dev/pci/twa.c

1.16  christos /*	$NetBSD: twa.c,v 1.16 2006/11/16 01:33:10 christos Exp $ */
 1.8  wrstuden /*	$wasabi: twa.c,v 1.27 2006/07/28 18:17:21 wrstuden Exp $	*/
 1.1  wrstuden
 1.1  wrstuden /*-
 1.1  wrstuden  * Copyright (c) 2004 The NetBSD Foundation, Inc.
 1.1  wrstuden  * All rights reserved.
 1.1  wrstuden  *
 1.1  wrstuden  * This code is derived from software contributed to The NetBSD Foundation
 1.1  wrstuden  * by Jordan Rhody of Wasabi Systems, Inc.
 1.1  wrstuden  *
 1.1  wrstuden  * Redistribution and use in source and binary forms, with or without
 1.1  wrstuden  * modification, are permitted provided that the following conditions
 1.1  wrstuden  * are met:
 1.1  wrstuden  * 1. Redistributions of source code must retain the above copyright
 1.1  wrstuden  *    notice, this list of conditions and the following disclaimer.
 1.1  wrstuden  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  wrstuden  *    notice, this list of conditions and the following disclaimer in the
 1.1  wrstuden  *    documentation and/or other materials provided with the distribution.
 1.1  wrstuden  * 3. All advertising materials mentioning features or use of this software
 1.1  wrstuden  *    must display the following acknowledgement:
 1.1  wrstuden  *        This product includes software developed by the NetBSD
 1.1  wrstuden  *        Foundation, Inc. and its contributors.
 1.1  wrstuden  * 4. Neither the name of The NetBSD Foundation nor the names of its
 1.1  wrstuden  *    contributors may be used to endorse or promote products derived
 1.1  wrstuden  *    from this software without specific prior written permission.
 1.1  wrstuden  *
 1.1  wrstuden  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1  wrstuden  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1  wrstuden  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1  wrstuden  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1  wrstuden  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1  wrstuden  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1  wrstuden  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1  wrstuden  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1  wrstuden  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1  wrstuden  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1  wrstuden  * POSSIBILITY OF SUCH DAMAGE.
 1.1  wrstuden  */
 1.1  wrstuden
 1.1  wrstuden /*-
 1.1  wrstuden  * Copyright (c) 2003-04 3ware, Inc.
 1.1  wrstuden  * Copyright (c) 2000 Michael Smith
 1.1  wrstuden  * Copyright (c) 2000 BSDi
 1.1  wrstuden  * All rights reserved.
 1.1  wrstuden  *
 1.1  wrstuden  * Redistribution and use in source and binary forms, with or without
 1.1  wrstuden  * modification, are permitted provided that the following conditions
 1.1  wrstuden  * are met:
 1.1  wrstuden  * 1. Redistributions of source code must retain the above copyright
 1.1  wrstuden  *    notice, this list of conditions and the following disclaimer.
 1.1  wrstuden  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  wrstuden  *    notice, this list of conditions and the following disclaimer in the
 1.1  wrstuden  *    documentation and/or other materials provided with the distribution.
 1.1  wrstuden  *
 1.1  wrstuden  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
 1.1  wrstuden  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1  wrstuden  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1  wrstuden  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
 1.1  wrstuden  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1  wrstuden  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 1.1  wrstuden  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1  wrstuden  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1  wrstuden  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1  wrstuden  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1  wrstuden  * SUCH DAMAGE.
 1.1  wrstuden  *
 1.1  wrstuden  *	$FreeBSD: src/sys/dev/twa/twa.c,v 1.2 2004/04/02 15:09:57 des Exp $
 1.1  wrstuden  */
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * 3ware driver for 9000 series storage controllers.
 1.1  wrstuden  *
 1.1  wrstuden  * Author: Vinod Kashyap
 1.1  wrstuden  */
 1.1  wrstuden
 1.1  wrstuden #include <sys/cdefs.h>
1.16  christos __KERNEL_RCSID(0, "$NetBSD: twa.c,v 1.16 2006/11/16 01:33:10 christos Exp $");
 1.1  wrstuden
 1.1  wrstuden #include <sys/param.h>
 1.1  wrstuden #include <sys/systm.h>
 1.1  wrstuden #include <sys/kernel.h>
 1.1  wrstuden #include <sys/device.h>
 1.1  wrstuden #include <sys/queue.h>
 1.1  wrstuden #include <sys/proc.h>
 1.2  wrstuden #include <sys/bswap.h>
 1.1  wrstuden #include <sys/buf.h>
 1.1  wrstuden #include <sys/bufq.h>
 1.1  wrstuden #include <sys/endian.h>
 1.1  wrstuden #include <sys/malloc.h>
 1.1  wrstuden #include <sys/conf.h>
 1.1  wrstuden #include <sys/disk.h>
1.13      manu #include <sys/sysctl.h>
 1.1  wrstuden #include <sys/syslog.h>
1.13      manu #if 1
1.13      manu #include <sys/ktrace.h>
1.13      manu #endif
 1.1  wrstuden
 1.1  wrstuden #include <uvm/uvm_extern.h>
 1.1  wrstuden
 1.1  wrstuden #include <machine/bus.h>
 1.1  wrstuden
 1.1  wrstuden #include <dev/pci/pcireg.h>
 1.1  wrstuden #include <dev/pci/pcivar.h>
 1.1  wrstuden #include <dev/pci/pcidevs.h>
 1.1  wrstuden #include <dev/pci/twareg.h>
 1.1  wrstuden #include <dev/pci/twavar.h>
 1.1  wrstuden #include <dev/pci/twaio.h>
 1.1  wrstuden
 1.1  wrstuden #include <dev/scsipi/scsipi_all.h>
 1.1  wrstuden #include <dev/scsipi/scsipi_disk.h>
 1.1  wrstuden #include <dev/scsipi/scsipiconf.h>
 1.1  wrstuden #include <dev/scsipi/scsi_spc.h>
 1.1  wrstuden
 1.1  wrstuden #include <dev/ldvar.h>
 1.1  wrstuden
 1.1  wrstuden #include "locators.h"
 1.1  wrstuden
 1.1  wrstuden #define	PCI_CBIO	0x10
 1.1  wrstuden
 1.1  wrstuden static int	twa_fetch_aen(struct twa_softc *);
 1.1  wrstuden static void	twa_aen_callback(struct twa_request *);
 1.7    simonb static int	twa_find_aen(struct twa_softc *sc, uint16_t);
 1.1  wrstuden static uint16_t	twa_enqueue_aen(struct twa_softc *sc,
 1.1  wrstuden 			struct twa_command_header *);
 1.1  wrstuden
 1.1  wrstuden static void	twa_attach(struct device *, struct device *, void *);
 1.1  wrstuden static void	twa_shutdown(void *);
 1.7    simonb static int	twa_init_connection(struct twa_softc *, uint16_t, uint32_t,
 1.7    simonb 				    uint16_t, uint16_t, uint16_t, uint16_t, uint16_t *,
 1.7    simonb 					uint16_t *, uint16_t *, uint16_t *, uint32_t *);
 1.1  wrstuden static int	twa_intr(void *);
 1.1  wrstuden static int 	twa_match(struct device *, struct cfdata *, void *);
 1.1  wrstuden static int	twa_reset(struct twa_softc *);
 1.1  wrstuden
 1.1  wrstuden static int	twa_print(void *, const char *);
 1.1  wrstuden static int	twa_soft_reset(struct twa_softc *);
 1.1  wrstuden
 1.7    simonb static int	twa_check_ctlr_state(struct twa_softc *, uint32_t);
 1.1  wrstuden static int	twa_get_param(struct twa_softc *, int, int, size_t,
 1.1  wrstuden 				void (* callback)(struct twa_request *),
 1.1  wrstuden 				struct twa_param_9k **);
 1.1  wrstuden static int 	twa_set_param(struct twa_softc *, int, int, int, void *,
 1.1  wrstuden 				void (* callback)(struct twa_request *));
 1.1  wrstuden static void	twa_describe_controller(struct twa_softc *);
 1.7    simonb static int	twa_wait_status(struct twa_softc *, uint32_t, uint32_t);
 1.1  wrstuden static int	twa_done(struct twa_softc *);
 1.1  wrstuden #if 0
 1.1  wrstuden static int	twa_flash_firmware(struct twa_softc *sc);
 1.1  wrstuden static int	twa_hard_reset(struct twa_softc *sc);
 1.1  wrstuden #endif
 1.1  wrstuden
 1.1  wrstuden extern struct	cfdriver twa_cd;
 1.1  wrstuden extern uint32_t twa_fw_img_size;
 1.1  wrstuden extern uint8_t	twa_fw_img[];
 1.1  wrstuden
 1.1  wrstuden CFATTACH_DECL(twa, sizeof(struct twa_softc),
 1.1  wrstuden     twa_match, twa_attach, NULL, NULL);
 1.1  wrstuden
1.13      manu /* FreeBSD driver revision for sysctl expected by the 3ware cli */
1.13      manu const char twaver[] = "1.50.01.002";
1.13      manu
 1.1  wrstuden /* AEN messages. */
 1.1  wrstuden static const struct twa_message	twa_aen_table[] = {
 1.1  wrstuden 	{0x0000, "AEN queue empty"},
 1.1  wrstuden 	{0x0001, "Controller reset occurred"},
 1.1  wrstuden 	{0x0002, "Degraded unit detected"},
 1.1  wrstuden 	{0x0003, "Controller error occured"},
 1.1  wrstuden 	{0x0004, "Background rebuild failed"},
 1.1  wrstuden 	{0x0005, "Background rebuild done"},
 1.1  wrstuden 	{0x0006, "Incomplete unit detected"},
 1.1  wrstuden 	{0x0007, "Background initialize done"},
 1.1  wrstuden 	{0x0008, "Unclean shutdown detected"},
 1.1  wrstuden 	{0x0009, "Drive timeout detected"},
 1.1  wrstuden 	{0x000A, "Drive error detected"},
 1.1  wrstuden 	{0x000B, "Rebuild started"},
 1.1  wrstuden 	{0x000C, "Background initialize started"},
 1.1  wrstuden 	{0x000D, "Entire logical unit was deleted"},
 1.1  wrstuden 	{0x000E, "Background initialize failed"},
 1.1  wrstuden 	{0x000F, "SMART attribute exceeded threshold"},
 1.1  wrstuden 	{0x0010, "Power supply reported AC under range"},
 1.1  wrstuden 	{0x0011, "Power supply reported DC out of range"},
 1.1  wrstuden 	{0x0012, "Power supply reported a malfunction"},
 1.1  wrstuden 	{0x0013, "Power supply predicted malfunction"},
 1.1  wrstuden 	{0x0014, "Battery charge is below threshold"},
 1.1  wrstuden 	{0x0015, "Fan speed is below threshold"},
 1.1  wrstuden 	{0x0016, "Temperature sensor is above threshold"},
 1.1  wrstuden 	{0x0017, "Power supply was removed"},
 1.1  wrstuden 	{0x0018, "Power supply was inserted"},
 1.1  wrstuden 	{0x0019, "Drive was removed from a bay"},
 1.1  wrstuden 	{0x001A, "Drive was inserted into a bay"},
 1.1  wrstuden 	{0x001B, "Drive bay cover door was opened"},
 1.1  wrstuden 	{0x001C, "Drive bay cover door was closed"},
 1.1  wrstuden 	{0x001D, "Product case was opened"},
 1.1  wrstuden 	{0x0020, "Prepare for shutdown (power-off)"},
 1.1  wrstuden 	{0x0021, "Downgrade UDMA mode to lower speed"},
 1.1  wrstuden 	{0x0022, "Upgrade UDMA mode to higher speed"},
 1.1  wrstuden 	{0x0023, "Sector repair completed"},
 1.1  wrstuden 	{0x0024, "Sbuf memory test failed"},
 1.1  wrstuden 	{0x0025, "Error flushing cached write data to disk"},
 1.1  wrstuden 	{0x0026, "Drive reported data ECC error"},
 1.1  wrstuden 	{0x0027, "DCB has checksum error"},
 1.1  wrstuden 	{0x0028, "DCB version is unsupported"},
 1.1  wrstuden 	{0x0029, "Background verify started"},
 1.1  wrstuden 	{0x002A, "Background verify failed"},
 1.1  wrstuden 	{0x002B, "Background verify done"},
 1.1  wrstuden 	{0x002C, "Bad sector overwritten during rebuild"},
 1.1  wrstuden 	{0x002E, "Replace failed because replacement drive too small"},
 1.1  wrstuden 	{0x002F, "Verify failed because array was never initialized"},
 1.1  wrstuden 	{0x0030, "Unsupported ATA drive"},
 1.1  wrstuden 	{0x0031, "Synchronize host/controller time"},
 1.1  wrstuden 	{0x0032, "Spare capacity is inadequate for some units"},
 1.1  wrstuden 	{0x0033, "Background migration started"},
 1.1  wrstuden 	{0x0034, "Background migration failed"},
 1.1  wrstuden 	{0x0035, "Background migration done"},
 1.1  wrstuden 	{0x0036, "Verify detected and fixed data/parity mismatch"},
 1.1  wrstuden 	{0x0037, "SO-DIMM incompatible"},
 1.1  wrstuden 	{0x0038, "SO-DIMM not detected"},
 1.1  wrstuden 	{0x0039, "Corrected Sbuf ECC error"},
 1.1  wrstuden 	{0x003A, "Drive power on reset detected"},
 1.1  wrstuden 	{0x003B, "Background rebuild paused"},
 1.1  wrstuden 	{0x003C, "Background initialize paused"},
 1.1  wrstuden 	{0x003D, "Background verify paused"},
 1.1  wrstuden 	{0x003E, "Background migration paused"},
 1.1  wrstuden 	{0x003F, "Corrupt flash file system detected"},
 1.1  wrstuden 	{0x0040, "Flash file system repaired"},
 1.1  wrstuden 	{0x0041, "Unit number assignments were lost"},
 1.1  wrstuden 	{0x0042, "Error during read of primary DCB"},
 1.1  wrstuden 	{0x0043, "Latent error found in backup DCB"},
 1.1  wrstuden 	{0x0044, "Battery voltage is normal"},
 1.1  wrstuden 	{0x0045, "Battery voltage is low"},
 1.1  wrstuden 	{0x0046, "Battery voltage is high"},
 1.1  wrstuden 	{0x0047, "Battery voltage is too low"},
 1.1  wrstuden 	{0x0048, "Battery voltage is too high"},
 1.1  wrstuden 	{0x0049, "Battery temperature is normal"},
 1.1  wrstuden 	{0x004A, "Battery temperature is low"},
 1.1  wrstuden 	{0x004B, "Battery temperature is high"},
 1.1  wrstuden 	{0x004C, "Battery temperature is too low"},
 1.1  wrstuden 	{0x004D, "Battery temperature is too high"},
 1.1  wrstuden 	{0x004E, "Battery capacity test started"},
 1.1  wrstuden 	{0x004F, "Cache synchronization skipped"},
 1.1  wrstuden 	{0x0050, "Battery capacity test completed"},
 1.1  wrstuden 	{0x0051, "Battery health check started"},
 1.1  wrstuden 	{0x0052, "Battery health check completed"},
 1.1  wrstuden 	{0x0053, "Need to do a capacity test"},
 1.1  wrstuden 	{0x0054, "Charge termination voltage is at high level"},
 1.1  wrstuden 	{0x0055, "Battery charging started"},
 1.1  wrstuden 	{0x0056, "Battery charging completed"},
 1.1  wrstuden 	{0x0057, "Battery charging fault"},
 1.1  wrstuden 	{0x0058, "Battery capacity is below warning level"},
 1.1  wrstuden 	{0x0059, "Battery capacity is below error level"},
 1.1  wrstuden 	{0x005A, "Battery is present"},
 1.1  wrstuden 	{0x005B, "Battery is not present"},
 1.1  wrstuden 	{0x005C, "Battery is weak"},
 1.1  wrstuden 	{0x005D, "Battery health check failed"},
 1.1  wrstuden 	{0x005E, "Cache synchronized after power fail"},
 1.1  wrstuden 	{0x005F, "Cache synchronization failed; some data lost"},
 1.1  wrstuden 	{0x0060, "Bad cache meta data checksum"},
 1.1  wrstuden 	{0x0061, "Bad cache meta data signature"},
 1.1  wrstuden 	{0x0062, "Cache meta data restore failed"},
 1.1  wrstuden 	{0x0063, "BBU not found after power fail"},
 1.1  wrstuden 	{0x00FC, "Recovered/finished array membership update"},
 1.1  wrstuden 	{0x00FD, "Handler lockup"},
 1.1  wrstuden 	{0x00FE, "Retrying PCI transfer"},
 1.1  wrstuden 	{0x00FF, "AEN queue is full"},
 1.1  wrstuden 	{0xFFFFFFFF, (char *)NULL}
 1.1  wrstuden };
 1.1  wrstuden
 1.1  wrstuden /* AEN severity table. */
 1.1  wrstuden static const char	*twa_aen_severity_table[] = {
 1.1  wrstuden 	"None",
 1.1  wrstuden 	"ERROR",
 1.1  wrstuden 	"WARNING",
 1.1  wrstuden 	"INFO",
 1.1  wrstuden 	"DEBUG",
 1.1  wrstuden 	(char *)NULL
 1.1  wrstuden };
 1.1  wrstuden
 1.1  wrstuden /* Error messages. */
 1.1  wrstuden static const struct twa_message	twa_error_table[] = {
 1.1  wrstuden 	{0x0100, "SGL entry contains zero data"},
 1.1  wrstuden 	{0x0101, "Invalid command opcode"},
 1.1  wrstuden 	{0x0102, "SGL entry has unaligned address"},
 1.1  wrstuden 	{0x0103, "SGL size does not match command"},
 1.1  wrstuden 	{0x0104, "SGL entry has illegal length"},
 1.1  wrstuden 	{0x0105, "Command packet is not aligned"},
 1.1  wrstuden 	{0x0106, "Invalid request ID"},
 1.1  wrstuden 	{0x0107, "Duplicate request ID"},
 1.1  wrstuden 	{0x0108, "ID not locked"},
 1.1  wrstuden 	{0x0109, "LBA out of range"},
 1.1  wrstuden 	{0x010A, "Logical unit not supported"},
 1.1  wrstuden 	{0x010B, "Parameter table does not exist"},
 1.1  wrstuden 	{0x010C, "Parameter index does not exist"},
 1.1  wrstuden 	{0x010D, "Invalid field in CDB"},
 1.1  wrstuden 	{0x010E, "Specified port has invalid drive"},
 1.1  wrstuden 	{0x010F, "Parameter item size mismatch"},
 1.1  wrstuden 	{0x0110, "Failed memory allocation"},
 1.1  wrstuden 	{0x0111, "Memory request too large"},
 1.1  wrstuden 	{0x0112, "Out of memory segments"},
 1.1  wrstuden 	{0x0113, "Invalid address to deallocate"},
