Results generated by fwts: Version V0.26.07 (2013年03月15日 14:33:59). Some of this work - Copyright (c) 1999 - 2010, Intel Corp. All rights reserved. Some of this work - Copyright (c) 2010 - 2013, Canonical. This test run on 09/08/13 at 12:20:40 on host Linux MacBook-Air 3.8.0-19-generic #30-Ubuntu SMP Wed May 1 16:35:23 UTC 2013 x86_64. Command: "fwts --batch". Running tests: version bios_info oops mtrr klog acpiinfo securebootcert csm maxreadreq crs aspm hpet_check dmi_decode microcode msr nx cpufreq maxfreq virt smbios pnp pciirq os2gap mpcheck hda_audio ebda bios32 wmi wakealarm syntaxcheck pcc osilinux method mcfg fan fadt dmar cstates checksum apicinstance apicedge acpitables. version: Gather kernel system information. ---------------------------------------------------------------------------------------------------- Test 1 of 4: Gather kernel signature. Signature: Ubuntu 3.8.0-19.30-generic 3.8.8 Test 2 of 4: Gather kernel system information. Kernel Version: Linux version 3.8.0-19-generic (buildd@allspice) (gcc version 4.7.3 (Ubuntu/Linaro 4.7.3-1ubuntu1) ) #30-Ubuntu SMP Wed May 1 16:35:23 UTC 2013 Test 3 of 4: Gather kernel boot command line. Kernel boot command line: BOOT_IMAGE=/boot/vmlinuz-3.8.0-19-generic root=UUID=a3ffc5df-b62b-4117-bef6-86a107c5d1fa ro nosmp Test 4 of 4: Gather ACPI driver version. ACPI Version: 20121018 ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 4 info only. ==================================================================================================== bios_info: Gather BIOS DMI information. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Gather BIOS DMI information BIOS Vendor : Apple Inc. BIOS Version : MBA61.88Z.0099.B00.1305241529 BIOS Release Date : 05/24/2013 Board Name : Mac-7DF21CB3ED6977E5 Board Serial # : C0232720134FHDWAF Board Version : MacBookAir6,2 Board Asset Tag : Base Board Asset Tag# Chassis Serial # : C02L12VFF6T5 Chassis Type : 10 Chassis Vendor : Apple Inc. Chassis Version : Mac-7DF21CB3ED6977E5 Chassic Asset Tag : Product Name : MacBookAir6,2 Product Serial # : C02L12VFF6T5 Product UUID : 93BB9BC7-6717-6255-8EA1-0842FBA8ADCA Product Version : 1.0 System Vendor : Apple Inc. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 1 info only. ==================================================================================================== oops: Scan kernel log for Oopses. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Kernel log oops check. PASSED: Test 1, Found no oopses in kernel log. PASSED: Test 1, Found no WARN_ON warnings in kernel log. ==================================================================================================== 2 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== mtrr: MTRR validation. ---------------------------------------------------------------------------------------------------- MTRR overview ------------- Reg 0: 0x00000000c0000000 - 0x0000000100000000 ( 1024 MB) Uncached Reg 1: 0x00000000a0000000 - 0x00000000c0000000 ( 512 MB) Uncached Reg 2: 0x0000000090000000 - 0x00000000a0000000 ( 256 MB) Uncached Reg 3: 0x0000000088000000 - 0x0000000090000000 ( 128 MB) Uncached Reg 4: 0x0000000084000000 - 0x0000000088000000 ( 64 MB) Uncached Reg 5: 0x0000000083800000 - 0x0000000084000000 ( 8 MB) Uncached Test 1 of 3: Validate the kernel MTRR IOMEM setup. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x10000 to 0x57fff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x10000 to 0x57fff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x59000 to 0x8efff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x59000 to 0x8efff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x90000 to 0x9fbff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x90000 to 0x9fbff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x100000 to 0x82d13fff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x100000 to 0x82d13fff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x82d53000 to 0x82d63fff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x82d53000 to 0x82d63fff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x82d76000 to 0x82d76fff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x82d76000 to 0x82d76fff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x82d8f000 to 0x82f5dfff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x82d8f000 to 0x82f5dfff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x82ff0000 to 0x82ffffff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x82ff0000 to 0x82ffffff (System RAM) is lacking attribute Write-Back. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x90000000 to 0x9fffffff (0000:02:00.0) has incorrect attribute Uncached. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0xa0000000 to 0xafffffff (0000:00:02.0) has incorrect attribute Uncached. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0xbcc00000 to 0xbcc0ffff (0000:0a:00.0) has incorrect attribute Uncached. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0xbcc10000 to 0xbcc1ffff (0000:0a:00.0) has incorrect attribute Uncached. FAILED [MEDIUM] MTRRIncorrectAttr: Test 1, Memory range 0x100000000 to 0x26f5fffff (System RAM) has incorrect attribute Default. FAILED [MEDIUM] MTRRLackingAttr: Test 1, Memory range 0x100000000 to 0x26f5fffff (System RAM) is lacking attribute Write-Back. Test 2 of 3: Validate the MTRR setup across all processors. PASSED: Test 2, All processors have the a consistent MTRR setup. Test 3 of 3: Check for AMD MtrrFixDramModEn being cleared by the BIOS. SKIPPED: Test 3, CPU is not an AMD, cannot test. ==================================================================================================== 1 passed, 22 failed, 0 warnings, 0 aborted, 1 skipped, 0 info only. ==================================================================================================== klog: Scan kernel log for errors and warnings. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Kernel log error check. FAILED [LOW] KlogAcpiSystemIOConflict: Test 1, LOW Kernel message: [ 137.565004] ACPI Warning: 0x0000000000000830-0x000000000000083f SystemIO conflicts with Region \GPIO 1 (20121018 /utaddress-251) ADVICE: A resource conflict between an ACPI OperationRegion and a native driver has been detected. By default the kernel will use a strict policy and will not allow this region to conflict and -EBUSY will be returned to the caller that was trying to allocate the already claimed region. If an ACPI driver is available for this device then this should be used instead of a native driver, so disabling the native driver may help. One can specify kernel boot paramater acpi_enforce_resources=lax to disable these checks but it may lead to random problems and system instability. Alternatively, one can specify acpi_enforce_resources=no and ACPI Operation Region resources will not be registered. FAILED [LOW] KlogAcpiSystemIOConflict: Test 1, LOW Kernel message: [ 137.565012] ACPI Warning: 0x0000000000000800-0x000000000000082f SystemIO conflicts with Region \GPIO 1 (20121018 /utaddress-251) ADVICE: A resource conflict between an ACPI OperationRegion and a native driver has been detected. By default the kernel will use a strict policy and will not allow this region to conflict and -EBUSY will be returned to the caller that was trying to allocate the already claimed region. If an ACPI driver is available for this device then this should be used instead of a native driver, so disabling the native driver may help. One can specify kernel boot paramater acpi_enforce_resources=lax to disable these checks but it may lead to random problems and system instability. Alternatively, one can specify acpi_enforce_resources=no and ACPI Operation Region resources will not be registered. FAILED [LOW] KlogAcpiSystemIOConflict: Test 1, LOW Kernel message: [ 137.565015] ACPI Warning: 0x0000000000000800-0x000000000000082f SystemIO conflicts with Region \IO_D 2 (20121018 /utaddress-251) ADVICE: A resource conflict between an ACPI OperationRegion and a native driver has been detected. By default the kernel will use a strict policy and will not allow this region to conflict and -EBUSY will be returned to the caller that was trying to allocate the already claimed region. If an ACPI driver is available for this device then this should be used instead of a native driver, so disabling the native driver may help. One can specify kernel boot paramater acpi_enforce_resources=lax to disable these checks but it may lead to random problems and system instability. Alternatively, one can specify acpi_enforce_resources=no and ACPI Operation Region resources will not be registered. FAILED [LOW] KlogAcpiSystemIOConflict: Test 1, LOW Kernel message: [ 137.565018] ACPI Warning: 0x0000000000000800-0x000000000000082f SystemIO conflicts with Region \IO_T 3 (20121018 /utaddress-251) ADVICE: A resource conflict between an ACPI OperationRegion and a native driver has been detected. By default the kernel will use a strict policy and will not allow this region to conflict and -EBUSY will be returned to the caller that was trying to allocate the already claimed region. If an ACPI driver is available for this device then this should be used instead of a native driver, so disabling the native driver may help. One can specify kernel boot paramater acpi_enforce_resources=lax to disable these checks but it may lead to random problems and system instability. Alternatively, one can specify acpi_enforce_resources=no and ACPI Operation Region resources will not be registered. Found 4 unique errors in kernel log. ==================================================================================================== 0 passed, 4 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== acpiinfo: General ACPI information check. ---------------------------------------------------------------------------------------------------- Test 1 of 3: Determine Kernel ACPI version. Kernel ACPICA driver version: 20121018, supports ACPI 5.0 Test 2 of 3: Determine machines ACPI version. FACP ACPI Version: 5.0 Test 3 of 3: Determine AML compiler. Determine the compiler used to generate the ACPI AML in the DSDT and SSDT. Table DSDT, OEM APPLE , created with INTL (Intel) compiler. Table SSDT0, OEM APPLE , created with INTL (Intel) compiler. Table SSDT1, OEM APPLE , created with INTL (Intel) compiler. Table SSDT2, OEM APPLE , created with INTL (Intel) compiler. Table SSDT3, OEM APPLE , created with INTL (Intel) compiler. Table SSDT4, OEM APPLE , created with INTL (Intel) compiler. Table SSDT5, OEM PmRef, created with INTL (Intel) compiler. Table SSDT6, OEM PmRef, created with INTL (Intel) compiler. