kernel-aes67/drivers/char/istallion.c

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/*****************************************************************************/
/*
* istallion.c -- stallion intelligent multiport serial driver.
*
* Copyright (C) 1996-1999 Stallion Technologies
* Copyright (C) 1994-1996 Greg Ungerer.
*
* This code is loosely based on the Linux serial driver, written by
* Linus Torvalds, Theodore T'so and others.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
/*****************************************************************************/
#include <linux/module.h>
#include <linux/slab.h>
#include <linux/interrupt.h>
#include <linux/tty.h>
#include <linux/tty_flip.h>
#include <linux/serial.h>
#include <linux/cdk.h>
#include <linux/comstats.h>
#include <linux/istallion.h>
#include <linux/ioport.h>
#include <linux/delay.h>
#include <linux/init.h>
#include <linux/device.h>
#include <linux/wait.h>
#include <linux/eisa.h>
#include <asm/io.h>
#include <asm/uaccess.h>
#include <linux/pci.h>
/*****************************************************************************/
/*
* Define different board types. Not all of the following board types
* are supported by this driver. But I will use the standard "assigned"
* board numbers. Currently supported boards are abbreviated as:
* ECP = EasyConnection 8/64, ONB = ONboard, BBY = Brumby and
* STAL = Stallion.
*/
#define BRD_UNKNOWN 0
#define BRD_STALLION 1
#define BRD_BRUMBY4 2
#define BRD_ONBOARD2 3
#define BRD_ONBOARD 4
#define BRD_BRUMBY8 5
#define BRD_BRUMBY16 6
#define BRD_ONBOARDE 7
#define BRD_ONBOARD32 9
#define BRD_ONBOARD2_32 10
#define BRD_ONBOARDRS 11
#define BRD_EASYIO 20
#define BRD_ECH 21
#define BRD_ECHMC 22
#define BRD_ECP 23
#define BRD_ECPE 24
#define BRD_ECPMC 25
#define BRD_ECHPCI 26
#define BRD_ECH64PCI 27
#define BRD_EASYIOPCI 28
#define BRD_ECPPCI 29
#define BRD_BRUMBY BRD_BRUMBY4
/*
* Define a configuration structure to hold the board configuration.
* Need to set this up in the code (for now) with the boards that are
* to be configured into the system. This is what needs to be modified
* when adding/removing/modifying boards. Each line entry in the
* stli_brdconf[] array is a board. Each line contains io/irq/memory
* ranges for that board (as well as what type of board it is).
* Some examples:
* { BRD_ECP, 0x2a0, 0, 0xcc000, 0, 0 },
* This line will configure an EasyConnection 8/64 at io address 2a0,
* and shared memory address of cc000. Multiple EasyConnection 8/64
* boards can share the same shared memory address space. No interrupt
* is required for this board type.
* Another example:
* { BRD_ECPE, 0x5000, 0, 0x80000000, 0, 0 },
* This line will configure an EasyConnection 8/64 EISA in slot 5 and
* shared memory address of 0x80000000 (2 GByte). Multiple
* EasyConnection 8/64 EISA boards can share the same shared memory
* address space. No interrupt is required for this board type.
* Another example:
* { BRD_ONBOARD, 0x240, 0, 0xd0000, 0, 0 },
* This line will configure an ONboard (ISA type) at io address 240,
* and shared memory address of d0000. Multiple ONboards can share
* the same shared memory address space. No interrupt required.
* Another example:
* { BRD_BRUMBY4, 0x360, 0, 0xc8000, 0, 0 },
* This line will configure a Brumby board (any number of ports!) at
* io address 360 and shared memory address of c8000. All Brumby boards
* configured into a system must have their own separate io and memory
* addresses. No interrupt is required.
* Another example:
* { BRD_STALLION, 0x330, 0, 0xd0000, 0, 0 },
* This line will configure an original Stallion board at io address 330
* and shared memory address d0000 (this would only be valid for a "V4.0"
* or Rev.O Stallion board). All Stallion boards configured into the
* system must have their own separate io and memory addresses. No
* interrupt is required.
*/
typedef struct {
int brdtype;
int ioaddr1;
int ioaddr2;
unsigned long memaddr;
int irq;
int irqtype;
} stlconf_t;
static stlconf_t stli_brdconf[] = {
/*{ BRD_ECP, 0x2a0, 0, 0xcc000, 0, 0 },*/
};
static int stli_nrbrds = ARRAY_SIZE(stli_brdconf);
/* stli_lock must NOT be taken holding brd_lock */
static spinlock_t stli_lock; /* TTY logic lock */
static spinlock_t brd_lock; /* Board logic lock */
/*
* There is some experimental EISA board detection code in this driver.
* By default it is disabled, but for those that want to try it out,
* then set the define below to be 1.
*/
#define STLI_EISAPROBE 0
/*****************************************************************************/
/*
* Define some important driver characteristics. Device major numbers
* allocated as per Linux Device Registry.
*/
#ifndef STL_SIOMEMMAJOR
#define STL_SIOMEMMAJOR 28
#endif
#ifndef STL_SERIALMAJOR
#define STL_SERIALMAJOR 24
#endif
#ifndef STL_CALLOUTMAJOR
#define STL_CALLOUTMAJOR 25
#endif
/*****************************************************************************/
/*
* Define our local driver identity first. Set up stuff to deal with
* all the local structures required by a serial tty driver.
*/
static char *stli_drvtitle = "Stallion Intelligent Multiport Serial Driver";
static char *stli_drvname = "istallion";
static char *stli_drvversion = "5.6.0";
static char *stli_serialname = "ttyE";
static struct tty_driver *stli_serial;
#define STLI_TXBUFSIZE 4096
/*
* Use a fast local buffer for cooked characters. Typically a whole
* bunch of cooked characters come in for a port, 1 at a time. So we
* save those up into a local buffer, then write out the whole lot
* with a large memcpy. Just use 1 buffer for all ports, since its
* use it is only need for short periods of time by each port.
*/
static char *stli_txcookbuf;
static int stli_txcooksize;
static int stli_txcookrealsize;
static struct tty_struct *stli_txcooktty;
/*
* Define a local default termios struct. All ports will be created
* with this termios initially. Basically all it defines is a raw port
* at 9600 baud, 8 data bits, no parity, 1 stop bit.
*/
static struct termios stli_deftermios = {
.c_cflag = (B9600 | CS8 | CREAD | HUPCL | CLOCAL),
.c_cc = INIT_C_CC,
};
/*
* Define global stats structures. Not used often, and can be
* re-used for each stats call.
*/
static comstats_t stli_comstats;
static combrd_t stli_brdstats;
static asystats_t stli_cdkstats;
static stlibrd_t stli_dummybrd;
static stliport_t stli_dummyport;
/*****************************************************************************/
static stlibrd_t *stli_brds[STL_MAXBRDS];
static int stli_shared;
/*
* Per board state flags. Used with the state field of the board struct.
* Not really much here... All we need to do is keep track of whether
* the board has been detected, and whether it is actually running a slave
* or not.
*/
#define BST_FOUND 0x1
#define BST_STARTED 0x2
/*
* Define the set of port state flags. These are marked for internal
* state purposes only, usually to do with the state of communications
* with the slave. Most of them need to be updated atomically, so always
* use the bit setting operations (unless protected by cli/sti).
*/
#define ST_INITIALIZING 1
#define ST_OPENING 2
#define ST_CLOSING 3
#define ST_CMDING 4
#define ST_TXBUSY 5
#define ST_RXING 6
#define ST_DOFLUSHRX 7
#define ST_DOFLUSHTX 8
#define ST_DOSIGS 9
#define ST_RXSTOP 10
#define ST_GETSIGS 11
/*
* Define an array of board names as printable strings. Handy for
* referencing boards when printing trace and stuff.
*/
static char *stli_brdnames[] = {
"Unknown",
"Stallion",
"Brumby",
"ONboard-MC",
"ONboard",
"Brumby",
"Brumby",
"ONboard-EI",
(char *) NULL,
"ONboard",
"ONboard-MC",
"ONboard-MC",
(char *) NULL,
(char *) NULL,
(char *) NULL,
(char *) NULL,
(char *) NULL,
(char *) NULL,
(char *) NULL,
(char *) NULL,
"EasyIO",
"EC8/32-AT",
"EC8/32-MC",
"EC8/64-AT",
"EC8/64-EI",
"EC8/64-MC",
"EC8/32-PCI",
"EC8/64-PCI",
"EasyIO-PCI",
"EC/RA-PCI",
};
/*****************************************************************************/
/*
* Define some string labels for arguments passed from the module
* load line. These allow for easy board definitions, and easy
* modification of the io, memory and irq resoucres.
*/
static char *board0[8];
static char *board1[8];
static char *board2[8];
static char *board3[8];
static char **stli_brdsp[] = {
(char **) &board0,
(char **) &board1,
(char **) &board2,
(char **) &board3
};
/*
* Define a set of common board names, and types. This is used to
* parse any module arguments.
*/
typedef struct stlibrdtype {
char *name;
int type;
} stlibrdtype_t;
static stlibrdtype_t stli_brdstr[] = {
{ "stallion", BRD_STALLION },
{ "1", BRD_STALLION },
{ "brumby", BRD_BRUMBY },
{ "brumby4", BRD_BRUMBY },
{ "brumby/4", BRD_BRUMBY },
{ "brumby-4", BRD_BRUMBY },
{ "brumby8", BRD_BRUMBY },
{ "brumby/8", BRD_BRUMBY },
{ "brumby-8", BRD_BRUMBY },
{ "brumby16", BRD_BRUMBY },
{ "brumby/16", BRD_BRUMBY },
{ "brumby-16", BRD_BRUMBY },
{ "2", BRD_BRUMBY },
{ "onboard2", BRD_ONBOARD2 },
{ "onboard-2", BRD_ONBOARD2 },
{ "onboard/2", BRD_ONBOARD2 },
{ "onboard-mc", BRD_ONBOARD2 },
{ "onboard/mc", BRD_ONBOARD2 },
{ "onboard-mca", BRD_ONBOARD2 },
{ "onboard/mca", BRD_ONBOARD2 },
{ "3", BRD_ONBOARD2 },
{ "onboard", BRD_ONBOARD },
{ "onboardat", BRD_ONBOARD },
{ "4", BRD_ONBOARD },
{ "onboarde", BRD_ONBOARDE },
{ "onboard-e", BRD_ONBOARDE },
{ "onboard/e", BRD_ONBOARDE },
{ "onboard-ei", BRD_ONBOARDE },
{ "onboard/ei", BRD_ONBOARDE },
{ "7", BRD_ONBOARDE },
{ "ecp", BRD_ECP },
{ "ecpat", BRD_ECP },
{ "ec8/64", BRD_ECP },
{ "ec8/64-at", BRD_ECP },
{ "ec8/64-isa", BRD_ECP },
{ "23", BRD_ECP },
{ "ecpe", BRD_ECPE },
{ "ecpei", BRD_ECPE },
{ "ec8/64-e", BRD_ECPE },
{ "ec8/64-ei", BRD_ECPE },
{ "24", BRD_ECPE },
{ "ecpmc", BRD_ECPMC },
{ "ec8/64-mc", BRD_ECPMC },
{ "ec8/64-mca", BRD_ECPMC },
{ "25", BRD_ECPMC },
{ "ecppci", BRD_ECPPCI },
{ "ec/ra", BRD_ECPPCI },
{ "ec/ra-pc", BRD_ECPPCI },
{ "ec/ra-pci", BRD_ECPPCI },
{ "29", BRD_ECPPCI },
};
/*
* Define the module agruments.
*/
MODULE_AUTHOR("Greg Ungerer");
MODULE_DESCRIPTION("Stallion Intelligent Multiport Serial Driver");
MODULE_LICENSE("GPL");
module_param_array(board0, charp, NULL, 0);
MODULE_PARM_DESC(board0, "Board 0 config -> name[,ioaddr[,memaddr]");
module_param_array(board1, charp, NULL, 0);
MODULE_PARM_DESC(board1, "Board 1 config -> name[,ioaddr[,memaddr]");
module_param_array(board2, charp, NULL, 0);
MODULE_PARM_DESC(board2, "Board 2 config -> name[,ioaddr[,memaddr]");
module_param_array(board3, charp, NULL, 0);
MODULE_PARM_DESC(board3, "Board 3 config -> name[,ioaddr[,memaddr]");
/*
* Set up a default memory address table for EISA board probing.
* The default addresses are all bellow 1Mbyte, which has to be the
* case anyway. They should be safe, since we only read values from
* them, and interrupts are disabled while we do it. If the higher
* memory support is compiled in then we also try probing around
* the 1Gb, 2Gb and 3Gb areas as well...
*/
static unsigned long stli_eisamemprobeaddrs[] = {
0xc0000, 0xd0000, 0xe0000, 0xf0000,
0x80000000, 0x80010000, 0x80020000, 0x80030000,
0x40000000, 0x40010000, 0x40020000, 0x40030000,
0xc0000000, 0xc0010000, 0xc0020000, 0xc0030000,
0xff000000, 0xff010000, 0xff020000, 0xff030000,
};
static int stli_eisamempsize = ARRAY_SIZE(stli_eisamemprobeaddrs);
/*
* Define the Stallion PCI vendor and device IDs.
*/
#ifdef CONFIG_PCI
#ifndef PCI_VENDOR_ID_STALLION
#define PCI_VENDOR_ID_STALLION 0x124d
#endif
#ifndef PCI_DEVICE_ID_ECRA
#define PCI_DEVICE_ID_ECRA 0x0004
#endif
static struct pci_device_id istallion_pci_tbl[] = {
{ PCI_DEVICE(PCI_VENDOR_ID_STALLION, PCI_DEVICE_ID_ECRA), },
{ 0 }
};
MODULE_DEVICE_TABLE(pci, istallion_pci_tbl);
#endif /* CONFIG_PCI */
/*****************************************************************************/
/*
* Hardware configuration info for ECP boards. These defines apply
* to the directly accessible io ports of the ECP. There is a set of
* defines for each ECP board type, ISA, EISA, MCA and PCI.
*/
#define ECP_IOSIZE 4
#define ECP_MEMSIZE (128 * 1024)
#define ECP_PCIMEMSIZE (256 * 1024)
#define ECP_ATPAGESIZE (4 * 1024)
#define ECP_MCPAGESIZE (4 * 1024)
#define ECP_EIPAGESIZE (64 * 1024)
#define ECP_PCIPAGESIZE (64 * 1024)
#define STL_EISAID 0x8c4e
/*
* Important defines for the ISA class of ECP board.
*/
#define ECP_ATIREG 0
#define ECP_ATCONFR 1
#define ECP_ATMEMAR 2
#define ECP_ATMEMPR 3
#define ECP_ATSTOP 0x1
#define ECP_ATINTENAB 0x10
#define ECP_ATENABLE 0x20
#define ECP_ATDISABLE 0x00
#define ECP_ATADDRMASK 0x3f000
#define ECP_ATADDRSHFT 12
/*
* Important defines for the EISA class of ECP board.
*/
#define ECP_EIIREG 0
#define ECP_EIMEMARL 1
#define ECP_EICONFR 2
#define ECP_EIMEMARH 3
#define ECP_EIENABLE 0x1
#define ECP_EIDISABLE 0x0
#define ECP_EISTOP 0x4
#define ECP_EIEDGE 0x00
#define ECP_EILEVEL 0x80
#define ECP_EIADDRMASKL 0x00ff0000
#define ECP_EIADDRSHFTL 16
#define ECP_EIADDRMASKH 0xff000000
#define ECP_EIADDRSHFTH 24
#define ECP_EIBRDENAB 0xc84
#define ECP_EISAID 0x4
/*
* Important defines for the Micro-channel class of ECP board.
* (It has a lot in common with the ISA boards.)
*/
#define ECP_MCIREG 0
#define ECP_MCCONFR 1
#define ECP_MCSTOP 0x20
#define ECP_MCENABLE 0x80
#define ECP_MCDISABLE 0x00
/*
* Important defines for the PCI class of ECP board.
* (It has a lot in common with the other ECP boards.)
*/
#define ECP_PCIIREG 0
#define ECP_PCICONFR 1
#define ECP_PCISTOP 0x01
/*
* Hardware configuration info for ONboard and Brumby boards. These
* defines apply to the directly accessible io ports of these boards.
*/
#define ONB_IOSIZE 16
#define ONB_MEMSIZE (64 * 1024)
#define ONB_ATPAGESIZE (64 * 1024)
#define ONB_MCPAGESIZE (64 * 1024)
#define ONB_EIMEMSIZE (128 * 1024)
#define ONB_EIPAGESIZE (64 * 1024)
/*
* Important defines for the ISA class of ONboard board.
*/
#define ONB_ATIREG 0
#define ONB_ATMEMAR 1
#define ONB_ATCONFR 2
#define ONB_ATSTOP 0x4
#define ONB_ATENABLE 0x01
#define ONB_ATDISABLE 0x00
#define ONB_ATADDRMASK 0xff0000
#define ONB_ATADDRSHFT 16
#define ONB_MEMENABLO 0
#define ONB_MEMENABHI 0x02
/*
* Important defines for the EISA class of ONboard board.
*/
#define ONB_EIIREG 0
#define ONB_EIMEMARL 1
#define ONB_EICONFR 2
#define ONB_EIMEMARH 3
#define ONB_EIENABLE 0x1
#define ONB_EIDISABLE 0x0
#define ONB_EISTOP 0x4
#define ONB_EIEDGE 0x00
#define ONB_EILEVEL 0x80
#define ONB_EIADDRMASKL 0x00ff0000
#define ONB_EIADDRSHFTL 16
#define ONB_EIADDRMASKH 0xff000000
#define ONB_EIADDRSHFTH 24
#define ONB_EIBRDENAB 0xc84
#define ONB_EISAID 0x1
/*
* Important defines for the Brumby boards. They are pretty simple,
* there is not much that is programmably configurable.
*/
#define BBY_IOSIZE 16
#define BBY_MEMSIZE (64 * 1024)
#define BBY_PAGESIZE (16 * 1024)
#define BBY_ATIREG 0
#define BBY_ATCONFR 1
#define BBY_ATSTOP 0x4
/*
* Important defines for the Stallion boards. They are pretty simple,
* there is not much that is programmably configurable.
*/
#define STAL_IOSIZE 16
#define STAL_MEMSIZE (64 * 1024)
#define STAL_PAGESIZE (64 * 1024)
/*
* Define the set of status register values for EasyConnection panels.
* The signature will return with the status value for each panel. From
* this we can determine what is attached to the board - before we have
* actually down loaded any code to it.
*/
#define ECH_PNLSTATUS 2
#define ECH_PNL16PORT 0x20
#define ECH_PNLIDMASK 0x07
#define ECH_PNLXPID 0x40
#define ECH_PNLINTRPEND 0x80
/*
* Define some macros to do things to the board. Even those these boards
* are somewhat related there is often significantly different ways of
* doing some operation on it (like enable, paging, reset, etc). So each
* board class has a set of functions which do the commonly required
* operations. The macros below basically just call these functions,
* generally checking for a NULL function - which means that the board
* needs nothing done to it to achieve this operation!
