/* * Copyright (c) 2000, 2001, 2002, 2003, 2004, 2005, 2008, 2009 * The President and Fellows of Harvard College. * * 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. * 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. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE UNIVERSITY AND CONTRIBUTORS ``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 UNIVERSITY OR CONTRIBUTORS 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. */ /* * Emulator passthrough filesystem. * * The idea is that this appears as a filesystem in the VFS layer, and * passes VFS operations through a somewhat complicated "hardware" * interface to some simulated "hardware" in System/161 that accesses * the filesystem System/161 is running in. * * This makes it unnecessary to copy the system files to the simulated * disk, although we recommend doing so and trying running without this * device as part of testing your filesystem. */ #include #include #include #include #include #include #include #include #include #include #include #include #include "autoconf.h" /* Register offsets */ #define REG_HANDLE 0 #define REG_OFFSET 4 #define REG_IOLEN 8 #define REG_OPER 12 #define REG_RESULT 16 /* I/O buffer offset */ #define EMU_BUFFER 32768 /* Operation codes for REG_OPER */ #define EMU_OP_OPEN 1 #define EMU_OP_CREATE 2 #define EMU_OP_EXCLCREATE 3 #define EMU_OP_CLOSE 4 #define EMU_OP_READ 5 #define EMU_OP_READDIR 6 #define EMU_OP_WRITE 7 #define EMU_OP_GETSIZE 8 #define EMU_OP_TRUNC 9 /* Result codes for REG_RESULT */ #define EMU_RES_SUCCESS 1 #define EMU_RES_BADHANDLE 2 #define EMU_RES_BADOP 3 #define EMU_RES_BADPATH 4 #define EMU_RES_BADSIZE 5 #define EMU_RES_EXISTS 6 #define EMU_RES_ISDIR 7 #define EMU_RES_MEDIA 8 #define EMU_RES_NOHANDLES 9 #define EMU_RES_NOSPACE 10 #define EMU_RES_NOTDIR 11 #define EMU_RES_UNKNOWN 12 #define EMU_RES_UNSUPP 13 //////////////////////////////////////////////////////////// // // Hardware ops // /* * Shortcut for reading a register */ static inline uint32_t emu_rreg(struct emu_softc *sc, uint32_t reg) { return bus_read_register(sc->e_busdata, sc->e_buspos, reg); } /* * Shortcut for writing a register */ static inline void emu_wreg(struct emu_softc *sc, uint32_t reg, uint32_t val) { bus_write_register(sc->e_busdata, sc->e_buspos, reg, val); } /* * Called by the underlying bus code when an interrupt happens */ void emu_irq(void *dev) { struct emu_softc *sc = dev; sc->e_result = emu_rreg(sc, REG_RESULT); emu_wreg(sc, REG_RESULT, 0); V(sc->e_sem); } /* * Convert the error codes reported by the "hardware" to errnos. * Or, on cases that indicate a programming error in emu.c, panic. */ static uint32_t translate_err(struct emu_softc *sc, uint32_t code) { switch (code) { case EMU_RES_SUCCESS: return 0; case EMU_RES_BADHANDLE: case EMU_RES_BADOP: case EMU_RES_BADSIZE: panic("emu%d: got fatal result code %d\n", sc->e_unit, code); case EMU_RES_BADPATH: return ENOENT; case EMU_RES_EXISTS: return EEXIST; case EMU_RES_ISDIR: return EISDIR; case EMU_RES_MEDIA: return EIO; case EMU_RES_NOHANDLES: return ENFILE; case EMU_RES_NOSPACE: return ENOSPC; case EMU_RES_NOTDIR: return ENOTDIR; case EMU_RES_UNKNOWN: return EIO; case EMU_RES_UNSUPP: return EUNIMP; } kprintf("emu%d: Unknown result code %d\n", sc->e_unit, code); return EAGAIN; } /* * Wait for an operation to complete, and return an errno for the result. */ static int emu_waitdone(struct emu_softc *sc) { P(sc->e_sem); return translate_err(sc, sc->e_result); } /* * Common file open routine (for both VOP_LOOKUP and VOP_CREATE). Not * for VOP_OPEN. At the hardware level, we need to "open" files