lib/sg_pt_osf1.c - platform/external/sg3_utils - Git at Google

 /*
  * Copyright (c) 2005-2010 Douglas Gilbert.
  * All rights reserved.
  * Use of this source code is governed by a BSD-style
  * license that can be found in the BSD_LICENSE file.
  */

 #include <fcntl.h>
 #include <sys/stat.h>
 #include <sys/types.h>
 #include <unistd.h>
 #include <sys/ioctl.h>
 #include <io/common/devgetinfo.h>
 #include <io/common/iotypes.h>
 #include <io/cam/cam.h>
 #include <io/cam/uagt.h>
 #include <io/cam/rzdisk.h>
 #include <io/cam/scsi_opcodes.h>
 #include <io/cam/scsi_all.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <errno.h>

 #include "sg_pt.h"
 #include "sg_lib.h"

 /* Changed to use struct sg_pt_base 20070403 */


 #define OSF1_MAXDEV 64

 struct osf1_dev_channel {
     int bus;
     int tgt;
     int lun;
 };

 // Private table of open devices: guaranteed zero on startup since
 // part of static data.
 static struct osf1_dev_channel *devicetable[OSF1_MAXDEV] = {0};
 static char *cam_dev = "/dev/cam";
 static int camfd;
 static int camopened = 0;

 struct sg_pt_osf1_scsi {
     unsigned char * cdb;
     int cdb_len;
     unsigned char * sense;
     int sense_len;
     unsigned char * dxferp;
     int dxfer_len;
     int dxfer_dir;
     int scsi_status;
     int resid;
     int sense_resid;
     int in_err;
     int os_err;
     int transport_err;
 };

 struct sg_pt_base {
     struct sg_pt_osf1_scsi impl;
 };


 /* Returns >= 0 if successful. If error in Unix returns negated errno. */
 int
 scsi_pt_open_device(const char * device_name, int read_only, int verbose)
 {
     int oflags = 0 /* O_NONBLOCK*/ ;

     oflags |= (read_only ? O_RDONLY : O_RDWR);
     return scsi_pt_open_flags(device_name, oflags, verbose);
 }

 /* Similar to scsi_pt_open_device() but takes Unix style open flags OR-ed
  * together. The 'flags' argument is ignored in OSF-1.
  * Returns >= 0 if successful, otherwise returns negated errno. */
 int
 scsi_pt_open_flags(const char * device_name, int flags, int verbose)
 {
     struct osf1_dev_channel *fdchan;
     int fd, k;

     if (NULL == sg_warnings_strm)
         sg_warnings_strm = stderr;

     if (!camopened) {
         camfd = open(cam_dev, O_RDWR, 0);
         if (camfd < 0)
             return -1;
         camopened++;
     }

     // Search table for a free entry
     for (k = 0; k < OSF1_MAXDEV; k++)
         if (! devicetable[k])
             break;

     if (k == OSF1_MAXDEV) {
         if (verbose)
             fprintf(sg_warnings_strm, "too many open devices "
                     "(%d)\n", OSF1_MAXDEV);
         errno=EMFILE;
         return -1;
     }

     fdchan = (struct osf1_dev_channel *)calloc(1,
                                 sizeof(struct osf1_dev_channel));
     if (fdchan == NULL) {
         // errno already set by call to malloc()
         return -1;
     }

     fd = open(device_name, O_RDONLY|O_NONBLOCK);
     if (fd > 0) {
         device_info_t devinfo;
         bzero(&devinfo, sizeof(devinfo));
         if (ioctl(fd, DEVGETINFO, &devinfo) == 0) {
             fdchan->bus = devinfo.v1.businfo.bus.scsi.bus_num;
             fdchan->tgt = devinfo.v1.businfo.bus.scsi.tgt_id;
             fdchan->lun = devinfo.v1.businfo.bus.scsi.lun;
         }
         close (fd);
     } else {
         free(fdchan);
         return -1;
     }

