kopia lustrzana https://gitlab.com/sane-project/backends
527 wiersze
23 KiB
C
527 wiersze
23 KiB
C
/* sane - Scanner Access Now Easy.
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Copyright (C) 1996, 1997 David Mosberger-Tang
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This file is part of the SANE package.
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License as
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published by the Free Software Foundation; either version 2 of the
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License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <https://www.gnu.org/licenses/>.
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As a special exception, the authors of SANE give permission for
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additional uses of the libraries contained in this release of SANE.
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The exception is that, if you link a SANE library with other files
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to produce an executable, this does not by itself cause the
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resulting executable to be covered by the GNU General Public
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License. Your use of that executable is in no way restricted on
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account of linking the SANE library code into it.
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This exception does not, however, invalidate any other reasons why
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the executable file might be covered by the GNU General Public
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License.
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If you submit changes to SANE to the maintainers to be included in
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a subsequent release, you agree by submitting the changes that
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those changes may be distributed with this exception intact.
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If you write modifications of your own for SANE, it is your choice
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whether to permit this exception to apply to your modifications.
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If you do not wish that, delete this exception notice.
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This file defines a server for Apollo Domain/OS systems. It does all
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of the scsi_$ calls that are needed for SANE. This is necessary because
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Domain/OS will not allow a child process to access a parent's SCSI
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device. The interface is through a common, mapped area. Mutex locks
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are used to prevent concurrency problems, and eventcounts are used to
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notify a waiting process that its request has completed.
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This program is intended to support only one device at a time,
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although multiple instances of this program may run concurrently. It is
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intended that this program be forked/execd by a SANE application, and
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that it will exit when the application exits.
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Upon startup, the program is invoked with the path to an object that
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needs to be mapped for communication. The parent process will have
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already initialized the 'public' eventcounts and locks, and will be
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waiting for the ResultReady eventcount to be incremented. After
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initialization, the server will increment this eventcount, and wait for
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an incoming request, which is signified by the CommandAvailable
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eventcount. This EC will be incremented after another process has
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filled in the parameter area.
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DBG levels:
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0 Error - always printed.
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1 Basic monitor - print entry to main functions, or errors that are
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normally suppressed because they are reported at a higher level.
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2 Medium monitor - show intermediate steps in functions
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3 Detailed monitor - if its there, print it
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*/
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#include <assert.h>
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#include <ctype.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <apollo/base.h>
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#include <apollo/ec2.h>
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#include <apollo/error.h>
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#include <apollo/fault.h>
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#include <apollo/ms.h>
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#include <apollo/mutex.h>
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#include <apollo/pfm.h>
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#include <apollo/scsi.h>
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#include "../include/sane/config.h"
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#include "../include/sane/sanei_scsi.h"
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#include "../include/sane/sanei_debug.h"
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#include "sanei_DomainOS.h"
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/* Timeout period for SCSI wait, in milliseconds.