*/
#define EBRDINIT(brdp) \
if (brdp->init != NULL) \
(* brdp->init)(brdp)
#define EBRDENABLE(brdp) \
if (brdp->enable != NULL) \
(* brdp->enable)(brdp);
#define EBRDDISABLE(brdp) \
if (brdp->disable != NULL) \
(* brdp->disable)(brdp);
#define EBRDINTR(brdp) \
if (brdp->intr != NULL) \
(* brdp->intr)(brdp);
#define EBRDRESET(brdp) \
if (brdp->reset != NULL) \
(* brdp->reset)(brdp);
#define EBRDGETMEMPTR(brdp,offset) \
(* brdp->getmemptr)(brdp, offset, __LINE__)
/*
* Define the maximal baud rate, and the default baud base for ports.
*/
#define STL_MAXBAUD 460800
#define STL_BAUDBASE 115200
#define STL_CLOSEDELAY (5 * HZ / 10)
/*****************************************************************************/
/*
* Define macros to extract a brd or port number from a minor number.
*/
#define MINOR2BRD(min) (((min) & 0xc0) >> 6)
#define MINOR2PORT(min) ((min) & 0x3f)
/*****************************************************************************/
/*
* Define some handy local macros...
*/
#undef MIN
#define MIN(a,b) (((a) <= (b)) ? (a) : (b))
#undef TOLOWER
#define TOLOWER(x) ((((x) >= 'A') && ((x) <= 'Z')) ? ((x) + 0x20) : (x))
/*****************************************************************************/
/*
* Prototype all functions in this driver!
*/
static int stli_parsebrd(stlconf_t *confp, char **argp);
static int stli_init(void);
static int stli_open(struct tty_struct *tty, struct file *filp);
static void stli_close(struct tty_struct *tty, struct file *filp);
static int stli_write(struct tty_struct *tty, const unsigned char *buf, int count);
static void stli_putchar(struct tty_struct *tty, unsigned char ch);
static void stli_flushchars(struct tty_struct *tty);
static int stli_writeroom(struct tty_struct *tty);
static int stli_charsinbuffer(struct tty_struct *tty);
static int stli_ioctl(struct tty_struct *tty, struct file *file, unsigned int cmd, unsigned long arg);
static void stli_settermios(struct tty_struct *tty, struct termios *old);
static void stli_throttle(struct tty_struct *tty);
static void stli_unthrottle(struct tty_struct *tty);
static void stli_stop(struct tty_struct *tty);
static void stli_start(struct tty_struct *tty);
static void stli_flushbuffer(struct tty_struct *tty);
static void stli_breakctl(struct tty_struct *tty, int state);
static void stli_waituntilsent(struct tty_struct *tty, int timeout);
static void stli_sendxchar(struct tty_struct *tty, char ch);
static void stli_hangup(struct tty_struct *tty);
static int stli_portinfo(stlibrd_t *brdp, stliport_t *portp, int portnr, char *pos);
static int stli_brdinit(stlibrd_t *brdp);
static int stli_startbrd(stlibrd_t *brdp);
static ssize_t stli_memread(struct file *fp, char __user *buf, size_t count, loff_t *offp);
static ssize_t stli_memwrite(struct file *fp, const char __user *buf, size_t count, loff_t *offp);
static int stli_memioctl(struct inode *ip, struct file *fp, unsigned int cmd, unsigned long arg);
static void stli_brdpoll(stlibrd_t *brdp, cdkhdr_t __iomem *hdrp);
static void stli_poll(unsigned long arg);
static int stli_hostcmd(stlibrd_t *brdp, stliport_t *portp);
static int stli_initopen(stlibrd_t *brdp, stliport_t *portp);
static int stli_rawopen(stlibrd_t *brdp, stliport_t *portp, unsigned long arg, int wait);
static int stli_rawclose(stlibrd_t *brdp, stliport_t *portp, unsigned long arg, int wait);
static int stli_waitcarrier(stlibrd_t *brdp, stliport_t *portp, struct file *filp);
static void stli_dohangup(void *arg);
static int stli_setport(stliport_t *portp);
static int stli_cmdwait(stlibrd_t *brdp, stliport_t *portp, unsigned long cmd, void *arg, int size, int copyback);
static void stli_sendcmd(stlibrd_t *brdp, stliport_t *portp, unsigned long cmd, void *arg, int size, int copyback);
static void __stli_sendcmd(stlibrd_t *brdp, stliport_t *portp, unsigned long cmd, void *arg, int size, int copyback);
static void stli_dodelaycmd(stliport_t *portp, cdkctrl_t __iomem *cp);
static void stli_mkasyport(stliport_t *portp, asyport_t *pp, struct termios *tiosp);
static void stli_mkasysigs(asysigs_t *sp, int dtr, int rts);
static long stli_mktiocm(unsigned long sigvalue);
static void stli_read(stlibrd_t *brdp, stliport_t *portp);
static int stli_getserial(stliport_t *portp, struct serial_struct __user *sp);
static int stli_setserial(stliport_t *portp, struct serial_struct __user *sp);
static int stli_getbrdstats(combrd_t __user *bp);
static int stli_getportstats(stliport_t *portp, comstats_t __user *cp);
static int stli_portcmdstats(stliport_t *portp);
static int stli_clrportstats(stliport_t *portp, comstats_t __user *cp);
static int stli_getportstruct(stliport_t __user *arg);
static int stli_getbrdstruct(stlibrd_t __user *arg);
static stlibrd_t *stli_allocbrd(void);
static void stli_ecpinit(stlibrd_t *brdp);
static void stli_ecpenable(stlibrd_t *brdp);
static void stli_ecpdisable(stlibrd_t *brdp);
static void __iomem *stli_ecpgetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_ecpreset(stlibrd_t *brdp);
static void stli_ecpintr(stlibrd_t *brdp);
static void stli_ecpeiinit(stlibrd_t *brdp);
static void stli_ecpeienable(stlibrd_t *brdp);
static void stli_ecpeidisable(stlibrd_t *brdp);
static void __iomem *stli_ecpeigetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_ecpeireset(stlibrd_t *brdp);
static void stli_ecpmcenable(stlibrd_t *brdp);
static void stli_ecpmcdisable(stlibrd_t *brdp);
static void __iomem *stli_ecpmcgetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_ecpmcreset(stlibrd_t *brdp);
static void stli_ecppciinit(stlibrd_t *brdp);
static void __iomem *stli_ecppcigetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_ecppcireset(stlibrd_t *brdp);
static void stli_onbinit(stlibrd_t *brdp);
static void stli_onbenable(stlibrd_t *brdp);
static void stli_onbdisable(stlibrd_t *brdp);
static void __iomem *stli_onbgetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_onbreset(stlibrd_t *brdp);
static void stli_onbeinit(stlibrd_t *brdp);
static void stli_onbeenable(stlibrd_t *brdp);
static void stli_onbedisable(stlibrd_t *brdp);
static void __iomem *stli_onbegetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_onbereset(stlibrd_t *brdp);
static void stli_bbyinit(stlibrd_t *brdp);
static void __iomem *stli_bbygetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_bbyreset(stlibrd_t *brdp);
static void stli_stalinit(stlibrd_t *brdp);
static void __iomem *stli_stalgetmemptr(stlibrd_t *brdp, unsigned long offset, int line);
static void stli_stalreset(stlibrd_t *brdp);
static stliport_t *stli_getport(int brdnr, int panelnr, int portnr);
static int stli_initecp(stlibrd_t *brdp);
static int stli_initonb(stlibrd_t *brdp);
static int stli_eisamemprobe(stlibrd_t *brdp);
static int stli_initports(stlibrd_t *brdp);
#ifdef CONFIG_PCI
static int stli_initpcibrd(int brdtype, struct pci_dev *devp);
#endif
/*****************************************************************************/
/*
* Define the driver info for a user level shared memory device. This
* device will work sort of like the /dev/kmem device - except that it
* will give access to the shared memory on the Stallion intelligent
* board. This is also a very useful debugging tool.
*/
static const struct file_operations stli_fsiomem = {
.owner = THIS_MODULE,
.read = stli_memread,
.write = stli_memwrite,
.ioctl = stli_memioctl,
};
/*****************************************************************************/
/*
* Define a timer_list entry for our poll routine. The slave board
* is polled every so often to see if anything needs doing. This is
* much cheaper on host cpu than using interrupts. It turns out to
* not increase character latency by much either...
*/
static DEFINE_TIMER(stli_timerlist, stli_poll, 0, 0);
static int stli_timeron;
/*
* Define the calculation for the timeout routine.
*/
#define STLI_TIMEOUT (jiffies + 1)
/*****************************************************************************/
static struct class *istallion_class;
/*
* Loadable module initialization stuff.
*/
static int __init istallion_module_init(void)
{
stli_init();
return 0;
}
/*****************************************************************************/
static void __exit istallion_module_exit(void)
{
stlibrd_t *brdp;
stliport_t *portp;
int i, j;
printk(KERN_INFO "Unloading %s: version %s\n", stli_drvtitle,
stli_drvversion);
/*
* Free up all allocated resources used by the ports. This includes
* memory and interrupts.
*/
if (stli_timeron) {
stli_timeron = 0;
del_timer_sync(&stli_timerlist);
}
i = tty_unregister_driver(stli_serial);
if (i) {
printk("STALLION: failed to un-register tty driver, "
"errno=%d\n", -i);
return;
}
put_tty_driver(stli_serial);
for (i = 0; i < 4; i++)
class_device_destroy(istallion_class, MKDEV(STL_SIOMEMMAJOR, i));
class_destroy(istallion_class);
if ((i = unregister_chrdev(STL_SIOMEMMAJOR, "staliomem")))
printk("STALLION: failed to un-register serial memory device, "
"errno=%d\n", -i);
kfree(stli_txcookbuf);
for (i = 0; (i < stli_nrbrds); i++) {
if ((brdp = stli_brds[i]) == NULL)
continue;
for (j = 0; (j < STL_MAXPORTS); j++) {
portp = brdp->ports[j];
if (portp != NULL) {
if (portp->tty != NULL)
tty_hangup(portp->tty);
kfree(portp);
}
}
iounmap(brdp->membase);
if (brdp->iosize > 0)
release_region(brdp->iobase, brdp->iosize);
kfree(brdp);
stli_brds[i] = NULL;
}
}
module_init(istallion_module_init);
module_exit(istallion_module_exit);
/*****************************************************************************/
/*
* Check for any arguments passed in on the module load command line.
*/
static void stli_argbrds(void)
{
stlconf_t conf;
stlibrd_t *brdp;
int i;
for (i = stli_nrbrds; i < ARRAY_SIZE(stli_brdsp); i++) {
memset(&conf, 0, sizeof(conf));
if (stli_parsebrd(&conf, stli_brdsp[i]) == 0)
continue;
if ((brdp = stli_allocbrd()) == NULL)
continue;
stli_nrbrds = i + 1;
brdp->brdnr = i;
brdp->brdtype = conf.brdtype;
brdp->iobase = conf.ioaddr1;
brdp->memaddr = conf.memaddr;
stli_brdinit(brdp);
}
}
/*****************************************************************************/
/*
* Convert an ascii string number into an unsigned long.
*/
static unsigned long stli_atol(char *str)
{
unsigned long val;
int base, c;
char *sp;
val = 0;
sp = str;
if ((*sp == '0') && (*(sp+1) == 'x')) {
base = 16;
sp += 2;
} else if (*sp == '0') {
base = 8;
sp++;
} else {
base = 10;
}
for (; (*sp != 0); sp++) {
c = (*sp > '9') ? (TOLOWER(*sp) - 'a' + 10) : (*sp - '0');
if ((c < 0) || (c >= base)) {
printk("STALLION: invalid argument %s\n", str);
val = 0;
break;
}
val = (val * base) + c;
}
return(val);
}
/*****************************************************************************/
/*
* Parse the supplied argument string, into the board conf struct.
*/
static int stli_parsebrd(stlconf_t *confp, char **argp)
{
char *sp;
int i;
if (argp[0] == NULL || *argp[0] == 0)
return 0;
for (sp = argp[0], i = 0; ((*sp != 0) && (i < 25)); sp++, i++)
*sp = TOLOWER(*sp);
for (i = 0; i < ARRAY_SIZE(stli_brdstr); i++) {
if (strcmp(stli_brdstr[i].name, argp[0]) == 0)
break;
}
if (i == ARRAY_SIZE(stli_brdstr)) {
printk("STALLION: unknown board name, %s?\n", argp[0]);
return 0;
}
confp->brdtype = stli_brdstr[i].type;
if (argp[1] != NULL && *argp[1] != 0)
confp->ioaddr1 = stli_atol(argp[1]);
if (argp[2] != NULL && *argp[2] != 0)
confp->memaddr = stli_atol(argp[2]);
return(1);
}
/*****************************************************************************/
static int stli_open(struct tty_struct *tty, struct file *filp)
{
stlibrd_t *brdp;
stliport_t *portp;
unsigned int minordev;
int brdnr, portnr, rc;
minordev = tty->index;
brdnr = MINOR2BRD(minordev);
if (brdnr >= stli_nrbrds)
return -ENODEV;
brdp = stli_brds[brdnr];
if (brdp == NULL)
return -ENODEV;
if ((brdp->state & BST_STARTED) == 0)
return -ENODEV;
portnr = MINOR2PORT(minordev);
if ((portnr < 0) || (portnr > brdp->nrports))
return -ENODEV;
portp = brdp->ports[portnr];
if (portp == NULL)
return -ENODEV;
if (portp->devnr < 1)
return -ENODEV;
/*
* Check if this port is in the middle of closing. If so then wait
* until it is closed then return error status based on flag settings.
* The sleep here does not need interrupt protection since the wakeup
* for it is done with the same context.
*/
if (portp->flags & ASYNC_CLOSING) {
interruptible_sleep_on(&portp->close_wait);
if (portp->flags & ASYNC_HUP_NOTIFY)
return -EAGAIN;
return -ERESTARTSYS;
}
/*
* On the first open of the device setup the port hardware, and
* initialize the per port data structure. Since initializing the port
* requires several commands to the board we will need to wait for any
* other open that is already initializing the port.
*/
portp->tty = tty;
tty->driver_data = portp;
portp->refcount++;
wait_event_interruptible(portp->raw_wait,
!test_bit(ST_INITIALIZING, &portp->state));
if (signal_pending(current))
return -ERESTARTSYS;
if ((portp->flags & ASYNC_INITIALIZED) == 0) {
set_bit(ST_INITIALIZING, &portp->state);
if ((rc = stli_initopen(brdp, portp)) >= 0) {
portp->flags |= ASYNC_INITIALIZED;
clear_bit(TTY_IO_ERROR, &tty->flags);
}
clear_bit(ST_INITIALIZING, &portp->state);
wake_up_interruptible(&portp->raw_wait);
if (rc < 0)
return rc;
}
/*
* Check if this port is in the middle of closing. If so then wait
* until it is closed then return error status, based on flag settings.
* The sleep here does not need interrupt protection since the wakeup
* for it is done with the same context.
*/
if (portp->flags & ASYNC_CLOSING) {
interruptible_sleep_on(&portp->close_wait);
if (portp->flags & ASYNC_HUP_NOTIFY)
return -EAGAIN;
return -ERESTARTSYS;
}
/*
* Based on type of open being done check if it can overlap with any
* previous opens still in effect. If we are a normal serial device
* then also we might have to wait for carrier.
*/
if (!(filp->f_flags & O_NONBLOCK)) {
if ((rc = stli_waitcarrier(brdp, portp, filp)) != 0)
return rc;
}
portp->flags |= ASYNC_NORMAL_ACTIVE;
return 0;
}
/*****************************************************************************/
static void stli_close(struct tty_struct *tty, struct file *filp)
{
stlibrd_t *brdp;
stliport_t *portp;
unsigned long flags;
portp = tty->driver_data;
if (portp == NULL)
return;
spin_lock_irqsave(&stli_lock, flags);
if (tty_hung_up_p(filp)) {
spin_unlock_irqrestore(&stli_lock, flags);
return;
}
if ((tty->count == 1) && (portp->refcount != 1))
portp->refcount = 1;
if (portp->refcount-- > 1) {
spin_unlock_irqrestore(&stli_lock, flags);
return;
}
portp->flags |= ASYNC_CLOSING;
/*
* May want to wait for data to drain before closing. The BUSY flag
* keeps track of whether we are still transmitting or not. It is
* updated by messages from the slave - indicating when all chars
* really have drained.
*/
if (tty == stli_txcooktty)
stli_flushchars(tty);
tty->closing = 1;
spin_unlock_irqrestore(&stli_lock, flags);
if (portp->closing_wait != ASYNC_CLOSING_WAIT_NONE)
tty_wait_until_sent(tty, portp->closing_wait);
portp->flags &= ~ASYNC_INITIALIZED;
brdp = stli_brds[portp->brdnr];
stli_rawclose(brdp, portp, 0, 0);
if (tty->termios->c_cflag & HUPCL) {
stli_mkasysigs(&portp->asig, 0, 0);
if (test_bit(ST_CMDING, &portp->state))
set_bit(ST_DOSIGS, &portp->state);
else
stli_sendcmd(brdp, portp, A_SETSIGNALS, &portp->asig,
sizeof(asysigs_t), 0);
}
clear_bit(ST_TXBUSY, &portp->state);
clear_bit(ST_RXSTOP, &portp->state);
set_bit(TTY_IO_ERROR, &tty->flags);
if (tty->ldisc.flush_buffer)
(tty->ldisc.flush_buffer)(tty);
set_bit(ST_DOFLUSHRX, &portp->state);
stli_flushbuffer(tty);
tty->closing = 0;
portp->tty = NULL;
if (portp->openwaitcnt) {
if (portp->close_delay)
msleep_interruptible(jiffies_to_msecs(portp->close_delay));
wake_up_interruptible(&portp->open_wait);
}
portp->flags &= ~(ASYNC_NORMAL_ACTIVE|ASYNC_CLOSING);
wake_up_interruptible(&portp->close_wait);
}
/*****************************************************************************/
/*
* Carry out first open operations on a port. This involves a number of
* commands to be sent to the slave. We need to open the port, set the
* notification events, set the initial port settings, get and set the
* initial signal values. We sleep and wait in between each one. But
* this still all happens pretty quickly.
*/
static int stli_initopen(stlibrd_t *brdp, stliport_t *portp)
{
struct tty_struct *tty;
asynotify_t nt;
asyport_t aport;
int rc;
if ((rc = stli_rawopen(brdp, portp, 0, 1)) < 0)
return rc;
memset(&nt, 0, sizeof(asynotify_t));
nt.data = (DT_TXLOW | DT_TXEMPTY | DT_RXBUSY | DT_RXBREAK);
nt.signal = SG_DCD;
if ((rc = stli_cmdwait(brdp, portp, A_SETNOTIFY, &nt,
sizeof(asynotify_t), 0)) < 0)
return rc;
tty = portp->tty;
if (tty == NULL)
return -ENODEV;
stli_mkasyport(portp, &aport, tty->termios);
if ((rc = stli_cmdwait(brdp, portp, A_SETPORT, &aport,
sizeof(asyport_t), 0)) < 0)
return rc;
set_bit(ST_GETSIGS, &portp->state);
if ((rc = stli_cmdwait(brdp, portp, A_GETSIGNALS, &portp->asig,
sizeof(asysigs_t), 1)) < 0)
return rc;
if (test_and_clear_bit(ST_GETSIGS, &portp->state))
portp->sigs = stli_mktiocm(portp->asig.sigvalue);
stli_mkasysigs(&portp->asig, 1, 1);
if ((rc = stli_cmdwait(brdp, portp, A_SETSIGNALS, &portp->asig,
sizeof(asysigs_t), 0)) < 0)
return rc;
return 0;
}
/*****************************************************************************/
/*
* Send an open message to the slave. This will sleep waiting for the
* acknowledgement, so must have user context. We need to co-ordinate
* with close events here, since we don't want open and close events
* to overlap.