 1.1  wrstuden 	{0x0114, "Out of memory"},
 1.1  wrstuden 	{0x0115, "Out of heap"},
 1.1  wrstuden 	{0x0120, "Double degrade"},
 1.1  wrstuden 	{0x0121, "Drive not degraded"},
 1.1  wrstuden 	{0x0122, "Reconstruct error"},
 1.1  wrstuden 	{0x0123, "Replace not accepted"},
 1.1  wrstuden 	{0x0124, "Replace drive capacity too small"},
 1.1  wrstuden 	{0x0125, "Sector count not allowed"},
 1.1  wrstuden 	{0x0126, "No spares left"},
 1.1  wrstuden 	{0x0127, "Reconstruct error"},
 1.1  wrstuden 	{0x0128, "Unit is offline"},
 1.1  wrstuden 	{0x0129, "Cannot update status to DCB"},
 1.1  wrstuden 	{0x0130, "Invalid stripe handle"},
 1.1  wrstuden 	{0x0131, "Handle that was not locked"},
 1.1  wrstuden 	{0x0132, "Handle that was not empy"},
 1.1  wrstuden 	{0x0133, "Handle has different owner"},
 1.1  wrstuden 	{0x0140, "IPR has parent"},
 1.1  wrstuden 	{0x0150, "Illegal Pbuf address alignment"},
 1.1  wrstuden 	{0x0151, "Illegal Pbuf transfer length"},
 1.1  wrstuden 	{0x0152, "Illegal Sbuf address alignment"},
 1.1  wrstuden 	{0x0153, "Illegal Sbuf transfer length"},
 1.1  wrstuden 	{0x0160, "Command packet too large"},
 1.1  wrstuden 	{0x0161, "SGL exceeds maximum length"},
 1.1  wrstuden 	{0x0162, "SGL has too many entries"},
 1.1  wrstuden 	{0x0170, "Insufficient resources for rebuilder"},
 1.1  wrstuden 	{0x0171, "Verify error (data != parity)"},
 1.1  wrstuden 	{0x0180, "Requested segment not in directory of this DCB"},
 1.1  wrstuden 	{0x0181, "DCB segment has unsupported version"},
 1.1  wrstuden 	{0x0182, "DCB segment has checksum error"},
 1.1  wrstuden 	{0x0183, "DCB support (settings) segment invalid"},
 1.1  wrstuden 	{0x0184, "DCB UDB (unit descriptor block) segment invalid"},
 1.1  wrstuden 	{0x0185, "DCB GUID (globally unique identifier) segment invalid"},
 1.1  wrstuden 	{0x01A0, "Could not clear Sbuf"},
 1.1  wrstuden 	{0x01C0, "Flash identify failed"},
 1.1  wrstuden 	{0x01C1, "Flash out of bounds"},
 1.1  wrstuden 	{0x01C2, "Flash verify error"},
 1.1  wrstuden 	{0x01C3, "Flash file object not found"},
 1.1  wrstuden 	{0x01C4, "Flash file already present"},
 1.1  wrstuden 	{0x01C5, "Flash file system full"},
 1.1  wrstuden 	{0x01C6, "Flash file not present"},
 1.1  wrstuden 	{0x01C7, "Flash file size error"},
 1.1  wrstuden 	{0x01C8, "Bad flash file checksum"},
 1.1  wrstuden 	{0x01CA, "Corrupt flash file system detected"},
 1.1  wrstuden 	{0x01D0, "Invalid field in parameter list"},
 1.1  wrstuden 	{0x01D1, "Parameter list length error"},
 1.1  wrstuden 	{0x01D2, "Parameter item is not changeable"},
 1.1  wrstuden 	{0x01D3, "Parameter item is not saveable"},
 1.1  wrstuden 	{0x0200, "UDMA CRC error"},
 1.1  wrstuden 	{0x0201, "Internal CRC error"},
 1.1  wrstuden 	{0x0202, "Data ECC error"},
 1.1  wrstuden 	{0x0203, "ADP level 1 error"},
 1.1  wrstuden 	{0x0204, "Port timeout"},
 1.1  wrstuden 	{0x0205, "Drive power on reset"},
 1.1  wrstuden 	{0x0206, "ADP level 2 error"},
 1.1  wrstuden 	{0x0207, "Soft reset failed"},
 1.1  wrstuden 	{0x0208, "Drive not ready"},
 1.1  wrstuden 	{0x0209, "Unclassified port error"},
 1.1  wrstuden 	{0x020A, "Drive aborted command"},
 1.1  wrstuden 	{0x0210, "Internal CRC error"},
 1.1  wrstuden 	{0x0211, "Host PCI bus abort"},
 1.1  wrstuden 	{0x0212, "Host PCI parity error"},
 1.1  wrstuden 	{0x0213, "Port handler error"},
 1.1  wrstuden 	{0x0214, "Token interrupt count error"},
 1.1  wrstuden 	{0x0215, "Timeout waiting for PCI transfer"},
 1.1  wrstuden 	{0x0216, "Corrected buffer ECC"},
 1.1  wrstuden 	{0x0217, "Uncorrected buffer ECC"},
 1.1  wrstuden 	{0x0230, "Unsupported command during flash recovery"},
 1.1  wrstuden 	{0x0231, "Next image buffer expected"},
 1.1  wrstuden 	{0x0232, "Binary image architecture incompatible"},
 1.1  wrstuden 	{0x0233, "Binary image has no signature"},
 1.1  wrstuden 	{0x0234, "Binary image has bad checksum"},
 1.1  wrstuden 	{0x0235, "Image downloaded overflowed buffer"},
 1.1  wrstuden 	{0x0240, "I2C device not found"},
 1.1  wrstuden 	{0x0241, "I2C transaction aborted"},
 1.1  wrstuden 	{0x0242, "SO-DIMM parameter(s) incompatible using defaults"},
 1.1  wrstuden 	{0x0243, "SO-DIMM unsupported"},
 1.1  wrstuden 	{0x0248, "SPI transfer status error"},
 1.1  wrstuden 	{0x0249, "SPI transfer timeout error"},
 1.1  wrstuden 	{0x0250, "Invalid unit descriptor size in CreateUnit"},
 1.1  wrstuden 	{0x0251, "Unit descriptor size exceeds data buffer in CreateUnit"},
 1.1  wrstuden 	{0x0252, "Invalid value in CreateUnit descriptor"},
 1.1  wrstuden 	{0x0253, "Inadequate disk space to support descriptor in CreateUnit"},
 1.1  wrstuden 	{0x0254, "Unable to create data channel for this unit descriptor"},
 1.1  wrstuden 	{0x0255, "CreateUnit descriptor specifies a drive already in use"},
 1.1  wrstuden        {0x0256, "Unable to write configuration to all disks during CreateUnit"},
 1.1  wrstuden 	{0x0257, "CreateUnit does not support this descriptor version"},
 1.1  wrstuden 	{0x0258, "Invalid subunit for RAID 0 or 5 in CreateUnit"},
 1.1  wrstuden 	{0x0259, "Too many descriptors in CreateUnit"},
 1.1  wrstuden 	{0x025A, "Invalid configuration specified in CreateUnit descriptor"},
 1.1  wrstuden 	{0x025B, "Invalid LBA offset specified in CreateUnit descriptor"},
 1.1  wrstuden 	{0x025C, "Invalid stripelet size specified in CreateUnit descriptor"},
 1.1  wrstuden 	{0x0260, "SMART attribute exceeded threshold"},
 1.1  wrstuden 	{0xFFFFFFFF, (char *)NULL}
 1.1  wrstuden };
 1.1  wrstuden
 1.1  wrstuden struct twa_pci_identity {
 1.1  wrstuden 	uint32_t	vendor_id;
 1.1  wrstuden 	uint32_t	product_id;
 1.1  wrstuden 	const char	*name;
 1.1  wrstuden };
 1.1  wrstuden
 1.1  wrstuden static const struct twa_pci_identity pci_twa_products[] = {
 1.1  wrstuden 	{ PCI_VENDOR_3WARE,
 1.1  wrstuden 	  PCI_PRODUCT_3WARE_9000,
 1.1  wrstuden 	  "3ware 9000 series",
 1.1  wrstuden 	},
 1.1  wrstuden 	{ PCI_VENDOR_3WARE,
 1.1  wrstuden 	  PCI_PRODUCT_3WARE_9550,
 1.1  wrstuden 	  "3ware 9550SX series",
 1.1  wrstuden 	},
 1.1  wrstuden 	{ 0,
 1.1  wrstuden 	  0,
 1.1  wrstuden 	  NULL,
 1.1  wrstuden 	},
 1.1  wrstuden };
 1.1  wrstuden
 1.1  wrstuden
 1.1  wrstuden static inline void
 1.7    simonb twa_outl(struct twa_softc *sc, int off, uint32_t val)
 1.1  wrstuden {
 1.6    simonb
 1.1  wrstuden 	bus_space_write_4(sc->twa_bus_iot, sc->twa_bus_ioh, off, val);
 1.1  wrstuden 	bus_space_barrier(sc->twa_bus_iot, sc->twa_bus_ioh, off, 4,
 1.1  wrstuden 	    BUS_SPACE_BARRIER_WRITE);
 1.1  wrstuden }
 1.1  wrstuden
 1.7    simonb static inline uint32_t	twa_inl(struct twa_softc *sc, int off)
 1.1  wrstuden {
 1.6    simonb
 1.1  wrstuden 	bus_space_barrier(sc->twa_bus_iot, sc->twa_bus_ioh, off, 4,
 1.1  wrstuden 	    BUS_SPACE_BARRIER_WRITE | BUS_SPACE_BARRIER_READ);
 1.1  wrstuden 	return (bus_space_read_4(sc->twa_bus_iot, sc->twa_bus_ioh, off));
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden void
 1.1  wrstuden twa_request_wait_handler(struct twa_request *tr)
 1.1  wrstuden {
 1.6    simonb
 1.1  wrstuden 	wakeup(tr);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
1.16  christos twa_match(struct device *parent, struct cfdata *cfdata,
1.15  christos     void *aux)
 1.1  wrstuden {
 1.1  wrstuden 	int i;
 1.1  wrstuden 	struct pci_attach_args *pa = aux;
 1.1  wrstuden 	const struct twa_pci_identity *entry = 0;
 1.1  wrstuden
 1.1  wrstuden 	if (PCI_VENDOR(pa->pa_id) == PCI_VENDOR_3WARE) {
 1.1  wrstuden 		for (i = 0; (pci_twa_products[i].product_id); i++) {
 1.1  wrstuden 			entry = &pci_twa_products[i];
 1.1  wrstuden 			if (entry->product_id == PCI_PRODUCT(pa->pa_id)) {
 1.1  wrstuden 				aprint_normal("%s: (rev. 0x%02x)\n",
 1.1  wrstuden 				    entry->name, PCI_REVISION(pa->pa_class));
 1.1  wrstuden 				return (1);
 1.1  wrstuden 			}
 1.1  wrstuden 		}
 1.1  wrstuden 	}
 1.1  wrstuden 	return (0);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static const char *
 1.7    simonb twa_find_msg_string(const struct twa_message *table, uint16_t code)
 1.1  wrstuden {
 1.1  wrstuden 	int	i;
 1.1  wrstuden
 1.1  wrstuden 	for (i = 0; table[i].message != NULL; i++)
 1.1  wrstuden 		if (table[i].code == code)
 1.1  wrstuden 			return(table[i].message);
 1.1  wrstuden
 1.1  wrstuden 	return(table[i].message);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden void
 1.1  wrstuden twa_release_request(struct twa_request *tr)
 1.1  wrstuden {
 1.1  wrstuden 	int s;
 1.1  wrstuden 	struct twa_softc *sc;
 1.1  wrstuden
 1.1  wrstuden 	sc = tr->tr_sc;
 1.1  wrstuden
 1.1  wrstuden 	if ((tr->tr_flags & TWA_CMD_AEN) == 0) {
 1.1  wrstuden 		s = splbio();
 1.1  wrstuden 		TAILQ_INSERT_TAIL(&tr->tr_sc->twa_free, tr, tr_link);
 1.1  wrstuden 		splx(s);
 1.1  wrstuden 		if (__predict_false((tr->tr_sc->twa_sc_flags &
 1.1  wrstuden 		    TWA_STATE_REQUEST_WAIT) != 0)) {
 1.1  wrstuden 			tr->tr_sc->twa_sc_flags &= ~TWA_STATE_REQUEST_WAIT;
 1.1  wrstuden 			wakeup(&sc->twa_free);
 1.1  wrstuden 		}
 1.1  wrstuden 	} else
 1.1  wrstuden 		tr->tr_flags &= ~TWA_CMD_AEN_BUSY;
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static void
 1.1  wrstuden twa_unmap_request(struct twa_request *tr)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_softc	*sc = tr->tr_sc;
 1.7    simonb 	uint8_t			cmd_status;
 1.9    bouyer 	int s;
 1.1  wrstuden
 1.1  wrstuden 	/* If the command involved data, unmap that too. */
 1.1  wrstuden 	if (tr->tr_data != NULL) {
 1.1  wrstuden 		if (tr->tr_cmd_pkt_type & TWA_CMD_PKT_TYPE_9K)
 1.1  wrstuden 			cmd_status = tr->tr_command->command.cmd_pkt_9k.status;
 1.1  wrstuden 		else
 1.1  wrstuden 			cmd_status =
 1.1  wrstuden 			      tr->tr_command->command.cmd_pkt_7k.generic.status;
 1.1  wrstuden
 1.1  wrstuden 		if (tr->tr_flags & TWA_CMD_DATA_OUT) {
 1.1  wrstuden 			bus_dmamap_sync(tr->tr_sc->twa_dma_tag, tr->tr_dma_map,
 1.1  wrstuden 				0, tr->tr_length, BUS_DMASYNC_POSTREAD);
 1.1  wrstuden 			/*
 1.1  wrstuden 			 * If we are using a bounce buffer, and we are reading
 1.1  wrstuden 			 * data, copy the real data in.
 1.1  wrstuden 			 */
 1.1  wrstuden 			if (tr->tr_flags & TWA_CMD_DATA_COPY_NEEDED)
 1.1  wrstuden 				if (cmd_status == 0)
 1.1  wrstuden 					memcpy(tr->tr_real_data, tr->tr_data,
 1.1  wrstuden 						tr->tr_real_length);
 1.1  wrstuden 		}
 1.1  wrstuden 		if (tr->tr_flags & TWA_CMD_DATA_IN)
 1.1  wrstuden 			bus_dmamap_sync(tr->tr_sc->twa_dma_tag, tr->tr_dma_map,
 1.1  wrstuden 				0, tr->tr_length, BUS_DMASYNC_POSTWRITE);
 1.1  wrstuden
 1.1  wrstuden 		bus_dmamap_unload(sc->twa_dma_tag, tr->tr_dma_map);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	/* Free alignment buffer if it was used. */
 1.1  wrstuden 	if (tr->tr_flags & TWA_CMD_DATA_COPY_NEEDED) {
 1.9    bouyer 		s = splvm();
 1.1  wrstuden 		uvm_km_free(kmem_map, (vaddr_t)tr->tr_data,
 1.1  wrstuden 		    tr->tr_length, UVM_KMF_WIRED);
 1.9    bouyer 		splx(s);
 1.1  wrstuden 		tr->tr_data = tr->tr_real_data;
 1.1  wrstuden 		tr->tr_length = tr->tr_real_length;
 1.1  wrstuden 	}
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_wait_request
 1.1  wrstuden  * Description:		Sends down a firmware cmd, and waits for the completion,
 1.1  wrstuden  *			but NOT in a tight loop.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		tr	-- ptr to request pkt
 1.1  wrstuden  *			timeout -- max # of seconds to wait before giving up
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.7    simonb twa_wait_request(struct twa_request *tr, uint32_t timeout)
 1.1  wrstuden {
 1.1  wrstuden 	time_t	end_time;
 1.1  wrstuden 	struct timeval	t1;
 1.8  wrstuden 	int	s, rv;
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_flags |= TWA_CMD_SLEEP_ON_REQUEST;
 1.1  wrstuden 	tr->tr_callback = twa_request_wait_handler;
 1.1  wrstuden 	tr->tr_status = TWA_CMD_BUSY;
 1.1  wrstuden
 1.8  wrstuden 	rv = twa_map_request(tr);
 1.8  wrstuden
 1.8  wrstuden 	if (rv != 0)
 1.8  wrstuden 		return (rv);
 1.1  wrstuden
 1.1  wrstuden 	microtime(&t1);
 1.1  wrstuden 	end_time = t1.tv_usec +
 1.1  wrstuden 		(timeout * 1000 * 100);
 1.1  wrstuden
 1.1  wrstuden 	while (tr->tr_status != TWA_CMD_COMPLETE) {
 1.8  wrstuden 		rv = tr->tr_error;
 1.8  wrstuden 		if (rv != 0)
 1.8  wrstuden 			return(rv);
 1.8  wrstuden 		if ((rv = tsleep(tr, PRIBIO, "twawait", timeout * hz)) == 0)
 1.1  wrstuden 			break;
 1.8  wrstuden
 1.8  wrstuden 		if (rv == EWOULDBLOCK) {
 1.1  wrstuden 			/*
 1.1  wrstuden 			 * We will reset the controller only if the request has
 1.1  wrstuden 			 * already been submitted, so as to not lose the
 1.1  wrstuden 			 * request packet.  If a busy request timed out, the
 1.1  wrstuden 			 * reset will take care of freeing resources.  If a
 1.1  wrstuden 			 * pending request timed out, we will free resources
 1.1  wrstuden 			 * for that request, right here.  So, the caller is
 1.1  wrstuden 			 * expected to NOT cleanup when ETIMEDOUT is returned.
 1.1  wrstuden 			 */
 1.8  wrstuden 			if (tr->tr_status == TWA_CMD_BUSY)
 1.1  wrstuden 				twa_reset(tr->tr_sc);
 1.1  wrstuden 			else {
 1.1  wrstuden 				/* Request was never submitted.  Clean up. */
 1.1  wrstuden 				s = splbio();
 1.6    simonb 				TAILQ_REMOVE(&tr->tr_sc->twa_pending, tr,
 1.6    simonb 				    tr_link);
 1.1  wrstuden 				splx(s);
 1.1  wrstuden
 1.1  wrstuden 				twa_unmap_request(tr);
 1.1  wrstuden 				if (tr->tr_data)
 1.1  wrstuden 					free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden
 1.1  wrstuden 				twa_release_request(tr);
 1.1  wrstuden 			}
 1.1  wrstuden 			return(ETIMEDOUT);
 1.1  wrstuden 		}
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * Either the request got completed, or we were woken up by a
 1.8  wrstuden 		 * signal. Calculate the new timeout, in case it was the
 1.6    simonb 		 * latter.
 1.1  wrstuden 		 */
 1.1  wrstuden 		microtime(&t1);
 1.1  wrstuden
 1.1  wrstuden 		timeout = (end_time - t1.tv_usec) / (1000 * 100);
 1.1  wrstuden 	}
 1.8  wrstuden 	return(rv);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_immediate_request
 1.1  wrstuden  * Description:		Sends down a firmware cmd, and waits for the completion
 1.1  wrstuden  *			in a tight loop.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		tr	-- ptr to request pkt
 1.1  wrstuden  *			timeout -- max # of seconds to wait before giving up
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.7    simonb twa_immediate_request(struct twa_request *tr, uint32_t timeout)
 1.1  wrstuden {
 1.1  wrstuden 	struct timeval t1;
 1.8  wrstuden 	int	s = 0, rv = 0;
 1.1  wrstuden
 1.8  wrstuden 	rv = twa_map_request(tr);
 1.8  wrstuden
 1.8  wrstuden 	if (rv != 0)
 1.8  wrstuden 		return(rv);
 1.1  wrstuden
 1.1  wrstuden 	timeout = (timeout * 10000 * 10);
 1.1  wrstuden
 1.1  wrstuden 	microtime(&t1);
 1.1  wrstuden
 1.1  wrstuden 	timeout += t1.tv_usec;
 1.1  wrstuden
 1.1  wrstuden 	do {
 1.8  wrstuden 		rv = tr->tr_error;
 1.8  wrstuden 		if (rv != 0)
 1.8  wrstuden 			return(rv);
 1.8  wrstuden 		s = splbio();
 1.1  wrstuden 		twa_done(tr->tr_sc);
 1.8  wrstuden 		splx(s);
 1.8  wrstuden 		if (tr->tr_status == TWA_CMD_COMPLETE)
 1.8  wrstuden 			return(rv);
 1.1  wrstuden 		microtime(&t1);
 1.1  wrstuden 	} while (t1.tv_usec <= timeout);
 1.1  wrstuden
 1.1  wrstuden 	/*
 1.1  wrstuden 	 * We will reset the controller only if the request has
 1.1  wrstuden 	 * already been submitted, so as to not lose the
 1.1  wrstuden 	 * request packet.  If a busy request timed out, the
 1.1  wrstuden 	 * reset will take care of freeing resources.  If a
 1.1  wrstuden 	 * pending request timed out, we will free resources
 1.1  wrstuden 	 * for that request, right here.  So, the caller is
 1.1  wrstuden 	 * expected to NOT cleanup when ETIMEDOUT is returned.
