd(&aitv.it_value, &time, &aitv.it_value); 2431 1.19.2.1 bouyer callout_reset(&p->p_realit_ch, hzto(&aitv.it_value), 2432 1.19.2.1 bouyer realitexpire, p); 2433 1.6 eeh } 2434 1.6 eeh p->p_realtimer = aitv; 2435 1.1 mrg } else 2436 1.6 eeh p->p_stats->p_timer[which] = aitv; 2437 1.6 eeh splx(s); 2438 1.6 eeh return (0); 2439 1.6 eeh } 2440 1.1 mrg 2441 1.1 mrg int 2442 1.19 eeh netbsd32_getitimer(p, v, retval) 2443 1.1 mrg struct proc *p; 2444 1.1 mrg void *v; 2445 1.1 mrg register_t *retval; 2446 1.1 mrg { 2447 1.19 eeh struct netbsd32_getitimer_args /* { 2448 1.1 mrg syscallarg(int) which; 2449 1.10 mrg syscallarg(netbsd32_itimervalp_t) itv; 2450 1.1 mrg } */ *uap = v; 2451 1.6 eeh int which = SCARG(uap, which); 2452 1.10 mrg struct netbsd32_itimerval s32it; 2453 1.6 eeh struct itimerval aitv; 2454 1.6 eeh int s; 2455 1.1 mrg 2456 1.6 eeh if ((u_int)which > ITIMER_PROF) 2457 1.6 eeh return (EINVAL); 2458 1.6 eeh s = splclock(); 2459 1.6 eeh if (which == ITIMER_REAL) { 2460 1.6 eeh /* 2461 1.6 eeh * Convert from absolute to relative time in .it_value 2462 1.6 eeh * part of real time timer. If time for real time timer 2463 1.6 eeh * has passed return 0, else return difference between 2464 1.6 eeh * current time and time for the timer to go off. 2465 1.6 eeh */ 2466 1.6 eeh aitv = p->p_realtimer; 2467 1.6 eeh if (timerisset(&aitv.it_value)) { 2468 1.6 eeh if (timercmp(&aitv.it_value, &time, <)) 2469 1.6 eeh timerclear(&aitv.it_value); 2470 1.6 eeh else 2471 1.6 eeh timersub(&aitv.it_value, &time, &aitv.it_value); 2472 1.6 eeh } 2473 1.6 eeh } else 2474 1.6 eeh aitv = p->p_stats->p_timer[which]; 2475 1.6 eeh splx(s); 2476 1.10 mrg netbsd32_from_itimerval(&aitv, &s32it); 2477 1.6 eeh return (copyout(&s32it, (caddr_t)(u_long)SCARG(uap, itv), sizeof(s32it))); 2478 1.1 mrg } 2479 1.1 mrg 2480 1.1 mrg int 2481 1.19 eeh netbsd32_fcntl(p, v, retval) 2482 1.1 mrg struct proc *p; 2483 1.1 mrg void *v; 2484 1.1 mrg register_t *retval; 2485 1.1 mrg { 2486 1.19 eeh struct netbsd32_fcntl_args /* { 2487 1.1 mrg syscallarg(int) fd; 2488 1.1 mrg syscallarg(int) cmd; 2489 1.10 mrg syscallarg(netbsd32_voidp) arg; 2490 1.1 mrg } */ *uap = v; 2491 1.1 mrg struct sys_fcntl_args ua; 2492 1.1 mrg 2493 1.11 mrg NETBSD32TO64_UAP(fd); 2494 1.11 mrg NETBSD32TO64_UAP(cmd); 2495 1.11 mrg NETBSD32TOP_UAP(arg, void); 2496 1.6 eeh /* XXXX we can do this 'cause flock doesn't change */ 2497 1.1 mrg return (sys_fcntl(p, &ua, retval)); 2498 1.1 mrg } 2499 1.1 mrg 2500 1.1 mrg int 2501 1.19 eeh netbsd32_dup2(p, v, retval) 2502 1.6 eeh struct proc *p; 2503 1.6 eeh void *v; 2504 1.6 eeh register_t *retval; 2505 1.6 eeh { 2506 1.19 eeh struct netbsd32_dup2_args /* { 2507 1.6 eeh syscallarg(int) from; 2508 1.6 eeh syscallarg(int) to; 2509 1.6 eeh } */ *uap = v; 2510 1.6 eeh struct sys_dup2_args ua; 2511 1.6 eeh 2512 1.11 mrg NETBSD32TO64_UAP(from); 2513 1.11 mrg NETBSD32TO64_UAP(to); 2514 1.6 eeh return (sys_dup2(p, &ua, retval)); 2515 1.6 eeh } 2516 1.6 eeh 2517 1.6 eeh int 2518 1.19 eeh netbsd32_select(p, v, retval) 2519 1.1 mrg struct proc *p; 2520 1.1 mrg void *v; 2521 1.1 mrg register_t *retval; 2522 1.1 mrg { 2523 1.19 eeh struct netbsd32_select_args /* { 2524 1.1 mrg syscallarg(int) nd; 2525 1.10 mrg syscallarg(netbsd32_fd_setp_t) in; 2526 1.10 mrg syscallarg(netbsd32_fd_setp_t) ou; 2527 1.10 mrg syscallarg(netbsd32_fd_setp_t) ex; 2528 1.10 mrg syscallarg(netbsd32_timevalp_t) tv; 2529 1.1 mrg } */ *uap = v; 2530 1.6 eeh /* This one must be done in-line 'cause of the timeval */ 2531 1.10 mrg struct netbsd32_timeval tv32; 2532 1.6 eeh caddr_t bits; 2533 1.6 eeh char smallbits[howmany(FD_SETSIZE, NFDBITS) * sizeof(fd_mask) * 6]; 2534 1.6 eeh struct timeval atv; 2535 1.6 eeh int s, ncoll, error = 0, timo; 2536 1.6 eeh size_t ni; 2537 1.6 eeh extern int selwait, nselcoll; 2538 1.6 eeh extern int selscan __P((struct proc *, fd_mask *, fd_mask *, int, register_t *)); 2539 1.1 mrg 2540 1.6 eeh if (SCARG(uap, nd) < 0) 2541 1.6 eeh return (EINVAL); 2542 1.6 eeh if (SCARG(uap, nd) > p->p_fd->fd_nfiles) { 2543 1.6 eeh /* forgiving; slightly wrong */ 2544 1.6 eeh SCARG(uap, nd) = p->p_fd->fd_nfiles; 2545 1.5 eeh } 2546 1.6 eeh ni = howmany(SCARG(uap, nd), NFDBITS) * sizeof(fd_mask); 2547 1.6 eeh if (ni * 6 > sizeof(smallbits)) 2548 1.6 eeh bits = malloc(ni * 6, M_TEMP, M_WAITOK); 2549 1.6 eeh else 2550 1.6 eeh bits = smallbits; 2551 1.1 mrg 2552 1.6 eeh #define getbits(name, x) \ 2553 1.6 eeh if (SCARG(uap, name)) { \ 2554 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, name), bits + ni * x, ni); \ 2555 1.6 eeh if (error) \ 2556 1.6 eeh goto done; \ 2557 1.6 eeh } else \ 2558 1.6 eeh memset(bits + ni * x, 0, ni); 2559 1.6 eeh getbits(in, 0); 2560 1.6 eeh getbits(ou, 1); 2561 1.6 eeh getbits(ex, 2); 2562 1.6 eeh #undef getbits 2563 1.6 eeh 2564 1.6 eeh if (SCARG(uap, tv)) { 2565 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, tv), (caddr_t)&tv32, 2566 1.6 eeh sizeof(tv32)); 2567 1.6 eeh if (error) 2568 1.6 eeh goto done; 2569 1.10 mrg netbsd32_to_timeval(&tv32, &atv); 2570 1.6 eeh if (itimerfix(&atv)) { 2571 1.6 eeh error = EINVAL; 2572 1.6 eeh goto done; 2573 1.6 eeh } 2574 1.6 eeh s = splclock(); 2575 1.6 eeh timeradd(&atv, &time, &atv); 2576 1.6 eeh splx(s); 2577 1.6 eeh } else 2578 1.6 eeh timo = 0; 2579 1.6 eeh retry: 2580 1.6 eeh ncoll = nselcoll; 2581 1.6 eeh p->p_flag |= P_SELECT; 2582 1.6 eeh error = selscan(p, (fd_mask *)(bits + ni * 0), 2583 1.6 eeh (fd_mask *)(bits + ni * 3), SCARG(uap, nd), retval); 2584 1.6 eeh if (error || *retval) 2585 1.6 eeh goto done; 2586 1.19.2.1 bouyer if (SCARG(uap, tv)) { 2587 1.19.2.1 bouyer /* 2588 1.19.2.1 bouyer * We have to recalculate the timeout on every retry. 2589 1.19.2.1 bouyer */ 2590 1.19.2.1 bouyer timo = hzto(&atv); 2591 1.19.2.1 bouyer if (timo <= 0) 2592 1.19.2.1 bouyer goto done; 2593 1.6 eeh } 2594 1.19.2.1 bouyer s = splhigh(); 2595 1.6 eeh if ((p->p_flag & P_SELECT) == 0 || nselcoll != ncoll) { 2596 1.6 eeh splx(s); 2597 1.6 eeh goto retry; 2598 1.6 eeh } 2599 1.6 eeh p->p_flag &= ~P_SELECT; 2600 1.6 eeh error = tsleep((caddr_t)&selwait, PSOCK | PCATCH, "select", timo); 2601 1.6 eeh splx(s); 2602 1.6 eeh if (error == 0) 2603 1.6 eeh goto retry; 2604 1.6 eeh done: 2605 1.6 eeh p->p_flag &= ~P_SELECT; 2606 1.6 eeh /* select is not restarted after signals... */ 2607 1.6 eeh if (error == ERESTART) 2608 1.6 eeh error = EINTR; 2609 1.6 eeh if (error == EWOULDBLOCK) 2610 1.6 eeh error = 0; 2611 1.6 eeh if (error == 0) { 2612 1.6 eeh #define putbits(name, x) \ 2613 1.6 eeh if (SCARG(uap, name)) { \ 2614 1.6 eeh error = copyout(bits + ni * x, (caddr_t)(u_long)SCARG(uap, name), ni); \ 2615 1.6 eeh if (error) \ 2616 1.6 eeh goto out; \ 2617 1.6 eeh } 2618 1.6 eeh putbits(in, 3); 2619 1.6 eeh putbits(ou, 4); 2620 1.6 eeh putbits(ex, 5); 2621 1.6 eeh #undef putbits 2622 1.5 eeh } 2623 1.6 eeh out: 2624 1.6 eeh if (ni * 6 > sizeof(smallbits)) 2625 1.6 eeh free(bits, M_TEMP); 2626 1.6 eeh return (error); 2627 1.6 eeh } 2628 1.6 eeh 2629 1.6 eeh int 2630 1.19 eeh netbsd32_fsync(p, v, retval) 2631 1.6 eeh struct proc *p; 2632 1.6 eeh void *v; 2633 1.6 eeh register_t *retval; 2634 1.6 eeh { 2635 1.19 eeh struct netbsd32_fsync_args /* { 2636 1.6 eeh syscallarg(int) fd; 2637 1.6 eeh } */ *uap = v; 2638 1.6 eeh struct sys_fsync_args ua; 2639 1.1 mrg 2640 1.11 mrg NETBSD32TO64_UAP(fd); 2641 1.6 eeh return (sys_fsync(p, &ua, retval)); 2642 1.6 eeh } 2643 1.6 eeh 2644 1.6 eeh int 2645 1.19 eeh netbsd32_setpriority(p, v, retval) 2646 1.6 eeh struct proc *p; 2647 1.6 eeh void *v; 2648 1.6 eeh register_t *retval; 2649 1.6 eeh { 2650 1.19 eeh struct netbsd32_setpriority_args /* { 2651 1.6 eeh syscallarg(int) which; 2652 1.6 eeh syscallarg(int) who; 2653 1.6 eeh syscallarg(int) prio; 2654 1.6 eeh } */ *uap = v; 2655 1.6 eeh struct sys_setpriority_args ua; 2656 1.6 eeh 2657 1.11 mrg NETBSD32TO64_UAP(which); 2658 1.11 mrg NETBSD32TO64_UAP(who); 2659 1.11 mrg NETBSD32TO64_UAP(prio); 2660 1.6 eeh return (sys_setpriority(p, &ua, retval)); 2661 1.6 eeh } 2662 1.6 eeh 2663 1.6 eeh int 2664 1.19 eeh netbsd32_socket(p, v, retval) 2665 1.6 eeh struct proc *p; 2666 1.6 eeh void *v; 2667 1.6 eeh register_t *retval; 2668 1.6 eeh { 2669 1.19 eeh struct netbsd32_socket_args /* { 2670 1.6 eeh syscallarg(int) domain; 2671 1.6 eeh syscallarg(int) type; 2672 1.6 eeh syscallarg(int) protocol; 2673 1.6 eeh } */ *uap = v; 2674 1.6 eeh struct sys_socket_args ua; 2675 1.6 eeh 2676 1.11 mrg NETBSD32TO64_UAP(domain); 2677 1.11 mrg NETBSD32TO64_UAP(type); 2678 1.11 mrg NETBSD32TO64_UAP(protocol); 2679 1.6 eeh return (sys_socket(p, &ua, retval)); 2680 1.1 mrg } 2681 1.1 mrg 2682 1.1 mrg int 2683 1.19 eeh netbsd32_connect(p, v, retval) 2684 1.1 mrg struct proc *p; 2685 1.1 mrg void *v; 2686 1.1 mrg register_t *retval; 2687 1.1 mrg { 2688 1.19 eeh struct netbsd32_connect_args /* { 2689 1.1 mrg syscallarg(int) s; 2690 1.10 mrg syscallarg(const netbsd32_sockaddrp_t) name; 2691 1.1 mrg syscallarg(int) namelen; 2692 1.1 mrg } */ *uap = v; 2693 1.1 mrg struct sys_connect_args ua; 2694 1.1 mrg 2695 1.11 mrg NETBSD32TO64_UAP(s); 2696 1.11 mrg NETBSD32TOP_UAP(name, struct sockaddr); 2697 1.11 mrg NETBSD32TO64_UAP(namelen); 2698 1.1 mrg return (sys_connect(p, &ua, retval)); 2699 1.1 mrg } 2700 1.1 mrg 2701 1.6 eeh int 2702 1.19 eeh netbsd32_getpriority(p, v, retval) 2703 1.6 eeh struct proc *p; 2704 1.6 eeh void *v; 2705 1.6 eeh register_t *retval; 2706 1.6 eeh { 2707 1.19 eeh struct netbsd32_getpriority_args /* { 2708 1.6 eeh syscallarg(int) which; 2709 1.6 eeh syscallarg(int) who; 2710 1.6 eeh } */ *uap = v; 2711 1.6 eeh struct sys_getpriority_args ua; 2712 1.6 eeh 2713 1.11 mrg NETBSD32TO64_UAP(which); 2714 1.11 mrg NETBSD32TO64_UAP(who); 2715 1.6 eeh return (sys_getpriority(p, &ua, retval)); 2716 1.6 eeh } 2717 1.6 eeh 2718 1.1 mrg int 2719 1.19 eeh netbsd32_bind(p, v, retval) 2720 1.1 mrg struct proc *p; 2721 1.1 mrg void *v; 2722 1.1 mrg register_t *retval; 2723 1.1 mrg { 2724 1.19 eeh struct netbsd32_bind_args /* { 2725 1.1 mrg syscallarg(int) s; 2726 1.10 mrg syscallarg(const netbsd32_sockaddrp_t) name; 2727 1.1 mrg syscallarg(int) namelen; 2728 1.1 mrg } */ *uap = v; 2729 1.6 eeh struct sys_bind_args ua; 2730 1.1 mrg 2731 1.11 mrg NETBSD32TO64_UAP(s); 2732 1.11 mrg NETBSD32TOP_UAP(name, struct sockaddr); 2733 1.11 mrg NETBSD32TO64_UAP(namelen); 2734 1.6 eeh return (sys_bind(p, &ua, retval)); 2735 1.1 mrg } 2736 1.1 mrg 2737 1.1 mrg int 2738 1.19 eeh netbsd32_setsockopt(p, v, retval) 2739 1.1 mrg struct proc *p; 2740 1.1 mrg void *v; 2741 1.1 mrg register_t *retval; 2742 1.1 mrg { 2743 1.19 eeh struct netbsd32_setsockopt_args /* { 2744 1.1 mrg syscallarg(int) s; 2745 1.1 mrg syscallarg(int) level; 2746 1.1 mrg syscallarg(int) name; 2747 1.10 mrg syscallarg(const netbsd32_voidp) val; 2748 1.1 mrg syscallarg(int) valsize; 2749 1.1 mrg } */ *uap = v; 2750 1.1 mrg struct sys_setsockopt_args ua; 2751 1.1 mrg 2752 1.11 mrg NETBSD32TO64_UAP(s); 2753 1.11 mrg NETBSD32TO64_UAP(level); 2754 1.11 mrg NETBSD32TO64_UAP(name); 2755 1.11 mrg NETBSD32TOP_UAP(val, void); 2756 1.11 mrg NETBSD32TO64_UAP(valsize); 2757 1.6 eeh /* may be more efficient to do this inline. */ 2758 1.1 mrg return (sys_setsockopt(p, &ua, retval)); 2759 1.1 mrg } 2760 1.1 mrg 2761 1.1 mrg int 2762 1.19 eeh netbsd32_listen(p, v, retval) 2763 1.6 eeh struct proc *p; 2764 1.6 eeh void *v; 2765 1.6 eeh register_t *retval; 2766 1.6 eeh { 2767 1.19 eeh struct netbsd32_listen_args /* { 2768 1.6 eeh syscallarg(int) s; 2769 1.6 eeh syscallarg(int) backlog; 2770 1.6 eeh } */ *uap = v; 2771 1.6 eeh struct sys_listen_args ua; 2772 1.6 eeh 2773 1.11 mrg NETBSD32TO64_UAP(s); 2774 1.11 mrg NETBSD32TO64_UAP(backlog); 2775 1.6 eeh return (sys_listen(p, &ua, retval)); 2776 1.6 eeh } 2777 1.6 eeh 2778 1.6 eeh int 2779 1.19 eeh netbsd32_gettimeofday(p, v, retval) 2780 1.1 mrg struct proc *p; 2781 1.1 mrg void *v; 2782 1.1 mrg register_t *retval; 2783 1.1 mrg { 2784 1.19 eeh struct netbsd32_gettimeofday_args /* { 2785 1.10 mrg syscallarg(netbsd32_timevalp_t) tp; 2786 1.10 mrg syscallarg(netbsd32_timezonep_t) tzp; 2787 1.1 mrg } */ *uap = v; 2788 1.6 eeh struct timeval atv; 2789 1.10 mrg struct netbsd32_timeval tv32; 2790 1.6 eeh int error = 0; 2791 1.10 mrg struct netbsd32_timezone tzfake; 2792 1.6 eeh 2793 1.6 eeh if (SCARG(uap, tp)) { 2794 1.6 eeh microtime(&atv); 2795 1.10 mrg netbsd32_from_timeval(&atv, &tv32); 2796 1.6 eeh error = copyout(&tv32, (caddr_t)(u_long)SCARG(uap, tp), sizeof(tv32)); 2797 1.6 eeh if (error) 2798 1.6 eeh return (error); 2799 1.6 eeh } 2800 1.6 eeh if (SCARG(uap, tzp)) { 2801 1.6 eeh /* 2802 1.6 eeh * NetBSD has no kernel notion of time zone, so we just 2803 1.6 eeh * fake up a timezone struct and return it if demanded. 2804 1.6 eeh */ 2805 1.6 eeh tzfake.tz_minuteswest = 0; 2806 1.6 eeh tzfake.tz_dsttime = 0; 2807 1.6 eeh error = copyout(&tzfake, (caddr_t)(u_long)SCARG(uap, tzp), sizeof(tzfake)); 2808 1.6 eeh } 2809 1.6 eeh return (error); 2810 1.6 eeh } 2811 1.1 mrg 2812 1.19.2.1 bouyer #if 0 2813 1.19.2.1 bouyer static int settime32 __P((struct timeval *)); 2814 1.6 eeh /* This function is used by clock_settime and settimeofday */ 2815 1.6 eeh static int 2816 1.19.2.1 bouyer settime32(tv) 2817 1.6 eeh struct timeval *tv; 2818 1.6 eeh { 2819 1.6 eeh struct timeval delta; 2820 1.6 eeh int s; 2821 1.1 mrg 2822 1.6 eeh /* WHAT DO WE DO ABOUT PENDING REAL-TIME TIMEOUTS??? */ 2823 1.6 eeh s = splclock(); 2824 1.6 eeh timersub(tv, &time, &delta); 2825 1.6 eeh if ((delta.tv_sec < 0 || delta.tv_usec < 0) && securelevel > 1) 2826 1.6 eeh return (EPERM); 2827 1.6 eeh #ifdef notyet 2828 1.6 eeh if ((delta.tv_sec < 86400) && securelevel > 0) 2829 1.6 eeh return (EPERM); 2830 1.6 eeh #endif 2831 1.6 eeh time = *tv; 2832 1.17 thorpej (void) spllowersoftclock(); 2833 1.6 eeh timeradd(&boottime, &delta, &boottime); 2834 1.6 eeh timeradd(&runtime, &delta, &runtime); 2835 1.6 eeh # if defined(NFS) || defined(NFSSERVER) 2836 1.19.2.1 bouyer { 2837 1.19.2.1 bouyer extern void nqnfs_lease_updatetime __P((int)); 2838 1.19.2.1 bouyer 2839 1.6 eeh nqnfs_lease_updatetime(delta.tv_sec); 2840 1.19.2.1 bouyer } 2841 1.6 eeh # endif 2842 1.6 eeh splx(s); 2843 1.6 eeh resettodr(); 2844 1.1 mrg return (0); 2845 1.1 mrg } 2846 1.19.2.1 bouyer #endif 2847 1.6 eeh 2848 1.1 mrg int 2849 1.19 eeh netbsd32_settimeofday(p, v, retval) 2850 1.1 mrg struct proc *p; 2851 1.1 mrg void *v; 2852 1.1 mrg register_t *retval; 2853 1.1 mrg { 2854 1.19 eeh struct netbsd32_settimeofday_args /* { 2855 1.10 mrg syscallarg(const netbsd32_timevalp_t) tv; 2856 1.10 mrg syscallarg(const netbsd32_timezonep_t) tzp; 2857 1.1 mrg } */ *uap = v; 2858 1.10 mrg struct netbsd32_timeval atv32; 2859 1.6 eeh struct timeval atv; 2860 1.10 mrg struct netbsd32_timezone atz; 2861 1.1 mrg int error; 2862 1.1 mrg 2863 1.6 eeh if ((error = suser(p->p_ucred, &p->p_acflag)) != 0) 2864 1.6 eeh return (error); 2865 1.6 eeh /* Verify all parameters before changing time. */ 2866 1.6 eeh if (SCARG(uap, tv) && (error = copyin((caddr_t)(u_long)SCARG(uap, tv), 2867 1.6 eeh &atv32, sizeof(atv32)))) 2868 1.6 eeh return (error); 2869 1.10 mrg netbsd32_to_timeval(&atv32, &atv); 2870 1.6 eeh /* XXX since we don't use tz, probably no point in doing copyin. */ 2871 1.6 eeh if (SCARG(uap, tzp) && (error = copyin((caddr_t)(u_long)SCARG(uap, tzp), 2872 1.6 eeh &atz, sizeof(atz)))) 2873 1.1 mrg return (error); 2874 1.6 eeh if (SCARG(uap, tv)) 2875 1.6 eeh if ((error = settime(&atv))) 2876 1.6 eeh return (error); 2877 1.6 eeh /* 2878 1.6 eeh * NetBSD has no kernel notion of time zone, and only an 2879 1.6 eeh * obsolete program would try to set it, so we log a warning. 