Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/vpo/@/compat/linux/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/vpo/@/compat/linux/linux_ipc.c |
/*- * Copyright (c) 1994-1995 Søren Schmidt * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer * in this position and unchanged. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/compat/linux/linux_ipc.c 225617 2011-09-16 13:58:51Z kmacy $"); #include <sys/param.h> #include <sys/systm.h> #include <sys/syscallsubr.h> #include <sys/sysproto.h> #include <sys/proc.h> #include <sys/limits.h> #include <sys/msg.h> #include <sys/sem.h> #include <sys/shm.h> #include "opt_compat.h" #ifdef COMPAT_LINUX32 #include <machine/../linux32/linux.h> #include <machine/../linux32/linux32_proto.h> #include <machine/../linux32/linux32_ipc64.h> #else #include <machine/../linux/linux.h> #include <machine/../linux/linux_proto.h> #include <machine/../linux/linux_ipc64.h> #endif #include <compat/linux/linux_ipc.h> #include <compat/linux/linux_util.h> struct l_seminfo { l_int semmap; l_int semmni; l_int semmns; l_int semmnu; l_int semmsl; l_int semopm; l_int semume; l_int semusz; l_int semvmx; l_int semaem; }; struct l_shminfo { l_int shmmax; l_int shmmin; l_int shmmni; l_int shmseg; l_int shmall; }; struct l_shm_info { l_int used_ids; l_ulong shm_tot; /* total allocated shm */ l_ulong shm_rss; /* total resident shm */ l_ulong shm_swp; /* total swapped shm */ l_ulong swap_attempts; l_ulong swap_successes; }; struct l_msginfo { l_int msgpool; l_int msgmap; l_int msgmax; l_int msgmnb; l_int msgmni; l_int msgssz; l_int msgtql; l_ushort msgseg; }; static void bsd_to_linux_shminfo( struct shminfo *bpp, struct l_shminfo *lpp) { lpp->shmmax = bpp->shmmax; lpp->shmmin = bpp->shmmin; lpp->shmmni = bpp->shmmni; lpp->shmseg = bpp->shmseg; lpp->shmall = bpp->shmall; } static void bsd_to_linux_shm_info( struct shm_info *bpp, struct l_shm_info *lpp) { lpp->used_ids = bpp->used_ids ; lpp->shm_tot = bpp->shm_tot ; lpp->shm_rss = bpp->shm_rss ; lpp->shm_swp = bpp->shm_swp ; lpp->swap_attempts = bpp->swap_attempts ; lpp->swap_successes = bpp->swap_successes ; } struct l_ipc_perm { l_key_t key; l_uid16_t uid; l_gid16_t gid; l_uid16_t cuid; l_gid16_t cgid; l_ushort mode; l_ushort seq; }; static void linux_to_bsd_ipc_perm(struct l_ipc_perm *lpp, struct ipc_perm *bpp) { bpp->key = lpp->key; bpp->uid = lpp->uid; bpp->gid = lpp->gid; bpp->cuid = lpp->cuid; bpp->cgid = lpp->cgid; bpp->mode = lpp->mode; bpp->seq = lpp->seq; } static void bsd_to_linux_ipc_perm(struct ipc_perm *bpp, struct l_ipc_perm *lpp) { lpp->key = bpp->key; lpp->uid = bpp->uid; lpp->gid = bpp->gid; lpp->cuid = bpp->cuid; lpp->cgid = bpp->cgid; lpp->mode = bpp->mode; lpp->seq = bpp->seq; } struct l_msqid_ds { struct l_ipc_perm msg_perm; l_uintptr_t msg_first; /* first message on queue,unused */ l_uintptr_t msg_last; /* last message in queue,unused */ l_time_t msg_stime; /* last msgsnd time */ l_time_t msg_rtime; /* last msgrcv time */ l_time_t