     devicetable[k] = fdchan;
     return k;
 }

 /* Returns 0 if successful. If error in Unix returns negated errno. */
 int
 scsi_pt_close_device(int device_fd)
 {
     struct osf1_dev_channel *fdchan;
     int i;

     if ((device_fd < 0) || (device_fd >= OSF1_MAXDEV)) {
         errno = ENODEV;
         return -1;
     }

     fdchan = devicetable[device_fd];
     if (NULL == fdchan) {
         errno = ENODEV;
         return -1;
     }

     free(fdchan);
     devicetable[device_fd] = NULL;

     for (i = 0; i < OSF1_MAXDEV; i++) {
         if (devicetable[i])
             break;
     }
     if (i == OSF1_MAXDEV) {
         close(camfd);
         camopened = 0;
     }
     return 0;
 }

 struct sg_pt_base *
 construct_scsi_pt_obj()
 {
     struct sg_pt_osf1_scsi * ptp;

     ptp = (struct sg_pt_osf1_scsi *)malloc(sizeof(struct sg_pt_osf1_scsi));
     if (ptp) {
         bzero(ptp, sizeof(struct sg_pt_osf1_scsi));
         ptp->dxfer_dir = CAM_DIR_NONE;
     }
     return (struct sg_pt_base *)ptp;
 }

 void
 destruct_scsi_pt_obj(struct sg_pt_base * vp)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (ptp)
         free(ptp);
 }

 void
 clear_scsi_pt_obj(struct sg_pt_base * vp)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (ptp) {
         bzero(ptp, sizeof(struct sg_pt_osf1_scsi));
         ptp->dxfer_dir = CAM_DIR_NONE;
     }
 }

 void
 set_scsi_pt_cdb(struct sg_pt_base * vp, const unsigned char * cdb,
                 int cdb_len)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (ptp->cdb)
         ++ptp->in_err;
     ptp->cdb = (unsigned char *)cdb;
     ptp->cdb_len = cdb_len;
 }

 void
 set_scsi_pt_sense(struct sg_pt_base * vp, unsigned char * sense,
                   int max_sense_len)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (ptp->sense)
         ++ptp->in_err;
     bzero(sense, max_sense_len);
     ptp->sense = sense;
     ptp->sense_len = max_sense_len;
 }

 /* from device */
 void
 set_scsi_pt_data_in(struct sg_pt_base * vp, unsigned char * dxferp,
                     int dxfer_len)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (ptp->dxferp)
         ++ptp->in_err;
     if (dxfer_len > 0) {
         ptp->dxferp = dxferp;
         ptp->dxfer_len = dxfer_len;
         ptp->dxfer_dir = CAM_DIR_IN;
     }
 }

 /* to device */
 void
 set_scsi_pt_data_out(struct sg_pt_base * vp, const unsigned char * dxferp,
                      int dxfer_len)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (ptp->dxferp)
         ++ptp->in_err;
     if (dxfer_len > 0) {
         ptp->dxferp = (unsigned char *)dxferp;
         ptp->dxfer_len = dxfer_len;
         ptp->dxfer_dir = CAM_DIR_OUT;
     }
 }

 void
 set_scsi_pt_packet_id(struct sg_pt_base * vp, int pack_id)
 {
 }

 void
 set_scsi_pt_tag(struct sg_pt_base * vp, uint64_t tag)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     ++ptp->in_err;
 }

 void
 set_scsi_pt_task_management(struct sg_pt_base * vp, int tmf_code)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     ++ptp->in_err;
 }

 void
 set_scsi_pt_task_attr(struct sg_pt_base * vp, int attrib, int priority)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;