2880 1.6 eeh */ 2881 1.6 eeh if (SCARG(uap, tzp)) 2882 1.6 eeh printf("pid %d attempted to set the " 2883 1.6 eeh "(obsolete) kernel time zone\n", p->p_pid); 2884 1.6 eeh return (0); 2885 1.6 eeh } 2886 1.6 eeh 2887 1.6 eeh int 2888 1.19 eeh netbsd32_fchown(p, v, retval) 2889 1.6 eeh struct proc *p; 2890 1.6 eeh void *v; 2891 1.6 eeh register_t *retval; 2892 1.6 eeh { 2893 1.19 eeh struct netbsd32_fchown_args /* { 2894 1.6 eeh syscallarg(int) fd; 2895 1.6 eeh syscallarg(uid_t) uid; 2896 1.6 eeh syscallarg(gid_t) gid; 2897 1.6 eeh } */ *uap = v; 2898 1.6 eeh struct sys_fchown_args ua; 2899 1.6 eeh 2900 1.11 mrg NETBSD32TO64_UAP(fd); 2901 1.11 mrg NETBSD32TO64_UAP(uid); 2902 1.11 mrg NETBSD32TO64_UAP(gid); 2903 1.6 eeh return (sys_fchown(p, &ua, retval)); 2904 1.6 eeh } 2905 1.6 eeh 2906 1.6 eeh int 2907 1.19 eeh netbsd32_fchmod(p, v, retval) 2908 1.6 eeh struct proc *p; 2909 1.6 eeh void *v; 2910 1.6 eeh register_t *retval; 2911 1.6 eeh { 2912 1.19 eeh struct netbsd32_fchmod_args /* { 2913 1.6 eeh syscallarg(int) fd; 2914 1.6 eeh syscallarg(mode_t) mode; 2915 1.6 eeh } */ *uap = v; 2916 1.6 eeh struct sys_fchmod_args ua; 2917 1.6 eeh 2918 1.11 mrg NETBSD32TO64_UAP(fd); 2919 1.11 mrg NETBSD32TO64_UAP(mode); 2920 1.6 eeh return (sys_fchmod(p, &ua, retval)); 2921 1.6 eeh } 2922 1.6 eeh 2923 1.6 eeh int 2924 1.19 eeh netbsd32_setreuid(p, v, retval) 2925 1.6 eeh struct proc *p; 2926 1.6 eeh void *v; 2927 1.6 eeh register_t *retval; 2928 1.6 eeh { 2929 1.19 eeh struct netbsd32_setreuid_args /* { 2930 1.6 eeh syscallarg(uid_t) ruid; 2931 1.6 eeh syscallarg(uid_t) euid; 2932 1.6 eeh } */ *uap = v; 2933 1.6 eeh struct sys_setreuid_args ua; 2934 1.6 eeh 2935 1.11 mrg NETBSD32TO64_UAP(ruid); 2936 1.11 mrg NETBSD32TO64_UAP(euid); 2937 1.6 eeh return (sys_setreuid(p, &ua, retval)); 2938 1.6 eeh } 2939 1.1 mrg 2940 1.6 eeh int 2941 1.19 eeh netbsd32_setregid(p, v, retval) 2942 1.6 eeh struct proc *p; 2943 1.6 eeh void *v; 2944 1.6 eeh register_t *retval; 2945 1.6 eeh { 2946 1.19 eeh struct netbsd32_setregid_args /* { 2947 1.6 eeh syscallarg(gid_t) rgid; 2948 1.6 eeh syscallarg(gid_t) egid; 2949 1.6 eeh } */ *uap = v; 2950 1.6 eeh struct sys_setregid_args ua; 2951 1.6 eeh 2952 1.11 mrg NETBSD32TO64_UAP(rgid); 2953 1.11 mrg NETBSD32TO64_UAP(egid); 2954 1.6 eeh return (sys_setregid(p, &ua, retval)); 2955 1.1 mrg } 2956 1.1 mrg 2957 1.1 mrg int 2958 1.19 eeh netbsd32_getrusage(p, v, retval) 2959 1.1 mrg struct proc *p; 2960 1.1 mrg void *v; 2961 1.1 mrg register_t *retval; 2962 1.1 mrg { 2963 1.19 eeh struct netbsd32_getrusage_args /* { 2964 1.1 mrg syscallarg(int) who; 2965 1.10 mrg syscallarg(netbsd32_rusagep_t) rusage; 2966 1.1 mrg } */ *uap = v; 2967 1.6 eeh struct rusage *rup; 2968 1.10 mrg struct netbsd32_rusage ru; 2969 1.6 eeh 2970 1.6 eeh switch (SCARG(uap, who)) { 2971 1.1 mrg 2972 1.6 eeh case RUSAGE_SELF: 2973 1.6 eeh rup = &p->p_stats->p_ru; 2974 1.6 eeh calcru(p, &rup->ru_utime, &rup->ru_stime, NULL); 2975 1.6 eeh break; 2976 1.1 mrg 2977 1.6 eeh case RUSAGE_CHILDREN: 2978 1.6 eeh rup = &p->p_stats->p_cru; 2979 1.6 eeh break; 2980 1.1 mrg 2981 1.6 eeh default: 2982 1.6 eeh return (EINVAL); 2983 1.6 eeh } 2984 1.10 mrg netbsd32_from_rusage(rup, &ru); 2985 1.6 eeh return (copyout(&ru, (caddr_t)(u_long)SCARG(uap, rusage), sizeof(ru))); 2986 1.1 mrg } 2987 1.1 mrg 2988 1.1 mrg int 2989 1.19 eeh netbsd32_getsockopt(p, v, retval) 2990 1.1 mrg struct proc *p; 2991 1.1 mrg void *v; 2992 1.1 mrg register_t *retval; 2993 1.1 mrg { 2994 1.19 eeh struct netbsd32_getsockopt_args /* { 2995 1.1 mrg syscallarg(int) s; 2996 1.1 mrg syscallarg(int) level; 2997 1.1 mrg syscallarg(int) name; 2998 1.10 mrg syscallarg(netbsd32_voidp) val; 2999 1.10 mrg syscallarg(netbsd32_intp) avalsize; 3000 1.1 mrg } */ *uap = v; 3001 1.1 mrg struct sys_getsockopt_args ua; 3002 1.1 mrg 3003 1.11 mrg NETBSD32TO64_UAP(s); 3004 1.11 mrg NETBSD32TO64_UAP(level); 3005 1.11 mrg NETBSD32TO64_UAP(name); 3006 1.11 mrg NETBSD32TOP_UAP(val, void); 3007 1.11 mrg NETBSD32TOP_UAP(avalsize, int); 3008 1.1 mrg return (sys_getsockopt(p, &ua, retval)); 3009 1.1 mrg } 3010 1.1 mrg 3011 1.1 mrg int 3012 1.19 eeh netbsd32_readv(p, v, retval) 3013 1.1 mrg struct proc *p; 3014 1.1 mrg void *v; 3015 1.1 mrg register_t *retval; 3016 1.1 mrg { 3017 1.19 eeh struct netbsd32_readv_args /* { 3018 1.1 mrg syscallarg(int) fd; 3019 1.10 mrg syscallarg(const netbsd32_iovecp_t) iovp; 3020 1.1 mrg syscallarg(int) iovcnt; 3021 1.1 mrg } */ *uap = v; 3022 1.6 eeh int fd = SCARG(uap, fd); 3023 1.19.2.1 bouyer struct file *fp; 3024 1.19.2.1 bouyer struct filedesc *fdp = p->p_fd; 3025 1.6 eeh 3026 1.6 eeh if ((u_int)fd >= fdp->fd_nfiles || 3027 1.6 eeh (fp = fdp->fd_ofiles[fd]) == NULL || 3028 1.6 eeh (fp->f_flag & FREAD) == 0) 3029 1.6 eeh return (EBADF); 3030 1.6 eeh 3031 1.10 mrg return (dofilereadv32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp), 3032 1.6 eeh SCARG(uap, iovcnt), &fp->f_offset, FOF_UPDATE_OFFSET, retval)); 3033 1.6 eeh } 3034 1.6 eeh 3035 1.6 eeh /* Damn thing copies in the iovec! */ 3036 1.6 eeh int 3037 1.6 eeh dofilereadv32(p, fd, fp, iovp, iovcnt, offset, flags, retval) 3038 1.6 eeh struct proc *p; 3039 1.6 eeh int fd; 3040 1.6 eeh struct file *fp; 3041 1.10 mrg struct netbsd32_iovec *iovp; 3042 1.6 eeh int iovcnt; 3043 1.6 eeh off_t *offset; 3044 1.6 eeh int flags; 3045 1.6 eeh register_t *retval; 3046 1.6 eeh { 3047 1.6 eeh struct uio auio; 3048 1.19.2.1 bouyer struct iovec *iov; 3049 1.6 eeh struct iovec *needfree; 3050 1.6 eeh struct iovec aiov[UIO_SMALLIOV]; 3051 1.6 eeh long i, cnt, error = 0; 3052 1.6 eeh u_int iovlen; 3053 1.6 eeh #ifdef KTRACE 3054 1.6 eeh struct iovec *ktriov = NULL; 3055 1.6 eeh #endif 3056 1.1 mrg 3057 1.6 eeh /* note: can't use iovlen until iovcnt is validated */ 3058 1.6 eeh iovlen = iovcnt * sizeof(struct iovec); 3059 1.6 eeh if ((u_int)iovcnt > UIO_SMALLIOV) { 3060 1.6 eeh if ((u_int)iovcnt > IOV_MAX) 3061 1.6 eeh return (EINVAL); 3062 1.6 eeh MALLOC(iov, struct iovec *, iovlen, M_IOV, M_WAITOK); 3063 1.6 eeh needfree = iov; 3064 1.6 eeh } else if ((u_int)iovcnt > 0) { 3065 1.6 eeh iov = aiov; 3066 1.6 eeh needfree = NULL; 3067 1.6 eeh } else 3068 1.6 eeh return (EINVAL); 3069 1.1 mrg 3070 1.6 eeh auio.uio_iov = iov; 3071 1.6 eeh auio.uio_iovcnt = iovcnt; 3072 1.6 eeh auio.uio_rw = UIO_READ; 3073 1.6 eeh auio.uio_segflg = UIO_USERSPACE; 3074 1.6 eeh auio.uio_procp = p; 3075 1.10 mrg error = netbsd32_to_iovecin(iovp, iov, iovcnt); 3076 1.6 eeh if (error) 3077 1.6 eeh goto done; 3078 1.6 eeh auio.uio_resid = 0; 3079 1.6 eeh for (i = 0; i < iovcnt; i++) { 3080 1.6 eeh auio.uio_resid += iov->iov_len; 3081 1.6 eeh /* 3082 1.6 eeh * Reads return ssize_t because -1 is returned on error. 3083 1.6 eeh * Therefore we must restrict the length to SSIZE_MAX to 3084 1.6 eeh * avoid garbage return values. 3085 1.6 eeh */ 3086 1.6 eeh if (iov->iov_len > SSIZE_MAX || auio.uio_resid > SSIZE_MAX) { 3087 1.6 eeh error = EINVAL; 3088 1.6 eeh goto done; 3089 1.6 eeh } 3090 1.6 eeh iov++; 3091 1.6 eeh } 3092 1.6 eeh #ifdef KTRACE 3093 1.6 eeh /* 3094 1.6 eeh * if tracing, save a copy of iovec 3095 1.6 eeh */ 3096 1.6 eeh if (KTRPOINT(p, KTR_GENIO)) { 3097 1.6 eeh MALLOC(ktriov, struct iovec *, iovlen, M_TEMP, M_WAITOK); 3098 1.6 eeh memcpy((caddr_t)ktriov, (caddr_t)auio.uio_iov, iovlen); 3099 1.6 eeh } 3100 1.6 eeh #endif 3101 1.6 eeh cnt = auio.uio_resid; 3102 1.6 eeh error = (*fp->f_ops->fo_read)(fp, offset, &auio, fp->f_cred, flags); 3103 1.6 eeh if (error) 3104 1.6 eeh if (auio.uio_resid != cnt && (error == ERESTART || 3105 1.6 eeh error == EINTR || error == EWOULDBLOCK)) 3106 1.6 eeh error = 0; 3107 1.6 eeh cnt -= auio.uio_resid; 3108 1.6 eeh #ifdef KTRACE 3109 1.6 eeh if (KTRPOINT(p, KTR_GENIO)) 3110 1.6 eeh if (error == 0) { 3111 1.19.2.1 bouyer ktrgenio(p, fd, UIO_READ, ktriov, cnt, 3112 1.6 eeh error); 3113 1.6 eeh FREE(ktriov, M_TEMP); 3114 1.6 eeh } 3115 1.6 eeh #endif 3116 1.6 eeh *retval = cnt; 3117 1.6 eeh done: 3118 1.6 eeh if (needfree) 3119 1.6 eeh FREE(needfree, M_IOV); 3120 1.1 mrg return (error); 3121 1.1 mrg } 3122 1.1 mrg 3123 1.6 eeh 3124 1.1 mrg int 3125 1.19 eeh netbsd32_writev(p, v, retval) 3126 1.1 mrg struct proc *p; 3127 1.1 mrg void *v; 3128 1.1 mrg register_t *retval; 3129 1.1 mrg { 3130 1.19 eeh struct netbsd32_writev_args /* { 3131 1.1 mrg syscallarg(int) fd; 3132 1.10 mrg syscallarg(const netbsd32_iovecp_t) iovp; 3133 1.1 mrg syscallarg(int) iovcnt; 3134 1.1 mrg } */ *uap = v; 3135 1.6 eeh int fd = SCARG(uap, fd); 3136 1.19.2.1 bouyer struct file *fp; 3137 1.19.2.1 bouyer struct filedesc *fdp = p->p_fd; 3138 1.6 eeh 3139 1.6 eeh if ((u_int)fd >= fdp->fd_nfiles || 3140 1.6 eeh (fp = fdp->fd_ofiles[fd]) == NULL || 3141 1.6 eeh (fp->f_flag & FWRITE) == 0) 3142 1.6 eeh return (EBADF); 3143 1.6 eeh 3144 1.10 mrg return (dofilewritev32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp), 3145 1.6 eeh SCARG(uap, iovcnt), &fp->f_offset, FOF_UPDATE_OFFSET, retval)); 3146 1.6 eeh } 3147 1.6 eeh 3148 1.6 eeh int 3149 1.6 eeh dofilewritev32(p, fd, fp, iovp, iovcnt, offset, flags, retval) 3150 1.6 eeh struct proc *p; 3151 1.6 eeh int fd; 3152 1.6 eeh struct file *fp; 3153 1.10 mrg struct netbsd32_iovec *iovp; 3154 1.6 eeh int iovcnt; 3155 1.6 eeh off_t *offset; 3156 1.6 eeh int flags; 3157 1.6 eeh register_t *retval; 3158 1.6 eeh { 3159 1.6 eeh struct uio auio; 3160 1.19.2.1 bouyer struct iovec *iov; 3161 1.6 eeh struct iovec *needfree; 3162 1.6 eeh struct iovec aiov[UIO_SMALLIOV]; 3163 1.6 eeh long i, cnt, error = 0; 3164 1.6 eeh u_int iovlen; 3165 1.6 eeh #ifdef KTRACE 3166 1.6 eeh struct iovec *ktriov = NULL; 3167 1.6 eeh #endif 3168 1.1 mrg 3169 1.6 eeh /* note: can't use iovlen until iovcnt is validated */ 3170 1.6 eeh iovlen = iovcnt * sizeof(struct iovec); 3171 1.6 eeh if ((u_int)iovcnt > UIO_SMALLIOV) { 3172 1.6 eeh if ((u_int)iovcnt > IOV_MAX) 3173 1.6 eeh return (EINVAL); 3174 1.6 eeh MALLOC(iov, struct iovec *, iovlen, M_IOV, M_WAITOK); 3175 1.6 eeh needfree = iov; 3176 1.6 eeh } else if ((u_int)iovcnt > 0) { 3177 1.6 eeh iov = aiov; 3178 1.6 eeh needfree = NULL; 3179 1.6 eeh } else 3180 1.6 eeh return (EINVAL); 3181 1.1 mrg 3182 1.6 eeh auio.uio_iov = iov; 3183 1.6 eeh auio.uio_iovcnt = iovcnt; 3184 1.6 eeh auio.uio_rw = UIO_WRITE; 3185 1.6 eeh auio.uio_segflg = UIO_USERSPACE; 3186 1.6 eeh auio.uio_procp = p; 3187 1.10 mrg error = netbsd32_to_iovecin(iovp, iov, iovcnt); 3188 1.6 eeh if (error) 3189 1.6 eeh goto done; 3190 1.6 eeh auio.uio_resid = 0; 3191 1.6 eeh for (i = 0; i < iovcnt; i++) { 3192 1.6 eeh auio.uio_resid += iov->iov_len; 3193 1.6 eeh /* 3194 1.6 eeh * Writes return ssize_t because -1 is returned on error. 3195 1.6 eeh * Therefore we must restrict the length to SSIZE_MAX to 3196 1.6 eeh * avoid garbage return values. 3197 1.6 eeh */ 3198 1.6 eeh if (iov->iov_len > SSIZE_MAX || auio.uio_resid > SSIZE_MAX) { 3199 1.6 eeh error = EINVAL; 3200 1.6 eeh goto done; 3201 1.6 eeh } 3202 1.6 eeh iov++; 3203 1.6 eeh } 3204 1.6 eeh #ifdef KTRACE 3205 1.6 eeh /* 3206 1.6 eeh * if tracing, save a copy of iovec 3207 1.6 eeh */ 3208 1.6 eeh if (KTRPOINT(p, KTR_GENIO)) { 3209 1.6 eeh MALLOC(ktriov, struct iovec *, iovlen, M_TEMP, M_WAITOK); 3210 1.6 eeh memcpy((caddr_t)ktriov, (caddr_t)auio.uio_iov, iovlen); 3211 1.6 eeh } 3212 1.6 eeh #endif 3213 1.6 eeh cnt = auio.uio_resid; 3214 1.6 eeh error = (*fp->f_ops->fo_write)(fp, offset, &auio, fp->f_cred, flags); 3215 1.6 eeh if (error) { 3216 1.6 eeh if (auio.uio_resid != cnt && (error == ERESTART || 3217 1.6 eeh error == EINTR || error == EWOULDBLOCK)) 3218 1.6 eeh error = 0; 3219 1.6 eeh if (error == EPIPE) 3220 1.6 eeh psignal(p, SIGPIPE); 3221 1.6 eeh } 3222 1.6 eeh cnt -= auio.uio_resid; 3223 1.6 eeh #ifdef KTRACE 3224 1.6 eeh if (KTRPOINT(p, KTR_GENIO)) 3225 1.6 eeh if (error == 0) { 3226 1.19.2.1 bouyer ktrgenio(p, fd, UIO_WRITE, ktriov, cnt, 3227 1.6 eeh error); 3228 1.6 eeh FREE(ktriov, M_TEMP); 3229 1.6 eeh } 3230 1.6 eeh #endif 3231 1.6 eeh *retval = cnt; 3232 1.6 eeh done: 3233 1.6 eeh if (needfree) 3234 1.6 eeh FREE(needfree, M_IOV); 3235 1.1 mrg return (error); 3236 1.1 mrg } 3237 1.1 mrg 3238 1.6 eeh 3239 1.1 mrg int 3240 1.19 eeh netbsd32_rename(p, v, retval) 3241 1.1 mrg struct proc *p; 3242 1.1 mrg void *v; 3243 1.1 mrg register_t *retval; 3244 1.1 mrg { 3245 1.19 eeh struct netbsd32_rename_args /* { 3246 1.10 mrg syscallarg(const netbsd32_charp) from; 3247 1.10 mrg syscallarg(const netbsd32_charp) to; 3248 1.1 mrg } */ *uap = v; 3249 1.1 mrg struct sys_rename_args ua; 3250 1.1 mrg 3251 1.19.2.1 bouyer NETBSD32TOP_UAP(from, const char); 3252 1.19.2.1 bouyer NETBSD32TOP_UAP(to, const char) 3253 1.6 eeh 3254 1.1 mrg return (sys_rename(p, &ua, retval)); 3255 1.1 mrg } 3256 1.1 mrg 3257 1.1 mrg int 3258 1.19 eeh netbsd32_flock(p, v, retval) 3259 1.6 eeh struct proc *p; 3260 1.6 eeh void *v; 3261 1.6 eeh register_t *retval; 3262 1.6 eeh { 3263 1.19 eeh struct netbsd32_flock_args /* { 3264 1.6 eeh syscallarg(int) fd; 3265 1.6 eeh syscallarg(int) how; 3266 1.6 eeh } */ *uap = v; 3267 1.6 eeh struct sys_flock_args ua; 3268 1.6 eeh 3269 1.11 mrg NETBSD32TO64_UAP(fd); 3270 1.11 mrg NETBSD32TO64_UAP(how) 3271 1.6 eeh 3272 1.6 eeh return (sys_flock(p, &ua, retval)); 3273 1.6 eeh } 3274 1.6 eeh 3275 1.6 eeh int 3276 1.19 eeh netbsd32_mkfifo(p, v, retval) 3277 1.1 mrg struct proc *p; 3278 1.1 mrg void *v; 3279 1.1 mrg register_t *retval; 3280 1.1 mrg { 3281 1.19 eeh