linux/drivers/scsi/in2000.c

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/*
* in2000.c - Linux device driver for the
* Always IN2000 ISA SCSI card.
*
* Copyright (c) 1996 John Shifflett, GeoLog Consulting
* john@geolog.com
* jshiffle@netcom.com
*
* 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, 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.
*
* For the avoidance of doubt the "preferred form" of this code is one which
* is in an open non patent encumbered format. Where cryptographic key signing
* forms part of the process of creating an executable the information
* including keys needed to generate an equivalently functional executable
* are deemed to be part of the source code.
*
* Drew Eckhardt's excellent 'Generic NCR5380' sources provided
* much of the inspiration and some of the code for this driver.
* The Linux IN2000 driver distributed in the Linux kernels through
* version 1.2.13 was an extremely valuable reference on the arcane
* (and still mysterious) workings of the IN2000's fifo. It also
* is where I lifted in2000_biosparam(), the gist of the card
* detection scheme, and other bits of code. Many thanks to the
* talented and courageous people who wrote, contributed to, and
* maintained that driver (including Brad McLean, Shaun Savage,
* Bill Earnest, Larry Doolittle, Roger Sunshine, John Luckey,
* Matt Postiff, Peter Lu, zerucha@shell.portal.com, and Eric
* Youngdale). I should also mention the driver written by
* Hamish Macdonald for the (GASP!) Amiga A2091 card, included
* in the Linux-m68k distribution; it gave me a good initial
* understanding of the proper way to run a WD33c93 chip, and I
* ended up stealing lots of code from it.
*
* _This_ driver is (I feel) an improvement over the old one in
* several respects:
* - All problems relating to the data size of a SCSI request are
* gone (as far as I know). The old driver couldn't handle
* swapping to partitions because that involved 4k blocks, nor
* could it deal with the st.c tape driver unmodified, because
* that usually involved 4k - 32k blocks. The old driver never
* quite got away from a morbid dependence on 2k block sizes -
* which of course is the size of the card's fifo.
*
* - Target Disconnection/Reconnection is now supported. Any
* system with more than one device active on the SCSI bus
* will benefit from this. The driver defaults to what I'm
* calling 'adaptive disconnect' - meaning that each command
* is evaluated individually as to whether or not it should
* be run with the option to disconnect/reselect (if the
* device chooses), or as a "SCSI-bus-hog".
*
* - Synchronous data transfers are now supported. Because there
* are a few devices (and many improperly terminated systems)
* that choke when doing sync, the default is sync DISABLED
* for all devices. This faster protocol can (and should!)
* be enabled on selected devices via the command-line.
*
* - Runtime operating parameters can now be specified through
* either the LILO or the 'insmod' command line. For LILO do:
* "in2000=blah,blah,blah"
* and with insmod go like:
* "insmod /usr/src/linux/modules/in2000.o setup_strings=blah,blah"
* The defaults should be good for most people. See the comment
* for 'setup_strings' below for more details.
*
* - The old driver relied exclusively on what the Western Digital
* docs call "Combination Level 2 Commands", which are a great
* idea in that the CPU is relieved of a lot of interrupt
* overhead. However, by accepting a certain (user-settable)
* amount of additional interrupts, this driver achieves
* better control over the SCSI bus, and data transfers are
* almost as fast while being much easier to define, track,
* and debug.
*
* - You can force detection of a card whose BIOS has been disabled.
*
* - Multiple IN2000 cards might almost be supported. I've tried to
* keep it in mind, but have no way to test...
*
*
* TODO:
* tagged queuing. multiple cards.
*
*
* NOTE:
* When using this or any other SCSI driver as a module, you'll
* find that with the stock kernel, at most _two_ SCSI hard
* drives will be linked into the device list (ie, usable).
* If your IN2000 card has more than 2 disks on its bus, you
* might want to change the define of 'SD_EXTRA_DEVS' in the
* 'hosts.h' file from 2 to whatever is appropriate. It took
* me a while to track down this surprisingly obscure and
* undocumented little "feature".
*
*
* People with bug reports, wish-lists, complaints, comments,
* or improvements are asked to pah-leeez email me (John Shifflett)
* at john@geolog.com or jshiffle@netcom.com! I'm anxious to get
* this thing into as good a shape as possible, and I'm positive
* there are lots of lurking bugs and "Stupid Places".
*
* Updated for Linux 2.5 by Alan Cox <alan@lxorguk.ukuu.org.uk>
* - Using new_eh handler
* - Hopefully got all the locking right again
* See "FIXME" notes for items that could do with more work
*/
#include <linux/module.h>
#include <linux/blkdev.h>
#include <linux/interrupt.h>
#include <linux/string.h>
#include <linux/delay.h>
#include <linux/proc_fs.h>
#include <linux/ioport.h>
#include <linux/stat.h>
#include <asm/io.h>
#include "scsi.h"
#include <scsi/scsi_host.h>
#define IN2000_VERSION "1.33-2.5"
#define IN2000_DATE "2002/11/03"
#include "in2000.h"
/*
* 'setup_strings' is a single string used to pass operating parameters and
* settings from the kernel/module command-line to the driver. 'setup_args[]'
* is an array of strings that define the compile-time default values for
* these settings. If Linux boots with a LILO or insmod command-line, those
* settings are combined with 'setup_args[]'. Note that LILO command-lines
* are prefixed with "in2000=" while insmod uses a "setup_strings=" prefix.
* The driver recognizes the following keywords (lower case required) and
* arguments:
*
* - ioport:addr -Where addr is IO address of a (usually ROM-less) card.
* - noreset -No optional args. Prevents SCSI bus reset at boot time.
* - nosync:x -x is a bitmask where the 1st 7 bits correspond with
* the 7 possible SCSI devices (bit 0 for device #0, etc).
* Set a bit to PREVENT sync negotiation on that device.
* The driver default is sync DISABLED on all devices.
* - period:ns -ns is the minimum # of nanoseconds in a SCSI data transfer
* period. Default is 500; acceptable values are 250 - 1000.
* - disconnect:x -x = 0 to never allow disconnects, 2 to always allow them.
* x = 1 does 'adaptive' disconnects, which is the default
* and generally the best choice.
* - debug:x -If 'DEBUGGING_ON' is defined, x is a bitmask that causes
* various types of debug output to printed - see the DB_xxx
* defines in in2000.h
* - proc:x -If 'PROC_INTERFACE' is defined, x is a bitmask that
* determines how the /proc interface works and what it
* does - see the PR_xxx defines in in2000.h
*
* Syntax Notes:
* - Numeric arguments can be decimal or the '0x' form of hex notation. There
* _must_ be a colon between a keyword and its numeric argument, with no
* spaces.
* - Keywords are separated by commas, no spaces, in the standard kernel
* command-line manner.
* - A keyword in the 'nth' comma-separated command-line member will overwrite
* the 'nth' element of setup_args[]. A blank command-line member (in
* other words, a comma with no preceding keyword) will _not_ overwrite
* the corresponding setup_args[] element.
*
* A few LILO examples (for insmod, use 'setup_strings' instead of 'in2000'):
* - in2000=ioport:0x220,noreset
* - in2000=period:250,disconnect:2,nosync:0x03
* - in2000=debug:0x1e
* - in2000=proc:3
*/
/* Normally, no defaults are specified... */
static char *setup_args[] = { "", "", "", "", "", "", "", "", "" };
/* filled in by 'insmod' */
static char *setup_strings;
module_param(setup_strings, charp, 0);
static inline uchar read_3393(struct IN2000_hostdata *hostdata, uchar reg_num)
{
write1_io(reg_num, IO_WD_ADDR);
return read1_io(IO_WD_DATA);
}
#define READ_AUX_STAT() read1_io(IO_WD_ASR)
static inline void write_3393(struct IN2000_hostdata *hostdata, uchar reg_num, uchar value)
{
write1_io(reg_num, IO_WD_ADDR);
write1_io(value, IO_WD_DATA);
}
static inline void write_3393_cmd(struct IN2000_hostdata *hostdata, uchar cmd)
{
/* while (READ_AUX_STAT() & ASR_CIP)
printk("|");*/
write1_io(WD_COMMAND, IO_WD_ADDR);
write1_io(cmd, IO_WD_DATA);
}
static uchar read_1_byte(struct IN2000_hostdata *hostdata)
{
uchar asr, x = 0;
write_3393(hostdata, WD_CONTROL, CTRL_IDI | CTRL_EDI | CTRL_POLLED);
write_3393_cmd(hostdata, WD_CMD_TRANS_INFO | 0x80);
do {
asr = READ_AUX_STAT();
if (asr & ASR_DBR)
x = read_3393(hostdata, WD_DATA);
} while (!(asr & ASR_INT));
return x;
}
static void write_3393_count(struct IN2000_hostdata *hostdata, unsigned long value)
{
write1_io(WD_TRANSFER_COUNT_MSB, IO_WD_ADDR);
write1_io((value >> 16), IO_WD_DATA);
write1_io((value >> 8), IO_WD_DATA);
write1_io(value, IO_WD_DATA);
}
static unsigned long read_3393_count(struct IN2000_hostdata *hostdata)
{
unsigned long value;
write1_io(WD_TRANSFER_COUNT_MSB, IO_WD_ADDR);
value = read1_io(IO_WD_DATA) << 16;
value |= read1_io(IO_WD_DATA) << 8;
value |= read1_io(IO_WD_DATA);
return value;
}
/* The 33c93 needs to be told which direction a command transfers its
* data; we use this function to figure it out. Returns true if there
* will be a DATA_OUT phase with this command, false otherwise.
* (Thanks to Joerg Dorchain for the research and suggestion.)