 1.1  wrstuden 	 */
 1.8  wrstuden 	rv = ETIMEDOUT;
 1.8  wrstuden
 1.8  wrstuden 	if (tr->tr_status == TWA_CMD_BUSY)
 1.1  wrstuden 		twa_reset(tr->tr_sc);
 1.1  wrstuden 	else {
 1.1  wrstuden 		/* Request was never submitted.  Clean up. */
 1.1  wrstuden 		s = splbio();
 1.1  wrstuden 		TAILQ_REMOVE(&tr->tr_sc->twa_pending, tr, tr_link);
 1.1  wrstuden 		splx(s);
 1.1  wrstuden 		twa_unmap_request(tr);
 1.1  wrstuden 		if (tr->tr_data)
 1.1  wrstuden 			free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	}
 1.8  wrstuden 	return (rv);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_inquiry(struct twa_request *tr, int lunid)
 1.1  wrstuden {
 1.1  wrstuden 	int error;
 1.1  wrstuden 	struct twa_command_9k *tr_9k_cmd;
 1.1  wrstuden
 1.1  wrstuden 	if (tr->tr_data == NULL)
 1.1  wrstuden 		return (ENOMEM);
 1.1  wrstuden
 1.1  wrstuden 	memset(tr->tr_data, 0, TWA_SECTOR_SIZE);
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_length = TWA_SECTOR_SIZE;
 1.1  wrstuden 	tr->tr_cmd_pkt_type = TWA_CMD_PKT_TYPE_9K;
 1.1  wrstuden 	tr->tr_flags |= TWA_CMD_DATA_IN;
 1.1  wrstuden
 1.1  wrstuden 	tr_9k_cmd = &tr->tr_command->command.cmd_pkt_9k;
 1.1  wrstuden
 1.1  wrstuden 	tr_9k_cmd->command.opcode = TWA_OP_EXECUTE_SCSI_COMMAND;
 1.1  wrstuden 	tr_9k_cmd->unit = lunid;
 1.1  wrstuden 	tr_9k_cmd->request_id = tr->tr_request_id;
 1.1  wrstuden 	tr_9k_cmd->status = 0;
 1.1  wrstuden 	tr_9k_cmd->sgl_offset = 16;
 1.1  wrstuden 	tr_9k_cmd->sgl_entries = 1;
 1.1  wrstuden 	/* create the CDB here */
 1.1  wrstuden 	tr_9k_cmd->cdb[0] = INQUIRY;
 1.1  wrstuden 	tr_9k_cmd->cdb[1] = ((lunid << 5) & 0x0e);
 1.1  wrstuden 	tr_9k_cmd->cdb[4] = 255;
 1.1  wrstuden
 1.1  wrstuden 	/* XXXX setup page data no lun device
 1.1  wrstuden 	 * it seems 9000 series does not indicate
 1.1  wrstuden 	 * NOTPRESENT - need more investigation
 1.1  wrstuden 	 */
 1.1  wrstuden 	((struct scsipi_inquiry_data *)tr->tr_data)->device =
 1.1  wrstuden 		SID_QUAL_LU_NOTPRESENT;
 1.1  wrstuden
 1.1  wrstuden 	error = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden
 1.8  wrstuden 	if (error != 0)
 1.8  wrstuden 		return (error);
 1.8  wrstuden
 1.1  wrstuden 	if (((struct scsipi_inquiry_data *)tr->tr_data)->device ==
 1.1  wrstuden 		SID_QUAL_LU_NOTPRESENT)
 1.1  wrstuden 		error = 1;
 1.1  wrstuden
 1.1  wrstuden 	return (error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.6    simonb twa_print_inquiry_data(struct twa_softc *sc, struct scsipi_inquiry_data *scsipi)
 1.1  wrstuden {
 1.6    simonb
 1.1  wrstuden     printf("%s: %s\n", sc->twa_dv.dv_xname, scsipi->vendor);
 1.1  wrstuden
 1.1  wrstuden     return (1);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden
 1.1  wrstuden static uint64_t
 1.1  wrstuden twa_read_capacity(struct twa_request *tr, int lunid)
 1.1  wrstuden {
 1.1  wrstuden 	int error;
 1.1  wrstuden 	struct twa_command_9k *tr_9k_cmd;
 1.1  wrstuden 	uint64_t array_size = 0LL;
 1.1  wrstuden
 1.1  wrstuden 	if (tr->tr_data == NULL)
 1.1  wrstuden 		return (ENOMEM);
 1.1  wrstuden
 1.1  wrstuden 	memset(tr->tr_data, 0, TWA_SECTOR_SIZE);
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_length = TWA_SECTOR_SIZE;
 1.1  wrstuden 	tr->tr_cmd_pkt_type = TWA_CMD_PKT_TYPE_9K;
 1.1  wrstuden 	tr->tr_flags |= TWA_CMD_DATA_OUT;
 1.1  wrstuden
 1.1  wrstuden 	tr_9k_cmd = &tr->tr_command->command.cmd_pkt_9k;
 1.1  wrstuden
 1.1  wrstuden 	tr_9k_cmd->command.opcode = TWA_OP_EXECUTE_SCSI_COMMAND;
 1.1  wrstuden 	tr_9k_cmd->unit = lunid;
 1.1  wrstuden 	tr_9k_cmd->request_id = tr->tr_request_id;
 1.1  wrstuden 	tr_9k_cmd->status = 0;
 1.1  wrstuden 	tr_9k_cmd->sgl_offset = 16;
 1.1  wrstuden 	tr_9k_cmd->sgl_entries = 1;
 1.1  wrstuden 	/* create the CDB here */
 1.1  wrstuden 	tr_9k_cmd->cdb[0] = READ_CAPACITY_16;
 1.1  wrstuden 	tr_9k_cmd->cdb[1] = ((lunid << 5) & 0x0e) | SRC16_SERVICE_ACTION;
 1.1  wrstuden
 1.1  wrstuden 	error = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.8  wrstuden
 1.8  wrstuden 	if (error == 0) {
 1.1  wrstuden #if BYTE_ORDER == BIG_ENDIAN
 1.8  wrstuden 		array_size = bswap64(_8btol(
 1.8  wrstuden 		    ((struct scsipi_read_capacity_16_data *)tr->tr_data->addr) + 1);
 1.1  wrstuden #else
 1.8  wrstuden 		array_size = _8btol(((struct scsipi_read_capacity_16_data *)
 1.1  wrstuden 				tr->tr_data)->addr) + 1;
 1.1  wrstuden #endif
 1.8  wrstuden 	}
 1.1  wrstuden 	return (array_size);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_request_sense(struct twa_request *tr, int lunid)
 1.1  wrstuden {
 1.1  wrstuden 	int error = 1;
 1.1  wrstuden 	struct twa_command_9k *tr_9k_cmd;
 1.1  wrstuden
 1.1  wrstuden 	if (tr->tr_data == NULL)
 1.1  wrstuden 		return (error);
 1.1  wrstuden
 1.1  wrstuden 	memset(tr->tr_data, 0, TWA_SECTOR_SIZE);
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_length = TWA_SECTOR_SIZE;
 1.1  wrstuden 	tr->tr_cmd_pkt_type = TWA_CMD_PKT_TYPE_9K;
 1.1  wrstuden 	tr->tr_flags |= TWA_CMD_DATA_OUT;
 1.1  wrstuden
 1.1  wrstuden 	tr_9k_cmd = &tr->tr_command->command.cmd_pkt_9k;
 1.1  wrstuden
 1.1  wrstuden 	tr_9k_cmd->command.opcode = TWA_OP_EXECUTE_SCSI_COMMAND;
 1.1  wrstuden 	tr_9k_cmd->unit = lunid;
 1.1  wrstuden 	tr_9k_cmd->request_id = tr->tr_request_id;
 1.1  wrstuden 	tr_9k_cmd->status = 0;
 1.1  wrstuden 	tr_9k_cmd->sgl_offset = 16;
 1.1  wrstuden 	tr_9k_cmd->sgl_entries = 1;
 1.1  wrstuden 	/* create the CDB here */
 1.1  wrstuden 	tr_9k_cmd->cdb[0] = SCSI_REQUEST_SENSE;
 1.1  wrstuden 	tr_9k_cmd->cdb[1] = ((lunid << 5) & 0x0e);
 1.1  wrstuden 	tr_9k_cmd->cdb[4] = 255;
 1.1  wrstuden
 1.1  wrstuden 	/*XXX AEN notification called in interrupt context
 1.1  wrstuden 	 * so just queue the request. Return as quickly
 1.1  wrstuden 	 * as possible from interrupt
 1.1  wrstuden 	 */
 1.1  wrstuden 	if ((tr->tr_flags & TWA_CMD_AEN) != 0)
 1.1  wrstuden 		error = twa_map_request(tr);
 1.1  wrstuden  	else
 1.1  wrstuden 		error = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden
 1.1  wrstuden 	return (error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_alloc_req_pkts(struct twa_softc *sc, int num_reqs)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request	*tr;
 1.1  wrstuden 	struct twa_command_packet *tc;
 1.1  wrstuden 	bus_dma_segment_t	seg;
 1.1  wrstuden 	size_t max_segs, max_xfer;
 1.1  wrstuden 	int	i, rv, rseg, size;
 1.1  wrstuden
 1.1  wrstuden 	if ((sc->twa_req_buf = malloc(num_reqs * sizeof(struct twa_request),
 1.1  wrstuden 					M_DEVBUF, M_NOWAIT)) == NULL)
 1.1  wrstuden 		return(ENOMEM);
 1.1  wrstuden
 1.1  wrstuden 	size = num_reqs * sizeof(struct twa_command_packet);
 1.1  wrstuden
 1.1  wrstuden 	/* Allocate memory for cmd pkts. */
 1.1  wrstuden 	if ((rv = bus_dmamem_alloc(sc->twa_dma_tag,
 1.1  wrstuden 		size, PAGE_SIZE, 0, &seg,
 1.1  wrstuden 		1, &rseg, BUS_DMA_NOWAIT)) != 0){
 1.1  wrstuden 			aprint_error("%s: unable to allocate "
 1.1  wrstuden 				"command packets, rv = %d\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname, rv);
 1.1  wrstuden 			return (ENOMEM);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	if ((rv = bus_dmamem_map(sc->twa_dma_tag,
 1.1  wrstuden 		&seg, rseg, size, (caddr_t *)&sc->twa_cmds,
 1.1  wrstuden 		BUS_DMA_NOWAIT | BUS_DMA_COHERENT)) != 0) {
 1.1  wrstuden 			aprint_error("%s: unable to map commands, rv = %d\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname, rv);
 1.1  wrstuden 			return (1);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	if ((rv = bus_dmamap_create(sc->twa_dma_tag,
 1.1  wrstuden 		size, num_reqs, size,
 1.1  wrstuden 		0, BUS_DMA_NOWAIT, &sc->twa_cmd_map)) != 0) {
 1.1  wrstuden 			aprint_error("%s: unable to create command DMA map, "
 1.1  wrstuden 				"rv = %d\n", sc->twa_dv.dv_xname, rv);
 1.1  wrstuden 			return (ENOMEM);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	if ((rv = bus_dmamap_load(sc->twa_dma_tag, sc->twa_cmd_map,
 1.1  wrstuden 		sc->twa_cmds, size, NULL,
 1.1  wrstuden 		BUS_DMA_NOWAIT)) != 0) {
 1.1  wrstuden 			aprint_error("%s: unable to load command DMA map, "
 1.1  wrstuden 				"rv = %d\n", sc->twa_dv.dv_xname, rv);
 1.1  wrstuden 			return (1);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	if ((uintptr_t)sc->twa_cmds % TWA_ALIGNMENT) {
 1.1  wrstuden 		aprint_error("%s: DMA map memory not aligned on %d boundary\n",
 1.1  wrstuden 			sc->twa_dv.dv_xname, TWA_ALIGNMENT);
 1.1  wrstuden
 1.1  wrstuden 		return (1);
 1.1  wrstuden 	}
 1.1  wrstuden 	tc = sc->twa_cmd_pkt_buf = (struct twa_command_packet *)sc->twa_cmds;
 1.1  wrstuden 	sc->twa_cmd_pkt_phys = sc->twa_cmd_map->dm_segs[0].ds_addr;
 1.1  wrstuden
 1.1  wrstuden 	memset(sc->twa_req_buf, 0, num_reqs * sizeof(struct twa_request));
 1.1  wrstuden 	memset(sc->twa_cmd_pkt_buf, 0,
 1.1  wrstuden 		num_reqs * sizeof(struct twa_command_packet));
 1.1  wrstuden
 1.1  wrstuden 	sc->sc_twa_request = sc->twa_req_buf;
 1.1  wrstuden 	max_segs = twa_get_maxsegs();
 1.1  wrstuden 	max_xfer = twa_get_maxxfer(max_segs);
 1.1  wrstuden
 1.1  wrstuden 	for (i = 0; i < num_reqs; i++, tc++) {
 1.1  wrstuden 		tr = &(sc->twa_req_buf[i]);
 1.1  wrstuden 		tr->tr_command = tc;
 1.1  wrstuden 		tr->tr_cmd_phys = sc->twa_cmd_pkt_phys +
 1.1  wrstuden 				(i * sizeof(struct twa_command_packet));
 1.1  wrstuden 		tr->tr_request_id = i;
 1.1  wrstuden 		tr->tr_sc = sc;
 1.1  wrstuden
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * Create a map for data buffers.  maxsize (256 * 1024) used in
 1.1  wrstuden 		 * bus_dma_tag_create above should suffice the bounce page needs
 1.1  wrstuden 		 * for data buffers, since the max I/O size we support is 128KB.
 1.1  wrstuden 		 * If we supported I/O's bigger than 256KB, we would have to
 1.1  wrstuden 		 * create a second dma_tag, with the appropriate maxsize.
 1.1  wrstuden 		 */
 1.1  wrstuden 		if ((rv = bus_dmamap_create(sc->twa_dma_tag,
 1.1  wrstuden 			max_xfer, max_segs, 1, 0, BUS_DMA_NOWAIT,
 1.1  wrstuden 			&tr->tr_dma_map)) != 0) {
 1.1  wrstuden 				aprint_error("%s: unable to create command "
 1.1  wrstuden 					"DMA map, rv = %d\n",
 1.1  wrstuden 					sc->twa_dv.dv_xname, rv);
 1.1  wrstuden 				return (ENOMEM);
 1.1  wrstuden 		}
 1.1  wrstuden 		/* Insert request into the free queue. */
 1.1  wrstuden 		if (i != 0) {
 1.1  wrstuden 			sc->twa_lookup[i] = tr;
 1.1  wrstuden 			twa_release_request(tr);
 1.1  wrstuden 		} else
 1.1  wrstuden 			tr->tr_flags |= TWA_CMD_AEN;
 1.1  wrstuden 	}
 1.1  wrstuden 	return(0);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static void
 1.1  wrstuden twa_recompute_openings(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_drive *td;
 1.1  wrstuden 	int unit;
 1.1  wrstuden 	int openings;
 1.1  wrstuden
 1.1  wrstuden 	if (sc->sc_nunits != 0)
 1.1  wrstuden 		openings = ((TWA_Q_LENGTH / 2) / sc->sc_nunits);
 1.1  wrstuden 	else
 1.1  wrstuden 		openings = 0;
 1.1  wrstuden 	if (openings == sc->sc_openings)
 1.1  wrstuden 		return;
 1.1  wrstuden 	sc->sc_openings = openings;
 1.1  wrstuden
 1.1  wrstuden #ifdef TWA_DEBUG
 1.1  wrstuden 	printf("%s: %d array%s, %d openings per array\n",
1.10  christos 	    sc->twa_dv.dv_xname, sc->sc_nunits,
 1.1  wrstuden 	    sc->sc_nunits == 1 ? "" : "s", sc->sc_openings);
 1.1  wrstuden #endif
 1.1  wrstuden 	for (unit = 0; unit < TWA_MAX_UNITS; unit++) {
 1.1  wrstuden 		td = &sc->sc_units[unit];
 1.1  wrstuden 		if (td->td_dev != NULL)
 1.1  wrstuden 			(*td->td_callbacks->tcb_openings)(td->td_dev,
 1.1  wrstuden 				sc->sc_openings);
 1.1  wrstuden 	}
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_request_bus_scan(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_drive *td;
 1.1  wrstuden 	struct twa_request *tr;
 1.1  wrstuden 	struct twa_attach_args twaa;
 1.2  wrstuden 	int locs[TWACF_NLOCS];
 1.1  wrstuden 	int s, unit;
 1.1  wrstuden
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden 	for (unit = 0; unit < TWA_MAX_UNITS; unit++) {
 1.1  wrstuden
 1.1  wrstuden 		if ((tr = twa_get_request(sc, 0)) == NULL) {
 1.1  wrstuden 			splx(s);
 1.1  wrstuden 			return (EIO);
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden
 1.1  wrstuden 		tr->tr_data = malloc(TWA_SECTOR_SIZE, M_DEVBUF, M_NOWAIT);
 1.1  wrstuden
 1.1  wrstuden 		if (tr->tr_data == NULL) {
 1.1  wrstuden 			twa_release_request(tr);
 1.1  wrstuden 			splx(s);
 1.1  wrstuden 			return (ENOMEM);
 1.1  wrstuden 		}
 1.1  wrstuden 		td = &sc->sc_units[unit];
 1.1  wrstuden
 1.1  wrstuden 		if (twa_inquiry(tr, unit) == 0) {
 1.1  wrstuden 			if (td->td_dev == NULL) {
 1.1  wrstuden             			twa_print_inquiry_data(sc,
 1.1  wrstuden 				   ((struct scsipi_inquiry_data *)tr->tr_data));
 1.1  wrstuden
 1.1  wrstuden 				sc->sc_nunits++;
 1.1  wrstuden
 1.1  wrstuden 				sc->sc_units[unit].td_size =
 1.1  wrstuden 					twa_read_capacity(tr, unit);
 1.1  wrstuden
 1.1  wrstuden 				twaa.twaa_unit = unit;
 1.1  wrstuden
 1.1  wrstuden 				twa_recompute_openings(sc);
 1.1  wrstuden
 1.2  wrstuden 				locs[TWACF_UNIT] = unit;
 1.2  wrstuden
 1.1  wrstuden 				sc->sc_units[unit].td_dev =
 1.6    simonb 				    config_found_sm_loc(&sc->twa_dv, "twa",
 1.6    simonb 				    locs, &twaa, twa_print, config_stdsubmatch);
 1.1  wrstuden 			}
 1.1  wrstuden 		} else {
 1.1  wrstuden 			if (td->td_dev != NULL) {
 1.1  wrstuden 				sc->sc_nunits--;
 1.1  wrstuden
 1.1  wrstuden 				(void) config_detach(td->td_dev, DETACH_FORCE);
 1.1  wrstuden 				td->td_dev = NULL;
 1.1  wrstuden 				td->td_size = 0;
 1.1  wrstuden
 1.1  wrstuden 				twa_recompute_openings(sc);
 1.1  wrstuden 			}
 1.1  wrstuden 		}
 1.1  wrstuden 		free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	}
 1.1  wrstuden 	splx(s);
 1.1  wrstuden
 1.1  wrstuden 	return (0);
 1.1  wrstuden }
 1.1  wrstuden
 1.8  wrstuden
 1.8  wrstuden #ifdef	DIAGNOSTIC
 1.8  wrstuden static inline void
 1.8  wrstuden twa_check_busy_q(struct twa_request *tr)
 1.8  wrstuden {
 1.8  wrstuden 	struct twa_request *rq;
 1.8  wrstuden 	struct twa_softc *sc = tr->tr_sc;
 1.8  wrstuden
 1.8  wrstuden 	TAILQ_FOREACH(rq, &sc->twa_busy, tr_link) {
 1.8  wrstuden 		if (tr->tr_request_id == rq->tr_request_id) {
 1.8  wrstuden 			panic("cannot submit same request more than once");
 1.8  wrstuden 		} else if (tr->bp == rq->bp && tr->bp != 0) {
 1.8  wrstuden 			/* XXX A check for 0 for the buf ptr is needed to
 1.8  wrstuden 			 * guard against ioctl requests with a buf ptr of
 1.8  wrstuden 			 * 0 and also aen notifications. Looking for
 1.8  wrstuden 			 * external cmds only.
 1.8  wrstuden 			 */
 1.8  wrstuden 			panic("cannot submit same buf more than once");
 1.8  wrstuden 		} else {
 1.8  wrstuden 			/* Empty else statement */
 1.8  wrstuden 		}
 1.8  wrstuden 	}
 1.8  wrstuden }
 1.8  wrstuden #endif
 1.8  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_start(struct twa_request *tr)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_softc	*sc = tr->tr_sc;
 1.7    simonb 	uint32_t		status_reg;
 1.1  wrstuden 	int			s;
 1.1  wrstuden 	int			error;
 1.1  wrstuden
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden 	/* Check to see if we can post a command. */
 1.1  wrstuden 	status_reg = twa_inl(sc, TWA_STATUS_REGISTER_OFFSET);
 1.1  wrstuden 	if ((error = twa_check_ctlr_state(sc, status_reg)))
 1.1  wrstuden 		goto out;
 1.1  wrstuden
 1.1  wrstuden 	if (status_reg & TWA_STATUS_COMMAND_QUEUE_FULL) {
 1.1  wrstuden 			if (tr->tr_status != TWA_CMD_PENDING) {
 1.1  wrstuden 				tr->tr_status = TWA_CMD_PENDING;
 1.1  wrstuden 				TAILQ_INSERT_TAIL(&tr->tr_sc->twa_pending,
 1.1  wrstuden 					tr, tr_link);
 1.1  wrstuden 			}
 1.1  wrstuden 			twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 					TWA_CONTROL_UNMASK_COMMAND_INTERRUPT);
 1.1  wrstuden 			error = EBUSY;
 1.1  wrstuden 	} else {
 1.1  wrstuden 	   	bus_dmamap_sync(sc->twa_dma_tag, sc->twa_cmd_map,
 1.1  wrstuden 			(caddr_t)tr->tr_command - sc->twa_cmds,
 1.1  wrstuden 			sizeof(struct twa_command_packet),
 1.1  wrstuden 			BUS_DMASYNC_PREWRITE | BUS_DMASYNC_PREREAD);
 1.1  wrstuden
 1.1  wrstuden 		/* Cmd queue is not full.  Post the command. */
 1.1  wrstuden 		TWA_WRITE_COMMAND_QUEUE(sc, tr->tr_cmd_phys +
 1.1  wrstuden 			sizeof(struct twa_command_header));
 1.1  wrstuden
 1.1  wrstuden 		/* Mark the request as currently being processed. */
 1.1  wrstuden 		tr->tr_status = TWA_CMD_BUSY;
 1.8  wrstuden
 1.8  wrstuden #ifdef	DIAGNOSTIC
 1.8  wrstuden 		twa_check_busy_q(tr);
 1.8  wrstuden #endif
 1.8  wrstuden
 1.1  wrstuden 		/* Move the request into the busy queue. */
 1.1  wrstuden 		TAILQ_INSERT_TAIL(&tr->tr_sc->twa_busy, tr, tr_link);
 1.1  wrstuden 	}
 1.1  wrstuden out:
 1.1  wrstuden 	splx(s);
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_drain_response_queue(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	union twa_response_queue	rq;
 1.7    simonb 	uint32_t			status_reg;
 1.1  wrstuden
 1.1  wrstuden 	for (;;) {
 1.1  wrstuden 		status_reg = twa_inl(sc, TWA_STATUS_REGISTER_OFFSET);
 1.1  wrstuden 		if (twa_check_ctlr_state(sc, status_reg))
 1.1  wrstuden 			return(1);
 1.1  wrstuden 		if (status_reg & TWA_STATUS_RESPONSE_QUEUE_EMPTY)
 1.1  wrstuden 			return(0); /* no more response queue entries */
 1.6    simonb 		rq = (union twa_response_queue)twa_inl(sc,
 1.6    simonb 		    TWA_RESPONSE_QUEUE_OFFSET);
 1.1  wrstuden 	}
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static void
 1.1  wrstuden twa_drain_busy_queue(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request	*tr;
 1.1  wrstuden
 1.1  wrstuden 	/* Walk the busy queue. */
 1.1  wrstuden
 1.1  wrstuden 	while ((tr = TAILQ_FIRST(&sc->twa_busy)) != NULL) {
 1.1  wrstuden 		TAILQ_REMOVE(&sc->twa_busy, tr, tr_link);
 1.1  wrstuden
 1.1  wrstuden 		twa_unmap_request(tr);
 1.1  wrstuden 		if ((tr->tr_cmd_pkt_type & TWA_CMD_PKT_TYPE_INTERNAL) ||
 1.1  wrstuden 			(tr->tr_cmd_pkt_type & TWA_CMD_PKT_TYPE_IOCTL)) {
 1.1  wrstuden 			/* It's an internal/ioctl request.  Simply free it. */
 1.1  wrstuden 			if (tr->tr_data)
 1.1  wrstuden 				free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden 			twa_release_request(tr);
 1.1  wrstuden 		} else {
 1.1  wrstuden 			/* It's a SCSI request.  Complete it. */
 1.1  wrstuden 			tr->tr_command->command.cmd_pkt_9k.status = EIO;
 1.1  wrstuden 			if (tr->tr_callback)
 1.1  wrstuden 				tr->tr_callback(tr);
 1.1  wrstuden 		}
 1.1  wrstuden 	}
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_drain_pending_queue(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request	*tr;
 1.1  wrstuden 	int			s, error = 0;
 1.1  wrstuden
 1.1  wrstuden 	/*
 1.1  wrstuden 	 * Pull requests off the pending queue, and submit them.