msg_ctime; /* last change time */ l_ulong msg_lcbytes; /* Reuse junk fields for 32 bit */ l_ulong msg_lqbytes; /* ditto */ l_ushort msg_cbytes; /* current number of bytes on queue */ l_ushort msg_qnum; /* number of messages in queue */ l_ushort msg_qbytes; /* max number of bytes on queue */ l_pid_t msg_lspid; /* pid of last msgsnd */ l_pid_t msg_lrpid; /* last receive pid */ } #if defined(__amd64__) && defined(COMPAT_LINUX32) __packed #endif ; struct l_semid_ds { struct l_ipc_perm sem_perm; l_time_t sem_otime; l_time_t sem_ctime; l_uintptr_t sem_base; l_uintptr_t sem_pending; l_uintptr_t sem_pending_last; l_uintptr_t undo; l_ushort sem_nsems; } #if defined(__amd64__) && defined(COMPAT_LINUX32) __packed #endif ; struct l_shmid_ds { struct l_ipc_perm shm_perm; l_int shm_segsz; l_time_t shm_atime; l_time_t shm_dtime; l_time_t shm_ctime; l_ushort shm_cpid; l_ushort shm_lpid; l_short shm_nattch; l_ushort private1; l_uintptr_t private2; l_uintptr_t private3; }; static void linux_to_bsd_semid_ds(struct l_semid_ds *lsp, struct semid_ds *bsp) { linux_to_bsd_ipc_perm(&lsp->sem_perm, &bsp->sem_perm); bsp->sem_otime = lsp->sem_otime; bsp->sem_ctime = lsp->sem_ctime; bsp->sem_nsems = lsp->sem_nsems; bsp->sem_base = PTRIN(lsp->sem_base); } static void bsd_to_linux_semid_ds(struct semid_ds *bsp, struct l_semid_ds *lsp) { bsd_to_linux_ipc_perm(&bsp->sem_perm, &lsp->sem_perm); lsp->sem_otime = bsp->sem_otime; lsp->sem_ctime = bsp->sem_ctime; lsp->sem_nsems = bsp->sem_nsems; lsp->sem_base = PTROUT(bsp->sem_base); } static void linux_to_bsd_shmid_ds(struct l_shmid_ds *lsp, struct shmid_ds *bsp) { linux_to_bsd_ipc_perm(&lsp->shm_perm, &bsp->shm_perm); bsp->shm_segsz = lsp->shm_segsz; bsp->shm_lpid = lsp->shm_lpid; bsp->shm_cpid = lsp->shm_cpid; bsp->shm_nattch = lsp->shm_nattch; bsp->shm_atime = lsp->shm_atime; bsp->shm_dtime = lsp->shm_dtime; bsp->shm_ctime = lsp->shm_ctime; } static void bsd_to_linux_shmid_ds(struct shmid_ds *bsp, struct l_shmid_ds *lsp) { bsd_to_linux_ipc_perm(&bsp->shm_perm, &lsp->shm_perm); if (bsp->shm_segsz > INT_MAX) lsp->shm_segsz = INT_MAX; else lsp->shm_segsz = bsp->shm_segsz; lsp->shm_lpid = bsp->shm_lpid; lsp->shm_cpid = bsp->shm_cpid; if (bsp->shm_nattch > SHRT_MAX) lsp->shm_nattch = SHRT_MAX; else lsp->shm_nattch = bsp->shm_nattch; lsp->shm_atime = bsp->shm_atime; lsp->shm_dtime = bsp->shm_dtime; lsp->shm_ctime = bsp->shm_ctime; lsp->private3 = 0; } static void linux_to_bsd_msqid_ds(struct l_msqid_ds *lsp, struct msqid_ds *bsp) { linux_to_bsd_ipc_perm(&lsp->msg_perm, &bsp->msg_perm); bsp->msg_cbytes = lsp->msg_cbytes; bsp->msg_qnum = lsp->msg_qnum; bsp->msg_qbytes = lsp->msg_qbytes; bsp->msg_lspid = lsp->msg_lspid; bsp->msg_lrpid = lsp->msg_lrpid; bsp->msg_stime = lsp->msg_stime; bsp->msg_rtime = lsp->msg_rtime; bsp->msg_ctime = lsp->msg_ctime; } static void bsd_to_linux_msqid_ds(struct msqid_ds *bsp, struct l_msqid_ds *lsp) { bsd_to_linux_ipc_perm(&bsp->msg_perm, &lsp->msg_perm); lsp->msg_cbytes = bsp->msg_cbytes; lsp->msg_qnum = bsp->msg_qnum; lsp->msg_qbytes = bsp->msg_qbytes; lsp->msg_lspid = bsp->msg_lspid; lsp->msg_lrpid = bsp->msg_lrpid; lsp->msg_stime = bsp->msg_stime; lsp->msg_rtime = bsp->msg_rtime; lsp->msg_ctime = bsp->msg_ctime; } static void linux_ipc_perm_to_ipc64_perm(struct l_ipc_perm *in, struct l_ipc64_perm *out) { /* XXX: do we really need to do something here? */ out->key = in->key; out->uid = in->uid; out->gid = in->gid; out->cuid = in->cuid; out->cgid = in->cgid; out->mode = in->mode; out->seq = in->seq; } static int linux_msqid_pullup(l_int ver, struct l_msqid_ds *linux_msqid, caddr_t uaddr) { struct l_msqid64_ds linux_msqid64; int error; if (ver == LINUX_IPC_64) { error = copyin(uaddr, &linux_msqid64, sizeof(linux_msqid64)); if (error != 0) return (error); bzero(linux_msqid, sizeof(*linux_msqid)); linux_msqid->msg_perm.uid = linux_msqid64.msg_perm.uid; linux_msqid->msg_perm.gid = linux_msqid64.msg_perm.gid; linux_msqid->msg_perm.mode = linux_msqid64.msg_perm.mode; if (linux_msqid64.msg_qbytes > USHRT_MAX) linux_msqid->msg_lqbytes = linux_msqid64.msg_qbytes; else linux_msqid->msg_qbytes = linux_msqid64.msg_qbytes; } else error = copyin(uaddr, linux_msqid, sizeof(*linux_msqid)); return (error); } static int linux_msqid_pushdown(l_int ver, struct l_msqid_ds *linux_msqid, caddr_t uaddr) { struct l_msqid64_ds linux_msqid64; if (ver == LINUX_IPC_64) { bzero(&linux_msqid64, sizeof(linux_msqid64)); linux_ipc_perm_to_ipc64_perm(&linux_msqid->msg_perm, &linux_msqid64.msg_perm); linux_msqid64.msg_stime = linux_msqid->msg_stime; linux_msqid64.msg_rtime = linux_msqid->msg_rtime; linux_msqid64.msg_ctime = linux_msqid->msg_ctime; if (linux_msqid->msg_cbytes == 0) linux_msqid64.msg_cbytes = linux_msqid->msg_lcbytes; else linux_msqid64.msg_cbytes = linux_msqid->msg_cbytes; linux_msqid64.msg_qnum = linux_msqid->msg_qnum; if (linux_msqid->msg_qbytes == 0) linux_msqid64.msg_qbytes = linux_msqid->msg_lqbytes; else linux_msqid64.msg_qbytes = linux_msqid->msg_qbytes; linux_msqid64.msg_lspid = linux_msqid->msg_lspid; linux_msqid64.msg_lrpid = linux_msqid->msg_lrpid; return (copyout(&linux_msqid64, uaddr, sizeof(linux_msqid64))); } else return (copyout(linux_msqid, uaddr, sizeof(*linux_msqid))); } static int linux_semid_pullup(l_int ver, struct l_semid_ds *linux_semid, caddr_t uaddr) { struct l_semid64_ds linux_semid64; int error; if (ver == LINUX_IPC_64) { error = copyin(uaddr, &linux_semid64, sizeof(linux_semid64)); if (error != 0) return (error); bzero(linux_semid, sizeof(*linux_semid)); linux_semid->sem_perm.uid = linux_semid64.sem_perm.uid; linux_semid->sem_perm.gid = linux_semid64.sem_perm.gid; linux_semid->sem_perm.mode = linux_semid64.sem_perm.mode; } else error = copyin(uaddr, linux_semid, sizeof(*linux_semid)); return (error); } static int linux_semid_pushdown(l_int ver, struct l_semid_ds *linux_semid, caddr_t uaddr) { struct l_semid64_ds linux_semid64; if (ver == LINUX_IPC_64) { bzero(&linux_semid64, sizeof(linux_semid64)); linux_ipc_perm_to_ipc64_perm(&linux_semid->sem_perm, &linux_semid64.sem_perm); linux_semid64.sem_otime = linux_semid->sem_otime; linux_semid64.sem_ctime = linux_semid->sem_ctime; linux_semid64.sem_nsems = linux_semid->sem_nsems; return (copyout(&linux_semid64, uaddr, sizeof(linux_semid64))); } else return (copyout(linux_semid, uaddr, sizeof(*linux_semid))); } static int linux_shmid_pullup(l_int ver, struct l_shmid_ds *linux_shmid, caddr_t uaddr) { struct l_shmid64_ds linux_shmid64; int error; if (ver == LINUX_IPC_64) { error = copyin(uaddr, &linux_shmid64, sizeof(linux_shmid64)); if (error != 0) return (error); bzero(linux_shmid, sizeof(*linux_shmid)); linux_shmid->shm_perm.uid = linux_shmid64.shm_perm.uid; linux_shmid->shm_perm.gid = linux_shmid64.shm_perm.gid; linux_shmid->shm_perm.mode = linux_shmid64.shm_perm.mode; } else error = copyin(uaddr, linux_shmid, sizeof(*linux_shmid)); return (error); } static int linux_shmid_pushdown(l_int ver, struct l_shmid_ds *linux_shmid, caddr_t uaddr) { struct l_shmid64_ds linux_shmid64; /* * XXX: This is backwards and loses information in shm_nattch * and shm_segsz. We should probably either expose the BSD * shmid structure directly and convert it to either the * non-64 or 64 variant directly or the code should always * convert to the 64 variant and then truncate values into the * non-64 variant if needed since the 64 variant has more * precision. */ if (ver == LINUX_IPC_64) { bzero(&linux_shmid64, sizeof(linux_shmid64)); linux_ipc_perm_to_ipc64_perm(&linux_shmid->shm_perm, &linux_shmid64.shm_perm); linux_shmid64.shm_segsz = linux_shmid->shm_segsz; linux_shmid64.shm_atime = linux_shmid->shm_atime; linux_shmid64.shm_dtime = linux_shmid->shm_dtime; linux_shmid64.shm_ctime = linux_shmid->shm_ctime; linux_shmid64.shm_cpid = linux_shmid->shm_cpid; linux_shmid64.shm_lpid = linux_shmid->shm_lpid; linux_shmid64.shm_nattch = linux_shmid->shm_nattch; return (copyout(&linux_shmid64, uaddr, sizeof(linux_shmid64))); } else return (copyout(linux_shmid, uaddr, sizeof(*linux_shmid))); } static int linux_shminfo_pushdown(l_int ver, struct l_shminfo *linux_shminfo, caddr_t uaddr) { struct l_shminfo64 linux_shminfo64; if (ver == LINUX_IPC_64) { bzero(&linux_shminfo64, sizeof(linux_shminfo64)); linux_shminfo64.shmmax = linux_shminfo->shmmax; linux_shminfo64.shmmin = linux_shminfo->shmmin; linux_shminfo64.shmmni = linux_shminfo->shmmni; linux_shminfo64.shmseg = linux_shminfo->shmseg; linux_shminfo64.shmall = linux_shminfo->shmall; return (copyout(&linux_shminfo64, uaddr, sizeof(linux_shminfo64))); } else return (copyout(linux_shminfo, uaddr, sizeof(*linux_shminfo))); } int linux_semop(struct thread *td, struct linux_semop_args *args) { struct semop_args /* { int semid; struct sembuf *sops; int nsops; } */ bsd_args; bsd_args.semid = args->semid; bsd_args.sops = PTRIN(args->tsops); bsd_args.nsops = args->nsops; return (sys_semop(td, &bsd_args)); } int linux_semget(struct thread *td, struct linux_semget_args *args) { struct semget_args /* { key_t key; int nsems; int semflg; } */ bsd_args; if (args->nsems < 0) return (EINVAL); bsd_args.key = args->key; bsd_args.nsems = args->nsems; bsd_args.semflg = args->semflg; return (sys_semget(td, &bsd_args)); } int linux_semctl(struct thread *td, struct linux_semctl_args *args) { struct l_semid_ds linux_semid; struct l_seminfo linux_seminfo; struct semid_ds semid; union semun semun; register_t rval; int cmd, error; switch (args->cmd & ~LINUX_IPC_64) { case LINUX_IPC_RMID: cmd = IPC_RMID; break; case LINUX_GETNCNT: cmd = GETNCNT; break; case LINUX_GETPID: cmd = GETPID; break; case LINUX_GETVAL: cmd = GETVAL; break; case LINUX_GETZCNT: cmd = GETZCNT; break; case LINUX_SETVAL: cmd = SETVAL; semun.val = args->arg.val; break; case LINUX_IPC_SET: cmd = IPC_SET; error = linux_semid_pullup(args->cmd & LINUX_IPC_64, &linux_semid, PTRIN(args->arg.buf)); if (error) return (error); linux_to_bsd_semid_ds(&linux_semid, &semid); semun.buf = &semid; return (kern_semctl(td, args->semid, args->semnum, cmd, &semun, td->td_retval)); case LINUX_IPC_STAT: case LINUX_SEM_STAT: if ((args->cmd & ~LINUX_IPC_64) == LINUX_IPC_STAT) cmd = IPC_STAT; else cmd = SEM_STAT; semun.buf = &semid; error = kern_semctl(td, args->semid, args->semnum, cmd, &semun, &rval); if (error) return (error); bsd_to_linux_semid_ds(&semid, &linux_semid); error = linux_semid_pushdown(args->cmd & LINUX_IPC_64, &linux_semid, PTRIN(args->arg.buf)); if (error == 0) td->td_retval[0] = (cmd == SEM_STAT) ? rval : 0; return (error); case LINUX_IPC_INFO: case LINUX_SEM_INFO: bcopy(&seminfo, &linux_seminfo.semmni, sizeof(linux_seminfo) - sizeof(linux_seminfo.semmap) ); /* * Linux does not use the semmap field but populates it with * the defined value from SEMMAP, which really is redefined to * SEMMNS, which they define as SEMMNI * SEMMSL. Try to * simulate this returning our dynamic semmns value. */ linux_seminfo.semmap = linux_seminfo.semmns; /* XXX BSD equivalent? #define used_semids 10 #define used_sems 10 linux_seminfo.semusz = used_semids; linux_seminfo.semaem = used_sems; */ error = copyout(&linux_seminfo, PTRIN(args->arg.buf), sizeof(linux_seminfo)); if (error) return (error); td->td_retval[0] = seminfo.semmni; return (0); /* No need for __semctl call */ case LINUX_GETALL: cmd = GETALL; semun.val = args->arg.val; break; case LINUX_SETALL: cmd = SETALL; semun.val = args->arg.val; break; default: linux_msg(td, "ipc type %d is not implemented", args->cmd & ~LINUX_IPC_64); return (EINVAL); } return (kern_semctl(td, args->semid, args->semnum, cmd, &semun, td->td_retval)); } int linux_msgsnd(struct thread *td, struct linux_msgsnd_args *args) { const void *msgp; long mtype; l_long lmtype; int error; if ((l_long)args->msgsz < 0 || args->msgsz > (l_long)msginfo.msgmax) return (EINVAL); msgp = PTRIN(args->msgp); if ((error = copyin(msgp, &lmtype, sizeof(lmtype))) != 0) return (error); mtype = (long)lmtype; return (kern_msgsnd(td, args->msqid, (const char *)msgp + sizeof(lmtype), args->msgsz, args->msgflg, mtype)); } int linux_msgrcv(struct thread *td, struct linux_msgrcv_args *args) { void *msgp; long mtype; l_long lmtype; int error; if ((l_long)args->msgsz < 0 || args->msgsz > (l_long)msginfo.msgmax) return (EINVAL); msgp = PTRIN(args->msgp); if ((error = kern_msgrcv(td, args->msqid, (char *)msgp + sizeof(lmtype), args->msgsz, args->msgtyp, args->msgflg, &mtype)) != 0) return (error); lmtype = (l_long)mtype; return (copyout(&lmtype, msgp, sizeof(lmtype))); } int linux_msgget(struct thread *td, struct linux_msgget_args *args) { struct msgget_args /* { key_t key; int msgflg; } */ bsd_args; bsd_args.key = args->key; bsd_args.msgflg = args->msgflg; return (sys_msgget(td, &bsd_args)); } int linux_msgctl(struct thread *td, struct linux_msgctl_args *args) { int error, bsd_cmd; struct l_msqid_ds linux_msqid; struct msqid_ds bsd_msqid; bsd_cmd = args->cmd & ~LINUX_IPC_64; switch (bsd_cmd) { case LINUX_IPC_INFO: case LINUX_MSG_INFO: { struct l_msginfo linux_msginfo; /* * XXX MSG_INFO uses the same data structure but returns different * dynamic counters in msgpool, msgmap, and msgtql fields. */ linux_msginfo.msgpool = (long)msginfo.msgmni * (long)msginfo.msgmnb / 1024L; /* XXX MSG_INFO. */ linux_msginfo.msgmap = msginfo.msgmnb; /* XXX MSG_INFO. */ linux_msginfo.msgmax = msginfo.msgmax; linux_msginfo.msgmnb = msginfo.msgmnb; linux_msginfo.msgmni = msginfo.msgmni; linux_msginfo.msgssz = msginfo.msgssz; linux_msginfo.msgtql = msginfo.msgtql; /* XXX MSG_INFO. */ linux_msginfo.msgseg = msginfo.msgseg; error = copyout(&linux_msginfo, PTRIN(args->buf), sizeof(linux_msginfo)); if (error == 0) td->td_retval[0] = msginfo.msgmni; /* XXX */ return (error); } /* * TODO: implement this * case LINUX_MSG_STAT: */ case LINUX_IPC_STAT: /* NOTHING */ break; case LINUX_IPC_SET: error = linux_msqid_pullup(args->cmd & LINUX_IPC_64, &linux_msqid, PTRIN(args->buf)); if (error) return (error); linux_to_bsd_msqid_ds(&linux_msqid, &bsd_msqid); break; case LINUX_IPC_RMID: /* NOTHING */ break; default: return (EINVAL); break; } error = kern_msgctl(td, args->msqid, bsd_cmd, &bsd_msqid); if (error != 0) if (bsd_cmd != LINUX_IPC_RMID || error != EINVAL) return (error); if (bsd_cmd == LINUX_IPC_STAT) { bsd_to_linux_msqid_ds(&bsd_msqid, &linux_msqid); return (linux_msqid_pushdown(args->cmd & LINUX_IPC_64, &linux_msqid, PTRIN(args->buf))); } return (0); } int linux_shmat(struct thread *td, struct linux_shmat_args *args) { struct shmat_args /* { int shmid; void *shmaddr; int shmflg; } */ bsd_args; int error; #if defined(__i386__) || (defined(__amd64__) && defined(COMPAT_LINUX32)) l_uintptr_t addr; #endif bsd_args.shmid = args->shmid; bsd_args.shmaddr = PTRIN(args->shmaddr); bsd_args.shmflg = args->shmflg; if ((error = sys_shmat(td, &bsd_args))) return (error); #if defined(__i386__) || (defined(__amd64__) && defined(COMPAT_LINUX32)) addr = td->td_retval[0]; if ((error = copyout(&addr, PTRIN(args->raddr), sizeof(addr)))) return (error); td->td_retval[0] = 0; #endif