*/
static int is_dir_out(Scsi_Cmnd * cmd)
{
switch (cmd->cmnd[0]) {
case WRITE_6:
case WRITE_10:
case WRITE_12:
case WRITE_LONG:
case WRITE_SAME:
case WRITE_BUFFER:
case WRITE_VERIFY:
case WRITE_VERIFY_12:
case COMPARE:
case COPY:
case COPY_VERIFY:
case SEARCH_EQUAL:
case SEARCH_HIGH:
case SEARCH_LOW:
case SEARCH_EQUAL_12:
case SEARCH_HIGH_12:
case SEARCH_LOW_12:
case FORMAT_UNIT:
case REASSIGN_BLOCKS:
case RESERVE:
case MODE_SELECT:
case MODE_SELECT_10:
case LOG_SELECT:
case SEND_DIAGNOSTIC:
case CHANGE_DEFINITION:
case UPDATE_BLOCK:
case SET_WINDOW:
case MEDIUM_SCAN:
case SEND_VOLUME_TAG:
case 0xea:
return 1;
default:
return 0;
}
}
static struct sx_period sx_table[] = {
{1, 0x20},
{252, 0x20},
{376, 0x30},
{500, 0x40},
{624, 0x50},
{752, 0x60},
{876, 0x70},
{1000, 0x00},
{0, 0}
};
static int round_period(unsigned int period)
{
int x;
for (x = 1; sx_table[x].period_ns; x++) {
if ((period <= sx_table[x - 0].period_ns) && (period > sx_table[x - 1].period_ns)) {
return x;
}
}
return 7;
}
static uchar calc_sync_xfer(unsigned int period, unsigned int offset)
{
uchar result;
period *= 4; /* convert SDTR code to ns */
result = sx_table[round_period(period)].reg_value;
result |= (offset < OPTIMUM_SX_OFF) ? offset : OPTIMUM_SX_OFF;
return result;
}
static void in2000_execute(struct Scsi_Host *instance);
static int in2000_queuecommand_lck(Scsi_Cmnd * cmd, void (*done) (Scsi_Cmnd *))
{
struct Scsi_Host *instance;
struct IN2000_hostdata *hostdata;
Scsi_Cmnd *tmp;
instance = cmd->device->host;
hostdata = (struct IN2000_hostdata *) instance->hostdata;
DB(DB_QUEUE_COMMAND, scmd_printk(KERN_DEBUG, cmd, "Q-%02x(", cmd->cmnd[0]))
/* Set up a few fields in the Scsi_Cmnd structure for our own use:
* - host_scribble is the pointer to the next cmd in the input queue
* - scsi_done points to the routine we call when a cmd is finished
* - result is what you'd expect
*/
cmd->host_scribble = NULL;
cmd->scsi_done = done;
cmd->result = 0;
/* We use the Scsi_Pointer structure that's included with each command
* as a scratchpad (as it's intended to be used!). The handy thing about
* the SCp.xxx fields is that they're always associated with a given
* cmd, and are preserved across disconnect-reselect. This means we
* can pretty much ignore SAVE_POINTERS and RESTORE_POINTERS messages
* if we keep all the critical pointers and counters in SCp:
* - SCp.ptr is the pointer into the RAM buffer
* - SCp.this_residual is the size of that buffer
* - SCp.buffer points to the current scatter-gather buffer
* - SCp.buffers_residual tells us how many S.G. buffers there are
* - SCp.have_data_in helps keep track of >2048 byte transfers
* - SCp.sent_command is not used
* - SCp.phase records this command's SRCID_ER bit setting
*/
if (scsi_bufflen(cmd)) {
cmd->SCp.buffer = scsi_sglist(cmd);
cmd->SCp.buffers_residual = scsi_sg_count(cmd) - 1;
cmd->SCp.ptr = sg_virt(cmd->SCp.buffer);
cmd->SCp.this_residual = cmd->SCp.buffer->length;
} else {
cmd->SCp.buffer = NULL;
cmd->SCp.buffers_residual = 0;
cmd->SCp.ptr = NULL;
cmd->SCp.this_residual = 0;
}
cmd->SCp.have_data_in = 0;
/* We don't set SCp.phase here - that's done in in2000_execute() */
/* WD docs state that at the conclusion of a "LEVEL2" command, the
* status byte can be retrieved from the LUN register. Apparently,
* this is the case only for *uninterrupted* LEVEL2 commands! If
* there are any unexpected phases entered, even if they are 100%
* legal (different devices may choose to do things differently),
* the LEVEL2 command sequence is exited. This often occurs prior
* to receiving the status byte, in which case the driver does a
* status phase interrupt and gets the status byte on its own.
* While such a command can then be "resumed" (ie restarted to
* finish up as a LEVEL2 command), the LUN register will NOT be
* a valid status byte at the command's conclusion, and we must
* use the byte obtained during the earlier interrupt. Here, we
* preset SCp.Status to an illegal value (0xff) so that when
* this command finally completes, we can tell where the actual
* status byte is stored.
*/
cmd->SCp.Status = ILLEGAL_STATUS_BYTE;
/* We need to disable interrupts before messing with the input
* queue and calling in2000_execute().
*/
/*
* Add the cmd to the end of 'input_Q'. Note that REQUEST_SENSE
* commands are added to the head of the queue so that the desired
* sense data is not lost before REQUEST_SENSE executes.
*/
if (!(hostdata->input_Q) || (cmd->cmnd[0] == REQUEST_SENSE)) {
cmd->host_scribble = (uchar *) hostdata->input_Q;
hostdata->input_Q = cmd;
} else { /* find the end of the queue */
for (tmp = (Scsi_Cmnd *) hostdata->input_Q; tmp->host_scribble; tmp = (Scsi_Cmnd *) tmp->host_scribble);
tmp->host_scribble = (uchar *) cmd;
}
/* We know that there's at least one command in 'input_Q' now.
* Go see if any of them are runnable!
*/
in2000_execute(cmd->device->host);
DB(DB_QUEUE_COMMAND, printk(")Q "))
return 0;
}
static DEF_SCSI_QCMD(in2000_queuecommand)
/*
* This routine attempts to start a scsi command. If the host_card is
* already connected, we give up immediately. Otherwise, look through
* the input_Q, using the first command we find that's intended
* for a currently non-busy target/lun.
* Note that this function is always called with interrupts already
* disabled (either from in2000_queuecommand() or in2000_intr()).
*/
static void in2000_execute(struct Scsi_Host *instance)
{
struct IN2000_hostdata *hostdata;
Scsi_Cmnd *cmd, *prev;
int i;
unsigned short *sp;
unsigned short f;
unsigned short flushbuf[16];
hostdata = (struct IN2000_hostdata *) instance->hostdata;
DB(DB_EXECUTE, printk("EX("))
if (hostdata->selecting || hostdata->connected) {
DB(DB_EXECUTE, printk(")EX-0 "))
return;
}
/*
* Search through the input_Q for a command destined
* for an idle target/lun.
*/
cmd = (Scsi_Cmnd *) hostdata->input_Q;
prev = NULL;
while (cmd) {
if (!(hostdata->busy[cmd->device->id] & (1 << cmd->device->lun)))
break;
prev = cmd;
cmd = (Scsi_Cmnd *) cmd->host_scribble;
}
/* quit if queue empty or all possible targets are busy */
if (!cmd) {
DB(DB_EXECUTE, printk(")EX-1 "))
return;
}
/* remove command from queue */
if (prev)
prev->host_scribble = cmd->host_scribble;
else
hostdata->input_Q = (Scsi_Cmnd *) cmd->host_scribble;
#ifdef PROC_STATISTICS
hostdata->cmd_cnt[cmd->device->id]++;
#endif
/*
* Start the selection process
*/
if (is_dir_out(cmd))
write_3393(hostdata, WD_DESTINATION_ID, cmd->device->id);
else
write_3393(hostdata, WD_DESTINATION_ID, cmd->device->id | DSTID_DPD);
/* Now we need to figure out whether or not this command is a good
* candidate for disconnect/reselect. We guess to the best of our
* ability, based on a set of hierarchical rules. When several
* devices are operating simultaneously, disconnects are usually
* an advantage. In a single device system, or if only 1 device
* is being accessed, transfers usually go faster if disconnects
* are not allowed:
*
* + Commands should NEVER disconnect if hostdata->disconnect =
* DIS_NEVER (this holds for tape drives also), and ALWAYS
* disconnect if hostdata->disconnect = DIS_ALWAYS.
* + Tape drive commands should always be allowed to disconnect.
* + Disconnect should be allowed if disconnected_Q isn't empty.
* + Commands should NOT disconnect if input_Q is empty.
* + Disconnect should be allowed if there are commands in input_Q
* for a different target/lun. In this case, the other commands
* should be made disconnect-able, if not already.
*
* I know, I know - this code would flunk me out of any
* "C Programming 101" class ever offered. But it's easy
* to change around and experiment with for now.
*/
cmd->SCp.phase = 0; /* assume no disconnect */
if (hostdata->disconnect == DIS_NEVER)
goto no;
if (hostdata->disconnect == DIS_ALWAYS)
goto yes;
if (cmd->device->type == 1) /* tape drive? */
goto yes;
if (hostdata->disconnected_Q) /* other commands disconnected? */
goto yes;
if (!(hostdata->input_Q)) /* input_Q empty? */
goto no;
for (prev = (Scsi_Cmnd *) hostdata->input_Q; prev; prev = (Scsi_Cmnd *) prev->host_scribble) {
if ((prev->device->id != cmd->device->id) || (prev->device->lun != cmd->device->lun)) {
for (prev = (Scsi_Cmnd *) hostdata->input_Q; prev; prev = (Scsi_Cmnd *) prev->host_scribble)
prev->SCp.phase = 1;
goto yes;
}
}
goto no;
yes:
cmd->SCp.phase = 1;
#ifdef PROC_STATISTICS
hostdata->disc_allowed_cnt[cmd->device->id]++;
#endif
no:
write_3393(hostdata, WD_SOURCE_ID, ((cmd->SCp.phase) ? SRCID_ER : 0));
write_3393(hostdata, WD_TARGET_LUN, cmd->device->lun);
write_3393(hostdata, WD_SYNCHRONOUS_TRANSFER, hostdata->sync_xfer[cmd->device->id]);
hostdata->busy[cmd->device->id] |= (1 << cmd->device->lun);
if ((hostdata->level2 <= L2_NONE) || (hostdata->sync_stat[cmd->device->id] == SS_UNSET)) {
/*
* Do a 'Select-With-ATN' command. This will end with
* one of the following interrupts:
* CSR_RESEL_AM: failure - can try again later.
* CSR_TIMEOUT: failure - give up.
* CSR_SELECT: success - proceed.
*/
hostdata->selecting = cmd;
/* Every target has its own synchronous transfer setting, kept in
* the sync_xfer array, and a corresponding status byte in sync_stat[].
* Each target's sync_stat[] entry is initialized to SS_UNSET, and its
* sync_xfer[] entry is initialized to the default/safe value. SS_UNSET
* means that the parameters are undetermined as yet, and that we
* need to send an SDTR message to this device after selection is
* complete. We set SS_FIRST to tell the interrupt routine to do so,
* unless we don't want to even _try_ synchronous transfers: In this
* case we set SS_SET to make the defaults final.
*/
if (hostdata->sync_stat[cmd->device->id] == SS_UNSET) {
if (hostdata->sync_off & (1 << cmd->device->id))
hostdata->sync_stat[cmd->device->id] = SS_SET;
else
hostdata->sync_stat[cmd->device->id] = SS_FIRST;
}
hostdata->state = S_SELECTING;
write_3393_count(hostdata, 0); /* this guarantees a DATA_PHASE interrupt */
write_3393_cmd(hostdata, WD_CMD_SEL_ATN);
}
else {
/*
* Do a 'Select-With-ATN-Xfer' command. This will end with
* one of the following interrupts:
* CSR_RESEL_AM: failure - can try again later.