 1.1  wrstuden 	 */
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden 	while ((tr = TAILQ_FIRST(&sc->twa_pending)) != NULL) {
 1.1  wrstuden 		TAILQ_REMOVE(&sc->twa_pending, tr, tr_link);
 1.1  wrstuden
 1.1  wrstuden 		if ((error = twa_start(tr))) {
 1.1  wrstuden 			if (error == EBUSY) {
 1.1  wrstuden 				tr->tr_status = TWA_CMD_PENDING;
 1.1  wrstuden
 1.1  wrstuden 				/* queue at the head */
 1.1  wrstuden 				TAILQ_INSERT_HEAD(&tr->tr_sc->twa_pending,
 1.1  wrstuden 					tr, tr_link);
 1.1  wrstuden 				error = 0;
 1.1  wrstuden 				break;
 1.1  wrstuden 			} else {
 1.1  wrstuden 				if (tr->tr_flags & TWA_CMD_SLEEP_ON_REQUEST) {
 1.1  wrstuden 					tr->tr_error = error;
 1.1  wrstuden 					tr->tr_callback(tr);
 1.1  wrstuden 					error = EIO;
 1.1  wrstuden 				}
 1.1  wrstuden 			}
 1.1  wrstuden 		}
 1.1  wrstuden 	}
 1.1  wrstuden 	splx(s);
 1.1  wrstuden
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_drain_aen_queue(struct twa_softc *sc)
 1.1  wrstuden {
 1.8  wrstuden 	int				s, error = 0;
 1.1  wrstuden 	struct twa_request		*tr;
 1.1  wrstuden 	struct twa_command_header	*cmd_hdr;
 1.1  wrstuden 	struct timeval	t1;
 1.7    simonb 	uint32_t		timeout;
 1.1  wrstuden
 1.1  wrstuden 	for (;;) {
 1.1  wrstuden 		if ((tr = twa_get_request(sc, 0)) == NULL) {
 1.1  wrstuden 			error = EIO;
 1.1  wrstuden 			break;
 1.1  wrstuden 		}
 1.1  wrstuden 		tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden 		tr->tr_callback = NULL;
 1.1  wrstuden
 1.1  wrstuden 		tr->tr_data = malloc(TWA_SECTOR_SIZE, M_DEVBUF, M_NOWAIT);
 1.1  wrstuden
 1.1  wrstuden 		if (tr->tr_data == NULL) {
 1.1  wrstuden 			error = 1;
 1.1  wrstuden 			goto out;
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		if (twa_request_sense(tr, 0) != 0) {
 1.1  wrstuden 			error = 1;
 1.1  wrstuden 			break;
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		timeout = (1000/*ms*/ * 100/*us*/ * TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden
 1.1  wrstuden 		microtime(&t1);
 1.1  wrstuden
 1.1  wrstuden 		timeout += t1.tv_usec;
 1.1  wrstuden
 1.1  wrstuden 		do {
 1.8  wrstuden 			s = splbio();
 1.1  wrstuden 			twa_done(tr->tr_sc);
 1.8  wrstuden 			splx(s);
 1.1  wrstuden 			if (tr->tr_status != TWA_CMD_BUSY)
 1.1  wrstuden 				break;
 1.1  wrstuden 			microtime(&t1);
 1.1  wrstuden 		} while (t1.tv_usec <= timeout);
 1.1  wrstuden
 1.1  wrstuden 		if (tr->tr_status != TWA_CMD_COMPLETE) {
 1.1  wrstuden 			error = ETIMEDOUT;
 1.1  wrstuden 			break;
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		if ((error = tr->tr_command->command.cmd_pkt_9k.status))
 1.1  wrstuden 			break;
 1.1  wrstuden
 1.1  wrstuden 		cmd_hdr = (struct twa_command_header *)(tr->tr_data);
 1.1  wrstuden 		if ((cmd_hdr->status_block.error) /* aen_code */
 1.1  wrstuden 				== TWA_AEN_QUEUE_EMPTY)
 1.1  wrstuden 			break;
 1.1  wrstuden 		(void)twa_enqueue_aen(sc, cmd_hdr);
 1.1  wrstuden
 1.1  wrstuden 		free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	}
 1.1  wrstuden out:
 1.1  wrstuden 	if (tr) {
 1.1  wrstuden 		if (tr->tr_data)
 1.1  wrstuden 			free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	}
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.8  wrstuden
 1.8  wrstuden #ifdef		DIAGNOSTIC
 1.8  wrstuden static void
 1.8  wrstuden twa_check_response_q(struct twa_request *tr, int clear)
 1.8  wrstuden {
 1.8  wrstuden 	int j;
 1.8  wrstuden 	static int i = 0;
 1.8  wrstuden 	static struct twa_request	*req = 0;
 1.8  wrstuden 	static struct buf		*hist[255];
 1.8  wrstuden
 1.8  wrstuden
 1.8  wrstuden 	if (clear) {
 1.8  wrstuden 		i = 0;
 1.8  wrstuden 		for (j = 0; j < 255; j++)
 1.8  wrstuden 			hist[j] = 0;
 1.8  wrstuden 		return;
 1.8  wrstuden 	}
 1.8  wrstuden
 1.8  wrstuden 	if (req == 0)
 1.8  wrstuden 		req = tr;
 1.8  wrstuden
 1.8  wrstuden 	if ((tr->tr_cmd_pkt_type & TWA_CMD_PKT_TYPE_EXTERNAL) != 0) {
 1.8  wrstuden 		if (req->tr_request_id == tr->tr_request_id)
 1.8  wrstuden 			panic("req id: %d on controller queue twice",
 1.8  wrstuden 		    	    tr->tr_request_id);
 1.8  wrstuden
 1.8  wrstuden 		for (j = 0; j < i; j++)
 1.8  wrstuden 			if (tr->bp == hist[j])
 1.8  wrstuden 				panic("req id: %d buf found twice",
 1.8  wrstuden 		    	    	    tr->tr_request_id);
 1.8  wrstuden 		}
 1.8  wrstuden 	req = tr;
 1.8  wrstuden
 1.8  wrstuden 	hist[i++] = req->bp;
 1.8  wrstuden }
 1.8  wrstuden #endif
 1.8  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_done(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	union twa_response_queue	rq;
 1.1  wrstuden 	struct twa_request		*tr;
 1.8  wrstuden 	int				rv = 0;
 1.7    simonb 	uint32_t			status_reg;
 1.1  wrstuden
 1.1  wrstuden 	for (;;) {
 1.1  wrstuden 		status_reg = twa_inl(sc, TWA_STATUS_REGISTER_OFFSET);
 1.8  wrstuden 		if ((rv = twa_check_ctlr_state(sc, status_reg)))
 1.1  wrstuden 			break;
 1.1  wrstuden 		if (status_reg & TWA_STATUS_RESPONSE_QUEUE_EMPTY)
 1.1  wrstuden 			break;
 1.1  wrstuden 		/* Response queue is not empty. */
 1.1  wrstuden 		rq = (union twa_response_queue)twa_inl(sc,
 1.1  wrstuden 			TWA_RESPONSE_QUEUE_OFFSET);
 1.1  wrstuden 		tr = sc->sc_twa_request + rq.u.response_id;
 1.8  wrstuden #ifdef		DIAGNOSTIC
 1.8  wrstuden 		twa_check_response_q(tr, 0);
 1.8  wrstuden #endif
 1.1  wrstuden 		/* Unmap the command packet, and any associated data buffer. */
 1.1  wrstuden 		twa_unmap_request(tr);
 1.8  wrstuden
 1.1  wrstuden 		tr->tr_status = TWA_CMD_COMPLETE;
 1.1  wrstuden 		TAILQ_REMOVE(&tr->tr_sc->twa_busy, tr, tr_link);
 1.1  wrstuden
 1.1  wrstuden 		if (tr->tr_callback)
 1.1  wrstuden 			tr->tr_callback(tr);
 1.1  wrstuden 	}
 1.1  wrstuden 	(void)twa_drain_pending_queue(sc);
 1.8  wrstuden
 1.8  wrstuden #ifdef		DIAGNOSTIC
 1.8  wrstuden 	twa_check_response_q(NULL, 1);
 1.8  wrstuden #endif
 1.8  wrstuden 	return(rv);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_init_ctlr
 1.1  wrstuden  * Description:		Establishes a logical connection with the controller.
 1.1  wrstuden  *			If bundled with firmware, determines whether or not
 1.1  wrstuden  *			to flash firmware, based on arch_id, fw SRL (Spec.
 1.1  wrstuden  *			Revision Level), branch & build #'s.  Also determines
 1.1  wrstuden  *			whether or not the driver is compatible with the
 1.1  wrstuden  *			firmware on the controller, before proceeding to work
 1.1  wrstuden  *			with it.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc	-- ptr to per ctlr structure
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.1  wrstuden twa_init_ctlr(struct twa_softc *sc)
 1.1  wrstuden {
 1.7    simonb 	uint16_t	fw_on_ctlr_srl = 0;
 1.7    simonb 	uint16_t	fw_on_ctlr_arch_id = 0;
 1.7    simonb 	uint16_t	fw_on_ctlr_branch = 0;
 1.7    simonb 	uint16_t	fw_on_ctlr_build = 0;
 1.7    simonb 	uint32_t	init_connect_result = 0;
 1.1  wrstuden 	int		error = 0;
 1.1  wrstuden #if 0
 1.1  wrstuden 	int8_t		fw_flashed = FALSE;
 1.1  wrstuden 	int8_t		fw_flash_failed = FALSE;
 1.1  wrstuden #endif
 1.1  wrstuden
 1.1  wrstuden 	/* Wait for the controller to become ready. */
 1.1  wrstuden 	if (twa_wait_status(sc, TWA_STATUS_MICROCONTROLLER_READY,
 1.1  wrstuden 					TWA_REQUEST_TIMEOUT_PERIOD)) {
 1.1  wrstuden 		return(ENXIO);
 1.1  wrstuden 	}
 1.1  wrstuden 	/* Drain the response queue. */
 1.1  wrstuden 	if (twa_drain_response_queue(sc))
 1.1  wrstuden 		return(1);
 1.1  wrstuden
 1.1  wrstuden 	/* Establish a logical connection with the controller. */
 1.1  wrstuden 	if ((error = twa_init_connection(sc, TWA_INIT_MESSAGE_CREDITS,
 1.1  wrstuden 			TWA_EXTENDED_INIT_CONNECT, TWA_CURRENT_FW_SRL,
 1.1  wrstuden 			TWA_9000_ARCH_ID, TWA_CURRENT_FW_BRANCH,
 1.1  wrstuden 			TWA_CURRENT_FW_BUILD, &fw_on_ctlr_srl,
 1.1  wrstuden 			&fw_on_ctlr_arch_id, &fw_on_ctlr_branch,
 1.1  wrstuden 			&fw_on_ctlr_build, &init_connect_result))) {
 1.1  wrstuden 		return(error);
 1.1  wrstuden 	}
 1.1  wrstuden #if 0
 1.1  wrstuden 	if ((init_connect_result & TWA_BUNDLED_FW_SAFE_TO_FLASH) &&
 1.1  wrstuden 		(init_connect_result & TWA_CTLR_FW_RECOMMENDS_FLASH)) {
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * The bundled firmware is safe to flash, and the firmware
 1.1  wrstuden 		 * on the controller recommends a flash.  So, flash!
 1.1  wrstuden 		 */
 1.6    simonb 		printf("%s: flashing bundled firmware...\n",
 1.6    simonb 		    sc->twa_dv.dv_xname);
 1.1  wrstuden
 1.1  wrstuden 		if ((error = twa_flash_firmware(sc))) {
 1.1  wrstuden 			fw_flash_failed = TRUE;
 1.1  wrstuden
 1.6    simonb 			printf("%s: unable to flash bundled firmware.\n",
 1.6    simonb 			    sc->twa_dv.dv_xname);
 1.1  wrstuden 		} else {
 1.1  wrstuden 			printf("%s: successfully flashed bundled firmware.\n",
 1.1  wrstuden 				 sc->twa_dv.dv_xname);
 1.1  wrstuden 			fw_flashed = TRUE;
 1.1  wrstuden 		}
 1.1  wrstuden 	}
 1.1  wrstuden 	if (fw_flashed) {
 1.1  wrstuden 		/* The firmware was flashed.  Have the new image loaded */
 1.1  wrstuden 		error = twa_hard_reset(sc);
 1.1  wrstuden 		if (error == 0)
 1.1  wrstuden 			error = twa_init_ctlr(sc);
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * If hard reset of controller failed, we need to return.
 1.1  wrstuden 		 * Otherwise, the above recursive call to twa_init_ctlr will
 1.1  wrstuden 		 * have completed the rest of the initialization (starting
 1.1  wrstuden 		 * from twa_drain_aen_queue below).  Don't do it again.
 1.1  wrstuden 		 * Just return.
 1.1  wrstuden 		 */
 1.1  wrstuden 		return(error);
 1.1  wrstuden 	} else {
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * Either we are not bundled with a firmware image, or
 1.1  wrstuden 		 * the bundled firmware is not safe to flash,
 1.1  wrstuden 		 * or flash failed for some reason.  See if we can at
 1.1  wrstuden 		 * least work with the firmware on the controller in the
 1.1  wrstuden 		 * current mode.
 1.1  wrstuden 		 */
 1.1  wrstuden 		if (init_connect_result & TWA_CTLR_FW_COMPATIBLE) {
 1.1  wrstuden 			/* Yes, we can.  Make note of the operating mode. */
 1.1  wrstuden 			sc->working_srl = TWA_CURRENT_FW_SRL;
 1.1  wrstuden 			sc->working_branch = TWA_CURRENT_FW_BRANCH;
 1.1  wrstuden 			sc->working_build = TWA_CURRENT_FW_BUILD;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			/*
 1.1  wrstuden 			 * No, we can't.  See if we can at least work with
 1.1  wrstuden 			 * it in the base mode.  We should never come here
 1.1  wrstuden 			 * if firmware has just been flashed.
 1.1  wrstuden 			 */
 1.6    simonb 			printf("%s: Driver/Firmware mismatch.  Negotiating "
 1.6    simonb 			    "for base level.\n", sc->twa_dv.dv_xname);
 1.6    simonb 			if ((error = twa_init_connection(sc,
 1.6    simonb 			    TWA_INIT_MESSAGE_CREDITS,
 1.6    simonb 			    TWA_EXTENDED_INIT_CONNECT, TWA_BASE_FW_SRL,
 1.6    simonb 			    TWA_9000_ARCH_ID, TWA_BASE_FW_BRANCH,
 1.6    simonb 			    TWA_BASE_FW_BUILD, &fw_on_ctlr_srl,
 1.6    simonb 			    &fw_on_ctlr_arch_id, &fw_on_ctlr_branch,
 1.6    simonb 			    &fw_on_ctlr_build, &init_connect_result))) {
 1.6    simonb 				printf("%s: can't initialize connection in "
 1.6    simonb 				    "base mode.\n", sc->twa_dv.dv_xname);
 1.1  wrstuden 				return(error);
 1.1  wrstuden 			}
 1.1  wrstuden 			if (!(init_connect_result & TWA_CTLR_FW_COMPATIBLE)) {
 1.1  wrstuden 				/*
 1.1  wrstuden 				 * The firmware on the controller is not even
 1.1  wrstuden 				 * compatible with our base mode.  We cannot
 1.1  wrstuden 				 * work with it.  Bail...
 1.1  wrstuden 				 */
 1.1  wrstuden 				printf("Incompatible firmware on controller\n");
 1.1  wrstuden #ifdef TWA_FLASH_FIRMWARE
 1.1  wrstuden 				if (fw_flash_failed)
 1.6    simonb 					printf("...and could not flash bundled "
 1.6    simonb 					    "firmware.\n");
 1.1  wrstuden 				else
 1.6    simonb 					printf("...and bundled firmware not "
 1.6    simonb 					    "safe to flash.\n");
 1.1  wrstuden #endif /* TWA_FLASH_FIRMWARE */
 1.1  wrstuden 				return(1);
 1.1  wrstuden 			}
 1.6    simonb 			/*
 1.6    simonb 			 * We can work with this firmware, but only in
 1.6    simonb 			 * base mode.
 1.6    simonb 			 */
 1.1  wrstuden 			sc->working_srl = TWA_BASE_FW_SRL;
 1.1  wrstuden 			sc->working_branch = TWA_BASE_FW_BRANCH;
 1.1  wrstuden 			sc->working_build = TWA_BASE_FW_BUILD;
 1.1  wrstuden 			sc->twa_operating_mode = TWA_BASE_MODE;
 1.1  wrstuden 		}
 1.1  wrstuden 	}
 1.1  wrstuden #endif
 1.1  wrstuden 	twa_drain_aen_queue(sc);
 1.1  wrstuden
 1.1  wrstuden 	/* Set controller state to initialized. */
 1.1  wrstuden 	sc->twa_state &= ~TWA_STATE_SHUTDOWN;
 1.1  wrstuden 	return(0);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_setup(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct tw_cl_event_packet *aen_queue;
 1.1  wrstuden 	uint32_t		i = 0;
 1.1  wrstuden 	int			error = 0;
 1.1  wrstuden
 1.1  wrstuden 	/* Initialize request queues. */
 1.1  wrstuden 	TAILQ_INIT(&sc->twa_free);
 1.1  wrstuden 	TAILQ_INIT(&sc->twa_busy);
 1.1  wrstuden 	TAILQ_INIT(&sc->twa_pending);
 1.1  wrstuden
 1.1  wrstuden 	sc->sc_nunits = 0;
 1.1  wrstuden 	sc->twa_sc_flags = 0;
 1.1  wrstuden
 1.1  wrstuden 	if (twa_alloc_req_pkts(sc, TWA_Q_LENGTH)) {
 1.1  wrstuden
 1.1  wrstuden 		return(ENOMEM);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	/* Allocate memory for the AEN queue. */
 1.6    simonb 	if ((aen_queue = malloc(sizeof(struct tw_cl_event_packet) *
 1.6    simonb 	    TWA_Q_LENGTH, M_DEVBUF, M_WAITOK)) == NULL) {
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * This should not cause us to return error.  We will only be
 1.1  wrstuden 		 * unable to support AEN's.  But then, we will have to check
 1.1  wrstuden 		 * time and again to see if we can support AEN's, if we
 1.1  wrstuden 		 * continue.  So, we will just return error.
