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  • Finding out why Dell Controler is Degraded

    - by Kyle Brandt
    I installed open manage on a couple of my PE 2950s for snmp monitoring of the RAID. All the checks seem to come back okay except for controllerState: [root@aMachine ~]# snmpwalk -v 2c -c bestNotToPostPasswords myMachine -m +StorageManagement-MIB controllerstate StorageManagement-MIB::controllerState.1 = INTEGER: degraded(6) Other checks seems to indicate the battery, LD, and physicals disks are all good unless I missing something. Can anyone tell if I am missing something or neglecting something import in my RAID monitoring/understanding? I get degraded for both these servers I have set up. A walk of the entire storage management tree for on of them: StorageManagement-MIB::softwareVersion.0 = STRING: "3.2.0" StorageManagement-MIB::globalStatus.0 = INTEGER: warning(2) StorageManagement-MIB::softwareManufacturer.0 = STRING: "Dell Inc." StorageManagement-MIB::softwareProduct.0 = STRING: "Server Administrator (Storage Management)" StorageManagement-MIB::softwareDescription.0 = STRING: "Configuration and monitoring of disk storage devices." StorageManagement-MIB::displayName.0 = STRING: "Server Administrator (Storage Management)" StorageManagement-MIB::description.0 = STRING: "Configuration and monitoring of disk storage devices." StorageManagement-MIB::agentVendor.0 = STRING: "Dell Inc." StorageManagement-MIB::agentTimeStamp.0 = INTEGER: 1273842310 StorageManagement-MIB::agentGetTimeout.0 = INTEGER: 5 StorageManagement-MIB::agentModifiers.0 = INTEGER: 0 StorageManagement-MIB::agentRefreshRate.0 = INTEGER: 300 StorageManagement-MIB::agentMibVersion.0 = STRING: "3.2" StorageManagement-MIB::agentManagementSoftwareURLName.0 = "" StorageManagement-MIB::agentGlobalSystemStatus.0 = INTEGER: nonCritical(4) StorageManagement-MIB::agentLastGlobalSystemStatus.0 = INTEGER: ok(3) StorageManagement-MIB::agentSmartThermalShutdown.0 = INTEGER: notApplicable(3) StorageManagement-MIB::controllerNumber.1 = INTEGER: 1 StorageManagement-MIB::controllerName.1 = STRING: "PERC 5/i Integrated" StorageManagement-MIB::controllerVendor.1 = STRING: "DELL" StorageManagement-MIB::controllerType.1 = INTEGER: sas(6) StorageManagement-MIB::controllerState.1 = INTEGER: degraded(6) StorageManagement-MIB::controllerRebuildRateInPercent.1 = INTEGER: 30 StorageManagement-MIB::controllerFWVersion.1 = STRING: "5.0.2-0003" StorageManagement-MIB::controllerCacheSizeInMB.1 = INTEGER: 256 StorageManagement-MIB::controllerCacheSizeInBytes.1 = INTEGER: 0 StorageManagement-MIB::controllerPhysicalDeviceCount.1 = INTEGER: 5 StorageManagement-MIB::controllerLogicalDeviceCount.1 = INTEGER: 1 StorageManagement-MIB::controllerRollUpStatus.1 = INTEGER: nonCritical(4) StorageManagement-MIB::controllerComponentStatus.1 = INTEGER: nonCritical(4) StorageManagement-MIB::controllerNexusID.1 = STRING: "\\0" StorageManagement-MIB::controllerAlarmState.1 = INTEGER: disabled(2) StorageManagement-MIB::controllerDriverVersion.1 = STRING: "00.00.03.05 " StorageManagement-MIB::controllerPCISlot.1 = STRING: "embedded" StorageManagement-MIB::controllerClusterMode.1 = INTEGER: notApplicable(99) StorageManagement-MIB::controllerMinFWVersion.1 = STRING: "5.2.1-0067" StorageManagement-MIB::controllerMinDriverVersion.1 = STRING: "00.00.03.21" StorageManagement-MIB::controllerChannelCount.1 = INTEGER: 2 StorageManagement-MIB::controllerReconstructRate.1 = INTEGER: 30 StorageManagement-MIB::controllerPatrolReadRate.1 = INTEGER: 30 StorageManagement-MIB::controllerBGIRate.1 = INTEGER: 30 StorageManagement-MIB::controllerCheckConsistencyRate.1 = INTEGER: 30 StorageManagement-MIB::controllerPatrolReadMode.1 = INTEGER: automatic(1) StorageManagement-MIB::controllerPatrolReadState.1 = INTEGER: stopped(1) StorageManagement-MIB::controllerPatrolReadIterations.1 = INTEGER: 162 StorageManagement-MIB::controllerEntry.57.1 = INTEGER: 99 StorageManagement-MIB::controllerEntry.58.1 = INTEGER: 99 StorageManagement-MIB::channelNumber.1 = INTEGER: 1 StorageManagement-MIB::channelNumber.2 = INTEGER: 2 StorageManagement-MIB::channelName.1 = STRING: "Connector 0" StorageManagement-MIB::channelName.2 = STRING: "Connector 1" StorageManagement-MIB::channelState.1 = INTEGER: ready(1) StorageManagement-MIB::channelState.2 = INTEGER: ready(1) StorageManagement-MIB::channelRollUpStatus.1 = INTEGER: ok(3) StorageManagement-MIB::channelRollUpStatus.2 = INTEGER: ok(3) StorageManagement-MIB::channelComponentStatus.1 = INTEGER: ok(3) StorageManagement-MIB::channelComponentStatus.2 = INTEGER: ok(3) StorageManagement-MIB::channelNexusID.1 = STRING: "\\0\\0" StorageManagement-MIB::channelNexusID.2 = STRING: "\\0\\1" StorageManagement-MIB::channelBusType.1 = INTEGER: sas(8) StorageManagement-MIB::channelBusType.2 = INTEGER: sas(8) StorageManagement-MIB::enclosureNumber.1 = INTEGER: 1 StorageManagement-MIB::enclosureName.1 = STRING: "Backplane" StorageManagement-MIB::enclosureVendor.1 = STRING: "DELL" StorageManagement-MIB::enclosureState.1 = INTEGER: ready(1) StorageManagement-MIB::enclosureProductID.1 = STRING: "BACKPLANE " StorageManagement-MIB::enclosureType.1 = INTEGER: internal(1) StorageManagement-MIB::enclosureChannelNumber.1 = INTEGER: 0 StorageManagement-MIB::enclosureRollUpStatus.1 = INTEGER: ok(3) StorageManagement-MIB::enclosureComponentStatus.1 = INTEGER: ok(3) StorageManagement-MIB::enclosureNexusID.1 = STRING: "\\0\\0\\0" StorageManagement-MIB::enclosureFirmwareVersion.1 = STRING: "1.00" StorageManagement-MIB::enclosureSASAddress.1 = STRING: "50019090B4C67200" StorageManagement-MIB::arrayDiskNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskNumber.2 = INTEGER: 2 StorageManagement-MIB::arrayDiskNumber.3 = INTEGER: 3 StorageManagement-MIB::arrayDiskNumber.4 = INTEGER: 4 StorageManagement-MIB::arrayDiskName.1 = STRING: "Physical Disk 0:0:0" StorageManagement-MIB::arrayDiskName.2 = STRING: "Physical Disk 0:0:1" StorageManagement-MIB::arrayDiskName.3 = STRING: "Physical Disk 0:0:2" StorageManagement-MIB::arrayDiskName.4 = STRING: "Physical Disk 0:0:3" StorageManagement-MIB::arrayDiskVendor.1 = STRING: "DELL " StorageManagement-MIB::arrayDiskVendor.2 = STRING: "DELL " StorageManagement-MIB::arrayDiskVendor.3 = STRING: "DELL " StorageManagement-MIB::arrayDiskVendor.4 = STRING: "DELL " StorageManagement-MIB::arrayDiskState.1 = INTEGER: online(3) StorageManagement-MIB::arrayDiskState.2 = INTEGER: online(3) StorageManagement-MIB::arrayDiskState.3 = INTEGER: online(3) StorageManagement-MIB::arrayDiskState.4 = INTEGER: online(3) StorageManagement-MIB::arrayDiskProductID.1 = STRING: "ST3146755SS " StorageManagement-MIB::arrayDiskProductID.2 = STRING: "ST3146755SS " StorageManagement-MIB::arrayDiskProductID.3 = STRING: "ST3146755SS " StorageManagement-MIB::arrayDiskProductID.4 = STRING: "ST3146755SS " StorageManagement-MIB::arrayDiskSerialNo.1 = STRING: "3LN0LRL0 " StorageManagement-MIB::arrayDiskSerialNo.2 = STRING: "3LN0JYJS " StorageManagement-MIB::arrayDiskSerialNo.3 = STRING: "3LN0LR0V " StorageManagement-MIB::arrayDiskSerialNo.4 = STRING: "3LN0JH97 " StorageManagement-MIB::arrayDiskRevision.1 = STRING: "T106" StorageManagement-MIB::arrayDiskRevision.2 = STRING: "T106" StorageManagement-MIB::arrayDiskRevision.3 = STRING: "T106" StorageManagement-MIB::arrayDiskRevision.4 = STRING: "T106" StorageManagement-MIB::arrayDiskEnclosureID.1 = STRING: "0" StorageManagement-MIB::arrayDiskEnclosureID.2 = STRING: "0" StorageManagement-MIB::arrayDiskEnclosureID.3 = STRING: "0" StorageManagement-MIB::arrayDiskEnclosureID.4 = STRING: "0" StorageManagement-MIB::arrayDiskChannel.