*/
static int stli_rawopen(stlibrd_t *brdp, stliport_t *portp, unsigned long arg, int wait)
{
cdkhdr_t __iomem *hdrp;
cdkctrl_t __iomem *cp;
unsigned char __iomem *bits;
unsigned long flags;
int rc;
/*
* Send a message to the slave to open this port.
*/
/*
* Slave is already closing this port. This can happen if a hangup
* occurs on this port. So we must wait until it is complete. The
* order of opens and closes may not be preserved across shared
* memory, so we must wait until it is complete.
*/
wait_event_interruptible(portp->raw_wait,
!test_bit(ST_CLOSING, &portp->state));
if (signal_pending(current)) {
return -ERESTARTSYS;
}
/*
* Everything is ready now, so write the open message into shared
* memory. Once the message is in set the service bits to say that
* this port wants service.
*/
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
cp = &((cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr))->ctrl;
writel(arg, &cp->openarg);
writeb(1, &cp->open);
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
bits = ((unsigned char __iomem *) hdrp) + brdp->slaveoffset +
portp->portidx;
writeb(readb(bits) | portp->portbit, bits);
EBRDDISABLE(brdp);
if (wait == 0) {
spin_unlock_irqrestore(&brd_lock, flags);
return 0;
}
/*
* Slave is in action, so now we must wait for the open acknowledgment
* to come back.
*/
rc = 0;
set_bit(ST_OPENING, &portp->state);
spin_unlock_irqrestore(&brd_lock, flags);
wait_event_interruptible(portp->raw_wait,
!test_bit(ST_OPENING, &portp->state));
if (signal_pending(current))
rc = -ERESTARTSYS;
if ((rc == 0) && (portp->rc != 0))
rc = -EIO;
return rc;
}
/*****************************************************************************/
/*
* Send a close message to the slave. Normally this will sleep waiting
* for the acknowledgement, but if wait parameter is 0 it will not. If
* wait is true then must have user context (to sleep).
*/
static int stli_rawclose(stlibrd_t *brdp, stliport_t *portp, unsigned long arg, int wait)
{
cdkhdr_t __iomem *hdrp;
cdkctrl_t __iomem *cp;
unsigned char __iomem *bits;
unsigned long flags;
int rc;
/*
* Slave is already closing this port. This can happen if a hangup
* occurs on this port.
*/
if (wait) {
wait_event_interruptible(portp->raw_wait,
!test_bit(ST_CLOSING, &portp->state));
if (signal_pending(current)) {
return -ERESTARTSYS;
}
}
/*
* Write the close command into shared memory.
*/
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
cp = &((cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr))->ctrl;
writel(arg, &cp->closearg);
writeb(1, &cp->close);
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
bits = ((unsigned char __iomem *) hdrp) + brdp->slaveoffset +
portp->portidx;
writeb(readb(bits) |portp->portbit, bits);
EBRDDISABLE(brdp);
set_bit(ST_CLOSING, &portp->state);
spin_unlock_irqrestore(&brd_lock, flags);
if (wait == 0)
return 0;
/*
* Slave is in action, so now we must wait for the open acknowledgment
* to come back.
*/
rc = 0;
wait_event_interruptible(portp->raw_wait,
!test_bit(ST_CLOSING, &portp->state));
if (signal_pending(current))
rc = -ERESTARTSYS;
if ((rc == 0) && (portp->rc != 0))
rc = -EIO;
return rc;
}
/*****************************************************************************/
/*
* Send a command to the slave and wait for the response. This must
* have user context (it sleeps). This routine is generic in that it
* can send any type of command. Its purpose is to wait for that command
* to complete (as opposed to initiating the command then returning).
*/
static int stli_cmdwait(stlibrd_t *brdp, stliport_t *portp, unsigned long cmd, void *arg, int size, int copyback)
{
wait_event_interruptible(portp->raw_wait,
!test_bit(ST_CMDING, &portp->state));
if (signal_pending(current))
return -ERESTARTSYS;
stli_sendcmd(brdp, portp, cmd, arg, size, copyback);
wait_event_interruptible(portp->raw_wait,
!test_bit(ST_CMDING, &portp->state));
if (signal_pending(current))
return -ERESTARTSYS;
if (portp->rc != 0)
return -EIO;
return 0;
}
/*****************************************************************************/
/*
* Send the termios settings for this port to the slave. This sleeps
* waiting for the command to complete - so must have user context.
*/
static int stli_setport(stliport_t *portp)
{
stlibrd_t *brdp;
asyport_t aport;
if (portp == NULL)
return -ENODEV;
if (portp->tty == NULL)
return -ENODEV;
if (portp->brdnr < 0 && portp->brdnr >= stli_nrbrds)
return -ENODEV;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return -ENODEV;
stli_mkasyport(portp, &aport, portp->tty->termios);
return(stli_cmdwait(brdp, portp, A_SETPORT, &aport, sizeof(asyport_t), 0));
}
/*****************************************************************************/
/*
* Possibly need to wait for carrier (DCD signal) to come high. Say
* maybe because if we are clocal then we don't need to wait...
*/
static int stli_waitcarrier(stlibrd_t *brdp, stliport_t *portp, struct file *filp)
{
unsigned long flags;
int rc, doclocal;
rc = 0;
doclocal = 0;
if (portp->tty->termios->c_cflag & CLOCAL)
doclocal++;
spin_lock_irqsave(&stli_lock, flags);
portp->openwaitcnt++;
if (! tty_hung_up_p(filp))
portp->refcount--;
spin_unlock_irqrestore(&stli_lock, flags);
for (;;) {
stli_mkasysigs(&portp->asig, 1, 1);
if ((rc = stli_cmdwait(brdp, portp, A_SETSIGNALS,
&portp->asig, sizeof(asysigs_t), 0)) < 0)
break;
if (tty_hung_up_p(filp) ||
((portp->flags & ASYNC_INITIALIZED) == 0)) {
if (portp->flags & ASYNC_HUP_NOTIFY)
rc = -EBUSY;
else
rc = -ERESTARTSYS;
break;
}
if (((portp->flags & ASYNC_CLOSING) == 0) &&
(doclocal || (portp->sigs & TIOCM_CD))) {
break;
}
if (signal_pending(current)) {
rc = -ERESTARTSYS;
break;
}
interruptible_sleep_on(&portp->open_wait);
}
spin_lock_irqsave(&stli_lock, flags);
if (! tty_hung_up_p(filp))
portp->refcount++;
portp->openwaitcnt--;
spin_unlock_irqrestore(&stli_lock, flags);
return rc;
}
/*****************************************************************************/
/*
* Write routine. Take the data and put it in the shared memory ring
* queue. If port is not already sending chars then need to mark the
* service bits for this port.
*/
static int stli_write(struct tty_struct *tty, const unsigned char *buf, int count)
{
cdkasy_t __iomem *ap;
cdkhdr_t __iomem *hdrp;
unsigned char __iomem *bits;
unsigned char __iomem *shbuf;
unsigned char *chbuf;
stliport_t *portp;
stlibrd_t *brdp;
unsigned int len, stlen, head, tail, size;
unsigned long flags;
if (tty == stli_txcooktty)
stli_flushchars(tty);
portp = tty->driver_data;
if (portp == NULL)
return 0;
if ((portp->brdnr < 0) || (portp->brdnr >= stli_nrbrds))
return 0;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return 0;
chbuf = (unsigned char *) buf;
/*
* All data is now local, shove as much as possible into shared memory.
*/
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
ap = (cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr);
head = (unsigned int) readw(&ap->txq.head);
tail = (unsigned int) readw(&ap->txq.tail);
if (tail != ((unsigned int) readw(&ap->txq.tail)))
tail = (unsigned int) readw(&ap->txq.tail);
size = portp->txsize;
if (head >= tail) {
len = size - (head - tail) - 1;
stlen = size - head;
} else {
len = tail - head - 1;
stlen = len;
}
len = MIN(len, count);
count = 0;
shbuf = (char __iomem *) EBRDGETMEMPTR(brdp, portp->txoffset);
while (len > 0) {
stlen = MIN(len, stlen);
memcpy_toio(shbuf + head, chbuf, stlen);
chbuf += stlen;
len -= stlen;
count += stlen;
head += stlen;
if (head >= size) {
head = 0;
stlen = tail;
}
}
ap = (cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr);
writew(head, &ap->txq.head);
if (test_bit(ST_TXBUSY, &portp->state)) {
if (readl(&ap->changed.data) & DT_TXEMPTY)
writel(readl(&ap->changed.data) & ~DT_TXEMPTY, &ap->changed.data);
}
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
bits = ((unsigned char __iomem *) hdrp) + brdp->slaveoffset +
portp->portidx;
writeb(readb(bits) | portp->portbit, bits);
set_bit(ST_TXBUSY, &portp->state);
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
return(count);
}
/*****************************************************************************/
/*
* Output a single character. We put it into a temporary local buffer
* (for speed) then write out that buffer when the flushchars routine
* is called. There is a safety catch here so that if some other port
* writes chars before the current buffer has been, then we write them
* first them do the new ports.
*/
static void stli_putchar(struct tty_struct *tty, unsigned char ch)
{
if (tty != stli_txcooktty) {
if (stli_txcooktty != NULL)
stli_flushchars(stli_txcooktty);
stli_txcooktty = tty;
}
stli_txcookbuf[stli_txcooksize++] = ch;
}
/*****************************************************************************/
/*
* Transfer characters from the local TX cooking buffer to the board.
* We sort of ignore the tty that gets passed in here. We rely on the
* info stored with the TX cook buffer to tell us which port to flush
* the data on. In any case we clean out the TX cook buffer, for re-use
* by someone else.
*/
static void stli_flushchars(struct tty_struct *tty)
{
cdkhdr_t __iomem *hdrp;
unsigned char __iomem *bits;
cdkasy_t __iomem *ap;
struct tty_struct *cooktty;
stliport_t *portp;
stlibrd_t *brdp;
unsigned int len, stlen, head, tail, size, count, cooksize;
unsigned char *buf;
unsigned char __iomem *shbuf;
unsigned long flags;
cooksize = stli_txcooksize;
cooktty = stli_txcooktty;
stli_txcooksize = 0;
stli_txcookrealsize = 0;
stli_txcooktty = NULL;
if (tty == NULL)
return;
if (cooktty == NULL)
return;
if (tty != cooktty)
tty = cooktty;
if (cooksize == 0)
return;
portp = tty->driver_data;
if (portp == NULL)
return;
if ((portp->brdnr < 0) || (portp->brdnr >= stli_nrbrds))
return;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return;
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
ap = (cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr);
head = (unsigned int) readw(&ap->txq.head);
tail = (unsigned int) readw(&ap->txq.tail);
if (tail != ((unsigned int) readw(&ap->txq.tail)))
tail = (unsigned int) readw(&ap->txq.tail);
size = portp->txsize;
if (head >= tail) {
len = size - (head - tail) - 1;
stlen = size - head;
} else {
len = tail - head - 1;
stlen = len;
}
len = MIN(len, cooksize);
count = 0;
shbuf = EBRDGETMEMPTR(brdp, portp->txoffset);
buf = stli_txcookbuf;
while (len > 0) {
stlen = MIN(len, stlen);
memcpy_toio(shbuf + head, buf, stlen);
buf += stlen;
len -= stlen;
count += stlen;
head += stlen;
if (head >= size) {
head = 0;
stlen = tail;
}
}
ap = (cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr);
writew(head, &ap->txq.head);
if (test_bit(ST_TXBUSY, &portp->state)) {
if (readl(&ap->changed.data) & DT_TXEMPTY)
writel(readl(&ap->changed.data) & ~DT_TXEMPTY, &ap->changed.data);
}
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
bits = ((unsigned char __iomem *) hdrp) + brdp->slaveoffset +
portp->portidx;
writeb(readb(bits) | portp->portbit, bits);
set_bit(ST_TXBUSY, &portp->state);
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
}
/*****************************************************************************/
static int stli_writeroom(struct tty_struct *tty)
{
cdkasyrq_t __iomem *rp;
stliport_t *portp;
stlibrd_t *brdp;
unsigned int head, tail, len;
unsigned long flags;
if (tty == stli_txcooktty) {
if (stli_txcookrealsize != 0) {
len = stli_txcookrealsize - stli_txcooksize;
return len;
}
}
portp = tty->driver_data;
if (portp == NULL)
return 0;
if ((portp->brdnr < 0) || (portp->brdnr >= stli_nrbrds))
return 0;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return 0;
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
rp = &((cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr))->txq;
head = (unsigned int) readw(&rp->head);
tail = (unsigned int) readw(&rp->tail);
if (tail != ((unsigned int) readw(&rp->tail)))
tail = (unsigned int) readw(&rp->tail);
len = (head >= tail) ? (portp->txsize - (head - tail)) : (tail - head);
len--;
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
if (tty == stli_txcooktty) {
stli_txcookrealsize = len;
len -= stli_txcooksize;
}
return len;
}
/*****************************************************************************/
/*
* Return the number of characters in the transmit buffer. Normally we
* will return the number of chars in the shared memory ring queue.
* We need to kludge around the case where the shared memory buffer is
* empty but not all characters have drained yet, for this case just
* return that there is 1 character in the buffer!
*/
static int stli_charsinbuffer(struct tty_struct *tty)
{
cdkasyrq_t __iomem *rp;
stliport_t *portp;
stlibrd_t *brdp;
unsigned int head, tail, len;
unsigned long flags;
if (tty == stli_txcooktty)
stli_flushchars(tty);
portp = tty->driver_data;
if (portp == NULL)
return 0;
if ((portp->brdnr < 0) || (portp->brdnr >= stli_nrbrds))
return 0;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return 0;
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
rp = &((cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr))->txq;
head = (unsigned int) readw(&rp->head);
tail = (unsigned int) readw(&rp->tail);
if (tail != ((unsigned int) readw(&rp->tail)))
tail = (unsigned int) readw(&rp->tail);
len = (head >= tail) ? (head - tail) : (portp->txsize - (tail - head));
if ((len == 0) && test_bit(ST_TXBUSY, &portp->state))
len = 1;
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
return len;
}
/*****************************************************************************/
/*
* Generate the serial struct info.
*/
static int stli_getserial(stliport_t *portp, struct serial_struct __user *sp)
{
struct serial_struct sio;
stlibrd_t *brdp;
memset(&sio, 0, sizeof(struct serial_struct));
sio.type = PORT_UNKNOWN;
sio.line = portp->portnr;
sio.irq = 0;
sio.flags = portp->flags;
sio.baud_base = portp->baud_base;
sio.close_delay = portp->close_delay;
sio.closing_wait = portp->closing_wait;
sio.custom_divisor = portp->custom_divisor;
sio.xmit_fifo_size = 0;
sio.hub6 = 0;
brdp = stli_brds[portp->brdnr];
if (brdp != NULL)
sio.port = brdp->iobase;
return copy_to_user(sp, &sio, sizeof(struct serial_struct)) ?
-EFAULT : 0;
}
/*****************************************************************************/
/*
* Set port according to the serial struct info.
* At this point we do not do any auto-configure stuff, so we will
* just quietly ignore any requests to change irq, etc.
*/
static int stli_setserial(stliport_t *portp, struct serial_struct __user *sp)
{
struct serial_struct sio;
int rc;
if (copy_from_user(&sio, sp, sizeof(struct serial_struct)))
return -EFAULT;
if (!capable(CAP_SYS_ADMIN)) {
if ((sio.baud_base != portp->baud_base) ||
(sio.close_delay != portp->close_delay) ||
((sio.flags & ~ASYNC_USR_MASK) !=
(portp->flags & ~ASYNC_USR_MASK)))
return -EPERM;
}
portp->flags = (portp->flags & ~ASYNC_USR_MASK) |
(sio.flags & ASYNC_USR_MASK);
portp->baud_base = sio.baud_base;
portp->close_delay = sio.close_delay;
portp->closing_wait = sio.closing_wait;
portp->custom_divisor = sio.custom_divisor;
if ((rc = stli_setport(portp)) < 0)
return rc;
return 0;
}
/*****************************************************************************/
static int stli_tiocmget(struct tty_struct *tty, struct file *file)
{
stliport_t *portp = tty->driver_data;
stlibrd_t *brdp;
int rc;
if (portp == NULL)
return -ENODEV;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return 0;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return 0;
if (tty->flags & (1 << TTY_IO_ERROR))
return -EIO;
if ((rc = stli_cmdwait(brdp, portp, A_GETSIGNALS,
&portp->asig, sizeof(asysigs_t), 1)) < 0)
return rc;
return stli_mktiocm(portp->asig.sigvalue);
}
static int stli_tiocmset(struct tty_struct *tty, struct file *file,
unsigned int set, unsigned int clear)
{
stliport_t *portp = tty->driver_data;
stlibrd_t *brdp;
int rts = -1, dtr = -1;
if (portp == NULL)
return -ENODEV;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return 0;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return 0;
if (tty->flags & (1 << TTY_IO_ERROR))
return -EIO;
if (set & TIOCM_RTS)
rts = 1;
if (set & TIOCM_DTR)
dtr = 1;
if (clear & TIOCM_RTS)
rts = 0;
if (clear & TIOCM_DTR)
dtr = 0;
stli_mkasysigs(&portp->asig, dtr, rts);
return stli_cmdwait(brdp, portp, A_SETSIGNALS, &portp->asig,
sizeof(asysigs_t), 0);
}
static int stli_ioctl(struct tty_struct *tty, struct file *file, unsigned int cmd, unsigned long arg)
{
stliport_t *portp;
stlibrd_t *brdp;
unsigned int ival;
int rc;
void __user *argp = (void __user *)arg;
portp = tty->driver_data;
if (portp == NULL)
return -ENODEV;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return 0;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return 0;
if ((cmd != TIOCGSERIAL) && (cmd != TIOCSSERIAL) &&
(cmd != COM_GETPORTSTATS) && (cmd != COM_CLRPORTSTATS)) {
if (tty->flags & (1 << TTY_IO_ERROR))
return -EIO;
}
rc = 0;
switch (cmd) {
case TIOCGSOFTCAR:
rc = put_user(((tty->termios->c_cflag & CLOCAL) ? 1 : 0),
(unsigned __user *) arg);
break;
case TIOCSSOFTCAR:
if ((rc = get_user(ival, (unsigned __user *) arg)) == 0)
tty->termios->c_cflag =
(tty->termios->c_cflag & ~CLOCAL) |
(ival ? CLOCAL : 0);
break;
case TIOCGSERIAL:
rc = stli_getserial(portp, argp);
break;
case TIOCSSERIAL:
rc = stli_setserial(portp, argp);
break;
case STL_GETPFLAG:
rc = put_user(portp->pflag, (unsigned __user *)argp);
break;
case STL_SETPFLAG:
if ((rc = get_user(portp->pflag, (unsigned __user *)argp)) == 0)
stli_setport(portp);
break;
case COM_GETPORTSTATS:
rc = stli_getportstats(portp, argp);
break;
case COM_CLRPORTSTATS:
rc = stli_clrportstats(portp, argp);
break;
case TIOCSERCONFIG:
case TIOCSERGWILD:
case TIOCSERSWILD:
case TIOCSERGETLSR:
case TIOCSERGSTRUCT:
case TIOCSERGETMULTI:
case TIOCSERSETMULTI:
default:
rc = -ENOIOCTLCMD;
break;
}
return rc;
}
/*****************************************************************************/
/*
* This routine assumes that we have user context and can sleep.
