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nexedi
linux
Commits
d4d9c3ac
Commit
d4d9c3ac
authored
Jul 30, 2002
by
David S. Miller
Browse files
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Browse Files
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Plain Diff
OpenPROM: Kill len check, it is pointless.
parent
aa2a3d64
Changes
11
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Showing
11 changed files
with
0 additions
and
3832 deletions
+0
-3832
drivers/sbus/char/openprom.c
drivers/sbus/char/openprom.c
+0
-3
drivers/sbus/char/sunserial.c
drivers/sbus/char/sunserial.c
+0
-457
drivers/sbus/char/sunserial.h
drivers/sbus/char/sunserial.h
+0
-53
drivers/sbus/char/zs.c
drivers/sbus/char/zs.c
+0
-2892
drivers/sbus/char/zs.h
drivers/sbus/char/zs.h
+0
-427
drivers/serial/sunkbd.c
drivers/serial/sunkbd.c
+0
-0
drivers/serial/sunkbd.h
drivers/serial/sunkbd.h
+0
-0
drivers/serial/sunmouse.c
drivers/serial/sunmouse.c
+0
-0
drivers/serial/sunmouse.h
drivers/serial/sunmouse.h
+0
-0
drivers/serial/sunsab.c
drivers/serial/sunsab.c
+0
-0
drivers/serial/sunsu.c
drivers/serial/sunsu.c
+0
-0
No files found.
drivers/sbus/char/openprom.c
View file @
d4d9c3ac
...
@@ -334,9 +334,6 @@ static int copyin_string(char *user, size_t len, char **ptr)
...
@@ -334,9 +334,6 @@ static int copyin_string(char *user, size_t len, char **ptr)
{
{
char
*
tmp
;
char
*
tmp
;
if
(
len
<
0
||
len
+
1
<
0
)
return
-
EINVAL
;
tmp
=
kmalloc
(
len
+
1
,
GFP_KERNEL
);
tmp
=
kmalloc
(
len
+
1
,
GFP_KERNEL
);
if
(
!
tmp
)
if
(
!
tmp
)
return
-
ENOMEM
;
return
-
ENOMEM
;
...
...
drivers/sbus/char/sunserial.c
deleted
100644 → 0
View file @
aa2a3d64
/* $Id: sunserial.c,v 1.81 2002/01/05 01:13:43 davem Exp $
* serial.c: Serial port driver infrastructure for the Sparc.
*
* Copyright (C) 1997 Eddie C. Dost (ecd@skynet.be)
*/
#include <linux/config.h>
#include <linux/kernel.h>
#include <linux/sched.h>
#include <linux/module.h>
#include <linux/errno.h>
#include <linux/tty.h>
#include <linux/serial.h>
#include <linux/serialP.h>
#include <linux/string.h>
#include <linux/kbd_diacr.h>
#include <linux/version.h>
#include <linux/init.h>
#include <linux/bootmem.h>
#include <asm/oplib.h>
#include "sunserial.h"
int
serial_console
;
int
stop_a_enabled
=
1
;
int
__init
con_is_present
(
void
)
{
return
serial_console
?
0
:
1
;
}
static
void
__init
nop_rs_kgdb_hook
(
int
channel
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
}
static
void
nop_rs_change_mouse_baud
(
int
baud
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
}
static
int
nop_rs_read_proc
(
char
*
page
,
char
**
start
,
off_t
off
,
int
count
,
int
*
eof
,
void
*
data
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
return
0
;
}
struct
sunserial_operations
rs_ops
=
{
0
,
nop_rs_kgdb_hook
,
nop_rs_change_mouse_baud
,
nop_rs_read_proc
};
void
rs_init
(
void
)
{
static
int
invoked
=
0
;
if
(
!
invoked
)
{
struct
initfunc
*
init
;
invoked
=
1
;
init
=
rs_ops
.
rs_init
;
while
(
init
)
{
(
void
)
init
->
init
();
init
=
init
->
next
;
}
}
}
void
__init
rs_kgdb_hook
(
int
channel
)
{
rs_ops
.
rs_kgdb_hook
(
channel
);
}
void
__init
serial_console_init
(
void
)
{
return
;
}
void
rs_change_mouse_baud
(
int
baud
)
{
rs_ops
.
rs_change_mouse_baud
(
baud
);
}
int
rs_read_proc
(
char
*
page
,
char
**
start
,
off_t
off
,
int
count
,
int
*
eof
,
void
*
data
)
{
return
rs_ops
.
rs_read_proc
(
page
,
start
,
off
,
count
,
eof
,
data
);
}
int
register_serial
(
struct
serial_struct
*
req
)
{
return
-
1
;
}
void
unregister_serial
(
int
line
)
{
}
static
void
nop_compute_shiftstate
(
void
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
}
static
void
nop_setledstate
(
struct
kbd_struct
*
kbd
,
unsigned
int
ledstate
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
}
static
unsigned
char
nop_getledstate
(
void
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
return
0
;
}
static
int
nop_setkeycode
(
unsigned
int
scancode
,
unsigned
int
keycode
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
return
-
EINVAL
;
}
static
int
nop_getkeycode
(
unsigned
int
scancode
)
{
printk
(
"Oops: %s called
\n
"
,
__FUNCTION__
);
return
-
EINVAL
;
}
struct
sunkbd_operations
kbd_ops
=
{
0
,
nop_compute_shiftstate
,
nop_setledstate
,
nop_getledstate
,
nop_setkeycode
,
nop_getkeycode
};
#ifdef CONFIG_USB
extern
void
pci_compute_shiftstate
(
void
);
extern
int
pci_setkeycode
(
unsigned
int
,
unsigned
int
);
extern
int
pci_getkeycode
(
unsigned
int
);
extern
void
pci_setledstate
(
struct
kbd_struct
*
,
unsigned
int
);
extern
unsigned
char
pci_getledstate
(
void
);
extern
int
pcikbd_init
(
void
);
#endif
int
kbd_init
(
void
)
{
struct
initfunc
*
init
;
int
err
=
-
ENODEV
;
init
=
kbd_ops
.
kbd_init
;
while
(
init
)
{
err
=
init
->
init
();
init
=
init
->
next
;
}
#ifdef CONFIG_USB
if
(
!
serial_console
&&
kbd_ops
.
compute_shiftstate
==
nop_compute_shiftstate
)
{
printk
(
"kbd_init: Assuming USB keyboard.
\n
"
);
kbd_ops
.
compute_shiftstate
=
pci_compute_shiftstate
;
kbd_ops
.
setledstate
=
pci_setledstate
;
kbd_ops
.
getledstate
=
pci_getledstate
;
kbd_ops
.
setkeycode
=
pci_setkeycode
;
kbd_ops
.
getkeycode
=
pci_getkeycode
;
pcikbd_init
();
}
#endif
return
err
;
}
void
compute_shiftstate
(
void
)
{
kbd_ops
.
compute_shiftstate
();
}
void
setledstate
(
struct
kbd_struct
*
kbd
,
unsigned
int
ledstate
)
{
kbd_ops
.
setledstate
(
kbd
,
ledstate
);
}
unsigned
char
getledstate
(
void
)
{
return
kbd_ops
.
getledstate
();
}
int
setkeycode
(
unsigned
int
scancode
,
unsigned
int
keycode
)
{
return
kbd_ops
.
setkeycode
(
scancode
,
keycode
);
}
int
getkeycode
(
unsigned
int
scancode
)
{
return
kbd_ops
.
getkeycode
(
scancode
);
}
void
*
__init
sunserial_alloc_bootmem
(
unsigned
long
size
)
{
void
*
ret
;
ret
=
__alloc_bootmem
(
size
,
SMP_CACHE_BYTES
,
0UL
);
if
(
ret
!=
NULL
)
memset
(
ret
,
0
,
size
);
return
ret
;
}
void
sunserial_setinitfunc
(
int
(
*
init
)
(
void
))
{
struct
initfunc
*
rs_init
;
rs_init
=
sunserial_alloc_bootmem
(
sizeof
(
struct
initfunc
));
if
(
rs_init
==
NULL
)
{
prom_printf
(
"sunserial_setinitfunc: Cannot alloc initfunc.
\n
"
);
prom_halt
();
}
rs_init
->
init
=
init
;
rs_init
->
next
=
rs_ops
.
rs_init
;
rs_ops
.
rs_init
=
rs_init
;
}
void
sunserial_console_termios
(
struct
console
*
con
)
{
char
mode
[
16
],
buf
[
16
],
*
s
;
char
*
mode_prop
=
"ttyX-mode"
;
char
*
cd_prop
=
"ttyX-ignore-cd"
;
char
*
dtr_prop
=
"ttyX-rts-dtr-off"
;
int
baud
,
bits
,
stop
,
cflag
;
char
parity
;
int
carrier
=
0
;
int
rtsdtr
=
1
;
int
topnd
,
nd
;
if
(
!
serial_console
)
return
;
if
(
serial_console
==
1
)
{
mode_prop
[
3
]
=
'a'
;
cd_prop
[
3
]
=
'a'
;
dtr_prop
[
3
]
=
'a'
;
}
else
{
mode_prop
[
3
]
=
'b'
;
cd_prop
[
3
]
=
'b'
;
dtr_prop
[
3
]
=
'b'
;
}
topnd
=
prom_getchild
(
prom_root_node
);
nd
=
prom_searchsiblings
(
topnd
,
"options"
);
if
(
!
nd
)
{
strcpy
(
mode
,
"9600,8,n,1,-"
);
goto
no_options
;
}
if
(
!
prom_node_has_property
(
nd
,
mode_prop
))
{
strcpy
(
mode
,
"9600,8,n,1,-"
);
goto
no_options
;
}
memset
(
mode
,
0
,
sizeof
(
mode
));
prom_getstring
(
nd
,
mode_prop
,
mode
,
sizeof
(
mode
));
if
(
prom_node_has_property
(
nd
,
cd_prop
))
{
memset
(
buf
,
0
,
sizeof
(
buf
));
prom_getstring
(
nd
,
cd_prop
,
buf
,
sizeof
(
buf
));
if
(
!
strcmp
(
buf
,
"false"
))
carrier
=
1
;
/* XXX: this is unused below. */
}
if
(
prom_node_has_property
(
nd
,
cd_prop
))
{
memset
(
buf
,
0
,
sizeof
(
buf
));
prom_getstring
(
nd
,
cd_prop
,
buf
,
sizeof
(
buf
));
if
(
!
strcmp
(
buf
,
"false"
))
rtsdtr
=
0
;
/* XXX: this is unused below. */
}
no_options:
cflag
=
CREAD
|
HUPCL
|
CLOCAL
;
s
=
mode
;
baud
=
simple_strtoul
(
s
,
0
,
0
);
s
=
strchr
(
s
,
','
);
bits
=
simple_strtoul
(
++
s
,
0
,
0
);
s
=
strchr
(
s
,
','
);
parity
=
*
(
++
s
);
s
=
strchr
(
s
,
','
);
stop
=
simple_strtoul
(
++
s
,
0
,
0
);
s
=
strchr
(
s
,
','
);
/* XXX handshake is not handled here. */
switch
(
baud
)
{
case
150
:
cflag
|=
B150
;
break
;
case
300
:
cflag
|=
B300
;
break
;
case
600
:
cflag
|=
B600
;
break
;
case
1200
:
cflag
|=
B1200
;
break
;
case
2400
:
cflag
|=
B2400
;
break
;
case
4800
:
cflag
|=
B4800
;
break
;
case
9600
:
cflag
|=
B9600
;
break
;
case
19200
:
cflag
|=
B19200
;
break
;
case
38400
:
cflag
|=
B38400
;
break
;
default:
baud
=
9600
;
cflag
|=
B9600
;
break
;
}
switch
(
bits
)
{
case
5
:
cflag
|=
CS5
;
break
;
case
6
:
cflag
|=
CS6
;
break
;
case
7
:
cflag
|=
CS7
;
break
;
case
8
:
cflag
|=
CS8
;
break
;
default:
cflag
|=
CS8
;
break
;
}
switch
(
parity
)
{
case
'o'
:
cflag
|=
(
PARENB
|
PARODD
);
break
;
case
'e'
:
cflag
|=
PARENB
;
break
;
case
'n'
:
default
:
break
;
}
switch
(
stop
)
{
case
2
:
cflag
|=
CSTOPB
;
break
;
case
1
:
default
:
break
;
}
con
->
cflag
=
cflag
;
}
void
sunkbd_setinitfunc
(
int
(
*
init
)
(
void
))
{
struct
initfunc
*
kbd_init
;
kbd_init
=
sunserial_alloc_bootmem
(
sizeof
(
struct
initfunc
));
if
(
kbd_init
==
NULL
)
{
prom_printf
(
"sunkbd_setinitfunc: Cannot alloc initfunc.
\n
"
);
prom_halt
();
}
kbd_init
->
init
=
init
;
kbd_init
->
next
=
kbd_ops
.
kbd_init
;
kbd_ops
.
kbd_init
=
kbd_init
;
}
#ifdef CONFIG_PCI
void
sunkbd_install_keymaps
(
ushort
**
src_key_maps
,
unsigned
int
src_keymap_count
,
char
*
src_func_buf
,
char
**
src_func_table
,
int
src_funcbufsize
,
int
src_funcbufleft
,
struct
kbdiacr
*
src_accent_table
,
unsigned
int
src_accent_table_size
)
{
extern
unsigned
int
keymap_count
;
int
i
,
j
;
for
(
i
=
0
;
i
<
MAX_NR_KEYMAPS
;
i
++
)
{
if
(
src_key_maps
[
i
])
{
if
(
!
key_maps
[
i
])
{
key_maps
[
i
]
=
(
ushort
*
)
sunserial_alloc_bootmem
(
NR_KEYS
*
sizeof
(
ushort
));
if
(
key_maps
[
i
]
==
NULL
)
{
prom_printf
(
"sunkbd_install_keymaps: "
"Cannot alloc key_map(%d).
\n
"
,
i
);
prom_halt
();
}
}
for
(
j
=
0
;
j
<
NR_KEYS
;
j
++
)
key_maps
[
i
][
j
]
=
src_key_maps
[
i
][
j
];
}
key_maps
[
i
]
=
src_key_maps
[
i
];
}
keymap_count
=
src_keymap_count
;
for
(
i
=
0
;
i
<
MAX_NR_FUNC
;
i
++
)
func_table
[
i
]
=
src_func_table
[
i
];
funcbufptr
=
src_func_buf
;
funcbufsize
=
src_funcbufsize
;
funcbufleft
=
src_funcbufleft
;
for
(
i
=
0
;
i
<
MAX_DIACR
;
i
++
)
accent_table
[
i
]
=
src_accent_table
[
i
];
accent_table_size
=
src_accent_table_size
;
}
#endif
extern
int
su_probe
(
void
);
extern
int
zs_probe
(
void
);
#ifdef CONFIG_SAB82532
extern
int
sab82532_probe
(
void
);
#endif
#ifdef CONFIG_PCI
extern
int
ps2kbd_probe
(
void
);
#endif
void
__init
sun_serial_setup
(
void
)
{
int
ret
=
1
;
#if defined(CONFIG_PCI) && !defined(__sparc_v9__)
/*
* Probing sequence on sparc differs from sparc64.
* Keyboard is probed ahead of su because we want su function
* when keyboard is active. su is probed ahead of zs in order to
* get console on MrCoffee with fine but disconnected zs.
*/
if
(
!
serial_console
)
ps2kbd_probe
();
if
(
su_probe
()
==
0
)
return
;
#endif
if
(
zs_probe
()
==
0
)
return
;
#ifdef CONFIG_SAB82532
ret
=
sab82532_probe
();
#endif
#if defined(CONFIG_PCI) && defined(__sparc_v9__)
/*
* Keyboard serial devices.
*
* Well done, Sun, prom_devopen("/pci@1f,4000/ebus@1/su@14,3083f8")
* hangs the machine if no keyboard is connected to the device...
* All PCI PROMs seem to do this, I have seen this on the Ultra 450
* with version 3.5 PROM, and on the Ultra/AX with 3.1.5 PROM.
*
* So be very careful not to probe for keyboards if we are on a
* serial console.
*/
if
(
!
serial_console
)
ps2kbd_probe
();
if
(
su_probe
()
==
0
)
return
;
#endif
if
(
!
ret
)
return
;
#ifdef __sparc_v9__
{
extern
int
this_is_starfire
;
/* Hello, Starfire. Pleased to meet you :) */
if
(
this_is_starfire
!=
0
)
return
;
}
#endif
prom_printf
(
"No serial devices found, bailing out.
\n
"
);
prom_halt
();
}
drivers/sbus/char/sunserial.h
deleted
100644 → 0
View file @
aa2a3d64
/* $Id: sunserial.h,v 1.19 1999/12/01 10:45:59 davem Exp $
* sunserial.h: SUN serial driver infrastructure (including keyboards).
*
* Copyright (C) 1997 Eddie C. Dost (ecd@skynet.be)
*/
#ifndef _SPARC_SUNSERIAL_H
#define _SPARC_SUNSERIAL_H 1
#include <linux/config.h>
#include <linux/tty.h>
#include <linux/kd.h>
#include <linux/kbd_kern.h>
#include <linux/console.h>
struct
initfunc
{
int
(
*
init
)
(
void
);
struct
initfunc
*
next
;
};
struct
sunserial_operations
{
struct
initfunc
*
rs_init
;
void
(
*
rs_kgdb_hook
)
(
int
);
void
(
*
rs_change_mouse_baud
)
(
int
);
int
(
*
rs_read_proc
)
(
char
*
,
char
**
,
off_t
,
int
,
int
*
,
void
*
);
};
struct
sunkbd_operations
{
struct
initfunc
*
kbd_init
;
void
(
*
compute_shiftstate
)
(
void
);
void
(
*
setledstate
)
(
struct
kbd_struct
*
,
unsigned
int
);
unsigned
char
(
*
getledstate
)
(
void
);
int
(
*
setkeycode
)
(
unsigned
int
,
unsigned
int
);
int
(
*
getkeycode
)
(
unsigned
int
);
};
extern
struct
sunserial_operations
rs_ops
;
extern
struct
sunkbd_operations
kbd_ops
;
extern
void
sunserial_setinitfunc
(
int
(
*
)
(
void
));
extern
void
sunkbd_setinitfunc
(
int
(
*
)
(
void
));
extern
int
serial_console
;
extern
int
stop_a_enabled
;
extern
void
sunserial_console_termios
(
struct
console
*
);
#ifdef CONFIG_PCI
extern
void
sunkbd_install_keymaps
(
ushort
**
,
unsigned
int
,
char
*
,
char
**
,
int
,
int
,
struct
kbdiacr
*
,
unsigned
int
);
#endif
#endif
/* !(_SPARC_SUNSERIAL_H) */
drivers/sbus/char/zs.c
deleted
100644 → 0
View file @
aa2a3d64
/* $Id: zs.c,v 1.71 2002/01/12 07:04:54 davem Exp $
* zs.c: Zilog serial port driver for the Sparc.