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskChannel.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskChannel.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskChannel.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskLengthInMB.1 = INTEGER: 139392 StorageManagement-MIB::arrayDiskLengthInMB.2 = INTEGER: 139392 StorageManagement-MIB::arrayDiskLengthInMB.3 = INTEGER: 139392 StorageManagement-MIB::arrayDiskLengthInMB.4 = INTEGER: 139392 StorageManagement-MIB::arrayDiskLengthInBytes.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskLengthInBytes.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskLengthInBytes.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskLengthInBytes.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInMB.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInMB.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInMB.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInMB.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInBytes.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInBytes.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInBytes.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskLargestContiguousFreeSpaceInBytes.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskTargetID.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskTargetID.2 = INTEGER: 1 StorageManagement-MIB::arrayDiskTargetID.3 = INTEGER: 2 StorageManagement-MIB::arrayDiskTargetID.4 = INTEGER: 3 StorageManagement-MIB::arrayDiskLunID.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskLunID.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskLunID.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskLunID.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskUsedSpaceInMB.1 = INTEGER: 139392 StorageManagement-MIB::arrayDiskUsedSpaceInMB.2 = INTEGER: 139392 StorageManagement-MIB::arrayDiskUsedSpaceInMB.3 = INTEGER: 139392 StorageManagement-MIB::arrayDiskUsedSpaceInMB.4 = INTEGER: 139392 StorageManagement-MIB::arrayDiskUsedSpaceInBytes.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskUsedSpaceInBytes.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskUsedSpaceInBytes.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskUsedSpaceInBytes.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInMB.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInMB.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInMB.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInMB.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInBytes.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInBytes.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInBytes.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskFreeSpaceInBytes.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskBusType.1 = INTEGER: sas(8) StorageManagement-MIB::arrayDiskBusType.2 = INTEGER: sas(8) StorageManagement-MIB::arrayDiskBusType.3 = INTEGER: sas(8) StorageManagement-MIB::arrayDiskBusType.4 = INTEGER: sas(8) StorageManagement-MIB::arrayDiskSpareState.1 = INTEGER: notASpare(5) StorageManagement-MIB::arrayDiskSpareState.2 = INTEGER: notASpare(5) StorageManagement-MIB::arrayDiskSpareState.3 = INTEGER: notASpare(5) StorageManagement-MIB::arrayDiskSpareState.4 = INTEGER: notASpare(5) StorageManagement-MIB::arrayDiskRollUpStatus.1 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskRollUpStatus.2 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskRollUpStatus.3 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskRollUpStatus.4 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskComponentStatus.1 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskComponentStatus.2 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskComponentStatus.3 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskComponentStatus.4 = INTEGER: ok(3) StorageManagement-MIB::arrayDiskNexusID.1 = STRING: "\\0\\0\\0\\0" StorageManagement-MIB::arrayDiskNexusID.2 = STRING: "\\0\\0\\0\\1" StorageManagement-MIB::arrayDiskNexusID.3 = STRING: "\\0\\0\\0\\2" StorageManagement-MIB::arrayDiskNexusID.4 = STRING: "\\0\\0\\0\\3" StorageManagement-MIB::arrayDiskPartNumber.1 = STRING: "SG0DR2381253172FLRL0A00 " StorageManagement-MIB::arrayDiskPartNumber.2 = STRING: "SG0DR2381253172FJYJSA00 " StorageManagement-MIB::arrayDiskPartNumber.3 = STRING: "SG0DR2381253172FLR0VA00 " StorageManagement-MIB::arrayDiskPartNumber.4 = STRING: "SG0DR2381253172FJH97A00 " StorageManagement-MIB::arrayDiskSASAddress.1 = STRING: "5000C50002380201" StorageManagement-MIB::arrayDiskSASAddress.2 = STRING: "5000C50002385B89" StorageManagement-MIB::arrayDiskSASAddress.3 = STRING: "5000C50002385AA9" StorageManagement-MIB::arrayDiskSASAddress.4 = STRING: "5000C500023841E1" StorageManagement-MIB::arrayDiskSmartAlertIndication.1 = INTEGER: no(1) StorageManagement-MIB::arrayDiskSmartAlertIndication.2 = INTEGER: no(1) StorageManagement-MIB::arrayDiskSmartAlertIndication.3 = INTEGER: no(1) StorageManagement-MIB::arrayDiskSmartAlertIndication.4 = INTEGER: no(1) StorageManagement-MIB::arrayDiskManufactureDay.1 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureDay.2 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureDay.3 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureDay.4 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureWeek.1 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureWeek.2 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureWeek.3 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureWeek.4 = STRING: "07" StorageManagement-MIB::arrayDiskManufactureYear.1 = STRING: "2005" StorageManagement-MIB::arrayDiskManufactureYear.2 = STRING: "2005" StorageManagement-MIB::arrayDiskManufactureYear.3 = STRING: "2005" StorageManagement-MIB::arrayDiskManufactureYear.4 = STRING: "2005" StorageManagement-MIB::arrayDiskMediaType.1 = INTEGER: hdd(2) StorageManagement-MIB::arrayDiskMediaType.2 = INTEGER: hdd(2) StorageManagement-MIB::arrayDiskMediaType.3 = INTEGER: hdd(2) StorageManagement-MIB::arrayDiskMediaType.4 = INTEGER: hdd(2) StorageManagement-MIB::arrayDiskEntry.36.