* Looks like it is true for the current ttys implementation..!!
*/
static void stli_settermios(struct tty_struct *tty, struct termios *old)
{
stliport_t *portp;
stlibrd_t *brdp;
struct termios *tiosp;
asyport_t aport;
if (tty == NULL)
return;
portp = tty->driver_data;
if (portp == NULL)
return;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return;
tiosp = tty->termios;
if ((tiosp->c_cflag == old->c_cflag) &&
(tiosp->c_iflag == old->c_iflag))
return;
stli_mkasyport(portp, &aport, tiosp);
stli_cmdwait(brdp, portp, A_SETPORT, &aport, sizeof(asyport_t), 0);
stli_mkasysigs(&portp->asig, ((tiosp->c_cflag & CBAUD) ? 1 : 0), -1);
stli_cmdwait(brdp, portp, A_SETSIGNALS, &portp->asig,
sizeof(asysigs_t), 0);
if ((old->c_cflag & CRTSCTS) && ((tiosp->c_cflag & CRTSCTS) == 0))
tty->hw_stopped = 0;
if (((old->c_cflag & CLOCAL) == 0) && (tiosp->c_cflag & CLOCAL))
wake_up_interruptible(&portp->open_wait);
}
/*****************************************************************************/
/*
* Attempt to flow control who ever is sending us data. We won't really
* do any flow control action here. We can't directly, and even if we
* wanted to we would have to send a command to the slave. The slave
* knows how to flow control, and will do so when its buffers reach its
* internal high water marks. So what we will do is set a local state
* bit that will stop us sending any RX data up from the poll routine
* (which is the place where RX data from the slave is handled).
*/
static void stli_throttle(struct tty_struct *tty)
{
stliport_t *portp = tty->driver_data;
if (portp == NULL)
return;
set_bit(ST_RXSTOP, &portp->state);
}
/*****************************************************************************/
/*
* Unflow control the device sending us data... That means that all
* we have to do is clear the RXSTOP state bit. The next poll call
* will then be able to pass the RX data back up.
*/
static void stli_unthrottle(struct tty_struct *tty)
{
stliport_t *portp = tty->driver_data;
if (portp == NULL)
return;
clear_bit(ST_RXSTOP, &portp->state);
}
/*****************************************************************************/
/*
* Stop the transmitter.
*/
static void stli_stop(struct tty_struct *tty)
{
}
/*****************************************************************************/
/*
* Start the transmitter again.
*/
static void stli_start(struct tty_struct *tty)
{
}
/*****************************************************************************/
/*
* Scheduler called hang up routine. This is called from the scheduler,
* not direct from the driver "poll" routine. We can't call it there
* since the real local hangup code will enable/disable the board and
* other things that we can't do while handling the poll. Much easier
* to deal with it some time later (don't really care when, hangups
* aren't that time critical).
*/
static void stli_dohangup(void *arg)
{
stliport_t *portp = (stliport_t *) arg;
if (portp->tty != NULL) {
tty_hangup(portp->tty);
}
}
/*****************************************************************************/
/*
* Hangup this port. This is pretty much like closing the port, only
* a little more brutal. No waiting for data to drain. Shutdown the
* port and maybe drop signals. This is rather tricky really. We want
* to close the port as well.
*/
static void stli_hangup(struct tty_struct *tty)
{
stliport_t *portp;
stlibrd_t *brdp;
unsigned long flags;
portp = tty->driver_data;
if (portp == NULL)
return;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return;
portp->flags &= ~ASYNC_INITIALIZED;
if (!test_bit(ST_CLOSING, &portp->state))
stli_rawclose(brdp, portp, 0, 0);
spin_lock_irqsave(&stli_lock, flags);
if (tty->termios->c_cflag & HUPCL) {
stli_mkasysigs(&portp->asig, 0, 0);
if (test_bit(ST_CMDING, &portp->state)) {
set_bit(ST_DOSIGS, &portp->state);
set_bit(ST_DOFLUSHTX, &portp->state);
set_bit(ST_DOFLUSHRX, &portp->state);
} else {
stli_sendcmd(brdp, portp, A_SETSIGNALSF,
&portp->asig, sizeof(asysigs_t), 0);
}
}
clear_bit(ST_TXBUSY, &portp->state);
clear_bit(ST_RXSTOP, &portp->state);
set_bit(TTY_IO_ERROR, &tty->flags);
portp->tty = NULL;
portp->flags &= ~ASYNC_NORMAL_ACTIVE;
portp->refcount = 0;
spin_unlock_irqrestore(&stli_lock, flags);
wake_up_interruptible(&portp->open_wait);
}
/*****************************************************************************/
/*
* Flush characters from the lower buffer. We may not have user context
* so we cannot sleep waiting for it to complete. Also we need to check
* if there is chars for this port in the TX cook buffer, and flush them
* as well.
*/
static void stli_flushbuffer(struct tty_struct *tty)
{
stliport_t *portp;
stlibrd_t *brdp;
unsigned long ftype, flags;
portp = tty->driver_data;
if (portp == NULL)
return;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return;
spin_lock_irqsave(&brd_lock, flags);
if (tty == stli_txcooktty) {
stli_txcooktty = NULL;
stli_txcooksize = 0;
stli_txcookrealsize = 0;
}
if (test_bit(ST_CMDING, &portp->state)) {
set_bit(ST_DOFLUSHTX, &portp->state);
} else {
ftype = FLUSHTX;
if (test_bit(ST_DOFLUSHRX, &portp->state)) {
ftype |= FLUSHRX;
clear_bit(ST_DOFLUSHRX, &portp->state);
}
__stli_sendcmd(brdp, portp, A_FLUSH, &ftype, sizeof(u32), 0);
}
spin_unlock_irqrestore(&brd_lock, flags);
tty_wakeup(tty);
}
/*****************************************************************************/
static void stli_breakctl(struct tty_struct *tty, int state)
{
stlibrd_t *brdp;
stliport_t *portp;
long arg;
portp = tty->driver_data;
if (portp == NULL)
return;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return;
arg = (state == -1) ? BREAKON : BREAKOFF;
stli_cmdwait(brdp, portp, A_BREAK, &arg, sizeof(long), 0);
}
/*****************************************************************************/
static void stli_waituntilsent(struct tty_struct *tty, int timeout)
{
stliport_t *portp;
unsigned long tend;
if (tty == NULL)
return;
portp = tty->driver_data;
if (portp == NULL)
return;
if (timeout == 0)
timeout = HZ;
tend = jiffies + timeout;
while (test_bit(ST_TXBUSY, &portp->state)) {
if (signal_pending(current))
break;
msleep_interruptible(20);
if (time_after_eq(jiffies, tend))
break;
}
}
/*****************************************************************************/
static void stli_sendxchar(struct tty_struct *tty, char ch)
{
stlibrd_t *brdp;
stliport_t *portp;
asyctrl_t actrl;
portp = tty->driver_data;
if (portp == NULL)
return;
if (portp->brdnr < 0 || portp->brdnr >= stli_nrbrds)
return;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return;
memset(&actrl, 0, sizeof(asyctrl_t));
if (ch == STOP_CHAR(tty)) {
actrl.rxctrl = CT_STOPFLOW;
} else if (ch == START_CHAR(tty)) {
actrl.rxctrl = CT_STARTFLOW;
} else {
actrl.txctrl = CT_SENDCHR;
actrl.tximdch = ch;
}
stli_cmdwait(brdp, portp, A_PORTCTRL, &actrl, sizeof(asyctrl_t), 0);
}
/*****************************************************************************/
#define MAXLINE 80
/*
* Format info for a specified port. The line is deliberately limited
* to 80 characters. (If it is too long it will be truncated, if too
* short then padded with spaces).
*/
static int stli_portinfo(stlibrd_t *brdp, stliport_t *portp, int portnr, char *pos)
{
char *sp, *uart;
int rc, cnt;
rc = stli_portcmdstats(portp);
uart = "UNKNOWN";
if (brdp->state & BST_STARTED) {
switch (stli_comstats.hwid) {
case 0: uart = "2681"; break;
case 1: uart = "SC26198"; break;
default:uart = "CD1400"; break;
}
}
sp = pos;
sp += sprintf(sp, "%d: uart:%s ", portnr, uart);
if ((brdp->state & BST_STARTED) && (rc >= 0)) {
sp += sprintf(sp, "tx:%d rx:%d", (int) stli_comstats.txtotal,
(int) stli_comstats.rxtotal);
if (stli_comstats.rxframing)
sp += sprintf(sp, " fe:%d",
(int) stli_comstats.rxframing);
if (stli_comstats.rxparity)
sp += sprintf(sp, " pe:%d",
(int) stli_comstats.rxparity);
if (stli_comstats.rxbreaks)
sp += sprintf(sp, " brk:%d",
(int) stli_comstats.rxbreaks);
if (stli_comstats.rxoverrun)
sp += sprintf(sp, " oe:%d",
(int) stli_comstats.rxoverrun);
cnt = sprintf(sp, "%s%s%s%s%s ",
(stli_comstats.signals & TIOCM_RTS) ? "|RTS" : "",
(stli_comstats.signals & TIOCM_CTS) ? "|CTS" : "",
(stli_comstats.signals & TIOCM_DTR) ? "|DTR" : "",
(stli_comstats.signals & TIOCM_CD) ? "|DCD" : "",
(stli_comstats.signals & TIOCM_DSR) ? "|DSR" : "");
*sp = ' ';
sp += cnt;
}
for (cnt = (sp - pos); (cnt < (MAXLINE - 1)); cnt++)
*sp++ = ' ';
if (cnt >= MAXLINE)
pos[(MAXLINE - 2)] = '+';
pos[(MAXLINE - 1)] = '\n';
return(MAXLINE);
}
/*****************************************************************************/
/*
* Port info, read from the /proc file system.
*/
static int stli_readproc(char *page, char **start, off_t off, int count, int *eof, void *data)
{
stlibrd_t *brdp;
stliport_t *portp;
int brdnr, portnr, totalport;
int curoff, maxoff;
char *pos;
pos = page;
totalport = 0;
curoff = 0;
if (off == 0) {
pos += sprintf(pos, "%s: version %s", stli_drvtitle,
stli_drvversion);
while (pos < (page + MAXLINE - 1))
*pos++ = ' ';
*pos++ = '\n';
}
curoff = MAXLINE;
/*
* We scan through for each board, panel and port. The offset is
* calculated on the fly, and irrelevant ports are skipped.
*/
for (brdnr = 0; (brdnr < stli_nrbrds); brdnr++) {
brdp = stli_brds[brdnr];
if (brdp == NULL)
continue;
if (brdp->state == 0)
continue;
maxoff = curoff + (brdp->nrports * MAXLINE);
if (off >= maxoff) {
curoff = maxoff;
continue;
}
totalport = brdnr * STL_MAXPORTS;
for (portnr = 0; (portnr < brdp->nrports); portnr++,
totalport++) {
portp = brdp->ports[portnr];
if (portp == NULL)
continue;
if (off >= (curoff += MAXLINE))
continue;
if ((pos - page + MAXLINE) > count)
goto stli_readdone;
pos += stli_portinfo(brdp, portp, totalport, pos);
}
}
*eof = 1;
stli_readdone:
*start = page;
return(pos - page);
}
/*****************************************************************************/
/*
* Generic send command routine. This will send a message to the slave,
* of the specified type with the specified argument. Must be very
* careful of data that will be copied out from shared memory -
* containing command results. The command completion is all done from
* a poll routine that does not have user context. Therefore you cannot
* copy back directly into user space, or to the kernel stack of a
* process. This routine does not sleep, so can be called from anywhere.
*
* The caller must hold the brd_lock (see also stli_sendcmd the usual
* entry point)
*/
static void __stli_sendcmd(stlibrd_t *brdp, stliport_t *portp, unsigned long cmd, void *arg, int size, int copyback)
{
cdkhdr_t __iomem *hdrp;
cdkctrl_t __iomem *cp;
unsigned char __iomem *bits;
unsigned long flags;
spin_lock_irqsave(&brd_lock, flags);
if (test_bit(ST_CMDING, &portp->state)) {
printk(KERN_ERR "STALLION: command already busy, cmd=%x!\n",
(int) cmd);
spin_unlock_irqrestore(&brd_lock, flags);
return;
}
EBRDENABLE(brdp);
cp = &((cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr))->ctrl;
if (size > 0) {
memcpy_toio((void __iomem *) &(cp->args[0]), arg, size);
if (copyback) {
portp->argp = arg;
portp->argsize = size;
}
}
writel(0, &cp->status);
writel(cmd, &cp->cmd);
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
bits = ((unsigned char __iomem *) hdrp) + brdp->slaveoffset +
portp->portidx;
writeb(readb(bits) | portp->portbit, bits);
set_bit(ST_CMDING, &portp->state);
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
}
static void stli_sendcmd(stlibrd_t *brdp, stliport_t *portp, unsigned long cmd, void *arg, int size, int copyback)
{
unsigned long flags;
spin_lock_irqsave(&brd_lock, flags);
__stli_sendcmd(brdp, portp, cmd, arg, size, copyback);
spin_unlock_irqrestore(&brd_lock, flags);
}
/*****************************************************************************/
/*
* Read data from shared memory. This assumes that the shared memory
* is enabled and that interrupts are off. Basically we just empty out
* the shared memory buffer into the tty buffer. Must be careful to
* handle the case where we fill up the tty buffer, but still have
* more chars to unload.
*/
static void stli_read(stlibrd_t *brdp, stliport_t *portp)
{
cdkasyrq_t __iomem *rp;
char __iomem *shbuf;
struct tty_struct *tty;
unsigned int head, tail, size;
unsigned int len, stlen;
if (test_bit(ST_RXSTOP, &portp->state))
return;
tty = portp->tty;
if (tty == NULL)
return;
rp = &((cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr))->rxq;
head = (unsigned int) readw(&rp->head);
if (head != ((unsigned int) readw(&rp->head)))
head = (unsigned int) readw(&rp->head);
tail = (unsigned int) readw(&rp->tail);
size = portp->rxsize;
if (head >= tail) {
len = head - tail;
stlen = len;
} else {
len = size - (tail - head);
stlen = size - tail;
}
[PATCH] TTY layer buffering revamp The API and code have been through various bits of initial review by serial driver people but they definitely need to live somewhere for a while so the unconverted drivers can get knocked into shape, existing drivers that have been updated can be better tuned and bugs whacked out. This replaces the tty flip buffers with kmalloc objects in rings. In the normal situation for an IRQ driven serial port at typical speeds the behaviour is pretty much the same, two buffers end up allocated and the kernel cycles between them as before. When there are delays or at high speed we now behave far better as the buffer pool can grow a bit rather than lose characters. This also means that we can operate at higher speeds reliably. For drivers that receive characters in blocks (DMA based, USB and especially virtualisation) the layer allows a lot of driver specific code that works around the tty layer with private secondary queues to be removed. The IBM folks need this sort of layer, the smart serial port people do, the virtualisers do (because a virtualised tty typically operates at infinite speed rather than emulating 9600 baud). Finally many drivers had invalid and unsafe attempts to avoid buffer overflows by directly invoking tty methods extracted out of the innards of work queue structs. These are no longer needed and all go away. That fixes various random hangs with serial ports on overflow. The other change in here is to optimise the receive_room path that is used by some callers. It turns out that only one ldisc uses receive room except asa constant and it updates it far far less than the value is read. We thus make it a variable not a function call. I expect the code to contain bugs due to the size alone but I'll be watching and squashing them and feeding out new patches as it goes. Because the buffers now dynamically expand you should only run out of buffering when the kernel runs out of memory for real. That means a lot of the horrible hacks high performance drivers used to do just aren't needed any more. Description: tty_insert_flip_char is an old API and continues to work as before, as does tty_flip_buffer_push() [this is why many drivers dont need modification]. It does now also return the number of chars inserted There are also tty_buffer_request_room(tty, len) which asks for a buffer block of the length requested and returns the space found. This improves efficiency with hardware that knows how much to transfer. and tty_insert_flip_string_flags(tty, str, flags, len) to insert a string of characters and flags For a smart interface the usual code is len = tty_request_buffer_room(tty, amount_hardware_says); tty_insert_flip_string(tty, buffer_from_card, len); More description! At the moment tty buffers are attached directly to the tty. This is causing a lot of the problems related to tty layer locking, also problems at high speed and also with bursty data (such as occurs in virtualised environments) I'm working on ripping out the flip buffers and replacing them with a pool of dynamically allocated buffers. This allows both for old style "byte I/O" devices and also helps virtualisation and smart devices where large blocks of data suddenely materialise and need storing. So far so good. Lots of drivers reference tty->flip.*. Several of them also call directly and unsafely into function pointers it provides. This will all break. Most drivers can use tty_insert_flip_char which can be kept as an API but others need more. At the moment I've added the following interfaces, if people think more will be needed now is a good time to say int tty_buffer_request_room(tty, size) Try and ensure at least size bytes are available, returns actual room (may be zero). At the moment it just uses the flipbuf space but that will change. Repeated calls without characters being added are not cumulative. (ie if you call it with 1, 1, 1, and then 4 you'll have four characters of space. The other functions will also try and grow buffers in future but this will be a more efficient way when you know block sizes. int tty_insert_flip_char(tty, ch, flag) As before insert a character if there is room. Now returns 1 for success, 0 for failure. int tty_insert_flip_string(tty, str, len) Insert a block of non error characters. Returns the number inserted. int tty_prepare_flip_string(tty, strptr, len) Adjust the buffer to allow len characters to be added. Returns a buffer pointer in strptr and the length available. This allows for hardware that needs to use functions like insl or mencpy_fromio. Signed-off-by: Alan Cox <alan@redhat.com> Cc: Paul Fulghum <paulkf@microgate.com> Signed-off-by: Hirokazu Takata <takata@linux-m32r.org> Signed-off-by: Serge Hallyn <serue@us.ibm.com> Signed-off-by: Jeff Dike <jdike@addtoit.com> Signed-off-by: John Hawkes <hawkes@sgi.com> Signed-off-by: Martin Schwidefsky <schwidefsky@de.ibm.com> Signed-off-by: Adrian Bunk <bunk@stusta.de> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2006-01-09 23:54:13 -05:00
len = tty_buffer_request_room(tty, len);
shbuf = (char __iomem *) EBRDGETMEMPTR(brdp, portp->rxoffset);
while (len > 0) {
unsigned char *cptr;
stlen = MIN(len, stlen);
tty_prepare_flip_string(tty, &cptr, stlen);
memcpy_fromio(cptr, shbuf + tail, stlen);
len -= stlen;
tail += stlen;
if (tail >= size) {
tail = 0;
stlen = head;
}
}
rp = &((cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr))->rxq;
writew(tail, &rp->tail);
if (head != tail)
set_bit(ST_RXING, &portp->state);
tty_schedule_flip(tty);
}
/*****************************************************************************/
/*
* Set up and carry out any delayed commands. There is only a small set
* of slave commands that can be done "off-level". So it is not too
* difficult to deal with them here.