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We are using 100 seconds here. */
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#define DomainScsiTimeout 100000
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/* Communication Area pointer */
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struct DomainServerCommon *com;
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/* Handle for fault handler */
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pfm_$fh_handle_t FaultHandle;
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static struct
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{
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void *DomainSCSIPtr; /* Pointer to the data block for this device */
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void *DomainSensePtr; /* Pointer to the sense area for this device */
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u_int in_use : 1; /* is this DomainFdInfo in use? */
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u_int fake_fd : 1; /* is this a fake file descriptor? */
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scsi_$handle_t scsi_handle; /* SCSI handle */
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scsi_$operation_id_t op_id; /* op_id of current request */
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} *DomainFdInfo;
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/* This function is called error might have occurred, but it would be one that I
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don't know how to handle, or never expect to happen. */
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static void DomainErrorCheck(status_$t status, const char *message)
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{
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char *subsystem, *module, *code;
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short subsystem_length, module_length, code_length;
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if (status.all)
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{
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DBG(0, "Unrecoverable Domain/OS Error 0x%08x: %s\n", status.all, message);
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error_$find_text(status, &subsystem, &subsystem_length, &module, &module_length, &code, &code_length);
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if (subsystem_length && module_length && code_length)
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DBG(0, "%.*s (%.*s/%.*s)\n", code_length, code, subsystem_length, subsystem, module_length, module);
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exit(EXIT_FAILURE);
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}
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}
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/* This function is the fault handler for the server. Currently, it only
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handles asynchronous faults. It always returns to the faulting code, but
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it disables the handler, so that the server can be killed if the parent is
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unable to do so. */
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pfm_$fh_func_val_t FaultHandler(pfm_$fault_rec_t *FaultStatusPtr)
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{
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status_$t status;
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DBG(1, "In fault handler, status is %08x\n", FaultStatusPtr->status.all);
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switch (FaultStatusPtr->status.all)
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{
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case fault_$quit:
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pfm_$release_fault_handler(FaultHandle, &status);
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DomainErrorCheck(status, "Can't release fault handler");
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return pfm_$return_to_faulting_code;
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default:
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DBG(0, "Unrecognized fault type %08x, exiting\n", FaultStatusPtr->status.all);
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exit(EXIT_FAILURE);
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}
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}
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static void DomainSCSIOpen(void)
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{
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static int num_alloced = 0;
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int fd;
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scsi_$handle_t scsi_handle;
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pinteger len;
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void *DataBasePtr;
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/* Find fake fd. */
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for (fd = 0; fd < num_alloced; ++fd)
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if (!DomainFdInfo[fd].in_use)
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break;
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/* Acquire the device */
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DBG(1, "DomainSCSIOpen: dev='%s', fd=%d\n", com->open_path, fd);
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len = strlen(com->open_path);
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scsi_$acquire((char *)com->open_path, len, &scsi_handle, &com->CommandStatus);
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if (com->CommandStatus.all != status_$ok)
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{
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/* we have a failure, return an error code, and generate debug output */
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DBG(1, "DomainSCSIOpen: acquire failed, Domain/OS status is %08x\n", com->CommandStatus.all);
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error_$print(com->CommandStatus);
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return;
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}
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else