     ++ptp->in_err;
 }

 void
 set_scsi_pt_flags(struct sg_pt_base * objp, int flags)
 {
     /* do nothing, suppress warnings */
     objp = objp;
     flags = flags;
 }

 static int
 release_sim(struct sg_pt_base *vp, int device_fd, int verbose) {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;
     struct osf1_dev_channel *fdchan = devicetable[device_fd];
     UAGT_CAM_CCB uagt;
     CCB_RELSIM relsim;
     int retval;

     if (NULL == sg_warnings_strm)
         sg_warnings_strm = stderr;

     bzero(&uagt, sizeof(uagt));
     bzero(&relsim, sizeof(relsim));

     uagt.uagt_ccb = (CCB_HEADER *) &relsim;
     uagt.uagt_ccblen = sizeof(relsim);

     relsim.cam_ch.cam_ccb_len = sizeof(relsim);
     relsim.cam_ch.cam_func_code = XPT_REL_SIMQ;
     relsim.cam_ch.cam_flags = CAM_DIR_IN | CAM_DIS_CALLBACK;
     relsim.cam_ch.cam_path_id = fdchan->bus;
     relsim.cam_ch.cam_target_id = fdchan->tgt;
     relsim.cam_ch.cam_target_lun = fdchan->lun;

     retval = ioctl(camfd, UAGT_CAM_IO, &uagt);
     if (retval < 0) {
         if (verbose)
             fprintf(sg_warnings_strm, "CAM ioctl error (Release SIM Queue)\n");
     }
     return retval;
 }

 int
 do_scsi_pt(struct sg_pt_base * vp, int device_fd, int time_secs, int verbose)
 {
     struct sg_pt_osf1_scsi * ptp = &vp->impl;
     struct osf1_dev_channel *fdchan;
     int len, retval;
     CCB_SCSIIO ccb;
     UAGT_CAM_CCB uagt;
     unsigned char sensep[ADDL_SENSE_LENGTH];


     if (NULL == sg_warnings_strm)
         sg_warnings_strm = stderr;
     ptp->os_err = 0;
     if (ptp->in_err) {
         if (verbose)
             fprintf(sg_warnings_strm, "Replicated or unused set_scsi_pt...\n");
         return SCSI_PT_DO_BAD_PARAMS;
     }
     if (NULL == ptp->cdb) {
         if (verbose)
             fprintf(sg_warnings_strm, "No command (cdb) given\n");
         return SCSI_PT_DO_BAD_PARAMS;
     }

     if ((device_fd < 0) || (device_fd >= OSF1_MAXDEV)) {
         if (verbose)
             fprintf(sg_warnings_strm, "Bad file descriptor\n");
         ptp->os_err = ENODEV;
         return -ptp->os_err;
     }
     fdchan = devicetable[device_fd];
     if (NULL == fdchan) {
         if (verbose)
             fprintf(sg_warnings_strm, "File descriptor closed??\n");
         ptp->os_err = ENODEV;
         return -ptp->os_err;
     }
     if (0 == camopened) {
         if (verbose)
             fprintf(sg_warnings_strm, "No open CAM device\n");
         return SCSI_PT_DO_BAD_PARAMS;
     }

     bzero(&uagt, sizeof(uagt));
     bzero(&ccb, sizeof(ccb));

     uagt.uagt_ccb = (CCB_HEADER *) &ccb;
     uagt.uagt_ccblen = sizeof(ccb);
     uagt.uagt_snsbuf = ccb.cam_sense_ptr = ptp->sense ? ptp->sense : sensep;
     uagt.uagt_snslen = ccb.cam_sense_len = ptp->sense ? ptp->sense_len :
                                                         sizeof sensep;
     uagt.uagt_buffer = ccb.cam_data_ptr =  ptp->dxferp;
     uagt.uagt_buflen = ccb.cam_dxfer_len = ptp->dxfer_len;