 1.1  wrstuden 		 */
 1.1  wrstuden 		return (ENOMEM);
 1.1  wrstuden 	}
 1.1  wrstuden 	/* Initialize the aen queue. */
 1.1  wrstuden 	memset(aen_queue, 0, sizeof(struct tw_cl_event_packet) * TWA_Q_LENGTH);
 1.1  wrstuden
 1.1  wrstuden 	for (i = 0; i < TWA_Q_LENGTH; i++)
 1.1  wrstuden 		sc->twa_aen_queue[i] = &(aen_queue[i]);
 1.1  wrstuden
 1.1  wrstuden 	twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 		TWA_CONTROL_DISABLE_INTERRUPTS);
 1.1  wrstuden
 1.1  wrstuden 	/* Initialize the controller. */
 1.1  wrstuden 	if ((error = twa_init_ctlr(sc))) {
 1.1  wrstuden 		/* Soft reset the controller, and try one more time. */
 1.1  wrstuden
 1.6    simonb 		printf("%s: controller initialization failed. "
 1.6    simonb 		    "Retrying initialization\n", sc->twa_dv.dv_xname);
 1.1  wrstuden
 1.1  wrstuden 		if ((error = twa_soft_reset(sc)) == 0)
 1.1  wrstuden 			error = twa_init_ctlr(sc);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	twa_describe_controller(sc);
 1.1  wrstuden
 1.1  wrstuden 	error = twa_request_bus_scan(sc);
 1.1  wrstuden
 1.1  wrstuden 	twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 		TWA_CONTROL_CLEAR_ATTENTION_INTERRUPT |
 1.1  wrstuden 		TWA_CONTROL_UNMASK_RESPONSE_INTERRUPT |
 1.1  wrstuden 		TWA_CONTROL_ENABLE_INTERRUPTS);
 1.1  wrstuden
 1.1  wrstuden 	return (error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden void *twa_sdh;
 1.1  wrstuden
 1.1  wrstuden static void
1.16  christos twa_attach(struct device *parent, struct device *self, void *aux)
 1.1  wrstuden {
 1.1  wrstuden 	struct pci_attach_args *pa;
 1.1  wrstuden 	struct twa_softc *sc;
 1.1  wrstuden 	pci_chipset_tag_t pc;
 1.1  wrstuden 	pcireg_t csr;
 1.1  wrstuden 	pci_intr_handle_t ih;
 1.1  wrstuden 	const char *intrstr;
1.13      manu 	struct ctlname ctlnames[] = CTL_NAMES;
1.13      manu 	const struct sysctlnode *node;
1.13      manu 	int i;
 1.1  wrstuden
 1.1  wrstuden 	sc = (struct twa_softc *)self;
 1.1  wrstuden
 1.1  wrstuden 	pa = aux;
 1.1  wrstuden 	pc = pa->pa_pc;
 1.1  wrstuden 	sc->pc = pa->pa_pc;
 1.1  wrstuden 	sc->tag = pa->pa_tag;
 1.1  wrstuden 	sc->twa_dma_tag = pa->pa_dmat;
 1.1  wrstuden
 1.1  wrstuden 	aprint_naive(": RAID controller\n");
 1.1  wrstuden 	aprint_normal(": 3ware Apache\n");
 1.1  wrstuden
 1.1  wrstuden 	if (PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_3WARE_9000) {
 1.1  wrstuden 		if (pci_mapreg_map(pa, PCI_MAPREG_START, PCI_MAPREG_TYPE_IO, 0,
 1.1  wrstuden 	    	    &sc->twa_bus_iot, &sc->twa_bus_ioh, NULL, NULL)) {
 1.1  wrstuden 			aprint_error("%s: can't map i/o space\n",
 1.1  wrstuden 			    sc->twa_dv.dv_xname);
 1.1  wrstuden 			return;
 1.1  wrstuden 		}
 1.1  wrstuden 	} else if (PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_3WARE_9550) {
 1.1  wrstuden 		if (pci_mapreg_map(pa, PCI_MAPREG_START + 0x08,
 1.1  wrstuden 	    	    PCI_MAPREG_MEM_TYPE_64BIT, 0, &sc->twa_bus_iot,
 1.1  wrstuden 		    &sc->twa_bus_ioh, NULL, NULL)) {
 1.1  wrstuden 			aprint_error("%s: can't map mem space\n",
 1.1  wrstuden 			    sc->twa_dv.dv_xname);
 1.1  wrstuden 			return;
 1.1  wrstuden 		}
 1.1  wrstuden 	} else {
 1.1  wrstuden 		aprint_error("%s: product id 0x%02x not recognized\n",
 1.1  wrstuden 		    sc->twa_dv.dv_xname, PCI_PRODUCT(pa->pa_id));
 1.1  wrstuden 		return;
 1.1  wrstuden 	}
 1.1  wrstuden 	/* Enable the device. */
 1.1  wrstuden 	csr = pci_conf_read(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG);
 1.1  wrstuden
 1.1  wrstuden 	pci_conf_write(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG,
 1.1  wrstuden 	    csr | PCI_COMMAND_MASTER_ENABLE);
 1.1  wrstuden
 1.1  wrstuden 	/* Map and establish the interrupt. */
 1.1  wrstuden 	if (pci_intr_map(pa, &ih)) {
 1.1  wrstuden 		aprint_error("%s: can't map interrupt\n", sc->twa_dv.dv_xname);
 1.1  wrstuden 		return;
 1.1  wrstuden 	}
 1.1  wrstuden 	intrstr = pci_intr_string(pc, ih);
 1.1  wrstuden
 1.1  wrstuden 	sc->twa_ih = pci_intr_establish(pc, ih, IPL_BIO, twa_intr, sc);
 1.1  wrstuden 	if (sc->twa_ih == NULL) {
 1.1  wrstuden 		aprint_error("%s: can't establish interrupt%s%s\n",
 1.1  wrstuden 			sc->twa_dv.dv_xname,
 1.1  wrstuden 			(intrstr) ? " at " : "",
 1.1  wrstuden 			(intrstr) ? intrstr : "");
 1.1  wrstuden 		return;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	if (intrstr != NULL)
 1.1  wrstuden 		aprint_normal("%s: interrupting at %s\n",
 1.1  wrstuden 			sc->twa_dv.dv_xname, intrstr);
 1.1  wrstuden
 1.1  wrstuden 	twa_setup(sc);
 1.1  wrstuden
 1.1  wrstuden 	if (twa_sdh == NULL)
 1.1  wrstuden 		twa_sdh = shutdownhook_establish(twa_shutdown, NULL);
 1.1  wrstuden
1.13      manu 	/* sysctl set-up for 3ware cli */
1.13      manu 	if (sysctl_createv(NULL, 0, NULL, NULL,
1.13      manu 				CTLFLAG_PERMANENT, CTLTYPE_NODE, "hw",
1.13      manu 				NULL, NULL, 0, NULL, 0,
1.13      manu 				CTL_HW, CTL_EOL) != 0) {
1.13      manu 		printf("%s: could not create %s sysctl node\n",
1.13      manu 			sc->twa_dv.dv_xname, ctlnames[CTL_HW].ctl_name);
1.13      manu 		return;
1.13      manu 	}
1.13      manu 	if (sysctl_createv(NULL, 0, NULL, &node,
1.13      manu         			0, CTLTYPE_NODE, sc->twa_dv.dv_xname,
1.13      manu         			SYSCTL_DESCR("twa driver information"),
1.13      manu         			NULL, 0, NULL, 0,
1.13      manu 				CTL_HW, CTL_CREATE, CTL_EOL) != 0) {
1.13      manu                 printf("%s: could not create %s.%s sysctl node\n",
1.13      manu 			sc->twa_dv.dv_xname, ctlnames[CTL_HW].ctl_name,
1.13      manu 			sc->twa_dv.dv_xname);
1.13      manu 		return;
1.13      manu 	}
1.13      manu 	if ((i = sysctl_createv(NULL, 0, NULL, NULL,
1.13      manu         			0, CTLTYPE_STRING, "driver_version",
1.13      manu         			SYSCTL_DESCR("twa driver version"),
1.13      manu         			NULL, 0, &twaver, 0,
1.13      manu 				CTL_HW, node->sysctl_num, CTL_CREATE, CTL_EOL))
1.13      manu 				!= 0) {
1.13      manu                 printf("%s: could not create %s.%s.driver_version sysctl\n",
1.13      manu 			sc->twa_dv.dv_xname, ctlnames[CTL_HW].ctl_name,
1.13      manu 			sc->twa_dv.dv_xname);
1.13      manu 		return;
1.13      manu 	}
1.13      manu
 1.1  wrstuden 	return;
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static void
1.16  christos twa_shutdown(void *arg)
 1.1  wrstuden {
 1.1  wrstuden 	extern struct cfdriver twa_cd;
 1.1  wrstuden 	struct twa_softc *sc;
 1.1  wrstuden 	int i, rv, unit;
 1.1  wrstuden
 1.1  wrstuden 	for (i = 0; i < twa_cd.cd_ndevs; i++) {
 1.1  wrstuden 		if ((sc = device_lookup(&twa_cd, i)) == NULL)
 1.1  wrstuden 			continue;
 1.1  wrstuden
 1.1  wrstuden 		for (unit = 0; unit < TWA_MAX_UNITS; unit++)
 1.1  wrstuden 			if (sc->sc_units[unit].td_dev != NULL)
 1.1  wrstuden 				(void) config_detach(sc->sc_units[unit].td_dev,
 1.1  wrstuden 					DETACH_FORCE | DETACH_QUIET);
 1.1  wrstuden
 1.1  wrstuden 		twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 			TWA_CONTROL_DISABLE_INTERRUPTS);
 1.1  wrstuden
 1.1  wrstuden 		/* Let the controller know that we are going down. */
 1.1  wrstuden 		rv = twa_init_connection(sc, TWA_SHUTDOWN_MESSAGE_CREDITS,
 1.1  wrstuden 				0, 0, 0, 0, 0,
 1.1  wrstuden 				NULL, NULL, NULL, NULL, NULL);
 1.1  wrstuden 	}
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden void
 1.1  wrstuden twa_register_callbacks(struct twa_softc *sc, int unit,
 1.1  wrstuden     const struct twa_callbacks *tcb)
 1.1  wrstuden {
 1.1  wrstuden
 1.1  wrstuden 	sc->sc_units[unit].td_callbacks = tcb;
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Print autoconfiguration message for a sub-device
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.1  wrstuden twa_print(void *aux, const char *pnp)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_attach_args *twaa;
 1.1  wrstuden
 1.1  wrstuden 	twaa = aux;
 1.1  wrstuden
 1.1  wrstuden 	if (pnp !=NULL)
 1.1  wrstuden 		aprint_normal("block device at %s\n", pnp);
 1.1  wrstuden 	aprint_normal(" unit %d\n", twaa->twaa_unit);
 1.1  wrstuden 	return (UNCONF);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static void
 1.1  wrstuden twa_fillin_sgl(struct twa_sg *sgl, bus_dma_segment_t *segs, int nsegments)
 1.1  wrstuden {
 1.1  wrstuden 	int	i;
 1.1  wrstuden 	for (i = 0; i < nsegments; i++) {
 1.1  wrstuden 		sgl[i].address = segs[i].ds_addr;
 1.7    simonb 		sgl[i].length = (uint32_t)(segs[i].ds_len);
 1.1  wrstuden 	}
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_submit_io(struct twa_request *tr)
 1.1  wrstuden {
 1.1  wrstuden 	int	error;
 1.1  wrstuden
 1.1  wrstuden 	if ((error = twa_start(tr))) {
 1.1  wrstuden 		if (error == EBUSY)
 1.1  wrstuden 			error = 0; /* request is in the pending queue */
 1.1  wrstuden 		else {
 1.1  wrstuden 			tr->tr_error = error;
 1.1  wrstuden 		}
 1.1  wrstuden 	}
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_setup_data_dmamap
 1.1  wrstuden  * Description:		Callback of bus_dmamap_load for the buffer associated
 1.1  wrstuden  *			with data.  Updates the cmd pkt (size/sgl_entries
 1.1  wrstuden  *			fields, as applicable) to reflect the number of sg
 1.1  wrstuden  *			elements.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		arg	-- ptr to request pkt
 1.1  wrstuden  *			segs	-- ptr to a list of segment descriptors
 1.1  wrstuden  *			nsegments--# of segments
 1.1  wrstuden  *			error	-- 0 if no errors encountered before callback,
 1.1  wrstuden  *				   non-zero if errors were encountered
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	None
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.6    simonb twa_setup_data_dmamap(void *arg, bus_dma_segment_t *segs, int nsegments,
 1.6    simonb     int error)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request		*tr = (struct twa_request *)arg;
 1.1  wrstuden 	struct twa_command_packet	*cmdpkt = tr->tr_command;
 1.1  wrstuden 	struct twa_command_9k		*cmd9k;
 1.1  wrstuden 	union twa_command_7k		*cmd7k;
 1.7    simonb 	uint8_t				sgl_offset;
 1.1  wrstuden
 1.1  wrstuden 	if (error == EFBIG) {
 1.1  wrstuden 		tr->tr_error = error;
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	if (tr->tr_cmd_pkt_type & TWA_CMD_PKT_TYPE_9K) {
 1.1  wrstuden 		cmd9k = &(cmdpkt->command.cmd_pkt_9k);
 1.1  wrstuden 		twa_fillin_sgl(&(cmd9k->sg_list[0]), segs, nsegments);
 1.1  wrstuden 		cmd9k->sgl_entries += nsegments - 1;
 1.1  wrstuden 	} else {
 1.1  wrstuden 		/* It's a 7000 command packet. */
 1.1  wrstuden 		cmd7k = &(cmdpkt->command.cmd_pkt_7k);
 1.1  wrstuden 		if ((sgl_offset = cmdpkt->command.cmd_pkt_7k.generic.sgl_offset))
 1.1  wrstuden 			twa_fillin_sgl((struct twa_sg *)
 1.7    simonb 					(((uint32_t *)cmd7k) + sgl_offset),
 1.1  wrstuden 					segs, nsegments);
 1.1  wrstuden 		/* Modify the size field, based on sg address size. */
 1.1  wrstuden 		cmd7k->generic.size +=
 1.1  wrstuden 			((TWA_64BIT_ADDRESSES ? 3 : 2) * nsegments);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	if (tr->tr_flags & TWA_CMD_DATA_IN)
 1.1  wrstuden 		bus_dmamap_sync(tr->tr_sc->twa_dma_tag, tr->tr_dma_map, 0,
 1.1  wrstuden 			tr->tr_length, BUS_DMASYNC_PREREAD);
 1.1  wrstuden 	if (tr->tr_flags & TWA_CMD_DATA_OUT) {
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * If we're using an alignment buffer, and we're
 1.1  wrstuden 		 * writing data, copy the real data out.
 1.1  wrstuden 		 */
 1.1  wrstuden 		if (tr->tr_flags & TWA_CMD_DATA_COPY_NEEDED)
 1.1  wrstuden 			memcpy(tr->tr_data, tr->tr_real_data,
 1.1  wrstuden 				tr->tr_real_length);
 1.1  wrstuden 		bus_dmamap_sync(tr->tr_sc->twa_dma_tag, tr->tr_dma_map, 0,
 1.1  wrstuden 			tr->tr_length, BUS_DMASYNC_PREWRITE);
 1.1  wrstuden 	}
 1.1  wrstuden 	error = twa_submit_io(tr);
 1.1  wrstuden
 1.1  wrstuden out:
 1.1  wrstuden 	if (error) {
 1.1  wrstuden 		twa_unmap_request(tr);
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * If the caller had been returned EINPROGRESS, and he has
 1.1  wrstuden 		 * registered a callback for handling completion, the callback
 1.1  wrstuden 		 * will never get called because we were unable to submit the
 1.1  wrstuden 		 * request.  So, free up the request right here.
 1.1  wrstuden 		 */
 1.1  wrstuden 		if ((tr->tr_flags & TWA_CMD_IN_PROGRESS) && (tr->tr_callback))
 1.1  wrstuden 			twa_release_request(tr);
 1.1  wrstuden 	}
 1.1  wrstuden 	return (error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_map_request
 1.1  wrstuden  * Description:		Maps a cmd pkt and data associated with it, into
 1.1  wrstuden  *			DMA'able memory.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		tr	-- ptr to request pkt
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden int
 1.1  wrstuden twa_map_request(struct twa_request *tr)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_softc	*sc = tr->tr_sc;
 1.1  wrstuden 	int			 s, rv, error = 0;
 1.1  wrstuden
 1.1  wrstuden 	/* If the command involves data, map that too. */
 1.1  wrstuden 	if (tr->tr_data != NULL) {
 1.1  wrstuden
 1.1  wrstuden 		if (((u_long)tr->tr_data & (511)) != 0) {
 1.1  wrstuden 			tr->tr_flags |= TWA_CMD_DATA_COPY_NEEDED;
 1.1  wrstuden 			tr->tr_real_data = tr->tr_data;
 1.1  wrstuden 			tr->tr_real_length = tr->tr_length;
 1.1  wrstuden 			s = splvm();
 1.1  wrstuden 			tr->tr_data = (void *)uvm_km_alloc(kmem_map,
 1.1  wrstuden 			    tr->tr_length, 512, UVM_KMF_NOWAIT|UVM_KMF_WIRED);
 1.1  wrstuden 			splx(s);
 1.1  wrstuden
 1.1  wrstuden 			if (tr->tr_data == NULL) {
 1.1  wrstuden 				tr->tr_data = tr->tr_real_data;
 1.1  wrstuden 				tr->tr_length = tr->tr_real_length;
 1.1  wrstuden 				return(ENOMEM);
 1.1  wrstuden 			}
 1.1  wrstuden 			if ((tr->tr_flags & TWA_CMD_DATA_IN) != 0)
 1.1  wrstuden 				memcpy(tr->tr_data, tr->tr_real_data,
 1.1  wrstuden 					tr->tr_length);
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * Map the data buffer into bus space and build the S/G list.
 1.1  wrstuden 		 */
 1.1  wrstuden 		rv = bus_dmamap_load(sc->twa_dma_tag, tr->tr_dma_map,
 1.1  wrstuden 			tr->tr_data, tr->tr_length, NULL, BUS_DMA_NOWAIT |
 1.1  wrstuden 			BUS_DMA_STREAMING | (tr->tr_flags & TWA_CMD_DATA_OUT) ?
 1.1  wrstuden 			BUS_DMA_READ : BUS_DMA_WRITE);
 1.1  wrstuden
 1.1  wrstuden 		if (rv != 0) {
 1.1  wrstuden 			if ((tr->tr_flags & TWA_CMD_DATA_COPY_NEEDED) != 0) {
 1.1  wrstuden 				s = splvm();
 1.1  wrstuden 				uvm_km_free(kmem_map, (vaddr_t)tr->tr_data,
 1.1  wrstuden 				    tr->tr_length, UVM_KMF_WIRED);
 1.1  wrstuden 				splx(s);
 1.1  wrstuden 			}
 1.1  wrstuden 			return (rv);
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		if ((rv = twa_setup_data_dmamap(tr,
 1.1  wrstuden 				tr->tr_dma_map->dm_segs,
 1.1  wrstuden 				tr->tr_dma_map->dm_nsegs, error))) {
 1.1  wrstuden
 1.1  wrstuden 			if (tr->tr_flags & TWA_CMD_DATA_COPY_NEEDED) {
 1.9    bouyer 				s = splvm();
 1.1  wrstuden 				uvm_km_free(kmem_map, (vaddr_t)tr->tr_data,
 1.1  wrstuden 				    tr->tr_length, UVM_KMF_WIRED);
 1.9    bouyer 				splx(s);
 1.1  wrstuden 				tr->tr_data = tr->tr_real_data;
 1.1  wrstuden 				tr->tr_length = tr->tr_real_length;
 1.1  wrstuden 			}
 1.1  wrstuden 		} else
 1.1  wrstuden 			error = tr->tr_error;
 1.1  wrstuden
 1.1  wrstuden 	} else
 1.1  wrstuden 		if ((rv = twa_submit_io(tr)))
 1.1  wrstuden 			twa_unmap_request(tr);
 1.1  wrstuden
 1.1  wrstuden 	return (rv);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden #if 0
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_flash_firmware
 1.1  wrstuden  * Description:		Flashes bundled firmware image onto controller.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc	-- ptr to per ctlr structure
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.1  wrstuden twa_flash_firmware(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request			*tr;
 1.1  wrstuden 	struct twa_command_download_firmware	*cmd;
 1.1  wrstuden 	uint32_t				count;
 1.1  wrstuden 	uint32_t				fw_img_chunk_size;
 1.1  wrstuden 	uint32_t				this_chunk_size = 0;
 1.1  wrstuden 	uint32_t				remaining_img_size = 0;
 1.1  wrstuden 	int					s, error = 0;
 1.1  wrstuden 	int					i;
 1.1  wrstuden
 1.1  wrstuden 	if ((tr = twa_get_request(sc, 0)) == NULL) {
 1.1  wrstuden 		/* No free request packets available.  Can't proceed. */
 1.1  wrstuden 		error = EIO;
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	count = (twa_fw_img_size / 65536);
 1.1  wrstuden
 1.1  wrstuden 	count += ((twa_fw_img_size % 65536) != 0) ? 1 : 0;
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden 	/* Allocate sufficient memory to hold a chunk of the firmware image. */
 1.1  wrstuden 	fw_img_chunk_size = ((twa_fw_img_size / count) + 511) & ~511;
 1.1  wrstuden
 1.1  wrstuden 	s = splvm();
 1.1  wrstuden 	tr->tr_data = (void *)uvm_km_alloc(kmem_map, fw_img_chunk_size, 512,
 1.1  wrstuden 				UVM_KMF_WIRED);
 1.1  wrstuden 	splx(s);
 1.1  wrstuden
 1.1  wrstuden 	if (tr->tr_data == NULL) {
 1.1  wrstuden 		error = ENOMEM;
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	remaining_img_size = twa_fw_img_size;
 1.1  wrstuden 	cmd = &(tr->tr_command->command.cmd_pkt_7k.download_fw);
 1.1  wrstuden
 1.1  wrstuden 	for (i = 0; i < count; i++) {
 1.1  wrstuden 		/* Build a cmd pkt for downloading firmware. */
 1.1  wrstuden 		memset(tr->tr_command, 0, sizeof(struct twa_command_packet));
 1.1  wrstuden
 1.1  wrstuden 		tr->tr_command->cmd_hdr.header_desc.size_header = 128;
 1.1  wrstuden
 1.1  wrstuden 		cmd->opcode = TWA_OP_DOWNLOAD_FIRMWARE;
 1.6    simonb 		cmd->sgl_offset = 2;	/* offset in dwords, to the beginning
 1.6    simonb 					   of sg list */
 1.6    simonb 		cmd->size = 2;		/* this field will be updated at data
 1.6    simonb 					   map time */
 1.1  wrstuden 		cmd->request_id = tr->tr_request_id;
 1.1  wrstuden 		cmd->unit = 0;
 1.1  wrstuden 		cmd->status = 0;
 1.1  wrstuden 		cmd->flags = 0;
 1.1  wrstuden 		cmd->param = 8;	/* prom image */
 1.1  wrstuden
 1.1  wrstuden 		if (i != (count - 1))
 1.1  wrstuden 			this_chunk_size = fw_img_chunk_size;
 1.1  wrstuden 		else	 /* last chunk */
 1.1  wrstuden 			this_chunk_size = remaining_img_size;
 1.1  wrstuden
 1.1  wrstuden 		remaining_img_size -= this_chunk_size;
 1.1  wrstuden
1.14  jmcneill 		memset(tr->tr_data, 0, fw_img_chunk_size);
 1.1  wrstuden
 1.1  wrstuden 		memcpy(tr->tr_data, twa_fw_img + (i * fw_img_chunk_size),
 1.1  wrstuden 			this_chunk_size);
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * The next line will effect only the last chunk.
