/* When a needed block is not in the cache, it must be fetched from the disk. * Special character files also require I/O. The routines for these are here. * * The entry points in this file are: * dev_open: FS opens a device * dev_close: FS closes a device * dev_io: FS does a read or write on a device * dev_status: FS processes callback request alert * gen_opcl: generic call to a task to perform an open/close * gen_io: generic call to a task to perform an I/O operation * no_dev: open/close processing for devices that don't exist * no_dev_io: i/o processing for devices that don't exist * tty_opcl: perform tty-specific processing for open/close * ctty_opcl: perform controlling-tty-specific processing for open/close * ctty_io: perform controlling-tty-specific processing for I/O * do_ioctl: perform the IOCTL system call * do_setsid: perform the SETSID system call (FS side) */ #include "fs.h" #include #include #include #include #include "file.h" #include "fproc.h" #include "inode.h" #include "param.h" #include "super.h" #define ELEMENTS(a) (sizeof(a)/sizeof((a)[0])) extern int dmap_size; PRIVATE int dummyproc; /*===========================================================================* * dev_open * *===========================================================================*/ PUBLIC int dev_open(dev, proc, flags) dev_t dev; /* device to open */ int proc; /* process to open for */ int flags; /* mode bits and flags */ { int major, r; struct dmap *dp; /* Determine the major device number call the device class specific * open/close routine. (This is the only routine that must check the * device number for being in range. All others can trust this check.) */ major = (dev >> MAJOR) & BYTE; if (major >= NR_DEVICES) major = 0; dp = &dmap[major]; if (dp->dmap_driver == NONE) return ENXIO; r = (*dp->dmap_opcl)(DEV_OPEN, dev, proc, flags); if (r == SUSPEND) panic(__FILE__,"suspend on open from", dp->dmap_driver); return(r); } /*===========================================================================* * dev_close * *===========================================================================*/ PUBLIC void dev_close(dev) dev_t dev; /* device to close */ { /* See if driver is roughly valid. */ if (dmap[(dev >> MAJOR)].dmap_driver == NONE) { return; } (void) (*dmap[(dev >> MAJOR) & BYTE].dmap_opcl)(DEV_CLOSE, dev, 0, 0); } /*===========================================================================* * dev_status * *===========================================================================*/ PUBLIC void dev_status(message *m) { message st; int d, get_more = 1; for(d = 0; d < NR_DEVICES; d++) if (dmap[d].dmap_driver != NONE && dmap[d].dmap_driver == m->m_source) break; if (d >= NR_DEVICES) return; do { int r; st.m_type = DEV_STATUS; if ((r=sendrec(m->m_source, &st)) != OK) { printf("DEV_STATUS failed to %d: %d\n", m->m_source, r); if (r == EDEADSRCDST) return; if (r == EDSTDIED) return; if (r == ESRCDIED) return; panic(__FILE__,"couldn't sendrec for DEV_STATUS", r); } switch(st.m_type) { case DEV_REVIVE: revive(st.REP_ENDPT, st.REP_STATUS); break; case DEV_IO_READY: select_notified(d, st.DEV_MINOR, st.DEV_SEL_OPS); break; default: printf("FS: unrecognized reply %d to DEV_STATUS\n", st.m_type); /* Fall through. */ case DEV_NO_STATUS: get_more = 0; break; } } while(get_more); return; } /*===========================================================================* * dev_io * *===========================================================================*/ PUBLIC int