     ccb.cam_timeout = time_secs;
     ccb.cam_ch.my_addr = (CCB_HEADER *) &ccb;
     ccb.cam_ch.cam_ccb_len = sizeof(ccb);
     ccb.cam_ch.cam_func_code = XPT_SCSI_IO;
     ccb.cam_ch.cam_flags = ptp->dxfer_dir;
     ccb.cam_cdb_len = ptp->cdb_len;
     memcpy(ccb.cam_cdb_io.cam_cdb_bytes, ptp->cdb, ptp->cdb_len);
     ccb.cam_ch.cam_path_id = fdchan->bus;
     ccb.cam_ch.cam_target_id = fdchan->tgt;
     ccb.cam_ch.cam_target_lun = fdchan->lun;

     if (ioctl(camfd, UAGT_CAM_IO, &uagt) < 0) {
         if (verbose)
             fprintf(sg_warnings_strm, "CAN I/O Error\n");
         ptp->os_err = EIO;
         return -ptp->os_err;
     }

     if (((ccb.cam_ch.cam_status & CAM_STATUS_MASK) == CAM_REQ_CMP) ||
             ((ccb.cam_ch.cam_status & CAM_STATUS_MASK) == CAM_REQ_CMP_ERR)) {
         ptp->scsi_status = ccb.cam_scsi_status;
         ptp->resid = ccb.cam_resid;
         if (ptp->sense)
             ptp->sense_resid = ccb.cam_sense_resid;
     } else {
         ptp->transport_err = 1;
     }

     /* If the SIM queue is frozen, release SIM queue. */
     if (ccb.cam_ch.cam_status & CAM_SIM_QFRZN)
         release_sim(vp, device_fd, verbose);

     return 0;
 }

 int
 get_scsi_pt_result_category(const struct sg_pt_base * vp)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (ptp->os_err)
         return SCSI_PT_RESULT_OS_ERR;
     else if (ptp->transport_err)
         return SCSI_PT_RESULT_TRANSPORT_ERR;
     else if ((SAM_STAT_CHECK_CONDITION == ptp->scsi_status) ||
              (SAM_STAT_COMMAND_TERMINATED == ptp->scsi_status))
         return SCSI_PT_RESULT_SENSE;
     else if (ptp->scsi_status)
         return SCSI_PT_RESULT_STATUS;
     else
         return SCSI_PT_RESULT_GOOD;
 }

 int
 get_scsi_pt_resid(const struct sg_pt_base * vp)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;

     return ptp->resid;
 }

 int
 get_scsi_pt_status_response(const struct sg_pt_base * vp)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;

     return ptp->scsi_status;
 }

 int
 get_scsi_pt_sense_len(const struct sg_pt_base * vp)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;
     int len;

     len = ptp->sense_len - ptp->sense_resid;
     return (len > 0) ? len : 0;
 }

 int
 get_scsi_pt_duration_ms(const struct sg_pt_base * vp)
 {
     // const struct sg_pt_osf1_scsi * ptp = &vp->impl;

     return -1;
 }

 int
 get_scsi_pt_transport_err(const struct sg_pt_base * vp)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;

     return ptp->transport_err;
 }

 int
 get_scsi_pt_os_err(const struct sg_pt_base * vp)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;

     return ptp->os_err;
 }

 char *
 get_scsi_pt_transport_err_str(const struct sg_pt_base * vp, int max_b_len,
                               char * b)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;

     if (0 == ptp->transport_err) {
         strncpy(b, "no transport error available", max_b_len);
         b[max_b_len - 1] = '\0';
         return b;
     }
     strncpy(b, "no transport error available", max_b_len);
     b[max_b_len - 1] = '\0';
     return b;
 }

 char *
 get_scsi_pt_os_err_str(const struct sg_pt_base * vp, int max_b_len, char * b)
 {
     const struct sg_pt_osf1_scsi * ptp = &vp->impl;
     const char * cp;

     cp = safe_strerror(ptp->os_err);
     strncpy(b, cp, max_b_len);
     if ((int)strlen(cp) >= max_b_len)
         b[max_b_len - 1] = '\0';
     return b;
 }
	/*
	* Copyright (c) 2005-2010 Douglas Gilbert.
	* All rights reserved.
	* Use of this source code is governed by a BSD-style
	* license that can be found in the BSD_LICENSE file.
	*/