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 3 info only. ==================================================================================================== securebootcert: Ubuntu UEFI secure boot test. ---------------------------------------------------------------------------------------------------- Cannot detect any UEFI firmware. Aborted. Aborted test, initialisation failed. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 1 aborted, 0 skipped, 0 info only. ==================================================================================================== csm: Check for UEFI Compatibility Support Module. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check for UEFI Compatibility Support Module. Checking for UEFI Compatibility Support Module (CSM) Int 10h jumps to 0xc0014 in option ROM at: 0xc0000..0xcec00 No CSM: Legacy BIOS firmware has video option ROM with Int 10h support. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 1 info only. ==================================================================================================== maxreadreq: Checks firmware has set PCI Express MaxReadReq to a higher value on non-motherboard devices. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check firmware settings MaxReadReq for PCI Express devices. MaxReadReq for pci://00:00:03.0 Audio device: Intel Corporation Device 0a0c (rev 09) is low (128) [Audio device]. MaxReadReq for pci://00:00:1b.0 Audio device: Intel Corporation Lynx Point-LP HD Audio Controller (rev 04) is low (128) [Audio device]. FAILED [LOW] LowMaxReadReq: Test 1, 2 devices have low MaxReadReq settings. Firmware may have configured these too low. ADVICE: The MaxReadRequest size is set too low and will affect performance. It will provide excellent bus sharing at the cost of bus data transfer rates. Although not a critical issue, it may be worth considering setting the MaxReadRequest size to 256 or 512 to increase throughput on the PCI Express bus. Some drivers (for example the Brocade Fibre Channel driver) allow one to override the firmware settings. Where possible, this BIOS configuration setting is worth increasing it a little more for better performance at a small reduction of bus sharing. ==================================================================================================== 0 passed, 1 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== crs: Check PCI host bridge configuration using _CRS. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check PCI host bridge configuration using _CRS. SKIPPED: Test 1, Cannot find host bridge message in kernel log, skipping test. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 1 skipped, 0 info only. ==================================================================================================== aspm: PCIe ASPM check. ---------------------------------------------------------------------------------------------------- Test 1 of 2: PCIe ASPM ACPI test. PCIe ASPM is controlled by Linux kernel. Test 2 of 2: PCIe ASPM registers test. PASSED: Test 2, PCIe ASPM setting matched was matched. PASSED: Test 2, PCIe ASPM setting matched was matched. WARNING: Test 2, RP 00h:1Ch.04h L0s not enabled. WARNING: Test 2, RP 00h:1Ch.04h L1 not enabled. WARNING: Test 2, Device 05h:00h.00h L0s not enabled. WARNING: Test 2, Device 05h:00h.00h L1 not enabled. ADVICE: The ASPM L0s low power Link state is optimized for short entry and exit latencies, while providing substantial power savings. Disabling L0s of a PCIe device may increases power consumption, and will impact the battery life of a mobile system. ADVICE: The ASPM L1 low power Link state is optimized for maximum power savings with longer entry and exit latencies. Disabling L1 of a PCIe device may increases power consumption, and will impact the battery life of a mobile system significantly. PASSED: Test 2, PCIe ASPM setting matched was matched. PASSED: Test 2, PCIe ASPM setting matched was matched. WARNING: Test 2, RP 05h:00h.00h L0s not enabled. WARNING: Test 2, RP 05h:00h.00h L1 not enabled. WARNING: Test 2, Device 06h:00h.00h L0s not enabled. WARNING: Test 2, Device 06h:00h.00h L1 not enabled. ADVICE: The ASPM L0s low power Link state is optimized for short entry and exit latencies, while providing substantial power savings. Disabling L0s of a PCIe device may increases power consumption, and will impact the battery life of a mobile system. ADVICE: The ASPM L1 low power Link state is optimized for maximum power savings with longer entry and exit latencies. Disabling L1 of a PCIe device may increases power consumption, and will impact the battery life of a mobile system significantly. PASSED: Test 2, PCIe ASPM setting matched was matched. WARNING: Test 2, RP 06h:00h.00h L0s not enabled. WARNING: Test 2, RP 06h:00h.00h L1 not enabled. WARNING: Test 2, Device 07h:00h.00h L0s not enabled. WARNING: Test 2, Device 07h:00h.00h L1 not enabled. ADVICE: The ASPM L0s low power Link state is optimized for short entry and exit latencies, while providing substantial power savings. Disabling L0s of a PCIe device may increases power consumption, and will impact the battery life of a mobile system. ADVICE: The ASPM L1 low power Link state is optimized for maximum power savings with longer entry and exit latencies. Disabling L1 of a PCIe device may increases power consumption, and will impact the battery life of a mobile system significantly. PASSED: Test 2, PCIe ASPM setting matched was matched. WARNING: Test 2, RP 06h:03h.00h L0s not enabled. WARNING: Test 2, RP 06h:03h.00h L1 not enabled. WARNING: Test 2, Device 08h:00h.00h L0s not enabled. WARNING: Test 2, Device 08h:00h.00h L1 not enabled. ADVICE: The ASPM L0s low power Link state is optimized for short entry and exit latencies, while providing substantial power savings. Disabling L0s of a PCIe device may increases power consumption, and will impact the battery life of a mobile system. ADVICE: The ASPM L1 low power Link state is optimized for maximum power savings with longer entry and exit latencies. Disabling L1 of a PCIe device may increases power consumption, and will impact the battery life of a mobile system significantly. PASSED: Test 2, PCIe ASPM setting matched was matched. WARNING: Test 2, RP 08h:00h.00h L0s not enabled. WARNING: Test 2, RP 08h:00h.00h L1 not enabled. WARNING: Test 2, Device 09h:00h.00h L1 not enabled. ADVICE: The ASPM L0s low power Link state is optimized for short entry and exit latencies, while providing substantial power savings. Disabling L0s of a PCIe device may increases power consumption, and will impact the battery life of a mobile system. ADVICE: The ASPM L1 low power Link state is optimized for maximum power savings with longer entry and exit latencies. Disabling L1 of a PCIe device may increases power consumption, and will impact the battery life of a mobile system significantly. FAILED [MEDIUM] PCIEASPM_Unmatched: Test 2, PCIe ASPM setting was not matched. RP 08h:00h.00h has ASPM = 00h. Device 09h:00h.00h has ASPM = 01h. ADVICE: ASPM control registers between root port and device must match in order for ASPM to be active. Unmatched configuration indicates software did not configure ASPM correctly and the system is not saving power at its full potential. WARNING: Test 2, RP 09h:00h.00h L1 not enabled. WARNING: Test 2, Device 0Ah:00h.00h L0s not enabled. WARNING: Test 2, Device 0Ah:00h.00h L1 not enabled. ADVICE: The ASPM L0s low power Link state is optimized for short entry and exit latencies, while providing substantial power savings. Disabling L0s of a PCIe device may increases power consumption, and will impact the battery life of a mobile system. ADVICE: The ASPM L1 low power Link state is optimized for maximum power savings with longer entry and exit latencies. Disabling L1 of a PCIe device may increases power consumption, and will impact the battery life of a mobile system significantly. FAILED [MEDIUM] PCIEASPM_Unmatched: Test 2, PCIe ASPM setting was not matched. RP 09h:00h.00h has ASPM = 01h. Device 0Ah:00h.00h has ASPM = 00h. ADVICE: ASPM control registers between root port and device must match in order for ASPM to be active. Unmatched configuration indicates software did not configure ASPM correctly and the system is not saving power at its full potential. ==================================================================================================== 7 passed, 2 failed, 22 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== hpet_check: HPET configuration test. ---------------------------------------------------------------------------------------------------- Test 1 of 4: Check HPET base in kernel log. This test checks the HPET PCI BAR for each timer block in the timer. The base address is passed by the firmware via an ACPI table. IRQ routing and initialization is also verified by the test. No base address found for HPET. Test 2 of 4: Check HPET base in HPET table. Hardware ID of Event Block: PCI Vendor ID : 0x8086 Legacy IRQ Routing Capable : 1 COUNT_SIZE_CAP counter size: 1 Number of comparitors : 2 Hardwre Revision ID : 0x1 Lower 32 bit base Address : 0xfed00000 Address Space ID : 0x0 Register Bit Width : 0x40 Register Bit Offset : 0x0 Address Width : 0x0 HPET sequence number : 0x0 Minimum clock tick : 0x80 Page Protection : 0x0 (No guaranteed protection) OEM attributes : 0x0 PASSED: Test 2, HPET looks sane. Test 3 of 4: Check HPET base in DSDT and/or SSDT. Test 4 of 4: Sanity check HPET configuration. Test skipped because previous test failed. ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== dmi_decode: Test DMI/SMBIOS tables for errors. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Test DMI/SMBIOS tables for errors. FAILED [HIGH] DMIValueOutOfRange: Test 1, Out of range value 0x2e (range allowed 0x01..0x2a) while accessing entry 'Processor Information (Type 4)' @ 0x000e0000, field 'Upgrade', offset 0x19 ADVICE: A value that is out of range is incorrect and not conforming to the SMBIOS specification. This field is not currently used by the Linux kernel, so this firmware bug shouldn't cause any problems. FAILED [LOW] DMIBadDefault: Test 1, String index 0x03 in table entry 'Processor Information (Type 4)' @ 0x000e0000, field 'Serial Number', offset 0x20 has a default value 'To Be Filled By O.E.M.' and probably has not been updated by the BIOS vendor. ADVICE: The DMI table contains data which is clearly been left in a default setting and not been configured for this machine. Somebody has probably forgotten to define this field and it basically means this field is effectively useless, however the kernel does not use this data so the issue is fairly low. FAILED [LOW] DMIBadDefault: Test 1, String index 0x05 in table entry 'Processor Information (Type 4)' @ 0x000e0000, field 'Asset Tag', offset 0x21 has a default value 'To Be Filled By O.E.M.' and probably has not been updated by the BIOS vendor. ADVICE: The DMI table contains data which is clearly been left in a default setting and not been configured for this machine. Somebody has probably forgotten to define this field and it basically means this field is effectively useless, however the kernel does not use this data so the issue is fairly low. ADVICE: It may be worth checking against section 7.5 of the System Management BIOS (SMBIOS) Reference Specification (see http://www.dmtf.org/standards/smbios). PASSED: Test 1, Entry @ 0x000e0095 'Cache Information (Type 7)' PASSED: Test 1, Entry @ 0x000e00aa 'Cache Information (Type 7)' PASSED: Test 1, Entry @ 0x000e00bf 'Cache Information (Type 7)' PASSED: Test 1, Entry @ 0x000e00d4 'Cache Information (Type 7)' PASSED: Test 1, Entry @ 0x000e00e9 'Physical Memory Array (Type 16)' PASSED: Test 1, Entry @ 0x000e00fa 'Unknown (Type 130)' PASSED: Test 1, Entry @ 0x000e01b6 'Memory Device (Type 17)' PASSED: Test 1, Entry @ 0x000e0220 'Unknown (Type 130)' PASSED: Test 1, Entry @ 0x000e02dc 'Memory Device (Type 17)' PASSED: Test 1, Entry @ 0x000e0346 'Memory Array Mapped Address (Type 19)' PASSED: Test 1, Entry @ 0x000e0357 'BIOS Information (Type 0)' PASSED: Test 1, Entry @ 0x000e03a4 'System Information (Type 1)' PASSED: Test 1, Entry @ 0x000e0402 'Base Board Information (Type 2)' PASSED: Test 1, Entry @ 0x000e0478 'Chassis Information (Type 3)' PASSED: Test 1, Entry @ 0x000e04bb 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e04cf 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e04e3 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e0503 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e0517 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e0531 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e0548 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e0568 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e0586 'Port Connector Information (Type 8)' PASSED: Test 1, Entry @ 0x000e05a4 'System Slot Information (Type 9)' PASSED: Test 1, Entry @ 0x000e05ba 'System Slot Information (Type 9)' PASSED: Test 1, Entry @ 0x000e05db 'System Slot Information (Type 9)' PASSED: Test 1, Entry @ 0x000e05fc 'System Slot Information (Type 9)' PASSED: Test 1, Entry @ 0x000e061d 'System Slot Information (Type 9)' PASSED: Test 1, Entry @ 0x000e063e 'On Board Devices (Type 10)' PASSED: Test 1, Entry @ 0x000e0661 'On Board Devices (Type 10)' PASSED: Test 1, Entry @ 0x000e067b 'On Board Devices (Type 10)' PASSED: Test 1, Entry @ 0x000e0687 'OEM Strings (Type 11)' PASSED: Test 1, Entry @ 0x000e074d 'System Configuration Options (Type 12)' FAILED [LOW] DMIStringIndexOutOfRange: Test 1, Out of range string index 0x01 while accessing entry 'BIOS Language Information (Type 13)' @ 0x000e0754, field 'BIOS Language String 1', offset 0x04 ADVICE: DMI strings are stored in a manner that uses a special index to fetch the Nth string from the data. For this particular DMI string the index given is not in range which means this particular entry is broken. The Linux kernel does not use this string, so this error will not cause any system errors. ADVICE: It may be worth checking against section 7.14 of the System Management BIOS (SMBIOS) Reference Specification (see http://www.dmtf.org/standards/smbios). PASSED: Test 1, Entry @ 0x000e076c 'System Boot Information (Type 32)' PASSED: Test 1, Entry @ 0x000e0782 'Unknown (Type 131)' PASSED: Test 1, Entry @ 0x000e078a 'Unknown (Type 128)' PASSED: Test 1, Entry @ 0x000e07e4 'Unknown (Type 221)' FAILED [HIGH] DMIInvalidEntryLength: Test 1, Invald header length of entry #39, length was 0x00. ADVICE: DMI entry header lengths must be 4 or more bytes long so this error indicates that the DMI table is unreliable and DMI table checking has been aborted at entry #39. FAILED [MEDIUM] DMIBadTableLength: Test 1, DMI table length was 2509 bytes (as specified by the SMBIOS header) but the DMI entries used 2098 bytes. FAILED [MEDIUM] DMIStructCount: Test 1, DMI table was DMI 42 entries in size (as specified by the SMBIOS header) but only 39 DMI entries were found. ==================================================================================================== 37 passed, 7 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== microcode: Check if system is using latest microcode. ---------------------------------------------------------------------------------------------------- Cannot read microcode file /usr/share/misc/intel-microcode.dat. Aborted test, initialisation failed. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 1 aborted, 0 skipped, 0 info only. ==================================================================================================== msr: MSR register tests. ---------------------------------------------------------------------------------------------------- Test 1 of 5: Check CPU generic MSRs. PASSED: Test 1, MSR P5_MC_TYPE (0x1) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MONITOR_FILTER_SIZE (0x6) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR PLATFORM_ID (0x17) (mask:1c000000000000) was consistent across 1 CPUs. PASSED: Test 1, MSR EBL_CR_POWERON (0x2a) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR APIC_BASE (0x1b) (mask:fffffffffffffeff) was consistent across 1 CPUs. PASSED: Test 1, MSR FEATURE_CONTROL (0x3a) (mask:ff07) was consistent across 1 CPUs. PASSED: Test 1, MSR BIOS_SIGN_ID (0x8b) (mask:ffffffff00000000) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRRCAP (0xfe) (mask:fff) was consistent across 1 CPUs. PASSED: Test 1, MSR SYSENTER_CS (0x174) (mask:ffff) was consistent across 1 CPUs. PASSED: Test 1, MSR SYSENTER_ESP (0x175) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR SYSENTER_EIP (0x176) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MCG_CAP (0x179) (mask:1ff0fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MCG_STATUS (0x17a) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR CLOCK_MODULATION (0x19a) (mask:1f) was consistent across 1 CPUs. PASSED: Test 1, MSR THERM_INTERRUPT (0x19b) (mask:180801f) was consistent across 1 CPUs. PASSED: Test 1, MSR MISC_ENABLE (0x1a0) (mask:400c51889) was consistent across 1 CPUs. PASSED: Test 1, MSR PACKAGE_THERM_INTERRUPT (0x1b2) (mask:1ffff17) was consistent across 1 CPUs. PASSED: Test 1, MSR SMRR_PHYSBASE (0x1f2) (mask:fffff0ff) was consistent across 1 CPUs. PASSED: Test 1, MSR SMRR_PHYSMASK (0x1f3) (mask:fffff800) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE0 (0x200) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK0 (0x201) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE1 (0x202) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK1 (0x203) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE2 (0x204) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK2 (0x205) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE3 (0x206) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK3 (0x207) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE4 (0x208) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK4 (0x209) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE5 (0x20a) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK5 (0x20b) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE6 (0x20c) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK6 (0x20d) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE7 (0x20e) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK7 (0x20f) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE8 (0x210) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK8 (0x211) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSBASE9 (0x212) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_PHYSMASK9 (0x213) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX64K_000 (0x250) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX16K_800 (0x258) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX16K_a00 (0x259) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_C000 (0x268) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_C800 (0x269) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_D000 (0x26a) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_D800 (0x26b) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_E000 (0x26c) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_E800 (0x26d) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_F000 (0x26e) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_FIX4K_F800 (0x26f) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR PAT (0x277) (mask:707070707070703) was consistent across 1 CPUs. PASSED: Test 1, MSR MC0_CTL2 (0x280) (mask:40007fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MC1_CTL2 (0x281) (mask:40007fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MC2_CTL2 (0x282) (mask:40007fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MC3_CTL2 (0x283) (mask:40007fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MC4_CTL2 (0x284) (mask:40007fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MC5_CTL2 (0x285) (mask:40007fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MC6_CTL2 (0x286) (mask:40007fff) was consistent across 1 CPUs. PASSED: Test 1, MSR MTRR_DEF_TYPE (0x2ff) (mask:c0f) was consistent across 1 CPUs. PASSED: Test 1, MSR PEBS_ENABLE (0x3f1) (mask:1) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_BASIC (0x480) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_PINPASED_CTLS (0x481) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_PROCBASED_CTLS (0x482) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_EXIT_CTLS (0x483) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_ENTRY_CTLS (0x484) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_MISC (0x485) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_CR0_FIXED0 (0x486) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_CR0_FIXED1 (0x487) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_CR4_FIXED0 (0x488) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_CR4_FIXED1 (0x489) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_VMX_VMCS_ENUM (0x48a) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_PROCBASED_CTLS2 (0x48b) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_EPT_VPID_CAP (0x48c) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_TRUE_PINBASED_CTLS (0x48d) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_TRUE_PROCBASED_CTLS (0x48e) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_TRUE_EXIT_CTLS (0x48f) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR VMX_TRUE_ENTRY_CTLS (0x490) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR EFER (0xc0000080) (mask:d01) was consistent across 1 CPUs. PASSED: Test 1, MSR STAR (0xc0000081) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR LSTAR (0xc0000082) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR FMASK (0xc0000084) (mask:ffffffffffffffff) was consistent across 1 CPUs. PASSED: Test 1, MSR KERNEL_GS_BASE (0xc0000102) (mask:ffffffffffffffff) was consistent across 1 CPUs. Test 2 of 5: Check CPU specific model MSRs. No model specific tests for model 0x45. Test 3 of 5: Check all P State Ratios. PASSED: Test 3, MSR Minimum P-State (0xce) (mask:ff) was consistent across 1 CPUs. PASSED: Test 3, MSR Maximum P-State (0xce) (mask:ff) was consistent across 1 CPUs. Test 4 of 5: Check C1 and C3 autodemotion. PASSED: Test 4, MSR C1 and C3 Autodemotion (0xe2) (mask:3) was consistent across 1 CPUs. C1 and C3 Autodemotion disabled. Test 5 of 5: Check SMRR MSR registers. PASSED: Test 5, MSR SMRR_PHYSBASE (0x1f2) (mask:fffff) was consistent across 1 CPUs. PASSED: Test 5, MSR SMRR_TYPE (0x1f2) (mask:7) was consistent across 1 CPUs. PASSED: Test 5, MSR SMRR_PHYSMASK (0x1f3) (mask:fffff) was consistent across 1 CPUs. PASSED: Test 5, MSR SMRR_VALID (0x1f3) (mask:1) was consistent across 1 CPUs. ==================================================================================================== 89 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== nx: Test if CPU NX is disabled by the BIOS. ---------------------------------------------------------------------------------------------------- Test 1 of 3: Check CPU NX capability. PASSED: Test 1, CPU has NX flags, BIOS is not disabling it. Test 2 of 3: Check all CPUs have same BIOS set NX flag. This test verifies that all CPUs have the same NX flag setting. Although rare, BIOS may set the NX flag differently per CPU. Only one CPU, no need to run test. Test 3 of 3: Check all CPUs have same msr setting in MSR 0x1a0. This test verifies that all CPUs have the same NX flag setting by examining the per CPU MSR register 0x1a0. PASSED: Test 3, All 1 CPUs have the NX flag in MSR 0x1a0 set. ==================================================================================================== 2 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== cpufreq: CPU frequency scaling tests (takes ~1-2 mins). ---------------------------------------------------------------------------------------------------- Test 1 of 1: CPU P-State Checks. For each processor in the system, this test steps through the various frequency states (P-states) that the BIOS advertises for the processor. For each processor/frequency combination, a quick performance value is measured. The test then validates that: 1. Each processor has the same number of frequency states. 2. Higher advertised frequencies have a higher performance. 3. No duplicate frequency values are reported by the BIOS. 4. BIOS doing Sw_All P-state coordination across cores. 5. BIOS doing Sw_Any P-state coordination across cores. CPU 0: 18 CPU frequency steps supported. Frequency | Relative Speed | Bogo loops -----------+----------------+----------- 2.35 GHz | 79.5 % | 128127 2.35 GHz | 49.9 % | 80503 2.25 GHz | 99.9 % | 160966 2.15 GHz | 98.3 % | 158449 2.05 GHz | 99.0 % | 159613 1.95 GHz | 100.0 % | 161185 1.85 GHz | 100.0 % | 161160 1.75 GHz | 100.0 % | 161149 1.65 GHz | 94.0 % | 151561 1500 MHz | 94.1 % | 151610 1400 MHz | 92.0 % | 148296 1300 MHz | 94.1 % | 151642 1200 MHz | 94.0 % | 151466 1100 MHz | 94.0 % | 151568 1000 MHz | 93.3 % | 150314 900 MHz | 92.2 % | 148586 800 MHz | 94.1 % | 151656 759 MHz | 94.1 % | 151646 FAILED [MEDIUM] CPUFreqSlowerOnCPU: Test 1, Supposedly higher frequency 900 MHz is slower (148586 bogo loops) than frequency 900 MHz (151656 bogo loops) on CPU 0. FAILED [MEDIUM] CPUFreqSlowerOnCPU: Test 1, Supposedly higher frequency 1200 MHz is slower (151466 bogo loops) than frequency 1200 MHz (151568 bogo loops) on CPU 0. FAILED [MEDIUM] CPUFreqSlowerOnCPU: Test 1, Supposedly higher frequency 1400 MHz is slower (148296 bogo loops) than frequency 1400 MHz (151642 bogo loops) on CPU 0. FAILED [MEDIUM] CPUFreqSlowerOnCPU: Test 1, Supposedly higher frequency 1.65 GHz is slower (151561 bogo loops) than frequency 1.65 GHz (151610 bogo loops) on CPU 0. WARNING: Test 1, Frequency 1800000 not achievable; _PSS limit of 1700000 in effect? FAILED [MEDIUM] CPUFreqSlowerOnCPU: Test 1, Supposedly higher frequency 2.05 GHz is slower (159613 bogo loops) than frequency 2.05 GHz (161185 bogo loops) on CPU 0. FAILED [MEDIUM] CPUFreqSlowerOnCPU: Test 1, Supposedly higher frequency 2.15 GHz is slower (158449 bogo loops) than frequency 2.15 GHz (159613 bogo loops) on CPU 0. FAILED [MEDIUM] CPUFreqSlowerOnCPU: Test 1, Supposedly higher frequency 2.35 GHz is slower (80503 bogo loops) than frequency 2.35 GHz (160966 bogo loops) on CPU 0. ==================================================================================================== 0 passed, 7 failed, 1 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== maxfreq: Check max CPU frequencies against max scaling frequency. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Maximum CPU frequency check. This test checks the maximum CPU frequency as detected by the kernel for each CPU against maxiumum frequency as specified by the BIOS frequency scaling settings. FAILED [MEDIUM] CPUFreqSpeedMismatch: Test 1, Maximum scaling frequency 2.301000 GHz do not match expected frequency 1.700000 GHz ADVICE: The maximum scaling frequency 2.301000 GHz for CPU 0 configured by the BIOS in /sys/devices /system/cpu/cpu0/cpufreq/scaling_available_frequencies does not match the expected maximum CPU frequency 1.700000 GHz that the CPU can run at. This usually indicates a misconfiguration of the ACPI _PSS (Performance Supported States) object. This is described in section 8.4.4.2 of the APCI specification. ==================================================================================================== 0 passed, 1 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== virt: Test CPU Virtualisation Configuration. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check CPU Virtualisation Configuration. Check VT/VMX Virtualization extensions are set up correctly. PASSED: Test 1, Virtualization extensions supported and enabled by BIOS. ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== smbios: Check SMBIOS. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Find and Check SMBIOS Table Entry Point. This test tries to find and sanity check the SMBIOS data structures. PASSED: Test 1, Found SMBIOS Table Entry Point at 0xfe110 SMBIOS Entry Point Structure: Anchor String : _SM_ Checksum : 0xab Entry Point Length : 0x1f Major Version : 0x02 Minor Version : 0x04 Maximum Struct Size : 0xd2 Entry Point Revision : 0x00 Formatted Area : 0x00 0x00 0x00 0x00 0x00 Intermediate Anchor : _DMI_ Intermediate Checksum : 0x36 Structure Table Length : 0x09cd Structure Table Address: 0x000e0000 # of SMBIOS Structures : 0x002a SBMIOS BCD Revision : 24 ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== pnp: Check BIOS Support Installation structure. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check PnP BIOS Support Installation structure. This test tries to find and sanity check the Plug and Play BIOS Support Installation Check structure. Found PnP Installation Check structure at 0x000fe0e0 Signature : $PnP Version : 0x10 (1.0) Length : 0x0021 bytes Control Field : 0x0000 (Not supported) Event Notification Flag Address : 0x00000000 (undefined) Real Mode 16 bit Code Address : 0xf000:bc94 Real Mode 16 bit Data Address : 0x0040:0000 16 bit Protected Mode Code Address : 0x000fbc9f 16 bit Protected Mode Data Address : 0x00000400 OEM Device Identifier : 0x8224744e (SST2482) PASSED: Test 1, Version 1.0 detected. PASSED: Test 1, PnP Installation Check structure is the correct length of 33 bytes. ==================================================================================================== 2 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== pciirq: Check PCI IRQ Routing Table. ---------------------------------------------------------------------------------------------------- Test 1 of 1: PCI IRQ Routing Table. This test tries to find and sanity check the PCI IRQ Routing Table, as defined by http: //www.microsoft.com/taiwan/whdc/archive/pciirq.mspx and described in pages 233-238 of PCI System Architecture, Fourth Edition, Mindshare, Inc. (1999). NOTE: The PCI IRQ Routing Table only really knows about ISA IRQs and is generally not used with APIC. Could not find PCI IRQ Routing Table. Since this table is for legacy BIOS systems which don't have ACPI support this is generally not a problem. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== os2gap: OS/2 memory hole test. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check the OS/2 15Mb memory hole is absent. PASSED: Test 1, No OS/2 memory hole found. ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== mpcheck: Check MultiProcessor Tables. ---------------------------------------------------------------------------------------------------- Failed to get _MP_ data from firmware. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 9 skipped, 0 info only. ==================================================================================================== hda_audio: Check HDA Audio Pin Configs. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check HDA Audio Pin Configs. Checking 'hwC0D0': Vendor Name : Intel Vendor ID : 0x80862807 Subsystem ID : 0x80860101 Revision ID : 0x100000 BIOS pin configurations: Pin Setting 0x0003 0x18560010 PASSED: Test 1, Default BIOS pin configurations did not have software override. Checking 'hwC1D0': Vendor Name : Cirrus Logic Vendor ID : 0x10134208 Subsystem ID : 0x106b7200 Revision ID : 0x100300 BIOS pin configurations: Pin Setting 0x0010 0x002b4020 0x0011 0x400000f0 0x0012 0x90100110 0x0013 0x400000f0 0x0014 0x400000f0 0x0015 0x400000f0 0x0016 0x400000f0 0x0017 0x400000f0 0x0018 0x00ab9030 0x0019 0x400000f0 0x001a 0x400000f0 0x001b 0x400000f0 0x001c 0x90a60100 0x001d 0x400000f0 0x001e 0x400000f0 0x001f 0x400000f0 0x0020 0x400000f0 0x0021 0x400000f0 0x0022 0x400000f0 PASSED: Test 1, Default BIOS pin configurations did not have software override. ==================================================================================================== 2 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== ebda: Validate EBDA region is mapped and reserved in memory map table. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check EBDA is reserved in E820 table. The Extended BIOS Data Area (EBDA) is normally located at the end of the low 640K region and is typically 2-4K in size. It should be reserved in the Int 15 AX=E820 BIOS memory map table. PASSED: Test 1, EBDA region mapped at 0x9fc00 and reserved as a 128K region in the Int 15 AX=E820 BIOS memory map table at 0x9fc00..0xbffff. ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== bios32: Check BIOS32 Service Directory. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check BIOS32 Service Directory. This test tries to find and sanity check the BIOS32 Service Directory as defined in the Standard BIOS 32-bit Service Directory Proposal, Revision 0.4 May 24, 1993, Phoenix Technologies Ltd and also the PCI BIOS specification. Could not find BIOS32 Service Directory. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== wmi: Extract and analyse Windows Management Instrumentation (WMI). ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check Windows Management Instrumentation No ACPI _WDG WMI data found. ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== wakealarm: Test ACPI Wakealarm. ---------------------------------------------------------------------------------------------------- Test 1 of 4: Check existence of /sys/class/rtc/rtc0/wakealarm. PASSED: Test 1, /sys/class/rtc/rtc0/wakealarm found. Test 2 of 4: Trigger wakealarm for 1 seconds in the future. Trigger wakealarm for 1 seconds in the future. PASSED: Test 2, RTC wakealarm was triggered successfully. Test 3 of 4: Check if wakealarm is fired. PASSED: Test 3, RTC wakealarm triggered and fired successfully. Test 4 of 4: Multiple wakealarm firing tests. Trigger wakealarm for 1 seconds in the future. Trigger wakealarm for 2 seconds in the future. Trigger wakealarm for 3 seconds in the future. Trigger wakealarm for 4 seconds in the future. PASSED: Test 4, RTC wakealarm triggered and fired successfully. ==================================================================================================== 4 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== syntaxcheck: Re-assemble DSDT and find syntax errors and warnings. ---------------------------------------------------------------------------------------------------- Test 1 of 2: Disassemble and reassemble DSDT Checking ACPI table DSDT (#0) PASSED: Test 1, DSDT (0) reassembly, Found 0 errors, 0 warnings. Test 2 of 2: Disassemble and reassemble SSDT Checking ACPI table SSDT (#0) PASSED: Test 2, SSDT (0) reassembly, Found 0 errors, 0 warnings. Checking ACPI table SSDT (#1) FAILED [HIGH] AMLAsmASL_MSG_SYNTAX: Test 2, Assembler error in line 22 Line | AML source ---------------------------------------------------------------------------------------------------- 00019| 00020| DefinitionBlock ("/tmp/fwts_iasl_5024.aml", "SSDT", 1, "APPLE ", "SmcDppt", 0x00001000) 00021| { ==================================================================================================== ADVICE: (for error #4124, ASL_MSG_SYNTAX): The disassembled code cannot be reassembled using the strict IASL compiler as it contains syntax errors. Table SSDT (1) reassembly: Found 1 errors, 0 warnings. Checking ACPI table SSDT (#2) FAILED [MEDIUM] AMLAsmASL_MSG_RESULT_NOT_USED: Test 2, Assembler warning in line 84 Line | AML source ---------------------------------------------------------------------------------------------------- 00081| } 00082| }, Local0) 00083| DTGP (Arg0, Arg1, Arg2, Arg3) 00084| RefOf (Local0) | ^ | warning (level 0) 1113: Result is not used, operator has no effect 00085| Return (Local0) 00086| } 00087| ==================================================================================================== ADVICE: (for warning (level 0) #1113, ASL_MSG_RESULT_NOT_USED): The result from an operation is not used. This is probably not intended and could be a bug and should be checked. Table SSDT (2) reassembly: Found 0 errors, 1 warnings. Checking ACPI table SSDT (#3) FAILED [MEDIUM] AMLAsmASL_MSG_RESULT_NOT_USED: Test 2, Assembler warning in line 583 Line | AML source ---------------------------------------------------------------------------------------------------- 00580| } 00581| }, Local0) 00582| DTGP (Arg0, Arg1, Arg2, Arg3) 00583| RefOf (Local0) | ^ | warning (level 0) 1113: Result is not used, operator has no effect 00584| Return (Local0) 00585| } 00586| ==================================================================================================== ADVICE: (for warning (level 0) #1113, ASL_MSG_RESULT_NOT_USED): The result from an operation is not used. This is probably not intended and could be a bug and should be checked. FAILED [MEDIUM] AMLAsmASL_MSG_RESULT_NOT_USED: Test 2, Assembler warning in line 2426 Line | AML source ---------------------------------------------------------------------------------------------------- 02423| 0x01 02424| }, Local0) 02425| DTGP (Arg0, Arg1, Arg2, Arg3) 02426| RefOf (Local0) | ^ | warning (level 0) 1113: Result is not used, operator has no effect 02427| Return (Local0) 02428| } 02429| } ==================================================================================================== ADVICE: (for warning (level 0) #1113, ASL_MSG_RESULT_NOT_USED): The result from an operation is not used. This is probably not intended and could be a bug and should be checked. Table SSDT (3) reassembly: Found 0 errors, 2 warnings. Checking ACPI table SSDT (#4) PASSED: Test 2, SSDT (4) reassembly, Found 0 errors, 0 warnings. Checking ACPI table SSDT (#5) PASSED: Test 2, SSDT (5) reassembly, Found 0 errors, 0 warnings. Checking ACPI table SSDT (#6) FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 121 Line | AML source ---------------------------------------------------------------------------------------------------- 00118| 00119| Store (CPDC (Arg0), Local0) 00120| GCAP (Local0) 00121| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00122| } 00123| 00124| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 268 Line | AML source ---------------------------------------------------------------------------------------------------- 00265| { 00266| Store (\_PR.CPU0.CPDC (Arg0), Local0) 00267| GCAP (Local0) 00268| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00269| } 00270| 00271| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 339 Line | AML source ---------------------------------------------------------------------------------------------------- 00336| { 00337| Store (\_PR.CPU0.CPDC (Arg0), Local0) 00338| GCAP (Local0) 00339| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00340| } 00341| 00342| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 386 Line | AML source ---------------------------------------------------------------------------------------------------- 00383| { 00384| Store (\_PR.CPU0.CPDC (Arg0), Local0) 00385| GCAP (Local0) 00386| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00387| } 00388| 00389| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 433 Line | AML source ---------------------------------------------------------------------------------------------------- 00430| { 00431| Store (\_PR.CPU0.CPDC (Arg0), Local0) 00432| GCAP (Local0) 00433| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00434| } 00435| 00436| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 480 Line | AML source ---------------------------------------------------------------------------------------------------- 00477| { 00478| Store (\_PR.CPU0.CPDC (Arg0), Local0) 00479| GCAP (Local0) 00480| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00481| } 00482| 00483| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 527 Line | AML source ---------------------------------------------------------------------------------------------------- 00524| { 00525| Store (\_PR.CPU0.CPDC (Arg0), Local0) 00526| GCAP (Local0) 00527| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00528| } 00529| 00530| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. FAILED [MEDIUM] AMLAsmASL_MSG_RESERVED_NO_RETURN_VAL: Test 2, Assembler warning in line 574 Line | AML source ---------------------------------------------------------------------------------------------------- 00571| { 00572| Store (\_PR.CPU0.CPDC (Arg0), Local0) 00573| GCAP (Local0) 00574| Return (Local0) | ^ | warning (level 0) 1104: Reserved method should not return a value (_PDC) 00575| } 00576| 00577| Method (_OSC, 4, NotSerialized) // _OSC: Operating System Capabilities ==================================================================================================== ADVICE: (for warning (level 0) #1104, ASL_MSG_RESERVED_NO_RETURN_VAL): A reserved method returned a value however it is not expected to return anything, so this does not conform to the expected behaviour. The kernel will most probably ignore the return value, so this is not going to produce any run time errors. Table SSDT (6) reassembly: Found 0 errors, 8 warnings. ==================================================================================================== 4 passed, 12 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== pcc: Processor Clocking Control (PCC) Test. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check PCCH. This test checks the sanity of the Processor Clocking Control as found on some HP ProLiant machines. Most computers do not use this interface to control the CPU clock frequency, so this test will be skipped. This machine does not use Processor Clocking Control (PCC). ==================================================================================================== 0 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 1 info only. ==================================================================================================== osilinux: Disassemble DSDT to check for _OSI("Linux"). ---------------------------------------------------------------------------------------------------- Test 1 of 1: Disassemble DSDT to check for _OSI("Linux"). This is not strictly a failure mode, it just alerts one that this has been defined in the DSDT and probably should be avoided since the Linux ACPI driver matches onto the Windows _OSI strings { Store (0x2710, OSYS) } If (\_OSI ("Linux")) { Store (0x03E8, OSYS) } If (\_OSI ("Windows 2009")) { Store (0x07D9, OSYS) } If (\_OSI ("Windows 2012")) { Store (0x07DC, OSYS) } } WARNING: Test 1, DSDT implements a deprecated _OSI("Linux") test. { If (_OSI ("Linux")) { Store (0x03E8, OSYS) } Else { If (_OSI ("Windows 2009")) { Store (0x07D9, OSYS) } WARNING: Test 1, DSDT implements a deprecated _OSI("Linux") test. ==================================================================================================== 0 passed, 0 failed, 2 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== method: ACPI DSDT Method Semantic Tests. ---------------------------------------------------------------------------------------------------- Test 1 of 144: Check Method Names. Found 2283 Objects PASSED: Test 1, Method names contain legal characters. Test 2 of 144: Check _AEI. SKIPPED: Test 2, Skipping test for non-existant object _AEI. Test 3 of 144: Check _DDN (DOS Device Name). PASSED: Test 3, \_SB_.PCI0.SPI1._DDN correctly returned a string. Test 4 of 144: Check _HID (Hardware ID). PASSED: Test 4, \_SB_.PCI0._HID returned an integer 0x080ad041 (EISA ID PNP0A08). PASSED: Test 4, \_SB_.PCI0.LPCB.DMAC._HID returned an integer 0x0002d041 (EISA ID PNP0200). PASSED: Test 4, \_SB_.PCI0.LPCB.FWHD._HID returned an integer 0x0008d425 (EISA ID INT0800). PASSED: Test 4, \_SB_.PCI0.LPCB.HPET._HID returned an integer 0x0301d041 (EISA ID PNP0103). PASSED: Test 4, \_SB_.PCI0.LPCB.IPIC._HID returned an integer 0x0000d041 (EISA ID PNP0000). PASSED: Test 4, \_SB_.PCI0.LPCB.MATH._HID returned an integer 0x040cd041 (EISA ID PNP0C04). PASSED: Test 4, \_SB_.PCI0.LPCB.LDRC._HID returned an integer 0x020cd041 (EISA ID PNP0C02). PASSED: Test 4, \_SB_.PCI0.LPCB.RTC_._HID returned an integer 0x000bd041 (EISA ID PNP0B00). PASSED: Test 4, \_SB_.PCI0.LPCB.TIMR._HID returned an integer 0x0001d041 (EISA ID PNP0100). PASSED: Test 4, \_SB_.PCI0.LPCB.SMC_._HID returned an integer 0x01001006 (EISA ID APP0001). PASSED: Test 4, \_SB_.PCI0.LPCB.ALS0._HID returned a string 'ACPI0008' as expected. PASSED: Test 4, \_SB_.PCI0.LPCB.EC__._HID returned an integer 0x090cd041 (EISA ID PNP0C09). PASSED: Test 4, \_SB_.PCI0.LPCB.EC__.SMB0._HID returned a string 'ACPI0001' as expected. PASSED: Test 4, \_SB_.PCI0.LPCB.EC__.SMB0.SBS0._HID returned a string 'ACPI0002' as expected. PASSED: Test 4, \_SB_.PCI0.SPI1.SPIT._HID returned an integer 0x0d001006 (EISA ID APP000D). PASSED: Test 4, \_SB_.PCI0.PDRC._HID returned an integer 0x020cd041 (EISA ID PNP0C02). PASSED: Test 4, \_SB_.MEM2._HID returned an integer 0x010cd041 (EISA ID PNP0C01). PASSED: Test 4, \_SB_.LNKA._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.LNKB._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.LNKC._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.LNKD._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.LNKE._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.LNKF._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.LNKG._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.LNKH._HID returned an integer 0x0f0cd041 (EISA ID PNP0C0F). PASSED: Test 4, \_SB_.BAT0._HID returned an integer 0x0a0cd041 (EISA ID PNP0C0A). PASSED: Test 4, \_SB_.ADP1._HID returned a string 'ACPI0003' as expected. PASSED: Test 4, \_SB_.LID0._HID returned an integer 0x0d0cd041 (EISA ID PNP0C0D). PASSED: Test 4, \_SB_.PWRB._HID returned an integer 0x0c0cd041 (EISA ID PNP0C0C). PASSED: Test 4, \_SB_.PNLF._HID returned an integer 0x02001006 (EISA ID APP0002). PASSED: Test 4, \_SB_.SLPB._HID returned an integer 0x0e0cd041 (EISA ID PNP0C0E). Test 5 of 144: Check _HRV (Hardware Revision Number). SKIPPED: Test 5, Skipping test for non-existant object _HRV. Test 6 of 144: Check _PLD (Physical Device Location). PASSED: Test 6, \_SB_.PCI0.XHC1.RHUB.HS01._PLD correctly returned a sane looking package. PASSED: Test 6, \_SB_.PCI0.XHC1.RHUB.HS02._PLD correctly returned a sane looking package. PASSED: Test 6, \_SB_.PCI0.XHC1.RHUB.HS03._PLD correctly returned a sane looking package. PASSED: Test 6, \_SB_.PCI0.XHC1.RHUB.HS05._PLD correctly returned a sane looking package. PASSED: Test 6, \_SB_.PCI0.XHC1.RHUB.SSP1._PLD correctly returned a sane looking package. PASSED: Test 6, \_SB_.PCI0.XHC1.RHUB.SSP2._PLD correctly returned a sane looking package. PASSED: Test 6, \_SB_.PCI0.XHC1.RHUB.SSP3._PLD correctly returned a sane looking package. Test 7 of 144: Check _SUB (Subsystem ID). SKIPPED: Test 7, Skipping test for non-existant object _SUB. Test 8 of 144: Check _SUN (Slot User Number). PASSED: Test 8, \_SB_.PCI0.RP05.UPSB.DSB1._SUN correctly returned an integer. PASSED: Test 8, \_SB_.PCI0.RP05.UPSB.DSB2._SUN correctly returned an integer. PASSED: Test 8, \_SB_.PCI0.RP05.UPSB.DSB3._SUN correctly returned an integer. PASSED: Test 8, \_SB_.PCI0.RP05.UPSB.DSB4._SUN correctly returned an integer. Test 9 of 144: Check _STR (String). FAILED [MEDIUM] MethodReturnBadType: Test 9, Method \_SB_.PCI0.RP05.UPSB.DSB0.NHI0._STR did not return ACPI_TYPE_STRING. Test 10 of 144: Check _UID (Unique ID). PASSED: Test 10, \_SB_.PCI0._UID correctly returned sane looking value 0x00000000. PASSED: Test 10, \_SB_.PCI0.LPCB.LDRC._UID correctly returned sane looking value 0x00000002. PASSED: Test 10, \_SB_.PCI0.LPCB.EC__._UID correctly returned sane looking value 0x00000000. PASSED: Test 10, \_SB_.PCI0.SDMA._UID correctly returned sane looking value 0x00000001. PASSED: Test 10, \_SB_.PCI0.SPI1._UID correctly returned sane looking value 0x00000002. PASSED: Test 10, \_SB_.PCI0.SPI1.SPIT._UID correctly returned sane looking value 0x00000001. PASSED: Test 10, \_SB_.PCI0.PDRC._UID correctly returned sane looking value 0x00000001. PASSED: Test 10, \_SB_.MEM2._UID correctly returned sane looking value 0x00000002. PASSED: Test 10, \_SB_.LNKA._UID correctly returned sane looking value 0x00000001. PASSED: Test 10, \_SB_.LNKB._UID correctly returned sane looking value 0x00000002. PASSED: Test 10, \_SB_.LNKC._UID correctly returned sane looking value 0x00000003. PASSED: Test 10, \_SB_.LNKD._UID correctly returned sane looking value 0x00000004. PASSED: Test 10, \_SB_.LNKE._UID correctly returned sane looking value 0x00000005. PASSED: Test 10, \_SB_.LNKF._UID correctly returned sane looking value 0x00000006. PASSED: Test 10, \_SB_.LNKG._UID correctly returned sane looking value 0x00000007. PASSED: Test 10, \_SB_.LNKH._UID correctly returned sane looking value 0x00000008. PASSED: Test 10, \_SB_.BAT0._UID correctly returned sane looking value 0x00000000. PASSED: Test 10, \_SB_.PNLF._UID correctly returned sane looking value 0x0000000f. Test 11 of 144: Check _CRS (Current Resource Settings). PASSED: Test 11, \_SB_.PCI0._CRS (WORD Address Space Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.DMAC._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.FWHD._CRS (32-bit Fixed Location Memory Range Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.HPET._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.IPIC._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.MATH._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.LDRC._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.RTC_._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.TIMR._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.SMC_._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.LPCB.EC__._CRS (I/O Port Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.SDMA._CRS (Extended IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.SPI1._CRS (Extended IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.PCI0.PDRC._CRS (32-bit Fixed Location Memory Range Descriptor) looks sane. PASSED: Test 11, \_SB_.MEM2._CRS (32-bit Fixed Location Memory