*/
static void stli_dodelaycmd(stliport_t *portp, cdkctrl_t __iomem *cp)
{
int cmd;
if (test_bit(ST_DOSIGS, &portp->state)) {
if (test_bit(ST_DOFLUSHTX, &portp->state) &&
test_bit(ST_DOFLUSHRX, &portp->state))
cmd = A_SETSIGNALSF;
else if (test_bit(ST_DOFLUSHTX, &portp->state))
cmd = A_SETSIGNALSFTX;
else if (test_bit(ST_DOFLUSHRX, &portp->state))
cmd = A_SETSIGNALSFRX;
else
cmd = A_SETSIGNALS;
clear_bit(ST_DOFLUSHTX, &portp->state);
clear_bit(ST_DOFLUSHRX, &portp->state);
clear_bit(ST_DOSIGS, &portp->state);
memcpy_toio((void __iomem *) &(cp->args[0]), (void *) &portp->asig,
sizeof(asysigs_t));
writel(0, &cp->status);
writel(cmd, &cp->cmd);
set_bit(ST_CMDING, &portp->state);
} else if (test_bit(ST_DOFLUSHTX, &portp->state) ||
test_bit(ST_DOFLUSHRX, &portp->state)) {
cmd = ((test_bit(ST_DOFLUSHTX, &portp->state)) ? FLUSHTX : 0);
cmd |= ((test_bit(ST_DOFLUSHRX, &portp->state)) ? FLUSHRX : 0);
clear_bit(ST_DOFLUSHTX, &portp->state);
clear_bit(ST_DOFLUSHRX, &portp->state);
memcpy_toio((void __iomem *) &(cp->args[0]), (void *) &cmd, sizeof(int));
writel(0, &cp->status);
writel(A_FLUSH, &cp->cmd);
set_bit(ST_CMDING, &portp->state);
}
}
/*****************************************************************************/
/*
* Host command service checking. This handles commands or messages
* coming from the slave to the host. Must have board shared memory
* enabled and interrupts off when called. Notice that by servicing the
* read data last we don't need to change the shared memory pointer
* during processing (which is a slow IO operation).
* Return value indicates if this port is still awaiting actions from
* the slave (like open, command, or even TX data being sent). If 0
* then port is still busy, otherwise no longer busy.
*/
static int stli_hostcmd(stlibrd_t *brdp, stliport_t *portp)
{
cdkasy_t __iomem *ap;
cdkctrl_t __iomem *cp;
struct tty_struct *tty;
asynotify_t nt;
unsigned long oldsigs;
int rc, donerx;
ap = (cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr);
cp = &ap->ctrl;
/*
* Check if we are waiting for an open completion message.
*/
if (test_bit(ST_OPENING, &portp->state)) {
rc = readl(&cp->openarg);
if (readb(&cp->open) == 0 && rc != 0) {
if (rc > 0)
rc--;
writel(0, &cp->openarg);
portp->rc = rc;
clear_bit(ST_OPENING, &portp->state);
wake_up_interruptible(&portp->raw_wait);
}
}
/*
* Check if we are waiting for a close completion message.
*/
if (test_bit(ST_CLOSING, &portp->state)) {
rc = (int) readl(&cp->closearg);
if (readb(&cp->close) == 0 && rc != 0) {
if (rc > 0)
rc--;
writel(0, &cp->closearg);
portp->rc = rc;
clear_bit(ST_CLOSING, &portp->state);
wake_up_interruptible(&portp->raw_wait);
}
}
/*
* Check if we are waiting for a command completion message. We may
* need to copy out the command results associated with this command.
*/
if (test_bit(ST_CMDING, &portp->state)) {
rc = readl(&cp->status);
if (readl(&cp->cmd) == 0 && rc != 0) {
if (rc > 0)
rc--;
if (portp->argp != NULL) {
memcpy_fromio(portp->argp, (void __iomem *) &(cp->args[0]),
portp->argsize);
portp->argp = NULL;
}
writel(0, &cp->status);
portp->rc = rc;
clear_bit(ST_CMDING, &portp->state);
stli_dodelaycmd(portp, cp);
wake_up_interruptible(&portp->raw_wait);
}
}
/*
* Check for any notification messages ready. This includes lots of
* different types of events - RX chars ready, RX break received,
* TX data low or empty in the slave, modem signals changed state.
*/
donerx = 0;
if (ap->notify) {
nt = ap->changed;
ap->notify = 0;
tty = portp->tty;
if (nt.signal & SG_DCD) {
oldsigs = portp->sigs;
portp->sigs = stli_mktiocm(nt.sigvalue);
clear_bit(ST_GETSIGS, &portp->state);
if ((portp->sigs & TIOCM_CD) &&
((oldsigs & TIOCM_CD) == 0))
wake_up_interruptible(&portp->open_wait);
if ((oldsigs & TIOCM_CD) &&
((portp->sigs & TIOCM_CD) == 0)) {
if (portp->flags & ASYNC_CHECK_CD) {
if (tty)
schedule_work(&portp->tqhangup);
}
}
}
if (nt.data & DT_TXEMPTY)
clear_bit(ST_TXBUSY, &portp->state);
if (nt.data & (DT_TXEMPTY | DT_TXLOW)) {
if (tty != NULL) {
tty_wakeup(tty);
EBRDENABLE(brdp);
wake_up_interruptible(&tty->write_wait);
}
}
if ((nt.data & DT_RXBREAK) && (portp->rxmarkmsk & BRKINT)) {
if (tty != NULL) {
[PATCH] TTY layer buffering revamp The API and code have been through various bits of initial review by serial driver people but they definitely need to live somewhere for a while so the unconverted drivers can get knocked into shape, existing drivers that have been updated can be better tuned and bugs whacked out. This replaces the tty flip buffers with kmalloc objects in rings. In the normal situation for an IRQ driven serial port at typical speeds the behaviour is pretty much the same, two buffers end up allocated and the kernel cycles between them as before. When there are delays or at high speed we now behave far better as the buffer pool can grow a bit rather than lose characters. This also means that we can operate at higher speeds reliably. For drivers that receive characters in blocks (DMA based, USB and especially virtualisation) the layer allows a lot of driver specific code that works around the tty layer with private secondary queues to be removed. The IBM folks need this sort of layer, the smart serial port people do, the virtualisers do (because a virtualised tty typically operates at infinite speed rather than emulating 9600 baud). Finally many drivers had invalid and unsafe attempts to avoid buffer overflows by directly invoking tty methods extracted out of the innards of work queue structs. These are no longer needed and all go away. That fixes various random hangs with serial ports on overflow. The other change in here is to optimise the receive_room path that is used by some callers. It turns out that only one ldisc uses receive room except asa constant and it updates it far far less than the value is read. We thus make it a variable not a function call. I expect the code to contain bugs due to the size alone but I'll be watching and squashing them and feeding out new patches as it goes. Because the buffers now dynamically expand you should only run out of buffering when the kernel runs out of memory for real. That means a lot of the horrible hacks high performance drivers used to do just aren't needed any more. Description: tty_insert_flip_char is an old API and continues to work as before, as does tty_flip_buffer_push() [this is why many drivers dont need modification]. It does now also return the number of chars inserted There are also tty_buffer_request_room(tty, len) which asks for a buffer block of the length requested and returns the space found. This improves efficiency with hardware that knows how much to transfer. and tty_insert_flip_string_flags(tty, str, flags, len) to insert a string of characters and flags For a smart interface the usual code is len = tty_request_buffer_room(tty, amount_hardware_says); tty_insert_flip_string(tty, buffer_from_card, len); More description! At the moment tty buffers are attached directly to the tty. This is causing a lot of the problems related to tty layer locking, also problems at high speed and also with bursty data (such as occurs in virtualised environments) I'm working on ripping out the flip buffers and replacing them with a pool of dynamically allocated buffers. This allows both for old style "byte I/O" devices and also helps virtualisation and smart devices where large blocks of data suddenely materialise and need storing. So far so good. Lots of drivers reference tty->flip.*. Several of them also call directly and unsafely into function pointers it provides. This will all break. Most drivers can use tty_insert_flip_char which can be kept as an API but others need more. At the moment I've added the following interfaces, if people think more will be needed now is a good time to say int tty_buffer_request_room(tty, size) Try and ensure at least size bytes are available, returns actual room (may be zero). At the moment it just uses the flipbuf space but that will change. Repeated calls without characters being added are not cumulative. (ie if you call it with 1, 1, 1, and then 4 you'll have four characters of space. The other functions will also try and grow buffers in future but this will be a more efficient way when you know block sizes. int tty_insert_flip_char(tty, ch, flag) As before insert a character if there is room. Now returns 1 for success, 0 for failure. int tty_insert_flip_string(tty, str, len) Insert a block of non error characters. Returns the number inserted. int tty_prepare_flip_string(tty, strptr, len) Adjust the buffer to allow len characters to be added. Returns a buffer pointer in strptr and the length available. This allows for hardware that needs to use functions like insl or mencpy_fromio. Signed-off-by: Alan Cox <alan@redhat.com> Cc: Paul Fulghum <paulkf@microgate.com> Signed-off-by: Hirokazu Takata <takata@linux-m32r.org> Signed-off-by: Serge Hallyn <serue@us.ibm.com> Signed-off-by: Jeff Dike <jdike@addtoit.com> Signed-off-by: John Hawkes <hawkes@sgi.com> Signed-off-by: Martin Schwidefsky <schwidefsky@de.ibm.com> Signed-off-by: Adrian Bunk <bunk@stusta.de> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2006-01-09 23:54:13 -05:00
tty_insert_flip_char(tty, 0, TTY_BREAK);
if (portp->flags & ASYNC_SAK) {
do_SAK(tty);
EBRDENABLE(brdp);
}
[PATCH] TTY layer buffering revamp The API and code have been through various bits of initial review by serial driver people but they definitely need to live somewhere for a while so the unconverted drivers can get knocked into shape, existing drivers that have been updated can be better tuned and bugs whacked out. This replaces the tty flip buffers with kmalloc objects in rings. In the normal situation for an IRQ driven serial port at typical speeds the behaviour is pretty much the same, two buffers end up allocated and the kernel cycles between them as before. When there are delays or at high speed we now behave far better as the buffer pool can grow a bit rather than lose characters. This also means that we can operate at higher speeds reliably. For drivers that receive characters in blocks (DMA based, USB and especially virtualisation) the layer allows a lot of driver specific code that works around the tty layer with private secondary queues to be removed. The IBM folks need this sort of layer, the smart serial port people do, the virtualisers do (because a virtualised tty typically operates at infinite speed rather than emulating 9600 baud). Finally many drivers had invalid and unsafe attempts to avoid buffer overflows by directly invoking tty methods extracted out of the innards of work queue structs. These are no longer needed and all go away. That fixes various random hangs with serial ports on overflow. The other change in here is to optimise the receive_room path that is used by some callers. It turns out that only one ldisc uses receive room except asa constant and it updates it far far less than the value is read. We thus make it a variable not a function call. I expect the code to contain bugs due to the size alone but I'll be watching and squashing them and feeding out new patches as it goes. Because the buffers now dynamically expand you should only run out of buffering when the kernel runs out of memory for real. That means a lot of the horrible hacks high performance drivers used to do just aren't needed any more. Description: tty_insert_flip_char is an old API and continues to work as before, as does tty_flip_buffer_push() [this is why many drivers dont need modification]. It does now also return the number of chars inserted There are also tty_buffer_request_room(tty, len) which asks for a buffer block of the length requested and returns the space found. This improves efficiency with hardware that knows how much to transfer. and tty_insert_flip_string_flags(tty, str, flags, len) to insert a string of characters and flags For a smart interface the usual code is len = tty_request_buffer_room(tty, amount_hardware_says); tty_insert_flip_string(tty, buffer_from_card, len); More description! At the moment tty buffers are attached directly to the tty. This is causing a lot of the problems related to tty layer locking, also problems at high speed and also with bursty data (such as occurs in virtualised environments) I'm working on ripping out the flip buffers and replacing them with a pool of dynamically allocated buffers. This allows both for old style "byte I/O" devices and also helps virtualisation and smart devices where large blocks of data suddenely materialise and need storing. So far so good. Lots of drivers reference tty->flip.*. Several of them also call directly and unsafely into function pointers it provides. This will all break. Most drivers can use tty_insert_flip_char which can be kept as an API but others need more. At the moment I've added the following interfaces, if people think more will be needed now is a good time to say int tty_buffer_request_room(tty, size) Try and ensure at least size bytes are available, returns actual room (may be zero). At the moment it just uses the flipbuf space but that will change. Repeated calls without characters being added are not cumulative. (ie if you call it with 1, 1, 1, and then 4 you'll have four characters of space. The other functions will also try and grow buffers in future but this will be a more efficient way when you know block sizes. int tty_insert_flip_char(tty, ch, flag) As before insert a character if there is room. Now returns 1 for success, 0 for failure. int tty_insert_flip_string(tty, str, len) Insert a block of non error characters. Returns the number inserted. int tty_prepare_flip_string(tty, strptr, len) Adjust the buffer to allow len characters to be added. Returns a buffer pointer in strptr and the length available. This allows for hardware that needs to use functions like insl or mencpy_fromio. Signed-off-by: Alan Cox <alan@redhat.com> Cc: Paul Fulghum <paulkf@microgate.com> Signed-off-by: Hirokazu Takata <takata@linux-m32r.org> Signed-off-by: Serge Hallyn <serue@us.ibm.com> Signed-off-by: Jeff Dike <jdike@addtoit.com> Signed-off-by: John Hawkes <hawkes@sgi.com> Signed-off-by: Martin Schwidefsky <schwidefsky@de.ibm.com> Signed-off-by: Adrian Bunk <bunk@stusta.de> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2006-01-09 23:54:13 -05:00
tty_schedule_flip(tty);
}
}
if (nt.data & DT_RXBUSY) {
donerx++;
stli_read(brdp, portp);
}
}
/*
* It might seem odd that we are checking for more RX chars here.
* But, we need to handle the case where the tty buffer was previously
* filled, but we had more characters to pass up. The slave will not
* send any more RX notify messages until the RX buffer has been emptied.
* But it will leave the service bits on (since the buffer is not empty).
* So from here we can try to process more RX chars.
*/
if ((!donerx) && test_bit(ST_RXING, &portp->state)) {
clear_bit(ST_RXING, &portp->state);
stli_read(brdp, portp);
}
return((test_bit(ST_OPENING, &portp->state) ||
test_bit(ST_CLOSING, &portp->state) ||
test_bit(ST_CMDING, &portp->state) ||
test_bit(ST_TXBUSY, &portp->state) ||
test_bit(ST_RXING, &portp->state)) ? 0 : 1);
}
/*****************************************************************************/
/*
* Service all ports on a particular board. Assumes that the boards
* shared memory is enabled, and that the page pointer is pointed
* at the cdk header structure.
*/
static void stli_brdpoll(stlibrd_t *brdp, cdkhdr_t __iomem *hdrp)
{
stliport_t *portp;
unsigned char hostbits[(STL_MAXCHANS / 8) + 1];
unsigned char slavebits[(STL_MAXCHANS / 8) + 1];
unsigned char __iomem *slavep;
int bitpos, bitat, bitsize;
int channr, nrdevs, slavebitchange;
bitsize = brdp->bitsize;
nrdevs = brdp->nrdevs;
/*
* Check if slave wants any service. Basically we try to do as
* little work as possible here. There are 2 levels of service
* bits. So if there is nothing to do we bail early. We check
* 8 service bits at a time in the inner loop, so we can bypass
* the lot if none of them want service.
*/
memcpy_fromio(&hostbits[0], (((unsigned char __iomem *) hdrp) + brdp->hostoffset),
bitsize);
memset(&slavebits[0], 0, bitsize);
slavebitchange = 0;
for (bitpos = 0; (bitpos < bitsize); bitpos++) {
if (hostbits[bitpos] == 0)
continue;
channr = bitpos * 8;
for (bitat = 0x1; (channr < nrdevs); channr++, bitat <<= 1) {
if (hostbits[bitpos] & bitat) {
portp = brdp->ports[(channr - 1)];
if (stli_hostcmd(brdp, portp)) {
slavebitchange++;
slavebits[bitpos] |= bitat;
}
}
}
}
/*
* If any of the ports are no longer busy then update them in the
* slave request bits. We need to do this after, since a host port
* service may initiate more slave requests.
*/
if (slavebitchange) {
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
slavep = ((unsigned char __iomem *) hdrp) + brdp->slaveoffset;
for (bitpos = 0; (bitpos < bitsize); bitpos++) {
if (readb(slavebits + bitpos))
writeb(readb(slavep + bitpos) & ~slavebits[bitpos], slavebits + bitpos);
}
}
}
/*****************************************************************************/
/*
* Driver poll routine. This routine polls the boards in use and passes
* messages back up to host when necessary. This is actually very
* CPU efficient, since we will always have the kernel poll clock, it
* adds only a few cycles when idle (since board service can be
* determined very easily), but when loaded generates no interrupts
* (with their expensive associated context change).
*/
static void stli_poll(unsigned long arg)
{
cdkhdr_t __iomem *hdrp;
stlibrd_t *brdp;
int brdnr;
stli_timerlist.expires = STLI_TIMEOUT;
add_timer(&stli_timerlist);
/*
* Check each board and do any servicing required.
*/
for (brdnr = 0; (brdnr < stli_nrbrds); brdnr++) {
brdp = stli_brds[brdnr];
if (brdp == NULL)
continue;
if ((brdp->state & BST_STARTED) == 0)
continue;
spin_lock(&brd_lock);
EBRDENABLE(brdp);
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
if (readb(&hdrp->hostreq))
stli_brdpoll(brdp, hdrp);
EBRDDISABLE(brdp);
spin_unlock(&brd_lock);
}
}
/*****************************************************************************/
/*
* Translate the termios settings into the port setting structure of
* the slave.
*/
static void stli_mkasyport(stliport_t *portp, asyport_t *pp, struct termios *tiosp)
{
memset(pp, 0, sizeof(asyport_t));
/*
* Start of by setting the baud, char size, parity and stop bit info.
*/
pp->baudout = tty_get_baud_rate(portp->tty);
if ((tiosp->c_cflag & CBAUD) == B38400) {
if ((portp->flags & ASYNC_SPD_MASK) == ASYNC_SPD_HI)
pp->baudout = 57600;
else if ((portp->flags & ASYNC_SPD_MASK) == ASYNC_SPD_VHI)
pp->baudout = 115200;
else if ((portp->flags & ASYNC_SPD_MASK) == ASYNC_SPD_SHI)
pp->baudout = 230400;
else if ((portp->flags & ASYNC_SPD_MASK) == ASYNC_SPD_WARP)
pp->baudout = 460800;
else if ((portp->flags & ASYNC_SPD_MASK) == ASYNC_SPD_CUST)
pp->baudout = (portp->baud_base / portp->custom_divisor);
}
if (pp->baudout > STL_MAXBAUD)
pp->baudout = STL_MAXBAUD;
pp->baudin = pp->baudout;
switch (tiosp->c_cflag & CSIZE) {
case CS5:
pp->csize = 5;
break;
case CS6:
pp->csize = 6;
break;
case CS7:
pp->csize = 7;
break;
default:
pp->csize = 8;
break;
}
if (tiosp->c_cflag & CSTOPB)
pp->stopbs = PT_STOP2;
else
pp->stopbs = PT_STOP1;
if (tiosp->c_cflag & PARENB) {
if (tiosp->c_cflag & PARODD)
pp->parity = PT_ODDPARITY;
else
pp->parity = PT_EVENPARITY;
} else {
pp->parity = PT_NOPARITY;
}
/*
* Set up any flow control options enabled.