	#include <fcntl.h>
	#include <sys/stat.h>
	#include <sys/types.h>
	#include <unistd.h>
	#include <sys/ioctl.h>
	#include <io/common/devgetinfo.h>
	#include <io/common/iotypes.h>
	#include <io/cam/cam.h>
	#include <io/cam/uagt.h>
	#include <io/cam/rzdisk.h>
	#include <io/cam/scsi_opcodes.h>
	#include <io/cam/scsi_all.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#include <errno.h>

	#include "sg_pt.h"
	#include "sg_lib.h"

	/* Changed to use struct sg_pt_base 20070403 */


	#define OSF1_MAXDEV 64

	struct osf1_dev_channel {
	int bus;
	int tgt;
	int lun;
	};

	// Private table of open devices: guaranteed zero on startup since
	// part of static data.
	static struct osf1_dev_channel *devicetable[OSF1_MAXDEV] = {0};
	static char *cam_dev = "/dev/cam";
	static int camfd;
	static int camopened = 0;

	struct sg_pt_osf1_scsi {
	unsigned char * cdb;
	int cdb_len;
	unsigned char * sense;
	int sense_len;
	unsigned char * dxferp;
	int dxfer_len;
	int dxfer_dir;
	int scsi_status;
	int resid;
	int sense_resid;
	int in_err;
	int os_err;
	int transport_err;
	};

	struct sg_pt_base {
	struct sg_pt_osf1_scsi impl;
	};


	/* Returns >= 0 if successful. If error in Unix returns negated errno. */
	int
	scsi_pt_open_device(const char * device_name, int read_only, int verbose)
	{
	int oflags = 0 /* O_NONBLOCK*/ ;

	oflags \|= (read_only ? O_RDONLY : O_RDWR);
	return scsi_pt_open_flags(device_name, oflags, verbose);
	}

	/* Similar to scsi_pt_open_device() but takes Unix style open flags OR-ed
	* together. The 'flags' argument is ignored in OSF-1.
	* Returns >= 0 if successful, otherwise returns negated errno. */
	int
	scsi_pt_open_flags(const char * device_name, int flags, int verbose)
	{
	struct osf1_dev_channel *fdchan;
	int fd, k;

	if (NULL == sg_warnings_strm)
	sg_warnings_strm = stderr;

	if (!camopened) {
	camfd = open(cam_dev, O_RDWR, 0);
	if (camfd < 0)
	return -1;
	camopened++;
	}

	// Search table for a free entry
	for (k = 0; k < OSF1_MAXDEV; k++)
	if (! devicetable[k])
	break;

	if (k == OSF1_MAXDEV) {
	if (verbose)
	fprintf(sg_warnings_strm, "too many open devices "
	"(%d)\n", OSF1_MAXDEV);
	errno=EMFILE;
	return -1;
	}

	fdchan = (struct osf1_dev_channel *)calloc(1,
	sizeof(struct osf1_dev_channel));
	if (fdchan == NULL) {
	// errno already set by call to malloc()
	return -1;
	}

	fd = open(device_name, O_RDONLY\|O_NONBLOCK);
	if (fd > 0) {
	device_info_t devinfo;
	bzero(&devinfo, sizeof(devinfo));
	if (ioctl(fd, DEVGETINFO, &devinfo) == 0) {
	fdchan->bus = devinfo.v1.businfo.bus.scsi.bus_num;
	fdchan->tgt = devinfo.v1.businfo.bus.scsi.tgt_id;
	fdchan->lun = devinfo.v1.businfo.bus.scsi.lun;
	}
	close (fd);
	} else {
	free(fdchan);
	return -1;
	}