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskEntry.36.2 = INTEGER: 1 StorageManagement-MIB::arrayDiskEntry.36.3 = INTEGER: 1 StorageManagement-MIB::arrayDiskEntry.36.4 = INTEGER: 1 StorageManagement-MIB::arrayDiskEntry.40.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskEntry.40.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskEntry.40.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskEntry.40.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskEntry.41.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskEntry.41.2 = INTEGER: 0 StorageManagement-MIB::arrayDiskEntry.41.3 = INTEGER: 0 StorageManagement-MIB::arrayDiskEntry.41.4 = INTEGER: 0 StorageManagement-MIB::arrayDiskEnclosureConnectionNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionNumber.2 = INTEGER: 2 StorageManagement-MIB::arrayDiskEnclosureConnectionNumber.3 = INTEGER: 3 StorageManagement-MIB::arrayDiskEnclosureConnectionNumber.4 = INTEGER: 4 StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskName.1 = STRING: "Physical Disk 0:0:0" StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskName.2 = STRING: "Physical Disk 0:0:1" StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskName.3 = STRING: "Physical Disk 0:0:2" StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskName.4 = STRING: "Physical Disk 0:0:3" StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskNumber.2 = INTEGER: 2 StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskNumber.3 = INTEGER: 3 StorageManagement-MIB::arrayDiskEnclosureConnectionArrayDiskNumber.4 = INTEGER: 4 StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureName.1 = STRING: "Backplane" StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureName.2 = STRING: "Backplane" StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureName.3 = STRING: "Backplane" StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureName.4 = STRING: "Backplane" StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureNumber.2 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureNumber.3 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionEnclosureNumber.4 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionControllerName.1 = STRING: "PERC 5/i Integrated" StorageManagement-MIB::arrayDiskEnclosureConnectionControllerName.2 = STRING: "PERC 5/i Integrated" StorageManagement-MIB::arrayDiskEnclosureConnectionControllerName.3 = STRING: "PERC 5/i Integrated" StorageManagement-MIB::arrayDiskEnclosureConnectionControllerName.4 = STRING: "PERC 5/i Integrated" StorageManagement-MIB::arrayDiskEnclosureConnectionControllerNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionControllerNumber.2 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionControllerNumber.3 = INTEGER: 1 StorageManagement-MIB::arrayDiskEnclosureConnectionControllerNumber.4 = INTEGER: 1 StorageManagement-MIB::batteryNumber.1 = INTEGER: 1 StorageManagement-MIB::batteryName.1 = STRING: "Battery 0" StorageManagement-MIB::batteryVendor.1 = STRING: "DELL" StorageManagement-MIB::batteryState.1 = INTEGER: ready(1) StorageManagement-MIB::batteryRollUpStatus.1 = INTEGER: ok(3) StorageManagement-MIB::batteryComponentStatus.1 = INTEGER: ok(3) StorageManagement-MIB::batteryNexusID.1 = STRING: "\\0\\0" StorageManagement-MIB::batteryPredictedCapacity.1 = INTEGER: ready(2) StorageManagement-MIB::batteryNextLearnTime.1 = INTEGER: 21 StorageManagement-MIB::batteryLearnState.1 = INTEGER: idle(16) StorageManagement-MIB::batteryEntry.13.1 = INTEGER: 0 StorageManagement-MIB::batteryMaxLearnDelay.1 = INTEGER: 168 StorageManagement-MIB::batteryConnectionNumber.1 = INTEGER: 1 StorageManagement-MIB::batteryConnectionBatteryName.1 = STRING: "Battery 0" StorageManagement-MIB::batteryConnectionBatteryNumber.1 = INTEGER: 1 StorageManagement-MIB::batteryConnectionControllerName.1 = STRING: "PERC 5/i Integrated" StorageManagement-MIB::batteryConnectionControllerNumber.1 = INTEGER: 1 StorageManagement-MIB::virtualDiskNumber.1 = INTEGER: 1 StorageManagement-MIB::virtualDiskName.1 = STRING: "Virtual Disk 0" StorageManagement-MIB::virtualDiskDeviceName.1 = STRING: "/dev/sda" StorageManagement-MIB::virtualDiskState.1 = INTEGER: ready(1) StorageManagement-MIB::virtualDiskLengthInMB.1 = INTEGER: 278784 StorageManagement-MIB::virtualDiskLengthInBytes.1 = INTEGER: 0 StorageManagement-MIB::virtualDiskWritePolicy.1 = INTEGER: writeBack(3) StorageManagement-MIB::virtualDiskReadPolicy.1 = INTEGER: noReadAhead(5) StorageManagement-MIB::virtualDiskCachePolicy.1 = INTEGER: not-applicable(99) StorageManagement-MIB::virtualDiskLayout.1 = INTEGER: raid-10(10) StorageManagement-MIB::virtualDiskCurStripeSizeInMB.1 = INTEGER: 0 StorageManagement-MIB::virtualDiskCurStripeSizeInBytes.1 = INTEGER: 65536 StorageManagement-MIB::virtualDiskTargetID.1 = INTEGER: 0 StorageManagement-MIB::virtualDiskRollUpStatus.1 = INTEGER: ok(3) StorageManagement-MIB::virtualDiskComponentStatus.1 = INTEGER: ok(3) StorageManagement-MIB::virtualDiskNexusID.1 = STRING: "\\0\\0" StorageManagement-MIB::virtualDiskArrayDiskType.1 = INTEGER: sas(1) StorageManagement-MIB::virtualDiskEntry.23.1 = INTEGER: 2 StorageManagement-MIB::virtualDiskEntry.24.1 = INTEGER: 0 StorageManagement-MIB::arrayDiskLogicalConnectionNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskLogicalConnectionNumber.2 = INTEGER: 2 StorageManagement-MIB::arrayDiskLogicalConnectionNumber.3 = INTEGER: 3 StorageManagement-MIB::arrayDiskLogicalConnectionNumber.4 = INTEGER: 4 StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskName.1 = STRING: "Physical Disk 0:0:0" StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskName.2 = STRING: "Physical Disk 0:0:1" StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskName.3 = STRING: "Physical Disk 0:0:2" StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskName.4 = STRING: "Physical Disk 0:0:3" StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskNumber.2 = INTEGER: 2 StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskNumber.3 = INTEGER: 3 StorageManagement-MIB::arrayDiskLogicalConnectionArrayDiskNumber.4 = INTEGER: 4 StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskName.1 = STRING: "Virtual Disk 0" StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskName.2 = STRING: "Virtual Disk 0" StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskName.3 = STRING: "Virtual Disk 0" StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskName.4 = STRING: "Virtual Disk 0" StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskNumber.1 = INTEGER: 1 StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskNumber.2 = INTEGER: 1 StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskNumber.3 = INTEGER: 1 StorageManagement-MIB::arrayDiskLogicalConnectionVirtualDiskNumber.4 = INTEGER: 1

