minix3/net/inet/sr.c

837 lines
17 KiB
C

/* this file contains the interface of the network software with the file
* system.
*
* Copyright 1995 Philip Homburg
*/
#include "inet.h"
#include "mq.h"
#include "qp.h"
#include "proto.h"
#include "generic/type.h"
#include "generic/assert.h"
#include "generic/buf.h"
#include "generic/event.h"
#include "generic/sr.h"
#include "sr_int.h"
THIS_FILE
sr_fd_t sr_fd_table[FD_NR];
static struct vscp_vec s_cp_req[SCPVEC_NR];
static int sr_open(devminor_t minor, int access, endpoint_t user_endpt);
static int sr_close(devminor_t minor);
static ssize_t sr_read(devminor_t minor, u64_t position, endpoint_t endpt,
cp_grant_id_t grant, size_t size, int flags, cdev_id_t id);
static ssize_t sr_write(devminor_t minor, u64_t position, endpoint_t endpt,
cp_grant_id_t grant, size_t size, int flags, cdev_id_t id);
static int sr_ioctl(devminor_t minor, unsigned long request, endpoint_t endpt,
cp_grant_id_t grant, int flags, endpoint_t user_endpt, cdev_id_t id);
static int sr_rwio(sr_req_t *req);
static int sr_restart_read(sr_fd_t *fdp);
static int sr_restart_write(sr_fd_t *fdp);
static int sr_restart_ioctl(sr_fd_t *fdp);
static int sr_cancel(devminor_t minor, endpoint_t endpt, cdev_id_t id);
static int sr_select(devminor_t minor, unsigned int ops, endpoint_t endpt);
static sr_fd_t *sr_getchannel(int minor);
static acc_t *sr_get_userdata(int fd, size_t offset, size_t count, int
for_ioctl);
static int sr_put_userdata(int fd, size_t offset, acc_t *data, int
for_ioctl);
static void sr_select_res(int fd, unsigned ops);
static int walk_queue(sr_fd_t *sr_fd, mq_t **q_head_ptr, mq_t **q_tail_ptr,
int type, endpoint_t endpt, cdev_id_t id, int first_flag);
static void sr_event(event_t *evp, ev_arg_t arg);
static int cp_u2b(endpoint_t proc, cp_grant_id_t gid, vir_bytes offset,
acc_t **var_acc_ptr, int size);
static int cp_b2u(acc_t *acc_ptr, endpoint_t proc, cp_grant_id_t gid,
vir_bytes offset);
static struct chardriver inet_tab = {
.cdr_open = sr_open,
.cdr_close = sr_close,
.cdr_read = sr_read,
.cdr_write = sr_write,
.cdr_ioctl = sr_ioctl,
.cdr_cancel = sr_cancel,
.cdr_select = sr_select
};
void sr_init()
{
int i;
for (i=0; i<FD_NR; i++)
{
sr_fd_table[i].srf_flags= SFF_FREE;
ev_init(&sr_fd_table[i].srf_ioctl_ev);
ev_init(&sr_fd_table[i].srf_read_ev);
ev_init(&sr_fd_table[i].srf_write_ev);
}
}
void sr_rec(message *m, int ipc_status)
{
chardriver_process(&inet_tab, m, ipc_status);
}
void sr_add_minor(minor, port, openf, closef, readf, writef,
ioctlf, cancelf, selectf)
int minor;
int port;
sr_open_t openf;
sr_close_t closef;
sr_read_t readf;
sr_write_t writef;
sr_ioctl_t ioctlf;
sr_cancel_t cancelf;
sr_select_t selectf;
{
sr_fd_t *sr_fd;
assert (minor>=0 && minor<FD_NR);