	devicetable[k] = fdchan;
	return k;
	}

	/* Returns 0 if successful. If error in Unix returns negated errno. */
	int
	scsi_pt_close_device(int device_fd)
	{
	struct osf1_dev_channel *fdchan;
	int i;

	if ((device_fd < 0) \|\| (device_fd >= OSF1_MAXDEV)) {
	errno = ENODEV;
	return -1;
	}

	fdchan = devicetable[device_fd];
	if (NULL == fdchan) {
	errno = ENODEV;
	return -1;
	}

	free(fdchan);
	devicetable[device_fd] = NULL;

	for (i = 0; i < OSF1_MAXDEV; i++) {
	if (devicetable[i])
	break;
	}
	if (i == OSF1_MAXDEV) {
	close(camfd);
	camopened = 0;
	}
	return 0;
	}

	struct sg_pt_base *
	construct_scsi_pt_obj()
	{
	struct sg_pt_osf1_scsi * ptp;

	ptp = (struct sg_pt_osf1_scsi *)malloc(sizeof(struct sg_pt_osf1_scsi));
	if (ptp) {
	bzero(ptp, sizeof(struct sg_pt_osf1_scsi));
	ptp->dxfer_dir = CAM_DIR_NONE;
	}
	return (struct sg_pt_base *)ptp;
	}

	void
	destruct_scsi_pt_obj(struct sg_pt_base * vp)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (ptp)
	free(ptp);
	}

	void
	clear_scsi_pt_obj(struct sg_pt_base * vp)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (ptp) {
	bzero(ptp, sizeof(struct sg_pt_osf1_scsi));
	ptp->dxfer_dir = CAM_DIR_NONE;
	}
	}

	void
	set_scsi_pt_cdb(struct sg_pt_base * vp, const unsigned char * cdb,
	int cdb_len)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (ptp->cdb)
	++ptp->in_err;
	ptp->cdb = (unsigned char *)cdb;
	ptp->cdb_len = cdb_len;
	}

	void
	set_scsi_pt_sense(struct sg_pt_base * vp, unsigned char * sense,
	int max_sense_len)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (ptp->sense)
	++ptp->in_err;
	bzero(sense, max_sense_len);
	ptp->sense = sense;
	ptp->sense_len = max_sense_len;
	}

	/* from device */
	void
	set_scsi_pt_data_in(struct sg_pt_base * vp, unsigned char * dxferp,
	int dxfer_len)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (ptp->dxferp)
	++ptp->in_err;
	if (dxfer_len > 0) {
	ptp->dxferp = dxferp;
	ptp->dxfer_len = dxfer_len;
	ptp->dxfer_dir = CAM_DIR_IN;
	}
	}

	/* to device */
	void
	set_scsi_pt_data_out(struct sg_pt_base * vp, const unsigned char * dxferp,
	int dxfer_len)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (ptp->dxferp)
	++ptp->in_err;
	if (dxfer_len > 0) {
	ptp->dxferp = (unsigned char *)dxferp;
	ptp->dxfer_len = dxfer_len;
	ptp->dxfer_dir = CAM_DIR_OUT;
	}
	}

	void
	set_scsi_pt_packet_id(struct sg_pt_base * vp, int pack_id)
	{
	}

	void
	set_scsi_pt_tag(struct sg_pt_base * vp, uint64_t tag)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	++ptp->in_err;
	}

	void
	set_scsi_pt_task_management(struct sg_pt_base * vp, int tmf_code)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	++ptp->in_err;
	}

	void
	set_scsi_pt_task_attr(struct sg_pt_base * vp, int attrib, int priority)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;