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  • smallest perimiter rectangle with given integer area and integer sides

    - by remuladgryta
    Given an integer area A, how can one find integer sides w and h of a rectangle such that w*h = A and w+h is as small as possible? I'd rather the algorithm be simple than efficient (although within reasonable efficiency). What would be the best way to accomplish this? Finding out the prime factors of A, then combining them in some way that tries to balance w and h? Finding the two squares with integer sides with areas closest to A and then somehow interpolating between them? Any other method i'm not thinking of?

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  • Bit reversal of an integer, ignoring integer size and endianness

    - by ??O?????
    Given an integer typedef: typedef unsigned int TYPE; or typedef unsigned long TYPE; I have the following code to reverse the bits of an integer: TYPE max_bit= (TYPE)-1; void reverse_int_setup() { TYPE bits= (TYPE)max_bit; while (bits <<= 1) max_bit= bits; } TYPE reverse_int(TYPE arg) { TYPE bit_setter= 1, bit_tester= max_bit, result= 0; for (result= 0; bit_tester; bit_tester>>= 1, bit_setter<<= 1) if (arg & bit_tester) result|= bit_setter; return result; } One just needs first to run reverse_int_setup(), which stores an integer with the highest bit turned on, then any call to reverse_int(arg) returns arg with its bits reversed (to be used as a key to a binary tree, taken from an increasing counter, but that's more or less irrelevant). Is there a platform-agnostic way to have in compile-time the correct value for max_int after the call to reverse_int_setup(); Otherwise, is there an algorithm you consider better/leaner than the one I have for reverse_int()? Thanks.

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  • Ivar definitions show 'long' type encoding as 'long long' type encoding

    - by Frank C.
    I've found what I think may be a bug with Ivar and Objective-C runtime. I'm using XCode 3.2.1 and associated libraries, developing a 64 bit app on X86_64 (MacBook Pro). Where I would expect the type encoding for the following "longVal" to be 'l', the Ivar encoding is showing a 'q' (which is a 'long long'). Anyone else seeing this? Simplified code and output follows: Code: #import <Foundation/Foundation.h> #import <objc/runtime.h> @interface Bug : NSObject { long longVal; long long longerVal; } @property (nonatomic,assign) long longVal; @property (nonatomic,assign) long long longerVal; @end @implementation Bug @synthesize longVal,longerVal; @end int main (int argc, const char * argv[]) { NSAutoreleasePool * pool = [[NSAutoreleasePool alloc] init]; unsigned int ivarCount=0; Ivar *ivars= class_copyIvarList([Bug class], &ivarCount); for(unsigned int x=0;x<ivarCount;x++) { NSLog(@"Name [%@] encoding [%@]", [NSString stringWithCString:ivar_getName(ivars[x]) encoding:NSUTF8StringEncoding], [NSString stringWithCString:ivar_getTypeEncoding(ivars[x]) encoding:NSUTF8StringEncoding]); } [pool drain]; return 0; } And here is output from debug console: This GDB was configured as "x86_64-apple-darwin".tty /dev/ttys000 Loading program into debugger… sharedlibrary apply-load-rules all Program loaded. run [Switching to process 6048] Running… 2010-03-17 22:16:29.138 ivarbug[6048:a0f] Name [longVal] encoding [q] 2010-03-17 22:16:29.146 ivarbug[6048:a0f] Name [longerVal] encoding [q] (gdb) continue Not a pretty picture! -- Frank

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  • Question about C behaviour for unsigned integer underflow

    - by nn
    I have read in many places that integer overflow is well-defined in C unlike the signed counterpart. Is underflow the same? For example: unsigned int x = -1; // Does x == UINT_MAX? Thanks. I can't recall where, but i read somewhere that arithmetic on unsigned integral types is modular, so if that were the case then -1 == UINT_MAX mod (UINT_MAX+1).

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  • Is it possible to add -pedantic to GCC command line, yet have it not warn about 'long long'

    - by doublep
    I'm using mostly GCC to develop my library, but I'd like to ensure cross-compiler compatibility and especially standard conformance as much as possible. For this, I have add several -W... flags to command line. I'd also add -pedantic, but I have a problem with its warning about long long type. The latter is important for my library and is properly guarded with #if code, i.e. is not compiled on compilers that don't know it anyway. In short: can I have GCC in -pedantic mode warn about any extension except long long?

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  • Saturated addition of two signed Java 'long' values

    - by finnw
    How can one add two long values (call them x and y) in Java so that if the result overflows then it is clamped to the range Long.MIN_VALUE..Long.MAX_VALUE? For adding ints one can perform the arithmetic in long precision and cast the result back to an int, e.g.: int saturatedAdd(int x, int y) { long sum = (long) x + (long) y; long clampedSum = Math.max((long) Integer.MIN_VALUE, Math.min(sum, (long) Integer.MAX_VALUE)); return (int) clampedSum; } or import com.google.common.primitives.Ints; int saturatedAdd(int x, int y) { long sum = (long) x + (long) y; return Ints.saturatedCast(sum); } but in the case of long there is no larger primitive type that can hold the intermediate (unclamped) sum. Since this is Java, I cannot use inline assembly (in particular SSE's saturated add instructions.) It can be implemented using BigInteger, e.g. static final BigInteger bigMin = BigInteger.valueOf(Long.MIN_VALUE); static final BigInteger bigMax = BigInteger.valueOf(Long.MAX_VALUE); long saturatedAdd(long x, long y) { BigInteger sum = BigInteger.valueOf(x).add(BigInteger.valueOf(y)); return bigMin.max(sum).min(bigMax).longValue(); } however performance is important so this method is not ideal (though useful for testing.) I don't know whether avoiding branching can significantly affect performance in Java. I assume it can, but I would like to benchmark methods both with and without branching. Related: http://stackoverflow.com/questions/121240/saturating-addition-in-c

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  • Need help implementing an Android service that does http long polling

    - by Erdal
    I've seen persistent TCP connections implemented (http://devtcg.blogspot.com/2009/01/push-services-implementing-persistent.html), but my needs are a little different. I need an Android service that always runs in the background and keeps a long polling connection to an HTTP server and communicates with it using JSON over POST method. Does anyone have anything similar to this?