struct netbsd32_mkfifo_args /* { 3282 1.10 mrg syscallarg(const netbsd32_charp) path; 3283 1.1 mrg syscallarg(mode_t) mode; 3284 1.1 mrg } */ *uap = v; 3285 1.1 mrg struct sys_mkfifo_args ua; 3286 1.1 mrg 3287 1.11 mrg NETBSD32TOP_UAP(path, const char) 3288 1.11 mrg NETBSD32TO64_UAP(mode); 3289 1.1 mrg return (sys_mkfifo(p, &ua, retval)); 3290 1.1 mrg } 3291 1.1 mrg 3292 1.1 mrg int 3293 1.19 eeh netbsd32_shutdown(p, v, retval) 3294 1.6 eeh struct proc *p; 3295 1.6 eeh void *v; 3296 1.6 eeh register_t *retval; 3297 1.6 eeh { 3298 1.19 eeh struct netbsd32_shutdown_args /* { 3299 1.6 eeh syscallarg(int) s; 3300 1.6 eeh syscallarg(int) how; 3301 1.6 eeh } */ *uap = v; 3302 1.6 eeh struct sys_shutdown_args ua; 3303 1.6 eeh 3304 1.11 mrg NETBSD32TO64_UAP(s) 3305 1.11 mrg NETBSD32TO64_UAP(how); 3306 1.6 eeh return (sys_shutdown(p, &ua, retval)); 3307 1.6 eeh } 3308 1.6 eeh 3309 1.6 eeh int 3310 1.19 eeh netbsd32_socketpair(p, v, retval) 3311 1.6 eeh struct proc *p; 3312 1.6 eeh void *v; 3313 1.6 eeh register_t *retval; 3314 1.6 eeh { 3315 1.19 eeh struct netbsd32_socketpair_args /* { 3316 1.6 eeh syscallarg(int) domain; 3317 1.6 eeh syscallarg(int) type; 3318 1.6 eeh syscallarg(int) protocol; 3319 1.10 mrg syscallarg(netbsd32_intp) rsv; 3320 1.6 eeh } */ *uap = v; 3321 1.6 eeh struct sys_socketpair_args ua; 3322 1.6 eeh 3323 1.11 mrg NETBSD32TO64_UAP(domain); 3324 1.11 mrg NETBSD32TO64_UAP(type); 3325 1.11 mrg NETBSD32TO64_UAP(protocol); 3326 1.11 mrg NETBSD32TOP_UAP(rsv, int); 3327 1.6 eeh /* Since we're just copying out two `int's we can do this */ 3328 1.6 eeh return (sys_socketpair(p, &ua, retval)); 3329 1.6 eeh } 3330 1.6 eeh 3331 1.6 eeh int 3332 1.19 eeh netbsd32_mkdir(p, v, retval) 3333 1.1 mrg struct proc *p; 3334 1.1 mrg void *v; 3335 1.1 mrg register_t *retval; 3336 1.1 mrg { 3337 1.19 eeh struct netbsd32_mkdir_args /* { 3338 1.10 mrg syscallarg(const netbsd32_charp) path; 3339 1.1 mrg syscallarg(mode_t) mode; 3340 1.1 mrg } */ *uap = v; 3341 1.1 mrg struct sys_mkdir_args ua; 3342 1.1 mrg 3343 1.11 mrg NETBSD32TOP_UAP(path, const char) 3344 1.11 mrg NETBSD32TO64_UAP(mode); 3345 1.1 mrg return (sys_mkdir(p, &ua, retval)); 3346 1.1 mrg } 3347 1.1 mrg 3348 1.1 mrg int 3349 1.19 eeh netbsd32_rmdir(p, v, retval) 3350 1.1 mrg struct proc *p; 3351 1.1 mrg void *v; 3352 1.1 mrg register_t *retval; 3353 1.1 mrg { 3354 1.19 eeh struct netbsd32_rmdir_args /* { 3355 1.10 mrg syscallarg(const netbsd32_charp) path; 3356 1.1 mrg } */ *uap = v; 3357 1.1 mrg struct sys_rmdir_args ua; 3358 1.1 mrg 3359 1.11 mrg NETBSD32TOP_UAP(path, const char); 3360 1.1 mrg return (sys_rmdir(p, &ua, retval)); 3361 1.1 mrg } 3362 1.1 mrg 3363 1.1 mrg int 3364 1.19 eeh netbsd32_utimes(p, v, retval) 3365 1.1 mrg struct proc *p; 3366 1.1 mrg void *v; 3367 1.1 mrg register_t *retval; 3368 1.1 mrg { 3369 1.19 eeh struct netbsd32_utimes_args /* { 3370 1.10 mrg syscallarg(const netbsd32_charp) path; 3371 1.10 mrg syscallarg(const netbsd32_timevalp_t) tptr; 3372 1.1 mrg } */ *uap = v; 3373 1.6 eeh int error; 3374 1.6 eeh struct nameidata nd; 3375 1.6 eeh 3376 1.6 eeh NDINIT(&nd, LOOKUP, FOLLOW, UIO_USERSPACE, (char *)(u_long)SCARG(uap, path), p); 3377 1.6 eeh if ((error = namei(&nd)) != 0) 3378 1.6 eeh return (error); 3379 1.1 mrg 3380 1.6 eeh error = change_utimes32(nd.ni_vp, (struct timeval *)(u_long)SCARG(uap, tptr), p); 3381 1.1 mrg 3382 1.6 eeh vrele(nd.ni_vp); 3383 1.6 eeh return (error); 3384 1.6 eeh } 3385 1.6 eeh 3386 1.6 eeh /* 3387 1.6 eeh * Common routine to set access and modification times given a vnode. 3388 1.6 eeh */ 3389 1.6 eeh static int 3390 1.6 eeh change_utimes32(vp, tptr, p) 3391 1.6 eeh struct vnode *vp; 3392 1.6 eeh struct timeval *tptr; 3393 1.6 eeh struct proc *p; 3394 1.6 eeh { 3395 1.10 mrg struct netbsd32_timeval tv32[2]; 3396 1.6 eeh struct timeval tv[2]; 3397 1.6 eeh struct vattr vattr; 3398 1.6 eeh int error; 3399 1.6 eeh 3400 1.6 eeh VATTR_NULL(&vattr); 3401 1.6 eeh if (tptr == NULL) { 3402 1.6 eeh microtime(&tv[0]); 3403 1.6 eeh tv[1] = tv[0]; 3404 1.6 eeh vattr.va_vaflags |= VA_UTIMES_NULL; 3405 1.6 eeh } else { 3406 1.6 eeh error = copyin(tptr, tv, sizeof(tv)); 3407 1.6 eeh if (error) 3408 1.6 eeh return (error); 3409 1.6 eeh } 3410 1.10 mrg netbsd32_to_timeval(&tv32[0], &tv[0]); 3411 1.10 mrg netbsd32_to_timeval(&tv32[1], &tv[1]); 3412 1.6 eeh VOP_LEASE(vp, p, p->p_ucred, LEASE_WRITE); 3413 1.6 eeh vn_lock(vp, LK_EXCLUSIVE | LK_RETRY); 3414 1.6 eeh vattr.va_atime.tv_sec = tv[0].tv_sec; 3415 1.6 eeh vattr.va_atime.tv_nsec = tv[0].tv_usec * 1000; 3416 1.6 eeh vattr.va_mtime.tv_sec = tv[1].tv_sec; 3417 1.6 eeh vattr.va_mtime.tv_nsec = tv[1].tv_usec * 1000; 3418 1.6 eeh error = VOP_SETATTR(vp, &vattr, p->p_ucred, p); 3419 1.6 eeh VOP_UNLOCK(vp, 0); 3420 1.6 eeh return (error); 3421 1.1 mrg } 3422 1.1 mrg 3423 1.1 mrg int 3424 1.19 eeh netbsd32_adjtime(p, v, retval) 3425 1.1 mrg struct proc *p; 3426 1.1 mrg void *v; 3427 1.1 mrg register_t *retval; 3428 1.1 mrg { 3429 1.19 eeh struct netbsd32_adjtime_args /* { 3430 1.10 mrg syscallarg(const netbsd32_timevalp_t) delta; 3431 1.10 mrg syscallarg(netbsd32_timevalp_t) olddelta; 3432 1.1 mrg } */ *uap = v; 3433 1.10 mrg struct netbsd32_timeval atv; 3434 1.6 eeh int32_t ndelta, ntickdelta, odelta; 3435 1.6 eeh int s, error; 3436 1.6 eeh extern long bigadj, timedelta; 3437 1.6 eeh extern int tickdelta; 3438 1.1 mrg 3439 1.6 eeh if ((error = suser(p->p_ucred, &p->p_acflag)) != 0) 3440 1.6 eeh return (error); 3441 1.1 mrg 3442 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, delta), &atv, sizeof(struct timeval)); 3443 1.1 mrg if (error) 3444 1.1 mrg return (error); 3445 1.6 eeh /* 3446 1.6 eeh * Compute the total correction and the rate at which to apply it. 3447 1.6 eeh * Round the adjustment down to a whole multiple of the per-tick 3448 1.6 eeh * delta, so that after some number of incremental changes in 3449 1.6 eeh * hardclock(), tickdelta will become zero, lest the correction 3450 1.6 eeh * overshoot and start taking us away from the desired final time. 3451 1.6 eeh */ 3452 1.6 eeh ndelta = atv.tv_sec * 1000000 + atv.tv_usec; 3453 1.6 eeh if (ndelta > bigadj) 3454 1.6 eeh ntickdelta = 10 * tickadj; 3455 1.6 eeh else 3456 1.6 eeh ntickdelta = tickadj; 3457 1.6 eeh if (ndelta % ntickdelta) 3458 1.6 eeh ndelta = ndelta / ntickdelta * ntickdelta; 3459 1.1 mrg 3460 1.6 eeh /* 3461 1.6 eeh * To make hardclock()'s job easier, make the per-tick delta negative 3462 1.6 eeh * if we want time to run slower; then hardclock can simply compute 3463 1.6 eeh * tick + tickdelta, and subtract tickdelta from timedelta. 3464 1.6 eeh */ 3465 1.6 eeh if (ndelta < 0) 3466 1.6 eeh ntickdelta = -ntickdelta; 3467 1.6 eeh s = splclock(); 3468 1.6 eeh odelta = timedelta; 3469 1.6 eeh timedelta = ndelta; 3470 1.6 eeh tickdelta = ntickdelta; 3471 1.6 eeh splx(s); 3472 1.6 eeh 3473 1.6 eeh if (SCARG(uap, olddelta)) { 3474 1.6 eeh atv.tv_sec = odelta / 1000000; 3475 1.6 eeh atv.tv_usec = odelta % 1000000; 3476 1.6 eeh (void) copyout(&atv, (caddr_t)(u_long)SCARG(uap, olddelta), 3477 1.6 eeh sizeof(struct timeval)); 3478 1.6 eeh } 3479 1.1 mrg return (0); 3480 1.1 mrg } 3481 1.1 mrg 3482 1.1 mrg int 3483 1.19 eeh netbsd32_quotactl(p, v, retval) 3484 1.1 mrg struct proc *p; 3485 1.1 mrg void *v; 3486 1.1 mrg register_t *retval; 3487 1.1 mrg { 3488 1.19 eeh struct netbsd32_quotactl_args /* { 3489 1.10 mrg syscallarg(const netbsd32_charp) path; 3490 1.1 mrg syscallarg(int) cmd; 3491 1.1 mrg syscallarg(int) uid; 3492 1.10 mrg syscallarg(netbsd32_caddr_t) arg; 3493 1.1 mrg } */ *uap = v; 3494 1.1 mrg struct sys_quotactl_args ua; 3495 1.1 mrg 3496 1.11 mrg NETBSD32TOP_UAP(path, const char); 3497 1.11 mrg NETBSD32TO64_UAP(cmd); 3498 1.11 mrg NETBSD32TO64_UAP(uid); 3499 1.11 mrg NETBSD32TOX64_UAP(arg, caddr_t); 3500 1.1 mrg return (sys_quotactl(p, &ua, retval)); 3501 1.1 mrg } 3502 1.1 mrg 3503 1.6 eeh #if defined(NFS) || defined(NFSSERVER) 3504 1.1 mrg int 3505 1.19 eeh netbsd32_nfssvc(p, v, retval) 3506 1.1 mrg struct proc *p; 3507 1.1 mrg void *v; 3508 1.1 mrg register_t *retval; 3509 1.1 mrg { 3510 1.6 eeh #if 0 3511 1.19 eeh struct netbsd32_nfssvc_args /* { 3512 1.1 mrg syscallarg(int) flag; 3513 1.10 mrg syscallarg(netbsd32_voidp) argp; 3514 1.1 mrg } */ *uap = v; 3515 1.1 mrg struct sys_nfssvc_args ua; 3516 1.1 mrg 3517 1.11 mrg NETBSD32TO64_UAP(flag); 3518 1.11 mrg NETBSD32TOP_UAP(argp, void); 3519 1.1 mrg return (sys_nfssvc(p, &ua, retval)); 3520 1.6 eeh #else 3521 1.6 eeh /* Why would we want to support a 32-bit nfsd? */ 3522 1.6 eeh return (ENOSYS); 3523 1.6 eeh #endif 3524 1.1 mrg } 3525 1.6 eeh #endif 3526 1.1 mrg 3527 1.1 mrg int 3528 1.19 eeh netbsd32_statfs(p, v, retval) 3529 1.1 mrg struct proc *p; 3530 1.1 mrg void *v; 3531 1.1 mrg register_t *retval; 3532 1.1 mrg { 3533 1.19 eeh struct netbsd32_statfs_args /* { 3534 1.10 mrg syscallarg(const netbsd32_charp) path; 3535 1.10 mrg syscallarg(netbsd32_statfsp_t) buf; 3536 1.1 mrg } */ *uap = v; 3537 1.19.2.1 bouyer struct mount *mp; 3538 1.19.2.1 bouyer struct statfs *sp; 3539 1.10 mrg struct netbsd32_statfs s32; 3540 1.1 mrg int error; 3541 1.6 eeh struct nameidata nd; 3542 1.1 mrg 3543 1.6 eeh NDINIT(&nd, LOOKUP, FOLLOW, UIO_USERSPACE, (char *)(u_long)SCARG(uap, path), p); 3544 1.6 eeh if ((error = namei(&nd)) != 0) 3545 1.6 eeh return (error); 3546 1.6 eeh mp = nd.ni_vp->v_mount; 3547 1.6 eeh sp = &mp->mnt_stat; 3548 1.6 eeh vrele(nd.ni_vp); 3549 1.6 eeh if ((error = VFS_STATFS(mp, sp, p)) != 0) 3550 1.1 mrg return (error); 3551 1.6 eeh sp->f_flags = mp->mnt_flag & MNT_VISFLAGMASK; 3552 1.10 mrg netbsd32_from_statfs(sp, &s32); 3553 1.6 eeh return (copyout(&s32, (caddr_t)(u_long)SCARG(uap, buf), sizeof(s32))); 3554 1.1 mrg } 3555 1.1 mrg 3556 1.1 mrg int 3557 1.19 eeh netbsd32_fstatfs(p, v, retval) 3558 1.1 mrg struct proc *p; 3559 1.1 mrg void *v; 3560 1.1 mrg register_t *retval; 3561 1.1 mrg { 3562 1.19 eeh struct netbsd32_fstatfs_args /* { 3563 1.1 mrg syscallarg(int) fd; 3564 1.10 mrg syscallarg(netbsd32_statfsp_t) buf; 3565 1.1 mrg } */ *uap = v; 3566 1.6 eeh struct file *fp; 3567 1.19.2.1 bouyer struct mount *mp; 3568 1.19.2.1 bouyer struct statfs *sp; 3569 1.10 mrg struct netbsd32_statfs s32; 3570 1.1 mrg int error; 3571 1.1 mrg 3572 1.12 thorpej /* getvnode() will use the descriptor for us */ 3573 1.6 eeh if ((error = getvnode(p->p_fd, SCARG(uap, fd), &fp)) != 0) 3574 1.6 eeh return (error); 3575 1.6 eeh mp = ((struct vnode *)fp->f_data)->v_mount; 3576 1.6 eeh sp = &mp->mnt_stat; 3577 1.6 eeh if ((error = VFS_STATFS(mp, sp, p)) != 0) 3578 1.12 thorpej goto out; 3579 1.6 eeh sp->f_flags = mp->mnt_flag & MNT_VISFLAGMASK; 3580 1.10 mrg netbsd32_from_statfs(sp, &s32); 3581 1.12 thorpej error = copyout(&s32, (caddr_t)(u_long)SCARG(uap, buf), sizeof(s32)); 3582 1.12 thorpej out: 3583 1.19 eeh FILE_UNUSE(fp, p); 3584 1.12 thorpej return (error); 3585 1.1 mrg } 3586 1.1 mrg 3587 1.6 eeh #if defined(NFS) || defined(NFSSERVER) 3588 1.1 mrg int 3589 1.19 eeh netbsd32_getfh(p, v, retval) 3590 1.1 mrg struct proc *p; 3591 1.1 mrg void *v; 3592 1.1 mrg register_t *retval; 3593 1.1 mrg { 3594 1.19 eeh struct netbsd32_getfh_args /* { 3595 1.10 mrg syscallarg(const netbsd32_charp) fname; 3596 1.10 mrg syscallarg(netbsd32_fhandlep_t) fhp; 3597 1.1 mrg } */ *uap = v; 3598 1.1 mrg struct sys_getfh_args ua; 3599 1.1 mrg 3600 1.11 mrg NETBSD32TOP_UAP(fname, const char); 3601 1.11 mrg NETBSD32TOP_UAP(fhp, struct fhandle); 3602 1.6 eeh /* Lucky for us a fhandlep_t doesn't change sizes */ 3603 1.1 mrg return (sys_getfh(p, &ua, retval)); 3604 1.1 mrg } 3605 1.6 eeh #endif 3606 1.1 mrg 3607 1.1 mrg int 3608 1.19 eeh netbsd32_sysarch(p, v, retval) 3609 1.1 mrg struct proc *p; 3610 1.1 mrg void *v; 3611 1.1 mrg register_t *retval; 3612 1.1 mrg { 3613 1.19 eeh struct netbsd32_sysarch_args /* { 3614 1.1 mrg syscallarg(int) op; 3615 1.10 mrg syscallarg(netbsd32_voidp) parms; 3616 1.1 mrg } */ *uap = v; 3617 1.1 mrg 3618 1.6 eeh switch (SCARG(uap, op)) { 3619 1.6 eeh default: 3620 1.19 eeh printf("(sparc64) netbsd32_sysarch(%d)\n", SCARG(uap, op)); 3621 1.6 eeh return EINVAL; 3622 1.6 eeh } 3623 1.1 mrg } 3624 1.1 mrg 3625 1.1 mrg int 3626 1.19 eeh netbsd32_pread(p, v, retval) 3627 1.1 mrg struct proc *p; 3628 1.1 mrg void *v; 3629 1.1 mrg register_t *retval; 3630 1.1 mrg { 3631 1.19 eeh struct netbsd32_pread_args /* { 3632 1.1 mrg syscallarg(int) fd; 3633 1.10 mrg syscallarg(netbsd32_voidp) buf; 3634 1.10 mrg syscallarg(netbsd32_size_t) nbyte; 3635 1.1 mrg syscallarg(int) pad; 3636 1.1 mrg syscallarg(off_t) offset; 3637 1.1 mrg } */ *uap = v; 3638 1.1 mrg struct sys_pread_args ua; 3639 1.1 mrg ssize_t rt; 3640 1.1 mrg int error; 3641 1.1 mrg 3642 1.11 mrg NETBSD32TO64_UAP(fd); 3643 1.11 mrg NETBSD32TOP_UAP(buf, void); 3644 1.11 mrg NETBSD32TOX_UAP(nbyte, size_t); 3645 1.11 mrg NETBSD32TO64_UAP(pad); 3646 1.11 mrg NETBSD32TO64_UAP(offset); 3647 1.1 mrg error = sys_pread(p, &ua, (register_t *)&rt); 3648 1.19.2.1 bouyer *retval = rt; 3649 1.1 mrg return (error); 3650 1.1 mrg } 3651 1.1 mrg 3652 1.1 mrg int 3653 1.19 eeh netbsd32_pwrite(p, v, retval) 3654 1.1 mrg struct proc *p; 3655 1.1 mrg void *v; 3656 1.1 mrg register_t *retval; 3657 1.1 mrg { 3658 1.19 eeh struct netbsd32_pwrite_args /* { 3659 1.1 mrg syscallarg(int) fd; 3660 1.10 mrg syscallarg(const netbsd32_voidp) buf; 3661 1.10 mrg syscallarg(netbsd32_size_t) nbyte; 3662 1.1 mrg syscallarg(int) pad; 3663 1.1 mrg syscallarg(off_t) offset; 3664 1.1 mrg } */ *uap = v; 3665 1.1 mrg struct sys_pwrite_args ua; 3666 1.1 mrg ssize_t rt; 3667 1.1 mrg int error; 3668 1.1 mrg 3669 1.11 mrg NETBSD32TO64_UAP(fd); 3670 1.11 mrg NETBSD32TOP_UAP(buf, void); 3671 1.11 mrg NETBSD32TOX_UAP(nbyte, size_t); 3672 1.11 mrg NETBSD32TO64_UAP(pad); 3673 1.11 mrg NETBSD32TO64_UAP(offset); 3674 1.1 mrg error = sys_pwrite(p, &ua, (register_t *)&rt); 3675 1.19.2.1 bouyer *retval = rt; 3676 1.1 mrg return (error); 3677 1.1 mrg } 3678 1.1 mrg 3679 1.6 eeh #ifdef NTP 3680 1.1 mrg int 3681 1.19 eeh netbsd32_ntp_gettime(p, v, retval) 3682 1.1 mrg struct proc *p; 3683 1.1 mrg void *v; 3684 1.1 mrg register_t *retval; 3685 1.1 mrg { 3686 1.19 eeh struct netbsd32_ntp_gettime_args /* { 3687 1.10 mrg syscallarg(netbsd32_ntptimevalp_t) ntvp; 3688 1.1 mrg } */ *uap = v; 3689 1.10 mrg struct netbsd32_ntptimeval ntv32; 3690 1.6 eeh struct timeval atv; 3691 1.1 mrg struct ntptimeval ntv; 3692 1.6 eeh int error = 0; 3693 1.6 eeh int s; 3694 1.1 mrg 3695 1.6 eeh /* The following are NTP variables */ 3696 1.6 eeh extern long time_maxerror; 3697 1.6 eeh extern long time_esterror; 3698 1.6 eeh extern int time_status; 3699 1.6 eeh extern int time_state; /* clock state */ 3700 1.6 eeh extern int time_status; /* clock status bits */ 3701 1.6 eeh 3702 1.6 eeh if (SCARG(uap, ntvp)) { 3703 1.6 eeh s = splclock(); 3704 1.6 eeh #ifdef EXT_CLOCK 3705 1.6 eeh /* 3706 1.6 eeh * The microtime() external clock routine returns a 3707 1.6 eeh * status code. If less than zero, we declare an error 3708 1.6 eeh * in the clock status word and return the kernel 3709 1.6 eeh * (software) time variable. While there are other 3710 1.6 eeh * places that call microtime(), this is the only place 3711 1.6 eeh * that matters from an application point of view. 3712 1.6 eeh */ 3713 1.6 eeh if (microtime(&atv) < 0) { 3714 1.6 eeh time_status |= STA_CLOCKERR; 3715 1.6 eeh ntv.time = time; 3716 1.6 eeh } else 3717 1.6 eeh time_status &= ~STA_CLOCKERR; 3718 1.6 eeh #else /* EXT_CLOCK */ 3719 1.6 eeh microtime(&atv); 3720 1.6 eeh #endif /* EXT_CLOCK */ 3721 1.6 eeh ntv.time = atv; 3722 1.6 eeh ntv.maxerror = time_maxerror; 3723 1.6 eeh ntv.esterror = time_esterror; 3724 1.6 eeh (void) splx(s); 3725 1.1 mrg 3726 1.10 mrg netbsd32_from_timeval(&ntv.time, &ntv32.time); 3727 1.10 mrg ntv32.maxerror = (netbsd32_long)ntv.maxerror; 3728 1.10 mrg ntv32.esterror = (netbsd32_long)ntv.esterror; 3729 1.6 eeh error = copyout((caddr_t)&ntv32, (caddr_t)(u_long)SCARG(uap, ntvp), 3730 1.6 eeh sizeof(ntv32)); 3731 1.6 eeh } 3732 1.6 eeh if (!error) { 3733 1.6 eeh 3734 1.6 eeh /* 3735 1.6 eeh * Status word error decode. If any of these conditions 3736 1.6 eeh * occur, an error is returned, instead of the status 3737 1.6 eeh * word. Most applications will care only about the fact 3738 1.6 eeh * the system clock may not be trusted, not about the 3739 1.6 eeh * details. 