	++ptp->in_err;
	}

	void
	set_scsi_pt_flags(struct sg_pt_base * objp, int flags)
	{
	/* do nothing, suppress warnings */
	objp = objp;
	flags = flags;
	}

	static int
	release_sim(struct sg_pt_base *vp, int device_fd, int verbose) {
	struct sg_pt_osf1_scsi * ptp = &vp->impl;
	struct osf1_dev_channel *fdchan = devicetable[device_fd];
	UAGT_CAM_CCB uagt;
	CCB_RELSIM relsim;
	int retval;

	if (NULL == sg_warnings_strm)
	sg_warnings_strm = stderr;

	bzero(&uagt, sizeof(uagt));
	bzero(&relsim, sizeof(relsim));

	uagt.uagt_ccb = (CCB_HEADER *) &relsim;
	uagt.uagt_ccblen = sizeof(relsim);

	relsim.cam_ch.cam_ccb_len = sizeof(relsim);
	relsim.cam_ch.cam_func_code = XPT_REL_SIMQ;
	relsim.cam_ch.cam_flags = CAM_DIR_IN \| CAM_DIS_CALLBACK;
	relsim.cam_ch.cam_path_id = fdchan->bus;
	relsim.cam_ch.cam_target_id = fdchan->tgt;
	relsim.cam_ch.cam_target_lun = fdchan->lun;

	retval = ioctl(camfd, UAGT_CAM_IO, &uagt);
	if (retval < 0) {
	if (verbose)
	fprintf(sg_warnings_strm, "CAM ioctl error (Release SIM Queue)\n");
	}
	return retval;
	}

	int
	do_scsi_pt(struct sg_pt_base * vp, int device_fd, int time_secs, int verbose)
	{
	struct sg_pt_osf1_scsi * ptp = &vp->impl;
	struct osf1_dev_channel *fdchan;
	int len, retval;
	CCB_SCSIIO ccb;
	UAGT_CAM_CCB uagt;
	unsigned char sensep[ADDL_SENSE_LENGTH];


	if (NULL == sg_warnings_strm)
	sg_warnings_strm = stderr;
	ptp->os_err = 0;
	if (ptp->in_err) {
	if (verbose)
	fprintf(sg_warnings_strm, "Replicated or unused set_scsi_pt...\n");
	return SCSI_PT_DO_BAD_PARAMS;
	}
	if (NULL == ptp->cdb) {
	if (verbose)
	fprintf(sg_warnings_strm, "No command (cdb) given\n");
	return SCSI_PT_DO_BAD_PARAMS;
	}

	if ((device_fd < 0) \|\| (device_fd >= OSF1_MAXDEV)) {
	if (verbose)
	fprintf(sg_warnings_strm, "Bad file descriptor\n");
	ptp->os_err = ENODEV;
	return -ptp->os_err;
	}
	fdchan = devicetable[device_fd];
	if (NULL == fdchan) {
	if (verbose)
	fprintf(sg_warnings_strm, "File descriptor closed??\n");
	ptp->os_err = ENODEV;
	return -ptp->os_err;
	}
	if (0 == camopened) {
	if (verbose)
	fprintf(sg_warnings_strm, "No open CAM device\n");
	return SCSI_PT_DO_BAD_PARAMS;
	}

	bzero(&uagt, sizeof(uagt));
	bzero(&ccb, sizeof(ccb));

	uagt.uagt_ccb = (CCB_HEADER *) &ccb;
	uagt.uagt_ccblen = sizeof(ccb);
	uagt.uagt_snsbuf = ccb.cam_sense_ptr = ptp->sense ? ptp->sense : sensep;
	uagt.uagt_snslen = ccb.cam_sense_len = ptp->sense ? ptp->sense_len :
	sizeof sensep;
	uagt.uagt_buffer = ccb.cam_data_ptr = ptp->dxferp;
	uagt.uagt_buflen = ccb.cam_dxfer_len = ptp->dxfer_len;