*/
if (tiosp->c_iflag & IXON) {
pp->flow |= F_IXON;
if (tiosp->c_iflag & IXANY)
pp->flow |= F_IXANY;
}
if (tiosp->c_cflag & CRTSCTS)
pp->flow |= (F_RTSFLOW | F_CTSFLOW);
pp->startin = tiosp->c_cc[VSTART];
pp->stopin = tiosp->c_cc[VSTOP];
pp->startout = tiosp->c_cc[VSTART];
pp->stopout = tiosp->c_cc[VSTOP];
/*
* Set up the RX char marking mask with those RX error types we must
* catch. We can get the slave to help us out a little here, it will
* ignore parity errors and breaks for us, and mark parity errors in
* the data stream.
*/
if (tiosp->c_iflag & IGNPAR)
pp->iflag |= FI_IGNRXERRS;
if (tiosp->c_iflag & IGNBRK)
pp->iflag |= FI_IGNBREAK;
portp->rxmarkmsk = 0;
if (tiosp->c_iflag & (INPCK | PARMRK))
pp->iflag |= FI_1MARKRXERRS;
if (tiosp->c_iflag & BRKINT)
portp->rxmarkmsk |= BRKINT;
/*
* Set up clocal processing as required.
*/
if (tiosp->c_cflag & CLOCAL)
portp->flags &= ~ASYNC_CHECK_CD;
else
portp->flags |= ASYNC_CHECK_CD;
/*
* Transfer any persistent flags into the asyport structure.
*/
pp->pflag = (portp->pflag & 0xffff);
pp->vmin = (portp->pflag & P_RXIMIN) ? 1 : 0;
pp->vtime = (portp->pflag & P_RXITIME) ? 1 : 0;
pp->cc[1] = (portp->pflag & P_RXTHOLD) ? 1 : 0;
}
/*****************************************************************************/
/*
* Construct a slave signals structure for setting the DTR and RTS
* signals as specified.
*/
static void stli_mkasysigs(asysigs_t *sp, int dtr, int rts)
{
memset(sp, 0, sizeof(asysigs_t));
if (dtr >= 0) {
sp->signal |= SG_DTR;
sp->sigvalue |= ((dtr > 0) ? SG_DTR : 0);
}
if (rts >= 0) {
sp->signal |= SG_RTS;
sp->sigvalue |= ((rts > 0) ? SG_RTS : 0);
}
}
/*****************************************************************************/
/*
* Convert the signals returned from the slave into a local TIOCM type
* signals value. We keep them locally in TIOCM format.
*/
static long stli_mktiocm(unsigned long sigvalue)
{
long tiocm = 0;
tiocm |= ((sigvalue & SG_DCD) ? TIOCM_CD : 0);
tiocm |= ((sigvalue & SG_CTS) ? TIOCM_CTS : 0);
tiocm |= ((sigvalue & SG_RI) ? TIOCM_RI : 0);
tiocm |= ((sigvalue & SG_DSR) ? TIOCM_DSR : 0);
tiocm |= ((sigvalue & SG_DTR) ? TIOCM_DTR : 0);
tiocm |= ((sigvalue & SG_RTS) ? TIOCM_RTS : 0);
return(tiocm);
}
/*****************************************************************************/
/*
* All panels and ports actually attached have been worked out. All
* we need to do here is set up the appropriate per port data structures.
*/
static int stli_initports(stlibrd_t *brdp)
{
stliport_t *portp;
int i, panelnr, panelport;
for (i = 0, panelnr = 0, panelport = 0; (i < brdp->nrports); i++) {
portp = kzalloc(sizeof(stliport_t), GFP_KERNEL);
if (!portp) {
printk("STALLION: failed to allocate port structure\n");
continue;
}
portp->magic = STLI_PORTMAGIC;
portp->portnr = i;
portp->brdnr = brdp->brdnr;
portp->panelnr = panelnr;
portp->baud_base = STL_BAUDBASE;
portp->close_delay = STL_CLOSEDELAY;
portp->closing_wait = 30 * HZ;
INIT_WORK(&portp->tqhangup, stli_dohangup, portp);
init_waitqueue_head(&portp->open_wait);
init_waitqueue_head(&portp->close_wait);
init_waitqueue_head(&portp->raw_wait);
panelport++;
if (panelport >= brdp->panels[panelnr]) {
panelport = 0;
panelnr++;
}
brdp->ports[i] = portp;
}
return 0;
}
/*****************************************************************************/
/*
* All the following routines are board specific hardware operations.
*/
static void stli_ecpinit(stlibrd_t *brdp)
{
unsigned long memconf;
outb(ECP_ATSTOP, (brdp->iobase + ECP_ATCONFR));
udelay(10);
outb(ECP_ATDISABLE, (brdp->iobase + ECP_ATCONFR));
udelay(100);
memconf = (brdp->memaddr & ECP_ATADDRMASK) >> ECP_ATADDRSHFT;
outb(memconf, (brdp->iobase + ECP_ATMEMAR));
}
/*****************************************************************************/
static void stli_ecpenable(stlibrd_t *brdp)
{
outb(ECP_ATENABLE, (brdp->iobase + ECP_ATCONFR));
}
/*****************************************************************************/
static void stli_ecpdisable(stlibrd_t *brdp)
{
outb(ECP_ATDISABLE, (brdp->iobase + ECP_ATCONFR));
}
/*****************************************************************************/
static void __iomem *stli_ecpgetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
void __iomem *ptr;
unsigned char val;
if (offset > brdp->memsize) {
printk(KERN_ERR "STALLION: shared memory pointer=%x out of "
"range at line=%d(%d), brd=%d\n",
(int) offset, line, __LINE__, brdp->brdnr);
ptr = NULL;
val = 0;
} else {
ptr = brdp->membase + (offset % ECP_ATPAGESIZE);
val = (unsigned char) (offset / ECP_ATPAGESIZE);
}
outb(val, (brdp->iobase + ECP_ATMEMPR));
return(ptr);
}
/*****************************************************************************/
static void stli_ecpreset(stlibrd_t *brdp)
{
outb(ECP_ATSTOP, (brdp->iobase + ECP_ATCONFR));
udelay(10);
outb(ECP_ATDISABLE, (brdp->iobase + ECP_ATCONFR));
udelay(500);
}
/*****************************************************************************/
static void stli_ecpintr(stlibrd_t *brdp)
{
outb(0x1, brdp->iobase);
}
/*****************************************************************************/
/*
* The following set of functions act on ECP EISA boards.
*/
static void stli_ecpeiinit(stlibrd_t *brdp)
{
unsigned long memconf;
outb(0x1, (brdp->iobase + ECP_EIBRDENAB));
outb(ECP_EISTOP, (brdp->iobase + ECP_EICONFR));
udelay(10);
outb(ECP_EIDISABLE, (brdp->iobase + ECP_EICONFR));
udelay(500);
memconf = (brdp->memaddr & ECP_EIADDRMASKL) >> ECP_EIADDRSHFTL;
outb(memconf, (brdp->iobase + ECP_EIMEMARL));
memconf = (brdp->memaddr & ECP_EIADDRMASKH) >> ECP_EIADDRSHFTH;
outb(memconf, (brdp->iobase + ECP_EIMEMARH));
}
/*****************************************************************************/
static void stli_ecpeienable(stlibrd_t *brdp)
{
outb(ECP_EIENABLE, (brdp->iobase + ECP_EICONFR));
}
/*****************************************************************************/
static void stli_ecpeidisable(stlibrd_t *brdp)
{
outb(ECP_EIDISABLE, (brdp->iobase + ECP_EICONFR));
}
/*****************************************************************************/
static void __iomem *stli_ecpeigetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
void __iomem *ptr;
unsigned char val;
if (offset > brdp->memsize) {
printk(KERN_ERR "STALLION: shared memory pointer=%x out of "
"range at line=%d(%d), brd=%d\n",
(int) offset, line, __LINE__, brdp->brdnr);
ptr = NULL;
val = 0;
} else {
ptr = brdp->membase + (offset % ECP_EIPAGESIZE);
if (offset < ECP_EIPAGESIZE)
val = ECP_EIENABLE;
else
val = ECP_EIENABLE | 0x40;
}
outb(val, (brdp->iobase + ECP_EICONFR));
return(ptr);
}
/*****************************************************************************/
static void stli_ecpeireset(stlibrd_t *brdp)
{
outb(ECP_EISTOP, (brdp->iobase + ECP_EICONFR));
udelay(10);
outb(ECP_EIDISABLE, (brdp->iobase + ECP_EICONFR));
udelay(500);
}
/*****************************************************************************/
/*
* The following set of functions act on ECP MCA boards.
*/
static void stli_ecpmcenable(stlibrd_t *brdp)
{
outb(ECP_MCENABLE, (brdp->iobase + ECP_MCCONFR));
}
/*****************************************************************************/
static void stli_ecpmcdisable(stlibrd_t *brdp)
{
outb(ECP_MCDISABLE, (brdp->iobase + ECP_MCCONFR));
}
/*****************************************************************************/
static void __iomem *stli_ecpmcgetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
void __iomem *ptr;
unsigned char val;
if (offset > brdp->memsize) {
printk(KERN_ERR "STALLION: shared memory pointer=%x out of "
"range at line=%d(%d), brd=%d\n",
(int) offset, line, __LINE__, brdp->brdnr);
ptr = NULL;
val = 0;
} else {
ptr = brdp->membase + (offset % ECP_MCPAGESIZE);
val = ((unsigned char) (offset / ECP_MCPAGESIZE)) | ECP_MCENABLE;
}
outb(val, (brdp->iobase + ECP_MCCONFR));
return(ptr);
}
/*****************************************************************************/
static void stli_ecpmcreset(stlibrd_t *brdp)
{
outb(ECP_MCSTOP, (brdp->iobase + ECP_MCCONFR));
udelay(10);
outb(ECP_MCDISABLE, (brdp->iobase + ECP_MCCONFR));
udelay(500);
}
/*****************************************************************************/
/*
* The following set of functions act on ECP PCI boards.
*/
static void stli_ecppciinit(stlibrd_t *brdp)
{
outb(ECP_PCISTOP, (brdp->iobase + ECP_PCICONFR));
udelay(10);
outb(0, (brdp->iobase + ECP_PCICONFR));
udelay(500);
}
/*****************************************************************************/
static void __iomem *stli_ecppcigetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
void __iomem *ptr;
unsigned char val;
if (offset > brdp->memsize) {
printk(KERN_ERR "STALLION: shared memory pointer=%x out of "
"range at line=%d(%d), board=%d\n",
(int) offset, line, __LINE__, brdp->brdnr);
ptr = NULL;
val = 0;
} else {
ptr = brdp->membase + (offset % ECP_PCIPAGESIZE);
val = (offset / ECP_PCIPAGESIZE) << 1;
}
outb(val, (brdp->iobase + ECP_PCICONFR));
return(ptr);
}
/*****************************************************************************/
static void stli_ecppcireset(stlibrd_t *brdp)
{
outb(ECP_PCISTOP, (brdp->iobase + ECP_PCICONFR));
udelay(10);
outb(0, (brdp->iobase + ECP_PCICONFR));
udelay(500);
}
/*****************************************************************************/
/*
* The following routines act on ONboards.
*/
static void stli_onbinit(stlibrd_t *brdp)
{
unsigned long memconf;
outb(ONB_ATSTOP, (brdp->iobase + ONB_ATCONFR));
udelay(10);
outb(ONB_ATDISABLE, (brdp->iobase + ONB_ATCONFR));
mdelay(1000);
memconf = (brdp->memaddr & ONB_ATADDRMASK) >> ONB_ATADDRSHFT;
outb(memconf, (brdp->iobase + ONB_ATMEMAR));
outb(0x1, brdp->iobase);
mdelay(1);
}
/*****************************************************************************/
static void stli_onbenable(stlibrd_t *brdp)
{
outb((brdp->enabval | ONB_ATENABLE), (brdp->iobase + ONB_ATCONFR));
}
/*****************************************************************************/
static void stli_onbdisable(stlibrd_t *brdp)
{
outb((brdp->enabval | ONB_ATDISABLE), (brdp->iobase + ONB_ATCONFR));
}
/*****************************************************************************/
static void __iomem *stli_onbgetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
void __iomem *ptr;
if (offset > brdp->memsize) {
printk(KERN_ERR "STALLION: shared memory pointer=%x out of "
"range at line=%d(%d), brd=%d\n",
(int) offset, line, __LINE__, brdp->brdnr);
ptr = NULL;
} else {
ptr = brdp->membase + (offset % ONB_ATPAGESIZE);
}
return(ptr);
}
/*****************************************************************************/
static void stli_onbreset(stlibrd_t *brdp)
{
outb(ONB_ATSTOP, (brdp->iobase + ONB_ATCONFR));
udelay(10);
outb(ONB_ATDISABLE, (brdp->iobase + ONB_ATCONFR));
mdelay(1000);
}
/*****************************************************************************/
/*
* The following routines act on ONboard EISA.
*/
static void stli_onbeinit(stlibrd_t *brdp)
{
unsigned long memconf;
outb(0x1, (brdp->iobase + ONB_EIBRDENAB));
outb(ONB_EISTOP, (brdp->iobase + ONB_EICONFR));
udelay(10);
outb(ONB_EIDISABLE, (brdp->iobase + ONB_EICONFR));
mdelay(1000);
memconf = (brdp->memaddr & ONB_EIADDRMASKL) >> ONB_EIADDRSHFTL;
outb(memconf, (brdp->iobase + ONB_EIMEMARL));
memconf = (brdp->memaddr & ONB_EIADDRMASKH) >> ONB_EIADDRSHFTH;
outb(memconf, (brdp->iobase + ONB_EIMEMARH));
outb(0x1, brdp->iobase);
mdelay(1);
}
/*****************************************************************************/
static void stli_onbeenable(stlibrd_t *brdp)
{
outb(ONB_EIENABLE, (brdp->iobase + ONB_EICONFR));
}
/*****************************************************************************/
static void stli_onbedisable(stlibrd_t *brdp)
{
outb(ONB_EIDISABLE, (brdp->iobase + ONB_EICONFR));
}
/*****************************************************************************/
static void __iomem *stli_onbegetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
void __iomem *ptr;
unsigned char val;
if (offset > brdp->memsize) {
printk(KERN_ERR "STALLION: shared memory pointer=%x out of "
"range at line=%d(%d), brd=%d\n",
(int) offset, line, __LINE__, brdp->brdnr);
ptr = NULL;
val = 0;
} else {
ptr = brdp->membase + (offset % ONB_EIPAGESIZE);
if (offset < ONB_EIPAGESIZE)
val = ONB_EIENABLE;
else
val = ONB_EIENABLE | 0x40;
}
outb(val, (brdp->iobase + ONB_EICONFR));
return(ptr);
}
/*****************************************************************************/
static void stli_onbereset(stlibrd_t *brdp)
{
outb(ONB_EISTOP, (brdp->iobase + ONB_EICONFR));
udelay(10);
outb(ONB_EIDISABLE, (brdp->iobase + ONB_EICONFR));
mdelay(1000);
}
/*****************************************************************************/
/*
* The following routines act on Brumby boards.
*/
static void stli_bbyinit(stlibrd_t *brdp)
{
outb(BBY_ATSTOP, (brdp->iobase + BBY_ATCONFR));
udelay(10);
outb(0, (brdp->iobase + BBY_ATCONFR));
mdelay(1000);
outb(0x1, brdp->iobase);
mdelay(1);
}
/*****************************************************************************/
static void __iomem *stli_bbygetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
void __iomem *ptr;
unsigned char val;
BUG_ON(offset > brdp->memsize);
ptr = brdp->membase + (offset % BBY_PAGESIZE);
val = (unsigned char) (offset / BBY_PAGESIZE);
outb(val, (brdp->iobase + BBY_ATCONFR));
return(ptr);
}
/*****************************************************************************/
static void stli_bbyreset(stlibrd_t *brdp)
{
outb(BBY_ATSTOP, (brdp->iobase + BBY_ATCONFR));
udelay(10);
outb(0, (brdp->iobase + BBY_ATCONFR));
mdelay(1000);
}
/*****************************************************************************/
/*
* The following routines act on original old Stallion boards.
*/
static void stli_stalinit(stlibrd_t *brdp)
{
outb(0x1, brdp->iobase);
mdelay(1000);
}
/*****************************************************************************/
static void __iomem *stli_stalgetmemptr(stlibrd_t *brdp, unsigned long offset, int line)
{
BUG_ON(offset > brdp->memsize);
return brdp->membase + (offset % STAL_PAGESIZE);
}
/*****************************************************************************/
static void stli_stalreset(stlibrd_t *brdp)
{
u32 __iomem *vecp;
vecp = (u32 __iomem *) (brdp->membase + 0x30);
writel(0xffff0000, vecp);
outb(0, brdp->iobase);
mdelay(1000);
}
/*****************************************************************************/
/*
* Try to find an ECP board and initialize it. This handles only ECP
* board types.
*/
static int stli_initecp(stlibrd_t *brdp)
{
cdkecpsig_t sig;
cdkecpsig_t __iomem *sigsp;
unsigned int status, nxtid;
char *name;
int panelnr, nrports;
if (!request_region(brdp->iobase, brdp->iosize, "istallion"))
return -EIO;
if ((brdp->iobase == 0) || (brdp->memaddr == 0))
{
release_region(brdp->iobase, brdp->iosize);
return -ENODEV;
}
brdp->iosize = ECP_IOSIZE;
/*
* Based on the specific board type setup the common vars to access
* and enable shared memory. Set all board specific information now
* as well.