sr_fd= &sr_fd_table[minor];
assert(!(sr_fd->srf_flags & SFF_INUSE));
sr_fd->srf_flags= SFF_INUSE | SFF_MINOR;
sr_fd->srf_port= port;
sr_fd->srf_open= openf;
sr_fd->srf_close= closef;
sr_fd->srf_write= writef;
sr_fd->srf_read= readf;
sr_fd->srf_ioctl= ioctlf;
sr_fd->srf_cancel= cancelf;
sr_fd->srf_select= selectf;
}
static int sr_open(devminor_t minor, int UNUSED(access),
endpoint_t UNUSED(user_endpt))
{
sr_fd_t *sr_fd;
int i, fd;
if (minor<0 || minor>FD_NR)
{
DBLOCK(1, printf("replying EINVAL\n"));
return EINVAL;
}
if (!(sr_fd_table[minor].srf_flags & SFF_MINOR))
{
DBLOCK(1, printf("replying ENXIO\n"));
return ENXIO;
}
for (i=0; i<FD_NR && (sr_fd_table[i].srf_flags & SFF_INUSE); i++);
if (i>=FD_NR)
{
DBLOCK(1, printf("replying ENFILE\n"));
return ENFILE;
}
sr_fd= &sr_fd_table[i];
*sr_fd= sr_fd_table[minor];
sr_fd->srf_flags= SFF_INUSE;
fd= (*sr_fd->srf_open)(sr_fd->srf_port, i, sr_get_userdata,
sr_put_userdata, 0 /* no put_pkt */, sr_select_res);
if (fd<0)
{
sr_fd->srf_flags= SFF_FREE;
DBLOCK(1, printf("replying %d\n", fd));
return fd;
}
sr_fd->srf_fd= fd;
return CDEV_CLONED | i;
}
static int sr_close(devminor_t minor)
{
sr_fd_t *sr_fd;
sr_fd= sr_getchannel(minor);
assert (sr_fd);
if (sr_fd->srf_flags & SFF_BUSY)
ip_panic(("close on busy channel"));
assert (!(sr_fd->srf_flags & SFF_MINOR));
(*sr_fd->srf_close)(sr_fd->srf_fd);
sr_fd->srf_flags= SFF_FREE;
return OK;
}
static int sr_rwio(sr_req_t *req)
{
sr_fd_t *sr_fd;
mq_t *m, **q_head_ptr = NULL, **q_tail_ptr = NULL;
int ip_flag = 0, susp_flag = 0, first_flag = 0;
int r = OK;
ioreq_t request;
size_t size;
if (!(m = mq_get()))
ip_panic(("out of messages"));
m->mq_req = *req;
sr_fd= sr_getchannel(m->mq_req.srr_minor);
assert (sr_fd);
switch(m->mq_req.srr_type)
{
case SRR_READ:
q_head_ptr= &sr_fd->srf_read_q;
q_tail_ptr= &sr_fd->srf_read_q_tail;
ip_flag= SFF_READ_IP;
susp_flag= SFF_READ_SUSP;
first_flag= SFF_READ_FIRST;
break;
case SRR_WRITE:
q_head_ptr= &sr_fd->srf_write_q;
q_tail_ptr= &sr_fd->srf_write_q_tail;
ip_flag= SFF_WRITE_IP;
susp_flag= SFF_WRITE_SUSP;
first_flag= SFF_WRITE_FIRST;
break;
case SRR_IOCTL:
q_head_ptr= &sr_fd->srf_ioctl_q;
q_tail_ptr= &sr_fd->srf_ioctl_q_tail;
ip_flag= SFF_IOCTL_IP;
susp_flag= SFF_IOCTL_SUSP;
first_flag= SFF_IOCTL_FIRST;
break;
default:
ip_panic(("illegal request type"));
}
if (sr_fd->srf_flags & ip_flag)
{
assert(sr_fd->srf_flags & susp_flag);
assert(*q_head_ptr);
if (m->mq_req.srr_flags & CDEV_NONBLOCK) {
mq_free(m);
return EAGAIN;
}
(*q_tail_ptr)->mq_next= m;
*q_tail_ptr= m;
return EDONTREPLY;
}
assert(!*q_head_ptr);
*q_tail_ptr= *q_head_ptr= m;
sr_fd->srf_flags |= ip_flag;
assert(!(sr_fd->srf_flags & first_flag));
sr_fd->srf_flags |= first_flag;
switch(m->mq_req.srr_type)
{
case SRR_READ:
r= (*sr_fd->srf_read)(sr_fd->srf_fd, m->mq_req.srr_size);
break;
case SRR_WRITE:
r= (*sr_fd->srf_write)(sr_fd->srf_fd, m->mq_req.srr_size);
break;
case SRR_IOCTL:
request= m->mq_req.srr_req;
size= _MINIX_IOCTL_SIZE(request);
if (size>MAX_IOCTL_S)
{
DBLOCK(1, printf("replying EINVAL\n"));
r= sr_put_userdata(sr_fd-sr_fd_table, EINVAL,
NULL, 1);
assert(r == OK);
assert(sr_fd->srf_flags & first_flag);
sr_fd->srf_flags &= ~first_flag;
return EDONTREPLY;
}
r= (*sr_fd->srf_ioctl)(sr_fd->srf_fd, request);
break;
default:
ip_panic(("illegal case entry"));
}
assert(sr_fd->srf_flags & first_flag);
sr_fd->srf_flags &= ~first_flag;
assert(r == OK || r == SUSPEND ||
(printf("r= %d\n", r), 0));
if (r == SUSPEND) {
sr_fd->srf_flags |= susp_flag;
if (m->mq_req.srr_flags & CDEV_NONBLOCK) {
r= sr_cancel(m->mq_req.srr_minor, m->mq_req.srr_endpt,
m->mq_req.srr_id);
assert(r == EDONTREPLY); /* head of the queue */
}
} else
mq_free(m);
return EDONTREPLY; /* request already completed */
}
static ssize_t sr_read(devminor_t minor, u64_t UNUSED(position),
endpoint_t endpt, cp_grant_id_t grant, size_t size, int flags,
cdev_id_t id)
{
sr_req_t req;
req.srr_type = SRR_READ;
req.srr_minor = minor;
req.srr_endpt = endpt;
req.srr_grant = grant;
req.srr_size = size;
req.srr_flags = flags;
req.srr_id = id;
return sr_rwio(&req);
}
static ssize_t sr_write(devminor_t minor, u64_t UNUSED(position),
endpoint_t endpt, cp_grant_id_t grant, size_t size, int flags,
cdev_id_t id)
{
sr_req_t req;
req.srr_type = SRR_WRITE;
req.srr_minor = minor;
req.srr_endpt = endpt;
req.srr_grant = grant;
req.srr_size = size;
req.srr_flags = flags;
req.srr_id = id;
return sr_rwio(&req);
}
static int sr_ioctl(devminor_t minor, unsigned long request, endpoint_t endpt,
cp_grant_id_t grant, int flags, endpoint_t UNUSED(user_endpt),
cdev_id_t id)
{
sr_req_t req;
req.srr_type = SRR_IOCTL;
req.srr_minor = minor;
req.srr_req = request;
req.srr_endpt = endpt;
req.srr_grant = grant;
req.srr_flags = flags;
req.srr_id = id;
return sr_rwio(&req);
}
static int sr_restart_read(sr_fd)
sr_fd_t *sr_fd;
{
mq_t *mp;
int r;
mp= sr_fd->srf_read_q;
assert(mp);
if (sr_fd->srf_flags & SFF_READ_IP)
{
assert(sr_fd->srf_flags & SFF_READ_SUSP);
return SUSPEND;
}
sr_fd->srf_flags |= SFF_READ_IP;
r= (*sr_fd->srf_read)(sr_fd->srf_fd, mp->mq_req.srr_size);
assert(r == OK || r == SUSPEND ||
(printf("r= %d\n", r), 0));
if (r == SUSPEND)
sr_fd->srf_flags |= SFF_READ_SUSP;
return r;
}
static int sr_restart_write(sr_fd)
sr_fd_t *sr_fd;
{
mq_t *mp;
int r;
mp= sr_fd->srf_write_q;
assert(mp);
if (sr_fd->srf_flags & SFF_WRITE_IP)
{
assert(sr_fd->srf_flags & SFF_WRITE_SUSP);
return SUSPEND;
}
sr_fd->srf_flags |= SFF_WRITE_IP;
r= (*sr_fd->srf_write)(sr_fd->srf_fd, mp->mq_req.srr_size);