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  • Twice as long and half as long

    - by PointsToShare
    We are in a project and we hit some snags. What’s a snag? An activity that takes longer than expected. Actually it takes longer than the time assigned to it by an over pressed PM who accepts an impossible time table and tries his best to make it possible, but I digress (again!).  So we have snags and we also have the opposite. Let’s call these “cinches”. The question is: how does a combination of snags and cinches affect the project timeline? Well, there is no simple answer. It depends on the projects dependencies as we see in the PERT chart. If all the snags are in the critical path and all the cinches are elsewhere then the cinches don’t help at all. In fact any snag in the critical path will delay the project.  Conversely, a cinch in the critical path will expedite it. A snag outside the critical path might be serious enough to even change the critical path. Thus without the PERT chart, we cannot really tell. Still there is a principle involved – Time and speed are non-linear! Twice as long adds a full unit, half as long only takes ½ unit away. Let’s just investigate a simple project. It consists of two activities – S and C - each estimated to take a week. Alas, S is a snag and really needs twice the time allotted and – a sigh of relief – C is a cinch and will take half the time allotted, so everything is Hun-key-dory, or is it?  Even here the PERT chart is important. We have 2 cases: 1: S depends on C (or vice versa) as in when the two activities are assigned to one employee. Here the estimated time was 1 + 1 and the actual time was 2 + ½ and we are ½ week late or 25% late. 2: S and C are done in parallel. Here the estimated time was 1, but the actual time is 2 – we are a whole week or 100% late. Let’s change the equation a little. S need 1.5 and C needs .5 so in case 1, we have the loss fully compensated by the gain, but in case 2 we are still behind. There are cases where this really makes no difference. This is when the critical path is not affected and we have enough slack in the other paths to counteract the difference between its snags and cinches – Let’s call this difference DSC. So if the slack is greater than DSC the project will not suffer. Conclusion: There is no general rule about snags and cinches. We need to examine each case within its project, still as we saw in the 4 examples above; the snag is generally more powerful than the cinch. Long live Murphy! That’s All Folks

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  • Compare new Integer Objects in ArrayList Question

    - by thechiman
    I am storing Integer objects representing an index of objects I want to track. Later in my code I want to check to see if a particular object's index corresponds to one of those Integers I stored earlier. I am doing this by creating an ArrayList and creating a new Integer from the index of a for loop: ArrayList<Integer> courseselectItems = new ArrayList(); //Find the course elements that are within a courseselect element and add their indicies to the ArrayList for(int i=0; i<numberElementsInNodeList; i++) { if (nodeList.item(i).getParentNode().getNodeName().equals("courseselect")) { courseselectItems.add(new Integer(i)); } } I then want to check later if the ArrayList contains a particular index: //Cycle through the namedNodeMap array to find each of the course codes for(int i=0; i<numberElementsInNodeList; i++) { if(!courseselectItems.contains(new Integer(i))) { //Do Stuff } } My question is, when I create a new Integer by using new Integer(i) will I be able to compare integers using ArrayList.contains()? That is to say, when I create a new object using new Integer(i), will that be the same as the previously created Integer object if the int value used to create them are the same? I hope I didn't make this too unclear. Thanks for the help!

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  • How does the last integer promotion rule ever get applied in C?

    - by SiegeX
    6.3.1.8p1: Otherwise, the integer promotions are performed on both operands. Then the following rules are applied to the promoted operands: If both operands have the same type, then no further conversion is needed. Otherwise, if both operands have signed integer types or both have unsigned integer types, the operand with the type of lesser integer conversion rank is converted to the type of the operand with greater rank. Otherwise, if the operand that has unsigned integer type has rank greater or equal to the rank of the type of the other operand, then the operand with signed integer type is converted to the type of the operand with unsigned integer type. Otherwise, if the type of the operand with signed integer type can represent all of the values of the type of the operand with unsigned integer type, then the operand with unsigned integer type is converted to the type of the operand with signed integer type. Otherwise, both operands are converted to the unsigned integer type corresponding to the type of the operand with signed integer type. For the bolded rule to be applied it would seem to imply you need to have have an unsigned interger type who's rank is less than the signed integer type and the signed integer type cannot hold all the values of the unsigned integer type. Is there a real world example of such a case or is this statement serving as a catch-all to cover all possible permutations?

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  • It's a Long, Long Way to Tipperary but not that Far to Yak about Apps

    - by linda.fishman.hoyle
    I wanted to let everyone know that my blog URL will be moving to http://blogs.oracle.com/lindafishman/. I will focus my future writings to be about the upgrade and adoption strategies of Oracle E-Business Suite customers. To give you a little preview, here is a link to a book of 60 customers who are live on E-Business Suite Release 12 and 12.1. We have thousands of customers live on Release 12.x and are feverishly trying to write as many stories as we can so those of you who are thinking about upgrading, putting a business case together to move from another ERP application to E-Business Suite or for small and midsize companies who want a better understanding of the benefits E-Business Suite provides organizations of your size, this will be the place to go. See you at the new site! Linda

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  • How to check if a integer is sum of given integers?

    - by p3trix
    Lets say I have a integer result and an array of integers, lets say [a,b,c] (not a fixed length). I need to detect if result=a*i +b*j + c*k, with i,j,k=0. I prefer a solution in C/C# if it is possible. PS The problem is from a reservation system, a trip can be sold if its durations is a combination of given durations. Thanks!

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  • Interop c# using a "long" from c++

    - by Daniel
    On my System: sizeof(long) in c++ is 4 aka 32bits sizeof(long) in c# is 8 aka 64 bits So in my Interop method declarations I've been substituting c++ longs with c# int's however I get the feeling this isn't safe? Why is a long the same size as an int in c++? And long long is 64bits? What's next a long long long long??

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  • What is a Delphi version of the C++ header for the DVP7010B video card DLL?