Range Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKA._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKB._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKC._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKD._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKE._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKF._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKG._CRS (IRQ Descriptor) looks sane. PASSED: Test 11, \_SB_.LNKH._CRS (IRQ Descriptor) looks sane. Test 12 of 144: Check _DIS (Disable). PASSED: Test 12, \_SB_.LNKA._DIS returned no values as expected. PASSED: Test 12, \_SB_.LNKB._DIS returned no values as expected. PASSED: Test 12, \_SB_.LNKC._DIS returned no values as expected. PASSED: Test 12, \_SB_.LNKD._DIS returned no values as expected. PASSED: Test 12, \_SB_.LNKE._DIS returned no values as expected. PASSED: Test 12, \_SB_.LNKF._DIS returned no values as expected. PASSED: Test 12, \_SB_.LNKG._DIS returned no values as expected. PASSED: Test 12, \_SB_.LNKH._DIS returned no values as expected. Test 13 of 144: Check _DMA (Direct Memory Access). SKIPPED: Test 13, Skipping test for non-existant object _DMA. Test 14 of 144: Check _FIX (Fixed Register Resource Provider). SKIPPED: Test 14, Skipping test for non-existant object _FIX. Test 15 of 144: Check _GSB (Global System Interrupt Base). SKIPPED: Test 15, Skipping test for non-existant object _GSB. Test 16 of 144: Check _HPP (Hot Plug Parameters). SKIPPED: Test 16, Skipping test for non-existant object _HPP. Test 17 of 144: Check _PRS (Possible Resource Settings). PASSED: Test 17, \_SB_.LNKA._PRS (IRQ Descriptor) looks sane. PASSED: Test 17, \_SB_.LNKB._PRS (IRQ Descriptor) looks sane. PASSED: Test 17, \_SB_.LNKC._PRS (IRQ Descriptor) looks sane. PASSED: Test 17, \_SB_.LNKD._PRS (IRQ Descriptor) looks sane. PASSED: Test 17, \_SB_.LNKE._PRS (IRQ Descriptor) looks sane. PASSED: Test 17, \_SB_.LNKF._PRS (IRQ Descriptor) looks sane. PASSED: Test 17, \_SB_.LNKG._PRS (IRQ Descriptor) looks sane. PASSED: Test 17, \_SB_.LNKH._PRS (IRQ Descriptor) looks sane. Test 18 of 144: Check _PXM (Proximity). SKIPPED: Test 18, Skipping test for non-existant object _PXM. Test 19 of 144: Check _EDL (Eject Device List). SKIPPED: Test 19, Skipping test for non-existant object _EDL. Test 20 of 144: Check _EJD (Ejection Dependent Device). SKIPPED: Test 20, Skipping test for non-existant object _EJD. Test 21 of 144: Check _EJ0 (Eject). ACPICA Exception AE_AML_INFINITE_LOOP during execution of method _EJ0 WARNING: Test 21, Detected an infinite loop when evaluating method '\_SB_.PCI0.RP05.UPSB.DSB0.NHI0._EJ0'. ADVICE: This may occur because we are emulating the execution in this test environment and cannot handshake with the embedded controller or jump to the BIOS via SMIs. However, the fact that AML code spins forever means that lockup conditions are not being checked for in the AML bytecode. Test 22 of 144: Check _EJ1 (Eject). SKIPPED: Test 22, Skipping test for non-existant object _EJ1. Test 23 of 144: Check _EJ2 (Eject). SKIPPED: Test 23, Skipping test for non-existant object _EJ2. Test 24 of 144: Check _EJ3 (Eject). SKIPPED: Test 24, Skipping test for non-existant object _EJ3. Test 25 of 144: Check _EJ4 (Eject). SKIPPED: Test 25, Skipping test for non-existant object _EJ4. Test 26 of 144: Check _LCK (Lock). SKIPPED: Test 26, Skipping test for non-existant object _LCK. Test 27 of 144: Check _RMV (Remove). PASSED: Test 27, \_SB_.PCI0.RP03.ARPT._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB0.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB3._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB3.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB4._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB4.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB5._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB6._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB0.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB3._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB3.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB4._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB4.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB5._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB6._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB5._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB6._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB0.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB3._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB3.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB4._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB4.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB5._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB6._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB0.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB3._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB3.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB4._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB4.DEV0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB5._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB6._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB5._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB6._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB3._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP05.UPSB.DSB4._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.RP06.SSD0._RMV correctly returned sane looking value 0x00000000. PASSED: Test 27, \_SB_.PCI0.XHC1.RHUB.SSP3._RMV correctly returned sane looking value 0x00000000. Test 28 of 144: Check _STA (Status). PASSED: Test 28, \_SB_.PCI0.LPCB.HPET._STA correctly returned sane looking value 0x00000000. PASSED: Test 28, \_SB_.PCI0.LPCB.SMC_._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.PCI0.LPCB.ALS0._STA correctly returned sane looking value 0x00000000. PASSED: Test 28, \_SB_.PCI0.LPCB.EC__.SMB0._STA correctly returned sane looking value 0x00000000. PASSED: Test 28, \_SB_.PCI0.RP02._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP03._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP03.ARPT._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB0.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB0.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB3._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB3.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB4._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB4.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB5._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB6._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB0.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB3._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB3.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB4._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB4.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB5._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB6._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB5._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB6._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB0.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB0.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB3._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB3.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB4._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB4.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB5._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB6._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB0.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB3._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB3.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB4._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB4.DEV0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB5._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB6._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB5._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB6._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB3._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.RP05.UPSB.DSB4._STA correctly returned sane looking value 0x00000009. PASSED: Test 28, \_SB_.PCI0.SDMA._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.PCI0.SPI1._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.PCI0.SPI1.SPIT._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.PCI0.HDAU._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.LNKA._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.LNKB._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.LNKC._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.LNKD._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.LNKE._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.LNKF._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.LNKG._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.LNKH._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.BAT0._STA correctly returned sane looking value 0x0000000f. PASSED: Test 28, \_SB_.PNLF._STA correctly returned sane looking value 0x0000000b. PASSED: Test 28, \_SB_.SLPB._STA correctly returned sane looking value 0x0000000b. Test 29 of 144: Check _BDN (BIOS Dock Name). SKIPPED: Test 29, Skipping test for non-existant object _BDN. Test 30 of 144: Check _BBN (Base Bus Number). PASSED: Test 30, \_SB_.PCI0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP02._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP03._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB3._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB4._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB5._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB6._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB3._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB4._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB5._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB6._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB5._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB6._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB3._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB4._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB5._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB6._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB0._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB3._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB4._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB5._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB6._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB5._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB6._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB3._BBN