* CSR_TIMEOUT: failure - give up.
* anything else: success - proceed.
*/
hostdata->connected = cmd;
write_3393(hostdata, WD_COMMAND_PHASE, 0);
/* copy command_descriptor_block into WD chip
* (take advantage of auto-incrementing)
*/
write1_io(WD_CDB_1, IO_WD_ADDR);
for (i = 0; i < cmd->cmd_len; i++)
write1_io(cmd->cmnd[i], IO_WD_DATA);
/* The wd33c93 only knows about Group 0, 1, and 5 commands when
* it's doing a 'select-and-transfer'. To be safe, we write the
* size of the CDB into the OWN_ID register for every case. This
* way there won't be problems with vendor-unique, audio, etc.
*/
write_3393(hostdata, WD_OWN_ID, cmd->cmd_len);
/* When doing a non-disconnect command, we can save ourselves a DATA
* phase interrupt later by setting everything up now. With writes we
* need to pre-fill the fifo; if there's room for the 32 flush bytes,
* put them in there too - that'll avoid a fifo interrupt. Reads are
* somewhat simpler.
* KLUDGE NOTE: It seems that you can't completely fill the fifo here:
* This results in the IO_FIFO_COUNT register rolling over to zero,
* and apparently the gate array logic sees this as empty, not full,
* so the 3393 chip is never signalled to start reading from the
* fifo. Or maybe it's seen as a permanent fifo interrupt condition.
* Regardless, we fix this by temporarily pretending that the fifo
* is 16 bytes smaller. (I see now that the old driver has a comment
* about "don't fill completely" in an analogous place - must be the
* same deal.) This results in CDROM, swap partitions, and tape drives
* needing an extra interrupt per write command - I think we can live
* with that!
*/
if (!(cmd->SCp.phase)) {
write_3393_count(hostdata, cmd->SCp.this_residual);
write_3393(hostdata, WD_CONTROL, CTRL_IDI | CTRL_EDI | CTRL_BUS);
write1_io(0, IO_FIFO_WRITE); /* clear fifo counter, write mode */
if (is_dir_out(cmd)) {
hostdata->fifo = FI_FIFO_WRITING;
if ((i = cmd->SCp.this_residual) > (IN2000_FIFO_SIZE - 16))
i = IN2000_FIFO_SIZE - 16;
cmd->SCp.have_data_in = i; /* this much data in fifo */
i >>= 1; /* Gulp. Assuming modulo 2. */
sp = (unsigned short *) cmd->SCp.ptr;
f = hostdata->io_base + IO_FIFO;
#ifdef FAST_WRITE_IO
FAST_WRITE2_IO();
#else
while (i--)
write2_io(*sp++, IO_FIFO);
#endif
/* Is there room for the flush bytes? */
if (cmd->SCp.have_data_in <= ((IN2000_FIFO_SIZE - 16) - 32)) {
sp = flushbuf;
i = 16;
#ifdef FAST_WRITE_IO
FAST_WRITE2_IO();
#else
while (i--)
write2_io(0, IO_FIFO);
#endif
}
}
else {
write1_io(0, IO_FIFO_READ); /* put fifo in read mode */
hostdata->fifo = FI_FIFO_READING;
cmd->SCp.have_data_in = 0; /* nothing transferred yet */
}
} else {
write_3393_count(hostdata, 0); /* this guarantees a DATA_PHASE interrupt */
}
hostdata->state = S_RUNNING_LEVEL2;
write_3393_cmd(hostdata, WD_CMD_SEL_ATN_XFER);
}
/*
* Since the SCSI bus can handle only 1 connection at a time,
* we get out of here now. If the selection fails, or when
* the command disconnects, we'll come back to this routine
* to search the input_Q again...
*/
DB(DB_EXECUTE, printk("%s)EX-2 ", (cmd->SCp.phase) ? "d:" : ""))
}
static void transfer_pio(uchar * buf, int cnt, int data_in_dir, struct IN2000_hostdata *hostdata)
{
uchar asr;
DB(DB_TRANSFER, printk("(%p,%d,%s)", buf, cnt, data_in_dir ? "in" : "out"))
write_3393(hostdata, WD_CONTROL, CTRL_IDI | CTRL_EDI | CTRL_POLLED);
write_3393_count(hostdata, cnt);
write_3393_cmd(hostdata, WD_CMD_TRANS_INFO);
if (data_in_dir) {
do {
asr = READ_AUX_STAT();
if (asr & ASR_DBR)
*buf++ = read_3393(hostdata, WD_DATA);
} while (!(asr & ASR_INT));
} else {
do {
asr = READ_AUX_STAT();
if (asr & ASR_DBR)
write_3393(hostdata, WD_DATA, *buf++);
} while (!(asr & ASR_INT));
}
/* Note: we are returning with the interrupt UN-cleared.
* Since (presumably) an entire I/O operation has
* completed, the bus phase is probably different, and
* the interrupt routine will discover this when it
* responds to the uncleared int.
*/
}
static void transfer_bytes(Scsi_Cmnd * cmd, int data_in_dir)
{
struct IN2000_hostdata *hostdata;
unsigned short *sp;
unsigned short f;
int i;
hostdata = (struct IN2000_hostdata *) cmd->device->host->hostdata;
/* Normally, you'd expect 'this_residual' to be non-zero here.
* In a series of scatter-gather transfers, however, this
* routine will usually be called with 'this_residual' equal
* to 0 and 'buffers_residual' non-zero. This means that a
* previous transfer completed, clearing 'this_residual', and
* now we need to setup the next scatter-gather buffer as the
* source or destination for THIS transfer.
*/
if (!cmd->SCp.this_residual && cmd->SCp.buffers_residual) {
++cmd->SCp.buffer;
--cmd->SCp.buffers_residual;
cmd->SCp.this_residual = cmd->SCp.buffer->length;
cmd->SCp.ptr = sg_virt(cmd->SCp.buffer);
}
/* Set up hardware registers */
write_3393(hostdata, WD_SYNCHRONOUS_TRANSFER, hostdata->sync_xfer[cmd->device->id]);
write_3393_count(hostdata, cmd->SCp.this_residual);
write_3393(hostdata, WD_CONTROL, CTRL_IDI | CTRL_EDI | CTRL_BUS);
write1_io(0, IO_FIFO_WRITE); /* zero counter, assume write */
/* Reading is easy. Just issue the command and return - we'll
* get an interrupt later when we have actual data to worry about.
*/
if (data_in_dir) {
write1_io(0, IO_FIFO_READ);
if ((hostdata->level2 >= L2_DATA) || (hostdata->level2 == L2_BASIC && cmd->SCp.phase == 0)) {
write_3393(hostdata, WD_COMMAND_PHASE, 0x45);
write_3393_cmd(hostdata, WD_CMD_SEL_ATN_XFER);
hostdata->state = S_RUNNING_LEVEL2;
} else
write_3393_cmd(hostdata, WD_CMD_TRANS_INFO);
hostdata->fifo = FI_FIFO_READING;
cmd->SCp.have_data_in = 0;
return;
}
/* Writing is more involved - we'll start the WD chip and write as
* much data to the fifo as we can right now. Later interrupts will
* write any bytes that don't make it at this stage.
*/
if ((hostdata->level2 >= L2_DATA) || (hostdata->level2 == L2_BASIC && cmd->SCp.phase == 0)) {
write_3393(hostdata, WD_COMMAND_PHASE, 0x45);
write_3393_cmd(hostdata, WD_CMD_SEL_ATN_XFER);
hostdata->state = S_RUNNING_LEVEL2;
} else
write_3393_cmd(hostdata, WD_CMD_TRANS_INFO);
hostdata->fifo = FI_FIFO_WRITING;
sp = (unsigned short *) cmd->SCp.ptr;
if ((i = cmd->SCp.this_residual) > IN2000_FIFO_SIZE)
i = IN2000_FIFO_SIZE;
cmd->SCp.have_data_in = i;
i >>= 1; /* Gulp. We assume this_residual is modulo 2 */
f = hostdata->io_base + IO_FIFO;
#ifdef FAST_WRITE_IO
FAST_WRITE2_IO();
#else
while (i--)
write2_io(*sp++, IO_FIFO);
#endif
}
/* We need to use spin_lock_irqsave() & spin_unlock_irqrestore() in this
* function in order to work in an SMP environment. (I'd be surprised
* if the driver is ever used by anyone on a real multi-CPU motherboard,
* but it _does_ need to be able to compile and run in an SMP kernel.)
*/
IRQ: Maintain regs pointer globally rather than passing to IRQ handlers Maintain a per-CPU global "struct pt_regs *" variable which can be used instead of passing regs around manually through all ~1800 interrupt handlers in the Linux kernel. The regs pointer is used in few places, but it potentially costs both stack space and code to pass it around. On the FRV arch, removing the regs parameter from all the genirq function results in a 20% speed up of the IRQ exit path (ie: from leaving timer_interrupt() to leaving do_IRQ()). Where appropriate, an arch may override the generic storage facility and do something different with the variable. On FRV, for instance, the address is maintained in GR28 at all times inside the kernel as part of general exception handling. Having looked over the code, it appears that the parameter may be handed down through up to twenty or so layers of functions. Consider a USB character device attached to a USB hub, attached to a USB controller that posts its interrupts through a cascaded auxiliary interrupt controller. A character device driver may want to pass regs to the sysrq handler through the input layer which adds another few layers of parameter passing. I've build this code with allyesconfig for x86_64 and i386. I've runtested the main part of the code on FRV and i386, though I can't test most of the drivers. I've also done partial conversion for powerpc and MIPS - these at least compile with minimal configurations. This will affect all archs. Mostly the changes should be relatively easy. Take do_IRQ(), store the regs pointer at the beginning, saving the old one: struct pt_regs *old_regs = set_irq_regs(regs); And put the old one back at the end: set_irq_regs(old_regs); Don't pass regs through to generic_handle_irq() or __do_IRQ(). In timer_interrupt(), this sort of change will be necessary: - update_process_times(user_mode(regs)); - profile_tick(CPU_PROFILING, regs); + update_process_times(user_mode(get_irq_regs())); + profile_tick(CPU_PROFILING); I'd like to move update_process_times()'s use of get_irq_regs() into itself, except that i386, alone of the archs, uses something other than user_mode(). Some notes on the interrupt handling in the drivers: (*) input_dev() is now gone entirely. The regs pointer is no longer stored in the input_dev struct. (*) finish_unlinks() in drivers/usb/host/ohci-q.c needs checking. It does something different depending on whether it's been supplied with a regs pointer or not. (*) Various IRQ handler function pointers have been moved to type irq_handler_t. Signed-Off-By: David Howells <dhowells@redhat.com> (cherry picked from 1b16e7ac850969f38b375e511e3fa2f474a33867 commit)
2006-10-05 13:55:46 +00:00
static irqreturn_t in2000_intr(int irqnum, void *dev_id)
{
struct Scsi_Host *instance = dev_id;
struct IN2000_hostdata *hostdata;
Scsi_Cmnd *patch, *cmd;
uchar asr, sr, phs, id, lun, *ucp, msg;
int i, j;
unsigned long length;
unsigned short *sp;
unsigned short f;
unsigned long flags;
hostdata = (struct IN2000_hostdata *) instance->hostdata;
/* Get the spin_lock and disable further ints, for SMP */
spin_lock_irqsave(instance->host_lock, flags);
#ifdef PROC_STATISTICS
hostdata->int_cnt++;
#endif
/* The IN2000 card has 2 interrupt sources OR'ed onto its IRQ line - the
* WD3393 chip and the 2k fifo (which is actually a dual-port RAM combined
* with a big logic array, so it's a little different than what you might
* expect). As far as I know, there's no reason that BOTH can't be active
* at the same time, but there's a problem: while we can read the 3393
* to tell if _it_ wants an interrupt, I don't know of a way to ask the
* fifo the same question. The best we can do is check the 3393 and if
* it _isn't_ the source of the interrupt, then we can be pretty sure
* that the fifo is the culprit.