dev_io(op, dev, proc_e, buf, pos, bytes, flags) int op; /* DEV_READ, DEV_WRITE, DEV_IOCTL, etc. */ dev_t dev; /* major-minor device number */ int proc_e; /* in whose address space is buf? */ void *buf; /* virtual address of the buffer */ off_t pos; /* byte position */ int bytes; /* how many bytes to transfer */ int flags; /* special flags, like O_NONBLOCK */ { /* Read or write from a device. The parameter 'dev' tells which one. */ struct dmap *dp; message dev_mess; /* Determine task dmap. */ dp = &dmap[(dev >> MAJOR) & BYTE]; /* See if driver is roughly valid. */ if (dp->dmap_driver == NONE) { printf("FS: dev_io: no driver for dev %x\n", dev); return ENXIO; } if(isokendpt(dp->dmap_driver, &dummyproc) != OK) { printf("FS: dev_io: old driver for dev %x (%d)\n", dev, dp->dmap_driver); return ENXIO; } /* Set up the message passed to task. */ dev_mess.m_type = op; dev_mess.DEVICE = (dev >> MINOR) & BYTE; dev_mess.POSITION = pos; dev_mess.IO_ENDPT = proc_e; dev_mess.ADDRESS = buf; dev_mess.COUNT = bytes; dev_mess.TTY_FLAGS = flags; /* Call the task. */ (*dp->dmap_io)(dp->dmap_driver, &dev_mess); if(dp->dmap_driver == NONE) { /* Driver has vanished. */ return EIO; } /* Task has completed. See if call completed. */ if (dev_mess.REP_STATUS == SUSPEND) { if (flags & O_NONBLOCK) { /* Not supposed to block. */ dev_mess.m_type = CANCEL; dev_mess.IO_ENDPT = proc_e; dev_mess.DEVICE = (dev >> MINOR) & BYTE; (*dp->dmap_io)(dp->dmap_driver, &dev_mess); if (dev_mess.REP_STATUS == EINTR) dev_mess.REP_STATUS = EAGAIN; } else { /* Suspend user. */ suspend(dp->dmap_driver); return(SUSPEND); } } return(dev_mess.REP_STATUS); } /*===========================================================================* * gen_opcl * *===========================================================================*/ PUBLIC int gen_opcl(op, dev, proc_e, flags) int op; /* operation, DEV_OPEN or DEV_CLOSE */ dev_t dev; /* device to open or close */ int proc_e; /* process to open/close for */ int flags; /* mode bits and flags */ { /* Called from the dmap struct in table.c on opens & closes of special files.*/ struct dmap *dp; message dev_mess; /* Determine task dmap. */ dp = &dmap[(dev >> MAJOR) & BYTE]; dev_mess.m_type = op; dev_mess.DEVICE = (dev >> MINOR) & BYTE; dev_mess.IO_ENDPT = proc_e; dev_mess.COUNT = flags; if (dp->dmap_driver == NONE) { printf("FS: gen_opcl: no driver for dev %x\n", dev); return ENXIO; } if(isokendpt(dp->dmap_driver, &dummyproc) != OK) { printf("FS: gen_opcl: old driver for dev %x (%d)\n", dev, dp->dmap_driver); return ENXIO; } /* Call the task. */ (*dp->dmap_io)(dp->dmap_driver, &dev_mess); return(dev_mess.REP_STATUS); } /*===========================================================================* * tty_opcl * *===========================================================================*/ PUBLIC int tty_opcl(op, dev, proc_e, flags) int op; /* operation, DEV_OPEN or DEV_CLOSE */ dev_t dev; /* device to open or close */ int proc_e; /* process to open/close for */ int flags; /* mode bits and flags */ { /* This procedure is called from the dmap struct on tty open/close. */ int r; register struct fproc *rfp; /* Add O_NOCTTY to the flags if this process is not a session leader, or * if it already has a controlling tty, or if it is someone elses * controlling tty. */ if (!fp->fp_sesldr || fp->fp_tty != 0) { flags |= O_NOCTTY; } else { for (rfp = &fproc[0]; rfp < &fproc[NR_PROCS]; rfp++) { if(rfp->fp_pid == PID_FREE) continue; if (rfp->fp_tty == dev) flags |= O_NOCTTY; } } r = gen_opcl(op, dev, proc_e, flags); /* Did this call make the tty the controlling tty? */ if (r == 1) { fp->fp_tty = dev; r = OK; } return(r); } /*===========================================================================* * ctty_opcl * *===========================================================================*/ PUBLIC int ctty_opcl(op, dev, proc_e, flags) int op; /* operation, DEV_OPEN or DEV_CLOSE */ dev_t dev; /* device to open or close */ int proc_e; /* process to open/close for */ int flags; /* mode bits and flags */ { /* This procedure is called from the dmap struct in table.c on opening/closing * /dev/tty, the magic device that translates to the controlling tty. */ return(fp->fp_tty == 0 ? ENXIO : OK); } /*===========================================================================* * do_setsid * *===========================================================================*/ PUBLIC int do_setsid() { /* Perform the FS side of the SETSID call, i.e. get rid of the controlling * terminal of a process, and make the process a session leader. */ register struct fproc *rfp; int slot; /* Only MM may do the SETSID call directly. */ if (who_e != PM_PROC_NR) return(ENOSYS); /* Make the process a session leader with no controlling tty. */ okendpt(m_in.endpt1, &slot); rfp = &fproc[slot]; rfp->fp_sesldr = TRUE; rfp->fp_tty = 0; return(OK); } /*===========================================================================* * do_ioctl * *===========================================================================*/ PUBLIC int do_ioctl() { /* Perform the ioctl(ls_fd, request, argx) system call (uses m2 fmt). */ struct filp *f; register struct inode *rip; dev_t dev; if ( (f = get_filp(m_in.ls_fd)) == NIL_FILP) return(err_code); rip = f->filp_ino; /* get inode pointer */ if ( (rip->i_mode & I_TYPE) != I_CHAR_SPECIAL && (rip->i_mode & I_TYPE) != I_BLOCK_SPECIAL) return(ENOTTY); dev = (dev_t) rip->i_zone[0]; #if ENABLE_BINCOMPAT if ((m_in.TTY_REQUEST >> 8) == 't') { /* Obsolete sgtty ioctl, message contains more than is sane. */ struct dmap *dp; message dev_mess; dp = &dmap[(dev >> MAJOR) & BYTE]; dev_mess = m; /* Copy full message with all the weird bits. */ dev_mess.m_type = DEV_IOCTL; dev_mess.PROC_NR = who_e; dev_mess.TTY_LINE = (dev >> MINOR) & BYTE; /* Call the task. */ if (dp->dmap_driver == NONE) { printf("FS: do_ioctl: no driver for dev %x\n", dev); return ENXIO; } if(isokendpt(dp->dmap_driver, &dummyproc) != OK) { printf("FS: do_ioctl: old driver for dev %x (%d)\n", dev, dp->dmap_driver); return ENXIO; } (*dp->dmap_io)(dp->dmap_driver, &dev_mess); m_out.TTY_SPEK = dev_mess.TTY_SPEK; /* erase and kill */ m_out.TTY_FLAGS = dev_mess.TTY_FLAGS; /* flags */ return(dev_mess.REP_STATUS); } #endif return(dev_io(DEV_IOCTL, dev, who_e, m_in.ADDRESS, 0L, m_in.REQUEST, f->filp_flags)); } /*===========================================================================* * gen_io * *===========================================================================*/ PUBLIC int gen_io(task_nr, mess_ptr) int task_nr; /* which task to call */ message *mess_ptr; /* pointer to message for task */ { /* All file system I/O ultimately comes down to I/O on major/minor device * pairs. These lead to calls on the following routines via the dmap table. */ int r, proc_e; proc_e = mess_ptr->IO_ENDPT; #if DEAD_CODE while ((r = sendrec(task_nr, mess_ptr)) == ELOCKED) { /* sendrec() failed to avoid deadlock. The task 'task_nr' is * trying to send a REVIVE message for an earlier request. * Handle it and go