3740 1.6 eeh * 3741 1.6 eeh * Hardware or software error 3742 1.6 eeh */ 3743 1.6 eeh if ((time_status & (STA_UNSYNC | STA_CLOCKERR)) || 3744 1.6 eeh 3745 1.6 eeh /* 3746 1.6 eeh * PPS signal lost when either time or frequency 3747 1.6 eeh * synchronization requested 3748 1.6 eeh */ 3749 1.6 eeh (time_status & (STA_PPSFREQ | STA_PPSTIME) && 3750 1.6 eeh !(time_status & STA_PPSSIGNAL)) || 3751 1.6 eeh 3752 1.6 eeh /* 3753 1.6 eeh * PPS jitter exceeded when time synchronization 3754 1.6 eeh * requested 3755 1.6 eeh */ 3756 1.6 eeh (time_status & STA_PPSTIME && 3757 1.6 eeh time_status & STA_PPSJITTER) || 3758 1.6 eeh 3759 1.6 eeh /* 3760 1.6 eeh * PPS wander exceeded or calibration error when 3761 1.6 eeh * frequency synchronization requested 3762 1.6 eeh */ 3763 1.6 eeh (time_status & STA_PPSFREQ && 3764 1.6 eeh time_status & (STA_PPSWANDER | STA_PPSERROR))) 3765 1.6 eeh *retval = TIME_ERROR; 3766 1.6 eeh else 3767 1.19.2.1 bouyer *retval = time_state; 3768 1.1 mrg } 3769 1.6 eeh return(error); 3770 1.1 mrg } 3771 1.1 mrg 3772 1.1 mrg int 3773 1.19 eeh netbsd32_ntp_adjtime(p, v, retval) 3774 1.1 mrg struct proc *p; 3775 1.1 mrg void *v; 3776 1.1 mrg register_t *retval; 3777 1.1 mrg { 3778 1.19 eeh struct netbsd32_ntp_adjtime_args /* { 3779 1.10 mrg syscallarg(netbsd32_timexp_t) tp; 3780 1.1 mrg } */ *uap = v; 3781 1.10 mrg struct netbsd32_timex ntv32; 3782 1.6 eeh struct timex ntv; 3783 1.6 eeh int error = 0; 3784 1.6 eeh int modes; 3785 1.6 eeh int s; 3786 1.6 eeh extern long time_freq; /* frequency offset (scaled ppm) */ 3787 1.6 eeh extern long time_maxerror; 3788 1.6 eeh extern long time_esterror; 3789 1.6 eeh extern int time_state; /* clock state */ 3790 1.6 eeh extern int time_status; /* clock status bits */ 3791 1.6 eeh extern long time_constant; /* pll time constant */ 3792 1.6 eeh extern long time_offset; /* time offset (us) */ 3793 1.6 eeh extern long time_tolerance; /* frequency tolerance (scaled ppm) */ 3794 1.6 eeh extern long time_precision; /* clock precision (us) */ 3795 1.6 eeh 3796 1.6 eeh if ((error = copyin((caddr_t)(u_long)SCARG(uap, tp), (caddr_t)&ntv32, 3797 1.6 eeh sizeof(ntv32)))) 3798 1.6 eeh return (error); 3799 1.10 mrg netbsd32_to_timex(&ntv32, &ntv); 3800 1.1 mrg 3801 1.6 eeh /* 3802 1.6 eeh * Update selected clock variables - only the superuser can 3803 1.6 eeh * change anything. Note that there is no error checking here on 3804 1.6 eeh * the assumption the superuser should know what it is doing. 3805 1.6 eeh */ 3806 1.6 eeh modes = ntv.modes; 3807 1.6 eeh if (modes != 0 && (error = suser(p->p_ucred, &p->p_acflag))) 3808 1.1 mrg return (error); 3809 1.1 mrg 3810 1.6 eeh s = splclock(); 3811 1.6 eeh if (modes & MOD_FREQUENCY) 3812 1.6 eeh #ifdef PPS_SYNC 3813 1.6 eeh time_freq = ntv.freq - pps_freq; 3814 1.6 eeh #else /* PPS_SYNC */ 3815 1.6 eeh time_freq = ntv.freq; 3816 1.6 eeh #endif /* PPS_SYNC */ 3817 1.6 eeh if (modes & MOD_MAXERROR) 3818 1.6 eeh time_maxerror = ntv.maxerror; 3819 1.6 eeh if (modes & MOD_ESTERROR) 3820 1.6 eeh time_esterror = ntv.esterror; 3821 1.6 eeh if (modes & MOD_STATUS) { 3822 1.6 eeh time_status &= STA_RONLY; 3823 1.6 eeh time_status |= ntv.status & ~STA_RONLY; 3824 1.6 eeh } 3825 1.6 eeh if (modes & MOD_TIMECONST) 3826 1.6 eeh time_constant = ntv.constant; 3827 1.6 eeh if (modes & MOD_OFFSET) 3828 1.6 eeh hardupdate(ntv.offset); 3829 1.6 eeh 3830 1.6 eeh /* 3831 1.6 eeh * Retrieve all clock variables 3832 1.6 eeh */ 3833 1.6 eeh if (time_offset < 0) 3834 1.6 eeh ntv.offset = -(-time_offset >> SHIFT_UPDATE); 3835 1.6 eeh else 3836 1.6 eeh ntv.offset = time_offset >> SHIFT_UPDATE; 3837 1.6 eeh #ifdef PPS_SYNC 3838 1.6 eeh ntv.freq = time_freq + pps_freq; 3839 1.6 eeh #else /* PPS_SYNC */ 3840 1.6 eeh ntv.freq = time_freq; 3841 1.6 eeh #endif /* PPS_SYNC */ 3842 1.6 eeh ntv.maxerror = time_maxerror; 3843 1.6 eeh ntv.esterror = time_esterror; 3844 1.6 eeh ntv.status = time_status; 3845 1.6 eeh ntv.constant = time_constant; 3846 1.6 eeh ntv.precision = time_precision; 3847 1.6 eeh ntv.tolerance = time_tolerance; 3848 1.6 eeh #ifdef PPS_SYNC 3849 1.6 eeh ntv.shift = pps_shift; 3850 1.6 eeh ntv.ppsfreq = pps_freq; 3851 1.6 eeh ntv.jitter = pps_jitter >> PPS_AVG; 3852 1.6 eeh ntv.stabil = pps_stabil; 3853 1.6 eeh ntv.calcnt = pps_calcnt; 3854 1.6 eeh ntv.errcnt = pps_errcnt; 3855 1.6 eeh ntv.jitcnt = pps_jitcnt; 3856 1.6 eeh ntv.stbcnt = pps_stbcnt; 3857 1.6 eeh #endif /* PPS_SYNC */ 3858 1.6 eeh (void)splx(s); 3859 1.6 eeh 3860 1.19.2.1 bouyer netbsd32_from_timex(&ntv, &ntv32); 3861 1.19.2.1 bouyer error = copyout((caddr_t)&ntv32, (caddr_t)(u_long)SCARG(uap, tp), 3862 1.19.2.1 bouyer sizeof(ntv32)); 3863 1.6 eeh if (!error) { 3864 1.6 eeh 3865 1.6 eeh /* 3866 1.6 eeh * Status word error decode. See comments in 3867 1.6 eeh * ntp_gettime() routine. 3868 1.6 eeh */ 3869 1.6 eeh if ((time_status & (STA_UNSYNC | STA_CLOCKERR)) || 3870 1.6 eeh (time_status & (STA_PPSFREQ | STA_PPSTIME) && 3871 1.6 eeh !(time_status & STA_PPSSIGNAL)) || 3872 1.6 eeh (time_status & STA_PPSTIME && 3873 1.6 eeh time_status & STA_PPSJITTER) || 3874 1.6 eeh (time_status & STA_PPSFREQ && 3875 1.6 eeh time_status & (STA_PPSWANDER | STA_PPSERROR))) 3876 1.6 eeh *retval = TIME_ERROR; 3877 1.6 eeh else 3878 1.19.2.1 bouyer *retval = time_state; 3879 1.6 eeh } 3880 1.6 eeh return error; 3881 1.6 eeh } 3882 1.19.2.1 bouyer #else 3883 1.19.2.1 bouyer int 3884 1.19.2.1 bouyer netbsd32_ntp_gettime(p, v, retval) 3885 1.19.2.1 bouyer struct proc *p; 3886 1.19.2.1 bouyer void *v; 3887 1.19.2.1 bouyer register_t *retval; 3888 1.19.2.1 bouyer { 3889 1.19.2.1 bouyer return(ENOSYS); 3890 1.19.2.1 bouyer } 3891 1.19.2.1 bouyer 3892 1.19.2.1 bouyer int 3893 1.19.2.1 bouyer netbsd32_ntp_adjtime(p, v, retval) 3894 1.19.2.1 bouyer struct proc *p; 3895 1.19.2.1 bouyer void *v; 3896 1.19.2.1 bouyer register_t *retval; 3897 1.19.2.1 bouyer { 3898 1.19.2.1 bouyer return (ENOSYS); 3899 1.19.2.1 bouyer } 3900 1.6 eeh #endif 3901 1.6 eeh 3902 1.6 eeh int 3903 1.19 eeh netbsd32_setgid(p, v, retval) 3904 1.6 eeh struct proc *p; 3905 1.6 eeh void *v; 3906 1.6 eeh register_t *retval; 3907 1.6 eeh { 3908 1.19 eeh struct netbsd32_setgid_args /* { 3909 1.6 eeh syscallarg(gid_t) gid; 3910 1.6 eeh } */ *uap = v; 3911 1.6 eeh struct sys_setgid_args ua; 3912 1.6 eeh 3913 1.11 mrg NETBSD32TO64_UAP(gid); 3914 1.6 eeh return (sys_setgid(p, v, retval)); 3915 1.6 eeh } 3916 1.6 eeh 3917 1.6 eeh int 3918 1.19 eeh netbsd32_setegid(p, v, retval) 3919 1.6 eeh struct proc *p; 3920 1.6 eeh void *v; 3921 1.6 eeh register_t *retval; 3922 1.6 eeh { 3923 1.19 eeh struct netbsd32_setegid_args /* { 3924 1.6 eeh syscallarg(gid_t) egid; 3925 1.6 eeh } */ *uap = v; 3926 1.6 eeh struct sys_setegid_args ua; 3927 1.6 eeh 3928 1.11 mrg NETBSD32TO64_UAP(egid); 3929 1.6 eeh return (sys_setegid(p, v, retval)); 3930 1.6 eeh } 3931 1.6 eeh 3932 1.6 eeh int 3933 1.19 eeh netbsd32_seteuid(p, v, retval) 3934 1.6 eeh struct proc *p; 3935 1.6 eeh void *v; 3936 1.6 eeh register_t *retval; 3937 1.6 eeh { 3938 1.19 eeh struct netbsd32_seteuid_args /* { 3939 1.6 eeh syscallarg(gid_t) euid; 3940 1.6 eeh } */ *uap = v; 3941 1.6 eeh struct sys_seteuid_args ua; 3942 1.6 eeh 3943 1.11 mrg NETBSD32TO64_UAP(euid); 3944 1.6 eeh return (sys_seteuid(p, v, retval)); 3945 1.1 mrg } 3946 1.1 mrg 3947 1.6 eeh #ifdef LFS 3948 1.1 mrg int 3949 1.19.2.1 bouyer netbsd32_sys_lfs_bmapv(p, v, retval) 3950 1.1 mrg struct proc *p; 3951 1.1 mrg void *v; 3952 1.1 mrg register_t *retval; 3953 1.1 mrg { 3954 1.6 eeh #if 0 3955 1.19 eeh struct netbsd32_lfs_bmapv_args /* { 3956 1.10 mrg syscallarg(netbsd32_fsid_tp_t) fsidp; 3957 1.10 mrg syscallarg(netbsd32_block_infop_t) blkiov; 3958 1.1 mrg syscallarg(int) blkcnt; 3959 1.1 mrg } */ *uap = v; 3960 1.1 mrg struct sys_lfs_bmapv_args ua; 3961 1.1 mrg 3962 1.11 mrg NETBSD32TOP_UAP(fdidp, struct fsid); 3963 1.11 mrg NETBSD32TO64_UAP(blkcnt); 3964 1.1 mrg /* XXX finish me */ 3965 1.1 mrg #else 3966 1.1 mrg 3967 1.1 mrg return (ENOSYS); /* XXX */ 3968 1.1 mrg #endif 3969 1.1 mrg } 3970 1.1 mrg 3971 1.1 mrg int 3972 1.19.2.1 bouyer netbsd32_sys_lfs_markv(p, v, retval) 3973 1.1 mrg struct proc *p; 3974 1.1 mrg void *v; 3975 1.1 mrg register_t *retval; 3976 1.1 mrg { 3977 1.19.2.1 bouyer #if 0 3978 1.19 eeh struct netbsd32_lfs_markv_args /* { 3979 1.10 mrg syscallarg(netbsd32_fsid_tp_t) fsidp; 3980 1.10 mrg syscallarg(netbsd32_block_infop_t) blkiov; 3981 1.1 mrg syscallarg(int) blkcnt; 3982 1.1 mrg } */ *uap = v; 3983 1.19.2.1 bouyer #endif 3984 1.1 mrg 3985 1.1 mrg return (ENOSYS); /* XXX */ 3986 1.1 mrg } 3987 1.1 mrg 3988 1.1 mrg int 3989 1.19.2.1 bouyer netbsd32_sys_lfs_segclean(p, v, retval) 3990 1.1 mrg struct proc *p; 3991 1.1 mrg void *v; 3992 1.1 mrg register_t *retval; 3993 1.1 mrg { 3994 1.19.2.1 bouyer #if 0 3995 1.19 eeh struct netbsd32_lfs_segclean_args /* { 3996 1.10 mrg syscallarg(netbsd32_fsid_tp_t) fsidp; 3997 1.10 mrg syscallarg(netbsd32_u_long) segment; 3998 1.1 mrg } */ *uap = v; 3999 1.19.2.1 bouyer #endif 4000 1.19.2.1 bouyer 4001 1.1 mrg return (ENOSYS); /* XXX */ 4002 1.1 mrg } 4003 1.1 mrg 4004 1.1 mrg int 4005 1.19.2.1 bouyer netbsd32_sys_lfs_segwait(p, v, retval) 4006 1.1 mrg struct proc *p; 4007 1.1 mrg void *v; 4008 1.1 mrg register_t *retval; 4009 1.1 mrg { 4010 1.19.2.1 bouyer #if 0 4011 1.19 eeh struct netbsd32_lfs_segwait_args /* { 4012 1.10 mrg syscallarg(netbsd32_fsid_tp_t) fsidp; 4013 1.10 mrg syscallarg(netbsd32_timevalp_t) tv; 4014 1.1 mrg } */ *uap = v; 4015 1.19.2.1 bouyer #endif 4016 1.19.2.1 bouyer 4017 1.1 mrg return (ENOSYS); /* XXX */ 4018 1.1 mrg } 4019 1.6 eeh #endif 4020 1.1 mrg 4021 1.1 mrg int 4022 1.19 eeh netbsd32_pathconf(p, v, retval) 4023 1.1 mrg struct proc *p; 4024 1.1 mrg void *v; 4025 1.1 mrg register_t *retval; 4026 1.1 mrg { 4027 1.19 eeh struct netbsd32_pathconf_args /* { 4028 1.1 mrg syscallarg(int) fd; 4029 1.1 mrg syscallarg(int) name; 4030 1.1 mrg } */ *uap = v; 4031 1.1 mrg struct sys_pathconf_args ua; 4032 1.1 mrg long rt; 4033 1.1 mrg int error; 4034 1.1 mrg 4035 1.11 mrg NETBSD32TOP_UAP(path, const char); 4036 1.11 mrg NETBSD32TO64_UAP(name); 4037 1.1 mrg error = sys_pathconf(p, &ua, (register_t *)&rt); 4038 1.19.2.1 bouyer *retval = rt; 4039 1.1 mrg return (error); 4040 1.1 mrg } 4041 1.1 mrg 4042 1.1 mrg int 4043 1.19 eeh netbsd32_fpathconf(p, v, retval) 4044 1.1 mrg struct proc *p; 4045 1.1 mrg void *v; 4046 1.1 mrg register_t *retval; 4047 1.1 mrg { 4048 1.19 eeh struct netbsd32_fpathconf_args /* { 4049 1.1 mrg syscallarg(int) fd; 4050 1.1 mrg syscallarg(int) name; 4051 1.1 mrg } */ *uap = v; 4052 1.1 mrg struct sys_fpathconf_args ua; 4053 1.1 mrg long rt; 4054 1.1 mrg int error; 4055 1.1 mrg 4056 1.11 mrg NETBSD32TO64_UAP(fd); 4057 1.11 mrg NETBSD32TO64_UAP(name); 4058 1.1 mrg error = sys_fpathconf(p, &ua, (register_t *)&rt); 4059 1.19.2.1 bouyer *retval = rt; 4060 1.1 mrg return (error); 4061 1.1 mrg } 4062 1.1 mrg 4063 1.1 mrg int 4064 1.19 eeh netbsd32_getrlimit(p, v, retval) 4065 1.1 mrg struct proc *p; 4066 1.1 mrg void *v; 4067 1.1 mrg register_t *retval; 4068 1.1 mrg { 4069 1.19 eeh struct netbsd32_getrlimit_args /* { 4070 1.1 mrg syscallarg(int) which; 4071 1.10 mrg syscallarg(netbsd32_rlimitp_t) rlp; 4072 1.1 mrg } */ *uap = v; 4073 1.6 eeh int which = SCARG(uap, which); 4074 1.1 mrg 4075 1.6 eeh if ((u_int)which >= RLIM_NLIMITS) 4076 1.6 eeh return (EINVAL); 4077 1.6 eeh return (copyout(&p->p_rlimit[which], (caddr_t)(u_long)SCARG(uap, rlp), 4078 1.6 eeh sizeof(struct rlimit))); 4079 1.1 mrg } 4080 1.1 mrg 4081 1.1 mrg int 4082 1.19 eeh netbsd32_setrlimit(p, v, retval) 4083 1.1 mrg struct proc *p; 4084 1.1 mrg void *v; 4085 1.1 mrg register_t *retval; 4086 1.1 mrg { 4087 1.19 eeh struct netbsd32_setrlimit_args /* { 4088 1.1 mrg syscallarg(int) which; 4089 1.10 mrg syscallarg(const netbsd32_rlimitp_t) rlp; 4090 1.1 mrg } */ *uap = v; 4091 1.6 eeh int which = SCARG(uap, which); 4092 1.6 eeh struct rlimit alim; 4093 1.6 eeh int error; 4094 1.1 mrg 4095 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, rlp), &alim, sizeof(struct rlimit)); 4096 1.6 eeh if (error) 4097 1.6 eeh return (error); 4098 1.18 bouyer return (dosetrlimit(p, p->p_cred, which, &alim)); 4099 1.1 mrg } 4100 1.1 mrg 4101 1.1 mrg int 4102 1.19 eeh netbsd32_mmap(p, v, retval) 4103 1.1 mrg struct proc *p; 4104 1.1 mrg void *v; 4105 1.1 mrg register_t *retval; 4106 1.1 mrg { 4107 1.19 eeh struct netbsd32_mmap_args /* { 4108 1.10 mrg syscallarg(netbsd32_voidp) addr; 4109 1.10 mrg syscallarg(netbsd32_size_t) len; 4110 1.1 mrg syscallarg(int) prot; 4111 1.1 mrg syscallarg(int) flags; 4112 1.1 mrg syscallarg(int) fd; 4113 1.10 mrg syscallarg(netbsd32_long) pad; 4114 1.1 mrg syscallarg(off_t) pos; 4115 1.1 mrg } */ *uap = v; 4116 1.1 mrg struct