* UPDATE: I have it on good authority (Bill Earnest) that bit 0 of the
* IO_FIFO_COUNT register mirrors the fifo interrupt state. I
* assume that bit clear means interrupt active. As it turns
* out, the driver really doesn't need to check for this after
* all, so my remarks above about a 'problem' can safely be
* ignored. The way the logic is set up, there's no advantage
* (that I can see) to worrying about it.
*
* It seems that the fifo interrupt signal is negated when we extract
* bytes during read or write bytes during write.
* - fifo will interrupt when data is moving from it to the 3393, and
* there are 31 (or less?) bytes left to go. This is sort of short-
* sighted: what if you don't WANT to do more? In any case, our
* response is to push more into the fifo - either actual data or
* dummy bytes if need be. Note that we apparently have to write at
* least 32 additional bytes to the fifo after an interrupt in order
* to get it to release the ones it was holding on to - writing fewer
* than 32 will result in another fifo int.
* UPDATE: Again, info from Bill Earnest makes this more understandable:
* 32 bytes = two counts of the fifo counter register. He tells
* me that the fifo interrupt is a non-latching signal derived
* from a straightforward boolean interpretation of the 7
* highest bits of the fifo counter and the fifo-read/fifo-write
* state. Who'd a thought?
*/
write1_io(0, IO_LED_ON);
asr = READ_AUX_STAT();
if (!(asr & ASR_INT)) { /* no WD33c93 interrupt? */
/* Ok. This is definitely a FIFO-only interrupt.
*
* If FI_FIFO_READING is set, there are up to 2048 bytes waiting to be read,
* maybe more to come from the SCSI bus. Read as many as we can out of the
* fifo and into memory at the location of SCp.ptr[SCp.have_data_in], and
* update have_data_in afterwards.
*
* If we have FI_FIFO_WRITING, the FIFO has almost run out of bytes to move
* into the WD3393 chip (I think the interrupt happens when there are 31
* bytes left, but it may be fewer...). The 3393 is still waiting, so we
* shove some more into the fifo, which gets things moving again. If the
* original SCSI command specified more than 2048 bytes, there may still
* be some of that data left: fine - use it (from SCp.ptr[SCp.have_data_in]).
* Don't forget to update have_data_in. If we've already written out the
* entire buffer, feed 32 dummy bytes to the fifo - they're needed to
* push out the remaining real data.
* (Big thanks to Bill Earnest for getting me out of the mud in here.)
*/
cmd = (Scsi_Cmnd *) hostdata->connected; /* assume we're connected */
CHECK_NULL(cmd, "fifo_int")
if (hostdata->fifo == FI_FIFO_READING) {
DB(DB_FIFO, printk("{R:%02x} ", read1_io(IO_FIFO_COUNT)))
sp = (unsigned short *) (cmd->SCp.ptr + cmd->SCp.have_data_in);
i = read1_io(IO_FIFO_COUNT) & 0xfe;
i <<= 2; /* # of words waiting in the fifo */
f = hostdata->io_base + IO_FIFO;
#ifdef FAST_READ_IO
FAST_READ2_IO();
#else
while (i--)
*sp++ = read2_io(IO_FIFO);
#endif
i = sp - (unsigned short *) (cmd->SCp.ptr + cmd->SCp.have_data_in);
i <<= 1;
cmd->SCp.have_data_in += i;
}
else if (hostdata->fifo == FI_FIFO_WRITING) {
DB(DB_FIFO, printk("{W:%02x} ", read1_io(IO_FIFO_COUNT)))
/* If all bytes have been written to the fifo, flush out the stragglers.
* Note that while writing 16 dummy words seems arbitrary, we don't
* have another choice that I can see. What we really want is to read
* the 3393 transfer count register (that would tell us how many bytes
* needed flushing), but the TRANSFER_INFO command hasn't completed
* yet (not enough bytes!) and that register won't be accessible. So,
* we use 16 words - a number obtained through trial and error.
* UPDATE: Bill says this is exactly what Always does, so there.
* More thanks due him for help in this section.
*/
if (cmd->SCp.this_residual == cmd->SCp.have_data_in) {
i = 16;
while (i--) /* write 32 dummy bytes */
write2_io(0, IO_FIFO);
}
/* If there are still bytes left in the SCSI buffer, write as many as we
* can out to the fifo.
*/
else {
sp = (unsigned short *) (cmd->SCp.ptr + cmd->SCp.have_data_in);
i = cmd->SCp.this_residual - cmd->SCp.have_data_in; /* bytes yet to go */
j = read1_io(IO_FIFO_COUNT) & 0xfe;
j <<= 2; /* how many words the fifo has room for */
if ((j << 1) > i)
j = (i >> 1);
while (j--)
write2_io(*sp++, IO_FIFO);
i = sp - (unsigned short *) (cmd->SCp.ptr + cmd->SCp.have_data_in);
i <<= 1;
cmd->SCp.have_data_in += i;
}
}
else {
printk("*** Spurious FIFO interrupt ***");
}
write1_io(0, IO_LED_OFF);
/* release the SMP spin_lock and restore irq state */
spin_unlock_irqrestore(instance->host_lock, flags);
return IRQ_HANDLED;
}
/* This interrupt was triggered by the WD33c93 chip. The fifo interrupt
* may also be asserted, but we don't bother to check it: we get more
* detailed info from FIFO_READING and FIFO_WRITING (see below).
*/
cmd = (Scsi_Cmnd *) hostdata->connected; /* assume we're connected */
sr = read_3393(hostdata, WD_SCSI_STATUS); /* clear the interrupt */
phs = read_3393(hostdata, WD_COMMAND_PHASE);
if (!cmd && (sr != CSR_RESEL_AM && sr != CSR_TIMEOUT && sr != CSR_SELECT)) {
printk("\nNR:wd-intr-1\n");
write1_io(0, IO_LED_OFF);
/* release the SMP spin_lock and restore irq state */
spin_unlock_irqrestore(instance->host_lock, flags);
return IRQ_HANDLED;
}
DB(DB_INTR, printk("{%02x:%02x-", asr, sr))
/* After starting a FIFO-based transfer, the next _WD3393_ interrupt is
* guaranteed to be in response to the completion of the transfer.
* If we were reading, there's probably data in the fifo that needs
* to be copied into RAM - do that here. Also, we have to update
* 'this_residual' and 'ptr' based on the contents of the
* TRANSFER_COUNT register, in case the device decided to do an
* intermediate disconnect (a device may do this if it has to
* do a seek, or just to be nice and let other devices have
* some bus time during long transfers).
* After doing whatever is necessary with the fifo, we go on and
* service the WD3393 interrupt normally.
*/
if (hostdata->fifo == FI_FIFO_READING) {
/* buffer index = start-of-buffer + #-of-bytes-already-read */
sp = (unsigned short *) (cmd->SCp.ptr + cmd->SCp.have_data_in);
/* bytes remaining in fifo = (total-wanted - #-not-got) - #-already-read */
i = (cmd->SCp.this_residual - read_3393_count(hostdata)) - cmd->SCp.have_data_in;
i >>= 1; /* Gulp. We assume this will always be modulo 2 */
f = hostdata->io_base + IO_FIFO;
#ifdef FAST_READ_IO
FAST_READ2_IO();
#else
while (i--)
*sp++ = read2_io(IO_FIFO);
#endif
hostdata->fifo = FI_FIFO_UNUSED;
length = cmd->SCp.this_residual;
cmd->SCp.this_residual = read_3393_count(hostdata);
cmd->SCp.ptr += (length - cmd->SCp.this_residual);
DB(DB_TRANSFER, printk("(%p,%d)", cmd->SCp.ptr, cmd->SCp.this_residual))
}
else if (hostdata->fifo == FI_FIFO_WRITING) {
hostdata->fifo = FI_FIFO_UNUSED;
length = cmd->SCp.this_residual;
cmd->SCp.this_residual = read_3393_count(hostdata);
cmd->SCp.ptr += (length - cmd->SCp.this_residual);
DB(DB_TRANSFER, printk("(%p,%d)", cmd->SCp.ptr, cmd->SCp.this_residual))
}
/* Respond to the specific WD3393 interrupt - there are quite a few! */
switch (sr) {
case CSR_TIMEOUT:
DB(DB_INTR, printk("TIMEOUT"))
if (hostdata->state == S_RUNNING_LEVEL2)
hostdata->connected = NULL;
else {
cmd = (Scsi_Cmnd *) hostdata->selecting; /* get a valid cmd */
CHECK_NULL(cmd, "csr_timeout")
hostdata->selecting = NULL;
}
cmd->result = DID_NO_CONNECT << 16;
hostdata->busy[cmd->device->id] &= ~(1 << cmd->device->lun);
hostdata->state = S_UNCONNECTED;
cmd->scsi_done(cmd);
/* We are not connected to a target - check to see if there
* are commands waiting to be executed.