assert(r == OK || r == SUSPEND ||
(printf("r= %d\n", r), 0));
if (r == SUSPEND)
sr_fd->srf_flags |= SFF_WRITE_SUSP;
return r;
}
static int sr_restart_ioctl(sr_fd)
sr_fd_t *sr_fd;
{
mq_t *mp;
int r;
mp= sr_fd->srf_ioctl_q;
assert(mp);
if (sr_fd->srf_flags & SFF_IOCTL_IP)
{
assert(sr_fd->srf_flags & SFF_IOCTL_SUSP);
return SUSPEND;
}
sr_fd->srf_flags |= SFF_IOCTL_IP;
r= (*sr_fd->srf_ioctl)(sr_fd->srf_fd, mp->mq_req.srr_req);
assert(r == OK || r == SUSPEND ||
(printf("r= %d\n", r), 0));
if (r == SUSPEND)
sr_fd->srf_flags |= SFF_IOCTL_SUSP;
return r;
}
static int sr_cancel(devminor_t minor, endpoint_t endpt, cdev_id_t id)
{
sr_fd_t *sr_fd;
int result;
sr_fd= sr_getchannel(minor);
assert (sr_fd);
result= walk_queue(sr_fd, &sr_fd->srf_ioctl_q,
&sr_fd->srf_ioctl_q_tail, SR_CANCEL_IOCTL,
endpt, id, SFF_IOCTL_FIRST);
if (result != EAGAIN)
return (result == OK) ? EDONTREPLY : EINTR;
result= walk_queue(sr_fd, &sr_fd->srf_read_q,
&sr_fd->srf_read_q_tail, SR_CANCEL_READ,
endpt, id, SFF_READ_FIRST);
if (result != EAGAIN)
return (result == OK) ? EDONTREPLY : EINTR;
result= walk_queue(sr_fd, &sr_fd->srf_write_q,
&sr_fd->srf_write_q_tail, SR_CANCEL_WRITE,
endpt, id, SFF_WRITE_FIRST);
if (result != EAGAIN)
return (result == OK) ? EDONTREPLY : EINTR;
/* We already replied to the request, so don't reply to the CANCEL. */
return EDONTREPLY;
}
static int sr_select(devminor_t minor, unsigned int ops, endpoint_t endpt)
{
sr_fd_t *sr_fd;
int r, m_ops;
unsigned int i_ops;
sr_fd= sr_getchannel(minor);
assert (sr_fd);
sr_fd->srf_select_proc= endpt;
i_ops= 0;
if (ops & CDEV_OP_RD) i_ops |= SR_SELECT_READ;
if (ops & CDEV_OP_WR) i_ops |= SR_SELECT_WRITE;
if (ops & CDEV_OP_ERR) i_ops |= SR_SELECT_EXCEPTION;
if (!(ops & CDEV_NOTIFY)) i_ops |= SR_SELECT_POLL;
r= (*sr_fd->srf_select)(sr_fd->srf_fd, i_ops);
if (r < 0) {
m_ops= r;
} else {
m_ops= 0;
if (r & SR_SELECT_READ) m_ops |= CDEV_OP_RD;
if (r & SR_SELECT_WRITE) m_ops |= CDEV_OP_WR;
if (r & SR_SELECT_EXCEPTION) m_ops |= CDEV_OP_ERR;
}
return m_ops;
}
static int walk_queue(sr_fd, q_head_ptr, q_tail_ptr, type, endpt, id,
first_flag)
sr_fd_t *sr_fd;
mq_t **q_head_ptr;
mq_t **q_tail_ptr;
int type;
endpoint_t endpt;
cdev_id_t id;
int first_flag;
{
mq_t *q_ptr_prv, *q_ptr;
int result;
for(q_ptr_prv= NULL, q_ptr= *q_head_ptr; q_ptr;
q_ptr_prv= q_ptr, q_ptr= q_ptr->mq_next)
{
if (q_ptr->mq_req.srr_endpt != endpt)
continue;
if (q_ptr->mq_req.srr_id != id)
continue;
if (!q_ptr_prv)
{
assert(!(sr_fd->srf_flags & first_flag));
sr_fd->srf_flags |= first_flag;
/* This will also send a reply. */
result= (*sr_fd->srf_cancel)(sr_fd->srf_fd, type);
assert(result == OK);
*q_head_ptr= q_ptr->mq_next;
mq_free(q_ptr);
assert(sr_fd->srf_flags & first_flag);
sr_fd->srf_flags &= ~first_flag;
return OK;