*/
switch (brdp->brdtype) {
case BRD_ECP:
brdp->membase = (void *) brdp->memaddr;
brdp->memsize = ECP_MEMSIZE;
brdp->pagesize = ECP_ATPAGESIZE;
brdp->init = stli_ecpinit;
brdp->enable = stli_ecpenable;
brdp->reenable = stli_ecpenable;
brdp->disable = stli_ecpdisable;
brdp->getmemptr = stli_ecpgetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_ecpreset;
name = "serial(EC8/64)";
break;
case BRD_ECPE:
brdp->membase = (void *) brdp->memaddr;
brdp->memsize = ECP_MEMSIZE;
brdp->pagesize = ECP_EIPAGESIZE;
brdp->init = stli_ecpeiinit;
brdp->enable = stli_ecpeienable;
brdp->reenable = stli_ecpeienable;
brdp->disable = stli_ecpeidisable;
brdp->getmemptr = stli_ecpeigetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_ecpeireset;
name = "serial(EC8/64-EI)";
break;
case BRD_ECPMC:
brdp->membase = (void *) brdp->memaddr;
brdp->memsize = ECP_MEMSIZE;
brdp->pagesize = ECP_MCPAGESIZE;
brdp->init = NULL;
brdp->enable = stli_ecpmcenable;
brdp->reenable = stli_ecpmcenable;
brdp->disable = stli_ecpmcdisable;
brdp->getmemptr = stli_ecpmcgetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_ecpmcreset;
name = "serial(EC8/64-MCA)";
break;
case BRD_ECPPCI:
brdp->membase = (void *) brdp->memaddr;
brdp->memsize = ECP_PCIMEMSIZE;
brdp->pagesize = ECP_PCIPAGESIZE;
brdp->init = stli_ecppciinit;
brdp->enable = NULL;
brdp->reenable = NULL;
brdp->disable = NULL;
brdp->getmemptr = stli_ecppcigetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_ecppcireset;
name = "serial(EC/RA-PCI)";
break;
default:
release_region(brdp->iobase, brdp->iosize);
return -EINVAL;
}
/*
* The per-board operations structure is all set up, so now let's go
* and get the board operational. Firstly initialize board configuration
* registers. Set the memory mapping info so we can get at the boards
* shared memory.
*/
EBRDINIT(brdp);
brdp->membase = ioremap(brdp->memaddr, brdp->memsize);
if (brdp->membase == NULL)
{
release_region(brdp->iobase, brdp->iosize);
return -ENOMEM;
}
/*
* Now that all specific code is set up, enable the shared memory and
* look for the a signature area that will tell us exactly what board
* this is, and what it is connected to it.
*/
EBRDENABLE(brdp);
sigsp = (cdkecpsig_t __iomem *) EBRDGETMEMPTR(brdp, CDK_SIGADDR);
memcpy_fromio(&sig, sigsp, sizeof(cdkecpsig_t));
EBRDDISABLE(brdp);
if (sig.magic != cpu_to_le32(ECP_MAGIC))
{
release_region(brdp->iobase, brdp->iosize);
return -ENODEV;
}
/*
* Scan through the signature looking at the panels connected to the
* board. Calculate the total number of ports as we go.
*/
for (panelnr = 0, nxtid = 0; (panelnr < STL_MAXPANELS); panelnr++) {
status = sig.panelid[nxtid];
if ((status & ECH_PNLIDMASK) != nxtid)
break;
brdp->panelids[panelnr] = status;
nrports = (status & ECH_PNL16PORT) ? 16 : 8;
if ((nrports == 16) && ((status & ECH_PNLXPID) == 0))
nxtid++;
brdp->panels[panelnr] = nrports;
brdp->nrports += nrports;
nxtid++;
brdp->nrpanels++;
}
brdp->state |= BST_FOUND;
return 0;
}
/*****************************************************************************/
/*
* Try to find an ONboard, Brumby or Stallion board and initialize it.
* This handles only these board types.
*/
static int stli_initonb(stlibrd_t *brdp)
{
cdkonbsig_t sig;
cdkonbsig_t __iomem *sigsp;
char *name;
int i;
/*
* Do a basic sanity check on the IO and memory addresses.
*/
if (brdp->iobase == 0 || brdp->memaddr == 0)
return -ENODEV;
brdp->iosize = ONB_IOSIZE;
if (!request_region(brdp->iobase, brdp->iosize, "istallion"))
return -EIO;
/*
* Based on the specific board type setup the common vars to access
* and enable shared memory. Set all board specific information now
* as well.
*/
switch (brdp->brdtype) {
case BRD_ONBOARD:
case BRD_ONBOARD32:
case BRD_ONBOARD2:
case BRD_ONBOARD2_32:
case BRD_ONBOARDRS:
brdp->memsize = ONB_MEMSIZE;
brdp->pagesize = ONB_ATPAGESIZE;
brdp->init = stli_onbinit;
brdp->enable = stli_onbenable;
brdp->reenable = stli_onbenable;
brdp->disable = stli_onbdisable;
brdp->getmemptr = stli_onbgetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_onbreset;
if (brdp->memaddr > 0x100000)
brdp->enabval = ONB_MEMENABHI;
else
brdp->enabval = ONB_MEMENABLO;
name = "serial(ONBoard)";
break;
case BRD_ONBOARDE:
brdp->memsize = ONB_EIMEMSIZE;
brdp->pagesize = ONB_EIPAGESIZE;
brdp->init = stli_onbeinit;
brdp->enable = stli_onbeenable;
brdp->reenable = stli_onbeenable;
brdp->disable = stli_onbedisable;
brdp->getmemptr = stli_onbegetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_onbereset;
name = "serial(ONBoard/E)";
break;
case BRD_BRUMBY4:
case BRD_BRUMBY8:
case BRD_BRUMBY16:
brdp->memsize = BBY_MEMSIZE;
brdp->pagesize = BBY_PAGESIZE;
brdp->init = stli_bbyinit;
brdp->enable = NULL;
brdp->reenable = NULL;
brdp->disable = NULL;
brdp->getmemptr = stli_bbygetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_bbyreset;
name = "serial(Brumby)";
break;
case BRD_STALLION:
brdp->memsize = STAL_MEMSIZE;
brdp->pagesize = STAL_PAGESIZE;
brdp->init = stli_stalinit;
brdp->enable = NULL;
brdp->reenable = NULL;
brdp->disable = NULL;
brdp->getmemptr = stli_stalgetmemptr;
brdp->intr = stli_ecpintr;
brdp->reset = stli_stalreset;
name = "serial(Stallion)";
break;
default:
release_region(brdp->iobase, brdp->iosize);
return -EINVAL;
}
/*
* The per-board operations structure is all set up, so now let's go
* and get the board operational. Firstly initialize board configuration
* registers. Set the memory mapping info so we can get at the boards
* shared memory.
*/
EBRDINIT(brdp);
brdp->membase = ioremap(brdp->memaddr, brdp->memsize);
if (brdp->membase == NULL)
{
release_region(brdp->iobase, brdp->iosize);
return -ENOMEM;
}
/*
* Now that all specific code is set up, enable the shared memory and
* look for the a signature area that will tell us exactly what board
* this is, and how many ports.
*/
EBRDENABLE(brdp);
sigsp = (cdkonbsig_t __iomem *) EBRDGETMEMPTR(brdp, CDK_SIGADDR);
memcpy_fromio(&sig, sigsp, sizeof(cdkonbsig_t));
EBRDDISABLE(brdp);
if (sig.magic0 != cpu_to_le16(ONB_MAGIC0) ||
sig.magic1 != cpu_to_le16(ONB_MAGIC1) ||
sig.magic2 != cpu_to_le16(ONB_MAGIC2) ||
sig.magic3 != cpu_to_le16(ONB_MAGIC3))
{
release_region(brdp->iobase, brdp->iosize);
return -ENODEV;
}
/*
* Scan through the signature alive mask and calculate how many ports
* there are on this board.
*/
brdp->nrpanels = 1;
if (sig.amask1) {
brdp->nrports = 32;
} else {
for (i = 0; (i < 16); i++) {
if (((sig.amask0 << i) & 0x8000) == 0)
break;
}
brdp->nrports = i;
}
brdp->panels[0] = brdp->nrports;
brdp->state |= BST_FOUND;
return 0;
}
/*****************************************************************************/
/*
* Start up a running board. This routine is only called after the
* code has been down loaded to the board and is operational. It will
* read in the memory map, and get the show on the road...
*/
static int stli_startbrd(stlibrd_t *brdp)
{
cdkhdr_t __iomem *hdrp;
cdkmem_t __iomem *memp;
cdkasy_t __iomem *ap;
unsigned long flags;
stliport_t *portp;
int portnr, nrdevs, i, rc = 0;
u32 memoff;
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
hdrp = (cdkhdr_t __iomem *) EBRDGETMEMPTR(brdp, CDK_CDKADDR);
nrdevs = hdrp->nrdevs;
#if 0
printk("%s(%d): CDK version %d.%d.%d --> "
"nrdevs=%d memp=%x hostp=%x slavep=%x\n",
__FILE__, __LINE__, readb(&hdrp->ver_release), readb(&hdrp->ver_modification),
readb(&hdrp->ver_fix), nrdevs, (int) readl(&hdrp->memp), readl(&hdrp->hostp),
readl(&hdrp->slavep));
#endif
if (nrdevs < (brdp->nrports + 1)) {
printk(KERN_ERR "STALLION: slave failed to allocate memory for "
"all devices, devices=%d\n", nrdevs);
brdp->nrports = nrdevs - 1;
}
brdp->nrdevs = nrdevs;
brdp->hostoffset = hdrp->hostp - CDK_CDKADDR;
brdp->slaveoffset = hdrp->slavep - CDK_CDKADDR;
brdp->bitsize = (nrdevs + 7) / 8;
memoff = readl(&hdrp->memp);
if (memoff > brdp->memsize) {
printk(KERN_ERR "STALLION: corrupted shared memory region?\n");
rc = -EIO;
goto stli_donestartup;
}
memp = (cdkmem_t __iomem *) EBRDGETMEMPTR(brdp, memoff);
if (readw(&memp->dtype) != TYP_ASYNCTRL) {
printk(KERN_ERR "STALLION: no slave control device found\n");
goto stli_donestartup;
}
memp++;
/*
* Cycle through memory allocation of each port. We are guaranteed to
* have all ports inside the first page of slave window, so no need to
* change pages while reading memory map.
*/
for (i = 1, portnr = 0; (i < nrdevs); i++, portnr++, memp++) {
if (readw(&memp->dtype) != TYP_ASYNC)
break;
portp = brdp->ports[portnr];
if (portp == NULL)
break;
portp->devnr = i;
portp->addr = readl(&memp->offset);
portp->reqbit = (unsigned char) (0x1 << (i * 8 / nrdevs));
portp->portidx = (unsigned char) (i / 8);
portp->portbit = (unsigned char) (0x1 << (i % 8));
}
writeb(0xff, &hdrp->slavereq);
/*
* For each port setup a local copy of the RX and TX buffer offsets
* and sizes. We do this separate from the above, because we need to
* move the shared memory page...
*/
for (i = 1, portnr = 0; (i < nrdevs); i++, portnr++) {
portp = brdp->ports[portnr];
if (portp == NULL)
break;
if (portp->addr == 0)
break;
ap = (cdkasy_t __iomem *) EBRDGETMEMPTR(brdp, portp->addr);
if (ap != NULL) {
portp->rxsize = readw(&ap->rxq.size);
portp->txsize = readw(&ap->txq.size);
portp->rxoffset = readl(&ap->rxq.offset);
portp->txoffset = readl(&ap->txq.offset);
}
}
stli_donestartup:
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
if (rc == 0)
brdp->state |= BST_STARTED;
if (! stli_timeron) {
stli_timeron++;
stli_timerlist.expires = STLI_TIMEOUT;
add_timer(&stli_timerlist);
}
return rc;
}
/*****************************************************************************/
/*
* Probe and initialize the specified board.
*/
static int __init stli_brdinit(stlibrd_t *brdp)
{
stli_brds[brdp->brdnr] = brdp;
switch (brdp->brdtype) {
case BRD_ECP:
case BRD_ECPE:
case BRD_ECPMC:
case BRD_ECPPCI:
stli_initecp(brdp);
break;
case BRD_ONBOARD:
case BRD_ONBOARDE:
case BRD_ONBOARD2:
case BRD_ONBOARD32:
case BRD_ONBOARD2_32:
case BRD_ONBOARDRS:
case BRD_BRUMBY4:
case BRD_BRUMBY8:
case BRD_BRUMBY16:
case BRD_STALLION:
stli_initonb(brdp);
break;
case BRD_EASYIO:
case BRD_ECH:
case BRD_ECHMC:
case BRD_ECHPCI:
printk(KERN_ERR "STALLION: %s board type not supported in "
"this driver\n", stli_brdnames[brdp->brdtype]);
return -ENODEV;
default:
printk(KERN_ERR "STALLION: board=%d is unknown board "
"type=%d\n", brdp->brdnr, brdp->brdtype);
return -ENODEV;
}
if ((brdp->state & BST_FOUND) == 0) {
printk(KERN_ERR "STALLION: %s board not found, board=%d "
"io=%x mem=%x\n",
stli_brdnames[brdp->brdtype], brdp->brdnr,
brdp->iobase, (int) brdp->memaddr);
return -ENODEV;
}
stli_initports(brdp);
printk(KERN_INFO "STALLION: %s found, board=%d io=%x mem=%x "
"nrpanels=%d nrports=%d\n", stli_brdnames[brdp->brdtype],
brdp->brdnr, brdp->iobase, (int) brdp->memaddr,
brdp->nrpanels, brdp->nrports);
return 0;
}
/*****************************************************************************/
/*
* Probe around trying to find where the EISA boards shared memory
* might be. This is a bit if hack, but it is the best we can do.
*/
static int stli_eisamemprobe(stlibrd_t *brdp)
{
cdkecpsig_t ecpsig, __iomem *ecpsigp;
cdkonbsig_t onbsig, __iomem *onbsigp;
int i, foundit;
/*
* First up we reset the board, to get it into a known state. There
* is only 2 board types here we need to worry about. Don;t use the
* standard board init routine here, it programs up the shared
* memory address, and we don't know it yet...
*/
if (brdp->brdtype == BRD_ECPE) {
outb(0x1, (brdp->iobase + ECP_EIBRDENAB));
outb(ECP_EISTOP, (brdp->iobase + ECP_EICONFR));
udelay(10);
outb(ECP_EIDISABLE, (brdp->iobase + ECP_EICONFR));
udelay(500);
stli_ecpeienable(brdp);
} else if (brdp->brdtype == BRD_ONBOARDE) {
outb(0x1, (brdp->iobase + ONB_EIBRDENAB));
outb(ONB_EISTOP, (brdp->iobase + ONB_EICONFR));
udelay(10);
outb(ONB_EIDISABLE, (brdp->iobase + ONB_EICONFR));
mdelay(100);
outb(0x1, brdp->iobase);
mdelay(1);
stli_onbeenable(brdp);
} else {
return -ENODEV;
}
foundit = 0;
brdp->memsize = ECP_MEMSIZE;
/*
* Board shared memory is enabled, so now we have a poke around and
* see if we can find it.
*/
for (i = 0; (i < stli_eisamempsize); i++) {
brdp->memaddr = stli_eisamemprobeaddrs[i];
brdp->membase = ioremap(brdp->memaddr, brdp->memsize);
if (brdp->membase == NULL)
continue;
if (brdp->brdtype == BRD_ECPE) {
ecpsigp = stli_ecpeigetmemptr(brdp,
CDK_SIGADDR, __LINE__);
memcpy_fromio(&ecpsig, ecpsigp, sizeof(cdkecpsig_t));
if (ecpsig.magic == cpu_to_le32(ECP_MAGIC))
foundit = 1;
} else {
onbsigp = (cdkonbsig_t __iomem *) stli_onbegetmemptr(brdp,
CDK_SIGADDR, __LINE__);
memcpy_fromio(&onbsig, onbsigp, sizeof(cdkonbsig_t));
if ((onbsig.magic0 == cpu_to_le16(ONB_MAGIC0)) &&
(onbsig.magic1 == cpu_to_le16(ONB_MAGIC1)) &&
(onbsig.magic2 == cpu_to_le16(ONB_MAGIC2)) &&
(onbsig.magic3 == cpu_to_le16(ONB_MAGIC3)))
foundit = 1;
}
iounmap(brdp->membase);
if (foundit)
break;
}
/*
* Regardless of whether we found the shared memory or not we must
* disable the region. After that return success or failure.
*/
if (brdp->brdtype == BRD_ECPE)
stli_ecpeidisable(brdp);
else
stli_onbedisable(brdp);
if (! foundit) {
brdp->memaddr = 0;
brdp->membase = NULL;
printk(KERN_ERR "STALLION: failed to probe shared memory "
"region for %s in EISA slot=%d\n",
stli_brdnames[brdp->brdtype], (brdp->iobase >> 12));
return -ENODEV;
}
return 0;
}
static int stli_getbrdnr(void)
{
int i;
for (i = 0; i < STL_MAXBRDS; i++) {
if (!stli_brds[i]) {
if (i >= stli_nrbrds)
stli_nrbrds = i + 1;
return i;
}
}
return -1;
}
/*****************************************************************************/
/*
* Probe around and try to find any EISA boards in system. The biggest
* problem here is finding out what memory address is associated with
* an EISA board after it is found. The registers of the ECPE and
* ONboardE are not readable - so we can't read them from there. We
* don't have access to the EISA CMOS (or EISA BIOS) so we don't
* actually have any way to find out the real value. The best we can
* do is go probing around in the usual places hoping we can find it.
*/
static int stli_findeisabrds(void)
{
stlibrd_t *brdp;
unsigned int iobase, eid;
int i;
/*
* Firstly check if this is an EISA system. If this is not an EISA system then
* don't bother going any further!
*/
if (EISA_bus)
return 0;
/*
* Looks like an EISA system, so go searching for EISA boards.
*/
for (iobase = 0x1000; (iobase <= 0xc000); iobase += 0x1000) {
outb(0xff, (iobase + 0xc80));
eid = inb(iobase + 0xc80);
eid |= inb(iobase + 0xc81) << 8;
if (eid != STL_EISAID)
continue;
/*
* We have found a board. Need to check if this board was
* statically configured already (just in case!).
*/
for (i = 0; (i < STL_MAXBRDS); i++) {
brdp = stli_brds[i];
if (brdp == NULL)
continue;
if (brdp->iobase == iobase)
break;
}
if (i < STL_MAXBRDS)
continue;
/*
* We have found a Stallion board and it is not configured already.
* Allocate a board structure and initialize it.
*/
if ((brdp = stli_allocbrd()) == NULL)
return -ENOMEM;
if ((brdp->brdnr = stli_getbrdnr()) < 0)
return -ENOMEM;
eid = inb(iobase + 0xc82);
if (eid == ECP_EISAID)
brdp->brdtype = BRD_ECPE;
else if (eid == ONB_EISAID)
brdp->brdtype = BRD_ONBOARDE;
else
brdp->brdtype = BRD_UNKNOWN;
brdp->iobase = iobase;
outb(0x1, (iobase + 0xc84));
if (stli_eisamemprobe(brdp))
outb(0, (iobase + 0xc84));
stli_brdinit(brdp);
}
return 0;
}
/*****************************************************************************/
/*
* Find the next available board number that is free.
*/
/*****************************************************************************/
#ifdef CONFIG_PCI
/*
* We have a Stallion board. Allocate a board structure and
* initialize it. Read its IO and MEMORY resources from PCI
* configuration space.
*/
static int stli_initpcibrd(int brdtype, struct pci_dev *devp)
{
stlibrd_t *brdp;
if (pci_enable_device(devp))
return -EIO;
if ((brdp = stli_allocbrd()) == NULL)
return -ENOMEM;
if ((brdp->brdnr = stli_getbrdnr()) < 0) {
printk(KERN_INFO "STALLION: too many boards found, "
"maximum supported %d\n", STL_MAXBRDS);
return 0;
}
brdp->brdtype = brdtype;
/*
* We have all resources from the board, so lets setup the actual
* board structure now.