return (0); } int linux_shmdt(struct thread *td, struct linux_shmdt_args *args) { struct shmdt_args /* { void *shmaddr; } */ bsd_args; bsd_args.shmaddr = PTRIN(args->shmaddr); return (sys_shmdt(td, &bsd_args)); } int linux_shmget(struct thread *td, struct linux_shmget_args *args) { struct shmget_args /* { key_t key; int size; int shmflg; } */ bsd_args; bsd_args.key = args->key; bsd_args.size = args->size; bsd_args.shmflg = args->shmflg; return (sys_shmget(td, &bsd_args)); } int linux_shmctl(struct thread *td, struct linux_shmctl_args *args) { struct l_shmid_ds linux_shmid; struct l_shminfo linux_shminfo; struct l_shm_info linux_shm_info; struct shmid_ds bsd_shmid; int error; switch (args->cmd & ~LINUX_IPC_64) { case LINUX_IPC_INFO: { struct shminfo bsd_shminfo; /* Perform shmctl wanting removed segments lookup */ error = kern_shmctl(td, args->shmid, IPC_INFO, (void *)&bsd_shminfo, NULL); if (error) return (error); bsd_to_linux_shminfo(&bsd_shminfo, &linux_shminfo); return (linux_shminfo_pushdown(args->cmd & LINUX_IPC_64, &linux_shminfo, PTRIN(args->buf))); } case LINUX_SHM_INFO: { struct shm_info bsd_shm_info; /* Perform shmctl wanting removed segments lookup */ error = kern_shmctl(td, args->shmid, SHM_INFO, (void *)&bsd_shm_info, NULL); if (error) return (error); bsd_to_linux_shm_info(&bsd_shm_info, &linux_shm_info); return (copyout(&linux_shm_info, PTRIN(args->buf), sizeof(struct l_shm_info))); } case LINUX_IPC_STAT: /* Perform shmctl wanting removed segments lookup */ error = kern_shmctl(td, args->shmid, IPC_STAT, (void *)&bsd_shmid, NULL); if (error) return (error); bsd_to_linux_shmid_ds(&bsd_shmid, &linux_shmid); return (linux_shmid_pushdown(args->cmd & LINUX_IPC_64, &linux_shmid, PTRIN(args->buf))); case LINUX_SHM_STAT: /* Perform shmctl wanting removed segments lookup */ error = kern_shmctl(td, args->shmid, IPC_STAT, (void *)&bsd_shmid, NULL); if (error) return (error); bsd_to_linux_shmid_ds(&bsd_shmid, &linux_shmid); return (linux_shmid_pushdown(args->cmd & LINUX_IPC_64, &linux_shmid, PTRIN(args->buf))); case LINUX_IPC_SET: error = linux_shmid_pullup(args->cmd & LINUX_IPC_64, &linux_shmid, PTRIN(args->buf)); if (error) return (error); linux_to_bsd_shmid_ds(&linux_shmid, &bsd_shmid); /* Perform shmctl wanting removed segments lookup */ return (kern_shmctl(td, args->shmid, IPC_SET, (void *)&bsd_shmid, NULL)); case LINUX_IPC_RMID: { void *buf; if (args->buf == 0) buf = NULL; else { error = linux_shmid_pullup(args->cmd & LINUX_IPC_64, &linux_shmid, PTRIN(args->buf)); if (error) return (error); linux_to_bsd_shmid_ds(&linux_shmid, &bsd_shmid); buf = (void *)&bsd_shmid; } return (kern_shmctl(td, args->shmid, IPC_RMID, buf, NULL)); } case LINUX_SHM_LOCK: /* FALLTHROUGH */ case LINUX_SHM_UNLOCK: /* FALLTHROUGH */ default: linux_msg(td, "ipc type %d not implemented", args->cmd & ~LINUX_IPC_64); return (EINVAL); } } MODULE_DEPEND(linux, sysvmsg, 1, 1, 1); MODULE_DEPEND(linux, sysvsem, 1, 1, 1); MODULE_DEPEND(linux, sysvshm, 1, 1, 1);