sys_mmap_args ua; 4117 1.1 mrg void *rt; 4118 1.1 mrg int error; 4119 1.1 mrg 4120 1.11 mrg NETBSD32TOP_UAP(addr, void); 4121 1.11 mrg NETBSD32TOX_UAP(len, size_t); 4122 1.11 mrg NETBSD32TO64_UAP(prot); 4123 1.11 mrg NETBSD32TO64_UAP(flags); 4124 1.11 mrg NETBSD32TO64_UAP(fd); 4125 1.11 mrg NETBSD32TOX_UAP(pad, long); 4126 1.11 mrg NETBSD32TOX_UAP(pos, off_t); 4127 1.1 mrg error = sys_mmap(p, &ua, (register_t *)&rt); 4128 1.1 mrg if ((long)rt > (long)UINT_MAX) 4129 1.19.2.2 bouyer printf("netbsd32_mmap: retval out of range: %p", rt); 4130 1.10 mrg *retval = (netbsd32_voidp)(u_long)rt; 4131 1.1 mrg return (error); 4132 1.1 mrg } 4133 1.1 mrg 4134 1.1 mrg int 4135 1.19 eeh netbsd32_lseek(p, v, retval) 4136 1.6 eeh struct proc *p; 4137 1.6 eeh void *v; 4138 1.6 eeh register_t *retval; 4139 1.6 eeh { 4140 1.19 eeh struct netbsd32_lseek_args /* { 4141 1.6 eeh syscallarg(int) fd; 4142 1.6 eeh syscallarg(int) pad; 4143 1.6 eeh syscallarg(off_t) offset; 4144 1.6 eeh syscallarg(int) whence; 4145 1.6 eeh } */ *uap = v; 4146 1.6 eeh struct sys_lseek_args ua; 4147 1.6 eeh 4148 1.11 mrg NETBSD32TO64_UAP(fd); 4149 1.11 mrg NETBSD32TO64_UAP(pad); 4150 1.11 mrg NETBSD32TO64_UAP(offset); 4151 1.11 mrg NETBSD32TO64_UAP(whence); 4152 1.6 eeh return (sys_lseek(p, &ua, retval)); 4153 1.6 eeh } 4154 1.6 eeh 4155 1.6 eeh int 4156 1.19 eeh netbsd32_truncate(p, v, retval) 4157 1.1 mrg struct proc *p; 4158 1.1 mrg void *v; 4159 1.1 mrg register_t *retval; 4160 1.1 mrg { 4161 1.19 eeh struct netbsd32_truncate_args /* { 4162 1.10 mrg syscallarg(const netbsd32_charp) path; 4163 1.1 mrg syscallarg(int) pad; 4164 1.1 mrg syscallarg(off_t) length; 4165 1.1 mrg } */ *uap = v; 4166 1.1 mrg struct sys_truncate_args ua; 4167 1.1 mrg 4168 1.11 mrg NETBSD32TOP_UAP(path, const char); 4169 1.11 mrg NETBSD32TO64_UAP(pad); 4170 1.11 mrg NETBSD32TO64_UAP(length); 4171 1.1 mrg return (sys_truncate(p, &ua, retval)); 4172 1.1 mrg } 4173 1.1 mrg 4174 1.1 mrg int 4175 1.19 eeh netbsd32_ftruncate(p, v, retval) 4176 1.6 eeh struct proc *p; 4177 1.6 eeh void *v; 4178 1.6 eeh register_t *retval; 4179 1.6 eeh { 4180 1.19 eeh struct netbsd32_ftruncate_args /* { 4181 1.6 eeh syscallarg(int) fd; 4182 1.6 eeh syscallarg(int) pad; 4183 1.6 eeh syscallarg(off_t) length; 4184 1.6 eeh } */ *uap = v; 4185 1.6 eeh struct sys_ftruncate_args ua; 4186 1.6 eeh 4187 1.11 mrg NETBSD32TO64_UAP(fd); 4188 1.11 mrg NETBSD32TO64_UAP(pad); 4189 1.11 mrg NETBSD32TO64_UAP(length); 4190 1.6 eeh return (sys_ftruncate(p, &ua, retval)); 4191 1.6 eeh } 4192 1.6 eeh 4193 1.6 eeh int 4194 1.19 eeh netbsd32___sysctl(p, v, retval) 4195 1.1 mrg struct proc *p; 4196 1.1 mrg void *v; 4197 1.1 mrg register_t *retval; 4198 1.1 mrg { 4199 1.19 eeh struct netbsd32___sysctl_args /* { 4200 1.10 mrg syscallarg(netbsd32_intp) name; 4201 1.1 mrg syscallarg(u_int) namelen; 4202 1.10 mrg syscallarg(netbsd32_voidp) old; 4203 1.10 mrg syscallarg(netbsd32_size_tp) oldlenp; 4204 1.10 mrg syscallarg(netbsd32_voidp) new; 4205 1.10 mrg syscallarg(netbsd32_size_t) newlen; 4206 1.1 mrg } */ *uap = v; 4207 1.19.2.1 bouyer int error; 4208 1.10 mrg netbsd32_size_t savelen = 0; 4209 1.6 eeh size_t oldlen = 0; 4210 1.6 eeh sysctlfn *fn; 4211 1.6 eeh int name[CTL_MAXNAME]; 4212 1.6 eeh 4213 1.6 eeh /* 4214 1.6 eeh * Some of these sysctl functions do their own copyin/copyout. 4215 1.6 eeh * We need to disable or emulate the ones that need their 4216 1.6 eeh * arguments converted. 4217 1.6 eeh */ 4218 1.6 eeh 4219 1.6 eeh if (SCARG(uap, new) != NULL && 4220 1.6 eeh (error = suser(p->p_ucred, &p->p_acflag))) 4221 1.6 eeh return (error); 4222 1.6 eeh /* 4223 1.6 eeh * all top-level sysctl names are non-terminal 4224 1.6 eeh */ 4225 1.6 eeh if (SCARG(uap, namelen) > CTL_MAXNAME || SCARG(uap, namelen) < 2) 4226 1.6 eeh return (EINVAL); 4227 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, name), &name, 4228 1.6 eeh SCARG(uap, namelen) * sizeof(int)); 4229 1.6 eeh if (error) 4230 1.6 eeh return (error); 4231 1.6 eeh 4232 1.6 eeh switch (name[0]) { 4233 1.6 eeh case CTL_KERN: 4234 1.6 eeh fn = kern_sysctl; 4235 1.6 eeh break; 4236 1.6 eeh case CTL_HW: 4237 1.6 eeh fn = hw_sysctl; 4238 1.6 eeh break; 4239 1.6 eeh case CTL_VM: 4240 1.6 eeh fn = uvm_sysctl; 4241 1.6 eeh break; 4242 1.6 eeh case CTL_NET: 4243 1.6 eeh fn = net_sysctl; 4244 1.6 eeh break; 4245 1.6 eeh case CTL_VFS: 4246 1.6 eeh fn = vfs_sysctl; 4247 1.6 eeh break; 4248 1.6 eeh case CTL_MACHDEP: 4249 1.6 eeh fn = cpu_sysctl; 4250 1.6 eeh break; 4251 1.6 eeh #ifdef DEBUG 4252 1.6 eeh case CTL_DEBUG: 4253 1.6 eeh fn = debug_sysctl; 4254 1.6 eeh break; 4255 1.6 eeh #endif 4256 1.6 eeh #ifdef DDB 4257 1.6 eeh case CTL_DDB: 4258 1.6 eeh fn = ddb_sysctl; 4259 1.6 eeh break; 4260 1.6 eeh #endif 4261 1.19.2.1 bouyer case CTL_PROC: 4262 1.19.2.1 bouyer fn = proc_sysctl; 4263 1.19.2.1 bouyer break; 4264 1.6 eeh default: 4265 1.6 eeh return (EOPNOTSUPP); 4266 1.6 eeh } 4267 1.1 mrg 4268 1.19.2.1 bouyer /* 4269 1.19.2.1 bouyer * XXX Hey, we wire `old', but what about `new'? 4270 1.19.2.1 bouyer */ 4271 1.19.2.1 bouyer 4272 1.6 eeh if (SCARG(uap, oldlenp) && 4273 1.19.2.1 bouyer (error = copyin((caddr_t)(u_long)SCARG(uap, oldlenp), &savelen, 4274 1.19.2.1 bouyer sizeof(savelen)))) 4275 1.6 eeh return (error); 4276 1.6 eeh if (SCARG(uap, old) != NULL) { 4277 1.19.2.1 bouyer error = lockmgr(&sysctl_memlock, LK_EXCLUSIVE, NULL); 4278 1.19.2.1 bouyer if (error) 4279 1.19.2.1 bouyer return (error); 4280 1.19.2.1 bouyer if (uvm_vslock(p, (void *)(u_long)SCARG(uap, old), savelen, 4281 1.19.2.1 bouyer VM_PROT_READ|VM_PROT_WRITE) != KERN_SUCCESS) { 4282 1.19.2.1 bouyer (void) lockmgr(&sysctl_memlock, LK_RELEASE, NULL); 4283 1.6 eeh return (EFAULT); 4284 1.13 thorpej } 4285 1.6 eeh oldlen = savelen; 4286 1.6 eeh } 4287 1.19.2.1 bouyer error = (*fn)(name + 1, SCARG(uap, namelen) - 1, 4288 1.19.2.1 bouyer (void *)(u_long)SCARG(uap, old), &oldlen, 4289 1.19.2.1 bouyer (void *)(u_long)SCARG(uap, new), SCARG(uap, newlen), p); 4290 1.6 eeh if (SCARG(uap, old) != NULL) { 4291 1.19.2.1 bouyer uvm_vsunlock(p, (void *)(u_long)SCARG(uap, old), savelen); 4292 1.19.2.1 bouyer (void) lockmgr(&sysctl_memlock, LK_RELEASE, NULL); 4293 1.6 eeh } 4294 1.6 eeh savelen = oldlen; 4295 1.6 eeh if (error) 4296 1.6 eeh return (error); 4297 1.6 eeh if (SCARG(uap, oldlenp)) 4298 1.19.2.1 bouyer error = copyout(&savelen, 4299 1.19.2.1 bouyer (caddr_t)(u_long)SCARG(uap, oldlenp), sizeof(savelen)); 4300 1.6 eeh return (error); 4301 1.1 mrg } 4302 1.1 mrg 4303 1.1 mrg int 4304 1.19 eeh netbsd32_mlock(p, v, retval) 4305 1.1 mrg struct proc *p; 4306 1.1 mrg void *v; 4307 1.1 mrg register_t *retval; 4308 1.1 mrg { 4309 1.19 eeh struct netbsd32_mlock_args /* { 4310 1.10 mrg syscallarg(const netbsd32_voidp) addr; 4311 1.10 mrg syscallarg(netbsd32_size_t) len; 4312 1.1 mrg } */ *uap = v; 4313 1.1 mrg struct sys_mlock_args ua; 4314 1.1 mrg 4315 1.11 mrg NETBSD32TOP_UAP(addr, const void); 4316 1.11 mrg NETBSD32TO64_UAP(len); 4317 1.1 mrg return (sys_mlock(p, &ua, retval)); 4318 1.1 mrg } 4319 1.1 mrg 4320 1.1 mrg int 4321 1.19 eeh netbsd32_munlock(p, v, retval) 4322 1.1 mrg struct proc *p; 4323 1.1 mrg void *v; 4324 1.1 mrg register_t *retval; 4325 1.1 mrg { 4326 1.19 eeh struct netbsd32_munlock_args /* { 4327 1.10 mrg syscallarg(const netbsd32_voidp) addr; 4328 1.10 mrg syscallarg(netbsd32_size_t) len; 4329 1.1 mrg } */ *uap = v; 4330 1.1 mrg struct sys_munlock_args ua; 4331 1.1 mrg 4332 1.11 mrg NETBSD32TOP_UAP(addr, const void); 4333 1.11 mrg NETBSD32TO64_UAP(len); 4334 1.1 mrg return (sys_munlock(p, &ua, retval)); 4335 1.1 mrg } 4336 1.1 mrg 4337 1.1 mrg int 4338 1.19 eeh netbsd32_undelete(p, v, retval) 4339 1.1 mrg struct proc *p; 4340 1.1 mrg void *v; 4341 1.1 mrg register_t *retval; 4342 1.1 mrg { 4343 1.19 eeh struct netbsd32_undelete_args /* { 4344 1.10 mrg syscallarg(const netbsd32_charp) path; 4345 1.1 mrg } */ *uap = v; 4346 1.1 mrg struct sys_undelete_args ua; 4347 1.1 mrg 4348 1.11 mrg NETBSD32TOP_UAP(path, const char); 4349 1.1 mrg return (sys_undelete(p, &ua, retval)); 4350 1.1 mrg } 4351 1.1 mrg 4352 1.1 mrg int 4353 1.19 eeh netbsd32_futimes(p, v, retval) 4354 1.1 mrg struct proc *p; 4355 1.1 mrg void *v; 4356 1.1 mrg register_t *retval; 4357 1.1 mrg { 4358 1.19 eeh struct netbsd32_futimes_args /* { 4359 1.1 mrg syscallarg(int) fd; 4360 1.10 mrg syscallarg(const netbsd32_timevalp_t) tptr; 4361 1.1 mrg } */ *uap = v; 4362 1.6 eeh int error; 4363 1.6 eeh struct file *fp; 4364 1.6 eeh 4365 1.12 thorpej /* getvnode() will use the descriptor for us */ 4366 1.6 eeh if ((error = getvnode(p->p_fd, SCARG(uap, fd), &fp)) != 0) 4367 1.6 eeh return (error); 4368 1.6 eeh 4369 1.12 thorpej error = change_utimes32((struct vnode *)fp->f_data, 4370 1.12 thorpej (struct timeval *)(u_long)SCARG(uap, tptr), p); 4371 1.19 eeh FILE_UNUSE(fp, p); 4372 1.12 thorpej return (error); 4373 1.6 eeh } 4374 1.6 eeh 4375 1.6 eeh int 4376 1.19 eeh netbsd32_getpgid(p, v, retval) 4377 1.6 eeh struct proc *p; 4378 1.6 eeh void *v; 4379 1.6 eeh register_t *retval; 4380 1.6 eeh { 4381 1.19 eeh struct netbsd32_getpgid_args /* { 4382 1.6 eeh syscallarg(pid_t) pid; 4383 1.6 eeh } */ *uap = v; 4384 1.6 eeh struct sys_getpgid_args ua; 4385 1.1 mrg 4386 1.11 mrg NETBSD32TO64_UAP(pid); 4387 1.6 eeh return (sys_getpgid(p, &ua, retval)); 4388 1.1 mrg } 4389 1.1 mrg 4390 1.1 mrg int 4391 1.19 eeh netbsd32_reboot(p, v, retval) 4392 1.1 mrg struct proc *p; 4393 1.1 mrg void *v; 4394 1.1 mrg register_t *retval; 4395 1.1 mrg { 4396 1.19 eeh struct netbsd32_reboot_args /* { 4397 1.1 mrg syscallarg(int) opt; 4398 1.10 mrg syscallarg(netbsd32_charp) bootstr; 4399 1.1 mrg } */ *uap = v; 4400 1.1 mrg struct sys_reboot_args ua; 4401 1.1 mrg 4402 1.11 mrg NETBSD32TO64_UAP(opt); 4403 1.11 mrg NETBSD32TOP_UAP(bootstr, char); 4404 1.1 mrg return (sys_reboot(p, &ua, retval)); 4405 1.1 mrg } 4406 1.1 mrg 4407 1.1 mrg int 4408 1.19 eeh netbsd32_poll(p, v, retval) 4409 1.1 mrg struct proc *p; 4410 1.1 mrg void *v; 4411 1.1 mrg register_t *retval; 4412 1.1 mrg { 4413 1.19 eeh struct netbsd32_poll_args /* { 4414 1.10 mrg syscallarg(netbsd32_pollfdp_t) fds; 4415 1.1 mrg syscallarg(u_int) nfds; 4416 1.1 mrg syscallarg(int) timeout; 4417 1.1 mrg } */ *uap = v; 4418 1.1 mrg struct sys_poll_args ua; 4419 1.1 mrg 4420 1.11 mrg NETBSD32TOP_UAP(fds, struct pollfd); 4421 1.11 mrg NETBSD32TO64_UAP(nfds); 4422 1.11 mrg NETBSD32TO64_UAP(timeout); 4423 1.1 mrg return (sys_poll(p, &ua, retval)); 4424 1.1 mrg } 4425 1.1 mrg 4426 1.19.2.1 bouyer #if defined(SYSVSEM) 4427 1.6 eeh /* 4428 1.6 eeh * XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX 4429 1.6 eeh * 4430 1.6 eeh * This is BSD. We won't support System V IPC. 4431 1.6 eeh * Too much work. 4432 1.6 eeh * 4433 1.6 eeh * XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX 4434 1.6 eeh */ 4435 1.1 mrg int 4436 1.19.2.1 bouyer netbsd32___semctl14(p, v, retval) 4437 1.1 mrg struct proc *p; 4438 1.1 mrg void *v; 4439 1.1 mrg register_t *retval; 4440 1.1 mrg { 4441 1.6 eeh #if 0 4442 1.19 eeh struct netbsd32___semctl_args /* { 4443 1.1 mrg syscallarg(int) semid; 4444 1.1 mrg syscallarg(int) semnum; 4445 1.1 mrg syscallarg(int) cmd; 4446 1.19.2.1 bouyer syscallarg(netbsd32_semunu_t *) arg; 4447 1.1 mrg } */ *uap = v; 4448 1.10 mrg union netbsd32_semun sem32; 4449 1.6 eeh int semid = SCARG(uap, semid); 4450 1.6 eeh int semnum = SCARG(uap, semnum); 4451 1.6 eeh int cmd = SCARG(uap, cmd); 4452 1.10 mrg union netbsd32_semun *arg = (void*)(u_long)SCARG(uap, arg); 4453 1.10 mrg union netbsd32_semun real_arg; 4454 1.6 eeh struct ucred *cred = p->p_ucred; 4455 1.6 eeh int i, rval, eval; 4456 1.10 mrg struct netbsd32_semid_ds sbuf; 4457 1.19.2.1 bouyer struct semid_ds *semaptr; 4458 1.6 eeh 4459 1.6 eeh semlock(p); 4460 1.6 eeh 4461 1.6 eeh semid = IPCID_TO_IX(semid); 4462 1.6 eeh if (semid < 0 || semid >= seminfo.semmsl) 4463 1.6 eeh return(EINVAL); 4464 1.6 eeh 4465 1.6 eeh semaptr = &sema[semid]; 4466 1.6 eeh if ((semaptr->sem_perm.mode & SEM_ALLOC) == 0 || 4467 1.6 eeh semaptr->sem_perm.seq != IPCID_TO_SEQ(SCARG(uap, semid))) 4468 1.6 eeh return(EINVAL); 4469 1.6 eeh 4470 1.6 eeh eval = 0; 4471 1.6 eeh rval = 0; 4472 1.6 eeh 4473 1.6 eeh switch (cmd) { 4474 1.6 eeh case IPC_RMID: 4475 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_M)) != 0) 4476 1.6 eeh return(eval); 4477 1.6 eeh semaptr->sem_perm.cuid = cred->cr_uid; 4478 1.6 eeh semaptr->sem_perm.uid = cred->cr_uid; 4479 1.6 eeh semtot -= semaptr->sem_nsems; 4480 1.19 eeh for (i = semaptr->_sem_base - sem; i < semtot; i++) 4481 1.6 eeh sem[i] = sem[i + semaptr->sem_nsems]; 4482 1.6 eeh for (i = 0; i < seminfo.semmni; i++) { 4483 1.6 eeh if ((sema[i].sem_perm.mode & SEM_ALLOC) && 4484 1.19 eeh sema[i]._sem_base > semaptr->_sem_base) 4485 1.19 eeh sema[i]._sem_base -= semaptr->sem_nsems; 4486 1.6 eeh } 4487 1.6 eeh semaptr->sem_perm.mode = 0; 4488 1.6 eeh semundo_clear(semid, -1); 4489 1.6 eeh wakeup((caddr_t)semaptr); 4490 1.6 eeh break; 4491 1.6 eeh 4492 1.6 eeh case IPC_SET: 4493 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_M))) 4494 1.6 eeh return(eval); 4495 1.6 eeh if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0) 4496 1.6 eeh return(eval); 4497 1.6 eeh if ((eval = copyin((caddr_t)(u_long)real_arg.buf, (caddr_t)&sbuf, 4498 1.6 eeh sizeof(sbuf))) != 0) 4499 1.6 eeh return(eval); 4500 1.6 eeh semaptr->sem_perm.uid = sbuf.sem_perm.uid; 4501 1.6 eeh semaptr->sem_perm.gid = sbuf.sem_perm.gid; 4502 1.6 eeh semaptr->sem_perm.mode = (semaptr->sem_perm.mode & ~0777) | 4503 1.6 eeh (sbuf.sem_perm.mode & 0777); 4504 1.6 eeh semaptr->sem_ctime = time.tv_sec; 4505 1.6 eeh break; 4506 1.6 eeh 4507 1.6 eeh case IPC_STAT: 4508 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R))) 4509 1.6 eeh return(eval); 4510 1.6 eeh if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0) 4511 1.6 eeh return(eval); 4512 1.6 eeh eval = copyout((caddr_t)semaptr, (caddr_t)(u_long)real_arg.buf, 4513 1.6 eeh sizeof(struct semid_ds)); 4514 1.6 eeh break; 4515 1.6 eeh 4516 1.6 eeh case GETNCNT: 4517 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R))) 4518 1.6 eeh return(eval); 4519 1.6 eeh if (semnum < 0 || semnum >= semaptr->sem_nsems) 4520 1.6 eeh return(EINVAL); 4521 1.19 eeh rval = semaptr->_sem_base[semnum].semncnt; 4522 1.6 eeh break; 4523 1.6 eeh 4524 1.6 eeh case GETPID: 4525 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R))) 4526 1.6 eeh return(eval); 4527 1.6 eeh if (semnum < 0 || semnum >= semaptr->sem_nsems) 4528 1.6 eeh return(EINVAL); 4529 1.19 eeh rval = semaptr->_sem_base[semnum].sempid; 4530 1.6 eeh break; 4531 1.6 eeh 4532 1.6 eeh case GETVAL: 4533 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R))) 4534 1.6 eeh return(eval); 4535 1.6 eeh if (semnum < 0 || semnum >= semaptr->sem_nsems) 4536 1.6 eeh return(EINVAL); 4537 1.19 eeh rval = semaptr->_sem_base[semnum].semval; 4538 1.6 eeh break; 4539 1.6 eeh 4540 1.6 eeh case GETALL: 4541 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R))) 4542 1.6 eeh return(eval); 4543 1.6 eeh if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0) 4544 1.6 eeh return(eval); 4545 1.6 eeh for (i = 0; i < semaptr->sem_nsems; i++) { 4546 1.19 eeh eval = copyout((caddr_t)&semaptr->_sem_base[i].semval, 4547 1.6 eeh &real_arg.array[i], sizeof(real_arg.array[0])); 4548 1.6 eeh if (eval != 0) 4549 1.6 eeh break; 4550 1.6 eeh } 4551 1.6 eeh break; 4552 1.1 mrg 4553 1.6 eeh case GETZCNT: 4554 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_R))) 4555 1.6 eeh return(eval); 4556 1.6 eeh if (semnum < 0 || semnum >= semaptr->sem_nsems) 4557 1.6 eeh return(EINVAL); 4558 1.19 eeh rval = semaptr->_sem_base[semnum].semzcnt; 4559 1.6 eeh break; 4560 1.6 eeh 4561 1.6 eeh case SETVAL: 4562 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_W))) 4563 1.6 eeh return(eval); 4564 1.6 eeh if (semnum < 0 || semnum >= semaptr->sem_nsems) 4565 1.6 eeh return(EINVAL); 4566 1.6 eeh if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0) 4567 1.6 eeh return(eval); 4568 1.19 eeh semaptr->_sem_base[semnum].semval = real_arg.val; 4569 1.6 eeh semundo_clear(semid, semnum); 4570 1.6 eeh wakeup((caddr_t)semaptr); 4571 1.6 eeh break; 4572 1.6 eeh 4573 1.6 eeh case SETALL: 4574 1.6 eeh if ((eval = ipcperm(cred, &semaptr->sem_perm, IPC_W))) 4575 1.6 eeh return(eval); 4576 1.6 eeh if ((eval = copyin(arg, &real_arg, sizeof(real_arg))) != 0) 4577 1.6 eeh return(eval); 4578 1.6 eeh for (i = 0; i < semaptr->sem_nsems; i++) { 4579 1.6 eeh eval = copyin(&real_arg.array[i], 4580 1.19 eeh (caddr_t)&semaptr->_sem_base[i].semval, 4581 1.6 eeh sizeof(real_arg.array[0])); 4582 1.6 eeh if (eval != 0) 4583 1.6 eeh break; 4584 1.1 mrg } 4585 1.6 eeh semundo_clear(semid, -1); 4586 1.6 eeh wakeup((caddr_t)semaptr); 4587 1.6 eeh break; 4588 1.1 mrg 4589 1.6 eeh default: 4590 1.6 eeh return(EINVAL); 4591 1.6 eeh } 4592 1.1 mrg 4593 1.6 eeh if (eval == 0) 4594 1.6 eeh *retval = rval; 4595 1.6 eeh return(eval); 4596 1.6 eeh #else 4597 1.6 eeh return (ENOSYS); 4598 1.6 eeh #endif 4599 1.1 mrg } 4600 1.1 mrg 4601 1.1 mrg int 4602 1.19 eeh netbsd32_semget(p, v, retval) 4603 1.1 mrg struct proc *p; 4604 1.1 mrg void *v; 4605 1.1 mrg register_t *retval; 4606 1.1 mrg { 4607 1.19 eeh struct netbsd32_semget_args /* { 4608 1.10 mrg syscallarg(netbsd32_key_t) key; 4609 1.1 mrg syscallarg(int) nsems; 4610 1.1 mrg syscallarg(int) semflg; 4611 1.1 mrg } */ *uap = v; 4612 1.1 mrg struct sys_semget_args ua; 4613 1.1 mrg 4614 1.11 mrg NETBSD32TOX_UAP(key, key_t); 4615 1.11 mrg NETBSD32TO64_UAP(nsems); 4616 1.11 mrg NETBSD32TO64_UAP(semflg); 4617 1.1 mrg return (sys_semget(p, &ua, retval)); 4618 1.1 mrg } 4619 1.1 mrg 4620 1.1 mrg int 4621 1.19 eeh netbsd32_semop(p, v, retval) 4622 1.1 mrg struct proc *p; 4623 1.1 mrg void *v; 4624 1.1 mrg register_t *retval; 4625 1.1 mrg { 4626 1.19 eeh struct netbsd32_semop_args /* { 4627 1.1 mrg syscallarg(int) semid; 4628 1.10 mrg syscallarg(netbsd32_sembufp_t) sops; 4629 1.10 mrg syscallarg(netbsd32_size_t) nsops; 4630 1.1 mrg } */ *uap = v; 4631 1.1 mrg struct sys_semop_args ua; 4632 1.1 mrg 4633 1.11 mrg NETBSD32TO64_UAP(semid); 4634 1.11 mrg NETBSD32TOP_UAP(sops, struct sembuf); 4635 1.11 mrg NETBSD32TOX_UAP(nsops, size_t); 4636 1.2 mrg return (sys_semop(p, &ua, retval)); 4637 1.1 mrg } 4638 1.1 mrg 4639 1.1 mrg int 4640 1.19 eeh netbsd32_semconfig(p, v, retval) 4641 1.6 eeh struct proc *p; 4642 1.6 eeh void *v; 4643 1.6 eeh register_t *retval; 4644 1.6 eeh { 4645 1.19 eeh struct netbsd32_semconfig_args /* { 4646 1.6 eeh syscallarg(int) flag; 4647 1.6 eeh } */ *uap = v; 4648 1.6 eeh struct sys_semconfig_args ua; 4649 1.6 eeh 4650 1.11 mrg NETBSD32TO64_UAP(flag); 4651 1.6 eeh return (sys_semconfig(p, &ua, retval)); 4652 1.6 eeh } 4653 1.19.2.1 bouyer #endif /* SYSVSEM */ 4654 1.19.2.1 bouyer 4655 1.19.2.1 bouyer #if defined(SYSVMSG) 4656 1.6 eeh 4657 1.6 eeh int 4658 1.19.2.1 bouyer netbsd32___msgctl13(p, v, retval) 4659 1.1 mrg struct proc *p; 4660 1.1 mrg void *v; 4661 1.1 mrg register_t *retval; 4662 1.1 mrg { 4663 1.6 eeh #if 0 4664 1.19 eeh struct netbsd32_msgctl_args /* { 4665 1.1 mrg syscallarg(int) msqid; 4666 1.1 mrg syscallarg(int) cmd; 4667 1.10 mrg syscallarg(netbsd32_msqid_dsp_t) buf; 4668 1.1 mrg } */ *uap = v; 4669 1.1 mrg struct sys_msgctl_args ua; 4670 1.1 mrg struct msqid_ds ds; 4671 1.10 mrg struct netbsd32_msqid_ds *ds32p; 4672 1.1 mrg int error; 4673 1.1 mrg 4674 1.11 mrg NETBSD32TO64_UAP(msqid); 4675 1.11 mrg NETBSD32TO64_UAP(cmd); 4676 1.10 mrg ds32p = (struct netbsd32_msqid_ds *)(u_long)SCARG(uap, buf); 4677 1.1 mrg if (ds32p) { 4678 1.1 mrg SCARG(&ua, buf) = NULL; 4679 1.10 mrg netbsd32_to_msqid_ds(ds32p, &ds); 4680 1.1 mrg } else 4681 1.1 mrg SCARG(&ua, buf) = NULL; 4682 1.1 mrg error = sys_msgctl(p, &ua, retval); 4683 1.1 mrg if (error) 4684 1.1 mrg return (error); 4685 1.1 mrg 4686 1.1 mrg if (ds32p) 4687 1.10 mrg netbsd32_from_msqid_ds(&ds, ds32p); 4688 1.1 mrg return (0); 4689 1.6 eeh #else 4690 1.6 eeh return (ENOSYS); 4691 1.6 eeh #endif 4692 1.1 mrg } 4693 1.1 mrg 4694 1.1 mrg int 4695 1.19 eeh netbsd32_msgget(p, v, retval) 4696 1.1 mrg struct proc *p; 4697 1.1 mrg void *v; 4698 1.1 mrg register_t *retval; 4699 1.1 mrg { 4700 1.6 eeh #if 0 4701 1.19 eeh struct netbsd32_msgget_args /* { 4702 1.10 mrg syscallarg(netbsd32_key_t) key; 4703 1.1 mrg syscallarg(int) msgflg; 4704 1.1 mrg } */ *uap = v; 4705 1.1 mrg struct sys_msgget_args ua; 4706 1.1 mrg 4707 1.11 mrg NETBSD32TOX_UAP(key, key_t); 4708 1.11 mrg NETBSD32TO64_UAP(msgflg); 4709 1.1 mrg return (sys_msgget(p, &ua, retval)); 4710 1.6 eeh #else 4711 1.6 eeh return (ENOSYS); 4712 1.6 eeh #endif 4713 1.1 mrg } 4714 1.1 mrg 4715 1.1 mrg int 4716 1.19 eeh netbsd32_msgsnd(p, v, retval) 4717 1.1 mrg struct proc *p; 4718 1.1 mrg void *v; 4719 1.1 mrg register_t *retval; 4720 1.1 mrg { 4721 1.6 eeh #if 0 4722 1.19 eeh struct netbsd32_msgsnd_args /* { 4723 1.1 mrg syscallarg(int) msqid; 4724 1.10 mrg syscallarg(const netbsd32_voidp) msgp; 4725 1.10 mrg syscallarg(netbsd32_size_t) msgsz; 4726 1.1 mrg syscallarg(int) msgflg; 4727 1.1 mrg } */ *uap = v; 4728 1.1 mrg struct sys_msgsnd_args ua; 4729 1.1 mrg 4730 1.11 mrg NETBSD32TO64_UAP(msqid); 4731 1.11 mrg NETBSD32TOP_UAP(msgp, void); 4732 1.11 mrg NETBSD32TOX_UAP(msgsz, size_t); 4733 1.11 mrg NETBSD32TO64_UAP(msgflg); 4734 1.1 mrg return (sys_msgsnd(p, &ua, retval)); 4735 1.6 eeh #else 4736 1.6 eeh return (ENOSYS); 4737 1.6 eeh #endif 4738 1.1 mrg } 4739 1.1 mrg 4740 1.1 mrg int 4741 1.19 eeh netbsd32_msgrcv(p, v, retval) 4742 1.1 mrg struct proc *p; 4743 1.1 mrg void *v; 4744 1.1 mrg register_t *retval; 4745 1.1 mrg { 4746 1.6 eeh #if 0 4747 1.19 eeh struct netbsd32_msgrcv_args /* { 4748 1.1 mrg syscallarg(int) msqid; 4749 1.10 mrg syscallarg(netbsd32_voidp) msgp; 4750 1.10 mrg syscallarg(netbsd32_size_t) msgsz; 4751 1.10 mrg syscallarg(netbsd32_long) msgtyp; 4752 1.1 mrg syscallarg(int) msgflg; 4753 1.1 mrg } */ *uap = v; 4754 1.1 mrg struct sys_msgrcv_args ua; 4755 1.1 mrg ssize_t rt; 4756 1.1 mrg int error; 4757 1.1 mrg 4758 1.11 mrg NETBSD32TO64_UAP(msqid); 4759 1.11 mrg NETBSD32TOP_UAP(msgp, void); 4760 1.11 mrg NETBSD32TOX_UAP(msgsz, size_t); 4761 1.11 mrg NETBSD32TOX_UAP(msgtyp, long); 4762 1.11 mrg NETBSD32TO64_UAP(msgflg); 4763 1.1 mrg error = sys_msgrcv(p, &ua, (register_t *)&rt); 4764 1.19.2.1 bouyer *retval = rt; 4765 1.1 mrg return (error); 4766 1.6 eeh #else 4767 1.6 eeh return (ENOSYS); 4768 1.6 eeh #endif 4769 1.1 mrg } 4770 1.19.2.1 bouyer #endif /* SYSVMSG */ 4771 1.19.2.1 bouyer 4772 1.19.2.1 bouyer #if defined(SYSVSHM) 4773 1.1 mrg 4774 1.1 mrg int 4775 1.19 eeh netbsd32_shmat(p, v, retval) 4776 1.1 mrg struct proc *p; 4777 1.1 mrg void *v; 4778 1.1 mrg register_t *retval; 4779 1.1 mrg { 4780 1.6 eeh #if 0 4781 1.19 eeh struct netbsd32_shmat_args /* { 4782 1.1 mrg syscallarg(int) shmid; 4783 1.10 mrg syscallarg(const netbsd32_voidp) shmaddr; 4784 1.1 mrg syscallarg(int) shmflg; 4785 1.1 mrg } */ *uap = v; 4786 1.1 mrg struct sys_shmat_args ua; 4787 1.1 mrg void *rt; 4788 1.1 mrg int error; 4789 1.1 mrg 4790 1.11 mrg NETBSD32TO64_UAP(shmid); 4791 1.11 mrg NETBSD32TOP_UAP(shmaddr, void); 4792 1.11 mrg NETBSD32TO64_UAP(shmflg); 4793 1.1 mrg error = sys_shmat(p, &ua, (register_t *)&rt); 4794 1.19.2.1 bouyer *retval = rt; 4795 1.1 mrg return (error); 4796 1.6 eeh #else 4797 1.6 eeh return (ENOSYS); 4798 1.6 eeh #endif 4799 1.1 mrg } 4800 1.1 mrg 4801 1.1 mrg int 4802 1.19.2.1 bouyer netbsd32___shmctl13(p, v, retval) 4803 1.1 mrg struct proc *p; 4804 1.1 mrg void *v; 4805 1.1 mrg register_t *retval; 4806 1.1 mrg { 4807 1.6 eeh #if 0 4808 1.19 eeh struct netbsd32_shmctl_args /* { 4809 1.1 mrg syscallarg(int) shmid; 4810 1.1 mrg syscallarg(int) cmd; 4811 1.10 mrg syscallarg(netbsd32_shmid_dsp_t) buf; 4812 1.1 mrg } */ *uap = v; 4813 1.1 mrg struct sys_shmctl_args ua; 4814 1.1 mrg struct shmid_ds ds; 4815 1.10 mrg struct netbsd32_shmid_ds *ds32p; 4816 1.1 mrg int error; 4817 1.1 mrg 4818 1.11 mrg NETBSD32TO64_UAP(shmid); 4819 1.11 mrg NETBSD32TO64_UAP(cmd); 4820 1.10 mrg ds32p = (struct netbsd32_shmid_ds *)(u_long)SCARG(uap, buf); 4821 1.1 mrg if (ds32p) { 4822 1.1 mrg SCARG(&ua, buf) = NULL; 4823 1.10 mrg netbsd32_to_shmid_ds(ds32p, &ds); 4824 1.1 mrg } else 4825 1.1 mrg SCARG(&ua, buf) = NULL; 4826 1.1 mrg error = sys_shmctl(p, &ua, retval); 4827 1.1 mrg if (error) 4828 1.1 mrg return (error); 4829 1.1 mrg 4830 1.1 mrg if (ds32p) 4831 1.10 mrg netbsd32_from_shmid_ds(&ds, ds32p); 4832 1.1 mrg return (0); 4833 1.6 eeh #else 4834 1.6 eeh return (ENOSYS); 4835 1.6 eeh #endif 4836 1.1 mrg } 4837 1.1 mrg 4838 1.1 mrg int 4839 1.19 eeh netbsd32_shmdt(p, v, retval) 4840 1.1 mrg struct proc *p; 4841 1.1 mrg void *v; 4842 1.1 mrg register_t *retval; 4843 1.1 mrg { 4844 1.6 eeh #if 0 4845 1.19 eeh struct netbsd32_shmdt_args /* { 4846 1.10 mrg syscallarg(const netbsd32_voidp) shmaddr; 4847 1.1 mrg } */ *uap = v; 4848 1.1 mrg struct sys_shmdt_args ua; 4849 1.1 mrg 4850 1.11 mrg NETBSD32TOP_UAP(shmaddr, const char); 4851 1.1 mrg return (sys_shmdt(p, &ua, retval)); 4852 1.6 eeh #else 4853 1.6 eeh return (ENOSYS); 4854 1.6 eeh #endif 4855 1.1 mrg } 4856 1.1 mrg 4857 1.1 mrg int 4858 1.19 eeh netbsd32_shmget(p, v, retval) 4859 1.1 mrg struct proc *p; 4860 1.1 mrg void *v; 4861 1.1 mrg register_t *retval; 4862 1.1 mrg { 4863 1.6 eeh #if 0 4864 1.19 eeh struct netbsd32_shmget_args /* { 4865 1.10 mrg syscallarg(netbsd32_key_t) key; 4866 1.10 mrg syscallarg(netbsd32_size_t) size; 4867 1.1 mrg syscallarg(int) shmflg; 4868 1.1 mrg } */ *uap = v; 4869 1.1 mrg struct sys_shmget_args ua; 4870 1.1 mrg 4871 1.11 mrg NETBSD32TOX_UAP(key, key_t) 4872 1.11 mrg NETBSD32TOX_UAP(size, size_t) 4873 1.11 mrg NETBSD32TO64_UAP(shmflg); 4874 1.1 mrg return (sys_shmget(p, &ua, retval)); 4875 1.6 eeh #else 4876 1.6 eeh return (ENOSYS); 4877 1.6 eeh #endif 4878 1.1 mrg } 4879 1.19.2.1 bouyer #endif /* SYSVSHM */ 4880 1.1 mrg 4881 1.1 mrg int 4882 1.19 eeh netbsd32_clock_gettime(p, v, retval) 4883 1.1 mrg struct proc *p; 4884 1.1 mrg void *v; 4885 1.1 mrg register_t *retval; 4886 1.1 mrg { 4887 1.19 eeh struct netbsd32_clock_gettime_args /* { 4888 1.10 mrg syscallarg(netbsd32_clockid_t) clock_id; 4889 1.10 mrg syscallarg(netbsd32_timespecp_t) tp; 4890 1.1 mrg } */ *uap = v; 4891 1.6 eeh clockid_t clock_id; 4892 1.6 eeh struct timeval atv; 4893 1.6 eeh struct timespec ats; 4894 1.10 mrg struct netbsd32_timespec ts32; 4895 1.6 eeh 4896 1.6 eeh clock_id = SCARG(uap, clock_id); 4897 1.6 eeh if (clock_id != CLOCK_REALTIME) 4898 1.6 eeh return (EINVAL); 4899 1.1 mrg 4900 1.6 eeh microtime(&atv); 4901 1.6 eeh TIMEVAL_TO_TIMESPEC(&atv,&ats); 4902 1.10 mrg netbsd32_from_timespec(&ats, &ts32); 4903 1.1 mrg 4904 1.6 eeh return copyout(&ts32, (caddr_t)(u_long)SCARG(uap, tp), sizeof(ts32)); 4905 1.1 mrg } 4906 1.1 mrg 4907 1.1 mrg int 4908 1.19 eeh netbsd32_clock_settime(p, v, retval) 4909 1.1 mrg struct proc *p; 4910 1.1 mrg void *v; 4911 1.1 mrg register_t *retval; 4912 1.1 mrg { 4913 1.19 eeh struct netbsd32_clock_settime_args /* { 4914 1.10 mrg syscallarg(netbsd32_clockid_t) clock_id; 4915 1.10 mrg syscallarg(const netbsd32_timespecp_t) tp; 4916 1.1 mrg } */ *uap = v; 4917 1.10 mrg struct netbsd32_timespec ts32; 4918 1.6 eeh clockid_t clock_id; 4919 1.6 eeh struct timeval atv; 4920 1.6 eeh struct timespec ats; 4921 1.6 eeh int error; 4922 1.6 eeh 4923 1.6 eeh if ((error = suser(p->p_ucred, &p->p_acflag)) != 0) 4924 1.6 eeh return (error); 4925 1.6 eeh 4926 1.6 eeh clock_id = SCARG(uap, clock_id); 4927 1.6 eeh if (clock_id != CLOCK_REALTIME) 4928 1.6 eeh return (EINVAL); 4929 1.6 eeh 4930 1.6 eeh if ((error = copyin((caddr_t)(u_long)SCARG(uap, tp), &ts32, sizeof(ts32))) != 0) 4931 1.6 eeh return (error); 4932 1.6 eeh 4933 1.10 mrg netbsd32_to_timespec(&ts32, &ats); 4934 1.6 eeh TIMESPEC_TO_TIMEVAL(&atv,&ats); 4935 1.6 eeh if ((error = settime(&atv))) 4936 1.6 eeh return (error); 4937 1.1 mrg 4938 1.6 eeh return 0; 4939 1.1 mrg } 4940 1.1 mrg 4941 1.1 mrg int 4942 1.19 eeh netbsd32_clock_getres(p, v, retval) 4943 1.1 mrg struct proc *p; 4944 1.1 mrg void *v; 4945 1.1 mrg register_t *retval; 4946 1.1 mrg { 4947 1.19 eeh struct netbsd32_clock_getres_args /* { 4948 1.10 mrg syscallarg(netbsd32_clockid_t) clock_id; 4949 1.10 mrg syscallarg(netbsd32_timespecp_t) tp; 4950 1.1 mrg } */ *uap = v; 4951 1.10 mrg struct netbsd32_timespec ts32; 4952 1.6 eeh clockid_t clock_id; 4953 1.1 mrg struct timespec ts; 4954 1.6 eeh int error = 0; 4955 1.6 eeh 4956 1.6 eeh clock_id = SCARG(uap, clock_id); 4957 1.6 eeh if (clock_id != CLOCK_REALTIME) 4958 1.6 eeh return (EINVAL); 4959 1.6 eeh 4960 1.6 eeh if (SCARG(uap, tp)) { 4961 1.6 eeh ts.tv_sec = 0; 4962 1.6 eeh ts.tv_nsec = 1000000000 / hz; 4963 1.1 mrg 4964 1.10 mrg netbsd32_from_timespec(&ts, &ts32); 4965 1.6 eeh error = copyout(&ts, (caddr_t)(u_long)SCARG(uap, tp), sizeof(ts)); 4966 1.6 eeh } 4967 1.1 mrg 4968 1.6 eeh return error; 4969 1.1 mrg } 4970 1.1 mrg 4971 1.1 mrg int 4972 1.19 eeh netbsd32_nanosleep(p, v, retval) 4973 1.1 mrg struct proc *p; 4974 1.1 mrg void *v; 4975 1.1 mrg register_t *retval; 4976 1.1 mrg { 4977 1.19 eeh