try again. */ if ((r = receive(task_nr, &local_m)) != OK) { break; } /* If we're trying to send a cancel message to a task which has just * sent a completion reply, ignore the reply and abort the cancel * request. The caller will do the revive for the process. */ if (mess_ptr->m_type == CANCEL && local_m.REP_ENDPT == proc_e) { return OK; } /* Otherwise it should be a REVIVE. */ if (local_m.m_type != REVIVE) { printf( "fs: strange device reply from %d, type = %d, proc = %d (1)\n", local_m.m_source, local_m.m_type, local_m.REP_ENDPT); continue; } revive(local_m.REP_ENDPT, local_m.REP_STATUS); } #endif /* The message received may be a reply to this call, or a REVIVE for some * other process. */ r = sendrec(task_nr, mess_ptr); for(;;) { if (r != OK) { if (r == EDEADSRCDST || r == EDSTDIED || r == ESRCDIED) { printf("fs: dead driver %d\n", task_nr); dmap_unmap_by_endpt(task_nr); return r; } if (r == ELOCKED) { printf("fs: ELOCKED talking to %d\n", task_nr); return r; } panic(__FILE__,"call_task: can't send/receive", r); } /* Did the process we did the sendrec() for get a result? */ if (mess_ptr->REP_ENDPT == proc_e) { break; } else if (mess_ptr->m_type == REVIVE) { /* Otherwise it should be a REVIVE. */ revive(mess_ptr->REP_ENDPT, mess_ptr->REP_STATUS); } else { printf( "fs: strange device reply from %d, type = %d, proc = %d (2) ignored\n", mess_ptr->m_source, mess_ptr->m_type, mess_ptr->REP_ENDPT); } r = receive(task_nr, mess_ptr); } return OK; } /*===========================================================================* * ctty_io * *===========================================================================*/ PUBLIC int ctty_io(task_nr, mess_ptr) int task_nr; /* not used - for compatibility with dmap_t */ message *mess_ptr; /* pointer to message for task */ { /* This routine is only called for one device, namely /dev/tty. Its job * is to change the message to use the controlling terminal, instead of the * major/minor pair for /dev/tty itself. */ struct dmap *dp; if (fp->fp_tty == 0) { /* No controlling tty present anymore, return an I/O error. */ mess_ptr->REP_STATUS = EIO; } else { /* Substitute the controlling terminal device. */ dp = &dmap[(fp->fp_tty >> MAJOR) & BYTE]; mess_ptr->DEVICE = (fp->fp_tty >> MINOR) & BYTE; if (dp->dmap_driver == NONE) { printf("FS: ctty_io: no driver for dev\n"); return EIO; } if(isokendpt(dp->dmap_driver, &dummyproc) != OK) { printf("FS: ctty_io: old driver %d\n", dp->dmap_driver); return EIO; } (*dp->dmap_io)(dp->dmap_driver, mess_ptr); } return OK; } /*===========================================================================* * no_dev * *===========================================================================*/ PUBLIC int no_dev(op, dev, proc, flags) int op; /* operation, DEV_OPEN or DEV_CLOSE */ dev_t dev; /* device to open or close */ int proc; /* process to open/close for */ int flags; /* mode bits and flags */ { /* Called when opening a nonexistent device. */ return(ENODEV); } /*===========================================================================* * no_dev_io * *===========================================================================*/ PUBLIC int no_dev_io(int proc, message *m) { /* Called when doing i/o on a nonexistent device. */ printf("FS: I/O on unmapped device number\n"); return EIO; } /*===========================================================================* * clone_opcl * *===========================================================================*/ PUBLIC int clone_opcl(op, dev, proc_e, flags) int