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{
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/* device acquired, setup buffers and buffer pointers */
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DBG(2, "DomainSCSIOpen: acquire OK, handle is %x\n", scsi_handle);
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/* Create/map the data area */
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tmpnam(com->open_path);
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DBG(2, "DomainSCSIOpen: Data block name will be '%s'\n", com->open_path);
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DataBasePtr = ms_$crmapl(com->open_path, strlen(com->open_path), 0, DomainMaxDataSize + DomainSenseSize, ms_$cowriters, &com->CommandStatus);
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DomainErrorCheck(com->CommandStatus, "Creating Data Area");
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assert((((int)DataBasePtr) & 0x3ff) == 0); /* Relies on Domain/OS mapping new objects on page boundary */
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DBG(2, "Data Buffer block created at %p, length = 0x%lx\n", DataBasePtr, DomainMaxDataSize + DomainSenseSize);
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/* Wire the buffer */
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scsi_$wire(scsi_handle, (void *)DataBasePtr, DomainMaxDataSize + DomainSenseSize, &com->CommandStatus);
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if (com->CommandStatus.all == status_$ok)
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{
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/* success, indicate status */
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DBG(2, "Buffer wire was successful\n");
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}
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else
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{
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/* failure, print detail and return code */
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DBG(1, "Buffer wire failed, Domain/OS status is %08x\n", com->CommandStatus.all);
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error_$print(com->CommandStatus);
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return;
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}
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}
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if (fd >= num_alloced)
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{
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size_t new_size, old_size;
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old_size = num_alloced * sizeof (DomainFdInfo[0]);
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num_alloced = fd + 8;
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new_size = num_alloced * sizeof (DomainFdInfo[0]);
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if (DomainFdInfo)
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DomainFdInfo = realloc (DomainFdInfo, new_size);
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else
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DomainFdInfo = malloc (new_size);
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memset ((char *) DomainFdInfo + old_size, 0, new_size - old_size);
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assert(DomainFdInfo);
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}
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DomainFdInfo[fd].in_use = 1;
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DomainFdInfo[fd].scsi_handle = scsi_handle;
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DomainFdInfo[fd].DomainSCSIPtr = DataBasePtr;
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DomainFdInfo[fd].DomainSensePtr = ((char *)DataBasePtr) + DomainMaxDataSize;
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com->fd = fd;
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}
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static void DomainSCSIClose(void)
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{
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DomainFdInfo[com->fd].in_use = 0;
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DBG(1, "sanei_scsi_close: fd=%d\n", com->fd);
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/* Unwire the buffer */
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scsi_$unwire(DomainFdInfo[com->fd].scsi_handle, DomainFdInfo[com->fd].DomainSCSIPtr, DomainMaxDataSize + DomainSenseSize, true, &com->CommandStatus);
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DomainErrorCheck(com->CommandStatus, "Unwiring SCSI buffers");
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/* Release the device */
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scsi_$release(DomainFdInfo[com->fd].scsi_handle, &com->CommandStatus);
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DomainErrorCheck(com->CommandStatus, "Releasing device");
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/* Unmap the buffer area */
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ms_$unmap(DomainFdInfo[com->fd].DomainSCSIPtr, DomainMaxDataSize + DomainSenseSize, &com->CommandStatus);
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DomainErrorCheck(com->CommandStatus, "Unmapping device data area");
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}
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/* I have never seen this called, and I'm not sure what to do with it, so I
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guarantee that it will generate a fault, and I can add support for it. */
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static void DomainSCSIFlushAll(void)
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{
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status_$t status;
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DBG(1, "DomainSCSIFlushAll: ()\n");
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DBG(0, "Error - unimplemented feature in module" "BACKEND_NAME");
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assert(1==0);
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}
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/* This function must only be called from DomainSCSIEnter. The current
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server architecture requires that the Wait immediately follow the Enter