 1.1  wrstuden 		 */
 1.1  wrstuden 		tr->tr_length = (this_chunk_size + 511) & ~511;
 1.1  wrstuden
 1.1  wrstuden 		tr->tr_flags |= TWA_CMD_DATA_OUT;
 1.1  wrstuden
 1.1  wrstuden 		error = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden
 1.1  wrstuden 		if (error) {
 1.1  wrstuden 			if (error == ETIMEDOUT)
 1.6    simonb 				/* clean-up done by twa_immediate_request */
 1.6    simonb 				return(error);
 1.1  wrstuden 			break;
 1.1  wrstuden 		}
 1.1  wrstuden 		error = cmd->status;
 1.1  wrstuden
 1.1  wrstuden 		if (i != (count - 1)) {
 1.1  wrstuden
 1.6    simonb 			/*
 1.6    simonb 			 * XXX FreeBSD code doesn't check for no error condition
 1.1  wrstuden 			 * but based on observation, error seems to return 0
 1.1  wrstuden 			 */
 1.6    simonb 			if ((error =
 1.6    simonb 			    tr->tr_command->cmd_hdr.status_block.error) == 0) {
 1.1  wrstuden 				continue;
 1.6    simonb 			} else if ((error =
 1.6    simonb 			    tr->tr_command->cmd_hdr.status_block.error) ==
 1.6    simonb 			    TWA_ERROR_MORE_DATA) {
 1.1  wrstuden 				    continue;
 1.1  wrstuden 			} else {
 1.1  wrstuden 				twa_hard_reset(sc);
 1.1  wrstuden 				break;
 1.1  wrstuden 			}
 1.1  wrstuden 		} else	 /* last chunk */
 1.1  wrstuden 			if (error) {
 1.6    simonb 				printf("%s: firmware flash request failed. "
 1.6    simonb 				    "error = 0x%x\n", sc->twa_dv.dv_xname,
 1.6    simonb 				    error);
 1.1  wrstuden 				twa_hard_reset(sc);
 1.1  wrstuden 			}
 1.6    simonb 	}
 1.1  wrstuden
 1.1  wrstuden 	if (tr->tr_data) {
 1.1  wrstuden 		s = splvm();
 1.1  wrstuden 		uvm_km_free(kmem_map, (vaddr_t)tr->tr_data,
 1.1  wrstuden 			fw_img_chunk_size, UVM_KMF_WIRED);
 1.1  wrstuden 		splx(s);
 1.1  wrstuden 	}
 1.1  wrstuden out:
 1.1  wrstuden 	if (tr)
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_hard_reset
 1.1  wrstuden  * Description:		Hard reset the controller.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc	-- ptr to per ctlr structure
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.1  wrstuden twa_hard_reset(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request			*tr;
 1.1  wrstuden 	struct twa_command_reset_firmware	*cmd;
 1.1  wrstuden 	int					error;
 1.1  wrstuden
 1.1  wrstuden 	if ((tr = twa_get_request(sc, 0)) == NULL)
 1.1  wrstuden 		return(EIO);
 1.1  wrstuden 	tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden 	/* Build a cmd pkt for sending down the hard reset command. */
 1.1  wrstuden 	tr->tr_command->cmd_hdr.header_desc.size_header = 128;
 1.1  wrstuden
 1.1  wrstuden 	cmd = &(tr->tr_command->command.cmd_pkt_7k.reset_fw);
 1.1  wrstuden 	cmd->opcode = TWA_OP_RESET_FIRMWARE;
 1.1  wrstuden 	cmd->size = 2;	/* this field will be updated at data map time */
 1.1  wrstuden 	cmd->request_id = tr->tr_request_id;
 1.1  wrstuden 	cmd->unit = 0;
 1.1  wrstuden 	cmd->status = 0;
 1.1  wrstuden 	cmd->flags = 0;
 1.1  wrstuden 	cmd->param = 0;	/* don't reload FPGA logic */
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_data = NULL;
 1.1  wrstuden 	tr->tr_length = 0;
 1.1  wrstuden
 1.1  wrstuden 	error = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden 	if (error) {
 1.6    simonb 		printf("%s: hard reset request could not be posted. "
 1.6    simonb 		    "error = 0x%x\n", sc->twa_dv.dv_xname, error);
 1.1  wrstuden 		if (error == ETIMEDOUT)
 1.6    simonb 			/* clean-up done by twa_immediate_request */
 1.6    simonb 			return(error);
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden 	if ((error = cmd->status)) {
 1.1  wrstuden 		printf("%s: hard reset request failed. error = 0x%x\n",
 1.1  wrstuden 			sc->twa_dv.dv_xname, error);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden out:
 1.1  wrstuden 	if (tr)
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden #endif
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_intr
 1.1  wrstuden  * Description:		Interrupt handler.  Determines the kind of interrupt,
 1.1  wrstuden  *			and calls the appropriate handler.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc	-- ptr to per ctlr structure
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	None
 1.1  wrstuden  */
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_intr(void *arg)
 1.1  wrstuden {
 1.8  wrstuden 	int	caught, s, rv;
 1.1  wrstuden 	struct twa_softc *sc;
 1.7    simonb 	uint32_t	status_reg;
 1.1  wrstuden 	sc = (struct twa_softc *)arg;
 1.1  wrstuden
 1.1  wrstuden 	caught = 0;
 1.1  wrstuden 	/* Collect current interrupt status. */
 1.1  wrstuden 	status_reg = twa_inl(sc, TWA_STATUS_REGISTER_OFFSET);
 1.1  wrstuden 	if (twa_check_ctlr_state(sc, status_reg)) {
 1.1  wrstuden 		caught = 1;
 1.1  wrstuden 		goto bail;
 1.1  wrstuden 	}
 1.1  wrstuden 	/* Dispatch based on the kind of interrupt. */
 1.1  wrstuden 	if (status_reg & TWA_STATUS_HOST_INTERRUPT) {
 1.1  wrstuden 		twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 			TWA_CONTROL_CLEAR_HOST_INTERRUPT);
 1.1  wrstuden 		caught = 1;
 1.1  wrstuden 	}
 1.1  wrstuden 	if ((status_reg & TWA_STATUS_ATTENTION_INTERRUPT) != 0) {
 1.1  wrstuden 		twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 			TWA_CONTROL_CLEAR_ATTENTION_INTERRUPT);
 1.1  wrstuden 		rv = twa_fetch_aen(sc);
 1.1  wrstuden #ifdef DIAGNOSTIC
 1.1  wrstuden 		if (rv != 0)
 1.1  wrstuden 			printf("%s: unable to retrieve AEN (%d)\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname, rv);
 1.1  wrstuden #endif
 1.1  wrstuden 		caught = 1;
 1.1  wrstuden 	}
 1.1  wrstuden 	if (status_reg & TWA_STATUS_COMMAND_INTERRUPT) {
 1.1  wrstuden 		/* Start any requests that might be in the pending queue. */
 1.1  wrstuden 		twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 			TWA_CONTROL_MASK_COMMAND_INTERRUPT);
 1.1  wrstuden 		(void)twa_drain_pending_queue(sc);
 1.1  wrstuden 		caught = 1;
 1.1  wrstuden 	}
 1.1  wrstuden 	if (status_reg & TWA_STATUS_RESPONSE_INTERRUPT) {
 1.8  wrstuden 		s = splbio();
 1.1  wrstuden 		twa_done(sc);
 1.8  wrstuden 		splx(s);
 1.1  wrstuden 		caught = 1;
 1.1  wrstuden 	}
 1.1  wrstuden bail:
 1.1  wrstuden 	return (caught);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Accept an open operation on the control device.
 1.1  wrstuden  */
 1.2  wrstuden static int
1.16  christos twaopen(dev_t dev, int flag, int mode, struct lwp *l)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_softc *twa;
 1.1  wrstuden
 1.1  wrstuden 	if ((twa = device_lookup(&twa_cd, minor(dev))) == NULL)
 1.1  wrstuden 		return (ENXIO);
 1.1  wrstuden
 1.1  wrstuden 	twa->twa_sc_flags |= TWA_STATE_OPEN;
 1.1  wrstuden
 1.1  wrstuden 	return (0);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Accept the last close on the control device.
 1.1  wrstuden  */
 1.2  wrstuden static int
1.16  christos twaclose(dev_t dev, int flag, int mode,
1.16  christos     struct lwp *l)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_softc *twa;
 1.1  wrstuden
 1.1  wrstuden 	twa = device_lookup(&twa_cd, minor(dev));
 1.1  wrstuden 	twa->twa_sc_flags &= ~TWA_STATE_OPEN;
 1.1  wrstuden 	return (0);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twaioctl
 1.1  wrstuden  * Description:		ioctl handler.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc	-- ptr to per ctlr structure
 1.1  wrstuden  *			cmd	-- ioctl cmd
 1.1  wrstuden  *			buf	-- ptr to buffer in kernel memory, which is
 1.1  wrstuden  *				   a copy of the input buffer in user-space
 1.1  wrstuden  * Output:		buf	-- ptr to buffer in kernel memory, which will
 1.1  wrstuden  *				   be copied of the output buffer in user-space
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.2  wrstuden static int
1.16  christos twaioctl(dev_t dev, u_long cmd, caddr_t data, int flag,
1.16  christos     struct lwp *l)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_softc *sc;
 1.1  wrstuden 	struct twa_ioctl_9k	*user_buf = (struct twa_ioctl_9k *)data;
 1.1  wrstuden 	struct tw_cl_event_packet event_buf;
 1.1  wrstuden 	struct twa_request 	*tr = 0;
 1.1  wrstuden 	int32_t			event_index = 0;
 1.1  wrstuden 	int32_t			start_index;
 1.1  wrstuden 	int			s, error = 0;
 1.1  wrstuden
 1.1  wrstuden 	sc = device_lookup(&twa_cd, minor(dev));
 1.1  wrstuden
 1.1  wrstuden 	switch (cmd) {
 1.1  wrstuden 	case TW_OSL_IOCTL_FIRMWARE_PASS_THROUGH:
 1.1  wrstuden 	{
 1.1  wrstuden 		struct twa_command_packet	*cmdpkt;
 1.7    simonb 		uint32_t			data_buf_size_adjusted;
 1.1  wrstuden
 1.1  wrstuden 		/* Get a request packet */
 1.1  wrstuden 		tr = twa_get_request_wait(sc, 0);
 1.1  wrstuden 		KASSERT(tr != NULL);
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * Make sure that the data buffer sent to firmware is a
 1.1  wrstuden 		 * 512 byte multiple in size.
 1.1  wrstuden 		 */
 1.1  wrstuden 		data_buf_size_adjusted =
 1.1  wrstuden 			(user_buf->twa_drvr_pkt.buffer_length + 511) & ~511;
 1.1  wrstuden
 1.1  wrstuden 		if ((tr->tr_length = data_buf_size_adjusted)) {
 1.1  wrstuden 			if ((tr->tr_data = malloc(data_buf_size_adjusted,
 1.1  wrstuden 			    M_DEVBUF, M_WAITOK)) == NULL) {
 1.1  wrstuden 				error = ENOMEM;
 1.1  wrstuden 				goto fw_passthru_done;
 1.1  wrstuden 			}
 1.1  wrstuden 			/* Copy the payload. */
 1.1  wrstuden 			if ((error = copyin((void *) (user_buf->pdata),
 1.1  wrstuden 				(void *) (tr->tr_data),
 1.1  wrstuden 				user_buf->twa_drvr_pkt.buffer_length)) != 0) {
 1.1  wrstuden 					goto fw_passthru_done;
 1.1  wrstuden 			}
 1.1  wrstuden 			tr->tr_flags |= TWA_CMD_DATA_IN | TWA_CMD_DATA_OUT;
 1.1  wrstuden 		}
 1.1  wrstuden 		tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_IOCTL;
 1.1  wrstuden 		cmdpkt = tr->tr_command;
 1.1  wrstuden
 1.1  wrstuden 		/* Copy the command packet. */
 1.1  wrstuden 		memcpy(cmdpkt, &(user_buf->twa_cmd_pkt),
 1.1  wrstuden 			sizeof(struct twa_command_packet));
 1.1  wrstuden 		cmdpkt->command.cmd_pkt_7k.generic.request_id =
 1.1  wrstuden 			tr->tr_request_id;
 1.1  wrstuden
 1.1  wrstuden 		/* Send down the request, and wait for it to complete. */
 1.1  wrstuden 		if ((error = twa_wait_request(tr, TWA_REQUEST_TIMEOUT_PERIOD))) 		{
 1.1  wrstuden 			if (error == ETIMEDOUT)
 1.1  wrstuden 				break; /* clean-up done by twa_wait_request */
 1.1  wrstuden 			goto fw_passthru_done;
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		/* Copy the command packet back into user space. */
 1.1  wrstuden 		memcpy(&user_buf->twa_cmd_pkt, cmdpkt,
 1.1  wrstuden 			sizeof(struct twa_command_packet));
 1.1  wrstuden
 1.1  wrstuden 		/* If there was a payload, copy it back too. */
 1.1  wrstuden 		if (tr->tr_length)
 1.1  wrstuden 			error = copyout(tr->tr_data, user_buf->pdata,
 1.1  wrstuden 					user_buf->twa_drvr_pkt.buffer_length);
 1.1  wrstuden fw_passthru_done:
 1.1  wrstuden 		/* Free resources. */
 1.1  wrstuden 		if (tr->tr_data)
 1.1  wrstuden 			free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden
 1.1  wrstuden 		if (tr)
 1.1  wrstuden 			twa_release_request(tr);
 1.1  wrstuden 		break;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	case TW_OSL_IOCTL_SCAN_BUS:
 1.1  wrstuden 		twa_request_bus_scan(sc);
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	case TW_CL_IOCTL_GET_FIRST_EVENT:
 1.1  wrstuden 		if (sc->twa_aen_queue_wrapped) {
 1.1  wrstuden 			if (sc->twa_aen_queue_overflow) {
 1.1  wrstuden 				/*
 1.1  wrstuden 				 * The aen queue has wrapped, even before some
 1.1  wrstuden 				 * events have been retrieved.  Let the caller
 1.1  wrstuden 				 * know that he missed out on some AEN's.
 1.1  wrstuden 				 */
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_OVERFLOW;
 1.1  wrstuden 				sc->twa_aen_queue_overflow = FALSE;
 1.1  wrstuden 			} else
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 			event_index = sc->twa_aen_head;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			if (sc->twa_aen_head == sc->twa_aen_tail) {
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_NO_EVENTS;
 1.1  wrstuden 				break;
 1.1  wrstuden 			}
 1.1  wrstuden 			user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 			event_index = sc->twa_aen_tail;	/* = 0 */
 1.1  wrstuden 		}
 1.1  wrstuden 		if ((error = copyout(sc->twa_aen_queue[event_index],
 1.6    simonb 		    user_buf->pdata, sizeof(struct tw_cl_event_packet))) != 0)
 1.6    simonb 			(sc->twa_aen_queue[event_index])->retrieved =
 1.6    simonb 			    TWA_AEN_RETRIEVED;
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	case TW_CL_IOCTL_GET_LAST_EVENT:
 1.1  wrstuden 		if (sc->twa_aen_queue_wrapped) {
 1.1  wrstuden 			if (sc->twa_aen_queue_overflow) {
 1.1  wrstuden 				/*
 1.1  wrstuden 				 * The aen queue has wrapped, even before some
 1.1  wrstuden 				 * events have been retrieved.  Let the caller
 1.1  wrstuden 				 * know that he missed out on some AEN's.
 1.1  wrstuden 				 */
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_OVERFLOW;
 1.1  wrstuden 				sc->twa_aen_queue_overflow = FALSE;
 1.1  wrstuden 			} else
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			if (sc->twa_aen_head == sc->twa_aen_tail) {
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_NO_EVENTS;
 1.1  wrstuden 				break;
 1.1  wrstuden 			}
 1.1  wrstuden 			user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 		}
 1.6    simonb 		event_index =
 1.6    simonb 		    (sc->twa_aen_head - 1 + TWA_Q_LENGTH) % TWA_Q_LENGTH;
 1.6    simonb 		if ((error = copyout(sc->twa_aen_queue[event_index],
 1.6    simonb 		    user_buf->pdata, sizeof(struct tw_cl_event_packet))) != 0)
 1.6    simonb 			(sc->twa_aen_queue[event_index])->retrieved =
 1.6    simonb 			    TWA_AEN_RETRIEVED;
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	case TW_CL_IOCTL_GET_NEXT_EVENT:
 1.1  wrstuden 		user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 		if (sc->twa_aen_queue_wrapped) {
 1.1  wrstuden
 1.1  wrstuden 			if (sc->twa_aen_queue_overflow) {
 1.1  wrstuden 				/*
 1.1  wrstuden 				 * The aen queue has wrapped, even before some
 1.1  wrstuden 				 * events have been retrieved.  Let the caller
 1.1  wrstuden 				 * know that he missed out on some AEN's.
 1.1  wrstuden 				 */
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_OVERFLOW;
 1.1  wrstuden 				sc->twa_aen_queue_overflow = FALSE;
 1.1  wrstuden 			}
 1.1  wrstuden 			start_index = sc->twa_aen_head;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			if (sc->twa_aen_head == sc->twa_aen_tail) {
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_NO_EVENTS;
 1.1  wrstuden 				break;
 1.1  wrstuden 			}
 1.1  wrstuden 			start_index = sc->twa_aen_tail;	/* = 0 */
 1.1  wrstuden 		}
 1.1  wrstuden 		error = copyin(user_buf->pdata, &event_buf,
 1.1  wrstuden 				sizeof(struct tw_cl_event_packet));
 1.1  wrstuden
 1.1  wrstuden 		event_index = (start_index + event_buf.sequence_id -
 1.6    simonb 		    (sc->twa_aen_queue[start_index])->sequence_id + 1)
 1.6    simonb 		    % TWA_Q_LENGTH;
 1.1  wrstuden
 1.6    simonb 		if (!((sc->twa_aen_queue[event_index])->sequence_id >
 1.6    simonb 		    event_buf.sequence_id)) {
 1.6    simonb 			if (user_buf->twa_drvr_pkt.status ==
 1.6    simonb 			    TWA_ERROR_AEN_OVERFLOW)
 1.6    simonb 				/* so we report the overflow next time */
 1.6    simonb 				sc->twa_aen_queue_overflow = TRUE;
 1.6    simonb 			user_buf->twa_drvr_pkt.status = TWA_ERROR_AEN_NO_EVENTS;
 1.1  wrstuden 			break;
 1.1  wrstuden 		}
 1.6    simonb 		if ((error = copyout(sc->twa_aen_queue[event_index],
 1.6    simonb 		    user_buf->pdata, sizeof(struct tw_cl_event_packet))) != 0)
 1.6    simonb 			(sc->twa_aen_queue[event_index])->retrieved =
 1.6    simonb 			    TWA_AEN_RETRIEVED;
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	case TW_CL_IOCTL_GET_PREVIOUS_EVENT:
 1.1  wrstuden 		user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 		if (sc->twa_aen_queue_wrapped) {
 1.1  wrstuden 			if (sc->twa_aen_queue_overflow) {
 1.1  wrstuden 				/*
 1.1  wrstuden 				 * The aen queue has wrapped, even before some
 1.1  wrstuden 				 * events have been retrieved.  Let the caller
 1.1  wrstuden 				 * know that he missed out on some AEN's.
 1.1  wrstuden 				 */
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_OVERFLOW;
 1.1  wrstuden 				sc->twa_aen_queue_overflow = FALSE;
 1.1  wrstuden 			}
 1.1  wrstuden 			start_index = sc->twa_aen_head;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			if (sc->twa_aen_head == sc->twa_aen_tail) {
 1.1  wrstuden 				user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_AEN_NO_EVENTS;
 1.1  wrstuden 				break;
 1.1  wrstuden 			}
 1.1  wrstuden 			start_index = sc->twa_aen_tail;	/* = 0 */
 1.1  wrstuden 		}
 1.1  wrstuden 		if ((error = copyin(user_buf->pdata, &event_buf,
 1.1  wrstuden 				sizeof(struct tw_cl_event_packet))) != 0)
 1.1  wrstuden
 1.1  wrstuden 		event_index = (start_index + event_buf.sequence_id -
 1.6    simonb 		    (sc->twa_aen_queue[start_index])->sequence_id - 1)
 1.6    simonb 		    % TWA_Q_LENGTH;
 1.6    simonb 		if (!((sc->twa_aen_queue[event_index])->sequence_id <
 1.6    simonb 		    event_buf.sequence_id)) {
 1.6    simonb 			if (user_buf->twa_drvr_pkt.status ==
 1.6    simonb 			    TWA_ERROR_AEN_OVERFLOW)
 1.6    simonb 				/* so we report the overflow next time */
 1.6    simonb 				sc->twa_aen_queue_overflow = TRUE;
 1.1  wrstuden 			user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 				TWA_ERROR_AEN_NO_EVENTS;
 1.1  wrstuden 			break;
 1.1  wrstuden 		}
 1.6    simonb 		if ((error = copyout(sc->twa_aen_queue [event_index],
 1.6    simonb 		    user_buf->pdata, sizeof(struct tw_cl_event_packet))) != 0)
 1.6    simonb 			aprint_error("%s: get_previous: Could not copyout to "
 1.6    simonb 			    "event_buf. error = %x\n", sc->twa_dv.dv_xname,
 1.6    simonb 			    error);
 1.1  wrstuden 		(sc->twa_aen_queue[event_index])->retrieved = TWA_AEN_RETRIEVED;
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	case TW_CL_IOCTL_GET_LOCK:
 1.1  wrstuden 	{
 1.1  wrstuden 		struct tw_cl_lock_packet	twa_lock;
 1.1  wrstuden
 1.1  wrstuden 		copyin(user_buf->pdata, &twa_lock,
 1.1  wrstuden 				sizeof(struct tw_cl_lock_packet));
 1.1  wrstuden 		s = splbio();
 1.1  wrstuden 		if ((sc->twa_ioctl_lock.lock == TWA_LOCK_FREE) ||
 1.1  wrstuden 			(twa_lock.force_flag) ||
 1.4    simonb 			(time_second >= sc->twa_ioctl_lock.timeout)) {
 1.1  wrstuden
 1.1  wrstuden 			sc->twa_ioctl_lock.lock = TWA_LOCK_HELD;
 1.4    simonb 			sc->twa_ioctl_lock.timeout = time_second +
 1.1  wrstuden 				(twa_lock.timeout_msec / 1000);
 1.1  wrstuden 			twa_lock.time_remaining_msec = twa_lock.timeout_msec;
 1.1  wrstuden 			user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			twa_lock.time_remaining_msec =
 1.4    simonb 				(sc->twa_ioctl_lock.timeout - time_second) *
 1.1  wrstuden 				1000;
 1.1  wrstuden 			user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 					TWA_ERROR_IOCTL_LOCK_ALREADY_HELD;
 1.1  wrstuden 		}
 1.1  wrstuden 		splx(s);
 1.1  wrstuden 		copyout(&twa_lock, user_buf->pdata,
 1.1  wrstuden 				sizeof(struct tw_cl_lock_packet));
 1.1  wrstuden 		break;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	case TW_CL_IOCTL_RELEASE_LOCK:
 1.1  wrstuden 		s = splbio();
 1.1  wrstuden 		if (sc->twa_ioctl_lock.lock == TWA_LOCK_FREE) {
 1.1  wrstuden 			user_buf->twa_drvr_pkt.status =
 1.1  wrstuden 				TWA_ERROR_IOCTL_LOCK_NOT_HELD;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			sc->twa_ioctl_lock.lock = TWA_LOCK_FREE;
 1.1  wrstuden 			user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden 		}
 1.1  wrstuden 		splx(s);
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	case TW_CL_IOCTL_GET_COMPATIBILITY_INFO:
 1.1  wrstuden 	{
 1.1  wrstuden 		struct tw_cl_compatibility_packet	comp_pkt;
 1.1  wrstuden
 1.1  wrstuden 		memcpy(comp_pkt.driver_version, TWA_DRIVER_VERSION_STRING,
 1.1  wrstuden 					sizeof(TWA_DRIVER_VERSION_STRING));
 1.1  wrstuden 		comp_pkt.working_srl = sc->working_srl;
 1.1  wrstuden 		comp_pkt.working_branch = sc->working_branch;
 1.1  wrstuden 		comp_pkt.working_build = sc->working_build;
 1.1  wrstuden 		user_buf->twa_drvr_pkt.status = 0;
 1.1  wrstuden
 1.1  wrstuden 		/* Copy compatibility information to user space. */
 1.1  wrstuden 		copyout(&comp_pkt, user_buf->pdata,
 1.1  wrstuden 				min(sizeof(struct tw_cl_compatibility_packet),
 1.1  wrstuden 					user_buf->twa_drvr_pkt.buffer_length));
 1.1  wrstuden 		break;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	case TWA_IOCTL_GET_UNITNAME:	/* WASABI EXTENSION */
 1.1  wrstuden 	{
 1.1  wrstuden 		struct twa_unitname	*tn;
 1.1  wrstuden 		struct twa_drive	*tdr;
 1.1  wrstuden
 1.1  wrstuden 		tn = (struct twa_unitname *)data;
 1.1  wrstuden 			/* XXX mutex */
 1.1  wrstuden 		if (tn->tn_unit < 0 || tn->tn_unit >= TWA_MAX_UNITS)
 1.1  wrstuden 			return (EINVAL);
 1.1  wrstuden 		tdr = &sc->sc_units[tn->tn_unit];
 1.1  wrstuden 		if (tdr->td_dev == NULL)
 1.1  wrstuden 			tn->tn_name[0] = '\0';
 1.1  wrstuden 		else
 1.1  wrstuden 			strlcpy(tn->tn_name, tdr->td_dev->dv_xname,
 1.1  wrstuden 			    sizeof(tn->tn_name));
 1.1  wrstuden 		return (0);
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	default:
 1.1  wrstuden 		/* Unknown opcode. */
 1.1  wrstuden 		error = ENOTTY;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.2  wrstuden const struct cdevsw twa_cdevsw = {
 1.2  wrstuden 	twaopen, twaclose, noread, nowrite, twaioctl,
1.12  christos 	nostop, notty, nopoll, nommap, nokqfilter, D_OTHER,
 1.2  wrstuden };
 1.2  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_get_param
 1.1  wrstuden  * Description:		Get a firmware parameter.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc		-- ptr to per ctlr structure
 1.1  wrstuden  *			table_id	-- parameter table #
 1.1  wrstuden  *			param_id	-- index of the parameter in the table
 1.1  wrstuden  *			param_size	-- size of the parameter in bytes
 1.1  wrstuden  *			callback	-- ptr to function, if any, to be called
 1.1  wrstuden  *					back on completion; NULL if no callback.