op; /* operation, DEV_OPEN or DEV_CLOSE */ dev_t dev; /* device to open or close */ int proc_e; /* process to open/close for */ int flags; /* mode bits and flags */ { /* Some devices need special processing upon open. Such a device is "cloned", * i.e. on a succesful open it is replaced by a new device with a new unique * minor device number. This new device number identifies a new object (such * as a new network connection) that has been allocated within a task. */ struct dmap *dp; int r, minor; message dev_mess; /* Determine task dmap. */ dp = &dmap[(dev >> MAJOR) & BYTE]; minor = (dev >> MINOR) & BYTE; dev_mess.m_type = op; dev_mess.DEVICE = minor; dev_mess.IO_ENDPT = proc_e; dev_mess.COUNT = flags; if (dp->dmap_driver == NONE) { printf("FS: clone_opcl: no driver for dev %x\n", dev); return ENXIO; } if(isokendpt(dp->dmap_driver, &dummyproc) != OK) { printf("FS: clone_opcl: old driver for dev %x (%d)\n", dev, dp->dmap_driver); return ENXIO; } /* Call the task. */ r= (*dp->dmap_io)(dp->dmap_driver, &dev_mess); if (r != OK) return r; if (op == DEV_OPEN && dev_mess.REP_STATUS >= 0) { if (dev_mess.REP_STATUS != minor) { /* A new minor device number has been returned. Create a * temporary device file to hold it. */ struct inode *ip; /* Device number of the new device. */ dev = (dev & ~(BYTE << MINOR)) | (dev_mess.REP_STATUS << MINOR); ip = alloc_inode(root_dev, ALL_MODES | I_CHAR_SPECIAL); if (ip == NIL_INODE) { /* Oops, that didn't work. Undo open. */ (void) clone_opcl(DEV_CLOSE, dev, proc_e, 0); return(err_code); } ip->i_zone[0] = dev; put_inode(fp->fp_filp[m_in.fd]->filp_ino); fp->fp_filp[m_in.fd]->filp_ino = ip; } dev_mess.REP_STATUS = OK; } return(dev_mess.REP_STATUS); } /*===========================================================================* * dev_up * *===========================================================================*/ PUBLIC void dev_up(int maj) { /* A new device driver has been mapped in. This function * checks if any filesystems are mounted on it, and if so, * dev_open()s them so the filesystem can be reused. */ struct super_block *sb; struct filp *fp; int r; /* Open a device once for every filp that's opened on it, * and once for every filesystem mounted from it. */ for(sb = super_block; sb < &super_block[NR_SUPERS]; sb++) { int minor; if(sb->s_dev == NO_DEV) continue; if(((sb->s_dev >> MAJOR) & BYTE) != maj) continue; minor = ((sb->s_dev >> MINOR) & BYTE); printf("FS: remounting dev %d/%d\n", maj, minor); if((r = dev_open(sb->s_dev, FS_PROC_NR, sb->s_rd_only ? R_BIT : (R_BIT|W_BIT))) != OK) { printf("FS: mounted dev %d/%d re-open failed: %d.\n", maj, minor, r); } } for(fp = filp; fp < &filp[NR_FILPS]; fp++) { struct inode *in; int minor; if(fp->filp_count < 1 || !(in=fp->filp_ino)) continue; if(((in->i_zone[0] >> MAJOR) & BYTE) != maj) continue; if(!(in->i_mode & (I_BLOCK_SPECIAL|I_CHAR_SPECIAL))) continue; minor = ((in->i_zone[0] >> MINOR) & BYTE); printf("FS: reopening special %d/%d..\n", maj, minor); if((r = dev_open(in->i_zone[0], FS_PROC_NR, in->i_mode & (R_BIT|W_BIT))) != OK) { int n; /* This function will set the fp_filp[]s of processes * holding that fp to NULL, but _not_ clear * fp_filp_inuse, so that fd can't be recycled until * it's close()d. */ n = inval_filp(fp); if(n != fp->filp_count) printf("FS: warning: invalidate/count " "discrepancy (%d, %d)\n", n, fp->filp_count); fp->filp_count = 0; printf("FS: file on dev %d/%d re-open failed: %d; " "invalidated %d fd's.\n", maj, minor, r, n); } } return; }