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command. */
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static void DomainSCSIWait(void)
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{
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int count;
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char *ascii_wait_status, *ascii_op_status;
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pinteger return_count;
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scsi_$op_status_t status_list[1];
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scsi_$wait_index_t wait_index;
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/* wait for the command completion */
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wait_index = scsi_$wait(DomainFdInfo[com->fd].scsi_handle, DomainScsiTimeout, true, DomainFdInfo[com->fd].op_id, 1, status_list, &return_count, &com->CommandStatus);
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DBG(2, " scsi_$wait returned status = %08x\n", com->CommandStatus.all);
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if (com->CommandStatus.all == status_$ok)
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{
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switch (wait_index)
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{
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case scsi_device_advance: ascii_wait_status = "scsi_device_advance"; break;
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case scsi_timeout: ascii_wait_status = "scsi_timeout"; break;
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case scsi_async_fault: ascii_wait_status = "scsi_async_fault"; break;
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default: ascii_wait_status = "unknown"; break;
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}
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DBG(2, " scsi_$wait status is %s, return_count is %d\n", ascii_wait_status, return_count);
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if (wait_index != scsi_device_advance)
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{
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DBG(1, "Error - SCSI timeout, or async fault\n");
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com->CommandStatus.all = scsi_$operation_timeout;
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}
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else for (count = 0; count < return_count; count++)
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{
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switch (status_list[count].op_status)
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{
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case scsi_good_status: ascii_op_status = "scsi_good_status"; break;
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case scsi_check_condition: ascii_op_status = "scsi_check_condition"; break;
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case scsi_condition_met: ascii_op_status = "scsi_condition_met"; break;
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case scsi_rsv1: ascii_op_status = "scsi_rsv1"; break;
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case scsi_busy: ascii_op_status = "scsi_busy"; break;
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case scsi_rsv2: ascii_op_status = "scsi_rsv2"; break;
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case scsi_rsv3: ascii_op_status = "scsi_rsv3"; break;
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case scsi_rsv4: ascii_op_status = "scsi_rsv4"; break;
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case scsi_intermediate_good: ascii_op_status = "scsi_intermediate_good"; break;
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case scsi_rsv5: ascii_op_status = "scsi_rsv5"; break;
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case scsi_intermediate_condition_met: ascii_op_status = "scsi_intermediate_condition_met"; break;
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case scsi_rsv6: ascii_op_status = "scsi_rsv6"; break;
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case scsi_reservation_conflict: ascii_op_status = "scsi_reservation_conflict"; break;
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case scsi_rsv7: ascii_op_status = "scsi_rsv7"; break;
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case scsi_rsv8: ascii_op_status = "scsi_rsv8"; break;
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case scsi_rsv9: ascii_op_status = "scsi_rsv9"; break;
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case scsi_undefined_status: ascii_op_status = "scsi_undefined_status"; break;
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default: ascii_op_status = "unknown"; break;
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}
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DBG(2, " list[%d]: op=%x cmd_status=%08x, status=%s\n", count, status_list[count].op, status_list[count].cmd_status.all, ascii_op_status);
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switch (status_list[count].cmd_status.all)
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{
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case status_$ok:
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switch (status_list[count].op_status)
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{
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case scsi_good_status:
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break;
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case scsi_busy:
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com->CommandStatus.all = status_$ok | 0x80000000;
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com->SCSIStatus = scsi_busy;
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break;
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case scsi_check_condition:
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{
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static unsigned char scanner_sense_cdb[] = {3, 0, 0, 0, DomainSenseSize, 0};
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static scsi_$cdb_t sense_cdb;
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static linteger sense_cdb_size;
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static scsi_$operation_id_t sense_op_id;