in * order to look at them, so by the time VOP_OPEN is called the * files are already open. */ static int emu_open(struct emu_softc *sc, uint32_t handle, const char *name, bool create, bool excl, mode_t mode, uint32_t *newhandle, int *newisdir) { uint32_t op; int result; if (strlen(name)+1 > EMU_MAXIO) { return ENAMETOOLONG; } if (create && excl) { op = EMU_OP_EXCLCREATE; } else if (create) { op = EMU_OP_CREATE; } else { op = EMU_OP_OPEN; } /* mode isn't supported (yet?) */ (void)mode; lock_acquire(sc->e_lock); strcpy(sc->e_iobuf, name); emu_wreg(sc, REG_IOLEN, strlen(name)); emu_wreg(sc, REG_HANDLE, handle); emu_wreg(sc, REG_OPER, op); result = emu_waitdone(sc); if (result==0) { *newhandle = emu_rreg(sc, REG_HANDLE); *newisdir = emu_rreg(sc, REG_IOLEN)>0; } lock_release(sc->e_lock); return result; } /* * Routine for closing a file we opened at the hardware level. * This is not necessarily called at VOP_CLOSE time; it's called * at VOP_RECLAIM time. */ static int emu_close(struct emu_softc *sc, uint32_t handle) { int result; bool mine; int retries = 0; mine = lock_do_i_hold(sc->e_lock); if (!mine) { lock_acquire(sc->e_lock); } while (1) { /* Retry operation up to 10 times */ emu_wreg(sc, REG_HANDLE, handle); emu_wreg(sc, REG_OPER, EMU_OP_CLOSE); result = emu_waitdone(sc); if (result==EIO && retries < 10) { kprintf("emu%d: I/O error on close, retrying\n", sc->e_unit); retries++; continue; } break; } if (!mine) { lock_release(sc->e_lock); } return result; } /* * Common code for read and readdir. */ static int emu_doread(struct emu_softc *sc, uint32_t handle, uint32_t len, uint32_t op, struct uio *uio) { int result; KASSERT(uio->uio_rw == UIO_READ); lock_acquire(sc->e_lock); emu_wreg(sc, REG_HANDLE, handle); emu_wreg(sc, REG_IOLEN, len); emu_wreg(sc, REG_OFFSET, uio->uio_offset); emu_wreg(sc, REG_OPER, op); result = emu_waitdone(sc); if (result) { goto out; } result = uiomove(sc->e_iobuf, emu_rreg(sc, REG_IOLEN), uio); uio->uio_offset = emu_rreg(sc, REG_OFFSET); out: lock_release(sc->e_lock); return result; } /* * Read from a hardware-level file handle. */ static int emu_read(struct emu_softc *sc, uint32_t handle, uint32_t len, struct uio *uio) { return emu_doread(sc, handle, len, EMU_OP_READ, uio); } /* * Read a directory entry from a hardware-level file handle. */ static int emu_readdir(struct emu_softc *sc, uint32_t handle, uint32_t len, struct uio *uio) { return emu_doread(sc, handle, len, EMU_OP_READDIR, uio); } /* * Write to a hardware-level file handle. */ static int emu_write(struct emu_softc *sc, uint32_t handle, uint32_t len, struct uio *uio) { int result; KASSERT(uio->uio_rw == UIO_WRITE); lock_acquire(sc->e_lock); emu_wreg(sc, REG_HANDLE, handle); emu_wreg(sc, REG_IOLEN, len); emu_wreg(sc, REG_OFFSET, uio->uio_offset); result = uiomove(sc->e_iobuf, len, uio); if (result) { goto out; } emu_wreg(sc, REG_OPER, EMU_OP_WRITE); result = emu_waitdone(sc); out: lock_release(sc->e_lock); return result; } /* * Get the file size associated with a hardware-level file handle. */ static int emu_getsize(struct emu_softc *sc, uint32_t handle, off_t *retval) { int result; lock_acquire(sc->e_lock); emu_wreg(sc, REG_HANDLE, handle); emu_wreg(sc, REG_OPER, EMU_OP_GETSIZE); result = emu_waitdone(sc); if (result==0) { *retval = emu_rreg(sc, REG_IOLEN); } lock_release(sc->e_lock); return result; } /* * Truncate a hardware-level file handle. */ static int emu_trunc(struct emu_softc *sc, uint32_t handle, off_t len) { int result; lock_acquire(sc->e_lock); emu_wreg(sc, REG_HANDLE, handle); emu_wreg(sc, REG_IOLEN, len); emu_wreg(sc, REG_OPER, EMU_OP_TRUNC); result = emu_waitdone(sc); lock_release(sc->e_lock); return result; } // //////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////// // // vnode functions // // at bottom of this section static int emufs_loadvnode(struct emufs_fs *ef, uint32_t handle, int isdir, struct emufs_vnode **ret); /* * VOP_OPEN on files */ static int emufs_open(struct vnode *v, int openflags) { /* * At this level we do not need to handle O_CREAT, O_EXCL, or O_TRUNC. * We *would* need to handle O_APPEND, but we don't support it. * * Any of O_RDONLY, O_WRONLY, and O_RDWR are valid, so we don't need * to check that either. */ if (openflags & O_APPEND) { return EUNIMP; } (void)v; return 0; } /* * VOP_OPEN on directories */ static int emufs_opendir(struct vnode *v, int openflags) { switch (openflags & O_ACCMODE) { case O_RDONLY: break; case O_WRONLY: case O_RDWR: default: return EISDIR; } if (openflags & O_APPEND) { return EISDIR; } (void)v; return 0; } /* * VOP_CLOSE */ static int emufs_close(struct vnode *v) { (void)v; return 0; } /* * VOP_RECLAIM * * Reclaim should make an effort to returning errors other than EBUSY. */ static int emufs_reclaim(struct vnode *v) { struct emufs_vnode *ev = v->vn_data; struct emufs_fs *ef = v->vn_fs->fs_data; unsigned ix, i, num; int result; /* * Need both of these locks, e_lock to protect the device * and vfs_biglock to protect the fs-related material. */ vfs_biglock_acquire(); lock_acquire(ef->ef_emu->e_lock); if (ev->ev_v.vn_refcount != 1) { lock_release(ef->ef_emu->e_lock); vfs_biglock_release(); return EBUSY; } /* emu_close retries on I/O error */ result = emu_close(ev->ev_emu, ev->ev_handle); if (result) { lock_release(ef->ef_emu->e_lock); vfs_biglock_release(); return result; } num = vnodearray_num(ef->ef_vnodes); ix = num; for (i=0; ief_vnodes, i); if (vx == v) { ix = i; break; } } if (ix == num) { panic("emu%d: reclaim vnode %u not in vnode pool\n", ef->ef_emu->e_unit, ev->ev_handle); } vnodearray_remove(ef->ef_vnodes, ix); VOP_CLEANUP(&ev->ev_v); lock_release(ef->ef_emu->e_lock); vfs_biglock_release(); kfree(ev); return 0; } /* * VOP_READ */ static int emufs_read(struct vnode *v, struct uio *uio) { struct emufs_vnode *ev = v->vn_data; uint32_t amt; size_t oldresid; int result; KASSERT(uio->uio_rw==UIO_READ); while (uio->uio_resid > 0) { amt = uio->uio_resid; if (amt > EMU_MAXIO) { amt = EMU_MAXIO; } oldresid = uio->uio_resid; result = emu_read(ev->ev_emu, ev->ev_handle, amt, uio); if (result) { return result; } if (uio->uio_resid == oldresid) { /* nothing read - EOF */ break; } } return 0; } /* * VOP_READDIR */ static int emufs_getdirentry(struct vnode *v, struct uio *uio) { struct emufs_vnode *ev = v->vn_data; uint32_t amt; KASSERT(uio->uio_rw==UIO_READ); amt = uio->uio_resid; if (amt > EMU_MAXIO) { amt = EMU_MAXIO; } return emu_readdir(ev->ev_emu, ev->ev_handle, amt, uio); } /* * VOP_WRITE */ static int emufs_write(struct vnode *v, struct uio *uio) { struct emufs_vnode *ev = v->vn_data; uint32_t amt; size_t oldresid; int result; KASSERT(uio->uio_rw==UIO_WRITE); while (uio->uio_resid > 0) { amt = uio->uio_resid; if (amt > EMU_MAXIO) { amt = EMU_MAXIO; } oldresid = uio->uio_resid; result = emu_write(ev->ev_emu, ev->ev_handle, amt, uio); if (result) { return result; } if (uio->uio_resid == oldresid) { /* nothing written...? */ break; } } return 0; } /* * VOP_IOCTL */ static int emufs_ioctl(struct vnode *v, int op, userptr_t data) { /* * No ioctls. */ (void)v; (void)op; (void)data; return EINVAL; } /* * VOP_STAT */ static int emufs_stat(struct vnode *v, struct stat *statbuf) { struct emufs_vnode *ev = v->vn_data; int