*
* Copyright (C) 1995 David S. Miller (davem@caip.rutgers.edu)
* Copyright (C) 1996 Eddie C. Dost (ecd@skynet.be)
* Fixes by Pete A. Zaitcev <zaitcev@yahoo.com>.
*
* Fixed to use tty_get_baud_rate().
* Theodore Ts'o <tytso@mit.edu>, 2001-Oct-12
*
* /proc/tty/driver/serial now exists and is readable.
* Alex Buell <alex.buell@tahallah.demon.co.uk>, 2001-12-23
*
*/
#include <linux/errno.h>
#include <linux/signal.h>
#include <linux/sched.h>
#include <linux/timer.h>
#include <linux/interrupt.h>
#include <linux/tty.h>
#include <linux/tty_flip.h>
#include <linux/config.h>
#include <linux/major.h>
#include <linux/string.h>
#include <linux/fcntl.h>
#include <linux/mm.h>
#include <linux/kernel.h>
#include <linux/keyboard.h>
#include <linux/console.h>
#include <linux/delay.h>
#include <linux/init.h>
#include <linux/bootmem.h>
#include <linux/sysrq.h>
#include <asm/io.h>
#include <asm/irq.h>
#include <asm/oplib.h>
#include <asm/system.h>
#include <asm/uaccess.h>
#include <asm/bitops.h>
#include <asm/kdebug.h>
#include <asm/page.h>
#include <asm/pgtable.h>
#include <asm/sbus.h>
#ifdef __sparc_v9__
#include <asm/fhc.h>
#endif
#ifdef CONFIG_PCI
#include <linux/pci.h>
#endif
#include "sunserial.h"
#include "zs.h"
#include "sunkbd.h"
#include "sunmouse.h"
static
int
num_serial
=
2
;
/* sun4/sun4c/sun4m - Two chips on board. */
#define NUM_SERIAL num_serial
#define NUM_CHANNELS (NUM_SERIAL * 2)
#define KEYBOARD_LINE 0x2
#define MOUSE_LINE 0x3
/* On 32-bit sparcs we need to delay after register accesses
* to accomodate sun4 systems, but we do not need to flush writes.
* On 64-bit sparc we only need to flush single writes to ensure
* completion.
*/
#ifndef __sparc_v9__
#define ZSDELAY() udelay(5)
#define ZSDELAY_LONG() udelay(20)
#define ZS_WSYNC(channel) do { } while(0)
#else
#define ZSDELAY()
#define ZSDELAY_LONG()
#define ZS_WSYNC(__channel) \
sbus_readb(&((__channel)->control))
#endif
struct
sun_zslayout
**
zs_chips
;
struct
sun_zschannel
**
zs_channels
;
struct
sun_zschannel
*
zs_mousechan
;
struct
sun_zschannel
*
zs_kbdchan
;
struct
sun_zschannel
*
zs_kgdbchan
;
int
*
zs_nodes
;
struct
sun_serial
*
zs_soft
;
struct
sun_serial
*
zs_chain
;
/* IRQ servicing chain */
int
zilog_irq
;
struct
tty_struct
*
zs_ttys
;
/* Console hooks... */
#ifdef CONFIG_SERIAL_CONSOLE
static
struct
console
zs_console
;
static
int
zs_console_init
(
void
);
/*
* Define this to get the zs_fair_output() functionality.
*/
#undef SERIAL_CONSOLE_FAIR_OUTPUT
#endif
/* CONFIG_SERIAL_CONSOLE */
static
unsigned
char
kgdb_regs
[
16
]
=
{
0
,
0
,
0
,
/* write 0, 1, 2 */
(
Rx8
|
RxENAB
),
/* write 3 */
(
X16CLK
|
SB1
|
PAR_EVEN
),
/* write 4 */
(
DTR
|
Tx8
|
TxENAB
),
/* write 5 */
0
,
0
,
0
,
/* write 6, 7, 8 */
(
NV
),
/* write 9 */
(
NRZ
),
/* write 10 */
(
TCBR
|
RCBR
),
/* write 11 */
0
,
0
,
/* BRG time constant, write 12 + 13 */
(
BRSRC
|
BRENAB
),
/* write 14 */
(
DCDIE
)
/* write 15 */
};
static
unsigned
char
zscons_regs
[
16
]
=
{
0
,
/* write 0 */
(
EXT_INT_ENAB
|
INT_ALL_Rx
),
/* write 1 */
0
,
/* write 2 */
(
Rx8
|
RxENAB
),
/* write 3 */
(
X16CLK
),
/* write 4 */
(
DTR
|
Tx8
|
TxENAB
),
/* write 5 */
0
,
0
,
0
,
/* write 6, 7, 8 */
(
NV
|
MIE
),
/* write 9 */
(
NRZ
),
/* write 10 */
(
TCBR
|
RCBR
),
/* write 11 */
0
,
0
,
/* BRG time constant, write 12 + 13 */
(
BRSRC
|
BRENAB
),
/* write 14 */
(
DCDIE
|
CTSIE
|
TxUIE
|
BRKIE
)
/* write 15 */
};
#define ZS_CLOCK 4915200
/* Zilog input clock rate */
DECLARE_TASK_QUEUE
(
tq_serial
);
static
struct
tty_driver
serial_driver
,
callout_driver
;
static
int
serial_refcount
;
/* serial subtype definitions */
#define SERIAL_TYPE_NORMAL 1
#define SERIAL_TYPE_CALLOUT 2
/* number of characters left in xmit buffer before we ask for more */
#define WAKEUP_CHARS 256
#define SERIAL_DO_RESTART
/* Debugging... DEBUG_INTR is bad to use when one of the zs
* lines is your console ;(
*/
#undef SERIAL_DEBUG_INTR
#undef SERIAL_DEBUG_OPEN
#undef SERIAL_DEBUG_FLOW
#define RS_STROBE_TIME 10
#define RS_ISR_PASS_LIMIT 256
#define _INLINE_ inline
int
zs_init
(
void
);
static
void
zs_kgdb_hook
(
int
);
static
void
change_speed
(
struct
sun_serial
*
info
);
static
struct
tty_struct
**
serial_table
;
static
struct
termios
**
serial_termios
;
static
struct
termios
**
serial_termios_locked
;
#ifndef MIN
#define MIN(a,b) ((a) < (b) ? (a) : (b))
#endif
#undef ZS_LOG
#ifdef ZS_LOG
struct
zs_logent
{
u8
reg
,
val
;
u8
write
,
__pad
;
#define REGIRQ 0xff
#define REGDATA 0xfe
#define REGCTRL 0xfd
};
struct
zs_logent
zslog
[
32
];
int
zs_curlog
;
#define ZSLOG(__reg, __val, __write) \
do{ int index = zs_curlog; \
zslog[index].reg = (__reg); \
zslog[index].val = (__val); \
zslog[index].write = (__write); \
zs_curlog = (index + 1) & (32 - 1); \
}while(0)
int
zs_dumplog
(
char
*
buffer
)
{
int
len
=
0
;
int
i
;
for
(
i
=
0
;
i
<
32
;
i
++
)
{
u8
reg
,
val
,
write
;
reg
=
zslog
[
i
].
reg
;
val
=
zslog
[
i
].
val
;
write
=
zslog
[
i
].
write
;
len
+=
sprintf
(
buffer
+
len
,
"ZSLOG[%2d]: reg %2x val %2x %s
\n
"
,
i
,
reg
,
val
,
write
?
"write"
:
"read"
);
}
len
+=
sprintf
(
buffer
+
len
,
"ZS current log index %d
\n
"
,
zs_curlog
);
return
len
;
}
#else
#define ZSLOG(x,y,z) do { } while (0)
#endif
/*
* tmp_buf is used as a temporary buffer by serial_write. We need to
* lock it in case the memcpy_fromfs blocks while swapping in a page,
* and some other program tries to do a serial write at the same time.
* Since the lock will only come under contention when the system is
* swapping and available memory is low, it makes sense to share one
* buffer across all the serial ports, since it significantly saves
* memory if large numbers of serial ports are open.
*/
static
unsigned
char
*
tmp_buf
=
0
;
static
DECLARE_MUTEX
(
tmp_buf_sem
);
static
inline
int
serial_paranoia_check
(
struct
sun_serial
*
info
,
kdev_t
device
,
const
char
*
routine
)
{
#ifdef SERIAL_PARANOIA_CHECK
static
const
char
*
badmagic
=
"Warning: bad magic number for serial struct (%d, %d) in %s
\n
"
;
static
const
char
*
badinfo
=
"Warning: null sun_serial for (%d, %d) in %s
\n
"
;
if
(
!
info
)
{
printk
(
badinfo
,
major
(
device
),
minor
(
device
),
routine
);
return
1
;
}
if
(
info
->
magic
!=
SERIAL_MAGIC
)
{
printk
(
badmagic
,
major
(
device
),
minor
(
device
),
routine
);
return
1
;
}
#endif
return
0
;
}
/* Reading and writing Zilog8530 registers. The delays are to make this
* driver work on the Sun4 which needs a settling delay after each chip
* register access, other machines handle this in hardware via auxiliary
* flip-flops which implement the settle time we do in software.
*/
static
unsigned
char
read_zsreg
(
struct
sun_zschannel
*
channel
,
unsigned
char
reg
)
{
unsigned
char
retval
;
sbus_writeb
(
reg
,
&
channel
->
control
);
ZSDELAY
();
retval
=
sbus_readb
(
&
channel
->
control
);
ZSDELAY
();
ZSLOG
(
reg
,
retval
,
0
);
return
retval
;
}
static
void
write_zsreg
(
struct
sun_zschannel
*
channel
,
unsigned
char
reg
,
unsigned
char
value
)
{
ZSLOG
(
reg
,
value
,
1
);
sbus_writeb
(
reg
,
&
channel
->
control
);
ZSDELAY
();
sbus_writeb
(
value
,
&
channel
->
control
);
ZSDELAY
();
}
static
void
load_zsregs
(
struct
sun_serial
*
info
,
unsigned
char
*
regs
)
{
struct
sun_zschannel
*
channel
=
info
->
zs_channel
;
unsigned
long
flags
;
unsigned
char
stat
;
int
i
;
for
(
i
=
0
;
i
<
1000
;
i
++
)
{
stat
=
read_zsreg
(
channel
,
R1
);
if
(
stat
&
ALL_SNT
)
break
;
udelay
(
100
);
}
write_zsreg
(
channel
,
R3
,
0
);
ZS_CLEARSTAT
(
channel
);
ZS_CLEARERR
(
channel
);
ZS_CLEARFIFO
(
channel
);
/* Load 'em up */
save_flags
(
flags
);
cli
();
if
(
info
->
channelA
)
write_zsreg
(
channel
,
R9
,
CHRA
);
else
write_zsreg
(
channel
,
R9
,
CHRB
);
ZSDELAY_LONG
();
write_zsreg
(
channel
,
R4
,
regs
[
R4
]);
write_zsreg
(
channel
,
R3
,
regs
[
R3
]
&
~
RxENAB
);
write_zsreg
(
channel
,
R5
,
regs
[
R5
]
&
~
TxENAB
);
write_zsreg
(
channel
,
R9
,
regs
[
R9
]
&
~
MIE
);
write_zsreg
(
channel
,
R10
,
regs
[
R10
]);
write_zsreg
(
channel
,
R11
,
regs
[
R11
]);
write_zsreg
(
channel
,
R12
,
regs
[
R12
]);
write_zsreg
(
channel
,
R13
,
regs
[
R13
]);
write_zsreg
(
channel
,
R14
,
regs
[
R14
]
&
~
BRENAB
);
write_zsreg
(
channel
,
R14
,
regs
[
R14
]);
write_zsreg
(
channel
,
R14
,
(
regs
[
R14
]
&
~
SNRZI
)
|
BRENAB
);
write_zsreg
(
channel
,
R3
,
regs
[
R3
]);
write_zsreg
(
channel
,
R5
,
regs
[
R5
]);
write_zsreg
(
channel
,
R15
,
regs
[
R15
]);
write_zsreg
(
channel
,
R0
,
RES_EXT_INT
);
write_zsreg
(
channel
,
R0
,
ERR_RES
);
write_zsreg
(
channel
,
R1
,
regs
[
R1
]);
write_zsreg
(
channel
,
R9
,
regs
[
R9
]);
restore_flags
(
flags
);
}
#define ZS_PUT_CHAR_MAX_DELAY 2000
/* 10 ms */
static
void
zs_put_char
(
struct
sun_zschannel
*
channel
,
char
ch
)
{
int
loops
=
ZS_PUT_CHAR_MAX_DELAY
;
/* Do not change this to use ZSDELAY as this is
* a timed polling loop and on sparc64 ZSDELAY
* is a nop. -DaveM
*/
do
{
u8
val
=
sbus_readb
(
&
channel
->
control
);
ZSLOG
(
REGCTRL
,
val
,
0
);
if
(
val
&
Tx_BUF_EMP
)
break
;
udelay
(
5
);
}
while
(
--
loops
);
sbus_writeb
(
ch
,
&
channel
->
data
);
ZSDELAY
();
ZS_WSYNC
(
channel
);
ZSLOG
(
REGDATA
,
ch
,
1
);
}
/* Sets or clears DTR/RTS on the requested line */
static
void
zs_rtsdtr
(
struct
sun_serial
*
ss
,
int
set
)
{
unsigned
long
flags
;
save_flags
(
flags
);
cli
();
if
(
set
)
{
ss
->
curregs
[
5
]
|=
(
RTS
|
DTR
);
write_zsreg
(
ss
->
zs_channel
,
5
,
ss
->
curregs
[
5
]);
}
else
{
ss
->
curregs
[
5
]
&=
~
(
RTS
|
DTR
);
write_zsreg
(
ss
->
zs_channel
,
5
,
ss
->
curregs
[
5
]);
}
restore_flags
(
flags
);
return
;
}
static
void
kgdb_chaninit
(
struct
sun_serial
*
ss
,
int
intson
,
int
bps
)
{
int
brg
;
if
(
intson
)
{
kgdb_regs
[
R1
]
=
INT_ALL_Rx
;
kgdb_regs
[
R9
]
|=
MIE
;
}
else
{
kgdb_regs
[
R1
]
=
0
;
kgdb_regs
[
R9
]
&=
~
MIE
;
}
brg
=
BPS_TO_BRG
(
bps
,
ZS_CLOCK
/
16
);
kgdb_regs
[
R12
]
=
(
brg
&
255
);
kgdb_regs
[
R13
]
=
((
brg
>>
8
)
&
255
);
load_zsregs
(
ss
,
kgdb_regs
);
}
/*
* ------------------------------------------------------------
* zs_stop() and zs_start()
*
* This routines are called before setting or resetting tty->stopped.
* They enable or disable transmitter interrupts, as necessary.
* ------------------------------------------------------------
*/
static
void
zs_stop
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
unsigned
long
flags
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_stop"
))
return
;
save_flags
(
flags
);
cli
();
if
(
info
->
curregs
[
5
]
&
TxENAB
)
{
info
->
curregs
[
5
]
&=
~
TxENAB
;
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
}
restore_flags
(
flags
);
}
static
void
zs_start
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
unsigned
long
flags
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_start"
))
return
;
save_flags
(
flags
);
cli
();
if
(
info
->
xmit_cnt
&&
info
->
xmit_buf
&&
!
(
info
->
curregs
[
5
]
&
TxENAB
))
{
info
->
curregs
[
5
]
|=
TxENAB
;
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
}
restore_flags
(
flags
);
}
/* Drop into either the boot monitor or kadb upon receiving a break
* from keyboard/console input.
*/
void
batten_down_hatches
(
void
)
{
if
(
!
stop_a_enabled
)
return
;
/* If we are doing kadb, we call the debugger
* else we just drop into the boot monitor.
* Note that we must flush the user windows
* first before giving up control.
*/
printk
(
"
\n
"
);
flush_user_windows
();
#ifndef __sparc_v9__
if
((((
unsigned
long
)
linux_dbvec
)
>=
DEBUG_FIRSTVADDR
)
&&
(((
unsigned
long
)
linux_dbvec
)
<=
DEBUG_LASTVADDR
))
sp_enter_debugger
();
else
#endif
prom_cmdline
();
/* XXX We want to notify the keyboard driver that all
* XXX keys are in the up state or else weird things
* XXX happen...
*/
return
;
}
/*
* ----------------------------------------------------------------------
*
* Here starts the interrupt handling routines. All of the following
* subroutines are declared as inline and are folded into
* zs_interrupt(). They were separated out for readability's sake.
*
* Note: zs_interrupt() is a "fast" interrupt, which means that it
* runs with interrupts turned off. People who may want to modify
* zs_interrupt() should try to keep the interrupt handler as fast as
* possible. After you are done making modifications, it is not a bad
* idea to do:
*
* gcc -S -DKERNEL -Wall -Wstrict-prototypes -O6 -fomit-frame-pointer serial.c
*
* and look at the resulting assemble code in serial.s.
*
* - Ted Ts'o (tytso@mit.edu), 7-Mar-93
* -----------------------------------------------------------------------
*/
/*
* This routine is used by the interrupt handler to schedule
* processing in the software interrupt portion of the driver.
