minix/servers/fs/pipe.c
2005-04-29 15:36:43 +00:00

305 lines
10 KiB
C

/* This file deals with the suspension and revival of processes. A process can
* be suspended because it wants to read or write from a pipe and can't, or
* because it wants to read or write from a special file and can't. When a
* process can't continue it is suspended, and revived later when it is able
* to continue.
*
* The entry points into this file are
* do_pipe: perform the PIPE system call
* pipe_check: check to see that a read or write on a pipe is feasible now
* suspend: suspend a process that cannot do a requested read or write
* release: check to see if a suspended process can be released and do it
* revive: mark a suspended process as able to run again
* do_unpause: a signal has been sent to a process; see if it suspended
*/
#include "fs.h"
#include <fcntl.h>
#include <signal.h>
#include <minix/callnr.h>
#include <minix/com.h>
#include "dmap.h"
#include "file.h"
#include "fproc.h"
#include "inode.h"
#include "param.h"
#include "super.h"
/*===========================================================================*
* do_pipe *
*===========================================================================*/
PUBLIC int do_pipe()
{
/* Perform the pipe(fil_des) system call. */
register struct fproc *rfp;
register struct inode *rip;
int r;
struct filp *fil_ptr0, *fil_ptr1;
int fil_des[2]; /* reply goes here */
/* Acquire two file descriptors. */
rfp = fp;
if ( (r = get_fd(0, R_BIT, &fil_des[0], &fil_ptr0)) != OK) return(r);
rfp->fp_filp[fil_des[0]] = fil_ptr0;
fil_ptr0->filp_count = 1;
if ( (r = get_fd(0, W_BIT, &fil_des[1], &fil_ptr1)) != OK) {
rfp->fp_filp[fil_des[0]] = NIL_FILP;
fil_ptr0->filp_count = 0;
return(r);
}
rfp->fp_filp[fil_des[1]] = fil_ptr1;
fil_ptr1->filp_count = 1;
/* Make the inode on the pipe device. */
if ( (rip = alloc_inode(root_dev, I_REGULAR) ) == NIL_INODE) {
rfp->fp_filp[fil_des[0]] = NIL_FILP;
fil_ptr0->filp_count = 0;
rfp->fp_filp[fil_des[1]] = NIL_FILP;
fil_ptr1->filp_count = 0;
return(err_code);
}
if (read_only(rip) != OK) panic("pipe device is read only", NO_NUM);
rip->i_pipe = I_PIPE;
rip->i_mode &= ~I_REGULAR;
rip->i_mode |= I_NAMED_PIPE; /* pipes and FIFOs have this bit set */
fil_ptr0->filp_ino = rip;
fil_ptr0->filp_flags = O_RDONLY;
dup_inode(rip); /* for double usage */
fil_ptr1->filp_ino = rip;
fil_ptr1->filp_flags = O_WRONLY;
rw_inode(rip, WRITING); /* mark inode as allocated */
m_out.reply_i1 = fil_des[0];
m_out.reply_i2 = fil_des[1];
rip->i_update = ATIME | CTIME | MTIME;
return(OK);
}
/*===========================================================================*
* pipe_check *
*===========================================================================*/
PUBLIC int pipe_check(rip, rw_flag, oflags, bytes, position, canwrite)
register struct inode *rip; /* the inode of the pipe */
int rw_flag; /* READING or WRITING */
int oflags; /* flags set by open or fcntl */
register int bytes; /* bytes to be read or written (all chunks) */
register off_t position; /* current file position */
int *canwrite; /* return: number of bytes we can write */
{
/* Pipes are a little different. If a process reads from an empty pipe for
* which a writer still exists, suspend the reader. If the pipe is empty
* and there is no writer, return 0 bytes. If a process is writing to a
* pipe and no one is reading from it, give a broken pipe error.
*/
/* If reading, check for empty pipe. */
if (rw_flag == READING) {
if (position >= rip->i_size) {
/* Process is reading from an empty pipe. */
int r = 0;
if (find_filp(rip, W_BIT) != NIL_FILP) {
/* Writer exists */
if (oflags & O_NONBLOCK) {
r = EAGAIN;
} else {
suspend(XPIPE); /* block reader */
r = SUSPEND;
}
/* If need be, activate sleeping writers. */
if (susp_count > 0) release(rip, WRITE, susp_count);
}
return(r);
}
} else {
/* Process is writing to a pipe. */
if (find_filp(rip, R_BIT) == NIL_FILP) {
/* Tell kernel to generate a SIGPIPE signal. */
sys_kill((int)(fp - fproc), SIGPIPE);
return(EPIPE);
}
if (position + bytes > PIPE_SIZE(rip->i_sp->s_block_size)) {
if ((oflags & O_NONBLOCK) && bytes < PIPE_SIZE(rip->i_sp->s_block_size))
return(EAGAIN);
else if ((oflags & O_NONBLOCK) && bytes > PIPE_SIZE(rip->i_sp->s_block_size)) {
if ( (*canwrite = (PIPE_SIZE(rip->i_sp->s_block_size) - position)) > 0) {
/* Do a partial write. Need to wakeup reader */
release(rip, READ, susp_count);
return(1);
} else {
return(EAGAIN);
}
}
if (bytes > PIPE_SIZE(rip->i_sp->s_block_size)) {
if ((*canwrite = PIPE_SIZE(rip->i_sp->s_block_size) - position) > 0) {
/* Do a partial write. Need to wakeup reader
* since we'll suspend ourself in read_write()
*/
release(rip, READ, susp_count);
return(1);
}
}
suspend(XPIPE); /* stop writer -- pipe full */
return(SUSPEND);
}
/* Writing to an empty pipe. Search for suspended reader. */
if (position == 0) release(rip, READ, susp_count);
}
*canwrite = 0;
return(1);
}
/*===========================================================================*
* suspend *
*===========================================================================*/
PUBLIC void suspend(task)
int task; /* who is proc waiting for? (PIPE = pipe) */
{
/* Take measures to suspend the processing of the present system call.