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static status_$t sense_status;
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static pinteger sense_return_count;
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static int temp;
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/* Issue the sense command (wire, issue, wait, unwire */
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sense_cdb_size = sizeof(scanner_sense_cdb);
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memcpy(&sense_cdb, scanner_sense_cdb, sense_cdb_size);
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scsi_$do_command_2(DomainFdInfo[com->fd].scsi_handle, sense_cdb, sense_cdb_size, DomainFdInfo[com->fd].DomainSensePtr, DomainSenseSize, scsi_read, &sense_op_id, &sense_status);
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DomainErrorCheck(sense_status, "Executing sense command");
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scsi_$wait(DomainFdInfo[com->fd].scsi_handle, DomainScsiTimeout, true, sense_op_id, 1, status_list, &sense_return_count, &sense_status);
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/* The following debug output is scanner specific */
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DBG(2, "Sense information: Error code=%02x, ASC=%02x, ASCQ=%02x\n", ((u_char *)DomainFdInfo[com->fd].DomainSensePtr)[0], ((char *)DomainFdInfo[com->fd].DomainSensePtr)[0xc], ((char *)DomainFdInfo[com->fd].DomainSensePtr)[0xd]);
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DBG(2, " Sense dump:\n");
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for (temp = 0; temp < DomainSenseSize; temp++)
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DBG(2, " %02x", ((u_char *)DomainFdInfo[com->fd].DomainSensePtr)[temp]);
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DBG(2, "\n");
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/* see if buffer underrun - ILI/Valid are set, and command was a read */
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/* Warning - this might be UMAX specific */
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if ((((char *)DomainFdInfo[com->fd].DomainSensePtr)[0] == 0xf0) && (((char *)DomainFdInfo[com->fd].DomainSensePtr)[2] & 0x20) && (com->cdb.g0.cmd == 0x28))
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{
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/* Warning - the following code is specific to endianness and int size */
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/* Its also very ugly */
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DBG(2, "Shortening destination length by %x bytes\n", *(int *)(((char *)DomainFdInfo[com->fd].DomainSensePtr)+3));
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com->dst_size -= *(int *)(((char *)DomainFdInfo[com->fd].DomainSensePtr)+3);
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DBG(2, "Final dest size is %x\n", com->dst_size);
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}
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else
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{
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/* Set this status so that the sense handler can be called */
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com->CommandStatus.all = status_$ok | 0x80000000;
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com->SCSIStatus = scsi_check_condition;
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}
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}
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break;
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default:
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/* I fault out in this case because I want to know about this error,
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and this guarantees that it will get attention. */
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DBG(0, "Unrecoverable Domain/OS scsi handler error: status=%08x\n", status_list[count].op_status);
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exit(EXIT_FAILURE);
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}
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break;
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/* Handle recognized error conditions by copying the error code over */
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case scsi_$operation_timeout:
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case scsi_$dma_underrun: /* received by some backend code */
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case scsi_$hdwr_failure: /* received when both scanners were active */
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com->CommandStatus = status_list[count].cmd_status;
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break;
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default:
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DBG(0, "Unrecoverable DomainOS scsi handler error: status=%08x\n", status_list[count].cmd_status.all);
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error_$print(status_list[count].cmd_status);
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exit(EXIT_FAILURE);
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}
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}
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/* Dump the buffer contents */
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if (com->direction == scsi_read)
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{
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DBG(3, "first words of buffer are:\n");
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for (return_count = 0; return_count < com->dst_size; return_count++)
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DBG(3, "%02X%c", ((unsigned char *)DomainFdInfo[com->fd].DomainSCSIPtr)[return_count], (return_count % 16) == 15 ? '\n' : ' ');
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DBG(3, "\n");
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}
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}
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else
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{
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/* scsi_$wait failed */
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DBG(1, "scsi_$wait failed, status is %08x\n", com->CommandStatus.all);
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}