struct netbsd32_nanosleep_args /* { 4978 1.10 mrg syscallarg(const netbsd32_timespecp_t) rqtp; 4979 1.10 mrg syscallarg(netbsd32_timespecp_t) rmtp; 4980 1.1 mrg } */ *uap = v; 4981 1.6 eeh static int nanowait; 4982 1.10 mrg struct netbsd32_timespec ts32; 4983 1.6 eeh struct timespec rqt; 4984 1.6 eeh struct timespec rmt; 4985 1.6 eeh struct timeval atv, utv; 4986 1.6 eeh int error, s, timo; 4987 1.6 eeh 4988 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, rqtp), (caddr_t)&ts32, 4989 1.6 eeh sizeof(ts32)); 4990 1.1 mrg if (error) 4991 1.1 mrg return (error); 4992 1.1 mrg 4993 1.10 mrg netbsd32_to_timespec(&ts32, &rqt); 4994 1.6 eeh TIMESPEC_TO_TIMEVAL(&atv,&rqt) 4995 1.6 eeh if (itimerfix(&atv)) 4996 1.6 eeh return (EINVAL); 4997 1.6 eeh 4998 1.6 eeh s = splclock(); 4999 1.6 eeh timeradd(&atv,&time,&atv); 5000 1.6 eeh timo = hzto(&atv); 5001 1.6 eeh /* 5002 1.6 eeh * Avoid inadvertantly sleeping forever 5003 1.6 eeh */ 5004 1.6 eeh if (timo == 0) 5005 1.6 eeh timo = 1; 5006 1.6 eeh splx(s); 5007 1.6 eeh 5008 1.6 eeh error = tsleep(&nanowait, PWAIT | PCATCH, "nanosleep", timo); 5009 1.6 eeh if (error == ERESTART) 5010 1.6 eeh error = EINTR; 5011 1.6 eeh if (error == EWOULDBLOCK) 5012 1.6 eeh error = 0; 5013 1.6 eeh 5014 1.6 eeh if (SCARG(uap, rmtp)) { 5015 1.6 eeh int error; 5016 1.6 eeh 5017 1.6 eeh s = splclock(); 5018 1.6 eeh utv = time; 5019 1.6 eeh splx(s); 5020 1.6 eeh 5021 1.6 eeh timersub(&atv, &utv, &utv); 5022 1.6 eeh if (utv.tv_sec < 0) 5023 1.6 eeh timerclear(&utv); 5024 1.6 eeh 5025 1.6 eeh TIMEVAL_TO_TIMESPEC(&utv,&rmt); 5026 1.10 mrg netbsd32_from_timespec(&rmt, &ts32); 5027 1.6 eeh error = copyout((caddr_t)&ts32, (caddr_t)(u_long)SCARG(uap,rmtp), 5028 1.6 eeh sizeof(ts32)); 5029 1.6 eeh if (error) 5030 1.6 eeh return (error); 5031 1.6 eeh } 5032 1.6 eeh 5033 1.6 eeh return error; 5034 1.6 eeh } 5035 1.6 eeh 5036 1.6 eeh int 5037 1.19 eeh netbsd32_fdatasync(p, v, retval) 5038 1.6 eeh struct proc *p; 5039 1.6 eeh void *v; 5040 1.6 eeh register_t *retval; 5041 1.6 eeh { 5042 1.19 eeh struct netbsd32_fdatasync_args /* { 5043 1.6 eeh syscallarg(int) fd; 5044 1.6 eeh } */ *uap = v; 5045 1.6 eeh struct sys_fdatasync_args ua; 5046 1.6 eeh 5047 1.11 mrg NETBSD32TO64_UAP(fd); 5048 1.6 eeh 5049 1.6 eeh return (sys_fdatasync(p, &ua, retval)); 5050 1.1 mrg } 5051 1.1 mrg 5052 1.1 mrg int 5053 1.19 eeh netbsd32___posix_rename(p, v, retval) 5054 1.1 mrg struct proc *p; 5055 1.1 mrg void *v; 5056 1.1 mrg register_t *retval; 5057 1.1 mrg { 5058 1.19 eeh struct netbsd32___posix_rename_args /* { 5059 1.10 mrg syscallarg(const netbsd32_charp) from; 5060 1.10 mrg syscallarg(const netbsd32_charp) to; 5061 1.1 mrg } */ *uap = v; 5062 1.1 mrg struct sys___posix_rename_args ua; 5063 1.1 mrg 5064 1.19.2.1 bouyer NETBSD32TOP_UAP(from, const char); 5065 1.19.2.1 bouyer NETBSD32TOP_UAP(to, const char); 5066 1.6 eeh 5067 1.1 mrg return (sys___posix_rename(p, &ua, retval)); 5068 1.1 mrg } 5069 1.1 mrg 5070 1.1 mrg int 5071 1.19 eeh netbsd32_swapctl(p, v, retval) 5072 1.1 mrg struct proc *p; 5073 1.1 mrg void *v; 5074 1.1 mrg register_t *retval; 5075 1.1 mrg { 5076 1.19 eeh struct netbsd32_swapctl_args /* { 5077 1.1 mrg syscallarg(int) cmd; 5078 1.10 mrg syscallarg(const netbsd32_voidp) arg; 5079 1.1 mrg syscallarg(int) misc; 5080 1.1 mrg } */ *uap = v; 5081 1.1 mrg struct sys_swapctl_args ua; 5082 1.1 mrg 5083 1.11 mrg NETBSD32TO64_UAP(cmd); 5084 1.11 mrg NETBSD32TOP_UAP(arg, const void); 5085 1.11 mrg NETBSD32TO64_UAP(misc); 5086 1.1 mrg return (sys_swapctl(p, &ua, retval)); 5087 1.1 mrg } 5088 1.1 mrg 5089 1.1 mrg int 5090 1.19 eeh netbsd32_getdents(p, v, retval) 5091 1.1 mrg struct proc *p; 5092 1.1 mrg void *v; 5093 1.1 mrg register_t *retval; 5094 1.1 mrg { 5095 1.19 eeh struct netbsd32_getdents_args /* { 5096 1.1 mrg syscallarg(int) fd; 5097 1.10 mrg syscallarg(netbsd32_charp) buf; 5098 1.10 mrg syscallarg(netbsd32_size_t) count; 5099 1.1 mrg } */ *uap = v; 5100 1.6 eeh struct file *fp; 5101 1.6 eeh int error, done; 5102 1.1 mrg 5103 1.12 thorpej /* getvnode() will use the descriptor for us */ 5104 1.6 eeh if ((error = getvnode(p->p_fd, SCARG(uap, fd), &fp)) != 0) 5105 1.6 eeh return (error); 5106 1.12 thorpej if ((fp->f_flag & FREAD) == 0) { 5107 1.12 thorpej error = EBADF; 5108 1.12 thorpej goto out; 5109 1.12 thorpej } 5110 1.6 eeh error = vn_readdir(fp, (caddr_t)(u_long)SCARG(uap, buf), UIO_USERSPACE, 5111 1.6 eeh SCARG(uap, count), &done, p, 0, 0); 5112 1.6 eeh *retval = done; 5113 1.12 thorpej out: 5114 1.19 eeh FILE_UNUSE(fp, p); 5115 1.6 eeh return (error); 5116 1.1 mrg } 5117 1.1 mrg 5118 1.6 eeh 5119 1.1 mrg int 5120 1.19 eeh netbsd32_minherit(p, v, retval) 5121 1.1 mrg struct proc *p; 5122 1.1 mrg void *v; 5123 1.1 mrg register_t *retval; 5124 1.1 mrg { 5125 1.19 eeh struct netbsd32_minherit_args /* { 5126 1.10 mrg syscallarg(netbsd32_voidp) addr; 5127 1.10 mrg syscallarg(netbsd32_size_t) len; 5128 1.1 mrg syscallarg(int) inherit; 5129 1.1 mrg } */ *uap = v; 5130 1.1 mrg struct sys_minherit_args ua; 5131 1.1 mrg 5132 1.11 mrg NETBSD32TOP_UAP(addr, void); 5133 1.11 mrg NETBSD32TOX_UAP(len, size_t); 5134 1.11 mrg NETBSD32TO64_UAP(inherit); 5135 1.1 mrg return (sys_minherit(p, &ua, retval)); 5136 1.1 mrg } 5137 1.1 mrg 5138 1.1 mrg int 5139 1.19 eeh netbsd32_lchmod(p, v, retval) 5140 1.1 mrg struct proc *p; 5141 1.1 mrg void *v; 5142 1.1 mrg register_t *retval; 5143 1.1 mrg { 5144 1.19 eeh struct netbsd32_lchmod_args /* { 5145 1.10 mrg syscallarg(const netbsd32_charp) path; 5146 1.1 mrg syscallarg(mode_t) mode; 5147 1.1 mrg } */ *uap = v; 5148 1.1 mrg struct sys_lchmod_args ua; 5149 1.1 mrg 5150 1.11 mrg NETBSD32TOP_UAP(path, const char); 5151 1.11 mrg NETBSD32TO64_UAP(mode); 5152 1.1 mrg return (sys_lchmod(p, &ua, retval)); 5153 1.1 mrg } 5154 1.1 mrg 5155 1.1 mrg int 5156 1.19 eeh netbsd32_lchown(p, v, retval) 5157 1.1 mrg struct proc *p; 5158 1.1 mrg void *v; 5159 1.1 mrg register_t *retval; 5160 1.1 mrg { 5161 1.19 eeh struct netbsd32_lchown_args /* { 5162 1.10 mrg syscallarg(const netbsd32_charp) path; 5163 1.1 mrg syscallarg(uid_t) uid; 5164 1.1 mrg syscallarg(gid_t) gid; 5165 1.1 mrg } */ *uap = v; 5166 1.1 mrg struct sys_lchown_args ua; 5167 1.1 mrg 5168 1.11 mrg NETBSD32TOP_UAP(path, const char); 5169 1.11 mrg NETBSD32TO64_UAP(uid); 5170 1.11 mrg NETBSD32TO64_UAP(gid); 5171 1.1 mrg return (sys_lchown(p, &ua, retval)); 5172 1.1 mrg } 5173 1.1 mrg 5174 1.1 mrg int 5175 1.19 eeh netbsd32_lutimes(p, v, retval) 5176 1.1 mrg struct proc *p; 5177 1.1 mrg void *v; 5178 1.1 mrg register_t *retval; 5179 1.1 mrg { 5180 1.19 eeh struct netbsd32_lutimes_args /* { 5181 1.10 mrg syscallarg(const netbsd32_charp) path; 5182 1.10 mrg syscallarg(const netbsd32_timevalp_t) tptr; 5183 1.1 mrg } */ *uap = v; 5184 1.6 eeh int error; 5185 1.6 eeh struct nameidata nd; 5186 1.1 mrg 5187 1.6 eeh NDINIT(&nd, LOOKUP, NOFOLLOW, UIO_USERSPACE, (caddr_t)(u_long)SCARG(uap, path), p); 5188 1.6 eeh if ((error = namei(&nd)) != 0) 5189 1.6 eeh return (error); 5190 1.6 eeh 5191 1.6 eeh error = change_utimes32(nd.ni_vp, (struct timeval *)(u_long)SCARG(uap, tptr), p); 5192 1.6 eeh 5193 1.6 eeh vrele(nd.ni_vp); 5194 1.6 eeh return (error); 5195 1.1 mrg } 5196 1.1 mrg 5197 1.6 eeh 5198 1.1 mrg int 5199 1.19 eeh netbsd32___msync13(p, v, retval) 5200 1.1 mrg struct proc *p; 5201 1.1 mrg void *v; 5202 1.1 mrg register_t *retval; 5203 1.1 mrg { 5204 1.19 eeh struct netbsd32___msync13_args /* { 5205 1.10 mrg syscallarg(netbsd32_voidp) addr; 5206 1.10 mrg syscallarg(netbsd32_size_t) len; 5207 1.1 mrg syscallarg(int) flags; 5208 1.1 mrg } */ *uap = v; 5209 1.1 mrg struct sys___msync13_args ua; 5210 1.1 mrg 5211 1.11 mrg NETBSD32TOP_UAP(addr, void); 5212 1.11 mrg NETBSD32TOX_UAP(len, size_t); 5213 1.11 mrg NETBSD32TO64_UAP(flags); 5214 1.1 mrg return (sys___msync13(p, &ua, retval)); 5215 1.1 mrg } 5216 1.1 mrg 5217 1.1 mrg int 5218 1.19 eeh netbsd32___stat13(p, v, retval) 5219 1.1 mrg struct proc *p; 5220 1.1 mrg void *v; 5221 1.1 mrg register_t *retval; 5222 1.1 mrg { 5223 1.19 eeh struct netbsd32___stat13_args /* { 5224 1.10 mrg syscallarg(const netbsd32_charp) path; 5225 1.10 mrg syscallarg(netbsd32_statp_t) ub; 5226 1.1 mrg } */ *uap = v; 5227 1.10 mrg struct netbsd32_stat sb32; 5228 1.1 mrg struct stat sb; 5229 1.1 mrg int error; 5230 1.6 eeh struct nameidata nd; 5231 1.19.2.1 bouyer caddr_t sg; 5232 1.19.2.2 bouyer const char *path; 5233 1.19.2.1 bouyer 5234 1.19.2.1 bouyer path = (char *)(u_long)SCARG(uap, path); 5235 1.19.2.1 bouyer sg = stackgap_init(p->p_emul); 5236 1.19.2.2 bouyer CHECK_ALT_EXIST(p, &sg, path); 5237 1.1 mrg 5238 1.19.2.1 bouyer NDINIT(&nd, LOOKUP, FOLLOW | LOCKLEAF, UIO_USERSPACE, path, p); 5239 1.6 eeh if ((error = namei(&nd)) != 0) 5240 1.6 eeh return (error); 5241 1.6 eeh error = vn_stat(nd.ni_vp, &sb, p); 5242 1.6 eeh vput(nd.ni_vp); 5243 1.1 mrg if (error) 5244 1.1 mrg return (error); 5245 1.10 mrg netbsd32_from___stat13(&sb, &sb32); 5246 1.6 eeh error = copyout(&sb32, (caddr_t)(u_long)SCARG(uap, ub), sizeof(sb32)); 5247 1.6 eeh return (error); 5248 1.1 mrg } 5249 1.1 mrg 5250 1.1 mrg int 5251 1.19 eeh netbsd32___fstat13(p, v, retval) 5252 1.1 mrg struct proc *p; 5253 1.1 mrg void *v; 5254 1.1 mrg register_t *retval; 5255 1.1 mrg { 5256 1.19 eeh struct netbsd32___fstat13_args /* { 5257 1.1 mrg syscallarg(int) fd; 5258 1.10 mrg syscallarg(netbsd32_statp_t) sb; 5259 1.1 mrg } */ *uap = v; 5260 1.6 eeh int fd = SCARG(uap, fd); 5261 1.19.2.1 bouyer struct filedesc *fdp = p->p_fd; 5262 1.19.2.1 bouyer struct file *fp; 5263 1.10 mrg struct netbsd32_stat sb32; 5264 1.6 eeh struct stat ub; 5265 1.6 eeh int error = 0; 5266 1.6 eeh 5267 1.6 eeh if ((u_int)fd >= fdp->fd_nfiles || 5268 1.6 eeh (fp = fdp->fd_ofiles[fd]) == NULL) 5269 1.6 eeh return (EBADF); 5270 1.6 eeh switch (fp->f_type) { 5271 1.6 eeh 5272 1.6 eeh case DTYPE_VNODE: 5273 1.6 eeh error = vn_stat((struct vnode *)fp->f_data, &ub, p); 5274 1.6 eeh break; 5275 1.6 eeh 5276 1.6 eeh case DTYPE_SOCKET: 5277 1.6 eeh error = soo_stat((struct socket *)fp->f_data, &ub); 5278 1.6 eeh break; 5279 1.6 eeh 5280 1.6 eeh default: 5281 1.6 eeh panic("fstat"); 5282 1.6 eeh /*NOTREACHED*/ 5283 1.6 eeh } 5284 1.6 eeh if (error == 0) { 5285 1.10 mrg netbsd32_from___stat13(&ub, &sb32); 5286 1.6 eeh error = copyout(&sb32, (caddr_t)(u_long)SCARG(uap, sb), sizeof(sb32)); 5287 1.6 eeh } 5288 1.6 eeh return (error); 5289 1.1 mrg } 5290 1.1 mrg 5291 1.1 mrg int 5292 1.19 eeh netbsd32___lstat13(p, v, retval) 5293 1.1 mrg struct proc *p; 5294 1.1 mrg void *v; 5295 1.1 mrg register_t *retval; 5296 1.1 mrg { 5297 1.19 eeh struct netbsd32___lstat13_args /* { 5298 1.10 mrg syscallarg(const netbsd32_charp) path; 5299 1.10 mrg syscallarg(netbsd32_statp_t) ub; 5300 1.1 mrg } */ *uap = v; 5301 1.10 mrg struct netbsd32_stat sb32; 5302 1.1 mrg struct stat sb; 5303 1.1 mrg int error; 5304 1.6 eeh struct nameidata nd; 5305 1.19.2.1 bouyer caddr_t sg; 5306 1.19.2.2 bouyer const char *path; 5307 1.19.2.1 bouyer 5308 1.19.2.1 bouyer path = (char *)(u_long)SCARG(uap, path); 5309 1.19.2.1 bouyer sg = stackgap_init(p->p_emul); 5310 1.19.2.2 bouyer CHECK_ALT_EXIST(p, &sg, path); 5311 1.1 mrg 5312 1.19.2.1 bouyer NDINIT(&nd, LOOKUP, FOLLOW | LOCKLEAF, UIO_USERSPACE, path, p); 5313 1.6 eeh if ((error = namei(&nd)) != 0) 5314 1.6 eeh return (error); 5315 1.6 eeh error = vn_stat(nd.ni_vp, &sb, p); 5316 1.6 eeh vput(nd.ni_vp); 5317 1.1 mrg if (error) 5318 1.1 mrg return (error); 5319 1.10 mrg netbsd32_from___stat13(&sb, &sb32); 5320 1.6 eeh error = copyout(&sb32, (caddr_t)(u_long)SCARG(uap, ub), sizeof(sb32)); 5321 1.6 eeh return (error); 5322 1.1 mrg } 5323 1.1 mrg 5324 1.1 mrg int 5325 1.19 eeh netbsd32___sigaltstack14(p, v, retval) 5326 1.1 mrg struct proc *p; 5327 1.1 mrg void *v; 5328 1.1 mrg register_t *retval; 5329 1.1 mrg { 5330 1.19 eeh struct netbsd32___sigaltstack14_args /* { 5331 1.10 mrg syscallarg(const netbsd32_sigaltstackp_t) nss; 5332 1.10 mrg syscallarg(netbsd32_sigaltstackp_t) oss; 5333 1.1 mrg } */ *uap = v; 5334 1.10 mrg struct netbsd32_sigaltstack s32; 5335 1.1 mrg struct sigaltstack nss, oss; 5336 1.1 mrg int error; 5337 1.1 mrg 5338 1.6 eeh if (SCARG(uap, nss)) { 5339 1.6 eeh error = copyin((caddr_t)(u_long)SCARG(uap, nss), &s32, sizeof(s32)); 5340 1.6 eeh if (error) 5341 1.6 eeh return (error); 5342 1.6 eeh nss.ss_sp = (void *)(u_long)s32.ss_sp; 5343 1.6 eeh nss.ss_size = (size_t)s32.ss_size; 5344 1.6 eeh nss.ss_flags = s32.ss_flags; 5345 1.6 eeh } 5346 1.6 eeh error = sigaltstack1(p, 5347 1.6 eeh SCARG(uap, nss) ? &nss : 0, SCARG(uap, oss) ? &oss : 0); 5348 1.1 mrg if (error) 5349 1.1 mrg return (error); 5350 1.6 eeh if (SCARG(uap, oss)) { 5351 1.10 mrg s32.ss_sp = (netbsd32_voidp)(u_long)oss.ss_sp; 5352 1.10 mrg s32.ss_size = (netbsd32_size_t)oss.ss_size; 5353 1.6 eeh s32.ss_flags = oss.ss_flags; 5354 1.6 eeh error = copyout(&s32, (caddr_t)(u_long)SCARG(uap, oss), sizeof(s32)); 5355 1.6 eeh if (error) 5356 1.6 eeh return (error); 5357 1.1 mrg } 5358 1.1 mrg return (0); 5359 1.1 mrg } 5360 1.1 mrg 5361 1.1 mrg int 5362 1.19 eeh netbsd32___posix_chown(p, v, retval) 5363 1.1 mrg struct proc *p; 5364 1.1 mrg void *v; 5365 1.1 mrg register_t *retval; 5366 1.1 mrg { 5367 1.19 eeh struct netbsd32___posix_chown_args /* { 5368 1.10 mrg syscallarg(const netbsd32_charp) path; 5369 1.1 mrg syscallarg(uid_t) uid; 5370 1.1 mrg syscallarg(gid_t) gid; 5371 1.1 mrg } */ *uap = v; 5372 1.1 mrg struct sys___posix_chown_args ua; 5373 1.1 mrg 5374 1.11 mrg NETBSD32TOP_UAP(path, const char); 5375 1.11 mrg NETBSD32TO64_UAP(uid); 5376 1.11 mrg NETBSD32TO64_UAP(gid); 5377 1.1 mrg return (sys___posix_chown(p, &ua, retval)); 5378 1.1 mrg } 5379 1.1 mrg 5380 1.1 mrg int 5381 1.19 eeh netbsd32___posix_fchown(p, v, retval) 5382 1.6 eeh struct proc *p; 5383 1.6 eeh void *v; 5384 1.6 eeh register_t *retval; 5385 1.6 eeh { 5386 1.19 eeh struct netbsd32___posix_fchown_args /* { 5387 1.6 eeh syscallarg(int) fd; 5388 1.6 eeh syscallarg(uid_t) uid; 5389 1.6 eeh syscallarg(gid_t) gid; 5390 1.6 eeh } */ *uap = v; 5391 1.6 eeh struct sys___posix_fchown_args ua; 5392 1.6 eeh 5393 1.11 mrg NETBSD32TO64_UAP(fd); 5394 1.11 mrg NETBSD32TO64_UAP(uid); 5395 1.11 mrg NETBSD32TO64_UAP(gid); 5396 1.6 eeh return (sys___posix_fchown(p, &ua, retval)); 5397 1.6 eeh } 5398 1.6 eeh 5399 1.6 eeh int 5400 1.19 eeh netbsd32___posix_lchown(p, v, retval) 5401 1.1 mrg struct proc *p; 5402 1.1 mrg void *v; 5403 1.1 mrg register_t *retval; 5404 1.1 mrg { 5405 1.19 eeh struct netbsd32___posix_lchown_args /* { 5406 1.10 mrg syscallarg(const netbsd32_charp) path; 