* Store the parameters to be used upon resuming in the process table.
* (Actually they are not used when a process is waiting for an I/O device,
* but they are needed for pipes, and it is not worth making the distinction.)
* The SUSPEND pseudo error should be returned after calling suspend().
*/
if (task == XPIPE || task == XPOPEN) susp_count++;/* #procs susp'ed on pipe*/
fp->fp_suspended = SUSPENDED;
fp->fp_fd = m_in.fd << 8 | call_nr;
fp->fp_task = -task;
if (task == XLOCK) {
fp->fp_buffer = (char *) m_in.name1; /* third arg to fcntl() */
fp->fp_nbytes = m_in.request; /* second arg to fcntl() */
} else {
fp->fp_buffer = m_in.buffer; /* for reads and writes */
fp->fp_nbytes = m_in.nbytes;
}
}
/*===========================================================================*
* release *
*===========================================================================*/
PUBLIC void release(ip, call_nr, count)
register struct inode *ip; /* inode of pipe */
int call_nr; /* READ, WRITE, OPEN or CREAT */
int count; /* max number of processes to release */
{
/* Check to see if any process is hanging on the pipe whose inode is in 'ip'.
* If one is, and it was trying to perform the call indicated by 'call_nr',
* release it.
*/
register struct fproc *rp;
/* Search the proc table. */
for (rp = &fproc[0]; rp < &fproc[NR_PROCS]; rp++) {
if (rp->fp_suspended == SUSPENDED &&
rp->fp_revived == NOT_REVIVING &&
(rp->fp_fd & BYTE) == call_nr &&
rp->fp_filp[rp->fp_fd>>8]->filp_ino == ip) {
revive((int)(rp - fproc), 0);
susp_count--; /* keep track of who is suspended */
if (--count == 0) return;
}
}
}
/*===========================================================================*
* revive *
*===========================================================================*/
PUBLIC void revive(proc_nr, bytes)
int proc_nr; /* process to revive */
int bytes; /* if hanging on task, how many bytes read */
{
/* Revive a previously blocked process. When a process hangs on tty, this
* is the way it is eventually released.
*/
register struct fproc *rfp;
register int task;
if (proc_nr < 0 || proc_nr >= NR_PROCS) panic("revive err", proc_nr);
rfp = &fproc[proc_nr];
if (rfp->fp_suspended == NOT_SUSPENDED || rfp->fp_revived == REVIVING)return;
/* The 'reviving' flag only applies to pipes. Processes waiting for TTY get
* a message right away. The revival process is different for TTY and pipes.
* For TTY revival, the work is already done, for pipes it is not: the proc
* must be restarted so it can try again.
*/
task = -rfp->fp_task;
if (task == XPIPE || task == XLOCK) {
/* Revive a process suspended on a pipe or lock. */
rfp->fp_revived = REVIVING;
reviving++; /* process was waiting on pipe or lock */
} else {
rfp->fp_suspended = NOT_SUSPENDED;
if (task == XPOPEN) /* process blocked in open or create */
reply(proc_nr, rfp->fp_fd>>8);
else {
/* Revive a process suspended on TTY or other device. */
rfp->fp_nbytes = bytes; /*pretend it wants only what there is*/
reply(proc_nr, bytes); /* unblock the process */
}
}
}
/*===========================================================================*
* do_unpause *
*===========================================================================*/
PUBLIC int do_unpause()
{
/* A signal has been sent to a user who is paused on the file system.
* Abort the system call with the EINTR error message.
*/
register struct fproc *rfp;
int proc_nr, task, fild;
struct filp *f;
dev_t dev;
message mess;
if (who > PM_PROC_NR) return(EPERM);
proc_nr = m_in.pro;
if (proc_nr < 0 || proc_nr >= NR_PROCS) panic("unpause err 1", proc_nr);
rfp = &fproc[proc_nr];
if (rfp->fp_suspended == NOT_SUSPENDED) return(OK);
task = -rfp->fp_task;
switch (task) {
case XPIPE: /* process trying to read or write a pipe */
break;
case XLOCK: /* process trying to set a lock with FCNTL */
break;
case XPOPEN: /* process trying to open a fifo */
break;
default: /* process trying to do device I/O (e.g. tty)*/
fild = (rfp->fp_fd >> 8) & BYTE;/* extract file descriptor */
if (fild < 0 || fild >= OPEN_MAX)panic("unpause err 2",NO_NUM);
f = rfp->fp_filp[fild];
dev = (dev_t) f->filp_ino->i_zone[0]; /* device hung on */
mess.TTY_LINE = (dev >> MINOR) & BYTE;
mess.PROC_NR = proc_nr;
/* Tell kernel R or W. Mode is from current call, not open. */
mess.COUNT = (rfp->fp_fd & BYTE) == READ ? R_BIT : W_BIT;
mess.m_type = CANCEL;
fp = rfp; /* hack - ctty_io uses fp */
(*dmap[(dev >> MAJOR) & BYTE].dmap_io)(task, &mess);
}
rfp->fp_suspended = NOT_SUSPENDED;
reply(proc_nr, EINTR); /* signal interrupted call */
return(OK);
}