*/
in2000_execute(instance);
break;
/* Note: this interrupt should not occur in a LEVEL2 command */
case CSR_SELECT:
DB(DB_INTR, printk("SELECT"))
hostdata->connected = cmd = (Scsi_Cmnd *) hostdata->selecting;
CHECK_NULL(cmd, "csr_select")
hostdata->selecting = NULL;
/* construct an IDENTIFY message with correct disconnect bit */
hostdata->outgoing_msg[0] = (0x80 | 0x00 | cmd->device->lun);
if (cmd->SCp.phase)
hostdata->outgoing_msg[0] |= 0x40;
if (hostdata->sync_stat[cmd->device->id] == SS_FIRST) {
#ifdef SYNC_DEBUG
printk(" sending SDTR ");
#endif
hostdata->sync_stat[cmd->device->id] = SS_WAITING;
/* tack on a 2nd message to ask about synchronous transfers */
hostdata->outgoing_msg[1] = EXTENDED_MESSAGE;
hostdata->outgoing_msg[2] = 3;
hostdata->outgoing_msg[3] = EXTENDED_SDTR;
hostdata->outgoing_msg[4] = OPTIMUM_SX_PER / 4;
hostdata->outgoing_msg[5] = OPTIMUM_SX_OFF;
hostdata->outgoing_len = 6;
} else
hostdata->outgoing_len = 1;
hostdata->state = S_CONNECTED;
break;
case CSR_XFER_DONE | PHS_DATA_IN:
case CSR_UNEXP | PHS_DATA_IN:
case CSR_SRV_REQ | PHS_DATA_IN:
DB(DB_INTR, printk("IN-%d.%d", cmd->SCp.this_residual, cmd->SCp.buffers_residual))
transfer_bytes(cmd, DATA_IN_DIR);
if (hostdata->state != S_RUNNING_LEVEL2)
hostdata->state = S_CONNECTED;
break;
case CSR_XFER_DONE | PHS_DATA_OUT:
case CSR_UNEXP | PHS_DATA_OUT:
case CSR_SRV_REQ | PHS_DATA_OUT:
DB(DB_INTR, printk("OUT-%d.%d", cmd->SCp.this_residual, cmd->SCp.buffers_residual))
transfer_bytes(cmd, DATA_OUT_DIR);
if (hostdata->state != S_RUNNING_LEVEL2)
hostdata->state = S_CONNECTED;
break;
/* Note: this interrupt should not occur in a LEVEL2 command */
case CSR_XFER_DONE | PHS_COMMAND:
case CSR_UNEXP | PHS_COMMAND:
case CSR_SRV_REQ | PHS_COMMAND:
DB(DB_INTR, printk("CMND-%02x", cmd->cmnd[0]))
transfer_pio(cmd->cmnd, cmd->cmd_len, DATA_OUT_DIR, hostdata);
hostdata->state = S_CONNECTED;
break;
case CSR_XFER_DONE | PHS_STATUS:
case CSR_UNEXP | PHS_STATUS:
case CSR_SRV_REQ | PHS_STATUS:
DB(DB_INTR, printk("STATUS="))
cmd->SCp.Status = read_1_byte(hostdata);
DB(DB_INTR, printk("%02x", cmd->SCp.Status))
if (hostdata->level2 >= L2_BASIC) {
sr = read_3393(hostdata, WD_SCSI_STATUS); /* clear interrupt */
hostdata->state = S_RUNNING_LEVEL2;
write_3393(hostdata, WD_COMMAND_PHASE, 0x50);
write_3393_cmd(hostdata, WD_CMD_SEL_ATN_XFER);
} else {
hostdata->state = S_CONNECTED;
}
break;
case CSR_XFER_DONE | PHS_MESS_IN:
case CSR_UNEXP | PHS_MESS_IN:
case CSR_SRV_REQ | PHS_MESS_IN:
DB(DB_INTR, printk("MSG_IN="))
msg = read_1_byte(hostdata);
sr = read_3393(hostdata, WD_SCSI_STATUS); /* clear interrupt */
hostdata->incoming_msg[hostdata->incoming_ptr] = msg;
if (hostdata->incoming_msg[0] == EXTENDED_MESSAGE)
msg = EXTENDED_MESSAGE;
else
hostdata->incoming_ptr = 0;
cmd->SCp.Message = msg;
switch (msg) {
case COMMAND_COMPLETE:
DB(DB_INTR, printk("CCMP"))
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_PRE_CMP_DISC;
break;
case SAVE_POINTERS:
DB(DB_INTR, printk("SDP"))
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
break;
case RESTORE_POINTERS:
DB(DB_INTR, printk("RDP"))
if (hostdata->level2 >= L2_BASIC) {
write_3393(hostdata, WD_COMMAND_PHASE, 0x45);
write_3393_cmd(hostdata, WD_CMD_SEL_ATN_XFER);
hostdata->state = S_RUNNING_LEVEL2;
} else {
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
}
break;
case DISCONNECT:
DB(DB_INTR, printk("DIS"))
cmd->device->disconnect = 1;
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_PRE_TMP_DISC;
break;
case MESSAGE_REJECT:
DB(DB_INTR, printk("REJ"))
#ifdef SYNC_DEBUG
printk("-REJ-");
#endif
if (hostdata->sync_stat[cmd->device->id] == SS_WAITING)
hostdata->sync_stat[cmd->device->id] = SS_SET;
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
break;
case EXTENDED_MESSAGE:
DB(DB_INTR, printk("EXT"))
ucp = hostdata->incoming_msg;
#ifdef SYNC_DEBUG
printk("%02x", ucp[hostdata->incoming_ptr]);
#endif
/* Is this the last byte of the extended message? */
if ((hostdata->incoming_ptr >= 2) && (hostdata->incoming_ptr == (ucp[1] + 1))) {
switch (ucp[2]) { /* what's the EXTENDED code? */
case EXTENDED_SDTR:
id = calc_sync_xfer(ucp[3], ucp[4]);
if (hostdata->sync_stat[cmd->device->id] != SS_WAITING) {
/* A device has sent an unsolicited SDTR message; rather than go
* through the effort of decoding it and then figuring out what
* our reply should be, we're just gonna say that we have a
* synchronous fifo depth of 0. This will result in asynchronous
* transfers - not ideal but so much easier.
* Actually, this is OK because it assures us that if we don't
* specifically ask for sync transfers, we won't do any.
*/
write_3393_cmd(hostdata, WD_CMD_ASSERT_ATN); /* want MESS_OUT */
hostdata->outgoing_msg[0] = EXTENDED_MESSAGE;
hostdata->outgoing_msg[1] = 3;
hostdata->outgoing_msg[2] = EXTENDED_SDTR;
hostdata->outgoing_msg[3] = hostdata->default_sx_per / 4;
hostdata->outgoing_msg[4] = 0;
hostdata->outgoing_len = 5;
hostdata->sync_xfer[cmd->device->id] = calc_sync_xfer(hostdata->default_sx_per / 4, 0);
} else {
hostdata->sync_xfer[cmd->device->id] = id;
}
#ifdef SYNC_DEBUG
printk("sync_xfer=%02x", hostdata->sync_xfer[cmd->device->id]);
#endif
hostdata->sync_stat[cmd->device->id] = SS_SET;
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
break;
case EXTENDED_WDTR:
write_3393_cmd(hostdata, WD_CMD_ASSERT_ATN); /* want MESS_OUT */
printk("sending WDTR ");
hostdata->outgoing_msg[0] = EXTENDED_MESSAGE;
hostdata->outgoing_msg[1] = 2;
hostdata->outgoing_msg[2] = EXTENDED_WDTR;
hostdata->outgoing_msg[3] = 0; /* 8 bit transfer width */
hostdata->outgoing_len = 4;
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
break;
default:
write_3393_cmd(hostdata, WD_CMD_ASSERT_ATN); /* want MESS_OUT */
printk("Rejecting Unknown Extended Message(%02x). ", ucp[2]);
hostdata->outgoing_msg[0] = MESSAGE_REJECT;
hostdata->outgoing_len = 1;
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
break;
}
hostdata->incoming_ptr = 0;
}
/* We need to read more MESS_IN bytes for the extended message */
else {
hostdata->incoming_ptr++;
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
}
break;
default:
printk("Rejecting Unknown Message(%02x) ", msg);
write_3393_cmd(hostdata, WD_CMD_ASSERT_ATN); /* want MESS_OUT */
hostdata->outgoing_msg[0] = MESSAGE_REJECT;
hostdata->outgoing_len = 1;
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
hostdata->state = S_CONNECTED;
}
break;
/* Note: this interrupt will occur only after a LEVEL2 command */
case CSR_SEL_XFER_DONE:
/* Make sure that reselection is enabled at this point - it may
* have been turned off for the command that just completed.
*/
write_3393(hostdata, WD_SOURCE_ID, SRCID_ER);
if (phs == 0x60) {
DB(DB_INTR, printk("SX-DONE"))
cmd->SCp.Message = COMMAND_COMPLETE;
lun = read_3393(hostdata, WD_TARGET_LUN);
DB(DB_INTR, printk(":%d.%d", cmd->SCp.Status, lun))
hostdata->connected = NULL;
hostdata->busy[cmd->device->id] &= ~(1 << cmd->device->lun);
hostdata->state = S_UNCONNECTED;
if (cmd->SCp.Status == ILLEGAL_STATUS_BYTE)
cmd->SCp.Status = lun;
if (cmd->cmnd[0] == REQUEST_SENSE && cmd->SCp.Status != GOOD)
cmd->result = (cmd->result & 0x00ffff) | (DID_ERROR << 16);
else
cmd->result = cmd->SCp.Status | (cmd->SCp.Message << 8);
cmd->scsi_done(cmd);
/* We are no longer connected to a target - check to see if
* there are commands waiting to be executed.
*/
in2000_execute(instance);
} else {
printk("%02x:%02x:%02x: Unknown SEL_XFER_DONE phase!!---", asr, sr, phs);
}
break;
/* Note: this interrupt will occur only after a LEVEL2 command */
case CSR_SDP:
DB(DB_INTR, printk("SDP"))
hostdata->state = S_RUNNING_LEVEL2;
write_3393(hostdata, WD_COMMAND_PHASE, 0x41);
write_3393_cmd(hostdata, WD_CMD_SEL_ATN_XFER);
break;
case CSR_XFER_DONE | PHS_MESS_OUT:
case CSR_UNEXP | PHS_MESS_OUT:
case CSR_SRV_REQ | PHS_MESS_OUT:
DB(DB_INTR, printk("MSG_OUT="))
/* To get here, we've probably requested MESSAGE_OUT and have
* already put the correct bytes in outgoing_msg[] and filled
* in outgoing_len. We simply send them out to the SCSI bus.
* Sometimes we get MESSAGE_OUT phase when we're not expecting
* it - like when our SDTR message is rejected by a target. Some
* targets send the REJECT before receiving all of the extended
* message, and then seem to go back to MESSAGE_OUT for a byte
* or two. Not sure why, or if I'm doing something wrong to
* cause this to happen. Regardless, it seems that sending
* NOP messages in these situations results in no harm and
* makes everyone happy.