*/
brdp->iobase = pci_resource_start(devp, 3);
brdp->memaddr = pci_resource_start(devp, 2);
stli_brdinit(brdp);
return 0;
}
/*****************************************************************************/
/*
* Find all Stallion PCI boards that might be installed. Initialize each
* one as it is found.
*/
static int stli_findpcibrds(void)
{
struct pci_dev *dev = NULL;
while ((dev = pci_get_device(PCI_VENDOR_ID_STALLION, PCI_DEVICE_ID_ECRA, dev))) {
stli_initpcibrd(BRD_ECPPCI, dev);
}
return 0;
}
#endif
/*****************************************************************************/
/*
* Allocate a new board structure. Fill out the basic info in it.
*/
static stlibrd_t *stli_allocbrd(void)
{
stlibrd_t *brdp;
brdp = kzalloc(sizeof(stlibrd_t), GFP_KERNEL);
if (!brdp) {
printk(KERN_ERR "STALLION: failed to allocate memory "
"(size=%Zd)\n", sizeof(stlibrd_t));
return NULL;
}
brdp->magic = STLI_BOARDMAGIC;
return brdp;
}
/*****************************************************************************/
/*
* Scan through all the boards in the configuration and see what we
* can find.
*/
static int stli_initbrds(void)
{
stlibrd_t *brdp, *nxtbrdp;
stlconf_t *confp;
int i, j;
if (stli_nrbrds > STL_MAXBRDS) {
printk(KERN_INFO "STALLION: too many boards in configuration "
"table, truncating to %d\n", STL_MAXBRDS);
stli_nrbrds = STL_MAXBRDS;
}
/*
* Firstly scan the list of static boards configured. Allocate
* resources and initialize the boards as found. If this is a
* module then let the module args override static configuration.
*/
for (i = 0; (i < stli_nrbrds); i++) {
confp = &stli_brdconf[i];
stli_parsebrd(confp, stli_brdsp[i]);
if ((brdp = stli_allocbrd()) == NULL)
return -ENOMEM;
brdp->brdnr = i;
brdp->brdtype = confp->brdtype;
brdp->iobase = confp->ioaddr1;
brdp->memaddr = confp->memaddr;
stli_brdinit(brdp);
}
/*
* Static configuration table done, so now use dynamic methods to
* see if any more boards should be configured.
*/
stli_argbrds();
if (STLI_EISAPROBE)
stli_findeisabrds();
#ifdef CONFIG_PCI
stli_findpcibrds();
#endif
/*
* All found boards are initialized. Now for a little optimization, if
* no boards are sharing the "shared memory" regions then we can just
* leave them all enabled. This is in fact the usual case.
*/
stli_shared = 0;
if (stli_nrbrds > 1) {
for (i = 0; (i < stli_nrbrds); i++) {
brdp = stli_brds[i];
if (brdp == NULL)
continue;
for (j = i + 1; (j < stli_nrbrds); j++) {
nxtbrdp = stli_brds[j];
if (nxtbrdp == NULL)
continue;
if ((brdp->membase >= nxtbrdp->membase) &&
(brdp->membase <= (nxtbrdp->membase +
nxtbrdp->memsize - 1))) {
stli_shared++;
break;
}
}
}
}
if (stli_shared == 0) {
for (i = 0; (i < stli_nrbrds); i++) {
brdp = stli_brds[i];
if (brdp == NULL)
continue;
if (brdp->state & BST_FOUND) {
EBRDENABLE(brdp);
brdp->enable = NULL;
brdp->disable = NULL;
}
}
}
return 0;
}
/*****************************************************************************/
/*
* Code to handle an "staliomem" read operation. This device is the
* contents of the board shared memory. It is used for down loading
* the slave image (and debugging :-)
*/
static ssize_t stli_memread(struct file *fp, char __user *buf, size_t count, loff_t *offp)
{
unsigned long flags;
void __iomem *memptr;
stlibrd_t *brdp;
int brdnr, size, n;
void *p;
loff_t off = *offp;
brdnr = iminor(fp->f_dentry->d_inode);
if (brdnr >= stli_nrbrds)
return -ENODEV;
brdp = stli_brds[brdnr];
if (brdp == NULL)
return -ENODEV;
if (brdp->state == 0)
return -ENODEV;
if (off >= brdp->memsize || off + count < off)
return 0;
size = MIN(count, (brdp->memsize - off));
/*
* Copy the data a page at a time
*/
p = (void *)__get_free_page(GFP_KERNEL);
if(p == NULL)
return -ENOMEM;
while (size > 0) {
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
memptr = EBRDGETMEMPTR(brdp, off);
n = MIN(size, (brdp->pagesize - (((unsigned long) off) % brdp->pagesize)));
n = MIN(n, PAGE_SIZE);
memcpy_fromio(p, memptr, n);
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
if (copy_to_user(buf, p, n)) {
count = -EFAULT;
goto out;
}
off += n;
buf += n;
size -= n;
}
out:
*offp = off;
free_page((unsigned long)p);
return count;
}
/*****************************************************************************/
/*
* Code to handle an "staliomem" write operation. This device is the
* contents of the board shared memory. It is used for down loading
* the slave image (and debugging :-)
*
* FIXME: copy under lock
*/
static ssize_t stli_memwrite(struct file *fp, const char __user *buf, size_t count, loff_t *offp)
{
unsigned long flags;
void __iomem *memptr;
stlibrd_t *brdp;
char __user *chbuf;
int brdnr, size, n;
void *p;
loff_t off = *offp;
brdnr = iminor(fp->f_dentry->d_inode);
if (brdnr >= stli_nrbrds)
return -ENODEV;
brdp = stli_brds[brdnr];
if (brdp == NULL)
return -ENODEV;
if (brdp->state == 0)
return -ENODEV;
if (off >= brdp->memsize || off + count < off)
return 0;
chbuf = (char __user *) buf;
size = MIN(count, (brdp->memsize - off));
/*
* Copy the data a page at a time
*/
p = (void *)__get_free_page(GFP_KERNEL);
if(p == NULL)
return -ENOMEM;
while (size > 0) {
n = MIN(size, (brdp->pagesize - (((unsigned long) off) % brdp->pagesize)));
n = MIN(n, PAGE_SIZE);
if (copy_from_user(p, chbuf, n)) {
if (count == 0)
count = -EFAULT;
goto out;
}
spin_lock_irqsave(&brd_lock, flags);
EBRDENABLE(brdp);
memptr = EBRDGETMEMPTR(brdp, off);
memcpy_toio(memptr, p, n);
EBRDDISABLE(brdp);
spin_unlock_irqrestore(&brd_lock, flags);
off += n;
chbuf += n;
size -= n;
}
out:
free_page((unsigned long) p);
*offp = off;
return count;
}
/*****************************************************************************/
/*
* Return the board stats structure to user app.
*/
static int stli_getbrdstats(combrd_t __user *bp)
{
stlibrd_t *brdp;
int i;
if (copy_from_user(&stli_brdstats, bp, sizeof(combrd_t)))
return -EFAULT;
if (stli_brdstats.brd >= STL_MAXBRDS)
return -ENODEV;
brdp = stli_brds[stli_brdstats.brd];
if (brdp == NULL)
return -ENODEV;
memset(&stli_brdstats, 0, sizeof(combrd_t));
stli_brdstats.brd = brdp->brdnr;
stli_brdstats.type = brdp->brdtype;
stli_brdstats.hwid = 0;
stli_brdstats.state = brdp->state;
stli_brdstats.ioaddr = brdp->iobase;
stli_brdstats.memaddr = brdp->memaddr;
stli_brdstats.nrpanels = brdp->nrpanels;
stli_brdstats.nrports = brdp->nrports;
for (i = 0; (i < brdp->nrpanels); i++) {
stli_brdstats.panels[i].panel = i;
stli_brdstats.panels[i].hwid = brdp->panelids[i];
stli_brdstats.panels[i].nrports = brdp->panels[i];
}
if (copy_to_user(bp, &stli_brdstats, sizeof(combrd_t)))
return -EFAULT;
return 0;
}
/*****************************************************************************/
/*
* Resolve the referenced port number into a port struct pointer.
*/
static stliport_t *stli_getport(int brdnr, int panelnr, int portnr)
{
stlibrd_t *brdp;
int i;
if (brdnr < 0 || brdnr >= STL_MAXBRDS)
return NULL;
brdp = stli_brds[brdnr];
if (brdp == NULL)
return NULL;
for (i = 0; (i < panelnr); i++)
portnr += brdp->panels[i];
if ((portnr < 0) || (portnr >= brdp->nrports))
return NULL;
return brdp->ports[portnr];
}
/*****************************************************************************/
/*
* Return the port stats structure to user app. A NULL port struct
* pointer passed in means that we need to find out from the app
* what port to get stats for (used through board control device).
*/
static int stli_portcmdstats(stliport_t *portp)
{
unsigned long flags;
stlibrd_t *brdp;
int rc;
memset(&stli_comstats, 0, sizeof(comstats_t));
if (portp == NULL)
return -ENODEV;
brdp = stli_brds[portp->brdnr];
if (brdp == NULL)
return -ENODEV;
if (brdp->state & BST_STARTED) {
if ((rc = stli_cmdwait(brdp, portp, A_GETSTATS,
&stli_cdkstats, sizeof(asystats_t), 1)) < 0)
return rc;
} else {
memset(&stli_cdkstats, 0, sizeof(asystats_t));
}
stli_comstats.brd = portp->brdnr;
stli_comstats.panel = portp->panelnr;
stli_comstats.port = portp->portnr;
stli_comstats.state = portp->state;
stli_comstats.flags = portp->flags;
spin_lock_irqsave(&brd_lock, flags);
if (portp->tty != NULL) {
if (portp->tty->driver_data == portp) {
stli_comstats.ttystate = portp->tty->flags;
stli_comstats.rxbuffered = -1;
if (portp->tty->termios != NULL) {
stli_comstats.cflags = portp->tty->termios->c_cflag;
stli_comstats.iflags = portp->tty->termios->c_iflag;
stli_comstats.oflags = portp->tty->termios->c_oflag;
stli_comstats.lflags = portp->tty->termios->c_lflag;
}
}
}
spin_unlock_irqrestore(&brd_lock, flags);
stli_comstats.txtotal = stli_cdkstats.txchars;
stli_comstats.rxtotal = stli_cdkstats.rxchars + stli_cdkstats.ringover;
stli_comstats.txbuffered = stli_cdkstats.txringq;
stli_comstats.rxbuffered += stli_cdkstats.rxringq;
stli_comstats.rxoverrun = stli_cdkstats.overruns;
stli_comstats.rxparity = stli_cdkstats.parity;
stli_comstats.rxframing = stli_cdkstats.framing;
stli_comstats.rxlost = stli_cdkstats.ringover;
stli_comstats.rxbreaks = stli_cdkstats.rxbreaks;
stli_comstats.txbreaks = stli_cdkstats.txbreaks;
stli_comstats.txxon = stli_cdkstats.txstart;
stli_comstats.txxoff = stli_cdkstats.txstop;
stli_comstats.rxxon = stli_cdkstats.rxstart;
stli_comstats.rxxoff = stli_cdkstats.rxstop;
stli_comstats.rxrtsoff = stli_cdkstats.rtscnt / 2;
stli_comstats.rxrtson = stli_cdkstats.rtscnt - stli_comstats.rxrtsoff;
stli_comstats.modem = stli_cdkstats.dcdcnt;
stli_comstats.hwid = stli_cdkstats.hwid;
stli_comstats.signals = stli_mktiocm(stli_cdkstats.signals);
return 0;
}
/*****************************************************************************/
/*
* Return the port stats structure to user app. A NULL port struct
* pointer passed in means that we need to find out from the app
* what port to get stats for (used through board control device).
*/
static int stli_getportstats(stliport_t *portp, comstats_t __user *cp)
{
stlibrd_t *brdp;
int rc;
if (!portp) {
if (copy_from_user(&stli_comstats, cp, sizeof(comstats_t)))
return -EFAULT;
portp = stli_getport(stli_comstats.brd, stli_comstats.panel,
stli_comstats.port);
if (!portp)
return -ENODEV;
}
brdp = stli_brds[portp->brdnr];
if (!brdp)
return -ENODEV;
if ((rc = stli_portcmdstats(portp)) < 0)
return rc;
return copy_to_user(cp, &stli_comstats, sizeof(comstats_t)) ?
-EFAULT : 0;
}
/*****************************************************************************/
/*
* Clear the port stats structure. We also return it zeroed out...
*/
static int stli_clrportstats(stliport_t *portp, comstats_t __user *cp)
{
stlibrd_t *brdp;
int rc;
if (!portp) {
if (copy_from_user(&stli_comstats, cp, sizeof(comstats_t)))
return -EFAULT;
portp = stli_getport(stli_comstats.brd, stli_comstats.panel,
stli_comstats.port);
if (!portp)
return -ENODEV;
}
brdp = stli_brds[portp->brdnr];
if (!brdp)
return -ENODEV;
if (brdp->state & BST_STARTED) {
if ((rc = stli_cmdwait(brdp, portp, A_CLEARSTATS, NULL, 0, 0)) < 0)
return rc;
}
memset(&stli_comstats, 0, sizeof(comstats_t));
stli_comstats.brd = portp->brdnr;
stli_comstats.panel = portp->panelnr;
stli_comstats.port = portp->portnr;
if (copy_to_user(cp, &stli_comstats, sizeof(comstats_t)))
return -EFAULT;
return 0;
}
/*****************************************************************************/
/*
* Return the entire driver ports structure to a user app.
*/
static int stli_getportstruct(stliport_t __user *arg)
{
stliport_t *portp;
if (copy_from_user(&stli_dummyport, arg, sizeof(stliport_t)))
return -EFAULT;
portp = stli_getport(stli_dummyport.brdnr, stli_dummyport.panelnr,
stli_dummyport.portnr);
if (!portp)
return -ENODEV;
if (copy_to_user(arg, portp, sizeof(stliport_t)))
return -EFAULT;
return 0;
}
/*****************************************************************************/
/*
* Return the entire driver board structure to a user app.
*/
static int stli_getbrdstruct(stlibrd_t __user *arg)
{
stlibrd_t *brdp;
if (copy_from_user(&stli_dummybrd, arg, sizeof(stlibrd_t)))
return -EFAULT;
if ((stli_dummybrd.brdnr < 0) || (stli_dummybrd.brdnr >= STL_MAXBRDS))
return -ENODEV;
brdp = stli_brds[stli_dummybrd.brdnr];
if (!brdp)
return -ENODEV;
if (copy_to_user(arg, brdp, sizeof(stlibrd_t)))
return -EFAULT;
return 0;
}
/*****************************************************************************/
/*
* The "staliomem" device is also required to do some special operations on
* the board. We need to be able to send an interrupt to the board,
* reset it, and start/stop it.
*/
static int stli_memioctl(struct inode *ip, struct file *fp, unsigned int cmd, unsigned long arg)
{
stlibrd_t *brdp;
int brdnr, rc, done;
void __user *argp = (void __user *)arg;
/*
* First up handle the board independent ioctls.
*/
done = 0;
rc = 0;
switch (cmd) {
case COM_GETPORTSTATS:
rc = stli_getportstats(NULL, argp);
done++;
break;
case COM_CLRPORTSTATS:
rc = stli_clrportstats(NULL, argp);
done++;
break;
case COM_GETBRDSTATS:
rc = stli_getbrdstats(argp);
done++;
break;
case COM_READPORT:
rc = stli_getportstruct(argp);
done++;
break;
case COM_READBOARD:
rc = stli_getbrdstruct(argp);
done++;
break;
}
if (done)
return rc;
/*
* Now handle the board specific ioctls. These all depend on the
* minor number of the device they were called from.
*/
brdnr = iminor(ip);
if (brdnr >= STL_MAXBRDS)
return -ENODEV;
brdp = stli_brds[brdnr];
if (!brdp)
return -ENODEV;
if (brdp->state == 0)
return -ENODEV;
switch (cmd) {
case STL_BINTR:
EBRDINTR(brdp);
break;
case STL_BSTART:
rc = stli_startbrd(brdp);
break;
case STL_BSTOP:
brdp->state &= ~BST_STARTED;
break;
case STL_BRESET:
brdp->state &= ~BST_STARTED;
EBRDRESET(brdp);
if (stli_shared == 0) {
if (brdp->reenable != NULL)
(* brdp->reenable)(brdp);
}
break;
default:
rc = -ENOIOCTLCMD;
break;
}
return rc;
}
static const struct tty_operations stli_ops = {
.open = stli_open,
.close = stli_close,
.write = stli_write,
.put_char = stli_putchar,
.flush_chars = stli_flushchars,
.write_room = stli_writeroom,
.chars_in_buffer = stli_charsinbuffer,
.ioctl = stli_ioctl,
.set_termios = stli_settermios,
.throttle = stli_throttle,
.unthrottle = stli_unthrottle,
.stop = stli_stop,
.start = stli_start,
.hangup = stli_hangup,
.flush_buffer = stli_flushbuffer,
.break_ctl = stli_breakctl,
.wait_until_sent = stli_waituntilsent,
.send_xchar = stli_sendxchar,
.read_proc = stli_readproc,
.tiocmget = stli_tiocmget,
.tiocmset = stli_tiocmset,
};
/*****************************************************************************/
static int __init stli_init(void)
{
int i;
printk(KERN_INFO "%s: version %s\n", stli_drvtitle, stli_drvversion);
spin_lock_init(&stli_lock);
spin_lock_init(&brd_lock);
stli_initbrds();
stli_serial = alloc_tty_driver(STL_MAXBRDS * STL_MAXPORTS);
if (!stli_serial)
return -ENOMEM;
/*
* Allocate a temporary write buffer.
*/
stli_txcookbuf = kmalloc(STLI_TXBUFSIZE, GFP_KERNEL);
if (!stli_txcookbuf)
printk(KERN_ERR "STALLION: failed to allocate memory "
"(size=%d)\n", STLI_TXBUFSIZE);
/*
* Set up a character driver for the shared memory region. We need this
* to down load the slave code image. Also it is a useful debugging tool.
*/
if (register_chrdev(STL_SIOMEMMAJOR, "staliomem", &stli_fsiomem))
printk(KERN_ERR "STALLION: failed to register serial memory "
"device\n");
istallion_class = class_create(THIS_MODULE, "staliomem");
for (i = 0; i < 4; i++)
class_device_create(istallion_class, NULL,
MKDEV(STL_SIOMEMMAJOR, i),
NULL, "staliomem%d", i);
/*
* Set up the tty driver structure and register us as a driver.
*/
stli_serial->owner = THIS_MODULE;
stli_serial->driver_name = stli_drvname;
stli_serial->name = stli_serialname;
stli_serial->major = STL_SERIALMAJOR;
stli_serial->minor_start = 0;
stli_serial->type = TTY_DRIVER_TYPE_SERIAL;
stli_serial->subtype = SERIAL_TYPE_NORMAL;
stli_serial->init_termios = stli_deftermios;
stli_serial->flags = TTY_DRIVER_REAL_RAW;
tty_set_operations(stli_serial, &stli_ops);
if (tty_register_driver(stli_serial)) {
put_tty_driver(stli_serial);
printk(KERN_ERR "STALLION: failed to register serial driver\n");
return -EBUSY;
}
return 0;
}
/*****************************************************************************/