*/
static
void
zs_sched_event
(
struct
sun_serial
*
info
,
int
event
)
{
info
->
event
|=
1
<<
event
;
queue_task
(
&
info
->
tqueue
,
&
tq_serial
);
mark_bh
(
SERIAL_BH
);
}
#ifndef __sparc_v9__
extern
void
breakpoint
(
void
);
/* For the KGDB frame character */
#endif
static
void
receive_chars
(
struct
sun_serial
*
info
,
struct
pt_regs
*
regs
)
{
struct
tty_struct
*
tty
=
info
->
tty
;
int
do_queue_task
=
0
;
while
(
1
)
{
unsigned
char
ch
,
r1
;
r1
=
read_zsreg
(
info
->
zs_channel
,
R1
);
if
(
r1
&
(
PAR_ERR
|
Rx_OVR
|
CRC_ERR
))
{
sbus_writeb
(
ERR_RES
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
ERR_RES
,
1
);
}
ch
=
sbus_readb
(
&
info
->
zs_channel
->
data
);
ZSLOG
(
REGDATA
,
ch
,
0
);
ch
&=
info
->
parity_mask
;
ZSDELAY
();
/* If this is the console keyboard, we need to handle
* L1-A's here.
*/
if
(
info
->
cons_keyb
)
{
if
(
ch
==
SUNKBD_RESET
)
{
l1a_state
.
kbd_id
=
1
;
l1a_state
.
l1_down
=
0
;
}
else
if
(
l1a_state
.
kbd_id
)
{
l1a_state
.
kbd_id
=
0
;
}
else
if
(
ch
==
SUNKBD_L1
)
{
l1a_state
.
l1_down
=
1
;
}
else
if
(
ch
==
(
SUNKBD_L1
|
SUNKBD_UP
))
{
l1a_state
.
l1_down
=
0
;
}
else
if
(
ch
==
SUNKBD_A
&&
l1a_state
.
l1_down
)
{
/* whee... */
batten_down_hatches
();
/* Continue execution... */
l1a_state
.
l1_down
=
0
;
l1a_state
.
kbd_id
=
0
;
return
;
}
sunkbd_inchar
(
ch
,
regs
);
goto
next_char
;
}
if
(
info
->
cons_mouse
)
{
sun_mouse_inbyte
(
ch
,
0
);
goto
next_char
;
}
if
(
info
->
is_cons
)
{
if
(
ch
==
0
)
{
/* whee, break received */
batten_down_hatches
();
/* Continue execution... */
return
;
}
}
#ifndef __sparc_v9__
/* Look for kgdb 'stop' character, consult the gdb
* documentation for remote target debugging and
* arch/sparc/kernel/sparc-stub.c to see how all this works.
*/
if
(
info
->
kgdb_channel
&&
(
ch
==
'\003'
))
{
breakpoint
();
return
;
}
#endif
if
(
!
tty
)
return
;
do_queue_task
++
;
if
(
tty
->
flip
.
count
>=
TTY_FLIPBUF_SIZE
)
break
;
tty
->
flip
.
count
++
;
if
(
r1
&
PAR_ERR
)
*
tty
->
flip
.
flag_buf_ptr
++
=
TTY_PARITY
;
else
if
(
r1
&
Rx_OVR
)
*
tty
->
flip
.
flag_buf_ptr
++
=
TTY_OVERRUN
;
else
if
(
r1
&
CRC_ERR
)
*
tty
->
flip
.
flag_buf_ptr
++
=
TTY_FRAME
;
else
*
tty
->
flip
.
flag_buf_ptr
++
=
0
;
*
tty
->
flip
.
char_buf_ptr
++
=
ch
;
next_char:
{
unsigned
char
stat
;
/* Check if we have another character... */
stat
=
sbus_readb
(
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZSLOG
(
REGCTRL
,
stat
,
0
);
if
(
!
(
stat
&
Rx_CH_AV
))
break
;
}
}
if
(
do_queue_task
!=
0
)
queue_task
(
&
tty
->
flip
.
tqueue
,
&
tq_timer
);
}
static
void
transmit_chars
(
struct
sun_serial
*
info
)
{
struct
tty_struct
*
tty
=
info
->
tty
;
if
(
info
->
x_char
)
{
/* Send next char */
zs_put_char
(
info
->
zs_channel
,
info
->
x_char
);
info
->
x_char
=
0
;
return
;
}
if
((
info
->
xmit_cnt
<=
0
)
||
(
tty
!=
0
&&
tty
->
stopped
))
{
/* That's peculiar... */
sbus_writeb
(
RES_Tx_P
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
RES_Tx_P
,
1
);
return
;
}
/* Send char */
zs_put_char
(
info
->
zs_channel
,
info
->
xmit_buf
[
info
->
xmit_tail
++
]);
info
->
xmit_tail
=
info
->
xmit_tail
&
(
SERIAL_XMIT_SIZE
-
1
);
info
->
xmit_cnt
--
;
if
(
info
->
xmit_cnt
<
WAKEUP_CHARS
)
zs_sched_event
(
info
,
RS_EVENT_WRITE_WAKEUP
);
if
(
info
->
xmit_cnt
<=
0
)
{
sbus_writeb
(
RES_Tx_P
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
RES_Tx_P
,
1
);
}
}
static
void
status_handle
(
struct
sun_serial
*
info
)
{
unsigned
char
status
;
/* Get status from Read Register 0 */
status
=
sbus_readb
(
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZSLOG
(
REGCTRL
,
status
,
0
);
/* Clear status condition... */
sbus_writeb
(
RES_EXT_INT
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
RES_EXT_INT
,
1
);
#if 0
if (status & DCD) {
if ((info->tty->termios->c_cflag & CRTSCTS) &&
((info->curregs[3] & AUTO_ENAB)==0)) {
info->curregs[3] |= AUTO_ENAB;
write_zsreg(info->zs_channel, 3, info->curregs[3]);
}
} else {
if ((info->curregs[3] & AUTO_ENAB)) {
info->curregs[3] &= ~AUTO_ENAB;
write_zsreg(info->zs_channel, 3, info->curregs[3]);
}
}
#endif
/* Whee, if this is console input and this is a
* 'break asserted' status change interrupt, call
* the boot prom.
*/
if
(
status
&
BRK_ABRT
)
{
if
(
info
->
break_abort
)
batten_down_hatches
();
if
(
info
->
cons_mouse
)
sun_mouse_inbyte
(
0
,
1
);
}
/* XXX Whee, put in a buffer somewhere, the status information
* XXX whee whee whee... Where does the information go...
*/
return
;
}
/*
* This is the serial driver's generic interrupt routine
*/
void
zs_interrupt
(
int
irq
,
void
*
dev_id
,
struct
pt_regs
*
regs
)
{
struct
sun_serial
*
info
;
int
i
;
info
=
(
struct
sun_serial
*
)
dev_id
;
ZSLOG
(
REGIRQ
,
0
,
0
);
for
(
i
=
0
;
i
<
NUM_SERIAL
;
i
++
)
{
unsigned
char
r3
=
read_zsreg
(
info
->
zs_channel
,
3
);
/* Channel A -- /dev/ttya or /dev/kbd, could be the console */
if
(
r3
&
(
CHAEXT
|
CHATxIP
|
CHARxIP
))
{
sbus_writeb
(
RES_H_IUS
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
RES_H_IUS
,
1
);
if
(
r3
&
CHARxIP
)
receive_chars
(
info
,
regs
);
if
(
r3
&
CHAEXT
)
status_handle
(
info
);
if
(
r3
&
CHATxIP
)
transmit_chars
(
info
);
}
/* Channel B -- /dev/ttyb or /dev/mouse, could be the console */
info
=
info
->
zs_next
;
if
(
r3
&
(
CHBEXT
|
CHBTxIP
|
CHBRxIP
))
{
sbus_writeb
(
RES_H_IUS
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
RES_H_IUS
,
1
);
if
(
r3
&
CHBRxIP
)
receive_chars
(
info
,
regs
);
if
(
r3
&
CHBEXT
)
status_handle
(
info
);
if
(
r3
&
CHBTxIP
)
transmit_chars
(
info
);
}
info
=
info
->
zs_next
;
}
}
/*
* -------------------------------------------------------------------
* Here ends the serial interrupt routines.
* -------------------------------------------------------------------
*/
/*
* This routine is used to handle the "bottom half" processing for the
* serial driver, known also the "software interrupt" processing.
* This processing is done at the kernel interrupt level, after the
* zs_interrupt() has returned, BUT WITH INTERRUPTS TURNED ON. This
* is where time-consuming activities which can not be done in the
* interrupt driver proper are done; the interrupt driver schedules
* them using zs_sched_event(), and they get done here.
*/
static
void
do_serial_bh
(
void
)
{
run_task_queue
(
&
tq_serial
);
}
static
void
do_softint
(
void
*
private_
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
private_
;
struct
tty_struct
*
tty
;
tty
=
info
->
tty
;
if
(
!
tty
)
return
;
if
(
test_and_clear_bit
(
RS_EVENT_WRITE_WAKEUP
,
&
info
->
event
))
{
if
((
tty
->
flags
&
(
1
<<
TTY_DO_WRITE_WAKEUP
))
&&
tty
->
ldisc
.
write_wakeup
)
(
tty
->
ldisc
.
write_wakeup
)(
tty
);
wake_up_interruptible
(
&
tty
->
write_wait
);
}
}
/*
* This routine is called from the scheduler tqueue when the interrupt
* routine has signalled that a hangup has occurred. The path of
* hangup processing is:
*
* serial interrupt routine -> (scheduler tqueue) ->
* do_serial_hangup() -> tty->hangup() -> zs_hangup()
*
*/
static
void
do_serial_hangup
(
void
*
private_
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
private_
;
struct
tty_struct
*
tty
;
tty
=
info
->
tty
;
if
(
!
tty
)
return
;
#ifdef SERIAL_DEBUG_OPEN
printk
(
"do_serial_hangup<%p: tty-%d
\n
"
,
__builtin_return_address
(
0
),
info
->
line
);
#endif
tty_hangup
(
tty
);
}
static
int
startup
(
struct
sun_serial
*
info
)
{
unsigned
long
flags
;
if
(
info
->
flags
&
ZILOG_INITIALIZED
)
return
0
;
if
(
!
info
->
xmit_buf
)
{
info
->
xmit_buf
=
(
unsigned
char
*
)
get_free_page
(
GFP_KERNEL
);
if
(
!
info
->
xmit_buf
)
return
-
ENOMEM
;
}
save_flags
(
flags
);
cli
();
#ifdef SERIAL_DEBUG_OPEN
printk
(
"Starting up tty-%d (irq %d)...
\n
"
,
info
->
line
,
info
->
irq
);
#endif
/*
* Clear the FIFO buffers and disable them
* (they will be reenabled in change_speed())
*/
ZS_CLEARFIFO
(
info
->
zs_channel
);
info
->
xmit_fifo_size
=
1
;
/*
* Clear the interrupt registers.
*/
sbus_writeb
(
ERR_RES
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
ERR_RES
,
1
);
sbus_writeb
(
RES_H_IUS
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
RES_H_IUS
,
1
);
/*
* Now, initialize the Zilog
*/
zs_rtsdtr
(
info
,
1
);
/*
* Finally, enable sequencing and interrupts
*/
info
->
curregs
[
1
]
|=
(
info
->
curregs
[
1
]
&
~
(
RxINT_MASK
))
|
(
EXT_INT_ENAB
|
INT_ALL_Rx
);
info
->
curregs
[
3
]
|=
(
RxENAB
|
Rx8
);
/* We enable Tx interrupts as needed. */
info
->
curregs
[
5
]
|=
(
TxENAB
|
Tx8
);
info
->
curregs
[
9
]
|=
(
NV
|
MIE
);
write_zsreg
(
info
->
zs_channel
,
3
,
info
->
curregs
[
3
]);
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
write_zsreg
(
info
->
zs_channel
,
9
,
info
->
curregs
[
9
]);
/*
* And clear the interrupt registers again for luck.
*/
sbus_writeb
(
ERR_RES
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
ERR_RES
,
1
);
sbus_writeb
(
RES_H_IUS
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZS_WSYNC
(
info
->
zs_channel
);
ZSLOG
(
REGCTRL
,
RES_H_IUS
,
1
);
if
(
info
->
tty
)
clear_bit
(
TTY_IO_ERROR
,
&
info
->
tty
->
flags
);
info
->
xmit_cnt
=
info
->
xmit_head
=
info
->
xmit_tail
=
0
;
/*
* and set the speed of the serial port
*/
change_speed
(
info
);
info
->
flags
|=
ZILOG_INITIALIZED
;
restore_flags
(
flags
);
return
0
;
}
/*
* This routine will shutdown a serial port; interrupts are disabled, and
* DTR is dropped if the hangup on close termio flag is on.
*/
static
void
shutdown
(
struct
sun_serial
*
info
)
{
unsigned
long
flags
;
if
(
!
(
info
->
flags
&
ZILOG_INITIALIZED
))
return
;
#ifdef SERIAL_DEBUG_OPEN
printk
(
"Shutting down serial port %d (irq %d)...."
,
info
->
line
,
info
->
irq
);
#endif
save_flags
(
flags
);
cli
();
/* Disable interrupts */
if
(
info
->
xmit_buf
)
{
free_page
((
unsigned
long
)
info
->
xmit_buf
);
info
->
xmit_buf
=
0
;
}
if
(
info
->
tty
)
set_bit
(
TTY_IO_ERROR
,
&
info
->
tty
->
flags
);
info
->
flags
&=
~
ZILOG_INITIALIZED
;
restore_flags
(
flags
);
}
/*
* This routine is called to set the UART divisor registers to match
* the specified baud rate for a serial port.
*/
static
void
change_speed
(
struct
sun_serial
*
info
)
{
unsigned
cflag
;
int
baud
,
quot
=
0
;
int
brg
;
if
(
!
info
->
tty
||
!
info
->
tty
->
termios
)
return
;
cflag
=
info
->
tty
->
termios
->
c_cflag
;
if
(
!
info
->
port
)
return
;
baud
=
tty_get_baud_rate
(
info
->
tty
);
if
((
baud
==
38400
)
&&
((
info
->
flags
&
ZILOG_SPD_MASK
)
==
ZILOG_SPD_CUST
))
quot
=
info
->
custom_divisor
;
if
(
quot
)
{
info
->
zs_baud
=
info
->
baud_base
/
quot
;
info
->
clk_divisor
=
16
;
info
->
curregs
[
4
]
=
X16CLK
;
info
->
curregs
[
11
]
=
TCBR
|
RCBR
;
brg
=
BPS_TO_BRG
(
info
->
zs_baud
,
ZS_CLOCK
/
info
->
clk_divisor
);
info
->
curregs
[
12
]
=
(
brg
&
255
);
info
->
curregs
[
13
]
=
((
brg
>>
8
)
&
255
);
info
->
curregs
[
14
]
=
BRSRC
|
BRENAB
;
zs_rtsdtr
(
info
,
1
);
}
else
if
(
baud
)
{
info
->
zs_baud
=
baud
;
info
->
clk_divisor
=
16
;
info
->
curregs
[
4
]
=
X16CLK
;
info
->
curregs
[
11
]
=
TCBR
|
RCBR
;
brg
=
BPS_TO_BRG
(
info
->
zs_baud
,
ZS_CLOCK
/
info
->
clk_divisor
);
info
->
curregs
[
12
]
=
(
brg
&
255
);
info
->
curregs
[
13
]
=
((
brg
>>
8
)
&
255
);
info
->
curregs
[
14
]
=
BRSRC
|
BRENAB
;
zs_rtsdtr
(
info
,
1
);
}
else
{
zs_rtsdtr
(
info
,
0
);
return
;
}
/* byte size and parity */
switch
(
cflag
&
CSIZE
)
{
case
CS5
:
info
->
curregs
[
3
]
&=
~
(
RxN_MASK
);
info
->
curregs
[
3
]
|=
Rx5
;
info
->
curregs
[
5
]
&=
~
(
TxN_MASK
);
info
->
curregs
[
5
]
|=
Tx5
;
info
->
parity_mask
=
0x1f
;
break
;
case
CS6
:
info
->
curregs
[
3
]
&=
~
(
RxN_MASK
);
info
->
curregs
[
3
]
|=
Rx6
;
info
->
curregs
[
5
]
&=
~
(
TxN_MASK
);
info
->
curregs
[
5
]
|=
Tx6
;
info
->
parity_mask
=
0x3f
;
break
;
case
CS7
:
info
->
curregs
[
3
]
&=
~
(
RxN_MASK
);
info
->
curregs
[
3
]
|=
Rx7
;
info
->
curregs
[
5
]
&=
~
(
TxN_MASK
);
info
->
curregs
[
5
]
|=
Tx7
;
info
->
parity_mask
=
0x7f
;
break
;
case
CS8
:
default:
/* defaults to 8 bits */
info
->
curregs
[
3
]
&=
~
(
RxN_MASK
);
info
->
curregs
[
3
]
|=
Rx8
;
info
->
curregs
[
5
]
&=
~
(
TxN_MASK
);
info
->
curregs
[
5
]
|=
Tx8
;
info
->
parity_mask
=
0xff
;
break
;
}
info
->
curregs
[
4
]
&=
~
(
0x0c
);
if
(
cflag
&
CSTOPB
)
{
info
->
curregs
[
4
]
|=
SB2
;
}
else
{
info
->
curregs
[
4
]
|=
SB1
;
}
if
(
cflag
&
PARENB
)
{
info
->
curregs
[
4
]
|=
PAR_ENAB
;
}
else
{
info
->
curregs
[
4
]
&=
~
PAR_ENAB
;
}
if
(
!
(
cflag
&
PARODD
))
{
info
->
curregs
[
4
]
|=
PAR_EVEN
;
}
else
{
info
->
curregs
[
4
]
&=
~
PAR_EVEN
;
}
/* Load up the new values */
load_zsregs
(
info
,
info
->
curregs
);
return
;
}
/* This is for mouse/keyboard output.