}
q_ptr_prv->mq_next= q_ptr->mq_next;
mq_free(q_ptr);
if (!q_ptr_prv->mq_next)
*q_tail_ptr= q_ptr_prv;
return EINTR;
}
return EAGAIN;
}
static sr_fd_t *sr_getchannel(minor)
int minor;
{
sr_fd_t *loc_fd;
compare(minor, >=, 0);
compare(minor, <, FD_NR);
loc_fd= &sr_fd_table[minor];
assert (!(loc_fd->srf_flags & SFF_MINOR) &&
(loc_fd->srf_flags & SFF_INUSE));
return loc_fd;
}
static acc_t *sr_get_userdata (fd, offset, count, for_ioctl)
int fd;
size_t offset;
size_t count;
int for_ioctl;
{
sr_fd_t *loc_fd;
mq_t **head_ptr, *m, *mq;
int ip_flag, susp_flag, first_flag;
int result, suspended, is_revive;
acc_t *acc;
event_t *evp;
ev_arg_t arg;
loc_fd= &sr_fd_table[fd];
if (for_ioctl)
{
head_ptr= &loc_fd->srf_ioctl_q;
evp= &loc_fd->srf_ioctl_ev;
ip_flag= SFF_IOCTL_IP;
susp_flag= SFF_IOCTL_SUSP;
first_flag= SFF_IOCTL_FIRST;
}
else
{
head_ptr= &loc_fd->srf_write_q;
evp= &loc_fd->srf_write_ev;
ip_flag= SFF_WRITE_IP;
susp_flag= SFF_WRITE_SUSP;
first_flag= SFF_WRITE_FIRST;
}
assert (loc_fd->srf_flags & ip_flag);
if (!count)
{
m= *head_ptr;
mq= m->mq_next;
*head_ptr= mq;
result= (int)offset;
is_revive= !(loc_fd->srf_flags & first_flag);
chardriver_reply_task(m->mq_req.srr_endpt, m->mq_req.srr_id,
result);
if (is_revive)
mq_free(m);
suspended= (loc_fd->srf_flags & susp_flag);
loc_fd->srf_flags &= ~(ip_flag|susp_flag);
if (suspended)
{
if (mq)
{
arg.ev_ptr= loc_fd;
ev_enqueue(evp, sr_event, arg);
}
}
return NULL;
}
result= cp_u2b ((*head_ptr)->mq_req.srr_endpt,
(*head_ptr)->mq_req.srr_grant, offset, &acc, count);
return result<0 ? NULL : acc;
}
static int sr_put_userdata (fd, offset, data, for_ioctl)
int fd;
size_t offset;
acc_t *data;
int for_ioctl;
{
sr_fd_t *loc_fd;
mq_t **head_ptr, *m, *mq;
int ip_flag, susp_flag, first_flag;
int result, suspended, is_revive;
event_t *evp;
ev_arg_t arg;
loc_fd= &sr_fd_table[fd];
if (for_ioctl)
{
head_ptr= &loc_fd->srf_ioctl_q;
evp= &loc_fd->srf_ioctl_ev;
ip_flag= SFF_IOCTL_IP;
susp_flag= SFF_IOCTL_SUSP;
first_flag= SFF_IOCTL_FIRST;
}
else
{
head_ptr= &loc_fd->srf_read_q;
evp= &loc_fd->srf_read_ev;
ip_flag= SFF_READ_IP;
susp_flag= SFF_READ_SUSP;
first_flag= SFF_READ_FIRST;
}
assert (loc_fd->srf_flags & ip_flag);
if (!data)
{
m= *head_ptr;
mq= m->mq_next;
*head_ptr= mq;
result= (int)offset;
is_revive= !(loc_fd->srf_flags & first_flag);
chardriver_reply_task(m->mq_req.srr_endpt, m->mq_req.srr_id,
result);
if (is_revive)
mq_free(m);
suspended= (loc_fd->srf_flags & susp_flag);
loc_fd->srf_flags &= ~(ip_flag|susp_flag);
if (suspended)
{
if (mq)
{
arg.ev_ptr= loc_fd;
ev_enqueue(evp, sr_event, arg);
}
}
return OK;
}
return cp_b2u (data, (*head_ptr)->mq_req.srr_endpt,
(*head_ptr)->mq_req.srr_grant, offset);
}
static void sr_select_res(int fd, unsigned ops)
{