result; bzero(statbuf, sizeof(struct stat)); result = emu_getsize(ev->ev_emu, ev->ev_handle, &statbuf->st_size); if (result) { return result; } result = VOP_GETTYPE(v, &statbuf->st_mode); if (result) { return result; } statbuf->st_mode |= 0644; /* possibly a lie */ statbuf->st_nlink = 1; /* might be a lie, but doesn't matter much */ statbuf->st_blocks = 0; /* almost certainly a lie */ return 0; } /* * VOP_GETTYPE for files */ static int emufs_file_gettype(struct vnode *v, uint32_t *result) { (void)v; *result = S_IFREG; return 0; } /* * VOP_GETTYPE for directories */ static int emufs_dir_gettype(struct vnode *v, uint32_t *result) { (void)v; *result = S_IFDIR; return 0; } /* * VOP_TRYSEEK */ static int emufs_tryseek(struct vnode *v, off_t pos) { if (pos<0) { return EINVAL; } /* Allow anything else */ (void)v; return 0; } /* * VOP_FSYNC */ static int emufs_fsync(struct vnode *v) { (void)v; return 0; } /* * VOP_TRUNCATE */ static int emufs_truncate(struct vnode *v, off_t len) { struct emufs_vnode *ev = v->vn_data; return emu_trunc(ev->ev_emu, ev->ev_handle, len); } /* * VOP_CREAT */ static int emufs_creat(struct vnode *dir, const char *name, bool excl, mode_t mode, struct vnode **ret) { struct emufs_vnode *ev = dir->vn_data; struct emufs_fs *ef = dir->vn_fs->fs_data; struct emufs_vnode *newguy; uint32_t handle; int result; int isdir; result = emu_open(ev->ev_emu, ev->ev_handle, name, true, excl, mode, &handle, &isdir); if (result) { return result; } result = emufs_loadvnode(ef, handle, isdir, &newguy); if (result) { emu_close(ev->ev_emu, handle); return result; } *ret = &newguy->ev_v; return 0; } /* * VOP_LOOKUP */ static int emufs_lookup(struct vnode *dir, char *pathname, struct vnode **ret) { struct emufs_vnode *ev = dir->vn_data; struct emufs_fs *ef = dir->vn_fs->fs_data; struct emufs_vnode *newguy; uint32_t handle; int result; int isdir; result = emu_open(ev->ev_emu, ev->ev_handle, pathname, false, false, 0, &handle, &isdir); if (result) { return result; } result = emufs_loadvnode(ef, handle, isdir, &newguy); if (result) { emu_close(ev->ev_emu, handle); return result; } *ret = &newguy->ev_v; return 0; } /* * VOP_LOOKPARENT */ static int emufs_lookparent(struct vnode *dir, char *pathname, struct vnode **ret, char *buf, size_t len) { char *s; s = strrchr(pathname, '/'); if (s==NULL) { /* just a last component, no directory part */ if (strlen(pathname)+1 > len) { return ENAMETOOLONG; } VOP_INCREF(dir); *ret = dir; strcpy(buf, pathname); return 0; } *s = 0; s++; if (strlen(s)+1 > len) { return ENAMETOOLONG; } strcpy(buf, s); return emufs_lookup(dir, pathname, ret); } /* * VOP_NAMEFILE */ static int emufs_namefile(struct vnode *v, struct uio *uio) { struct emufs_vnode *ev = v->vn_data; struct emufs_fs *ef = v->vn_fs->fs_data; if (ev == ef->ef_root) { /* * Root directory - name is empty string */ return 0; } (void)uio; return EUNIMP; } /* * VOP_MMAP */ static int emufs_mmap(struct vnode *v) { (void)v; return EUNIMP; } ////////////////////////////// /* * Bits not implemented at all on emufs */ static int emufs_dir_tryseek(struct vnode *v, off_t pos) { (void)v; (void)pos; return EUNIMP; } static int emufs_symlink(struct vnode *v, const char *contents, const char *name) { (void)v; (void)contents; (void)name; return EUNIMP; } static int emufs_mkdir(struct vnode *v, const char *name, mode_t mode) { (void)v; (void)name; (void)mode; return EUNIMP; } static int emufs_link(struct vnode *v, const char *name, struct vnode *target) { (void)v; (void)name; (void)target; return EUNIMP; } static int emufs_remove(struct vnode *v, const char *name) { (void)v; (void)name; return