*/
if (hostdata->outgoing_len == 0) {
hostdata->outgoing_len = 1;
hostdata->outgoing_msg[0] = NOP;
}
transfer_pio(hostdata->outgoing_msg, hostdata->outgoing_len, DATA_OUT_DIR, hostdata);
DB(DB_INTR, printk("%02x", hostdata->outgoing_msg[0]))
hostdata->outgoing_len = 0;
hostdata->state = S_CONNECTED;
break;
case CSR_UNEXP_DISC:
/* I think I've seen this after a request-sense that was in response
* to an error condition, but not sure. We certainly need to do
* something when we get this interrupt - the question is 'what?'.
* Let's think positively, and assume some command has finished
* in a legal manner (like a command that provokes a request-sense),
* so we treat it as a normal command-complete-disconnect.
*/
/* Make sure that reselection is enabled at this point - it may
* have been turned off for the command that just completed.
*/
write_3393(hostdata, WD_SOURCE_ID, SRCID_ER);
if (cmd == NULL) {
printk(" - Already disconnected! ");
hostdata->state = S_UNCONNECTED;
/* release the SMP spin_lock and restore irq state */
spin_unlock_irqrestore(instance->host_lock, flags);
return IRQ_HANDLED;
}
DB(DB_INTR, printk("UNEXP_DISC"))
hostdata->connected = NULL;
hostdata->busy[cmd->device->id] &= ~(1 << cmd->device->lun);
hostdata->state = S_UNCONNECTED;
if (cmd->cmnd[0] == REQUEST_SENSE && cmd->SCp.Status != GOOD)
cmd->result = (cmd->result & 0x00ffff) | (DID_ERROR << 16);
else
cmd->result = cmd->SCp.Status | (cmd->SCp.Message << 8);
cmd->scsi_done(cmd);
/* We are no longer connected to a target - check to see if
* there are commands waiting to be executed.
*/
in2000_execute(instance);
break;
case CSR_DISC:
/* Make sure that reselection is enabled at this point - it may
* have been turned off for the command that just completed.
*/
write_3393(hostdata, WD_SOURCE_ID, SRCID_ER);
DB(DB_INTR, printk("DISC"))
if (cmd == NULL) {
printk(" - Already disconnected! ");
hostdata->state = S_UNCONNECTED;
}
switch (hostdata->state) {
case S_PRE_CMP_DISC:
hostdata->connected = NULL;
hostdata->busy[cmd->device->id] &= ~(1 << cmd->device->lun);
hostdata->state = S_UNCONNECTED;
DB(DB_INTR, printk(":%d", cmd->SCp.Status))
if (cmd->cmnd[0] == REQUEST_SENSE && cmd->SCp.Status != GOOD)
cmd->result = (cmd->result & 0x00ffff) | (DID_ERROR << 16);
else
cmd->result = cmd->SCp.Status | (cmd->SCp.Message << 8);
cmd->scsi_done(cmd);
break;
case S_PRE_TMP_DISC:
case S_RUNNING_LEVEL2:
cmd->host_scribble = (uchar *) hostdata->disconnected_Q;
hostdata->disconnected_Q = cmd;
hostdata->connected = NULL;
hostdata->state = S_UNCONNECTED;
#ifdef PROC_STATISTICS
hostdata->disc_done_cnt[cmd->device->id]++;
#endif
break;
default:
printk("*** Unexpected DISCONNECT interrupt! ***");
hostdata->state = S_UNCONNECTED;
}
/* We are no longer connected to a target - check to see if
* there are commands waiting to be executed.
*/
in2000_execute(instance);
break;
case CSR_RESEL_AM:
DB(DB_INTR, printk("RESEL"))
/* First we have to make sure this reselection didn't */
/* happen during Arbitration/Selection of some other device. */
/* If yes, put losing command back on top of input_Q. */
if (hostdata->level2 <= L2_NONE) {
if (hostdata->selecting) {
cmd = (Scsi_Cmnd *) hostdata->selecting;
hostdata->selecting = NULL;
hostdata->busy[cmd->device->id] &= ~(1 << cmd->device->lun);
cmd->host_scribble = (uchar *) hostdata->input_Q;
hostdata->input_Q = cmd;
}
}
else {
if (cmd) {
if (phs == 0x00) {
hostdata->busy[cmd->device->id] &= ~(1 << cmd->device->lun);
cmd->host_scribble = (uchar *) hostdata->input_Q;
hostdata->input_Q = cmd;
} else {
printk("---%02x:%02x:%02x-TROUBLE: Intrusive ReSelect!---", asr, sr, phs);
while (1)
printk("\r");
}
}
}
/* OK - find out which device reselected us. */
id = read_3393(hostdata, WD_SOURCE_ID);
id &= SRCID_MASK;
/* and extract the lun from the ID message. (Note that we don't
* bother to check for a valid message here - I guess this is
* not the right way to go, but....)
*/
lun = read_3393(hostdata, WD_DATA);
if (hostdata->level2 < L2_RESELECT)
write_3393_cmd(hostdata, WD_CMD_NEGATE_ACK);
lun &= 7;
/* Now we look for the command that's reconnecting. */
cmd = (Scsi_Cmnd *) hostdata->disconnected_Q;
patch = NULL;
while (cmd) {
if (id == cmd->device->id && lun == cmd->device->lun)
break;
patch = cmd;
cmd = (Scsi_Cmnd *) cmd->host_scribble;
}
/* Hmm. Couldn't find a valid command.... What to do? */
if (!cmd) {
printk("---TROUBLE: target %d.%d not in disconnect queue---", id, lun);
break;
}
/* Ok, found the command - now start it up again. */
if (patch)
patch->host_scribble = cmd->host_scribble;
else
hostdata->disconnected_Q = (Scsi_Cmnd *) cmd->host_scribble;
hostdata->connected = cmd;
/* We don't need to worry about 'initialize_SCp()' or 'hostdata->busy[]'
* because these things are preserved over a disconnect.
* But we DO need to fix the DPD bit so it's correct for this command.
*/
if (is_dir_out(cmd))
write_3393(hostdata, WD_DESTINATION_ID, cmd->device->id);
else
write_3393(hostdata, WD_DESTINATION_ID, cmd->device->id | DSTID_DPD);
if (hostdata->level2 >= L2_RESELECT) {
write_3393_count(hostdata, 0); /* we want a DATA_PHASE interrupt */
write_3393(hostdata, WD_COMMAND_PHASE, 0x45);
write_3393_cmd(hostdata, WD_CMD_SEL_ATN_XFER);
hostdata->state = S_RUNNING_LEVEL2;
} else
hostdata->state = S_CONNECTED;
break;
default:
printk("--UNKNOWN INTERRUPT:%02x:%02x:%02x--", asr, sr, phs);
}
write1_io(0, IO_LED_OFF);
DB(DB_INTR, printk("} "))
/* release the SMP spin_lock and restore irq state */
spin_unlock_irqrestore(instance->host_lock, flags);
return IRQ_HANDLED;
}
#define RESET_CARD 0
#define RESET_CARD_AND_BUS 1
#define B_FLAG 0x80
/*
* Caller must hold instance lock!
*/
static int reset_hardware(struct Scsi_Host *instance, int type)
{
struct IN2000_hostdata *hostdata;
int qt, x;
hostdata = (struct IN2000_hostdata *) instance->hostdata;
write1_io(0, IO_LED_ON);
if (type == RESET_CARD_AND_BUS) {
write1_io(0, IO_CARD_RESET);
x = read1_io(IO_HARDWARE);
}
x = read_3393(hostdata, WD_SCSI_STATUS); /* clear any WD intrpt */
write_3393(hostdata, WD_OWN_ID, instance->this_id | OWNID_EAF | OWNID_RAF | OWNID_FS_8);
write_3393(hostdata, WD_CONTROL, CTRL_IDI | CTRL_EDI | CTRL_POLLED);
write_3393(hostdata, WD_SYNCHRONOUS_TRANSFER, calc_sync_xfer(hostdata->default_sx_per / 4, DEFAULT_SX_OFF));
write1_io(0, IO_FIFO_WRITE); /* clear fifo counter */
write1_io(0, IO_FIFO_READ); /* start fifo out in read mode */
write_3393(hostdata, WD_COMMAND, WD_CMD_RESET);
/* FIXME: timeout ?? */
while (!(READ_AUX_STAT() & ASR_INT))
cpu_relax(); /* wait for RESET to complete */
x = read_3393(hostdata, WD_SCSI_STATUS); /* clear interrupt */
write_3393(hostdata, WD_QUEUE_TAG, 0xa5); /* any random number */
qt = read_3393(hostdata, WD_QUEUE_TAG);
if (qt == 0xa5) {
x |= B_FLAG;
write_3393(hostdata, WD_QUEUE_TAG, 0);
}
write_3393(hostdata, WD_TIMEOUT_PERIOD, TIMEOUT_PERIOD_VALUE);
write_3393(hostdata, WD_CONTROL, CTRL_IDI | CTRL_EDI | CTRL_POLLED);
write1_io(0, IO_LED_OFF);
return x;
}
static int in2000_bus_reset(Scsi_Cmnd * cmd)
{
struct Scsi_Host *instance;
struct IN2000_hostdata *hostdata;
int x;
unsigned long flags;
instance = cmd->device->host;
hostdata = (struct IN2000_hostdata *) instance->hostdata;
printk(KERN_WARNING "scsi%d: Reset. ", instance->host_no);
spin_lock_irqsave(instance->host_lock, flags);
/* do scsi-reset here */
reset_hardware(instance, RESET_CARD_AND_BUS);
for (x = 0; x < 8; x++) {
hostdata->busy[x] = 0;
hostdata->sync_xfer[x] = calc_sync_xfer(DEFAULT_SX_PER / 4, DEFAULT_SX_OFF);
hostdata->sync_stat[x] = SS_UNSET; /* using default sync values */
}
hostdata->input_Q = NULL;
hostdata->selecting = NULL;
hostdata->connected = NULL;
hostdata->disconnected_Q = NULL;
hostdata->state = S_UNCONNECTED;
hostdata->fifo = FI_FIFO_UNUSED;
hostdata->incoming_ptr = 0;
hostdata->outgoing_len = 0;
cmd->result = DID_RESET << 16;
spin_unlock_irqrestore(instance->host_lock, flags);
return SUCCESS;
}
static int __in2000_abort(Scsi_Cmnd * cmd)
{
struct Scsi_Host *instance;
struct IN2000_hostdata *hostdata;
Scsi_Cmnd *tmp, *prev;
uchar sr, asr;
unsigned long timeout;
instance = cmd->device->host;
hostdata = (struct IN2000_hostdata *) instance->hostdata;
printk(KERN_DEBUG "scsi%d: Abort-", instance->host_no);
printk("(asr=%02x,count=%ld,resid=%d,buf_resid=%d,have_data=%d,FC=%02x)- ", READ_AUX_STAT(), read_3393_count(hostdata), cmd->SCp.this_residual, cmd->SCp.buffers_residual, cmd->SCp.have_data_in, read1_io(IO_FIFO_COUNT));
/*
* Case 1 : If the command hasn't been issued yet, we simply remove it
* from the inout_Q.