sr_fd_t *sr_fd;
unsigned int m_ops;
sr_fd= &sr_fd_table[fd];
m_ops= 0;
if (ops & SR_SELECT_READ) m_ops |= CDEV_OP_RD;
if (ops & SR_SELECT_WRITE) m_ops |= CDEV_OP_WR;
if (ops & SR_SELECT_EXCEPTION) m_ops |= CDEV_OP_ERR;
chardriver_reply_select(sr_fd->srf_select_proc, fd, m_ops);
}
static void sr_event(evp, arg)
event_t *evp;
ev_arg_t arg;
{
sr_fd_t *sr_fd;
int r;
sr_fd= arg.ev_ptr;
if (evp == &sr_fd->srf_write_ev)
{
while(sr_fd->srf_write_q)
{
r= sr_restart_write(sr_fd);
if (r == SUSPEND)
return;
}
return;
}
if (evp == &sr_fd->srf_read_ev)
{
while(sr_fd->srf_read_q)
{
r= sr_restart_read(sr_fd);
if (r == SUSPEND)
return;
}
return;
}
if (evp == &sr_fd->srf_ioctl_ev)
{
while(sr_fd->srf_ioctl_q)
{
r= sr_restart_ioctl(sr_fd);
if (r == SUSPEND)
return;
}
return;
}
ip_panic(("sr_event: unknown event\n"));
}
static int cp_u2b(proc, gid, offset, var_acc_ptr, size)
endpoint_t proc;
cp_grant_id_t gid;
vir_bytes offset;
acc_t **var_acc_ptr;
int size;
{
acc_t *acc;
int i, r;
acc= bf_memreq(size);
*var_acc_ptr= acc;
i=0;
while (acc)
{
size= (vir_bytes)acc->acc_length;
s_cp_req[i].v_from= proc;
s_cp_req[i].v_to= SELF;
s_cp_req[i].v_gid= gid;
s_cp_req[i].v_offset= offset;
s_cp_req[i].v_addr= (vir_bytes) ptr2acc_data(acc);
s_cp_req[i].v_bytes= size;
offset += size;
acc= acc->acc_next;
i++;
if (acc == NULL && i == 1)
{
r= sys_safecopyfrom(s_cp_req[0].v_from,
s_cp_req[0].v_gid, s_cp_req[0].v_offset,
s_cp_req[0].v_addr, s_cp_req[0].v_bytes);
if (r <0)
{
printf("sys_safecopyfrom failed: %d\n", r);
bf_afree(*var_acc_ptr);
*var_acc_ptr= 0;
return r;
}
i= 0;
continue;
}
if (i == SCPVEC_NR || acc == NULL)
{
r= sys_vsafecopy(s_cp_req, i);
if (r <0)
{
printf("cp_u2b: sys_vsafecopy failed: %d\n",
r);
bf_afree(*var_acc_ptr);
*var_acc_ptr= 0;
return r;
}
i= 0;
}
}
return OK;
}
static int cp_b2u(acc_ptr, proc, gid, offset)
acc_t *acc_ptr;
endpoint_t proc;
cp_grant_id_t gid;
vir_bytes offset;
{
acc_t *acc;
int i, r, size;
acc= acc_ptr;
i=0;
while (acc)
{
size= (vir_bytes)acc->acc_length;
if (size)
{
s_cp_req[i].v_from= SELF;
s_cp_req[i].v_to= proc;
s_cp_req[i].v_gid= gid;
s_cp_req[i].v_offset= offset;
s_cp_req[i].v_addr= (vir_bytes) ptr2acc_data(acc);
s_cp_req[i].v_bytes= size;
i++;
}
offset += size;
acc= acc->acc_next;
if (acc == NULL && i == 1)
{
r= sys_safecopyto(s_cp_req[0].v_to,
s_cp_req[0].v_gid, s_cp_req[0].v_offset,
s_cp_req[0].v_addr, s_cp_req[0].v_bytes);
if (r <0)
{
printf("sys_safecopyto failed: %d\n", r);
bf_afree(acc_ptr);
return r;
}
i= 0;
continue;
}
if (i == SCPVEC_NR || acc == NULL)
{
r= sys_vsafecopy(s_cp_req, i);
if (r <0)
{
printf("cp_b2u: sys_vsafecopy failed: %d\n",
r);
bf_afree(acc_ptr);
return r;
}
i= 0;
}
}
bf_afree(acc_ptr);
return OK;
}
/*
* $PchId: sr.c,v 1.17 2005/06/28 14:26:16 philip Exp $
*/