5407 1.1 mrg syscallarg(uid_t) uid; 5408 1.1 mrg syscallarg(gid_t) gid; 5409 1.1 mrg } */ *uap = v; 5410 1.1 mrg struct sys___posix_lchown_args ua; 5411 1.1 mrg 5412 1.11 mrg NETBSD32TOP_UAP(path, const char); 5413 1.11 mrg NETBSD32TO64_UAP(uid); 5414 1.11 mrg NETBSD32TO64_UAP(gid); 5415 1.1 mrg return (sys___posix_lchown(p, &ua, retval)); 5416 1.1 mrg } 5417 1.1 mrg 5418 1.1 mrg int 5419 1.19 eeh netbsd32_getsid(p, v, retval) 5420 1.6 eeh struct proc *p; 5421 1.6 eeh void *v; 5422 1.6 eeh register_t *retval; 5423 1.6 eeh { 5424 1.19 eeh struct netbsd32_getsid_args /* { 5425 1.6 eeh syscallarg(pid_t) pid; 5426 1.6 eeh } */ *uap = v; 5427 1.6 eeh struct sys_getsid_args ua; 5428 1.6 eeh 5429 1.11 mrg NETBSD32TO64_UAP(pid); 5430 1.6 eeh return (sys_getsid(p, &ua, retval)); 5431 1.6 eeh } 5432 1.6 eeh 5433 1.19.2.2 bouyer #ifdef KTRACE 5434 1.6 eeh int 5435 1.19 eeh netbsd32_fktrace(p, v, retval) 5436 1.6 eeh struct proc *p; 5437 1.6 eeh void *v; 5438 1.6 eeh register_t *retval; 5439 1.6 eeh { 5440 1.19 eeh struct netbsd32_fktrace_args /* { 5441 1.6 eeh syscallarg(const int) fd; 5442 1.6 eeh syscallarg(int) ops; 5443 1.6 eeh syscallarg(int) facs; 5444 1.6 eeh syscallarg(int) pid; 5445 1.6 eeh } */ *uap = v; 5446 1.19.2.2 bouyer #if 0 5447 1.6 eeh struct sys_fktrace_args ua; 5448 1.19.2.2 bouyer #else 5449 1.19.2.2 bouyer /* XXXX */ 5450 1.19.2.2 bouyer struct sys_fktrace_noconst_args { 5451 1.19.2.2 bouyer syscallarg(int) fd; 5452 1.19.2.2 bouyer syscallarg(int) ops; 5453 1.19.2.2 bouyer syscallarg(int) facs; 5454 1.19.2.2 bouyer syscallarg(int) pid; 5455 1.19.2.2 bouyer } ua; 5456 1.19.2.2 bouyer #endif 5457 1.6 eeh 5458 1.19.2.1 bouyer NETBSD32TOX_UAP(fd, int); 5459 1.11 mrg NETBSD32TO64_UAP(ops); 5460 1.11 mrg NETBSD32TO64_UAP(facs); 5461 1.11 mrg NETBSD32TO64_UAP(pid); 5462 1.6 eeh return (sys_fktrace(p, &ua, retval)); 5463 1.6 eeh } 5464 1.19.2.2 bouyer #endif /* KTRACE */ 5465 1.6 eeh 5466 1.6 eeh int 5467 1.19 eeh netbsd32_preadv(p, v, retval) 5468 1.1 mrg struct proc *p; 5469 1.1 mrg void *v; 5470 1.1 mrg register_t *retval; 5471 1.1 mrg { 5472 1.19 eeh struct netbsd32_preadv_args /* { 5473 1.1 mrg syscallarg(int) fd; 5474 1.10 mrg syscallarg(const netbsd32_iovecp_t) iovp; 5475 1.1 mrg syscallarg(int) iovcnt; 5476 1.1 mrg syscallarg(int) pad; 5477 1.1 mrg syscallarg(off_t) offset; 5478 1.1 mrg } */ *uap = v; 5479 1.6 eeh struct filedesc *fdp = p->p_fd; 5480 1.6 eeh struct file *fp; 5481 1.6 eeh struct vnode *vp; 5482 1.6 eeh off_t offset; 5483 1.6 eeh int error, fd = SCARG(uap, fd); 5484 1.6 eeh 5485 1.6 eeh if ((u_int)fd >= fdp->fd_nfiles || 5486 1.6 eeh (fp = fdp->fd_ofiles[fd]) == NULL || 5487 1.6 eeh (fp->f_flag & FREAD) == 0) 5488 1.6 eeh return (EBADF); 5489 1.6 eeh 5490 1.6 eeh vp = (struct vnode *)fp->f_data; 5491 1.6 eeh if (fp->f_type != DTYPE_VNODE 5492 1.6 eeh || vp->v_type == VFIFO) 5493 1.6 eeh return (ESPIPE); 5494 1.6 eeh 5495 1.6 eeh offset = SCARG(uap, offset); 5496 1.1 mrg 5497 1.6 eeh /* 5498 1.6 eeh * XXX This works because no file systems actually 5499 1.6 eeh * XXX take any action on the seek operation. 5500 1.6 eeh */ 5501 1.6 eeh if ((error = VOP_SEEK(vp, fp->f_offset, offset, fp->f_cred)) != 0) 5502 1.6 eeh return (error); 5503 1.1 mrg 5504 1.10 mrg return (dofilereadv32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp), SCARG(uap, iovcnt), 5505 1.6 eeh &offset, 0, retval)); 5506 1.1 mrg } 5507 1.1 mrg 5508 1.1 mrg int 5509 1.19 eeh netbsd32_pwritev(p, v, retval) 5510 1.1 mrg struct proc *p; 5511 1.1 mrg void *v; 5512 1.1 mrg register_t *retval; 5513 1.1 mrg { 5514 1.19 eeh struct netbsd32_pwritev_args /* { 5515 1.1 mrg syscallarg(int) fd; 5516 1.10 mrg syscallarg(const netbsd32_iovecp_t) iovp; 5517 1.1 mrg syscallarg(int) iovcnt; 5518 1.1 mrg syscallarg(int) pad; 5519 1.1 mrg syscallarg(off_t) offset; 5520 1.1 mrg } */ *uap = v; 5521 1.6 eeh struct filedesc *fdp = p->p_fd; 5522 1.6 eeh struct file *fp; 5523 1.6 eeh struct vnode *vp; 5524 1.6 eeh off_t offset; 5525 1.6 eeh int error, fd = SCARG(uap, fd); 5526 1.6 eeh 5527 1.6 eeh if ((u_int)fd >= fdp->fd_nfiles || 5528 1.6 eeh (fp = fdp->fd_ofiles[fd]) == NULL || 5529 1.6 eeh (fp->f_flag & FWRITE) == 0) 5530 1.6 eeh return (EBADF); 5531 1.6 eeh 5532 1.6 eeh vp = (struct vnode *)fp->f_data; 5533 1.6 eeh if (fp->f_type != DTYPE_VNODE 5534 1.6 eeh || vp->v_type == VFIFO) 5535 1.6 eeh return (ESPIPE); 5536 1.6 eeh 5537 1.6 eeh offset = SCARG(uap, offset); 5538 1.6 eeh 5539 1.6 eeh /* 5540 1.6 eeh * XXX This works because no file systems actually 5541 1.6 eeh * XXX take any action on the seek operation. 5542 1.6 eeh */ 5543 1.6 eeh if ((error = VOP_SEEK(vp, fp->f_offset, offset, fp->f_cred)) != 0) 5544 1.6 eeh return (error); 5545 1.6 eeh 5546 1.10 mrg return (dofilewritev32(p, fd, fp, (struct netbsd32_iovec *)(u_long)SCARG(uap, iovp), SCARG(uap, iovcnt), 5547 1.6 eeh &offset, 0, retval)); 5548 1.6 eeh } 5549 1.6 eeh 5550 1.19.2.1 bouyer /* ARGSUSED */ 5551 1.6 eeh int 5552 1.19.2.1 bouyer netbsd32___sigaction14(p, v, retval) 5553 1.19.2.1 bouyer struct proc *p; 5554 1.6 eeh void *v; 5555 1.6 eeh register_t *retval; 5556 1.6 eeh { 5557 1.19.2.1 bouyer struct netbsd32___sigaction14_args /* { 5558 1.19.2.1 bouyer syscallarg(int) signum; 5559 1.19.2.1 bouyer syscallarg(const struct sigaction *) nsa; 5560 1.19.2.1 bouyer syscallarg(struct sigaction *) osa; 5561 1.6 eeh } */ *uap = v; 5562 1.19.2.1 bouyer struct netbsd32_sigaction sa32; 5563 1.19.2.1 bouyer struct sigaction nsa, osa; 5564 1.1 mrg int error; 5565 1.1 mrg 5566 1.19.2.1 bouyer if (SCARG(uap, nsa)) { 5567 1.19.2.1 bouyer error = copyin((caddr_t)(u_long)SCARG(uap, nsa), 5568 1.19.2.1 bouyer &sa32, sizeof(sa32)); 5569 1.19.2.1 bouyer if (error) 5570 1.19.2.1 bouyer return (error); 5571 1.19.2.1 bouyer nsa.sa_handler = (void *)(u_long)sa32.sa_handler; 5572 1.19.2.1 bouyer nsa.sa_mask = sa32.sa_mask; 5573 1.19.2.1 bouyer nsa.sa_flags = sa32.sa_flags; 5574 1.19.2.1 bouyer } 5575 1.19.2.1 bouyer error = sigaction1(p, SCARG(uap, signum), 5576 1.19.2.1 bouyer SCARG(uap, nsa) ? &nsa : 0, SCARG(uap, osa) ? &osa : 0); 5577 1.6 eeh if (error) 5578 1.6 eeh return (error); 5579 1.19.2.1 bouyer if (SCARG(uap, osa)) { 5580 1.19.2.1 bouyer sa32.sa_handler = (netbsd32_voidp)(u_long)osa.sa_handler; 5581 1.19.2.1 bouyer sa32.sa_mask = osa.sa_mask; 5582 1.19.2.1 bouyer sa32.sa_flags = osa.sa_flags; 5583 1.19.2.1 bouyer error = copyout(&sa32, (caddr_t)(u_long)SCARG(uap, osa), sizeof(sa32)); 5584 1.19.2.1 bouyer if (error) 5585 1.19.2.1 bouyer return (error); 5586 1.19.2.1 bouyer } 5587 1.6 eeh return (0); 5588 1.6 eeh } 5589 1.6 eeh 5590 1.19.2.1 bouyer int netbsd32___sigpending14(p, v, retval) 5591 1.19.2.1 bouyer struct proc *p; 5592 1.19.2.1 bouyer void *v; 5593 1.19.2.1 bouyer register_t *retval; 5594 1.19.2.1 bouyer { 5595 1.19.2.1 bouyer struct netbsd32___sigpending14_args /* { 5596 1.19.2.1 bouyer syscallarg(sigset_t *) set; 5597 1.19.2.1 bouyer } */ *uap = v; 5598 1.19.2.1 bouyer struct sys___sigpending14_args ua; 5599 1.19.2.1 bouyer 5600 1.19.2.1 bouyer NETBSD32TOP_UAP(set, sigset_t); 5601 1.19.2.1 bouyer return (sys___sigpending14(p, &ua, retval)); 5602 1.19.2.1 bouyer } 5603 1.19.2.1 bouyer 5604 1.19.2.1 bouyer int netbsd32___sigprocmask14(p, v, retval) 5605 1.19.2.1 bouyer struct proc *p; 5606 1.19.2.1 bouyer void *v; 5607 1.19.2.1 bouyer register_t *retval; 5608 1.19.2.1 bouyer { 5609 1.19.2.1 bouyer struct netbsd32___sigprocmask14_args /* { 5610 1.19.2.1 bouyer syscallarg(int) how; 5611 1.19.2.1 bouyer syscallarg(const sigset_t *) set; 5612 1.19.2.1 bouyer syscallarg(sigset_t *) oset; 5613 1.19.2.1 bouyer } */ *uap = v; 5614 1.19.2.1 bouyer struct sys___sigprocmask14_args ua; 5615 1.19.2.1 bouyer 5616 1.19.2.1 bouyer NETBSD32TO64_UAP(how); 5617 1.19.2.1 bouyer NETBSD32TOP_UAP(set, sigset_t); 5618 1.19.2.1 bouyer NETBSD32TOP_UAP(oset, sigset_t); 5619 1.19.2.1 bouyer return (sys___sigprocmask14(p, &ua, retval)); 5620 1.19.2.1 bouyer } 5621 1.19.2.1 bouyer 5622 1.19.2.1 bouyer int netbsd32___sigsuspend14(p, v, retval) 5623 1.19.2.1 bouyer struct proc *p; 5624 1.19.2.1 bouyer void *v; 5625 1.19.2.1 bouyer register_t *retval; 5626 1.19.2.1 bouyer { 5627 1.19.2.1 bouyer struct netbsd32___sigsuspend14_args /* { 5628 1.19.2.1 bouyer syscallarg(const sigset_t *) set; 5629 1.19.2.1 bouyer } */ *uap = v; 5630 1.19.2.1 bouyer struct sys___sigsuspend14_args ua; 5631 1.19.2.1 bouyer 5632 1.19.2.1 bouyer NETBSD32TOP_UAP(set, sigset_t); 5633 1.19.2.1 bouyer return (sys___sigsuspend14(p, &ua, retval)); 5634 1.19.2.1 bouyer }; 5635 1.19.2.1 bouyer 5636 1.19.2.1 bouyer 5637 1.19.2.1 bouyer /* 5638 1.19.2.1 bouyer * Find pathname of process's current directory. 5639 1.19.2.1 bouyer * 5640 1.19.2.1 bouyer * Use vfs vnode-to-name reverse cache; if that fails, fall back 5641 1.19.2.1 bouyer * to reading directory contents. 5642 1.19.2.1 bouyer */ 5643 1.19.2.1 bouyer int 5644 1.19.2.1 bouyer getcwd_common __P((struct vnode *, struct vnode *, 5645 1.19.2.1 bouyer char **, char *, int, int, struct proc *)); 5646 1.19.2.1 bouyer 5647 1.19.2.1 bouyer int netbsd32___getcwd(p, v, retval) 5648 1.19.2.1 bouyer struct proc *p; 5649 1.19.2.1 bouyer void *v; 5650 1.19.2.1 bouyer register_t *retval; 5651 1.19.2.1 bouyer { 5652 1.19.2.1 bouyer struct netbsd32___getcwd_args /* { 5653 1.19.2.1 bouyer syscallarg(char *) bufp; 5654 1.19.2.1 bouyer syscallarg(size_t) length; 5655 1.19.2.1 bouyer } */ *uap = v; 5656 1.19.2.1 bouyer 5657 1.19.2.1 bouyer int error; 5658 1.19.2.1 bouyer char *path; 5659 1.19.2.1 bouyer char *bp, *bend; 5660 1.19.2.1 bouyer int len = (int)SCARG(uap, length); 5661 1.19.2.1 bouyer int lenused; 5662 1.19.2.1 bouyer 5663 1.19.2.1 bouyer if (len > MAXPATHLEN*4) 5664 1.19.2.1 bouyer len = MAXPATHLEN*4; 5665 1.19.2.1 bouyer else if (len < 2) 5666 1.19.2.1 bouyer return ERANGE; 5667 1.19.2.1 bouyer 5668 1.19.2.1 bouyer path = (char *)malloc(len, M_TEMP, M_WAITOK); 5669 1.19.2.1 bouyer if (!path) 5670 1.19.2.1 bouyer return ENOMEM; 5671 1.19.2.1 bouyer 5672 1.19.2.1 bouyer bp = &path[len]; 5673 1.19.2.1 bouyer bend = bp; 5674 1.19.2.1 bouyer *(--bp) = '\0'; 5675 1.19.2.1 bouyer 5676 1.19.2.1 bouyer /* 5677 1.19.2.1 bouyer * 5th argument here is "max number of vnodes to traverse". 5678 1.19.2.1 bouyer * Since each entry takes up at least 2 bytes in the output buffer, 5679 1.19.2.1 bouyer * limit it to N/2 vnodes for an N byte buffer. 5680 1.19.2.1 bouyer */ 5681 1.19.2.1 bouyer #define GETCWD_CHECK_ACCESS 0x0001 5682 1.19.2.1 bouyer error = getcwd_common (p->p_cwdi->cwdi_cdir, NULL, &bp, path, len/2, 5683 1.19.2.1 bouyer GETCWD_CHECK_ACCESS, p); 5684 1.19.2.1 bouyer 5685 1.19.2.1 bouyer if (error) 5686 1.19.2.1 bouyer goto out; 5687 1.19.2.1 bouyer lenused = bend - bp; 5688 1.19.2.1 bouyer *retval = lenused; 5689 1.19.2.1 bouyer /* put the result into user buffer */ 5690 1.19.2.1 bouyer error = copyout(bp, (caddr_t)(u_long)SCARG(uap, bufp), lenused); 5691 1.19.2.1 bouyer 5692 1.19.2.1 bouyer out: 5693 1.19.2.1 bouyer free(path, M_TEMP); 5694 1.19.2.1 bouyer return error; 5695 1.19.2.1 bouyer } 5696 1.19.2.1 bouyer 5697 1.19.2.1 bouyer int netbsd32_fchroot(p, v, retval) 5698 1.19.2.1 bouyer struct proc *p; 5699 1.19.2.1 bouyer void *v; 5700 1.19.2.1 bouyer register_t *retval; 5701 1.19.2.1 bouyer { 5702 1.19.2.1 bouyer struct netbsd32_fchroot_args /* { 5703 1.19.2.1 bouyer syscallarg(int) fd; 5704 1.19.2.1 bouyer } */ *uap = v; 5705 1.19.2.1 bouyer struct sys_fchroot_args ua; 5706 1.19.2.1 bouyer 5707 1.19.2.1 bouyer NETBSD32TO64_UAP(fd); 5708 1.19.2.1 bouyer return (sys_fchroot(p, &ua, retval)); 5709 1.19.2.1 bouyer } 5710 1.19.2.1 bouyer 5711 1.19.2.1 bouyer /* 5712 1.19.2.1 bouyer * Open a file given a file handle. 5713 1.19.2.1 bouyer * 5714 1.19.2.1 bouyer * Check permissions, allocate an open file structure, 5715 1.19.2.1 bouyer * and call the device open routine if any. 5716 1.19.2.1 bouyer */ 5717 1.19.2.1 bouyer int 5718 1.19.2.1 bouyer netbsd32_fhopen(p, v, retval) 5719 1.19.2.1 bouyer struct proc *p; 5720 1.19.2.1 bouyer void *v; 5721 1.19.2.1 bouyer register_t *retval; 5722 1.19.2.1 bouyer { 5723 1.19.2.1 bouyer struct netbsd32_fhopen_args /* { 5724 1.19.2.1 bouyer syscallarg(const fhandle_t *) fhp; 5725 1.19.2.1 bouyer syscallarg(int) flags; 5726 1.19.2.1 bouyer } */ *uap = v; 5727 1.19.2.1 bouyer struct sys_fhopen_args ua; 5728 1.19.2.1 bouyer 5729 1.19.2.1 bouyer NETBSD32TOP_UAP(fhp, fhandle_t); 5730 1.19.2.1 bouyer NETBSD32TO64_UAP(flags); 5731 1.19.2.1 bouyer return (sys_fhopen(p, &ua, retval)); 5732 1.19.2.1 bouyer } 5733 1.19.2.1 bouyer 5734 1.19.2.1 bouyer int netbsd32_fhstat(p, v, retval) 5735 1.19.2.1 bouyer struct proc *p; 5736 1.19.2.1 bouyer void *v; 5737 1.19.2.1 bouyer register_t *retval; 5738 1.19.2.1 bouyer { 5739 1.19.2.1 bouyer struct netbsd32_fhstat_args /* { 5740 1.19.2.1 bouyer syscallarg(const netbsd32_fhandlep_t) fhp; 5741 1.19.2.1 bouyer syscallarg(struct stat *) sb; 5742 1.19.2.1 bouyer } */ *uap = v; 5743 1.19.2.1 bouyer struct sys_fhstat_args ua; 5744 1.19.2.1 bouyer 5745 1.19.2.1 bouyer NETBSD32TOP_UAP(fhp, const fhandle_t); 5746 1.19.2.1 bouyer NETBSD32TOP_UAP(sb, struct stat); 5747 1.19.2.1 bouyer return (sys_fhstat(p, &ua, retval)); 5748 1.19.2.1 bouyer } 5749 1.19.2.1 bouyer 5750 1.19.2.1 bouyer int netbsd32_fhstatfs(p, v, retval) 5751 1.19.2.1 bouyer struct proc *p; 5752 1.19.2.1 bouyer void *v; 5753 1.19.2.1 bouyer register_t *retval; 5754 1.19.2.1 bouyer { 5755 1.19.2.1 bouyer struct netbsd32_fhstatfs_args /* { 5756 1.19.2.1 bouyer syscallarg(const netbsd32_fhandlep_t) fhp; 5757 1.19.2.1 bouyer syscallarg(struct statfs *) buf; 5758 1.19.2.1 bouyer } */ *uap = v; 5759 1.19.2.1 bouyer struct sys_fhstatfs_args ua; 5760 1.19.2.1 bouyer 5761 1.19.2.1 bouyer NETBSD32TOP_UAP(fhp, const fhandle_t); 5762 1.19.2.1 bouyer NETBSD32TOP_UAP(buf, struct statfs); 5763 1.19.2.1 bouyer return (sys_fhstatfs(p, &ua, retval)); 5764 1.19.2.1 bouyer } 5765 1.19.2.1 bouyer 5766 1.19.2.1 bouyer /* virtual memory syscalls */ 5767 1.6 eeh int 5768 1.19.2.1 bouyer netbsd32_ovadvise(p, v, retval) 5769 1.19.2.1 bouyer struct proc *p; 5770 1.6 eeh void *v; 5771 1.6 eeh register_t *retval; 5772 1.6 eeh { 5773 1.19.2.1 bouyer struct netbsd32_ovadvise_args /* { 5774 1.19.2.1 bouyer syscallarg(int) anom; 5775 1.6 eeh } */ *uap = v; 5776 1.19.2.1 bouyer struct sys_ovadvise_args ua; 5777 1.1 mrg 5778 1.19.2.1 bouyer NETBSD32TO64_UAP(anom); 5779 1.19.2.1 bouyer return (sys_ovadvise(p, &ua, retval)); 5780 1.1 mrg } 5781 1.19.2.1 bouyer 5782
Indexes created Mon Sep 22 21:09:42 GMT 2025