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}
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static void DomainSCSIEnter(void)
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{
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static int count;
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/* Give some debug info */
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DBG(1, "Entering DomainSCSIEnter, fd=%d, opcode=%02X\n", com->fd, com->cdb.all[0]);
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DBG(2, " CDB Contents: ");
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for (count = 0; count < com->cdb_size; count++)
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DBG(2, " %02X", com->cdb.all[count]);
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DBG(2, "\n");
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DBG(2, "Buffer address is 0x%08x\n", DomainFdInfo[com->fd].DomainSCSIPtr);
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DBG(2, "Buffer size is %x\n", com->buf_size);
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DBG(2, "Direction is %s\n", (com->direction == scsi_read) ? "READ" : "WRITE");
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/* now queue the command */
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scsi_$do_command_2(DomainFdInfo[com->fd].scsi_handle, com->cdb, com->cdb_size, DomainFdInfo[com->fd].DomainSCSIPtr, com->buf_size, com->direction, &DomainFdInfo[com->fd].op_id, &com->CommandStatus);
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if (com->CommandStatus.all == status_$ok)
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{
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/* success, indicate status */
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DBG(2, " scsi_$do_command_2 was successful, op_id is %x\n", DomainFdInfo[com->fd].op_id);
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|
|
/* If we supported multiple outstanding requests for one device, this would be
|
|
a good breakpoint. We would store the op_id in a private place, and construct
|
|
a queue for each device. This complicates things, and SANE doesn't seem to need
|
|
it, so it won't be implemented. The current server architecture does the wait
|
|
automatically, and status for the entire operation is returned. This means that
|
|
the sanei_scsi_req_enter and sanei_scsi_req_wait calls don't make sense, and
|
|
should generate an error. */
|
|
DomainSCSIWait();
|
|
}
|
|
else
|
|
{
|
|
/* failure, print detail and return code */
|
|
DBG(1, " scsi_$do_command_2 failed, status is %08x\n", com->CommandStatus.all);
|
|
}
|
|
}
|
|
|
|
|
|
/* This function is not currently used. */
|
|
static void DomainSCSIReqWait(void)
|
|
{
|
|
DBG(1, "sanei_scsi_req_wait: (id=%p)\n", NULL);
|
|
return;
|
|
}
|
|
|
|
|
|
/* Startup the server */
|
|
static void sanei_DomainOS_init(char *path)
|
|
{
|
|
int done, index;
|
|
long CommandTriggerValue;
|
|
ec2_$ptr_t CommandAvailablePtr[1];
|
|
status_$t status;
|
|
unsigned long length_mapped;
|
|
|
|
DBG(1, "Starting Domain SANE Server, common area path = '%s'\n", path);
|
|
com = ms_$mapl(path, strlen(path), 0, sizeof(struct DomainServerCommon), ms_$cowriters, ms_$wr, true, &length_mapped, &status);
|
|
DomainErrorCheck(status, "Can't open common area");
|
|
if (length_mapped < sizeof(struct DomainServerCommon))
|
|
{
|
|
DBG(0, "Error - can't open common area '%s' to required length\n", path);
|
|
DBG(0, " Required length = %lx, returned length = %lx\n", sizeof(struct DomainServerCommon), length_mapped);
|
|
exit(EXIT_FAILURE);
|
|
}
|
|
/* Make the file temporary, so it will disappear when it is closed */
|
|
ms_$mk_temporary(com, &status);
|
|
DomainErrorCheck(status, "Can't make common file temporary");
|
|
DBG(2, "Domain Server common area mapped, length is %lx\n", length_mapped);
|
|
/* The communication area is open, give the initial response */
|
|
ec2_$advance(&com->ResultReady, &status);
|
|
DomainErrorCheck(status, "Can't advance ResultReady EC after startup");
|
|
/* Enter the command loop */
|
|
CommandAvailablePtr[0] = &com->CommandAvailable;
|
|
CommandTriggerValue = ec2_$read(com->CommandAvailable) + 1;
|
|
/* Inhibit asynchronous faults */
|
|
/* pfm_$inhibit();*/
|
|
/* Establish the fault handler */
|
|
FaultHandle = pfm_$establish_fault_handler(pfm_$all_faults, 0, FaultHandler, &status);
|
|
DomainErrorCheck(status, "Can't establish fault handler");
|
|
done = 0;
|
|
do
|
|
{
|
|
/* Wait for the command */
|
|
DBG(2, "Waiting for incoming command\n");
|
|
do
|
|
{
|
|
index = ec2_$wait_svc(CommandAvailablePtr, &CommandTriggerValue, 1, &status);
|
|
}
|
|
while (status.all == ec2_$wait_quit);
|
|
DomainErrorCheck(status, "Error waiting on CommandAvailable EC");
|
|
assert (index == 1);
|
|
/* Get the trigger value for next time - this avoids a race/deadlock */
|
|
CommandTriggerValue = ec2_$read(com->CommandAvailable) + 1;
|
|
/* decode/execute the command */
|
|
DBG(2, "Received a command - opcode is %x\n", com->opcode);
|
|
switch(com->opcode)
|
|
{
|
|
case Open:
|
|
DomainSCSIOpen();
|
|
ec2_$advance(&com->CommandAccepted, &status);
|
|
DomainErrorCheck(status, "Can't advance CommandAccepted EC on open");
|
|
break;
|
|
case Close:
|
|
DomainSCSIClose();
|
|
ec2_$advance(&com->CommandAccepted, &status);
|
|
DomainErrorCheck(status, "Can't advance CommandAccepted EC on close");
|
|
break;
|
|
case Enter:
|
|
DomainSCSIEnter();
|
|
ec2_$advance(&com->CommandAccepted, &status);
|
|
DomainErrorCheck(status, "Can't advance CommandAccepted EC on enter");
|
|
break;
|
|
case Exit:
|
|
done = 1;
|
|
/* This lets the parent know that the command was accepted. It can be
|
|
used to avoid sending a signal. */
|
|
ec2_$advance(&com->CommandAccepted, &status);
|
|
DomainErrorCheck(status, "Can't advance CommandAccepted EC on exit");
|
|
break;
|
|
default:
|
|
DBG(1, "Invalid command %x received\n", com->opcode);
|
|
}
|
|
DBG(2, "Command processing complete\n");
|
|
}
|
|
while (!done);
|
|
/* This would be a good place to close all devices, but for now we'll assume
|
|
they have already been closed by a well-behaved program */
|
|
/* Unmap the common area */
|
|
ms_$unmap(com, sizeof(struct DomainServerCommon), &status);
|
|
DomainErrorCheck(status, "Error unmapping common area");
|
|
DBG(1, "Exiting Domain SANE Server\n");
|
|
/* pfm_$enable();*/
|
|
exit(EXIT_SUCCESS);
|
|
}
|