    - by grzegorz1
    I need help with converting c++ header file to delphi. I spent several days on this problem without success. Below is the original header file and my Delphi translation. C++ header #if _MSC_VER > 1000 #pragma once #endif // _MSC_VER > 1000 #ifdef DVP7010BDLL_EXPORTS #define DVP7010BDLL_API __declspec(dllexport) #else #define DVP7010BDLL_API __declspec(dllimport) #endif #define MAXBOARDS 4 #define MAXDEVS 4 #define ID_NEW_FRAME 37810 #define ID_MUX0_NEW_FRAME 37800 #define ID_MUX1_NEW_FRAME 37801 #define ID_MUX2_NEW_FRAME 37802 #define ID_MUX3_NEW_FRAME 37803 typedef enum { SUCCEEDED = 1, FAILED = 0, SDKINITFAILED = -1, PARAMERROR = -2, NODEVICES = -3, NOSAMPLE = -4, DEVICENUMERROR = -5, INPUTERROR = -6, // VERIFYHWERROR = -7 } Res; typedef enum tagAnalogVideoFormat { Video_None = 0x00000000, Video_NTSC_M = 0x00000001, Video_NTSC_M_J = 0x00000002, Video_PAL_B = 0x00000010, Video_PAL_M = 0x00000200, Video_PAL_N = 0x00000400, Video_SECAM_B = 0x00001000 } AnalogVideoFormat; typedef enum { SIZEFULLPAL=0, SIZED1, SIZEVGA, SIZEQVGA, SIZESUBQVGA } VideoSize; typedef enum { STOPPED = 1, RUNNING = 2, UNINITIALIZED = -1, UNKNOWNSTATE = -2 } CapState; class IDVP7010BDLL { public: int AdvDVP_CreateSDKInstence(void **pp); virtual int AdvDVP_InitSDK() PURE; virtual int AdvDVP_CloseSDK() PURE; virtual int AdvDVP_GetNoOfDevices(int *pNoOfDevs) PURE; virtual int AdvDVP_Start(int nDevNum, int SwitchingChans, HWND Main, HWND hwndPreview) PURE; virtual int AdvDVP_Stop(int nDevNum) PURE; virtual int AdvDVP_GetCapState(int nDevNum) PURE; virtual int AdvDVP_IsVideoPresent(int nDevNum, BOOL* VPresent) PURE; virtual int AdvDVP_GetCurFrameBuffer(int nDevNum, int VMux, long* bufSize, BYTE* buf) PURE; virtual int AdvDVP_SetNewFrameCallback(int nDevNum, int callback) PURE; virtual int AdvDVP_GetVideoFormat(int nDevNum, AnalogVideoFormat* vFormat) PURE; virtual int AdvDVP_SetVideoFormat(int nDevNum, AnalogVideoFormat vFormat) PURE; virtual int AdvDVP_GetFrameRate(int nDevNum, int *nFrameRate) PURE; virtual int AdvDVP_SetFrameRate(int nDevNum, int SwitchingChans, int nFrameRate) PURE; virtual int AdvDVP_GetResolution(int nDevNum, VideoSize *Size) PURE; virtual int AdvDVP_SetResolution(int nDevNum, VideoSize Size) PURE; virtual int AdvDVP_GetVideoInput(int nDevNum, int* input) PURE; virtual int AdvDVP_SetVideoInput(int nDevNum, int input) PURE; virtual int AdvDVP_GetBrightness(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetBrightness(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GetContrast(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetContrast(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GetHue(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetHue(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GetSaturation(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetSaturation(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GPIOGetData(int nDevNum, int DINum, BOOL* value) PURE; virtual int AdvDVP_GPIOSetData(int nDevNum, int DONum, BOOL value) PURE; }; Delphi unit IDVP7010BDLL_h; interface uses Windows, Messages, SysUtils, Classes; //{$if _MSC_VER > 1000} //pragma once //{$endif} // _MSC_VER > 1000 {$ifdef DVP7010BDLL_EXPORTS} //const DVP7010BDLL_API = __declspec(dllexport); {$else} //const DVP7010BDLL_API = __declspec(dllimport); {$endif} const MAXDEVS = 4; MAXMUXS = 4; ID_NEW_FRAME = 37810; ID_MUX0_NEW_FRAME = 37800; ID_MUX1_NEW_FRAME = 37801; ID_MUX2_NEW_FRAME = 37802; ID_MUX3_NEW_FRAME = 37803; // TRec SUCCEEDED = 1; FAILED = 0; SDKINITFAILED = -1; PARAMERROR = -2; NODEVICES = -3; NOSAMPLE = -4; DEVICENUMERROR = -5; INPUTERROR = -6; // TRec // TAnalogVideoFormat Video_None = $00000000; Video_NTSC_M = $00000001; Video_NTSC_M_J = $00000002; Video_PAL_B = $00000010; Video_PAL_M = $00000200; Video_PAL_N = $00000400; Video_SECAM_B = $00001000; // TAnalogVideoFormat // TCapState STOPPED = 1; RUNNING = 2; UNINITIALIZED = -1; UNKNOWNSTATE = -2; // TCapState type TCapState = Longint; TRes = Longint; TtagAnalogVideoFormat = DWORD; TAnalogVideoFormat = TtagAnalogVideoFormat; PAnalogVideoFormat = ^TAnalogVideoFormat; TVideoSize = ( SIZEFULLPAL, SIZED1, SIZEVGA, SIZEQVGA, SIZESUBQVGA); PVideoSize = ^TVideoSize; P_Pointer = ^Pointer; TIDVP7010BDLL = class function AdvDVP_CreateSDKInstence(pp: P_Pointer): integer; virtual; stdcall; abstract; function AdvDVP_InitSDK():Integer; virtual; stdcall; abstract; function AdvDVP_CloseSDK():Integer; virtual; stdcall; abstract; function AdvDVP_GetNoOfDevices(pNoOfDevs : PInteger) :Integer; virtual; stdcall; abstract; function AdvDVP_Start(nDevNum : Integer; SwitchingChans : Integer; Main : HWND; hwndPreview: HWND ) :Integer; virtual; stdcall; abstract; function AdvDVP_Stop(nDevNum : Integer ):Integer; virtual; stdcall; abstract; function AdvDVP_GetCapState(nDevNum : Integer ):Integer; virtual; stdcall; abstract; function AdvDVP_IsVideoPresent(nDevNum : Integer; VPresent : PBool) :Integer; virtual; stdcall; abstract; function AdvDVP_GetCurFrameBuffer(nDevNum : Integer; VMux : Integer; bufSize : PLongInt; buf : PByte) :Integer; virtual; stdcall; abstract; function AdvDVP_SetNewFrameCallback(nDevNum : Integer; callback : Integer ) :Integer; virtual; stdcall; abstract; function AdvDVP_GetVideoFormat(nDevNum : Integer; vFormat : PAnalogVideoFormat) :Integer; virtual; stdcall; abstract; function AdvDVP_SetVideoFormat(nDevNum : Integer; vFormat : TAnalogVideoFormat ) :Integer; virtual; stdcall; abstract; function AdvDVP_GetFrameRate(nDevNum : Integer; nFrameRate : Integer) :Integer; virtual; stdcall; abstract; function AdvDVP_SetFrameRate(nDevNum : Integer; SwitchingChans : Integer; nFrameRate : Integer) :Integer; virtual; stdcall; abstract; function AdvDVP_GetResolution(nDevNum : Integer; Size : PVideoSize) :Integer; virtual; stdcall; abstract; function AdvDVP_SetResolution(nDevNum : Integer; Size : TVideoSize ) :Integer; virtual; stdcall; abstract; function AdvDVP_GetVideoInput(nDevNum : Integer; input : PInteger) :Integer; virtual; stdcall; abstract; function AdvDVP_SetVideoInput(nDevNum : Integer; input : Integer) :Integer; virtual; stdcall; abstract; function AdvDVP_GetBrightness(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetBrightness(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GetContrast(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetContrast(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GetHue(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetHue(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GetSaturation(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetSaturation(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GPIOGetData(nDevNum : Integer; DINum:Integer; value : PBool) :Integer; virtual; stdcall; abstract; function AdvDVP_GPIOSetData(nDevNum : Integer; DONum:Integer; value : Boolean) :Integer; virtual; stdcall; abstract; end; function IDVP7010BDLL : TIDVP7010BDLL ; stdcall; implementation function IDVP7010BDLL; external 'DVP7010B.dll'; end.