*/
tmp = (Scsi_Cmnd *) hostdata->input_Q;
prev = NULL;
while (tmp) {
if (tmp == cmd) {
if (prev)
prev->host_scribble = cmd->host_scribble;
cmd->host_scribble = NULL;
cmd->result = DID_ABORT << 16;
printk(KERN_WARNING "scsi%d: Abort - removing command from input_Q. ", instance->host_no);
cmd->scsi_done(cmd);
return SUCCESS;
}
prev = tmp;
tmp = (Scsi_Cmnd *) tmp->host_scribble;
}
/*
* Case 2 : If the command is connected, we're going to fail the abort
* and let the high level SCSI driver retry at a later time or
* issue a reset.
*
* Timeouts, and therefore aborted commands, will be highly unlikely
* and handling them cleanly in this situation would make the common
* case of noresets less efficient, and would pollute our code. So,
* we fail.
*/
if (hostdata->connected == cmd) {
printk(KERN_WARNING "scsi%d: Aborting connected command - ", instance->host_no);
printk("sending wd33c93 ABORT command - ");
write_3393(hostdata, WD_CONTROL, CTRL_IDI | CTRL_EDI | CTRL_POLLED);
write_3393_cmd(hostdata, WD_CMD_ABORT);
/* Now we have to attempt to flush out the FIFO... */
printk("flushing fifo - ");
timeout = 1000000;
do {
asr = READ_AUX_STAT();
if (asr & ASR_DBR)
read_3393(hostdata, WD_DATA);
} while (!(asr & ASR_INT) && timeout-- > 0);
sr = read_3393(hostdata, WD_SCSI_STATUS);
printk("asr=%02x, sr=%02x, %ld bytes un-transferred (timeout=%ld) - ", asr, sr, read_3393_count(hostdata), timeout);
/*
* Abort command processed.
* Still connected.
* We must disconnect.
*/
printk("sending wd33c93 DISCONNECT command - ");
write_3393_cmd(hostdata, WD_CMD_DISCONNECT);
timeout = 1000000;
asr = READ_AUX_STAT();
while ((asr & ASR_CIP) && timeout-- > 0)
asr = READ_AUX_STAT();
sr = read_3393(hostdata, WD_SCSI_STATUS);
printk("asr=%02x, sr=%02x.", asr, sr);
hostdata->busy[cmd->device->id] &= ~(1 << cmd->device->lun);
hostdata->connected = NULL;
hostdata->state = S_UNCONNECTED;
cmd->result = DID_ABORT << 16;
cmd->scsi_done(cmd);
in2000_execute(instance);
return SUCCESS;
}
/*
* Case 3: If the command is currently disconnected from the bus,
* we're not going to expend much effort here: Let's just return
* an ABORT_SNOOZE and hope for the best...
*/
for (tmp = (Scsi_Cmnd *) hostdata->disconnected_Q; tmp; tmp = (Scsi_Cmnd *) tmp->host_scribble)
if (cmd == tmp) {
printk(KERN_DEBUG "scsi%d: unable to abort disconnected command.\n", instance->host_no);
return FAILED;
}
/*
* Case 4 : If we reached this point, the command was not found in any of
* the queues.
*
* We probably reached this point because of an unlikely race condition
* between the command completing successfully and the abortion code,
* so we won't panic, but we will notify the user in case something really
* broke.
*/
in2000_execute(instance);
printk("scsi%d: warning : SCSI command probably completed successfully" " before abortion. ", instance->host_no);
return SUCCESS;
}
static int in2000_abort(Scsi_Cmnd * cmd)
{
int rc;
spin_lock_irq(cmd->device->host->host_lock);
rc = __in2000_abort(cmd);
spin_unlock_irq(cmd->device->host->host_lock);
return rc;
}
#define MAX_IN2000_HOSTS 3
#define MAX_SETUP_ARGS ARRAY_SIZE(setup_args)
#define SETUP_BUFFER_SIZE 200
static char setup_buffer[SETUP_BUFFER_SIZE];
static char setup_used[MAX_SETUP_ARGS];
static int done_setup = 0;
static void __init in2000_setup(char *str, int *ints)
{
int i;
char *p1, *p2;
strlcpy(setup_buffer, str, SETUP_BUFFER_SIZE);
p1 = setup_buffer;
i = 0;
while (*p1 && (i < MAX_SETUP_ARGS)) {
p2 = strchr(p1, ',');
if (p2) {
*p2 = '\0';
if (p1 != p2)
setup_args[i] = p1;
p1 = p2 + 1;
i++;
} else {
setup_args[i] = p1;
break;
}
}
for (i = 0; i < MAX_SETUP_ARGS; i++)
setup_used[i] = 0;
done_setup = 1;
}
/* check_setup_args() returns index if key found, 0 if not
*/
static int __init check_setup_args(char *key, int *val, char *buf)
{
int x;
char *cp;
for (x = 0; x < MAX_SETUP_ARGS; x++) {
if (setup_used[x])
continue;
if (!strncmp(setup_args[x], key, strlen(key)))
break;
}
if (x == MAX_SETUP_ARGS)
return 0;
setup_used[x] = 1;
cp = setup_args[x] + strlen(key);
*val = -1;
if (*cp != ':')
return ++x;
cp++;
if ((*cp >= '0') && (*cp <= '9')) {
*val = simple_strtoul(cp, NULL, 0);
}
return ++x;
}
/* The "correct" (ie portable) way to access memory-mapped hardware
* such as the IN2000 EPROM and dip switch is through the use of
* special macros declared in 'asm/io.h'. We use readb() and readl()
* when reading from the card's BIOS area in in2000_detect().
*/
static u32 bios_tab[] in2000__INITDATA = {
0xc8000,
0xd0000,
0xd8000,
0
};
static unsigned short base_tab[] in2000__INITDATA = {
0x220,
0x200,
0x110,
0x100,
};
static int int_tab[] in2000__INITDATA = {
15,
14,
11,
10
};
static int probe_bios(u32 addr, u32 *s1, uchar *switches)
{
void __iomem *p = ioremap(addr, 0x34);
if (!p)
return 0;
*s1 = readl(p + 0x10);
if (*s1 == 0x41564f4e || readl(p + 0x30) == 0x61776c41) {
/* Read the switch image that's mapped into EPROM space */
*switches = ~readb(p + 0x20);
iounmap(p);
return 1;
}
iounmap(p);
return 0;
}
static int __init in2000_detect(struct scsi_host_template * tpnt)
{
struct Scsi_Host *instance;
struct IN2000_hostdata *hostdata;
int detect_count;
int bios;
int x;
unsigned short base;
uchar switches;
uchar hrev;
unsigned long flags;
int val;
char buf[32];
/* Thanks to help from Bill Earnest, probing for IN2000 cards is a
* pretty straightforward and fool-proof operation. There are 3
* possible locations for the IN2000 EPROM in memory space - if we
* find a BIOS signature, we can read the dip switch settings from
* the byte at BIOS+32 (shadowed in by logic on the card). From 2
* of the switch bits we get the card's address in IO space. There's
* an image of the dip switch there, also, so we have a way to back-
* check that this really is an IN2000 card. Very nifty. Use the
* 'ioport:xx' command-line parameter if your BIOS EPROM is absent
* or disabled.
*/
if (!done_setup && setup_strings)
in2000_setup(setup_strings, NULL);
detect_count = 0;
for (bios = 0; bios_tab[bios]; bios++) {
u32 s1 = 0;
if (check_setup_args("ioport", &val, buf)) {
base = val;
switches = ~inb(base + IO_SWITCHES) & 0xff;
printk("Forcing IN2000 detection at IOport 0x%x ", base);
bios = 2;
}
/*
* There have been a couple of BIOS versions with different layouts
* for the obvious ID strings. We look for the 2 most common ones and
* hope that they cover all the cases...
*/
else if (probe_bios(bios_tab[bios], &s1, &switches)) {
printk("Found IN2000 BIOS at 0x%x ", (unsigned int) bios_tab[bios]);
/* Find out where the IO space is */
x = switches & (SW_ADDR0 | SW_ADDR1);
base = base_tab[x];
/* Check for the IN2000 signature in IO space. */
x = ~inb(base + IO_SWITCHES) & 0xff;
if (x != switches) {
printk("Bad IO signature: %02x vs %02x.\n", x, switches);
continue;
}
} else
continue;
/* OK. We have a base address for the IO ports - run a few safety checks */
if (!(switches & SW_BIT7)) { /* I _think_ all cards do this */
printk("There is no IN-2000 SCSI card at IOport 0x%03x!\n", base);
continue;
}
/* Let's assume any hardware version will work, although the driver
* has only been tested on 0x21, 0x22, 0x25, 0x26, and 0x27. We'll
* print out the rev number for reference later, but accept them all.
*/
hrev = inb(base + IO_HARDWARE);
/* Bit 2 tells us if interrupts are disabled */
if (switches & SW_DISINT) {
printk("The IN-2000 SCSI card at IOport 0x%03x ", base);
printk("is not configured for interrupt operation!\n");
printk("This driver requires an interrupt: cancelling detection.\n");
continue;
}
/* Ok. We accept that there's an IN2000 at ioaddr 'base'. Now
* initialize it.