* XXX mouse output??? can we send it commands??? XXX
*/
static
void
kbd_put_char
(
unsigned
char
ch
)
{
struct
sun_zschannel
*
chan
=
zs_kbdchan
;
unsigned
long
flags
;
if
(
!
chan
)
return
;
save_flags
(
flags
);
cli
();
zs_put_char
(
chan
,
ch
);
restore_flags
(
flags
);
}
void
mouse_put_char
(
char
ch
)
{
struct
sun_zschannel
*
chan
=
zs_mousechan
;
unsigned
long
flags
;
if
(
!
chan
)
return
;
save_flags
(
flags
);
cli
();
zs_put_char
(
chan
,
ch
);
restore_flags
(
flags
);
}
/* These are for receiving and sending characters under the kgdb
* source level kernel debugger.
*/
void
putDebugChar
(
char
kgdb_char
)
{
struct
sun_zschannel
*
chan
=
zs_kgdbchan
;
while
((
sbus_readb
(
&
chan
->
control
)
&
Tx_BUF_EMP
)
==
0
)
udelay
(
5
);
sbus_writeb
(
kgdb_char
,
&
chan
->
data
);
ZS_WSYNC
(
chan
);
ZSLOG
(
REGDATA
,
kgdb_char
,
1
);
}
char
getDebugChar
(
void
)
{
struct
sun_zschannel
*
chan
=
zs_kgdbchan
;
u8
val
;
do
{
val
=
sbus_readb
(
&
chan
->
control
);
ZSLOG
(
REGCTRL
,
val
,
0
);
udelay
(
5
);
}
while
((
val
&
Rx_CH_AV
)
==
0
);
val
=
sbus_readb
(
&
chan
->
data
);
ZSLOG
(
REGDATA
,
val
,
0
);
return
val
;
}
static
void
zs_flush_chars
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
unsigned
long
flags
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_flush_chars"
))
return
;
save_flags
(
flags
);
cli
();
if
(
info
->
xmit_cnt
<=
0
||
tty
->
stopped
||
tty
->
hw_stopped
||
!
info
->
xmit_buf
)
goto
out
;
/* Enable transmitter */
info
->
curregs
[
1
]
|=
TxINT_ENAB
|
EXT_INT_ENAB
;
write_zsreg
(
info
->
zs_channel
,
1
,
info
->
curregs
[
1
]);
info
->
curregs
[
5
]
|=
TxENAB
;
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
/*
* Send a first (bootstrapping) character. A best solution is
* to call transmit_chars() here which handles output in a
* generic way. Current transmit_chars() not only transmits,
* but resets interrupts also what we do not desire here.
* XXX Discuss with David.
*/
zs_put_char
(
info
->
zs_channel
,
info
->
xmit_buf
[
info
->
xmit_tail
++
]);
info
->
xmit_tail
=
info
->
xmit_tail
&
(
SERIAL_XMIT_SIZE
-
1
);
info
->
xmit_cnt
--
;
out:
restore_flags
(
flags
);
}
static
int
zs_write
(
struct
tty_struct
*
tty
,
int
from_user
,
const
unsigned
char
*
buf
,
int
count
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
unsigned
long
flags
;
int
c
,
total
=
0
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_write"
))
return
0
;
if
(
!
info
||
!
info
->
xmit_buf
||
!
tmp_buf
)
return
0
;
save_flags
(
flags
);
if
(
from_user
)
{
down
(
&
tmp_buf_sem
);
while
(
1
)
{
c
=
MIN
(
count
,
MIN
(
SERIAL_XMIT_SIZE
-
info
->
xmit_cnt
-
1
,
SERIAL_XMIT_SIZE
-
info
->
xmit_head
));
if
(
c
<=
0
)
break
;
c
-=
copy_from_user
(
tmp_buf
,
buf
,
c
);
if
(
!
c
)
{
if
(
!
total
)
total
=
-
EFAULT
;
break
;
}
cli
();
c
=
MIN
(
c
,
MIN
(
SERIAL_XMIT_SIZE
-
info
->
xmit_cnt
-
1
,
SERIAL_XMIT_SIZE
-
info
->
xmit_head
));
memcpy
(
info
->
xmit_buf
+
info
->
xmit_head
,
tmp_buf
,
c
);
info
->
xmit_head
=
((
info
->
xmit_head
+
c
)
&
(
SERIAL_XMIT_SIZE
-
1
));
info
->
xmit_cnt
+=
c
;
restore_flags
(
flags
);
buf
+=
c
;
count
-=
c
;
total
+=
c
;
}
up
(
&
tmp_buf_sem
);
}
else
{
while
(
1
)
{
cli
();
c
=
MIN
(
count
,
MIN
(
SERIAL_XMIT_SIZE
-
info
->
xmit_cnt
-
1
,
SERIAL_XMIT_SIZE
-
info
->
xmit_head
));
if
(
c
<=
0
)
{
restore_flags
(
flags
);
break
;
}
memcpy
(
info
->
xmit_buf
+
info
->
xmit_head
,
buf
,
c
);
info
->
xmit_head
=
((
info
->
xmit_head
+
c
)
&
(
SERIAL_XMIT_SIZE
-
1
));
info
->
xmit_cnt
+=
c
;
restore_flags
(
flags
);
buf
+=
c
;
count
-=
c
;
total
+=
c
;
}
}
cli
();
if
(
info
->
xmit_cnt
&&
!
tty
->
stopped
&&
!
tty
->
hw_stopped
)
{
/* Enable transmitter */
info
->
curregs
[
1
]
|=
TxINT_ENAB
|
EXT_INT_ENAB
;
write_zsreg
(
info
->
zs_channel
,
1
,
info
->
curregs
[
1
]);
info
->
curregs
[
5
]
|=
TxENAB
;
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
#if 1
zs_put_char
(
info
->
zs_channel
,
info
->
xmit_buf
[
info
->
xmit_tail
++
]);
info
->
xmit_tail
=
info
->
xmit_tail
&
(
SERIAL_XMIT_SIZE
-
1
);
info
->
xmit_cnt
--
;
#endif
}
restore_flags
(
flags
);
return
total
;
}
static
int
zs_write_room
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
int
ret
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_write_room"
))
return
0
;
ret
=
SERIAL_XMIT_SIZE
-
info
->
xmit_cnt
-
1
;
if
(
ret
<
0
)
ret
=
0
;
return
ret
;
}
static
int
zs_chars_in_buffer
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_chars_in_buffer"
))
return
0
;
return
info
->
xmit_cnt
;
}
static
void
zs_flush_buffer
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_flush_buffer"
))
return
;
cli
();
info
->
xmit_cnt
=
info
->
xmit_head
=
info
->
xmit_tail
=
0
;
sti
();
wake_up_interruptible
(
&
tty
->
write_wait
);
if
((
tty
->
flags
&
(
1
<<
TTY_DO_WRITE_WAKEUP
))
&&
tty
->
ldisc
.
write_wakeup
)
(
tty
->
ldisc
.
write_wakeup
)(
tty
);
}
/*
* ------------------------------------------------------------
* zs_throttle()
*
* This routine is called by the upper-layer tty layer to signal that
* incoming characters should be throttled.
* ------------------------------------------------------------
*/
static
void
zs_throttle
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
#ifdef SERIAL_DEBUG_THROTTLE
char
buf
[
64
];
printk
(
"throttle %s: %d....
\n
"
,
_tty_name
(
tty
,
buf
),
tty
->
ldisc
.
chars_in_buffer
(
tty
));
#endif
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_throttle"
))
return
;
if
(
I_IXOFF
(
tty
))
info
->
x_char
=
STOP_CHAR
(
tty
);
/* Turn off RTS line */
cli
();
info
->
curregs
[
5
]
&=
~
RTS
;
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
sti
();
}
static
void
zs_unthrottle
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
#ifdef SERIAL_DEBUG_THROTTLE
char
buf
[
64
];
printk
(
"unthrottle %s: %d....
\n
"
,
_tty_name
(
tty
,
buf
),
tty
->
ldisc
.
chars_in_buffer
(
tty
));
#endif
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_unthrottle"
))
return
;
if
(
I_IXOFF
(
tty
))
{
if
(
info
->
x_char
)
info
->
x_char
=
0
;
else
info
->
x_char
=
START_CHAR
(
tty
);
}
/* Assert RTS line */
cli
();
info
->
curregs
[
5
]
|=
RTS
;
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
sti
();
}
/*
* ------------------------------------------------------------
* zs_ioctl() and friends
* ------------------------------------------------------------
*/
static
int
get_serial_info
(
struct
sun_serial
*
info
,
struct
serial_struct
*
retinfo
)
{
struct
serial_struct
tmp
;
if
(
!
retinfo
)
return
-
EFAULT
;
memset
(
&
tmp
,
0
,
sizeof
(
tmp
));
tmp
.
type
=
info
->
type
;
tmp
.
line
=
info
->
line
;
tmp
.
port
=
info
->
port
;
tmp
.
irq
=
info
->
irq
;
tmp
.
flags
=
info
->
flags
;
tmp
.
baud_base
=
info
->
baud_base
;
tmp
.
close_delay
=
info
->
close_delay
;
tmp
.
closing_wait
=
info
->
closing_wait
;
tmp
.
custom_divisor
=
info
->
custom_divisor
;
if
(
copy_to_user
(
retinfo
,
&
tmp
,
sizeof
(
*
retinfo
)))
return
-
EFAULT
;
return
0
;
}
static
int
set_serial_info
(
struct
sun_serial
*
info
,
struct
serial_struct
*
new_info
)
{
struct
serial_struct
new_serial
;
struct
sun_serial
old_info
;
int
retval
=
0
;
if
(
!
new_info
||
copy_from_user
(
&
new_serial
,
new_info
,
sizeof
(
new_serial
)))
return
-
EFAULT
;
old_info
=
*
info
;
if
(
!
capable
(
CAP_SYS_ADMIN
))
{
if
((
new_serial
.
baud_base
!=
info
->
baud_base
)
||
(
new_serial
.
type
!=
info
->
type
)
||
(
new_serial
.
close_delay
!=
info
->
close_delay
)
||
((
new_serial
.
flags
&
~
ZILOG_USR_MASK
)
!=
(
info
->
flags
&
~
ZILOG_USR_MASK
)))
return
-
EPERM
;
info
->
flags
=
((
info
->
flags
&
~
ZILOG_USR_MASK
)
|
(
new_serial
.
flags
&
ZILOG_USR_MASK
));
info
->
custom_divisor
=
new_serial
.
custom_divisor
;
goto
check_and_exit
;
}
if
(
new_serial
.
baud_base
<
9600
)
return
-
EINVAL
;
if
(
info
->
count
>
1
)
return
-
EBUSY
;
/*
* OK, past this point, all the error checking has been done.
* At this point, we start making changes.....
*/
info
->
baud_base
=
new_serial
.
baud_base
;
info
->
flags
=
((
info
->
flags
&
~
ZILOG_FLAGS
)
|
(
new_serial
.
flags
&
ZILOG_FLAGS
));
info
->
custom_divisor
=
new_serial
.
custom_divisor
;
info
->
type
=
new_serial
.
type
;
info
->
close_delay
=
new_serial
.
close_delay
;
info
->
closing_wait
=
new_serial
.
closing_wait
;
check_and_exit:
retval
=
startup
(
info
);
return
retval
;
}
/*
* get_lsr_info - get line status register info
*
* Purpose: Let user call ioctl() to get info when the UART physically
* is emptied. On bus types like RS485, the transmitter must
* release the bus after transmitting. This must be done when
* the transmit shift register is empty, not be done when the
* transmit holding register is empty. This functionality
* allows an RS485 driver to be written in user space.
*/
static
int
get_lsr_info
(
struct
sun_serial
*
info
,
unsigned
int
*
value
)
{
unsigned
char
status
;
cli
();
status
=
sbus_readb
(
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZSLOG
(
REGCTRL
,
status
,
0
);
sti
();
if
(
put_user
(
status
,
value
))
return
-
EFAULT
;
return
0
;
}
static
int
get_modem_info
(
struct
sun_serial
*
info
,
unsigned
int
*
value
)
{
unsigned
char
status
;
unsigned
int
result
;
cli
();
status
=
sbus_readb
(
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZSLOG
(
REGCTRL
,
status
,
0
);
sti
();
result
=
((
info
->
curregs
[
5
]
&
RTS
)
?
TIOCM_RTS
:
0
)
|
((
info
->
curregs
[
5
]
&
DTR
)
?
TIOCM_DTR
:
0
)
|
((
status
&
DCD
)
?
TIOCM_CAR
:
0
)
|
((
status
&
SYNC
)
?
TIOCM_DSR
:
0
)
|
((
status
&
CTS
)
?
TIOCM_CTS
:
0
);
if
(
put_user
(
result
,
value
))
return
-
EFAULT
;
return
0
;
}
static
int
set_modem_info
(
struct
sun_serial
*
info
,
unsigned
int
cmd
,
unsigned
int
*
value
)
{
unsigned
int
arg
;
if
(
get_user
(
arg
,
value
))
return
-
EFAULT
;
switch
(
cmd
)
{
case
TIOCMBIS
:
if
(
arg
&
TIOCM_RTS
)
info
->
curregs
[
5
]
|=
RTS
;
if
(
arg
&
TIOCM_DTR
)
info
->
curregs
[
5
]
|=
DTR
;
break
;
case
TIOCMBIC
:
if
(
arg
&
TIOCM_RTS
)
info
->
curregs
[
5
]
&=
~
RTS
;
if
(
arg
&
TIOCM_DTR
)
info
->
curregs
[
5
]
&=
~
DTR
;
break
;
case
TIOCMSET
:
info
->
curregs
[
5
]
=
((
info
->
curregs
[
5
]
&
~
(
RTS
|
DTR
))
|
((
arg
&
TIOCM_RTS
)
?
RTS
:
0
)
|
((
arg
&
TIOCM_DTR
)
?
DTR
:
0
));
break
;
default:
return
-
EINVAL
;
}
cli
();
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
sti
();
return
0
;
}
/*
* This routine sends a break character out the serial port.
*/
static
void
send_break
(
struct
sun_serial
*
info
,
int
duration
)
{
if
(
!
info
->
port
)
return
;
current
->
state
=
TASK_INTERRUPTIBLE
;
cli
();
write_zsreg
(
info
->
zs_channel
,
5
,
(
info
->
curregs
[
5
]
|
SND_BRK
));
schedule_timeout
(
duration
);
write_zsreg
(
info
->
zs_channel
,
5
,
info
->
curregs
[
5
]);
sti
();
}
static
int
zs_ioctl
(
struct
tty_struct
*
tty
,
struct
file
*
file
,
unsigned
int
cmd
,
unsigned
long
arg
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
int
retval
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_ioctl"
))
return
-
ENODEV
;
if
((
cmd
!=
TIOCGSERIAL
)
&&
(
cmd
!=
TIOCSSERIAL
)
&&
(
cmd
!=
TIOCSERCONFIG
)
&&
(
cmd
!=
TIOCSERGWILD
)
&&
(
cmd
!=
TIOCSERSWILD
)
&&
(
cmd
!=
TIOCSERGSTRUCT
))
{
if
(
tty
->
flags
&
(
1
<<
TTY_IO_ERROR
))
return
-
EIO
;
}
switch
(
cmd
)
{
case
TCSBRK
:
/* SVID version: non-zero arg --> no break */
retval
=
tty_check_change
(
tty
);
if
(
retval
)
return
retval
;
tty_wait_until_sent
(
tty
,
0
);
if
(
!
arg
)
send_break
(
info
,
HZ
/
4
);
/* 1/4 second */
return
0
;
case
TCSBRKP
:
/* support for POSIX tcsendbreak() */
retval
=
tty_check_change
(
tty
);
if
(
retval
)
return
retval
;
tty_wait_until_sent
(
tty
,
0
);
send_break
(
info
,
arg
?
arg
*
(
HZ
/
10
)
:
HZ
/
4
);
return
0
;
case
TIOCGSOFTCAR
:
if
(
put_user
(
C_CLOCAL
(
tty
)
?
1
:
0
,
(
unsigned
long
*
)
arg
))
return
-
EFAULT
;
return
0
;
case
TIOCSSOFTCAR
:
if
(
get_user
(
arg
,
(
unsigned
long
*
)
arg
))
return
-
EFAULT
;
tty
->
termios
->
c_cflag
=
((
tty
->
termios
->
c_cflag
&
~
CLOCAL
)
|
(
arg
?
CLOCAL
:
0
));
return
0
;
case
TIOCMGET
:
return
get_modem_info
(
info
,
(
unsigned
int
*
)
arg
);
case
TIOCMBIS
:
case
TIOCMBIC
:
case
TIOCMSET
:
return
set_modem_info
(
info
,
cmd
,
(
unsigned
int
*
)
arg
);
case
TIOCGSERIAL
:
return
get_serial_info
(
info
,
(
struct
serial_struct
*
)
arg
);
case
TIOCSSERIAL
:
return
set_serial_info
(
info
,
(
struct
serial_struct
*
)
arg
);
case
TIOCSERGETLSR
:
/* Get line status register */
return
get_lsr_info
(
info
,
(
unsigned
int
*
)
arg
);
case
TIOCSERGSTRUCT
:
if
(
copy_to_user
((
struct
sun_serial
*
)
arg
,
info
,
sizeof
(
struct
sun_serial
)))
return
-
EFAULT
;
return
0
;
default:
return
-
ENOIOCTLCMD
;
}
return
0
;
}
static
void
zs_set_termios
(
struct
tty_struct
*
tty
,
struct
termios
*
old_termios
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
if
(
tty
->
termios
->
c_cflag
==
old_termios
->
c_cflag
)
return
;
change_speed
(
info
);
if
((
old_termios
->
c_cflag
&
CRTSCTS
)
&&
!
(
tty
->
termios
->
c_cflag
&
CRTSCTS
))
{
tty
->
hw_stopped
=
0
;
zs_start
(
tty
);
}
}
/*
* ------------------------------------------------------------
* zs_close()
*
* This routine is called when the serial port gets closed. First, we
* wait for the last remaining data to be sent. Then, we unlink its
* ZILOG structure from the interrupt chain if necessary, and we free
* that IRQ if nothing is left in the chain.