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	ptr to param structure	-- success
 1.1  wrstuden  *			NULL			-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.1  wrstuden twa_get_param(struct twa_softc *sc, int table_id, int param_id,
 1.6    simonb     size_t param_size, void (* callback)(struct twa_request *tr),
 1.6    simonb     struct twa_param_9k **param)
 1.1  wrstuden {
 1.1  wrstuden 	int			rv = 0;
 1.1  wrstuden 	struct twa_request	*tr;
 1.1  wrstuden 	union twa_command_7k	*cmd;
 1.1  wrstuden
 1.1  wrstuden 	/* Get a request packet. */
 1.1  wrstuden 	if ((tr = twa_get_request(sc, 0)) == NULL) {
 1.1  wrstuden 		rv = EAGAIN;
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden
 1.1  wrstuden 	/* Allocate memory to read data into. */
 1.1  wrstuden 	if ((*param = (struct twa_param_9k *)
 1.1  wrstuden 		malloc(TWA_SECTOR_SIZE, M_DEVBUF, M_NOWAIT)) == NULL) {
 1.1  wrstuden 		rv = ENOMEM;
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	memset(*param, 0, sizeof(struct twa_param_9k) - 1 + param_size);
 1.1  wrstuden 	tr->tr_data = *param;
 1.1  wrstuden 	tr->tr_length = TWA_SECTOR_SIZE;
 1.1  wrstuden 	tr->tr_flags = TWA_CMD_DATA_IN | TWA_CMD_DATA_OUT;
 1.1  wrstuden
 1.1  wrstuden 	/* Build the cmd pkt. */
 1.1  wrstuden 	cmd = &(tr->tr_command->command.cmd_pkt_7k);
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_command->cmd_hdr.header_desc.size_header = 128;
 1.1  wrstuden
 1.1  wrstuden 	cmd->param.opcode = TWA_OP_GET_PARAM;
 1.1  wrstuden 	cmd->param.sgl_offset = 2;
 1.1  wrstuden 	cmd->param.size = 2;
 1.1  wrstuden 	cmd->param.request_id = tr->tr_request_id;
 1.1  wrstuden 	cmd->param.unit = 0;
 1.1  wrstuden 	cmd->param.param_count = 1;
 1.1  wrstuden
 1.1  wrstuden 	/* Specify which parameter we need. */
 1.1  wrstuden 	(*param)->table_id = table_id | TWA_9K_PARAM_DESCRIPTOR;
 1.1  wrstuden 	(*param)->parameter_id = param_id;
 1.1  wrstuden 	(*param)->parameter_size_bytes = param_size;
 1.1  wrstuden
 1.1  wrstuden 	/* Submit the command. */
 1.1  wrstuden 	if (callback == NULL) {
 1.1  wrstuden 		/* There's no call back; wait till the command completes. */
 1.1  wrstuden 		rv = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden
 1.1  wrstuden 		if (rv != 0)
 1.1  wrstuden 			goto out;
 1.1  wrstuden
 1.1  wrstuden 		if ((rv = cmd->param.status) != 0) {
 1.1  wrstuden 		     /* twa_drain_complete_queue will have done the unmapping */
 1.1  wrstuden 		     goto out;
 1.1  wrstuden 		}
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 		return (rv);
 1.1  wrstuden 	} else {
 1.1  wrstuden 		/* There's a call back.  Simply submit the command. */
 1.1  wrstuden 		tr->tr_callback = callback;
 1.1  wrstuden 		rv = twa_map_request(tr);
 1.1  wrstuden 		return (rv);
 1.1  wrstuden 	}
 1.1  wrstuden out:
 1.1  wrstuden 	if (tr)
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	return(rv);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_set_param
 1.1  wrstuden  * Description:		Set a firmware parameter.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc		-- ptr to per ctlr structure
 1.1  wrstuden  *			table_id	-- parameter table #
 1.1  wrstuden  *			param_id	-- index of the parameter in the table
 1.1  wrstuden  *			param_size	-- size of the parameter in bytes
 1.1  wrstuden  *			callback	-- ptr to function, if any, to be called
 1.1  wrstuden  *					back on completion; NULL if no callback.
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.6    simonb twa_set_param(struct twa_softc *sc, int table_id, int param_id, int param_size,
 1.6    simonb     void *data, void (* callback)(struct twa_request *tr))
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request	*tr;
 1.1  wrstuden 	union twa_command_7k	*cmd;
 1.1  wrstuden 	struct twa_param_9k	*param = NULL;
 1.1  wrstuden 	int			error = ENOMEM;
 1.1  wrstuden
 1.1  wrstuden 	tr = twa_get_request(sc, 0);
 1.1  wrstuden 	if (tr == NULL)
 1.1  wrstuden 		return (EAGAIN);
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden
 1.1  wrstuden 	/* Allocate memory to send data using. */
 1.1  wrstuden 	if ((param = (struct twa_param_9k *)
 1.1  wrstuden 			malloc(TWA_SECTOR_SIZE, M_DEVBUF, M_NOWAIT)) == NULL)
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	memset(param, 0, sizeof(struct twa_param_9k) - 1 + param_size);
 1.1  wrstuden 	tr->tr_data = param;
 1.1  wrstuden 	tr->tr_length = TWA_SECTOR_SIZE;
 1.1  wrstuden 	tr->tr_flags = TWA_CMD_DATA_IN | TWA_CMD_DATA_OUT;
 1.1  wrstuden
 1.1  wrstuden 	/* Build the cmd pkt. */
 1.1  wrstuden 	cmd = &(tr->tr_command->command.cmd_pkt_7k);
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_command->cmd_hdr.header_desc.size_header = 128;
 1.1  wrstuden
 1.1  wrstuden 	cmd->param.opcode = TWA_OP_SET_PARAM;
 1.1  wrstuden 	cmd->param.sgl_offset = 2;
 1.1  wrstuden 	cmd->param.size = 2;
 1.1  wrstuden 	cmd->param.request_id = tr->tr_request_id;
 1.1  wrstuden 	cmd->param.unit = 0;
 1.1  wrstuden 	cmd->param.param_count = 1;
 1.1  wrstuden
 1.1  wrstuden 	/* Specify which parameter we want to set. */
 1.1  wrstuden 	param->table_id = table_id | TWA_9K_PARAM_DESCRIPTOR;
 1.1  wrstuden 	param->parameter_id = param_id;
 1.1  wrstuden 	param->parameter_size_bytes = param_size;
 1.1  wrstuden 	memcpy(param->data, data, param_size);
 1.1  wrstuden
 1.1  wrstuden 	/* Submit the command. */
 1.1  wrstuden 	if (callback == NULL) {
 1.1  wrstuden 		/* There's no call back;  wait till the command completes. */
 1.1  wrstuden 		error = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden 		if (error == ETIMEDOUT)
 1.6    simonb 			/* clean-up done by twa_immediate_request */
 1.6    simonb 			return(error);
 1.1  wrstuden 		if (error)
 1.1  wrstuden 			goto out;
 1.1  wrstuden 		if ((error = cmd->param.status)) {
 1.6    simonb 			/*
 1.6    simonb 			 * twa_drain_complete_queue will have done the
 1.6    simonb 			 * unmapping.
 1.6    simonb 			 */
 1.6    simonb 			goto out;
 1.1  wrstuden 		}
 1.1  wrstuden 		free(param, M_DEVBUF);
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 		return(error);
 1.1  wrstuden 	} else {
 1.1  wrstuden 		/* There's a call back.  Simply submit the command. */
 1.1  wrstuden 		tr->tr_callback = callback;
 1.1  wrstuden 		if ((error = twa_map_request(tr)))
 1.1  wrstuden 			goto out;
 1.1  wrstuden
 1.1  wrstuden 		return (0);
 1.1  wrstuden 	}
 1.1  wrstuden out:
 1.1  wrstuden 	if (param)
 1.1  wrstuden 		free(param, M_DEVBUF);
 1.1  wrstuden 	if (tr)
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_init_connection
 1.1  wrstuden  * Description:		Send init_connection cmd to firmware
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc		-- ptr to per ctlr structure
 1.1  wrstuden  *			message_credits	-- max # of requests that we might send
 1.1  wrstuden  *					 down simultaneously.  This will be
 1.1  wrstuden  *					 typically set to 256 at init-time or
 1.1  wrstuden  *					after a reset, and to 1 at shutdown-time
 1.1  wrstuden  *			set_features	-- indicates if we intend to use 64-bit
 1.1  wrstuden  *					sg, also indicates if we want to do a
 1.1  wrstuden  *					basic or an extended init_connection;
 1.1  wrstuden  *
 1.1  wrstuden  * Note: The following input/output parameters are valid, only in case of an
 1.1  wrstuden  *		extended init_connection:
 1.1  wrstuden  *
 1.1  wrstuden  *			current_fw_srl		-- srl of fw we are bundled
 1.1  wrstuden  *						with, if any; 0 otherwise
 1.1  wrstuden  *			current_fw_arch_id	-- arch_id of fw we are bundled
 1.1  wrstuden  *						with, if any; 0 otherwise
 1.1  wrstuden  *			current_fw_branch	-- branch # of fw we are bundled
 1.1  wrstuden  *						with, if any; 0 otherwise
 1.1  wrstuden  *			current_fw_build	-- build # of fw we are bundled
 1.1  wrstuden  *						with, if any; 0 otherwise
 1.1  wrstuden  * Output:		fw_on_ctlr_srl		-- srl of fw on ctlr
 1.1  wrstuden  *			fw_on_ctlr_arch_id	-- arch_id of fw on ctlr
 1.1  wrstuden  *			fw_on_ctlr_branch	-- branch # of fw on ctlr
 1.1  wrstuden  *			fw_on_ctlr_build	-- build # of fw on ctlr
 1.1  wrstuden  *			init_connect_result	-- result bitmap of fw response
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.7    simonb twa_init_connection(struct twa_softc *sc, uint16_t message_credits,
 1.7    simonb     uint32_t set_features, uint16_t current_fw_srl,
 1.7    simonb     uint16_t current_fw_arch_id, uint16_t current_fw_branch,
1.16  christos     uint16_t current_fw_build, uint16_t *fw_on_ctlr_srl,
 1.7    simonb     uint16_t *fw_on_ctlr_arch_id, uint16_t *fw_on_ctlr_branch,
 1.7    simonb     uint16_t *fw_on_ctlr_build, uint32_t *init_connect_result)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request		*tr;
 1.1  wrstuden 	struct twa_command_init_connect	*init_connect;
 1.1  wrstuden 	int				error = 1;
 1.1  wrstuden
 1.1  wrstuden 	/* Get a request packet. */
 1.1  wrstuden 	if ((tr = twa_get_request(sc, 0)) == NULL)
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden 	/* Build the cmd pkt. */
 1.1  wrstuden 	init_connect = &(tr->tr_command->command.cmd_pkt_7k.init_connect);
 1.1  wrstuden
 1.1  wrstuden 	tr->tr_command->cmd_hdr.header_desc.size_header = 128;
 1.1  wrstuden
 1.1  wrstuden 	init_connect->opcode = TWA_OP_INIT_CONNECTION;
 1.1  wrstuden    	init_connect->request_id = tr->tr_request_id;
 1.1  wrstuden 	init_connect->message_credits = message_credits;
 1.1  wrstuden 	init_connect->features = set_features;
 1.1  wrstuden 	if (TWA_64BIT_ADDRESSES) {
 1.1  wrstuden 		printf("64 bit addressing supported for scatter/gather list\n");
 1.1  wrstuden 		init_connect->features |= TWA_64BIT_SG_ADDRESSES;
 1.1  wrstuden 	}
 1.1  wrstuden 	if (set_features & TWA_EXTENDED_INIT_CONNECT) {
 1.1  wrstuden 		/*
 1.1  wrstuden 		 * Fill in the extra fields needed for
 1.1  wrstuden 		 * an extended init_connect.
 1.1  wrstuden 		 */
 1.1  wrstuden 		init_connect->size = 6;
 1.1  wrstuden 		init_connect->fw_srl = current_fw_srl;
 1.1  wrstuden 		init_connect->fw_arch_id = current_fw_arch_id;
 1.1  wrstuden 		init_connect->fw_branch = current_fw_branch;
 1.1  wrstuden 	} else
 1.1  wrstuden 		init_connect->size = 3;
 1.1  wrstuden
 1.1  wrstuden 	/* Submit the command, and wait for it to complete. */
 1.1  wrstuden 	error = twa_immediate_request(tr, TWA_REQUEST_TIMEOUT_PERIOD);
 1.1  wrstuden 	if (error == ETIMEDOUT)
 1.1  wrstuden 		return(error); /* clean-up done by twa_immediate_request */
 1.1  wrstuden 	if (error)
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	if ((error = init_connect->status)) {
 1.6    simonb 		/* twa_drain_complete_queue will have done the unmapping */
 1.6    simonb 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden 	if (set_features & TWA_EXTENDED_INIT_CONNECT) {
 1.1  wrstuden 		*fw_on_ctlr_srl = init_connect->fw_srl;
 1.1  wrstuden 		*fw_on_ctlr_arch_id = init_connect->fw_arch_id;
 1.1  wrstuden 		*fw_on_ctlr_branch = init_connect->fw_branch;
 1.1  wrstuden 		*fw_on_ctlr_build = init_connect->fw_build;
 1.1  wrstuden 		*init_connect_result = init_connect->result;
 1.1  wrstuden 	}
 1.1  wrstuden 	twa_release_request(tr);
 1.1  wrstuden 	return(error);
 1.1  wrstuden
 1.1  wrstuden out:
 1.1  wrstuden 	if (tr)
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_reset(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	int	s;
 1.1  wrstuden 	int	error = 0;
 1.1  wrstuden
 1.1  wrstuden 	/*
 1.1  wrstuden 	 * Disable interrupts from the controller, and mask any
 1.1  wrstuden 	 * accidental entry into our interrupt handler.
 1.1  wrstuden 	 */
 1.1  wrstuden 	twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 		TWA_CONTROL_DISABLE_INTERRUPTS);
 1.1  wrstuden
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden
 1.1  wrstuden 	/* Soft reset the controller. */
 1.1  wrstuden 	if ((error = twa_soft_reset(sc)))
 1.1  wrstuden 		goto out;
 1.1  wrstuden
 1.1  wrstuden 	/* Re-establish logical connection with the controller. */
 1.1  wrstuden 	if ((error = twa_init_connection(sc, TWA_INIT_MESSAGE_CREDITS,
 1.1  wrstuden 					0, 0, 0, 0, 0,
 1.1  wrstuden 					NULL, NULL, NULL, NULL, NULL))) {
 1.1  wrstuden 		goto out;
 1.1  wrstuden 	}
 1.1  wrstuden 	/*
 1.1  wrstuden 	 * Complete all requests in the complete queue; error back all requests
 1.1  wrstuden 	 * in the busy queue.  Any internal requests will be simply freed.
 1.1  wrstuden 	 * Re-submit any requests in the pending queue.
 1.1  wrstuden 	 */
 1.1  wrstuden 	twa_drain_busy_queue(sc);
 1.1  wrstuden
 1.1  wrstuden out:
 1.1  wrstuden 	splx(s);
 1.1  wrstuden 	/*
 1.1  wrstuden 	 * Enable interrupts, and also clear attention and response interrupts.
 1.1  wrstuden 	 */
 1.1  wrstuden 	twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 		TWA_CONTROL_CLEAR_ATTENTION_INTERRUPT |
 1.1  wrstuden 		TWA_CONTROL_UNMASK_RESPONSE_INTERRUPT |
 1.1  wrstuden 		TWA_CONTROL_ENABLE_INTERRUPTS);
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_soft_reset(struct twa_softc *sc)
 1.1  wrstuden {
 1.7    simonb 	uint32_t	status_reg;
 1.1  wrstuden
 1.1  wrstuden 	twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 			TWA_CONTROL_ISSUE_SOFT_RESET |
 1.1  wrstuden 			TWA_CONTROL_CLEAR_HOST_INTERRUPT |
 1.1  wrstuden 			TWA_CONTROL_CLEAR_ATTENTION_INTERRUPT |
 1.1  wrstuden 			TWA_CONTROL_MASK_COMMAND_INTERRUPT |
 1.1  wrstuden 			TWA_CONTROL_MASK_RESPONSE_INTERRUPT |
 1.1  wrstuden 			TWA_CONTROL_DISABLE_INTERRUPTS);
 1.1  wrstuden
 1.1  wrstuden 	if (twa_wait_status(sc, TWA_STATUS_MICROCONTROLLER_READY |
 1.1  wrstuden 				TWA_STATUS_ATTENTION_INTERRUPT, 30)) {
 1.1  wrstuden 		aprint_error("%s: no attention interrupt after reset.\n",
 1.1  wrstuden 			sc->twa_dv.dv_xname);
 1.1  wrstuden 		return(1);
 1.1  wrstuden 	}
 1.1  wrstuden 	twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 		TWA_CONTROL_CLEAR_ATTENTION_INTERRUPT);
 1.1  wrstuden
 1.1  wrstuden 	if (twa_drain_response_queue(sc)) {
 1.6    simonb 		aprint_error("%s: cannot drain response queue.\n",
 1.6    simonb 		    sc->twa_dv.dv_xname);
 1.1  wrstuden 		return(1);
 1.1  wrstuden 	}
 1.1  wrstuden 	if (twa_drain_aen_queue(sc)) {
 1.6    simonb 		aprint_error("%s: cannot drain AEN queue.\n",
 1.6    simonb 		    sc->twa_dv.dv_xname);
 1.1  wrstuden 		return(1);
 1.1  wrstuden 	}
 1.1  wrstuden 	if (twa_find_aen(sc, TWA_AEN_SOFT_RESET)) {
 1.1  wrstuden 		aprint_error("%s: reset not reported by controller.\n",
 1.1  wrstuden 			 sc->twa_dv.dv_xname);
 1.1  wrstuden 		return(1);
 1.1  wrstuden 	}
 1.1  wrstuden 	status_reg = twa_inl(sc, TWA_STATUS_REGISTER_OFFSET);
 1.1  wrstuden 	if (TWA_STATUS_ERRORS(status_reg) ||
 1.6    simonb 	    twa_check_ctlr_state(sc, status_reg)) {
 1.6    simonb 		aprint_error("%s: controller errors detected.\n",
 1.6    simonb 		    sc->twa_dv.dv_xname);
 1.1  wrstuden 		return(1);
 1.1  wrstuden 	}
 1.1  wrstuden 	return(0);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.7    simonb twa_wait_status(struct twa_softc *sc, uint32_t status, uint32_t timeout)
 1.1  wrstuden {
 1.1  wrstuden 	struct timeval		t1;
 1.1  wrstuden 	time_t		end_time;
 1.7    simonb 	uint32_t	status_reg;
 1.1  wrstuden
 1.1  wrstuden 	timeout = (timeout * 1000 * 100);
 1.1  wrstuden
 1.1  wrstuden 	microtime(&t1);
 1.1  wrstuden
 1.1  wrstuden 	end_time = t1.tv_usec + timeout;
 1.1  wrstuden
 1.1  wrstuden 	do {
 1.1  wrstuden 		status_reg = twa_inl(sc, TWA_STATUS_REGISTER_OFFSET);
 1.6    simonb 		/* got the required bit(s)? */
 1.6    simonb 		if ((status_reg & status) == status)
 1.1  wrstuden 			return(0);
 1.1  wrstuden 		DELAY(100000);
 1.1  wrstuden 		microtime(&t1);
 1.1  wrstuden 	} while (t1.tv_usec <= end_time);
 1.1  wrstuden
 1.1  wrstuden 	return(1);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden static int
 1.1  wrstuden twa_fetch_aen(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request	*tr;
 1.1  wrstuden 	int			s, error = 0;
 1.1  wrstuden
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden
 1.8  wrstuden 	if ((tr = twa_get_request(sc, TWA_CMD_AEN)) == NULL) {
 1.8  wrstuden 		splx(s);
 1.1  wrstuden 		return(EIO);
 1.8  wrstuden 	}
 1.1  wrstuden 	tr->tr_cmd_pkt_type |= TWA_CMD_PKT_TYPE_INTERNAL;
 1.1  wrstuden 	tr->tr_callback = twa_aen_callback;
 1.1  wrstuden 	tr->tr_data = malloc(TWA_SECTOR_SIZE, M_DEVBUF, M_NOWAIT);
 1.1  wrstuden 	if (twa_request_sense(tr, 0) != 0) {
 1.1  wrstuden 		if (tr->tr_data)
 1.1  wrstuden 			free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden 		twa_release_request(tr);
 1.1  wrstuden 		error = 1;
 1.1  wrstuden 	}
 1.1  wrstuden 	splx(s);
 1.1  wrstuden
 1.1  wrstuden 	return(error);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_aen_callback
 1.1  wrstuden  * Description:		Callback for requests to fetch AEN's.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		tr	-- ptr to completed request pkt
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	None
 1.1  wrstuden  */
 1.1  wrstuden static void
 1.1  wrstuden twa_aen_callback(struct twa_request *tr)
 1.1  wrstuden {
 1.1  wrstuden 	int i;
 1.1  wrstuden 	int fetch_more_aens = 0;
 1.1  wrstuden 	struct twa_softc		*sc = tr->tr_sc;
 1.1  wrstuden 	struct twa_command_header	*cmd_hdr =
 1.1  wrstuden 		(struct twa_command_header *)(tr->tr_data);
 1.1  wrstuden 	struct twa_command_9k		*cmd =
 1.1  wrstuden 		&(tr->tr_command->command.cmd_pkt_9k);
 1.1  wrstuden
 1.1  wrstuden 	if (! cmd->status) {
 1.1  wrstuden 		if ((tr->tr_cmd_pkt_type & TWA_CMD_PKT_TYPE_9K) &&
 1.1  wrstuden 			(cmd->cdb[0] == 0x3 /* REQUEST_SENSE */))
 1.1  wrstuden 			if (twa_enqueue_aen(sc, cmd_hdr)
 1.1  wrstuden 				!= TWA_AEN_QUEUE_EMPTY)
 1.1  wrstuden 				fetch_more_aens = 1;
 1.1  wrstuden 	} else {
 1.1  wrstuden 		cmd_hdr->err_specific_desc[sizeof(cmd_hdr->err_specific_desc) - 1] = '\0';
 1.1  wrstuden 		for (i = 0; i < 18; i++)
 1.1  wrstuden 			printf("%x\t", tr->tr_command->cmd_hdr.sense_data[i]);
 1.1  wrstuden
 1.1  wrstuden 		printf(""); /* print new line */
 1.1  wrstuden
 1.1  wrstuden 		for (i = 0; i < 128; i++)
 1.1  wrstuden 			printf("%x\t", ((int8_t *)(tr->tr_data))[i]);
 1.1  wrstuden 	}
 1.1  wrstuden 	if (tr->tr_data)
 1.1  wrstuden 		free(tr->tr_data, M_DEVBUF);
 1.1  wrstuden 	twa_release_request(tr);
 1.1  wrstuden
 1.1  wrstuden 	if (fetch_more_aens)
 1.1  wrstuden 		twa_fetch_aen(sc);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_enqueue_aen
 1.1  wrstuden  * Description:		Queues AEN's to be supplied to user-space tools on request.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc	-- ptr to per ctlr structure
 1.1  wrstuden  *			cmd_hdr	-- ptr to hdr of fw cmd pkt, from where the AEN
 1.1  wrstuden  *				   details can be retrieved.