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  • Need help converting a C++ header file to delphi

    - by grzegorz1
    I need help with converting c++ header file to delphi. I spent several days on this problem without success. Below is the original header file and my Delphi translation. ///////////////////////// C++ header file //////////////////////////////////// if _MSC_VER 1000 pragma once endif // _MSC_VER 1000 ifdef DVP7010BDLL_EXPORTS define DVP7010BDLL_API __declspec(dllexport) else define DVP7010BDLL_API __declspec(dllimport) endif define MAXBOARDS 4 define MAXDEVS 4 define ID_NEW_FRAME 37810 define ID_MUX0_NEW_FRAME 37800 define ID_MUX1_NEW_FRAME 37801 define ID_MUX2_NEW_FRAME 37802 define ID_MUX3_NEW_FRAME 37803 typedef enum { SUCCEEDED = 1, FAILED = 0, SDKINITFAILED = -1, PARAMERROR = -2, NODEVICES = -3, NOSAMPLE = -4, DEVICENUMERROR = -5, INPUTERROR = -6, // VERIFYHWERROR = -7 } Res; typedef enum tagAnalogVideoFormat { Video_None = 0x00000000, Video_NTSC_M = 0x00000001, Video_NTSC_M_J = 0x00000002, Video_PAL_B = 0x00000010, Video_PAL_M = 0x00000200, Video_PAL_N = 0x00000400, Video_SECAM_B = 0x00001000 } AnalogVideoFormat; typedef enum { SIZEFULLPAL=0, SIZED1, SIZEVGA, SIZEQVGA, SIZESUBQVGA } VideoSize; typedef enum { STOPPED = 1, RUNNING = 2, UNINITIALIZED = -1, UNKNOWNSTATE = -2 } CapState; class IDVP7010BDLL { public: int AdvDVP_CreateSDKInstence(void **pp); virtual int AdvDVP_InitSDK() PURE; virtual int AdvDVP_CloseSDK() PURE; virtual int AdvDVP_GetNoOfDevices(int *pNoOfDevs) PURE; virtual int AdvDVP_Start(int nDevNum, int SwitchingChans, HWND Main, HWND hwndPreview) PURE; virtual int AdvDVP_Stop(int nDevNum) PURE; virtual int AdvDVP_GetCapState(int nDevNum) PURE; virtual int AdvDVP_IsVideoPresent(int nDevNum, BOOL* VPresent) PURE; virtual int AdvDVP_GetCurFrameBuffer(int nDevNum, int VMux, long* bufSize, BYTE* buf) PURE; virtual int AdvDVP_SetNewFrameCallback(int nDevNum, int callback) PURE; virtual int AdvDVP_GetVideoFormat(int nDevNum, AnalogVideoFormat* vFormat) PURE; virtual int AdvDVP_SetVideoFormat(int nDevNum, AnalogVideoFormat vFormat) PURE; virtual int AdvDVP_GetFrameRate(int nDevNum, int *nFrameRate) PURE; virtual int AdvDVP_SetFrameRate(int nDevNum, int SwitchingChans, int nFrameRate) PURE; virtual int AdvDVP_GetResolution(int nDevNum, VideoSize *Size) PURE; virtual int AdvDVP_SetResolution(int nDevNum, VideoSize Size) PURE; virtual int AdvDVP_GetVideoInput(int nDevNum, int* input) PURE; virtual int AdvDVP_SetVideoInput(int nDevNum, int input) PURE; virtual int AdvDVP_GetBrightness(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetBrightness(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GetContrast(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetContrast(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GetHue(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetHue(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GetSaturation(int nDevNum, int input, long *pnValue) PURE; virtual int AdvDVP_SetSaturation(int nDevNum, int input, long nValue) PURE; virtual int AdvDVP_GPIOGetData(int nDevNum, int DINum, BOOL* value) PURE; virtual int AdvDVP_GPIOSetData(int nDevNum, int DONum, BOOL value) PURE; }; /////////////////// delphi /////////////////////////////////////// unit IDVP7010BDLL_h; interface uses Windows, Messages, SysUtils, Classes; //{$if _MSC_VER 1000} //pragma once //{$endif} // _MSC_VER 1000 {$ifdef DVP7010BDLL_EXPORTS} //const DVP7010BDLL_API = __declspec(dllexport); {$else} //const DVP7010BDLL_API = __declspec(dllimport); {$endif} const MAXDEVS = 4; MAXMUXS = 4; ID_NEW_FRAME = 37810; ID_MUX0_NEW_FRAME = 37800; ID_MUX1_NEW_FRAME = 37801; ID_MUX2_NEW_FRAME = 37802; ID_MUX3_NEW_FRAME = 37803; // TRec SUCCEEDED = 1; FAILED = 0; SDKINITFAILED = -1; PARAMERROR = -2; NODEVICES = -3; NOSAMPLE = -4; DEVICENUMERROR = -5; INPUTERROR = -6; // TRec // TAnalogVideoFormat Video_None = $00000000; Video_NTSC_M = $00000001; Video_NTSC_M_J = $00000002; Video_PAL_B = $00000010; Video_PAL_M = $00000200; Video_PAL_N = $00000400; Video_SECAM_B = $00001000; // TAnalogVideoFormat // TCapState STOPPED = 1; RUNNING = 2; UNINITIALIZED = -1; UNKNOWNSTATE = -2; // TCapState type TCapState = Longint; TRes = Longint; TtagAnalogVideoFormat = DWORD; TAnalogVideoFormat = TtagAnalogVideoFormat; PAnalogVideoFormat = ^TAnalogVideoFormat; TVideoSize = ( SIZEFULLPAL, SIZED1, SIZEVGA, SIZEQVGA, SIZESUBQVGA); PVideoSize = ^TVideoSize; P_Pointer = ^Pointer; TIDVP7010BDLL = class function AdvDVP_CreateSDKInstence(pp: P_Pointer): integer; virtual; stdcall; abstract; function AdvDVP_InitSDK():Integer; virtual; stdcall; abstract; function AdvDVP_CloseSDK():Integer; virtual; stdcall; abstract; function AdvDVP_GetNoOfDevices(pNoOfDevs : PInteger) :Integer; virtual; stdcall; abstract; function AdvDVP_Start(nDevNum : Integer; SwitchingChans : Integer; Main : HWND; hwndPreview: HWND ) :Integer; virtual; stdcall; abstract; function AdvDVP_Stop(nDevNum : Integer ):Integer; virtual; stdcall; abstract; function AdvDVP_GetCapState(nDevNum : Integer ):Integer; virtual; stdcall; abstract; function AdvDVP_IsVideoPresent(nDevNum : Integer; VPresent : PBool) :Integer; virtual; stdcall; abstract; function AdvDVP_GetCurFrameBuffer(nDevNum : Integer; VMux : Integer; bufSize : PLongInt; buf : PByte) :Integer; virtual; stdcall; abstract; function AdvDVP_SetNewFrameCallback(nDevNum : Integer; callback : Integer ) :Integer; virtual; stdcall; abstract; function AdvDVP_GetVideoFormat(nDevNum : Integer; vFormat : PAnalogVideoFormat) :Integer; virtual; stdcall; abstract; function AdvDVP_SetVideoFormat(nDevNum : Integer; vFormat : TAnalogVideoFormat ) :Integer; virtual; stdcall; abstract; function AdvDVP_GetFrameRate(nDevNum : Integer; nFrameRate : Integer) :Integer; virtual; stdcall; abstract; function AdvDVP_SetFrameRate(nDevNum : Integer; SwitchingChans : Integer; nFrameRate : Integer) :Integer; virtual; stdcall; abstract; function AdvDVP_GetResolution(nDevNum : Integer; Size : PVideoSize) :Integer; virtual; stdcall; abstract; function AdvDVP_SetResolution(nDevNum : Integer; Size : TVideoSize ) :Integer; virtual; stdcall; abstract; function AdvDVP_GetVideoInput(nDevNum : Integer; input : PInteger) :Integer; virtual; stdcall; abstract; function AdvDVP_SetVideoInput(nDevNum : Integer; input : Integer) :Integer; virtual; stdcall; abstract; function AdvDVP_GetBrightness(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetBrightness(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GetContrast(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetContrast(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GetHue(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetHue(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GetSaturation(nDevNum : Integer; input: Integer; pnValue : PLongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_SetSaturation(nDevNum : Integer; input: Integer; nValue : LongInt) :Integer; virtual; stdcall; abstract; function AdvDVP_GPIOGetData(nDevNum : Integer; DINum:Integer; value : PBool) :Integer; virtual; stdcall; abstract; function AdvDVP_GPIOSetData(nDevNum : Integer; DONum:Integer; value : Boolean) :Integer; virtual; stdcall; abstract; end; function IDVP7010BDLL : TIDVP7010BDLL ; stdcall; implementation function IDVP7010BDLL; external 'DVP7010B.dll'; end.