* ------------------------------------------------------------
*/
static
void
zs_close
(
struct
tty_struct
*
tty
,
struct
file
*
filp
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
unsigned
long
flags
;
if
(
!
info
||
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_close"
))
return
;
save_flags
(
flags
);
cli
();
if
(
tty_hung_up_p
(
filp
))
{
restore_flags
(
flags
);
return
;
}
#ifdef SERIAL_DEBUG_OPEN
printk
(
"zs_close tty-%d, count = %d
\n
"
,
info
->
line
,
info
->
count
);
#endif
if
((
tty
->
count
==
1
)
&&
(
info
->
count
!=
1
))
{
/*
* Uh, oh. tty->count is 1, which means that the tty
* structure will be freed. Info->count should always
* be one in these conditions. If it's greater than
* one, we've got real problems, since it means the
* serial port won't be shutdown.
*/
printk
(
"zs_close: bad serial port count; tty->count is 1, "
"info->count is %d
\n
"
,
info
->
count
);
info
->
count
=
1
;
}
if
(
--
info
->
count
<
0
)
{
printk
(
"zs_close: bad serial port count for ttys%d: %d
\n
"
,
info
->
line
,
info
->
count
);
info
->
count
=
0
;
}
if
(
info
->
count
)
{
restore_flags
(
flags
);
return
;
}
info
->
flags
|=
ZILOG_CLOSING
;
/*
* Save the termios structure, since this port may have
* separate termios for callout and dialin.
*/
if
(
info
->
flags
&
ZILOG_NORMAL_ACTIVE
)
info
->
normal_termios
=
*
tty
->
termios
;
if
(
info
->
flags
&
ZILOG_CALLOUT_ACTIVE
)
info
->
callout_termios
=
*
tty
->
termios
;
/*
* Now we wait for the transmit buffer to clear; and we notify
* the line discipline to only process XON/XOFF characters.
*/
tty
->
closing
=
1
;
if
(
info
->
closing_wait
!=
ZILOG_CLOSING_WAIT_NONE
)
tty_wait_until_sent
(
tty
,
info
->
closing_wait
);
/*
* At this point we stop accepting input. To do this, we
* disable the receive line status interrupts, and tell the
* interrupt driver to stop checking the data ready bit in the
* line status register.
*/
/** if (!info->iscons) ... **/
info
->
curregs
[
3
]
&=
~
RxENAB
;
write_zsreg
(
info
->
zs_channel
,
3
,
info
->
curregs
[
3
]);
info
->
curregs
[
1
]
&=
~
(
RxINT_MASK
);
write_zsreg
(
info
->
zs_channel
,
1
,
info
->
curregs
[
1
]);
ZS_CLEARFIFO
(
info
->
zs_channel
);
shutdown
(
info
);
if
(
tty
->
driver
.
flush_buffer
)
tty
->
driver
.
flush_buffer
(
tty
);
if
(
tty
->
ldisc
.
flush_buffer
)
tty
->
ldisc
.
flush_buffer
(
tty
);
tty
->
closing
=
0
;
info
->
event
=
0
;
info
->
tty
=
0
;
if
(
tty
->
ldisc
.
num
!=
ldiscs
[
N_TTY
].
num
)
{
if
(
tty
->
ldisc
.
close
)
(
tty
->
ldisc
.
close
)(
tty
);
tty
->
ldisc
=
ldiscs
[
N_TTY
];
tty
->
termios
->
c_line
=
N_TTY
;
if
(
tty
->
ldisc
.
open
)
(
tty
->
ldisc
.
open
)(
tty
);
}
if
(
info
->
blocked_open
)
{
if
(
info
->
close_delay
)
{
current
->
state
=
TASK_INTERRUPTIBLE
;
schedule_timeout
(
info
->
close_delay
);
}
wake_up_interruptible
(
&
info
->
open_wait
);
}
info
->
flags
&=
~
(
ZILOG_NORMAL_ACTIVE
|
ZILOG_CALLOUT_ACTIVE
|
ZILOG_CLOSING
);
wake_up_interruptible
(
&
info
->
close_wait
);
#ifdef SERIAL_DEBUG_OPEN
printk
(
"zs_close tty-%d exiting, count = %d
\n
"
,
info
->
line
,
info
->
count
);
#endif
restore_flags
(
flags
);
}
/*
* zs_hangup() --- called by tty_hangup() when a hangup is signaled.
*/
void
zs_hangup
(
struct
tty_struct
*
tty
)
{
struct
sun_serial
*
info
=
(
struct
sun_serial
*
)
tty
->
driver_data
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_hangup"
))
return
;
if
(
info
->
is_cons
)
return
;
#ifdef SERIAL_DEBUG_OPEN
printk
(
"zs_hangup<%p: tty-%d, count = %d bye
\n
"
,
__builtin_return_address
(
0
),
info
->
line
,
info
->
count
);
#endif
zs_flush_buffer
(
tty
);
shutdown
(
info
);
info
->
event
=
0
;
info
->
count
=
0
;
info
->
flags
&=
~
(
ZILOG_NORMAL_ACTIVE
|
ZILOG_CALLOUT_ACTIVE
);
info
->
tty
=
0
;
wake_up_interruptible
(
&
info
->
open_wait
);
}
/*
*
* line_info - returns information about each channel
*
*/
static
inline
int
line_info
(
char
*
buf
,
struct
sun_serial
*
info
)
{
unsigned
char
status
;
char
stat_buf
[
30
];
int
ret
;
ret
=
sprintf
(
buf
,
"%d: uart:Zilog8530 port:%x irq:%d"
,
info
->
line
,
info
->
port
,
info
->
irq
);
cli
();
status
=
sbus_readb
(
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZSLOG
(
REGCTRL
,
status
,
0
);
sti
();
stat_buf
[
0
]
=
0
;
stat_buf
[
1
]
=
0
;
if
(
info
->
curregs
[
5
]
&
RTS
)
strcat
(
stat_buf
,
"|RTS"
);
if
(
status
&
CTS
)
strcat
(
stat_buf
,
"|CTS"
);
if
(
info
->
curregs
[
5
]
&
DTR
)
strcat
(
stat_buf
,
"|DTR"
);
if
(
status
&
SYNC
)
strcat
(
stat_buf
,
"|DSR"
);
if
(
status
&
DCD
)
strcat
(
stat_buf
,
"|CD"
);
ret
+=
sprintf
(
buf
+
ret
,
" baud:%d %s
\n
"
,
info
->
zs_baud
,
stat_buf
+
1
);
return
ret
;
}
/*
*
* zs_read_proc() - called when /proc/tty/driver/serial is read.
*
*/
int
zs_read_proc
(
char
*
page
,
char
**
start
,
off_t
off
,
int
count
,
int
*
eof
,
void
*
data
)
{
char
*
revision
=
"$Revision: 1.71 $"
;
char
*
version
,
*
p
;
int
i
,
len
=
0
,
l
;
off_t
begin
=
0
;
version
=
strchr
(
revision
,
' '
);
p
=
strchr
(
++
version
,
' '
);
*
p
=
'\0'
;
len
+=
sprintf
(
page
,
"serinfo:1.0 driver:%s
\n
"
,
version
);
*
p
=
' '
;
for
(
i
=
0
;
i
<
NUM_CHANNELS
&&
len
<
4000
;
i
++
)
{
l
=
line_info
(
page
+
len
,
&
zs_soft
[
i
]);
len
+=
l
;
if
(
len
+
begin
>
off
+
count
)
goto
done
;
if
(
len
+
begin
<
off
)
{
begin
+=
len
;
len
=
0
;
}
}
*
eof
=
1
;
done:
if
(
off
>=
len
+
begin
)
return
0
;
*
start
=
page
+
(
off
-
begin
);
return
((
count
<
begin
+
len
-
off
)
?
count
:
begin
+
len
-
off
);
}
/*
* ------------------------------------------------------------
* zs_open() and friends
* ------------------------------------------------------------
*/
static
int
block_til_ready
(
struct
tty_struct
*
tty
,
struct
file
*
filp
,
struct
sun_serial
*
info
)
{
DECLARE_WAITQUEUE
(
wait
,
current
);
int
retval
,
do_clocal
=
0
;
unsigned
char
r0
;
/*
* If the device is in the middle of being closed, then block
* until it's done, and then try again.
*/
if
(
info
->
flags
&
ZILOG_CLOSING
)
{
interruptible_sleep_on
(
&
info
->
close_wait
);
#ifdef SERIAL_DO_RESTART
if
(
info
->
flags
&
ZILOG_HUP_NOTIFY
)
return
-
EAGAIN
;
else
return
-
ERESTARTSYS
;
#else
return
-
EAGAIN
;
#endif
}
/*
* If this is a callout device, then just make sure the normal
* device isn't being used.
*/
if
(
tty
->
driver
.
subtype
==
SERIAL_TYPE_CALLOUT
)
{
if
(
info
->
flags
&
ZILOG_NORMAL_ACTIVE
)
return
-
EBUSY
;
if
((
info
->
flags
&
ZILOG_CALLOUT_ACTIVE
)
&&
(
info
->
flags
&
ZILOG_SESSION_LOCKOUT
)
&&
(
info
->
session
!=
current
->
session
))
return
-
EBUSY
;
if
((
info
->
flags
&
ZILOG_CALLOUT_ACTIVE
)
&&
(
info
->
flags
&
ZILOG_PGRP_LOCKOUT
)
&&
(
info
->
pgrp
!=
current
->
pgrp
))
return
-
EBUSY
;
info
->
flags
|=
ZILOG_CALLOUT_ACTIVE
;
return
0
;
}
/*
* If non-blocking mode is set, or the port is not enabled,
* then make the check up front and then exit.
*/
if
((
filp
->
f_flags
&
O_NONBLOCK
)
||
(
tty
->
flags
&
(
1
<<
TTY_IO_ERROR
)))
{
if
(
info
->
flags
&
ZILOG_CALLOUT_ACTIVE
)
return
-
EBUSY
;
info
->
flags
|=
ZILOG_NORMAL_ACTIVE
;
return
0
;
}
if
(
info
->
flags
&
ZILOG_CALLOUT_ACTIVE
)
{
if
(
info
->
normal_termios
.
c_cflag
&
CLOCAL
)
do_clocal
=
1
;
}
else
{
if
(
tty
->
termios
->
c_cflag
&
CLOCAL
)
do_clocal
=
1
;
}
/*
* Block waiting for the carrier detect and the line to become
* free (i.e., not in use by the callout). While we are in
* this loop, info->count is dropped by one, so that
* zs_close() knows when to free things. We restore it upon
* exit, either normal or abnormal.
*/
retval
=
0
;
add_wait_queue
(
&
info
->
open_wait
,
&
wait
);
#ifdef SERIAL_DEBUG_OPEN
printk
(
"block_til_ready before block: ttys%d, count = %d
\n
"
,
info
->
line
,
info
->
count
);
#endif
cli
();
if
(
!
tty_hung_up_p
(
filp
))
info
->
count
--
;
sti
();
info
->
blocked_open
++
;
while
(
1
)
{
cli
();
if
(
!
(
info
->
flags
&
ZILOG_CALLOUT_ACTIVE
))
zs_rtsdtr
(
info
,
1
);
sti
();
set_current_state
(
TASK_INTERRUPTIBLE
);
if
(
tty_hung_up_p
(
filp
)
||
!
(
info
->
flags
&
ZILOG_INITIALIZED
))
{
#ifdef SERIAL_DEBUG_OPEN
printk
(
"block_til_ready hup-ed: ttys%d, count = %d
\n
"
,
info
->
line
,
info
->
count
);
#endif
#ifdef SERIAL_DO_RESTART
if
(
info
->
flags
&
ZILOG_HUP_NOTIFY
)
retval
=
-
EAGAIN
;
else
retval
=
-
ERESTARTSYS
;
#else
retval
=
-
EAGAIN
;
#endif
break
;
}
cli
();
r0
=
read_zsreg
(
info
->
zs_channel
,
R0
);
sti
();
if
(
!
(
info
->
flags
&
ZILOG_CALLOUT_ACTIVE
)
&&
!
(
info
->
flags
&
ZILOG_CLOSING
)
&&
(
do_clocal
||
(
DCD
&
r0
)))
break
;
if
(
signal_pending
(
current
))
{
retval
=
-
ERESTARTSYS
;
break
;
}
#ifdef SERIAL_DEBUG_OPEN
printk
(
"block_til_ready blocking: ttys%d, count = %d
\n
"
,
info
->
line
,
info
->
count
);
#endif
schedule
();
}
current
->
state
=
TASK_RUNNING
;
remove_wait_queue
(
&
info
->
open_wait
,
&
wait
);
if
(
!
tty_hung_up_p
(
filp
))
info
->
count
++
;
info
->
blocked_open
--
;
#ifdef SERIAL_DEBUG_OPEN
printk
(
"block_til_ready after blocking: ttys%d, count = %d
\n
"
,
info
->
line
,
info
->
count
);
#endif
if
(
retval
)
return
retval
;
info
->
flags
|=
ZILOG_NORMAL_ACTIVE
;
return
0
;
}
/*
* This routine is called whenever a serial port is opened. It
* enables interrupts for a serial port, linking in its ZILOG structure into
* the IRQ chain. It also performs the serial-specific
* initialization for the tty structure.
*/
int
zs_open
(
struct
tty_struct
*
tty
,
struct
file
*
filp
)
{
struct
sun_serial
*
info
;
int
retval
,
line
;
line
=
minor
(
tty
->
device
)
-
tty
->
driver
.
minor_start
;
/* The zilog lines for the mouse/keyboard must be
* opened using their respective drivers.
*/
if
((
line
<
0
)
||
(
line
>=
NUM_CHANNELS
))
return
-
ENODEV
;
if
((
line
==
KEYBOARD_LINE
)
||
(
line
==
MOUSE_LINE
))
return
-
ENODEV
;
info
=
zs_soft
+
line
;
/* Is the kgdb running over this line? */
if
(
info
->
kgdb_channel
)
return
-
ENODEV
;
if
(
serial_paranoia_check
(
info
,
tty
->
device
,
"zs_open"
))
return
-
ENODEV
;
#ifdef SERIAL_DEBUG_OPEN
printk
(
"zs_open %s%d, count = %d
\n
"
,
tty
->
driver
.
name
,
info
->
line
,
info
->
count
);
#endif
if
(
info
->
tty
!=
0
&&
info
->
tty
!=
tty
)
{
/* Never happen? */
printk
(
"zs_open %s%d, tty overwrite.
\n
"
,
tty
->
driver
.
name
,
info
->
line
);
return
-
EBUSY
;
}
if
(
!
tmp_buf
)
{
unsigned
long
page
=
get_free_page
(
GFP_KERNEL
);
if
(
!
page
)
return
-
ENOMEM
;
if
(
tmp_buf
)
free_page
(
page
);
else
tmp_buf
=
(
unsigned
char
*
)
page
;
}
info
->
count
++
;
tty
->
driver_data
=
info
;
info
->
tty
=
tty
;
/*
* Start up serial port
*/
retval
=
startup
(
info
);
if
(
retval
)
return
retval
;
retval
=
block_til_ready
(
tty
,
filp
,
info
);
if
(
retval
)
{
#ifdef SERIAL_DEBUG_OPEN
printk
(
"zs_open returning after block_til_ready with %d
\n
"
,
retval
);
#endif
return
retval
;
}
if
((
info
->
count
==
1
)
&&
(
info
->
flags
&
ZILOG_SPLIT_TERMIOS
))
{
if
(
tty
->
driver
.
subtype
==
SERIAL_TYPE_NORMAL
)
*
tty
->
termios
=
info
->
normal_termios
;
else
*
tty
->
termios
=
info
->
callout_termios
;
change_speed
(
info
);
}
#ifdef CONFIG_SERIAL_CONSOLE
if
(
zs_console
.
cflag
&&
zs_console
.
index
==
line
)
{
tty
->
termios
->
c_cflag
=
zs_console
.
cflag
;
zs_console
.
cflag
=
0
;
change_speed
(
info
);
}
#endif
info
->
session
=
current
->
session
;
info
->
pgrp
=
current
->
pgrp
;
#ifdef SERIAL_DEBUG_OPEN
printk
(
"zs_open ttys%d successful..."
,
info
->
line
);
#endif
return
0
;
}
/* Finally, routines used to initialize the serial driver. */
static
void
show_serial_version
(
void
)
{
char
*
revision
=
"$Revision: 1.71 $"
;
char
*
version
,
*
p
;
version
=
strchr
(
revision
,
' '
);
p
=
strchr
(
++
version
,
' '
);
*
p
=
'\0'
;
printk
(
"Sparc Zilog8530 serial driver version %s
\n
"
,
version
);
*
p
=
' '
;
}
/* Probe the PROM for the request zs chip number.
*
* Note: The Sun Voyager shows two addresses and two intr for it's
* Zilogs, what the second does, I don't know. It does work
* with using only the first number of each property. Also
* we have a special version for sun4u.
*/
#ifdef __sparc_v9__
static
struct
sun_zslayout
*
__init
get_zs
(
int
chip
)
{
unsigned
int
vaddr
[
2
]
=
{
0
,
0
};
unsigned
long
mapped_addr
=
0
;
int
busnode
,
seen
,
zsnode
,
sun4u_ino
;
static
int
irq
=
0
;
if
(
chip
<
0
||
chip
>=
NUM_SERIAL
)
{
prom_printf
(
"get_zs bogon zs chip number"
);
prom_halt
();
}
if
(
central_bus
)
busnode
=
central_bus
->
child
->
prom_node
;
else
busnode
=
prom_searchsiblings
(
prom_getchild
(
prom_root_node
),
"sbus"
);
if
(
busnode
==
0
||
busnode
==
-
1
)
{
prom_printf
(
"get_zs: no zs bus to search"
);
prom_halt
();
}
zsnode
=
prom_getchild
(
busnode
);
seen
=
0
;
while
(
zsnode
)
{
int
slave
;
zsnode
=
prom_searchsiblings
(
zsnode
,
"zs"
);
slave
=
prom_getintdefault
(
zsnode
,
"slave"
,
-
1
);
if
((
slave
==
chip
)
||
(
seen
==
chip
))
{
int
len
=
prom_getproperty
(
zsnode
,
"address"
,
(
void
*
)
vaddr
,
sizeof
(
vaddr
));
if
(
len
==
-
1
||
central_bus
!=
NULL
)
{
struct
sbus_bus
*
sbus
=
NULL
;
struct
sbus_dev
*
sdev
=
NULL
;
/* "address" property is not guarenteed,
* everything in I/O is implicitly mapped
* anyways by our clever TLB miss handling
* scheme, so don't fail here. -DaveM
*/
if
(
central_bus
==
NULL
)
{
for_each_sbus
(
sbus
)
{
for_each_sbusdev
(
sdev
,
sbus
)
{
if
(
sdev
->
prom_node
==
zsnode
)
goto
found
;
}
}
}
found:
if
(
sdev
==
NULL
&&
central_bus
==
NULL
)
prom_halt
();
if
(
central_bus
==
NULL
)
{
mapped_addr
=
sbus_ioremap
(
&
sdev
->
resource
[
0
],
0
,
PAGE_SIZE
,
"Zilog Registers"
);
}
else
{
struct
linux_prom_registers
zsregs
[
1
];
int
err
;
err
=
prom_getproperty
(
zsnode
,
"reg"
,
(
char
*
)
&
zsregs
[
0
],
sizeof
(
zsregs
));
if
(
err
==
-
1
)
{
prom_printf
(
"ZS: Cannot map Zilog regs.