	ccb.cam_timeout = time_secs;
	ccb.cam_ch.my_addr = (CCB_HEADER *) &ccb;
	ccb.cam_ch.cam_ccb_len = sizeof(ccb);
	ccb.cam_ch.cam_func_code = XPT_SCSI_IO;
	ccb.cam_ch.cam_flags = ptp->dxfer_dir;
	ccb.cam_cdb_len = ptp->cdb_len;
	memcpy(ccb.cam_cdb_io.cam_cdb_bytes, ptp->cdb, ptp->cdb_len);
	ccb.cam_ch.cam_path_id = fdchan->bus;
	ccb.cam_ch.cam_target_id = fdchan->tgt;
	ccb.cam_ch.cam_target_lun = fdchan->lun;

	if (ioctl(camfd, UAGT_CAM_IO, &uagt) < 0) {
	if (verbose)
	fprintf(sg_warnings_strm, "CAN I/O Error\n");
	ptp->os_err = EIO;
	return -ptp->os_err;
	}

	if (((ccb.cam_ch.cam_status & CAM_STATUS_MASK) == CAM_REQ_CMP) \|\|
	((ccb.cam_ch.cam_status & CAM_STATUS_MASK) == CAM_REQ_CMP_ERR)) {
	ptp->scsi_status = ccb.cam_scsi_status;
	ptp->resid = ccb.cam_resid;
	if (ptp->sense)
	ptp->sense_resid = ccb.cam_sense_resid;
	} else {
	ptp->transport_err = 1;
	}

	/* If the SIM queue is frozen, release SIM queue. */
	if (ccb.cam_ch.cam_status & CAM_SIM_QFRZN)
	release_sim(vp, device_fd, verbose);

	return 0;
	}

	int
	get_scsi_pt_result_category(const struct sg_pt_base * vp)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (ptp->os_err)
	return SCSI_PT_RESULT_OS_ERR;
	else if (ptp->transport_err)
	return SCSI_PT_RESULT_TRANSPORT_ERR;
	else if ((SAM_STAT_CHECK_CONDITION == ptp->scsi_status) \|\|
	(SAM_STAT_COMMAND_TERMINATED == ptp->scsi_status))
	return SCSI_PT_RESULT_SENSE;
	else if (ptp->scsi_status)
	return SCSI_PT_RESULT_STATUS;
	else
	return SCSI_PT_RESULT_GOOD;
	}

	int
	get_scsi_pt_resid(const struct sg_pt_base * vp)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;

	return ptp->resid;
	}

	int
	get_scsi_pt_status_response(const struct sg_pt_base * vp)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;

	return ptp->scsi_status;
	}

	int
	get_scsi_pt_sense_len(const struct sg_pt_base * vp)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;
	int len;

	len = ptp->sense_len - ptp->sense_resid;
	return (len > 0) ? len : 0;
	}

	int
	get_scsi_pt_duration_ms(const struct sg_pt_base * vp)
	{
	// const struct sg_pt_osf1_scsi * ptp = &vp->impl;

	return -1;
	}

	int
	get_scsi_pt_transport_err(const struct sg_pt_base * vp)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;

	return ptp->transport_err;
	}

	int
	get_scsi_pt_os_err(const struct sg_pt_base * vp)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;

	return ptp->os_err;
	}

	char *
	get_scsi_pt_transport_err_str(const struct sg_pt_base * vp, int max_b_len,
	char * b)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;

	if (0 == ptp->transport_err) {
	strncpy(b, "no transport error available", max_b_len);
	b[max_b_len - 1] = '\0';
	return b;
	}
	strncpy(b, "no transport error available", max_b_len);
	b[max_b_len - 1] = '\0';
	return b;
	}

	char *
	get_scsi_pt_os_err_str(const struct sg_pt_base * vp, int max_b_len, char * b)
	{
	const struct sg_pt_osf1_scsi * ptp = &vp->impl;
	const char * cp;

	cp = safe_strerror(ptp->os_err);
	strncpy(b, cp, max_b_len);
	if ((int)strlen(cp) >= max_b_len)
	b[max_b_len - 1] = '\0';
	return b;
	}