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  • C++ Thread Safe Integer

    - by Paul Ridgway
    Hello everyone, I have currently created a C++ class for a thread safe integer which simply stores an integer privately and has public get a set functions which use a boost::mutex to ensure that only one change at a time can be applied to the integer. Is this the most efficient way to do it, I have been informed that mutexes are quite resource intensive? The class is used a lot, very rapidly so it could well be a bottleneck... Googleing C++ Thread Safe Integer returns unclear views and oppinions on the thread safety of integer operations on different architectures. Some say that a 32bit int on a 32bit arch is safe, but 64 on 32 isn't due to 'alignment' Others say it is compiler/OS specific (which I don't doubt). I am using Ubuntu 9.10 on 32 bit machines, some have dual cores and so threads may be executed simultaneously on different cores in some cases and I am using GCC 4.4's g++ compiler. Thanks in advance...

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  • C++ long long manipulation

    - by Krakkos
    Given 2 32bit ints iMSB and iLSB int iMSB = 12345678; // Most Significant Bits of file size in Bytes int iLSB = 87654321; // Least Significant Bits of file size in Bytes the long long form would be... // Always positive so use 31 bts long long full_size = ((long long)iMSB << 31); full_size += (long long)(iLSB); Now.. I don't need that much precision (that exact number of bytes), so, how can I convert the file size to MiBytes to 3 decimal places and convert to a string... tried this... long double file_size_megs = file_size_bytes / (1024 * 1024); char strNumber[20]; sprintf(strNumber, "%ld", file_size_megs); ... but dosen't seem to work. i.e. 1234567899878Bytes = 1177375.698MiB ??

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  • How long does it take to iterate through a long loop?

    - by Carl Rosenberger
    On a modern 64-Bit machine, how long do you think it takes to iterate through all the positive long numbers? Below is a code snippet in Java to demonstrate the idea. Without running the code yourself, how long do you think this code is going to run? How long will similar code run in other programming languages? public class LongLoop { public static void main(String[] args) { long startTime = System.currentTimeMillis(); for (long i = 0; i < Long.MAX_VALUE; i++) { // do nothing, just loop } long stopTime = System.currentTimeMillis(); long duration = stopTime - startTime; System.out.println("Time taken: " + duration + " milliseconds"); } }

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  • Should I redesign my code when my colleague says so?

    - by Kirill V. Lyadvinsky
    I wrote a function recently (with help of one guy from SO) that finds maximum of two ints. Here is the code: long get_max (long(*a)(long(*)(long(*)()),long(*)(long(*)(long**))), long(*b)(long(*) (long(*)()),long*,long(*)(long(*)()))){return (long)((((long(*)(long(*)(long(*)()),long( *)(long(*)())))a)> ((long(*)(long(*)(long(*)()),long(*)(long(*)())))b))?((long(*)( long(*)(long(*)()),long(*)(long(*)())))a):((long(*)(long(*)(long(*)()),long(*)(long(*)( ))))b));} int main() { long x = get_max( (long(*)(long(*)(long(*)()),long(*)(long(*)(long**)))) 500, (long(*)(long(*)(long(*)()),long*,long(*)(long(*)()))) 100 ); cout << x << endl; // print 500 as expected return 0; } It works fine, but my colleague says that I shouldn't use C style casts. But I think that all that modern static_cast's and reinterpret_cast's will make my code too cumbersome. Who's right? Should I redesign my code using C++ style casts or is original code OK? EDIT: For those who marks this question as not a question I'll try to be more clear: should I use C++ style cast instead of C style cast in the code above?

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  • String to Integer Smalltalk

    - by Anton
    Pretty simple question I need to get an integer from the user and I only know how to get a string from them. So if there is a way to get an integer from the user or to convert the string to an integer please let me know.

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