\n
"
);
prom_halt
();
}
apply_fhc_ranges
(
central_bus
->
child
,
&
zsregs
[
0
],
1
);
apply_central_ranges
(
central_bus
,
&
zsregs
[
0
],
1
);
mapped_addr
=
((((
u64
)
zsregs
[
0
].
which_io
)
<<
32UL
)
|
((
u64
)
zsregs
[
0
].
phys_addr
));
}
}
else
if
(
len
%
sizeof
(
unsigned
int
))
{
prom_printf
(
"WHOOPS: proplen for %s "
"was %d, need multiple of "
"%d
\n
"
,
"address"
,
len
,
sizeof
(
unsigned
int
));
panic
(
"zilog: address property"
);
}
zs_nodes
[
chip
]
=
zsnode
;
len
=
prom_getproperty
(
zsnode
,
"interrupts"
,
(
char
*
)
&
sun4u_ino
,
(
sizeof
(
sun4u_ino
)));
if
(
!
irq
)
{
if
(
central_bus
)
{
unsigned
long
iclr
,
imap
;
iclr
=
central_bus
->
child
->
fhc_regs
.
uregs
+
FHC_UREGS_ICLR
;
imap
=
central_bus
->
child
->
fhc_regs
.
uregs
+
FHC_UREGS_IMAP
;
irq
=
zilog_irq
=
build_irq
(
12
,
0
,
iclr
,
imap
);
}
else
{
irq
=
zilog_irq
=
sbus_build_irq
(
sbus_root
,
sun4u_ino
);
}
}
break
;
}
zsnode
=
prom_getsibling
(
zsnode
);
seen
++
;
}
if
(
!
zsnode
)
panic
(
"get_zs: whee chip not found"
);
if
(
!
vaddr
[
0
]
&&
!
mapped_addr
)
panic
(
"get_zs: whee no serial chip mappable"
);
if
(
mapped_addr
!=
0
)
{
return
(
struct
sun_zslayout
*
)
mapped_addr
;
}
else
{
return
(
struct
sun_zslayout
*
)
prom_virt_to_phys
((
unsigned
long
)
vaddr
[
0
],
0
);
}
}
#else
/* !(__sparc_v9__) */
static
struct
sun_zslayout
*
__init
get_zs
(
int
chip
)
{
struct
linux_prom_irqs
tmp_irq
[
2
];
unsigned
int
paddr
=
0
;
unsigned
int
vaddr
[
2
]
=
{
0
,
0
};
int
zsnode
,
tmpnode
,
iospace
,
slave
,
len
;
int
cpunode
=
0
,
bbnode
=
0
;
static
int
irq
=
0
;
int
chipid
=
chip
;
iospace
=
0
;
if
(
chip
<
0
||
chip
>=
NUM_SERIAL
)
panic
(
"get_zs bogon zs chip number"
);
if
(
sparc_cpu_model
==
sun4
)
{
struct
resource
dummy_resource
;
/* Grrr, these have to be hardcoded aieee */
switch
(
chip
)
{
case
0
:
paddr
=
0xf1000000
;
break
;
case
1
:
paddr
=
0xf0000000
;
break
;
};
iospace
=
0
;
zs_nodes
[
chip
]
=
0
;
if
(
!
irq
)
zilog_irq
=
irq
=
12
;
dummy_resource
.
start
=
paddr
;
dummy_resource
.
end
=
paddr
+
8
-
1
;
dummy_resource
.
flags
=
IORESOURCE_IO
;
vaddr
[
0
]
=
sbus_ioremap
(
&
dummy_resource
,
0
,
8
,
"Zilog Serial"
);
}
else
{
/* Can use the prom for other machine types */
zsnode
=
prom_getchild
(
prom_root_node
);
if
(
sparc_cpu_model
==
sun4d
)
{
int
no
=
0
;
tmpnode
=
zsnode
;
zsnode
=
0
;
bbnode
=
0
;
while
(
tmpnode
&&
(
tmpnode
=
prom_searchsiblings
(
tmpnode
,
"cpu-unit"
)))
{
bbnode
=
prom_getchild
(
tmpnode
);
if
(
bbnode
&&
(
bbnode
=
prom_searchsiblings
(
bbnode
,
"bootbus"
)))
{
if
(
no
==
(
chip
>>
1
))
{
cpunode
=
tmpnode
;
zsnode
=
prom_getchild
(
bbnode
);
chipid
=
(
chip
&
1
);
break
;
}
no
++
;
}
tmpnode
=
prom_getsibling
(
tmpnode
);
}
if
(
!
tmpnode
)
panic
(
"get_zs: couldn't find %dth bootbus
\n
"
,
chip
>>
1
);
}
else
{
tmpnode
=
prom_searchsiblings
(
zsnode
,
"obio"
);
if
(
tmpnode
)
zsnode
=
prom_getchild
(
tmpnode
);
}
if
(
!
zsnode
)
panic
(
"get_zs no zs serial prom node"
);
while
(
zsnode
)
{
zsnode
=
prom_searchsiblings
(
zsnode
,
"zs"
);
slave
=
prom_getintdefault
(
zsnode
,
"slave"
,
-
1
);
if
(
slave
==
chipid
)
{
/* The one we want */
if
(
sparc_cpu_model
!=
sun4d
)
{
len
=
prom_getproperty
(
zsnode
,
"address"
,
(
void
*
)
vaddr
,
sizeof
(
vaddr
));
if
(
len
%
sizeof
(
unsigned
int
))
{
prom_printf
(
"WHOOPS: proplen for %s "
"was %d, need multiple of "
"%d
\n
"
,
"address"
,
len
,
sizeof
(
unsigned
int
));
panic
(
"zilog: address property"
);
}
}
else
{
/* On sun4d don't have address property :( */
struct
linux_prom_registers
zsreg
[
4
];
struct
resource
res
;
if
(
prom_getproperty
(
zsnode
,
"reg"
,
(
char
*
)
zsreg
,
sizeof
(
zsreg
))
==
-
1
)
{
prom_printf
(
"Cannot map zs regs
\n
"
);
prom_halt
();
}
prom_apply_generic_ranges
(
bbnode
,
cpunode
,
zsreg
,
1
);
res
.
start
=
zsreg
[
0
].
phys_addr
;
res
.
end
=
res
.
start
+
8
-
1
;
res
.
flags
=
zsreg
[
0
].
which_io
|
IORESOURCE_IO
;
vaddr
[
0
]
=
sbus_ioremap
(
&
res
,
0
,
8
,
"Zilog Serial"
);
}
zs_nodes
[
chip
]
=
zsnode
;
len
=
prom_getproperty
(
zsnode
,
"intr"
,
(
char
*
)
tmp_irq
,
sizeof
(
tmp_irq
));
if
(
len
%
sizeof
(
struct
linux_prom_irqs
))
{
prom_printf
(
"WHOOPS: proplen for %s "
"was %d, need multiple of "
"%d
\n
"
,
"intr"
,
len
,
sizeof
(
struct
linux_prom_irqs
));
panic
(
"zilog: intr property"
);
}
if
(
!
irq
)
{
irq
=
zilog_irq
=
tmp_irq
[
0
].
pri
;
}
else
{
if
(
tmp_irq
[
0
].
pri
!=
irq
)
panic
(
"zilog: bogon irqs"
);
}
break
;
}
zsnode
=
prom_getsibling
(
zsnode
);
}
if
(
!
zsnode
)
panic
(
"get_zs whee chip not found"
);
}
if
(
!
vaddr
[
0
])
panic
(
"get_zs whee no serial chip mappable"
);
return
(
struct
sun_zslayout
*
)(
unsigned
long
)
vaddr
[
0
];
}
#endif
/* This is for the auto baud rate detection in the mouse driver. */
void
zs_change_mouse_baud
(
int
newbaud
)
{
int
channel
=
MOUSE_LINE
;
int
brg
;
zs_soft
[
channel
].
zs_baud
=
newbaud
;
brg
=
BPS_TO_BRG
(
zs_soft
[
channel
].
zs_baud
,
(
ZS_CLOCK
/
zs_soft
[
channel
].
clk_divisor
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R12
,
(
brg
&
0xff
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R13
,
((
brg
>>
8
)
&
0xff
));
}
void
__init
zs_init_alloc_failure
(
const
char
*
table_name
)
{
prom_printf
(
"zs_probe: Cannot alloc %s.
\n
"
,
table_name
);
prom_halt
();
}
void
*
__init
zs_alloc_bootmem
(
unsigned
long
size
)
{
void
*
ret
;
ret
=
__alloc_bootmem
(
size
,
SMP_CACHE_BYTES
,
0UL
);
if
(
ret
!=
NULL
)
memset
(
ret
,
0
,
size
);
return
ret
;
}
void
__init
zs_alloc_tables
(
void
)
{
zs_chips
=
(
struct
sun_zslayout
**
)
zs_alloc_bootmem
(
NUM_SERIAL
*
sizeof
(
struct
sun_zslayout
*
));
if
(
zs_chips
==
NULL
)
zs_init_alloc_failure
(
"zs_chips"
);
zs_channels
=
(
struct
sun_zschannel
**
)
zs_alloc_bootmem
(
NUM_CHANNELS
*
sizeof
(
struct
sun_zschannel
*
));
if
(
zs_channels
==
NULL
)
zs_init_alloc_failure
(
"zs_channels"
);
zs_nodes
=
(
int
*
)
zs_alloc_bootmem
(
NUM_SERIAL
*
sizeof
(
int
));
if
(
zs_nodes
==
NULL
)
zs_init_alloc_failure
(
"zs_nodes"
);
zs_soft
=
(
struct
sun_serial
*
)
zs_alloc_bootmem
(
NUM_CHANNELS
*
sizeof
(
struct
sun_serial
));
if
(
zs_soft
==
NULL
)
zs_init_alloc_failure
(
"zs_soft"
);
zs_ttys
=
(
struct
tty_struct
*
)
zs_alloc_bootmem
(
NUM_CHANNELS
*
sizeof
(
struct
tty_struct
));
if
(
zs_ttys
==
NULL
)
zs_init_alloc_failure
(
"zs_ttys"
);
serial_table
=
(
struct
tty_struct
**
)
zs_alloc_bootmem
(
NUM_CHANNELS
*
sizeof
(
struct
tty_struct
*
));
if
(
serial_table
==
NULL
)
zs_init_alloc_failure
(
"serial_table"
);
serial_termios
=
(
struct
termios
**
)
zs_alloc_bootmem
(
NUM_CHANNELS
*
sizeof
(
struct
termios
*
));
if
(
serial_termios
==
NULL
)
zs_init_alloc_failure
(
"serial_termios"
);
serial_termios_locked
=
(
struct
termios
**
)
zs_alloc_bootmem
(
NUM_CHANNELS
*
sizeof
(
struct
termios
*
));
if
(
serial_termios_locked
==
NULL
)
zs_init_alloc_failure
(
"serial_termios_locked"
);
}
int
__init
zs_probe
(
void
)
{
int
node
;
if
(
sparc_cpu_model
==
sun4
)
goto
no_probe
;
NUM_SERIAL
=
0
;
node
=
prom_getchild
(
prom_root_node
);
if
(
sparc_cpu_model
==
sun4d
)
{
int
bbnode
;
while
(
node
&&
(
node
=
prom_searchsiblings
(
node
,
"cpu-unit"
)))
{
bbnode
=
prom_getchild
(
node
);
if
(
bbnode
&&
prom_searchsiblings
(
bbnode
,
"bootbus"
))
NUM_SERIAL
+=
2
;
node
=
prom_getsibling
(
node
);
}
goto
no_probe
;
}
#ifdef __sparc_v9__
else
if
(
sparc_cpu_model
==
sun4u
)
{
int
central_node
;
/* Central bus zilogs must be checked for first,
* since Enterprise boxes might have SBUSes as well.
*/
central_node
=
prom_finddevice
(
"/central"
);
if
(
central_node
!=
0
&&
central_node
!=
-
1
)
node
=
prom_searchsiblings
(
prom_getchild
(
central_node
),
"fhc"
);
else
node
=
prom_searchsiblings
(
node
,
"sbus"
);
if
(
node
!=
0
&&
node
!=
-
1
)
node
=
prom_getchild
(
node
);
if
(
node
==
0
||
node
==
-
1
)
return
-
ENODEV
;
}
#endif
/* __sparc_v9__ */
else
{
node
=
prom_searchsiblings
(
node
,
"obio"
);
if
(
node
)
node
=
prom_getchild
(
node
);
NUM_SERIAL
=
2
;
goto
no_probe
;
}
node
=
prom_searchsiblings
(
node
,
"zs"
);
if
(
!
node
)
return
-
ENODEV
;
NUM_SERIAL
=
2
;
no_probe:
zs_alloc_tables
();
/* Fill in rs_ops struct... */
#ifdef CONFIG_SERIAL_CONSOLE
sunserial_setinitfunc
(
zs_console_init
);
#endif
sunserial_setinitfunc
(
zs_init
);
rs_ops
.
rs_kgdb_hook
=
zs_kgdb_hook
;
rs_ops
.
rs_change_mouse_baud
=
zs_change_mouse_baud
;
sunkbd_setinitfunc
(
sun_kbd_init
);
kbd_ops
.
compute_shiftstate
=
sun_compute_shiftstate
;
kbd_ops
.
setledstate
=
sun_setledstate
;
kbd_ops
.
getledstate
=
sun_getledstate
;
kbd_ops
.
setkeycode
=
sun_setkeycode
;
kbd_ops
.
getkeycode
=
sun_getkeycode
;
#if defined(__sparc_v9__) && defined(CONFIG_PCI)
sunkbd_install_keymaps
(
sun_key_maps
,
sun_keymap_count
,
sun_func_buf
,
sun_func_table
,
sun_funcbufsize
,
sun_funcbufleft
,
sun_accent_table
,
sun_accent_table_size
);
#endif
return
0
;
}
static
inline
void
zs_prepare
(
void
)
{
int
channel
,
chip
;
unsigned
long
flags
;
if
(
!
NUM_SERIAL
)
return
;
save_and_cli
(
flags
);
/* Set up our interrupt linked list */
zs_chain
=
&
zs_soft
[
0
];
for
(
channel
=
0
;
channel
<
NUM_CHANNELS
-
1
;
channel
++
)
{
zs_soft
[
channel
].
zs_next
=
&
zs_soft
[
channel
+
1
];
zs_soft
[
channel
].
line
=
channel
;
}
zs_soft
[
channel
].
zs_next
=
0
;
/* Initialize Softinfo */
for
(
chip
=
0
;
chip
<
NUM_SERIAL
;
chip
++
)
{
/* If we are doing kgdb over one of the channels on
* chip zero, kgdb_channel will be set to 1 by the
* zs_kgdb_hook() routine below.
*/
if
(
!
zs_chips
[
chip
])
{
zs_chips
[
chip
]
=
get_zs
(
chip
);
/* Two channels per chip */
zs_channels
[(
chip
*
2
)]
=
&
zs_chips
[
chip
]
->
channelA
;
zs_channels
[(
chip
*
2
)
+
1
]
=
&
zs_chips
[
chip
]
->
channelB
;
zs_soft
[(
chip
*
2
)].
kgdb_channel
=
0
;
zs_soft
[(
chip
*
2
)
+
1
].
kgdb_channel
=
0
;
}
/* First, set up channel A on this chip. */
channel
=
chip
*
2
;
zs_soft
[
channel
].
zs_channel
=
zs_channels
[
channel
];
zs_soft
[
channel
].
change_needed
=
0
;
zs_soft
[
channel
].
clk_divisor
=
16
;
zs_soft
[
channel
].
cons_keyb
=
0
;
zs_soft
[
channel
].
cons_mouse
=
0
;
zs_soft
[
channel
].
channelA
=
1
;
/* Now, channel B */
channel
++
;
zs_soft
[
channel
].
zs_channel
=
zs_channels
[
channel
];
zs_soft
[
channel
].
change_needed
=
0
;
zs_soft
[
channel
].
clk_divisor
=
16
;
zs_soft
[
channel
].
cons_keyb
=
0
;
zs_soft
[
channel
].
cons_mouse
=
0
;
zs_soft
[
channel
].
channelA
=
0
;
}
restore_flags
(
flags
);
}
int
__init
zs_init
(
void
)
{
int
channel
,
brg
,
i
;
unsigned
long
flags
;
struct
sun_serial
*
info
;
char
dummy
;
/* Setup base handler, and timer table. */
init_bh
(
SERIAL_BH
,
do_serial_bh
);
show_serial_version
();
/* Initialize the tty_driver structure */
/* SPARC: Not all of this is exactly right for us. */
memset
(
&
serial_driver
,
0
,
sizeof
(
struct
tty_driver
));
serial_driver
.
magic
=
TTY_DRIVER_MAGIC
;
serial_driver
.
driver_name
=
"serial"
;
#ifdef CONFIG_DEVFS_FS
serial_driver
.
name
=
"tts/%d"
;
#else
serial_driver
.
name
=
"ttyS"
;
#endif
serial_driver
.
major
=
TTY_MAJOR
;
serial_driver
.
minor_start
=
64
;
serial_driver
.
num
=
NUM_CHANNELS
;
serial_driver
.
type
=
TTY_DRIVER_TYPE_SERIAL
;
serial_driver
.
subtype
=
SERIAL_TYPE_NORMAL
;
serial_driver
.
init_termios
=
tty_std_termios
;
serial_driver
.
init_termios
.
c_cflag
=
B9600
|
CS8
|
CREAD
|
HUPCL
|
CLOCAL
;
serial_driver
.
flags
=
TTY_DRIVER_REAL_RAW
;
serial_driver
.
refcount
=
&
serial_refcount
;
serial_driver
.
table
=
serial_table
;
serial_driver
.
termios
=
serial_termios
;
serial_driver
.
termios_locked
=
serial_termios_locked
;
serial_driver
.
open
=
zs_open
;
serial_driver
.
close
=
zs_close
;
serial_driver
.
write
=
zs_write
;
serial_driver
.
flush_chars
=
zs_flush_chars
;
serial_driver
.
write_room
=
zs_write_room
;
serial_driver
.
chars_in_buffer
=
zs_chars_in_buffer
;
serial_driver
.
flush_buffer
=
zs_flush_buffer
;
serial_driver
.
ioctl
=
zs_ioctl
;
serial_driver
.
throttle
=
zs_throttle
;
serial_driver
.
unthrottle
=
zs_unthrottle
;
serial_driver
.
set_termios
=
zs_set_termios
;
serial_driver
.
stop
=
zs_stop
;
serial_driver
.
start
=
zs_start
;
serial_driver
.
hangup
=
zs_hangup
;
/* I'm too lazy, someone write versions of this for us. -DaveM */
/* I just did. :-) -AIB 2001-12-23 */
serial_driver
.
read_proc
=
zs_read_proc
;
/*
* The callout device is just like normal device except for
* major number and the subtype code.