*/
tpnt->proc_name = "in2000";
instance = scsi_register(tpnt, sizeof(struct IN2000_hostdata));
if (instance == NULL)
continue;
detect_count++;
hostdata = (struct IN2000_hostdata *) instance->hostdata;
instance->io_port = hostdata->io_base = base;
hostdata->dip_switch = switches;
hostdata->hrev = hrev;
write1_io(0, IO_FIFO_WRITE); /* clear fifo counter */
write1_io(0, IO_FIFO_READ); /* start fifo out in read mode */
write1_io(0, IO_INTR_MASK); /* allow all ints */
x = int_tab[(switches & (SW_INT0 | SW_INT1)) >> SW_INT_SHIFT];
if (request_irq(x, in2000_intr, 0, "in2000", instance)) {
printk("in2000_detect: Unable to allocate IRQ.\n");
detect_count--;
continue;
}
instance->irq = x;
instance->n_io_port = 13;
request_region(base, 13, "in2000"); /* lock in this IO space for our use */
for (x = 0; x < 8; x++) {
hostdata->busy[x] = 0;
hostdata->sync_xfer[x] = calc_sync_xfer(DEFAULT_SX_PER / 4, DEFAULT_SX_OFF);
hostdata->sync_stat[x] = SS_UNSET; /* using default sync values */
#ifdef PROC_STATISTICS
hostdata->cmd_cnt[x] = 0;
hostdata->disc_allowed_cnt[x] = 0;
hostdata->disc_done_cnt[x] = 0;
#endif
}
hostdata->input_Q = NULL;
hostdata->selecting = NULL;
hostdata->connected = NULL;
hostdata->disconnected_Q = NULL;
hostdata->state = S_UNCONNECTED;
hostdata->fifo = FI_FIFO_UNUSED;
hostdata->level2 = L2_BASIC;
hostdata->disconnect = DIS_ADAPTIVE;
hostdata->args = DEBUG_DEFAULTS;
hostdata->incoming_ptr = 0;
hostdata->outgoing_len = 0;
hostdata->default_sx_per = DEFAULT_SX_PER;
/* Older BIOS's had a 'sync on/off' switch - use its setting */
if (s1 == 0x41564f4e && (switches & SW_SYNC_DOS5))
hostdata->sync_off = 0x00; /* sync defaults to on */
else
hostdata->sync_off = 0xff; /* sync defaults to off */
#ifdef PROC_INTERFACE
hostdata->proc = PR_VERSION | PR_INFO | PR_STATISTICS | PR_CONNECTED | PR_INPUTQ | PR_DISCQ | PR_STOP;
#ifdef PROC_STATISTICS
hostdata->int_cnt = 0;
#endif
#endif
if (check_setup_args("nosync", &val, buf))
hostdata->sync_off = val;
if (check_setup_args("period", &val, buf))
hostdata->default_sx_per = sx_table[round_period((unsigned int) val)].period_ns;
if (check_setup_args("disconnect", &val, buf)) {
if ((val >= DIS_NEVER) && (val <= DIS_ALWAYS))
hostdata->disconnect = val;
else
hostdata->disconnect = DIS_ADAPTIVE;
}
if (check_setup_args("noreset", &val, buf))
hostdata->args ^= A_NO_SCSI_RESET;
if (check_setup_args("level2", &val, buf))
hostdata->level2 = val;
if (check_setup_args("debug", &val, buf))
hostdata->args = (val & DB_MASK);
#ifdef PROC_INTERFACE
if (check_setup_args("proc", &val, buf))
hostdata->proc = val;
#endif
/* FIXME: not strictly needed I think but the called code expects
to be locked */
spin_lock_irqsave(instance->host_lock, flags);
x = reset_hardware(instance, (hostdata->args & A_NO_SCSI_RESET) ? RESET_CARD : RESET_CARD_AND_BUS);
spin_unlock_irqrestore(instance->host_lock, flags);
hostdata->microcode = read_3393(hostdata, WD_CDB_1);
if (x & 0x01) {
if (x & B_FLAG)
hostdata->chip = C_WD33C93B;
else
hostdata->chip = C_WD33C93A;
} else
hostdata->chip = C_WD33C93;
printk("dip_switch=%02x irq=%d ioport=%02x floppy=%s sync/DOS5=%s ", (switches & 0x7f), instance->irq, hostdata->io_base, (switches & SW_FLOPPY) ? "Yes" : "No", (switches & SW_SYNC_DOS5) ? "Yes" : "No");
printk("hardware_ver=%02x chip=%s microcode=%02x\n", hrev, (hostdata->chip == C_WD33C93) ? "WD33c93" : (hostdata->chip == C_WD33C93A) ? "WD33c93A" : (hostdata->chip == C_WD33C93B) ? "WD33c93B" : "unknown", hostdata->microcode);
#ifdef DEBUGGING_ON
printk("setup_args = ");
for (x = 0; x < MAX_SETUP_ARGS; x++)
printk("%s,", setup_args[x]);
printk("\n");
#endif
if (hostdata->sync_off == 0xff)
printk("Sync-transfer DISABLED on all devices: ENABLE from command-line\n");
printk("IN2000 driver version %s - %s\n", IN2000_VERSION, IN2000_DATE);
}
return detect_count;
}
static int in2000_release(struct Scsi_Host *shost)
{
if (shost->irq)
free_irq(shost->irq, shost);
if (shost->io_port && shost->n_io_port)
release_region(shost->io_port, shost->n_io_port);
return 0;
}
/* NOTE: I lifted this function straight out of the old driver,
* and have not tested it. Presumably it does what it's
* supposed to do...
*/
static int in2000_biosparam(struct scsi_device *sdev, struct block_device *bdev, sector_t capacity, int *iinfo)
{
int size;
size = capacity;
iinfo[0] = 64;
iinfo[1] = 32;
iinfo[2] = size >> 11;
/* This should approximate the large drive handling that the DOS ASPI manager
uses. Drives very near the boundaries may not be handled correctly (i.e.
near 2.0 Gb and 4.0 Gb) */
if (iinfo[2] > 1024) {
iinfo[0] = 64;
iinfo[1] = 63;
iinfo[2] = (unsigned long) capacity / (iinfo[0] * iinfo[1]);
}
if (iinfo[2] > 1024) {
iinfo[0] = 128;
iinfo[1] = 63;
iinfo[2] = (unsigned long) capacity / (iinfo[0] * iinfo[1]);
}
if (iinfo[2] > 1024) {
iinfo[0] = 255;
iinfo[1] = 63;
iinfo[2] = (unsigned long) capacity / (iinfo[0] * iinfo[1]);
}
return 0;
}
static int in2000_write_info(struct Scsi_Host *instance, char *buf, int len)
{
#ifdef PROC_INTERFACE
char *bp;
struct IN2000_hostdata *hd;
int x, i;
hd = (struct IN2000_hostdata *) instance->hostdata;
buf[len] = '\0';
bp = buf;
if (!strncmp(bp, "debug:", 6)) {
bp += 6;
hd->args = simple_strtoul(bp, NULL, 0) & DB_MASK;
} else if (!strncmp(bp, "disconnect:", 11)) {
bp += 11;
x = simple_strtoul(bp, NULL, 0);
if (x < DIS_NEVER || x > DIS_ALWAYS)
x = DIS_ADAPTIVE;
hd->disconnect = x;
} else if (!strncmp(bp, "period:", 7)) {
bp += 7;
x = simple_strtoul(bp, NULL, 0);
hd->default_sx_per = sx_table[round_period((unsigned int) x)].period_ns;
} else if (!strncmp(bp, "resync:", 7)) {
bp += 7;
x = simple_strtoul(bp, NULL, 0);
for (i = 0; i < 7; i++)
if (x & (1 << i))
hd->sync_stat[i] = SS_UNSET;
} else if (!strncmp(bp, "proc:", 5)) {
bp += 5;
hd->proc = simple_strtoul(bp, NULL, 0);
} else if (!strncmp(bp, "level2:", 7)) {
bp += 7;
hd->level2 = simple_strtoul(bp, NULL, 0);
}
#endif
return len;
}
static int in2000_show_info(struct seq_file *m, struct Scsi_Host *instance)
{
#ifdef PROC_INTERFACE
unsigned long flags;
struct IN2000_hostdata *hd;
Scsi_Cmnd *cmd;
int x;
hd = (struct IN2000_hostdata *) instance->hostdata;
spin_lock_irqsave(instance->host_lock, flags);
if (hd->proc & PR_VERSION)
seq_printf(m, "\nVersion %s - %s.", IN2000_VERSION, IN2000_DATE);
if (hd->proc & PR_INFO) {
seq_printf(m, "\ndip_switch=%02x: irq=%d io=%02x floppy=%s sync/DOS5=%s", (hd->dip_switch & 0x7f), instance->irq, hd->io_base, (hd->dip_switch & 0x40) ? "Yes" : "No", (hd->dip_switch & 0x20) ? "Yes" : "No");
seq_printf(m, "\nsync_xfer[] = ");
for (x = 0; x < 7; x++)
seq_printf(m, "\t%02x", hd->sync_xfer[x]);
seq_printf(m, "\nsync_stat[] = ");
for (x = 0; x < 7; x++)
seq_printf(m, "\t%02x", hd->sync_stat[x]);
}
#ifdef PROC_STATISTICS
if (hd->proc & PR_STATISTICS) {
seq_printf(m, "\ncommands issued: ");
for (x = 0; x < 7; x++)
seq_printf(m, "\t%ld", hd->cmd_cnt[x]);
seq_printf(m, "\ndisconnects allowed:");
for (x = 0; x < 7; x++)
seq_printf(m, "\t%ld", hd->disc_allowed_cnt[x]);
seq_printf(m, "\ndisconnects done: ");
for (x = 0; x < 7; x++)
seq_printf(m, "\t%ld", hd->disc_done_cnt[x]);
seq_printf(m, "\ninterrupts: \t%ld", hd->int_cnt);
}
#endif
if (hd->proc & PR_CONNECTED) {
seq_printf(m, "\nconnected: ");
if (hd->connected) {
cmd = (Scsi_Cmnd *) hd->connected;
seq_printf(m, " %d:%d(%02x)", cmd->device->id, cmd->device->lun, cmd->cmnd[0]);
}
}
if (hd->proc & PR_INPUTQ) {
seq_printf(m, "\ninput_Q: ");
cmd = (Scsi_Cmnd *) hd->input_Q;
while (cmd) {
seq_printf(m, " %d:%d(%02x)", cmd->device->id, cmd->device->lun, cmd->cmnd[0]);
cmd = (Scsi_Cmnd *) cmd->host_scribble;
}
}
if (hd->proc & PR_DISCQ) {
seq_printf(m, "\ndisconnected_Q:");
cmd = (Scsi_Cmnd *) hd->disconnected_Q;
while (cmd) {
seq_printf(m, " %d:%d(%02x)", cmd->device->id, cmd->device->lun, cmd->cmnd[0]);
cmd = (Scsi_Cmnd *) cmd->host_scribble;
}
}
if (hd->proc & PR_TEST) {
; /* insert your own custom function here */
}
seq_printf(m, "\n");
spin_unlock_irqrestore(instance->host_lock, flags);
#endif /* PROC_INTERFACE */
return 0;
}
MODULE_LICENSE("GPL");
static struct scsi_host_template driver_template = {
.proc_name = "in2000",
.write_info = in2000_write_info,
.show_info = in2000_show_info,
.name = "Always IN2000",
.detect = in2000_detect,
.release = in2000_release,
.queuecommand = in2000_queuecommand,
.eh_abort_handler = in2000_abort,
.eh_bus_reset_handler = in2000_bus_reset,
.bios_param = in2000_biosparam,
.can_queue = IN2000_CAN_Q,
.this_id = IN2000_HOST_ID,
.sg_tablesize = IN2000_SG,
.cmd_per_lun = IN2000_CPL,
.use_clustering = DISABLE_CLUSTERING,
};
#include "scsi_module.c"