EUNIMP; } static int emufs_rmdir(struct vnode *v, const char *name) { (void)v; (void)name; return EUNIMP; } static int emufs_rename(struct vnode *v1, const char *n1, struct vnode *v2, const char *n2) { (void)v1; (void)n1; (void)v2; (void)n2; return EUNIMP; } ////////////////////////////// /* * Routines that fail * * It is kind of silly to write these out each with their particular * arguments; however, portable C doesn't let you cast function * pointers with different argument signatures even if the arguments * are never used. * * The BSD approach (all vnode ops take a vnode pointer and a void * pointer that's cast to a op-specific args structure) avoids this * problem but is otherwise not very appealing. */ static int emufs_void_op_isdir(struct vnode *v) { (void)v; return EISDIR; } static int emufs_uio_op_isdir(struct vnode *v, struct uio *uio) { (void)v; (void)uio; return EISDIR; } static int emufs_uio_op_notdir(struct vnode *v, struct uio *uio) { (void)v; (void)uio; return ENOTDIR; } static int emufs_name_op_notdir(struct vnode *v, const char *name) { (void)v; (void)name; return ENOTDIR; } static int emufs_readlink_notlink(struct vnode *v, struct uio *uio) { (void)v; (void)uio; return EINVAL; } static int emufs_creat_notdir(struct vnode *v, const char *name, bool excl, mode_t mode, struct vnode **retval) { (void)v; (void)name; (void)excl; (void)mode; (void)retval; return ENOTDIR; } static int emufs_symlink_notdir(struct vnode *v, const char *contents, const char *name) { (void)v; (void)contents; (void)name; return ENOTDIR; } static int emufs_mkdir_notdir(struct vnode *v, const char *name, mode_t mode) { (void)v; (void)name; (void)mode; return ENOTDIR; } static int emufs_link_notdir(struct vnode *v, const char *name, struct vnode *target) { (void)v; (void)name; (void)target; return ENOTDIR; } static int emufs_rename_notdir(struct vnode *v1, const char *n1, struct vnode *v2, const char *n2) { (void)v1; (void)n1; (void)v2; (void)n2; return ENOTDIR; } static int emufs_lookup_notdir(struct vnode *v, char *pathname, struct vnode **result) { (void)v; (void)pathname; (void)result; return ENOTDIR; } static int emufs_lookparent_notdir(struct vnode *v, char *pathname, struct vnode **result, char *buf, size_t len) { (void)v; (void)pathname; (void)result; (void)buf; (void)len; return ENOTDIR; } static int emufs_truncate_isdir(struct vnode *v, off_t len) { (void)v; (void)len; return ENOTDIR; } ////////////////////////////// /* * Function table for emufs files. */ static const struct vnode_ops emufs_fileops = { VOP_MAGIC, /* mark this a valid vnode ops table */ emufs_open, emufs_close, emufs_reclaim, emufs_read, emufs_readlink_notlink, emufs_uio_op_notdir, /* getdirentry */ emufs_write, emufs_ioctl, emufs_stat, emufs_file_gettype, emufs_tryseek, emufs_fsync, emufs_mmap, emufs_truncate, emufs_uio_op_notdir, /* namefile */ emufs_creat_notdir, emufs_symlink_notdir, emufs_mkdir_notdir, emufs_link_notdir, emufs_name_op_notdir, /* remove */ emufs_name_op_notdir, /* rmdir */ emufs_rename_notdir, emufs_lookup_notdir, emufs_lookparent_notdir, }; /* * Function table for emufs directories. */ static const struct vnode_ops emufs_dirops = { VOP_MAGIC, /* mark this a valid vnode ops table */ emufs_opendir, emufs_close, emufs_reclaim, emufs_uio_op_isdir, /* read */ emufs_uio_op_isdir, /* readlink */ emufs_getdirentry, emufs_uio_op_isdir, /* write */ emufs_ioctl, emufs_stat, emufs_dir_gettype, emufs_dir_tryseek, emufs_void_op_isdir, /* fsync */ emufs_void_op_isdir, /* mmap */ emufs_truncate_isdir, emufs_namefile, emufs_creat, emufs_symlink, emufs_mkdir, emufs_link, emufs_remove, emufs_rmdir, emufs_rename, emufs_lookup, emufs_lookparent, }; /* * Function to load a vnode into memory. */ static int emufs_loadvnode(struct emufs_fs *ef, uint32_t handle, int isdir, struct emufs_vnode **ret) { struct vnode *v; struct emufs_vnode *ev; unsigned i, num; int result; vfs_biglock_acquire(); lock_acquire(ef->ef_emu->e_lock); num = vnodearray_num(ef->ef_vnodes); for (i=0; ief_vnodes, i); ev = v->vn_data; if (ev->ev_handle == handle) { /* Found */ VOP_INCREF(&ev->ev_v); lock_release(ef->ef_emu->e_lock); vfs_biglock_release(); *ret = ev; return 0; } } /* Didn't have one; create it */ ev = kmalloc(sizeof(struct emufs_vnode)); if (ev==NULL) { lock_release(ef->ef_emu->e_lock); return ENOMEM; } ev->ev_emu = ef->ef_emu; ev->ev_handle = handle; result = VOP_INIT(&ev->ev_v, isdir ? &emufs_dirops : &emufs_fileops, &ef->ef_fs, ev); if (result) { lock_release(ef->ef_emu->e_lock); vfs_biglock_release(); kfree(ev); return result; } result = vnodearray_add(ef->ef_vnodes, &ev->ev_v, NULL); if (result) { /* note: VOP_CLEANUP undoes VOP_INIT - it does not kfree */ VOP_CLEANUP(&ev->ev_v); lock_release(ef->ef_emu->e_lock); vfs_biglock_release(); kfree(ev); return result; } lock_release(ef->ef_emu->e_lock); vfs_biglock_release(); *ret = ev; return 0; } // //////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////// // // Whole-filesystem functions // /* * FSOP_SYNC */ static int emufs_sync(struct fs *fs) { (void)fs; return 0; } /* * FSOP_GETVOLNAME */ static const char * emufs_getvolname(struct fs *fs) { /* We don't have a volume name beyond the device name */ (void)fs; return NULL; } /* * FSOP_GETROOT */ static struct vnode * emufs_getroot(struct fs *fs) { struct emufs_fs *ef; KASSERT(fs != NULL); ef = fs->fs_data; KASSERT(ef != NULL); KASSERT(ef->ef_root != NULL); VOP_INCREF(&ef->ef_root->ev_v); return &ef->ef_root->ev_v; } /* * FSOP_UNMOUNT */ static int emufs_unmount(struct fs *fs) { /* Always prohibit unmount, as we're not really "mounted" */ (void)fs; return EBUSY; } /* * Routine for "mounting" an emufs - we're not really mounted in the * sense that the VFS understands that term, because we're not * connected to a block device. * * Basically, we just add ourselves to the name list in the VFS layer. */ static int emufs_addtovfs(struct emu_softc *sc, const char *devname) { struct emufs_fs *ef; int result; ef = kmalloc(sizeof(struct emufs_fs)); if (ef==NULL) { return ENOMEM; } ef->ef_fs.fs_sync = emufs_sync; ef->ef_fs.fs_getvolname = emufs_getvolname; ef->ef_fs.fs_getroot = emufs_getroot; ef->ef_fs.fs_unmount = emufs_unmount; ef->ef_fs.fs_data = ef; ef->ef_emu = sc; ef->ef_root = NULL; ef->ef_vnodes = vnodearray_create(); if (ef->ef_vnodes == NULL) { kfree(ef); return ENOMEM; } result = emufs_loadvnode(ef, EMU_ROOTHANDLE, 1, &ef->ef_root); if (result) { kfree(ef); return result; } KASSERT(ef->ef_root!=NULL); result = vfs_addfs(devname, &ef->ef_fs); if (result) { VOP_DECREF(&ef->ef_root->ev_v); kfree(ef); } return result; } // //////////////////////////////////////////////////////////// /* * Config routine called by autoconf stuff. * * Initialize our data, then add ourselves to the VFS layer. */ int config_emu(struct emu_softc *sc, int emuno) { char name[32]; sc->e_lock = lock_create("emufs-lock"); if (sc->e_lock == NULL) { return ENOMEM; } sc->e_sem = sem_create("emufs-sem", 0); if (sc->e_sem == NULL) { lock_destroy(sc->e_lock); sc->e_lock = NULL; return ENOMEM; } sc->e_iobuf = bus_map_area(sc->e_busdata, sc->e_buspos, EMU_BUFFER); snprintf(name, sizeof(name), "emu%d", emuno); return emufs_addtovfs(sc, name); }