*/
callout_driver
=
serial_driver
;
callout_driver
.
name
=
"cua/%d"
;
callout_driver
.
major
=
TTYAUX_MAJOR
;
callout_driver
.
subtype
=
SERIAL_TYPE_CALLOUT
;
callout_driver
.
read_proc
=
0
;
callout_driver
.
proc_entry
=
0
;
if
(
tty_register_driver
(
&
serial_driver
))
panic
(
"Couldn't register serial driver
\n
"
);
if
(
tty_register_driver
(
&
callout_driver
))
panic
(
"Couldn't register callout driver
\n
"
);
save_flags
(
flags
);
cli
();
/* Initialize Softinfo */
zs_prepare
();
/* Grab IRQ line before poking the chips so we do
* not lose any interrupts.
*/
if
(
request_irq
(
zilog_irq
,
zs_interrupt
,
SA_SHIRQ
,
"Zilog8530"
,
zs_chain
))
{
prom_printf
(
"Unable to attach zs intr
\n
"
);
prom_halt
();
}
/* Initialize Hardware */
for
(
channel
=
0
;
channel
<
NUM_CHANNELS
;
channel
++
)
{
/* Hardware reset each chip */
if
(
!
(
channel
&
1
))
{
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R9
,
FHWRES
);
ZSDELAY_LONG
();
dummy
=
read_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R0
);
}
if
(
channel
==
KEYBOARD_LINE
)
{
zs_soft
[
channel
].
cons_keyb
=
1
;
zs_soft
[
channel
].
parity_mask
=
0xff
;
zs_kbdchan
=
zs_soft
[
channel
].
zs_channel
;
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R4
,
(
PAR_EVEN
|
X16CLK
|
SB1
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R3
,
Rx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R5
,
Tx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R9
,
NV
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R10
,
NRZ
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R11
,
(
TCBR
|
RCBR
));
zs_soft
[
channel
].
zs_baud
=
1200
;
brg
=
BPS_TO_BRG
(
zs_soft
[
channel
].
zs_baud
,
ZS_CLOCK
/
zs_soft
[
channel
].
clk_divisor
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R12
,
(
brg
&
0xff
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R13
,
((
brg
>>
8
)
&
0xff
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R14
,
BRSRC
);
/* Enable Rx/Tx, IRQs, and inform kbd driver */
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R14
,
(
BRSRC
|
BRENAB
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R3
,
(
Rx8
|
RxENAB
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R5
,
(
Tx8
|
TxENAB
|
DTR
|
RTS
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R15
,
(
DCDIE
|
CTSIE
|
TxUIE
|
BRKIE
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R0
,
RES_EXT_INT
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R0
,
RES_EXT_INT
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R1
,
(
EXT_INT_ENAB
|
INT_ALL_Rx
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R9
,
(
NV
|
MIE
));
ZS_CLEARERR
(
zs_soft
[
channel
].
zs_channel
);
ZS_CLEARFIFO
(
zs_soft
[
channel
].
zs_channel
);
}
else
if
(
channel
==
MOUSE_LINE
)
{
zs_soft
[
channel
].
cons_mouse
=
1
;
zs_soft
[
channel
].
parity_mask
=
0xff
;
zs_mousechan
=
zs_soft
[
channel
].
zs_channel
;
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R4
,
(
PAR_EVEN
|
X16CLK
|
SB1
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R3
,
Rx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R5
,
Tx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R9
,
NV
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R10
,
NRZ
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R11
,
(
TCBR
|
RCBR
));
zs_soft
[
channel
].
zs_baud
=
4800
;
brg
=
BPS_TO_BRG
(
zs_soft
[
channel
].
zs_baud
,
ZS_CLOCK
/
zs_soft
[
channel
].
clk_divisor
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R12
,
(
brg
&
0xff
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R13
,
((
brg
>>
8
)
&
0xff
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R14
,
BRSRC
);
/* Enable Rx, IRQs, and inform mouse driver */
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R14
,
(
BRSRC
|
BRENAB
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R3
,
(
Rx8
|
RxENAB
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R5
,
Tx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R15
,
(
DCDIE
|
CTSIE
|
TxUIE
|
BRKIE
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R0
,
RES_EXT_INT
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R0
,
RES_EXT_INT
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R1
,
(
EXT_INT_ENAB
|
INT_ALL_Rx
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R9
,
(
NV
|
MIE
));
sun_mouse_zsinit
();
}
else
if
(
zs_soft
[
channel
].
is_cons
)
{
brg
=
BPS_TO_BRG
(
zs_soft
[
channel
].
zs_baud
,
ZS_CLOCK
/
zs_soft
[
channel
].
clk_divisor
);
zscons_regs
[
12
]
=
brg
&
0xff
;
zscons_regs
[
13
]
=
(
brg
>>
8
)
&
0xff
;
memcpy
(
zs_soft
[
channel
].
curregs
,
zscons_regs
,
sizeof
(
zscons_regs
));
load_zsregs
(
&
zs_soft
[
channel
],
zscons_regs
);
ZS_CLEARERR
(
zs_soft
[
channel
].
zs_channel
);
ZS_CLEARFIFO
(
zs_soft
[
channel
].
zs_channel
);
}
else
if
(
zs_soft
[
channel
].
kgdb_channel
)
{
/* If this is the kgdb line, enable interrupts because
* we now want to receive the 'control-c' character
* from the client attached to us asynchronously.
*/
zs_soft
[
channel
].
parity_mask
=
0xff
;
kgdb_chaninit
(
&
zs_soft
[
channel
],
1
,
zs_soft
[
channel
].
zs_baud
);
}
else
{
zs_soft
[
channel
].
parity_mask
=
0xff
;
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R4
,
(
PAR_EVEN
|
X16CLK
|
SB1
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R3
,
Rx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R5
,
Tx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R9
,
NV
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R10
,
NRZ
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R11
,
(
RCBR
|
TCBR
));
zs_soft
[
channel
].
zs_baud
=
9600
;
brg
=
BPS_TO_BRG
(
zs_soft
[
channel
].
zs_baud
,
ZS_CLOCK
/
zs_soft
[
channel
].
clk_divisor
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R12
,
(
brg
&
0xff
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R13
,
((
brg
>>
8
)
&
0xff
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R14
,
BRSRC
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R14
,
(
BRSRC
|
BRENAB
));
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R3
,
Rx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R5
,
Tx8
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R15
,
DCDIE
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R9
,
NV
|
MIE
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R0
,
RES_EXT_INT
);
write_zsreg
(
zs_soft
[
channel
].
zs_channel
,
R0
,
RES_EXT_INT
);
}
}
for
(
info
=
zs_chain
,
i
=
0
;
info
;
info
=
info
->
zs_next
,
i
++
)
{
info
->
magic
=
SERIAL_MAGIC
;
info
->
port
=
(
long
)
info
->
zs_channel
;
info
->
line
=
i
;
info
->
tty
=
0
;
info
->
irq
=
zilog_irq
;
info
->
custom_divisor
=
16
;
info
->
close_delay
=
50
;
info
->
closing_wait
=
3000
;
info
->
x_char
=
0
;
info
->
event
=
0
;
info
->
count
=
0
;
info
->
blocked_open
=
0
;
info
->
tqueue
.
routine
=
do_softint
;
info
->
tqueue
.
data
=
info
;
info
->
tqueue_hangup
.
routine
=
do_serial_hangup
;
info
->
tqueue_hangup
.
data
=
info
;
info
->
callout_termios
=
callout_driver
.
init_termios
;
info
->
normal_termios
=
serial_driver
.
init_termios
;
init_waitqueue_head
(
&
info
->
open_wait
);
init_waitqueue_head
(
&
info
->
close_wait
);
printk
(
"tty%02d at 0x%04x (irq = %s)"
,
info
->
line
,
info
->
port
,
__irq_itoa
(
info
->
irq
));
printk
(
" is a Zilog8530
\n
"
);
}
restore_flags
(
flags
);
keyboard_zsinit
(
kbd_put_char
);
return
0
;
}
/* This is called at boot time to prime the kgdb serial debugging
* serial line. The 'tty_num' argument is 0 for /dev/ttya and 1
* for /dev/ttyb which is determined in setup_arch() from the
* boot command line flags.
*/
static
void
__init
zs_kgdb_hook
(
int
tty_num
)
{
int
chip
=
0
;
if
(
!
zs_chips
[
chip
])
{
zs_chips
[
chip
]
=
get_zs
(
chip
);
/* Two channels per chip */
zs_channels
[(
chip
*
2
)]
=
&
zs_chips
[
chip
]
->
channelA
;
zs_channels
[(
chip
*
2
)
+
1
]
=
&
zs_chips
[
chip
]
->
channelB
;
}
zs_soft
[
tty_num
].
zs_channel
=
zs_channels
[
tty_num
];
zs_kgdbchan
=
zs_soft
[
tty_num
].
zs_channel
;
zs_soft
[
tty_num
].
change_needed
=
0
;
zs_soft
[
tty_num
].
clk_divisor
=
16
;
zs_soft
[
tty_num
].
zs_baud
=
9600
;
zs_soft
[
tty_num
].
kgdb_channel
=
1
;
/* This runs kgdb */
zs_soft
[
tty_num
^
1
].
kgdb_channel
=
0
;
/* This does not */
/* Turn on transmitter/receiver at 8-bits/char */
kgdb_chaninit
(
&
zs_soft
[
tty_num
],
0
,
9600
);
ZS_CLEARERR
(
zs_kgdbchan
);
ZS_CLEARFIFO
(
zs_kgdbchan
);
}
#ifdef CONFIG_SERIAL_CONSOLE
/* This is for console output over ttya/ttyb */
static
void
zs_console_putchar
(
struct
sun_serial
*
info
,
char
ch
)
{
int
loops
=
ZS_PUT_CHAR_MAX_DELAY
;
unsigned
long
flags
;
if
(
!
info
->
zs_channel
)
return
;
save_flags
(
flags
);
cli
();
zs_put_char
(
info
->
zs_channel
,
ch
);
while
(
!
(
read_zsreg
(
info
->
zs_channel
,
R1
)
&
ALL_SNT
)
&&
--
loops
)
udelay
(
5
);
restore_flags
(
flags
);
}
#ifdef SERIAL_CONSOLE_FAIR_OUTPUT
/*
* Fair output driver allows a process to speak.
*/
static
void
zs_fair_output
(
struct
sun_serial
*
info
)
{
unsigned
long
flags
;
int
left
;
/* Output no more than that */
char
c
;
if
(
info
==
NULL
)
return
;
if
(
info
->
xmit_buf
==
NULL
)
return
;
save_flags
(
flags
);
cli
();
left
=
info
->
xmit_cnt
;
while
(
left
!=
0
)
{
c
=
info
->
xmit_buf
[
info
->
xmit_tail
];
info
->
xmit_tail
=
(
info
->
xmit_tail
+
1
)
&
(
SERIAL_XMIT_SIZE
-
1
);
info
->
xmit_cnt
--
;
restore_flags
(
flags
);
zs_console_putchar
(
info
,
c
);
cli
();
left
=
MIN
(
info
->
xmit_cnt
,
left
-
1
);
}
/* Last character is being transmitted now (hopefully). */
sbus_writeb
(
RES_Tx_P
,
&
info
->
zs_channel
->
control
);
ZSDELAY
();
ZSLOG
(
REGCTRL
,
RES_Tx_P
,
1
);
restore_flags
(
flags
);
return
;
}
#endif
/*
* zs_console_write is registered for printk.
*/
static
void
zs_console_write
(
struct
console
*
con
,
const
char
*
s
,
unsigned
count
)
{
struct
sun_serial
*
info
;
int
i
;
info
=
zs_soft
+
con
->
index
;
for
(
i
=
0
;
i
<
count
;
i
++
,
s
++
)
{
if
(
*
s
==
'\n'
)
zs_console_putchar
(
info
,
'\r'
);
zs_console_putchar
(
info
,
*
s
);
}
#ifdef SERIAL_CONSOLE_FAIR_OUTPUT
/* Comment this if you want to have a strict interrupt-driven output */
zs_fair_output
(
info
);
#endif
}
static
kdev_t
zs_console_device
(
struct
console
*
con
)
{
return
mk_kdev
(
TTY_MAJOR
,
64
+
con
->
index
);
}
static
int
__init
zs_console_setup
(
struct
console
*
con
,
char
*
options
)
{
static
struct
tty_struct
c_tty
;
static
struct
termios
c_termios
;
struct
sun_serial
*
info
;
int
brg
,
baud
;
info
=
zs_soft
+
con
->
index
;
info
->
is_cons
=
1
;
printk
(
"Console: ttyS%d (Zilog8530)
\n
"
,
info
->
line
);
sunserial_console_termios
(
con
);
memset
(
&
c_tty
,
0
,
sizeof
(
c_tty
));
memset
(
&
c_termios
,
0
,
sizeof
(
c_termios
));
c_tty
.
termios
=
&
c_termios
;
c_termios
.
c_cflag
=
con
->
cflag
;
baud
=
tty_get_baud_rate
(
&
c_tty
);
info
->
zs_baud
=
baud
;
switch
(
con
->
cflag
&
CSIZE
)
{
case
CS5
:
zscons_regs
[
3
]
=
Rx5
|
RxENAB
;
zscons_regs
[
5
]
=
Tx5
|
TxENAB
;
info
->
parity_mask
=
0x1f
;
break
;
case
CS6
:
zscons_regs
[
3
]
=
Rx6
|
RxENAB
;
zscons_regs
[
5
]
=
Tx6
|
TxENAB
;
info
->
parity_mask
=
0x3f
;
break
;
case
CS7
:
zscons_regs
[
3
]
=
Rx7
|
RxENAB
;
zscons_regs
[
5
]
=
Tx7
|
TxENAB
;
info
->
parity_mask
=
0x7f
;
break
;
default:
case
CS8
:
zscons_regs
[
3
]
=
Rx8
|
RxENAB
;
zscons_regs
[
5
]
=
Tx8
|
TxENAB
;
info
->
parity_mask
=
0xff
;
break
;
}
zscons_regs
[
5
]
|=
DTR
;
if
(
con
->
cflag
&
PARENB
)
zscons_regs
[
4
]
|=
PAR_ENAB
;
if
(
!
(
con
->
cflag
&
PARODD
))
zscons_regs
[
4
]
|=
PAR_EVEN
;
if
(
con
->
cflag
&
CSTOPB
)
zscons_regs
[
4
]
|=
SB2
;
else
zscons_regs
[
4
]
|=
SB1
;
brg
=
BPS_TO_BRG
(
baud
,
ZS_CLOCK
/
info
->
clk_divisor
);
zscons_regs
[
12
]
=
brg
&
0xff
;
zscons_regs
[
13
]
=
(
brg
>>
8
)
&
0xff
;
memcpy
(
info
->
curregs
,
zscons_regs
,
sizeof
(
zscons_regs
));
load_zsregs
(
info
,
zscons_regs
);
ZS_CLEARERR
(
info
->
zs_channel
);
ZS_CLEARFIFO
(
info
->
zs_channel
);
return
0
;
}
static
struct
console
zs_console
=
{
.
name
=
"ttyS"
,
.
write
=
zs_console_write
,
.
device
=
zs_console_device
,
.
setup
=
zs_console_setup
,
.
flags
=
CON_PRINTBUFFER
,
.
index
=
-
1
,
};
static
int
__init
zs_console_init
(
void
)
{
extern
int
con_is_present
(
void
);
if
(
con_is_present
())
return
0
;
zs_console
.
index
=
serial_console
-
1
;
register_console
(
&
zs_console
);
return
0
;
}
#endif
/* CONFIG_SERIAL_CONSOLE */
drivers/sbus/char/zs.h
deleted
100644 → 0
View file @
aa2a3d64
/* $Id: zs.h,v 1.3 1999/09/21 14:38:18 davem Exp $
* zs.h: Definitions for the Sparc Zilog serial driver.