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	None
 1.1  wrstuden  */
 1.1  wrstuden static uint16_t
 1.1  wrstuden twa_enqueue_aen(struct twa_softc *sc, struct twa_command_header *cmd_hdr)
 1.1  wrstuden {
 1.1  wrstuden 	int			rv, s;
 1.1  wrstuden 	struct tw_cl_event_packet *event;
 1.1  wrstuden 	uint16_t		aen_code;
 1.1  wrstuden 	unsigned long		sync_time;
 1.1  wrstuden
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden 	aen_code = cmd_hdr->status_block.error;
 1.1  wrstuden
 1.1  wrstuden 	switch (aen_code) {
 1.1  wrstuden 	case TWA_AEN_SYNC_TIME_WITH_HOST:
 1.1  wrstuden
 1.4    simonb 		sync_time = (time_second - (3 * 86400)) % 604800;
 1.1  wrstuden 		rv = twa_set_param(sc, TWA_PARAM_TIME_TABLE,
 1.1  wrstuden 				TWA_PARAM_TIME_SchedulerTime, 4,
 1.1  wrstuden 				&sync_time, twa_aen_callback);
 1.1  wrstuden #ifdef DIAGNOSTIC
 1.1  wrstuden 		if (rv != 0)
 1.1  wrstuden 			printf("%s: unable to sync time with ctlr\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname);
 1.1  wrstuden #endif
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	case TWA_AEN_QUEUE_EMPTY:
 1.1  wrstuden 		break;
 1.1  wrstuden
 1.1  wrstuden 	default:
 1.1  wrstuden 		/* Queue the event. */
 1.1  wrstuden 		event = sc->twa_aen_queue[sc->twa_aen_head];
 1.1  wrstuden 		if (event->retrieved == TWA_AEN_NOT_RETRIEVED)
 1.1  wrstuden 			sc->twa_aen_queue_overflow = TRUE;
 1.1  wrstuden 		event->severity =
 1.1  wrstuden 			cmd_hdr->status_block.substatus_block.severity;
 1.4    simonb 		event->time_stamp_sec = time_second;
 1.1  wrstuden 		event->aen_code = aen_code;
 1.1  wrstuden 		event->retrieved = TWA_AEN_NOT_RETRIEVED;
 1.1  wrstuden 		event->sequence_id = ++(sc->twa_current_sequence_id);
 1.1  wrstuden 		cmd_hdr->err_specific_desc[sizeof(cmd_hdr->err_specific_desc) - 1] = '\0';
 1.1  wrstuden 		event->parameter_len = strlen(cmd_hdr->err_specific_desc);
 1.1  wrstuden 		memcpy(event->parameter_data, cmd_hdr->err_specific_desc,
 1.1  wrstuden 			event->parameter_len);
 1.1  wrstuden
 1.1  wrstuden 		if (event->severity < TWA_AEN_SEVERITY_DEBUG) {
 1.1  wrstuden 			printf("%s: AEN 0x%04X: %s: %s: %s\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname,
 1.1  wrstuden 				aen_code,
 1.1  wrstuden 				twa_aen_severity_table[event->severity],
 1.1  wrstuden 				twa_find_msg_string(twa_aen_table, aen_code),
 1.1  wrstuden 				event->parameter_data);
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		if ((sc->twa_aen_head + 1) == TWA_Q_LENGTH)
 1.1  wrstuden 			sc->twa_aen_queue_wrapped = TRUE;
 1.1  wrstuden 		sc->twa_aen_head = (sc->twa_aen_head + 1) % TWA_Q_LENGTH;
 1.1  wrstuden 		break;
 1.1  wrstuden 	} /* switch */
 1.1  wrstuden 	splx(s);
 1.1  wrstuden
 1.1  wrstuden 	return (aen_code);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_find_aen
 1.1  wrstuden  * Description:		Reports whether a given AEN ever occurred.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc	-- ptr to per ctlr structure
 1.1  wrstuden  *			aen_code-- AEN to look for
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- success
 1.1  wrstuden  *			non-zero-- failure
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.7    simonb twa_find_aen(struct twa_softc *sc, uint16_t aen_code)
 1.1  wrstuden {
 1.7    simonb 	uint32_t	last_index;
 1.1  wrstuden 	int		s;
 1.1  wrstuden 	int		i;
 1.1  wrstuden
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden
 1.1  wrstuden 	if (sc->twa_aen_queue_wrapped)
 1.1  wrstuden 		last_index = sc->twa_aen_head;
 1.1  wrstuden 	else
 1.1  wrstuden 		last_index = 0;
 1.1  wrstuden
 1.1  wrstuden 	i = sc->twa_aen_head;
 1.1  wrstuden 	do {
 1.1  wrstuden 		i = (i + TWA_Q_LENGTH - 1) % TWA_Q_LENGTH;
 1.1  wrstuden 		if ((sc->twa_aen_queue[i])->aen_code == aen_code) {
 1.1  wrstuden 			splx(s);
 1.1  wrstuden 			return(0);
 1.1  wrstuden 		}
 1.1  wrstuden 	} while (i != last_index);
 1.1  wrstuden
 1.1  wrstuden 	splx(s);
 1.1  wrstuden 	return(1);
 1.1  wrstuden }
 1.1  wrstuden
1.12  christos static inline void
 1.1  wrstuden twa_request_init(struct twa_request *tr, int flags)
 1.1  wrstuden {
 1.1  wrstuden 	tr->tr_data = NULL;
 1.1  wrstuden 	tr->tr_real_data = NULL;
 1.1  wrstuden 	tr->tr_length = 0;
 1.1  wrstuden 	tr->tr_real_length = 0;
 1.1  wrstuden 	tr->tr_status = TWA_CMD_SETUP;/* command is in setup phase */
 1.1  wrstuden 	tr->tr_flags = flags;
 1.1  wrstuden 	tr->tr_error = 0;
 1.1  wrstuden 	tr->tr_callback = NULL;
 1.1  wrstuden 	tr->tr_cmd_pkt_type = 0;
 1.8  wrstuden 	tr->bp = 0;
 1.1  wrstuden
 1.1  wrstuden 	/*
 1.1  wrstuden 	 * Look at the status field in the command packet to see how
 1.1  wrstuden 	 * it completed the last time it was used, and zero out only
 1.1  wrstuden 	 * the portions that might have changed.  Note that we don't
 1.1  wrstuden 	 * care to zero out the sglist.
 1.1  wrstuden 	 */
 1.1  wrstuden 	if (tr->tr_command->command.cmd_pkt_9k.status)
 1.1  wrstuden 		memset(tr->tr_command, 0,
 1.1  wrstuden 			sizeof(struct twa_command_header) + 28);
 1.1  wrstuden 	else
 1.1  wrstuden 		memset(&(tr->tr_command->command), 0, 28);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden struct twa_request *
 1.1  wrstuden twa_get_request_wait(struct twa_softc *sc, int flags)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_request *tr;
 1.1  wrstuden 	int s;
 1.1  wrstuden
 1.1  wrstuden 	KASSERT((flags & TWA_CMD_AEN) == 0);
 1.1  wrstuden
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden 	while ((tr = TAILQ_FIRST(&sc->twa_free)) == NULL) {
 1.1  wrstuden 		sc->twa_sc_flags |= TWA_STATE_REQUEST_WAIT;
 1.1  wrstuden 		(void) tsleep(&sc->twa_free, PRIBIO, "twaccb", hz);
 1.1  wrstuden 	}
 1.1  wrstuden 	TAILQ_REMOVE(&sc->twa_free, tr, tr_link);
 1.1  wrstuden
 1.1  wrstuden 	splx(s);
 1.1  wrstuden
 1.1  wrstuden 	twa_request_init(tr, flags);
 1.1  wrstuden
 1.1  wrstuden 	return(tr);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden struct twa_request *
 1.1  wrstuden twa_get_request(struct twa_softc *sc, int flags)
 1.1  wrstuden {
 1.1  wrstuden 	int s;
 1.1  wrstuden 	struct twa_request *tr;
 1.1  wrstuden
 1.1  wrstuden 	/* Get a free request packet. */
 1.1  wrstuden 	s = splbio();
 1.1  wrstuden 	if (__predict_false((flags & TWA_CMD_AEN) != 0)) {
 1.1  wrstuden
 1.1  wrstuden 		if ((sc->sc_twa_request->tr_flags & TWA_CMD_AEN_BUSY) == 0) {
 1.1  wrstuden 			tr = sc->sc_twa_request;
 1.1  wrstuden 			flags |= TWA_CMD_AEN_BUSY;
 1.1  wrstuden 		} else {
 1.1  wrstuden 			splx(s);
 1.1  wrstuden 			return (NULL);
 1.1  wrstuden 		}
 1.1  wrstuden 	} else {
 1.1  wrstuden 		if (__predict_false((tr =
 1.1  wrstuden 				TAILQ_FIRST(&sc->twa_free)) == NULL)) {
 1.1  wrstuden 			splx(s);
 1.1  wrstuden 			return (NULL);
 1.1  wrstuden 		}
 1.1  wrstuden 		TAILQ_REMOVE(&sc->twa_free, tr, tr_link);
 1.1  wrstuden 	}
 1.1  wrstuden 	splx(s);
 1.1  wrstuden
 1.1  wrstuden 	twa_request_init(tr, flags);
 1.1  wrstuden
 1.1  wrstuden 	return(tr);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Print some information about the controller
 1.1  wrstuden  */
 1.1  wrstuden static void
 1.1  wrstuden twa_describe_controller(struct twa_softc *sc)
 1.1  wrstuden {
 1.1  wrstuden 	struct twa_param_9k	*p[10];
 1.1  wrstuden 	int			i, rv = 0;
 1.1  wrstuden 	uint32_t		dsize;
 1.1  wrstuden 	uint8_t			ports;
 1.1  wrstuden
 1.1  wrstuden 	memset(p, sizeof(struct twa_param_9k *), 10);
 1.1  wrstuden
 1.1  wrstuden 	/* Get the port count. */
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_CONTROLLER,
 1.1  wrstuden 		TWA_PARAM_CONTROLLER_PortCount, 1, NULL, &p[0]);
 1.1  wrstuden
 1.1  wrstuden 	/* get version strings */
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_VERSION, TWA_PARAM_VERSION_FW,
 1.1  wrstuden 		16, NULL, &p[1]);
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_VERSION, TWA_PARAM_VERSION_BIOS,
 1.1  wrstuden 		16, NULL, &p[2]);
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_VERSION, TWA_PARAM_VERSION_Mon,
 1.1  wrstuden 		16, NULL, &p[3]);
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_VERSION, TWA_PARAM_VERSION_PCBA,
 1.1  wrstuden 		8, NULL, &p[4]);
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_VERSION, TWA_PARAM_VERSION_ATA,
 1.1  wrstuden 		8, NULL, &p[5]);
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_VERSION, TWA_PARAM_VERSION_PCI,
 1.1  wrstuden 		8, NULL, &p[6]);
 1.1  wrstuden 	rv |= twa_get_param(sc, TWA_PARAM_DRIVESUMMARY, TWA_PARAM_DRIVESTATUS,
 1.1  wrstuden 		16, NULL, &p[7]);
 1.1  wrstuden
 1.1  wrstuden 	if (rv) {
 1.1  wrstuden 		/* some error occurred */
 1.1  wrstuden 		aprint_error("%s: failed to fetch version information\n",
 1.1  wrstuden 			sc->twa_dv.dv_xname);
 1.1  wrstuden 		goto bail;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.7    simonb 	ports = *(uint8_t *)(p[0]->data);
 1.1  wrstuden
 1.1  wrstuden 	aprint_normal("%s: %d ports, Firmware %.16s, BIOS %.16s\n",
 1.1  wrstuden 		sc->twa_dv.dv_xname, ports,
 1.1  wrstuden 		p[1]->data, p[2]->data);
 1.1  wrstuden
 1.1  wrstuden 	aprint_verbose("%s: Monitor %.16s, PCB %.8s, Achip %.8s, Pchip %.8s\n",
 1.1  wrstuden 		sc->twa_dv.dv_xname,
 1.1  wrstuden 		p[3]->data, p[4]->data,
 1.1  wrstuden 		p[5]->data, p[6]->data);
 1.1  wrstuden
 1.1  wrstuden 	for (i = 0; i < ports; i++) {
 1.1  wrstuden
 1.1  wrstuden 		if ((*((char *)(p[7]->data + i)) & TWA_DRIVE_DETECTED) == 0)
 1.1  wrstuden 			continue;
 1.1  wrstuden
1.11  christos 		rv = twa_get_param(sc, TWA_PARAM_DRIVE_TABLE + i,
 1.1  wrstuden 			TWA_PARAM_DRIVEMODELINDEX,
 1.1  wrstuden 			TWA_PARAM_DRIVEMODEL_LENGTH, NULL, &p[8]);
 1.1  wrstuden
 1.1  wrstuden 		if (rv != 0) {
 1.1  wrstuden 			aprint_error("%s: unable to get drive model for port"
 1.1  wrstuden 				" %d\n", sc->twa_dv.dv_xname, i);
 1.1  wrstuden 			continue;
 1.1  wrstuden 		}
 1.1  wrstuden
1.11  christos 		rv = twa_get_param(sc, TWA_PARAM_DRIVE_TABLE + i,
 1.1  wrstuden 			TWA_PARAM_DRIVESIZEINDEX,
 1.1  wrstuden 			TWA_PARAM_DRIVESIZE_LENGTH, NULL, &p[9]);
 1.1  wrstuden
 1.1  wrstuden 		if (rv != 0) {
 1.1  wrstuden 			aprint_error("%s: unable to get drive size"
 1.1  wrstuden 				" for port %d\n", sc->twa_dv.dv_xname,
 1.1  wrstuden 					i);
 1.1  wrstuden 			free(p[8], M_DEVBUF);
 1.1  wrstuden 			continue;
 1.1  wrstuden 		}
 1.1  wrstuden
 1.1  wrstuden 		dsize = *(uint32_t *)(p[9]->data);
 1.1  wrstuden
 1.1  wrstuden 		aprint_verbose("%s: port %d: %.40s %d MB\n",
 1.1  wrstuden 		    sc->twa_dv.dv_xname, i, p[8]->data, dsize / 2048);
 1.1  wrstuden
 1.1  wrstuden 		if (p[8])
 1.1  wrstuden 			free(p[8], M_DEVBUF);
 1.1  wrstuden 		if (p[9])
 1.1  wrstuden 			free(p[9], M_DEVBUF);
 1.1  wrstuden 	}
 1.1  wrstuden bail:
 1.1  wrstuden 	if (p[0])
 1.1  wrstuden 		free(p[0], M_DEVBUF);
 1.1  wrstuden 	if (p[1])
 1.1  wrstuden 		free(p[1], M_DEVBUF);
 1.1  wrstuden 	if (p[2])
 1.1  wrstuden 		free(p[2], M_DEVBUF);
 1.1  wrstuden 	if (p[3])
 1.1  wrstuden 		free(p[3], M_DEVBUF);
 1.1  wrstuden 	if (p[4])
 1.1  wrstuden 		free(p[4], M_DEVBUF);
 1.1  wrstuden 	if (p[5])
 1.1  wrstuden 		free(p[5], M_DEVBUF);
 1.1  wrstuden 	if (p[6])
 1.1  wrstuden 		free(p[6], M_DEVBUF);
 1.1  wrstuden }
 1.1  wrstuden
 1.1  wrstuden /*
 1.1  wrstuden  * Function name:	twa_check_ctlr_state
 1.1  wrstuden  * Description:		Makes sure that the fw status register reports a
 1.1  wrstuden  *			proper status.
 1.1  wrstuden  *
 1.1  wrstuden  * Input:		sc		-- ptr to per ctlr structure
 1.1  wrstuden  *			status_reg	-- value in the status register
 1.1  wrstuden  * Output:		None
 1.1  wrstuden  * Return value:	0	-- no errors
 1.1  wrstuden  *			non-zero-- errors
 1.1  wrstuden  */
 1.1  wrstuden static int
 1.7    simonb twa_check_ctlr_state(struct twa_softc *sc, uint32_t status_reg)
 1.1  wrstuden {
 1.1  wrstuden 	int		result = 0;
 1.1  wrstuden 	struct timeval	t1;
 1.1  wrstuden 	static time_t	last_warning[2] = {0, 0};
 1.1  wrstuden
 1.1  wrstuden 	/* Check if the 'micro-controller ready' bit is not set. */
 1.1  wrstuden 	if ((status_reg & TWA_STATUS_EXPECTED_BITS) !=
 1.1  wrstuden 				TWA_STATUS_EXPECTED_BITS) {
 1.1  wrstuden
 1.1  wrstuden 		microtime(&t1);
 1.1  wrstuden
 1.1  wrstuden 		last_warning[0] += (5 * 1000 * 100);
 1.1  wrstuden
 1.1  wrstuden 		if (t1.tv_usec > last_warning[0]) {
 1.1  wrstuden 			microtime(&t1);
 1.1  wrstuden 			last_warning[0] = t1.tv_usec;
 1.1  wrstuden 		}
 1.1  wrstuden 		result = 1;
 1.1  wrstuden 	}
 1.1  wrstuden
 1.1  wrstuden 	/* Check if any error bits are set. */
 1.1  wrstuden 	if ((status_reg & TWA_STATUS_UNEXPECTED_BITS) != 0) {
 1.1  wrstuden
 1.1  wrstuden 		microtime(&t1);
 1.1  wrstuden 		last_warning[1] += (5 * 1000 * 100);
 1.1  wrstuden 		if (t1.tv_usec > last_warning[1]) {
 1.1  wrstuden 		     	microtime(&t1);
 1.1  wrstuden 			last_warning[1] = t1.tv_usec;
 1.1  wrstuden 		}
 1.1  wrstuden 		if (status_reg & TWA_STATUS_PCI_PARITY_ERROR_INTERRUPT) {
 1.1  wrstuden 			aprint_error("%s: clearing PCI parity error "
 1.1  wrstuden 				"re-seat/move/replace card.\n",
 1.1  wrstuden 				 sc->twa_dv.dv_xname);
 1.1  wrstuden 			twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 				TWA_CONTROL_CLEAR_PARITY_ERROR);
 1.1  wrstuden 			pci_conf_write(sc->pc, sc->tag,
 1.1  wrstuden 				PCI_COMMAND_STATUS_REG,
 1.1  wrstuden 				TWA_PCI_CONFIG_CLEAR_PARITY_ERROR);
 1.1  wrstuden 			result = 1;
 1.1  wrstuden 		}
 1.1  wrstuden 		if (status_reg & TWA_STATUS_PCI_ABORT_INTERRUPT) {
 1.1  wrstuden 			aprint_error("%s: clearing PCI abort\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname);
 1.1  wrstuden 			twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 				TWA_CONTROL_CLEAR_PCI_ABORT);
 1.1  wrstuden 			pci_conf_write(sc->pc, sc->tag,
 1.1  wrstuden 				PCI_COMMAND_STATUS_REG,
 1.1  wrstuden 				TWA_PCI_CONFIG_CLEAR_PCI_ABORT);
 1.1  wrstuden 			result = 1;
 1.1  wrstuden 		}
 1.1  wrstuden 		if (status_reg & TWA_STATUS_QUEUE_ERROR_INTERRUPT) {
 1.1  wrstuden 			aprint_error("%s: clearing controller queue error\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname);
 1.1  wrstuden 			twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 				TWA_CONTROL_CLEAR_PCI_ABORT);
 1.1  wrstuden 			result = 1;
 1.1  wrstuden 		}
 1.1  wrstuden 		if (status_reg & TWA_STATUS_SBUF_WRITE_ERROR) {
 1.1  wrstuden 			aprint_error("%s: clearing SBUF write error\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname);
 1.1  wrstuden 			twa_outl(sc, TWA_CONTROL_REGISTER_OFFSET,
 1.1  wrstuden 				TWA_CONTROL_CLEAR_SBUF_WRITE_ERROR);
 1.1  wrstuden 			result = 1;
 1.1  wrstuden 		}
 1.1  wrstuden 		if (status_reg & TWA_STATUS_MICROCONTROLLER_ERROR) {
 1.1  wrstuden 			aprint_error("%s: micro-controller error\n",
 1.1  wrstuden 				sc->twa_dv.dv_xname);
 1.1  wrstuden 			result = 1;
 1.1  wrstuden 		}
 1.1  wrstuden 	}
 1.1  wrstuden 	return(result);
 1.1  wrstuden }