*
* Copyright (C) 1995 David S. Miller (davem@caip.rutgers.edu)
* Copyright (C) 1996 Eddie C. Dost (ecd@skynet.be)
*/
#ifndef _ZS_H
#define _ZS_H
/* Just one channel */
struct
sun_zschannel
{
volatile
unsigned
char
control
;
volatile
unsigned
char
pad1
;
volatile
unsigned
char
data
;
volatile
unsigned
char
pad2
;
};
/* The address space layout for each zs chip. Yes they are
* backwards.
*/
struct
sun_zslayout
{
struct
sun_zschannel
channelB
;
struct
sun_zschannel
channelA
;
};
#define NUM_ZSREGS 16
struct
serial_struct
{
int
type
;
int
line
;
int
port
;
int
irq
;
int
flags
;
int
xmit_fifo_size
;
int
custom_divisor
;
int
baud_base
;
unsigned
short
close_delay
;
char
reserved_char
[
2
];
int
hub6
;
unsigned
short
closing_wait
;
/* time to wait before closing */
unsigned
short
closing_wait2
;
/* no longer used... */
int
reserved
[
4
];
};
/*
* For the close wait times, 0 means wait forever for serial port to
* flush its output. 65535 means don't wait at all.
*/
#define ZILOG_CLOSING_WAIT_INF 0
#define ZILOG_CLOSING_WAIT_NONE 65535
/*
* Definitions for ZILOG_struct (and serial_struct) flags field
*/
#define ZILOG_HUP_NOTIFY 0x0001
/* Notify getty on hangups and closes
on the callout port */
#define ZILOG_FOURPORT 0x0002
/* Set OU1, OUT2 per AST Fourport settings */
#define ZILOG_SAK 0x0004
/* Secure Attention Key (Orange book) */
#define ZILOG_SPLIT_TERMIOS 0x0008
/* Separate termios for dialin/callout */
#define ZILOG_SPD_MASK 0x0030
#define ZILOG_SPD_HI 0x0010
/* Use 76800 instead of 38400 bps */
#define ZILOG_SPD_CUST 0x0030
/* Use user-specified divisor */
#define ZILOG_SKIP_TEST 0x0040
/* Skip UART test during autoconfiguration */
#define ZILOG_AUTO_IRQ 0x0080
/* Do automatic IRQ during autoconfiguration */
#define ZILOG_SESSION_LOCKOUT 0x0100
/* Lock out cua opens based on session */
#define ZILOG_PGRP_LOCKOUT 0x0200
/* Lock out cua opens based on pgrp */
#define ZILOG_CALLOUT_NOHUP 0x0400
/* Don't do hangups for cua device */
#define ZILOG_FLAGS 0x0FFF
/* Possible legal ZILOG flags */
#define ZILOG_USR_MASK 0x0430
/* Legal flags that non-privileged
* users can set or reset */
/* Internal flags used only by kernel/chr_drv/serial.c */
#define ZILOG_INITIALIZED 0x80000000
/* Serial port was initialized */
#define ZILOG_CALLOUT_ACTIVE 0x40000000
/* Call out device is active */
#define ZILOG_NORMAL_ACTIVE 0x20000000
/* Normal device is active */
#define ZILOG_BOOT_AUTOCONF 0x10000000
/* Autoconfigure port on bootup */
#define ZILOG_CLOSING 0x08000000
/* Serial port is closing */
#define ZILOG_CTS_FLOW 0x04000000
/* Do CTS flow control */
#define ZILOG_CHECK_CD 0x02000000
/* i.e., CLOCAL */
/* Software state per channel */
#ifdef __KERNEL__
/*
* This is our internal structure for each serial port's state.
*
* Many fields are paralleled by the structure used by the serial_struct
* structure.
*
* For definitions of the flags field, see tty.h
*/
struct
sun_serial
{
struct
sun_serial
*
zs_next
;
/* For IRQ servicing chain */
struct
sun_zschannel
*
zs_channel
;
/* Channel registers */
unsigned
char
read_reg_zero
;
char
soft_carrier
;
/* Use soft carrier on this channel */
char
cons_keyb
;
/* Channel runs the keyboard */
char
cons_mouse
;
/* Channel runs the mouse */
char
break_abort
;
/* Is serial console in, so process brk/abrt */
char
kgdb_channel
;
/* Kgdb is running on this channel */
char
is_cons
;
/* Is this our console. */
char
channelA
;
/* This is channel A. */
char
parity_mask
;
/* Mask out parity bits in data register. */
/* We need to know the current clock divisor
* to read the bps rate the chip has currently
* loaded.
*/
unsigned
char
clk_divisor
;
/* May be 1, 16, 32, or 64 */
int
zs_baud
;
/* Current write register values */
unsigned
char
curregs
[
NUM_ZSREGS
];
char
change_needed
;
int
magic
;
int
baud_base
;
int
port
;
int
irq
;
int
flags
;
/* defined in tty.h */
int
type
;
/* UART type */
struct
tty_struct
*
tty
;
int
read_status_mask
;
int
ignore_status_mask
;
int
timeout
;
int
xmit_fifo_size
;
int
custom_divisor
;
int
x_char
;
/* xon/xoff character */
int
close_delay
;
unsigned
short
closing_wait
;
unsigned
short
closing_wait2
;
unsigned
long
event
;
unsigned
long
last_active
;
int
line
;
int
count
;
/* # of fd on device */
int
blocked_open
;
/* # of blocked opens */
long
session
;
/* Session of opening process */
long
pgrp
;
/* pgrp of opening process */
unsigned
char
*
xmit_buf
;
int
xmit_head
;
int
xmit_tail
;
int
xmit_cnt
;
struct
tq_struct
tqueue
;
struct
tq_struct
tqueue_hangup
;
struct
termios
normal_termios
;
struct
termios
callout_termios
;
wait_queue_head_t
open_wait
;
wait_queue_head_t
close_wait
;
};
#define SERIAL_MAGIC 0x5301
/*
* The size of the serial xmit buffer is 1 page, or 4096 bytes
*/
#define SERIAL_XMIT_SIZE 4096
/*
* Events are used to schedule things to happen at timer-interrupt
* time, instead of at rs interrupt time.
*/
#define RS_EVENT_WRITE_WAKEUP 0
#endif
/* __KERNEL__ */
/* Conversion routines to/from brg time constants from/to bits
* per second.
*/
#define BRG_TO_BPS(brg, freq) ((freq) / 2 / ((brg) + 2))
#define BPS_TO_BRG(bps, freq) ((((freq) + (bps)) / (2 * (bps))) - 2)
/* The Zilog register set */
#define FLAG 0x7e
/* Write Register 0 */
#define R0 0
/* Register selects */
#define R1 1
#define R2 2
#define R3 3
#define R4 4
#define R5 5
#define R6 6
#define R7 7
#define R8 8
#define R9 9
#define R10 10
#define R11 11
#define R12 12
#define R13 13
#define R14 14
#define R15 15
#define NULLCODE 0
/* Null Code */
#define POINT_HIGH 0x8
/* Select upper half of registers */
#define RES_EXT_INT 0x10
/* Reset Ext. Status Interrupts */
#define SEND_ABORT 0x18
/* HDLC Abort */
#define RES_RxINT_FC 0x20
/* Reset RxINT on First Character */
#define RES_Tx_P 0x28
/* Reset TxINT Pending */
#define ERR_RES 0x30
/* Error Reset */
#define RES_H_IUS 0x38
/* Reset highest IUS */
#define RES_Rx_CRC 0x40
/* Reset Rx CRC Checker */
#define RES_Tx_CRC 0x80
/* Reset Tx CRC Checker */
#define RES_EOM_L 0xC0
/* Reset EOM latch */
/* Write Register 1 */
#define EXT_INT_ENAB 0x1
/* Ext Int Enable */
#define TxINT_ENAB 0x2
/* Tx Int Enable */
#define PAR_SPEC 0x4
/* Parity is special condition */
#define RxINT_DISAB 0
/* Rx Int Disable */
#define RxINT_FCERR 0x8
/* Rx Int on First Character Only or Error */
#define INT_ALL_Rx 0x10
/* Int on all Rx Characters or error */
#define INT_ERR_Rx 0x18
/* Int on error only */
#define RxINT_MASK 0x18
#define WT_RDY_RT 0x20
/* Wait/Ready on R/T */
#define WT_FN_RDYFN 0x40
/* Wait/FN/Ready FN */
#define WT_RDY_ENAB 0x80
/* Wait/Ready Enable */
/* Write Register #2 (Interrupt Vector) */
/* Write Register 3 */
#define RxENAB 0x1
/* Rx Enable */
#define SYNC_L_INH 0x2
/* Sync Character Load Inhibit */
#define ADD_SM 0x4
/* Address Search Mode (SDLC) */
#define RxCRC_ENAB 0x8
/* Rx CRC Enable */
#define ENT_HM 0x10
/* Enter Hunt Mode */
#define AUTO_ENAB 0x20
/* Auto Enables */
#define Rx5 0x0
/* Rx 5 Bits/Character */
#define Rx7 0x40
/* Rx 7 Bits/Character */
#define Rx6 0x80
/* Rx 6 Bits/Character */
#define Rx8 0xc0
/* Rx 8 Bits/Character */
#define RxN_MASK 0xc0
/* Write Register 4 */
#define PAR_ENAB 0x1
/* Parity Enable */
#define PAR_EVEN 0x2
/* Parity Even/Odd* */
#define SYNC_ENAB 0
/* Sync Modes Enable */
#define SB1 0x4
/* 1 stop bit/char */
#define SB15 0x8
/* 1.5 stop bits/char */
#define SB2 0xc
/* 2 stop bits/char */
#define MONSYNC 0
/* 8 Bit Sync character */
#define BISYNC 0x10
/* 16 bit sync character */
#define SDLC 0x20
/* SDLC Mode (01111110 Sync Flag) */
#define EXTSYNC 0x30
/* External Sync Mode */
#define X1CLK 0x0
/* x1 clock mode */
#define X16CLK 0x40
/* x16 clock mode */
#define X32CLK 0x80
/* x32 clock mode */
#define X64CLK 0xC0
/* x64 clock mode */
/* Write Register 5 */
#define TxCRC_ENAB 0x1
/* Tx CRC Enable */
#define RTS 0x2
/* RTS */
#define SDLC_CRC 0x4
/* SDLC/CRC-16 */
#define TxENAB 0x8
/* Tx Enable */
#define SND_BRK 0x10
/* Send Break */
#define Tx5 0x0
/* Tx 5 bits (or less)/character */
#define Tx7 0x20
/* Tx 7 bits/character */
#define Tx6 0x40
/* Tx 6 bits/character */
#define Tx8 0x60
/* Tx 8 bits/character */
#define TxN_MASK 0x60
#define DTR 0x80
/* DTR */
/* Write Register 6 (Sync bits 0-7/SDLC Address Field) */
/* Write Register 7 (Sync bits 8-15/SDLC 01111110) */
/* Write Register 8 (transmit buffer) */
/* Write Register 9 (Master interrupt control) */
#define VIS 1
/* Vector Includes Status */
#define NV 2
/* No Vector */
#define DLC 4
/* Disable Lower Chain */
#define MIE 8
/* Master Interrupt Enable */
#define STATHI 0x10
/* Status high */
#define NORESET 0
/* No reset on write to R9 */
#define CHRB 0x40
/* Reset channel B */
#define CHRA 0x80
/* Reset channel A */
#define FHWRES 0xc0
/* Force hardware reset */
/* Write Register 10 (misc control bits) */
#define BIT6 1
/* 6 bit/8bit sync */
#define LOOPMODE 2
/* SDLC Loop mode */
#define ABUNDER 4
/* Abort/flag on SDLC xmit underrun */
#define MARKIDLE 8
/* Mark/flag on idle */
#define GAOP 0x10
/* Go active on poll */
#define NRZ 0
/* NRZ mode */
#define NRZI 0x20
/* NRZI mode */
#define FM1 0x40
/* FM1 (transition = 1) */
#define FM0 0x60
/* FM0 (transition = 0) */
#define CRCPS 0x80
/* CRC Preset I/O */
/* Write Register 11 (Clock Mode control) */
#define TRxCXT 0
/* TRxC = Xtal output */
#define TRxCTC 1
/* TRxC = Transmit clock */
#define TRxCBR 2
/* TRxC = BR Generator Output */
#define TRxCDP 3
/* TRxC = DPLL output */
#define TRxCOI 4
/* TRxC O/I */
#define TCRTxCP 0
/* Transmit clock = RTxC pin */
#define TCTRxCP 8
/* Transmit clock = TRxC pin */
#define TCBR 0x10
/* Transmit clock = BR Generator output */
#define TCDPLL 0x18
/* Transmit clock = DPLL output */
#define RCRTxCP 0
/* Receive clock = RTxC pin */
#define RCTRxCP 0x20
/* Receive clock = TRxC pin */
#define RCBR 0x40
/* Receive clock = BR Generator output */
#define RCDPLL 0x60
/* Receive clock = DPLL output */
#define RTxCX 0x80
/* RTxC Xtal/No Xtal */
/* Write Register 12 (lower byte of baud rate generator time constant) */
/* Write Register 13 (upper byte of baud rate generator time constant) */
/* Write Register 14 (Misc control bits) */
#define BRENAB 1
/* Baud rate generator enable */
#define BRSRC 2
/* Baud rate generator source */
#define DTRREQ 4
/* DTR/Request function */
#define AUTOECHO 8
/* Auto Echo */
#define LOOPBAK 0x10
/* Local loopback */
#define SEARCH 0x20
/* Enter search mode */
#define RMC 0x40
/* Reset missing clock */
#define DISDPLL 0x60
/* Disable DPLL */
#define SSBR 0x80
/* Set DPLL source = BR generator */
#define SSRTxC 0xa0
/* Set DPLL source = RTxC */
#define SFMM 0xc0
/* Set FM mode */
#define SNRZI 0xe0
/* Set NRZI mode */
/* Write Register 15 (external/status interrupt control) */
#define ZCIE 2
/* Zero count IE */
#define DCDIE 8
/* DCD IE */
#define SYNCIE 0x10
/* Sync/hunt IE */
#define CTSIE 0x20
/* CTS IE */
#define TxUIE 0x40
/* Tx Underrun/EOM IE */
#define BRKIE 0x80
/* Break/Abort IE */
/* Read Register 0 */
#define Rx_CH_AV 0x1
/* Rx Character Available */
#define ZCOUNT 0x2
/* Zero count */
#define Tx_BUF_EMP 0x4
/* Tx Buffer empty */
#define DCD 0x8
/* DCD */
#define SYNC 0x10
/* Sync/hunt */
#define CTS 0x20
/* CTS */
#define TxEOM 0x40
/* Tx underrun */
#define BRK_ABRT 0x80
/* Break/Abort */
/* Read Register 1 */
#define ALL_SNT 0x1
/* All sent */
/* Residue Data for 8 Rx bits/char programmed */
#define RES3 0x8
/* 0/3 */
#define RES4 0x4
/* 0/4 */
#define RES5 0xc
/* 0/5 */
#define RES6 0x2
/* 0/6 */
#define RES7 0xa
/* 0/7 */
#define RES8 0x6
/* 0/8 */
#define RES18 0xe
/* 1/8 */
#define RES28 0x0
/* 2/8 */
/* Special Rx Condition Interrupts */
#define PAR_ERR 0x10
/* Parity error */
#define Rx_OVR 0x20
/* Rx Overrun Error */
#define CRC_ERR 0x40
/* CRC/Framing Error */
#define END_FR 0x80
/* End of Frame (SDLC) */
/* Read Register 2 (channel b only) - Interrupt vector */
#define CHB_Tx_EMPTY 0x00
#define CHB_EXT_STAT 0x02
#define CHB_Rx_AVAIL 0x04
#define CHB_SPECIAL 0x06
#define CHA_Tx_EMPTY 0x08
#define CHA_EXT_STAT 0x0a
#define CHA_Rx_AVAIL 0x0c
#define CHA_SPECIAL 0x0e
#define STATUS_MASK 0x0e
/* Read Register 3 (interrupt pending register) ch a only */
#define CHBEXT 0x1
/* Channel B Ext/Stat IP */
#define CHBTxIP 0x2
/* Channel B Tx IP */
#define CHBRxIP 0x4
/* Channel B Rx IP */
#define CHAEXT 0x8
/* Channel A Ext/Stat IP */
#define CHATxIP 0x10
/* Channel A Tx IP */
#define CHARxIP 0x20
/* Channel A Rx IP */
/* Read Register 8 (receive data register) */
/* Read Register 10 (misc status bits) */
#define ONLOOP 2
/* On loop */
#define LOOPSEND 0x10
/* Loop sending */
#define CLK2MIS 0x40
/* Two clocks missing */
#define CLK1MIS 0x80
/* One clock missing */
/* Read Register 12 (lower byte of baud rate generator constant) */
/* Read Register 13 (upper byte of baud rate generator constant) */
/* Read Register 15 (value of WR 15) */
/* Misc macros */
#define ZS_CLEARERR(channel) do { sbus_writeb(ERR_RES, &channel->control); \
udelay(5); } while(0)
#define ZS_CLEARSTAT(channel) do { sbus_writeb(RES_EXT_INT, &channel->control); \
udelay(5); } while(0)
#define ZS_CLEARFIFO(channel) do { sbus_readb(&channel->data); \
udelay(2); \
sbus_readb(&channel->data); \
udelay(2); \
sbus_readb(&channel->data); \
udelay(2); } while(0)
#endif
/* !(_ZS_H) */
drivers/s
bus/char
/sunkbd.c
→
drivers/s
erial
/sunkbd.c
View file @
d4d9c3ac
File moved
drivers/s
bus/char
/sunkbd.h
→
drivers/s
erial
/sunkbd.h
View file @
d4d9c3ac
File moved
drivers/s
bus/char
/sunmouse.c
→
drivers/s
erial
/sunmouse.c
View file @
d4d9c3ac
File moved
drivers/s
bus/char
/sunmouse.h
→
drivers/s
erial
/sunmouse.h
View file @
d4d9c3ac
File moved
drivers/s
bus/char/sab82532
.c
→
drivers/s
erial/sunsab
.c
View file @
d4d9c3ac
File moved
drivers/s
bus/char/
su.c
→
drivers/s
erial/sun
su.c
View file @
d4d9c3ac
File moved
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