correctly returned an integer. PASSED: Test 30, \_SB_.PCI0.RP05.UPSB.DSB4._BBN correctly returned an integer. Test 31 of 144: Check _DCK (Dock). SKIPPED: Test 31, Skipping test for non-existant object _DCK. Test 32 of 144: Check _INI (Initialize). PASSED: Test 32, \_SB_.PCI0._INI returned no values as expected. PASSED: Test 32, \_SB_._INI returned no values as expected. Test 33 of 144: Check _SEG (Segment). SKIPPED: Test 33, Skipping test for non-existant object _SEG. Test 34 of 144: Check _OFF (Set resource off). SKIPPED: Test 34, Skipping test for non-existant object _OFF. Test 35 of 144: Check _ON (Set resource on). SKIPPED: Test 35, Skipping test for non-existant object _ON. Test 36 of 144: Check _DSW (Device Sleep Wake). SKIPPED: Test 36, Skipping test for non-existant object _DSW. Test 37 of 144: Check _IRC (In Rush Current). SKIPPED: Test 37, Skipping test for non-existant object _IRC. Test 38 of 144: Check _PRE (Power Resources for Enumeration). SKIPPED: Test 38, Skipping test for non-existant object _PRE. Test 39 of 144: Check _PR0 (Power Resources for D0). SKIPPED: Test 39, Skipping test for non-existant object _PR0. Test 40 of 144: Check _PR1 (Power Resources for D1). SKIPPED: Test 40, Skipping test for non-existant object _PR1. Test 41 of 144: Check _PR2 (Power Resources for D2). SKIPPED: Test 41, Skipping test for non-existant object _PR2. Test 42 of 144: Check _PR3 (Power Resources for D3). SKIPPED: Test 42, Skipping test for non-existant object _PR3. Test 43 of 144: Check _PS0 (Power State 0). PASSED: Test 43, \_SB_.PCI0.HDEF._PS0 returned no values as expected. PASSED: Test 43, \_SB_.PCI0.RP03._PS0 returned no values as expected. PASSED: Test 43, \_SB_.PCI0.RP06._PS0 returned no values as expected. PASSED: Test 43, \_SB_.PCI0.XHC1._PS0 returned no values as expected. Test 44 of 144: Check _PS1 (Power State 1). SKIPPED: Test 44, Skipping test for non-existant object _PS1. Test 45 of 144: Check _PS2 (Power State 2). SKIPPED: Test 45, Skipping test for non-existant object _PS2. Test 46 of 144: Check _PS3 (Power State 3). PASSED: Test 46, \_SB_.PCI0.HDEF._PS3 returned no values as expected. PASSED: Test 46, \_SB_.PCI0.RP03._PS3 returned no values as expected. PASSED: Test 46, \_SB_.PCI0.RP06._PS3 returned no values as expected. PASSED: Test 46, \_SB_.PCI0.XHC1._PS3 returned no values as expected. Test 47 of 144: Check _PSC (Power State Current). SKIPPED: Test 47, Skipping test for non-existant object _PSC. Test 48 of 144: Check _PSE (Power State for Enumeration). SKIPPED: Test 48, Skipping test for non-existant object _PSE. Test 49 of 144: Check _PSW (Power State Wake). PASSED: Test 49, \_SB_.ADP1._PSW returned no values as expected. PASSED: Test 49, \_SB_.LID0._PSW returned no values as expected. Test 50 of 144: Check _S1D (S1 Device State). SKIPPED: Test 50, Skipping test for non-existant object _S1D. Test 51 of 144: Check _S2D (S2 Device State). SKIPPED: Test 51, Skipping test for non-existant object _S2D. Test 52 of 144: Check _S3D (S3 Device State). SKIPPED: Test 52, Skipping test for non-existant object _S3D. Test 53 of 144: Check _S4D (S4 Device State). SKIPPED: Test 53, Skipping test for non-existant object _S4D. Test 54 of 144: Check _S0W (S0 Device Wake State). SKIPPED: Test 54, Skipping test for non-existant object _S0W. Test 55 of 144: Check _S1W (S1 Device Wake State). SKIPPED: Test 55, Skipping test for non-existant object _S1W. Test 56 of 144: Check _S2W (S2 Device Wake State). SKIPPED: Test 56, Skipping test for non-existant object _S2W. Test 57 of 144: Check _S3W (S3 Device Wake State). SKIPPED: Test 57, Skipping test for non-existant object _S3W. Test 58 of 144: Check _S4W (S4 Device Wake State). SKIPPED: Test 58, Skipping test for non-existant object _S4W. Test 59 of 144: Check _S0_ (S0 System State). \_S0_ PM1a_CNT.SLP_TYP value: 0x00000000 \_S0_ PM1b_CNT.SLP_TYP value: 0x00000000 PASSED: Test 59, \_S0_ correctly returned a sane looking package. Test 60 of 144: Check _S1_ (S1 System State). SKIPPED: Test 60, Skipping test for non-existant object _S1_. Test 61 of 144: Check _S2_ (S2 System State). SKIPPED: Test 61, Skipping test for non-existant object _S2_. Test 62 of 144: Check _S3_ (S3 System State). SKIPPED: Test 62, Skipping test for non-existant object _S3_. Test 63 of 144: Check _S4_ (S4 System State). \_S4_ PM1a_CNT.SLP_TYP value: 0x00000006 \_S4_ PM1b_CNT.SLP_TYP value: 0x00000006 PASSED: Test 63, \_S4_ correctly returned a sane looking package. Test 64 of 144: Check _S5_ (S5 System State). \_S5_ PM1a_CNT.SLP_TYP value: 0x00000007 \_S5_ PM1b_CNT.SLP_TYP value: 0x00000007 PASSED: Test 64, \_S5_ correctly returned a sane looking package. Test 65 of 144: Check _SWS (System Wake Source). SKIPPED: Test 65, Skipping test for non-existant object _SWS. Test 66 of 144: Check _PSS (Performance Supported States). \_PR_.CPU0._PSS values: P-State Freq Power Latency Bus Master (MHz) (mW) (us) Latency (us) 0 2301 15000 10 10 1 2300 15000 10 10 2 2200 14088 10 10 3 2100 13340 10 10 4 2000 12462 10 10 5 1900 11745 10 10 6 1800 11042 10 10 7 1700 10215 10 10 8 1600 9542 10 10 9 1500 8882 10 10 10 1400 8101 10 10 11 1300 7471 10 10 12 1200 6855 10 10 13 1100 6121 10 10 14 1000 5531 10 10 15 900 4955 10 10 16 800 4267 10 10 17 759 3718 10 10 PASSED: Test 66, \_PR_.CPU0._PSS correctly returned a sane looking package. Test 67 of 144: Check _CPC (Continuous Performance Control). SKIPPED: Test 67, Skipping test for non-existant object _CPC. Test 68 of 144: Check _CSD (C State Dependencies). SKIPPED: Test 68, Skipping test for non-existant object _CSD. Test 69 of 144: Check _CST (C States). SKIPPED: Test 69, Skipping test for non-existant object _CST. Test 70 of 144: Check _PCT (Performance Control). PASSED: Test 70, \_PR_.CPU0._PCT correctly returned a sane looking package. Test 71 of 144: Check _PDL (P-State Depth Limit). SKIPPED: Test 71, Skipping test for non-existant object _PDL. Test 72 of 144: Check _PPC (Performance Present Capabilities). PASSED: Test 72, \_PR_.CPU0._PPC correctly returned an integer. Test 73 of 144: Check _PPE (Polling for Platform Error). SKIPPED: Test 73, Skipping test for non-existant object _PPE. Test 74 of 144: Check _TDL (T-State Depth Limit). SKIPPED: Test 74, Skipping test for non-existant object _TDL. Test 75 of 144: Check _TPC (Throttling Present Capabilities). SKIPPED: Test 75, Skipping test for non-existant object _TPC. Test 76 of 144: Check _TSD (Throttling State Dependencies). SKIPPED: Test 76, Skipping test for non-existant object _TSD. Test 77 of 144: Check _TSS (Throttling Supported States). SKIPPED: Test 77, Skipping test for non-existant object _TSS. Test 78 of 144: Check _ALC (Ambient Light Colour Chromaticity). SKIPPED: Test 78, Skipping test for non-existant object _ALC. Test 79 of 144: Check _ALI (Ambient Light Illuminance). PASSED: Test 79, \_SB_.PCI0.LPCB.ALS0._ALI correctly returned an integer. Test 80 of 144: Check _ALT (Ambient Light Temperature). SKIPPED: Test 80, Skipping test for non-existant object _ALT. Test 81 of 144: Check _ALP (Ambient Light Polling). SKIPPED: Test 81, Skipping test for non-existant object _ALP. Test 82 of 144: Check _LID (Lid Status). PASSED: Test 82, \_SB_.LID0._LID correctly returned sane looking value 0x00000000. Test 83 of 144: Check _GCP (Get Capabilities). SKIPPED: Test 83, Skipping test for non-existant object _GCP. Test 84 of 144: Check _GRT (Get Real Time). SKIPPED: Test 84, Skipping test for non-existant object _GRT. Test 85 of 144: Check _GWS (Get Wake Status). SKIPPED: Test 85, Skipping test for non-existant object _GWS. Test 86 of 144: Check _STP (Set Expired Timer Wake Policy). SKIPPED: Test 86, Skipping test for non-existant object _STP. Test 87 of 144: Check _STV (Set Timer Value). SKIPPED: Test 87, Skipping test for non-existant object _STV. Test 88 of 144: Check _TIP (Expired Timer Wake Policy). SKIPPED: Test 88, Skipping test for non-existant object _TIP. Test 89 of 144: Check _TIV (Timer Values). SKIPPED: Test 89, Skipping test for non-existant object _TIV. Test 90 of 144: Check _SBS (Smart Battery Subsystem). PASSED: Test 90, \_SB_.PCI0.LPCB.EC__.SMB0.SBS0._SBS correctly returned value 1 Maximum 1 Smart Battery, system manager/selector present Test 91 of 144: Check _BCT (Battery Charge Time). SKIPPED: Test 91, Skipping test for non-existant object _BCT. Test 92 of 144: Check _BIF (Battery Information). PASSED: Test 92, \_SB_.BAT0._BIF correctly returned a sane looking package. Test 93 of 144: Check _BIX (Battery Information Extended). SKIPPED: Test 93, Skipping test for non-existant object _BIX. Test 94 of 144: Check _BMA (Battery Measurement Averaging). SKIPPED: Test 94, Skipping test for non-existant object _BMA. Test 95 of 144: Check _BMC (Battery Maintenance Control). SKIPPED: Test 95, Skipping test for non-existant object _BMC. Test 96 of 144: Check _BMD (Battery Maintenance Data). SKIPPED: Test 96, Skipping test for non-existant object _BMD. Test 97 of 144: Check _BMS (Battery Measurement Sampling Time). SKIPPED: Test 97, Skipping test for non-existant object _BMS. Test 98 of 144: Check _BST (Battery Status). PASSED: Test 98, \_SB_.BAT0._BST correctly returned a sane looking package. Test 99 of 144: Check _BTP (Battery Trip Point). SKIPPED: Test 99, Skipping test for non-existant object _BTP. Test 100 of 144: Check _BTM (Battery Time). SKIPPED: Test 100, Skipping test for non-existant object _BTM. Test 101 of 144: Check _PCL (Power Consumer List). FAILED [CRITICAL] AETtype: Test 101, Detected error 'Type' when evaluating '\_SB_.ADP1._PCL'. Test 102 of 144: Check _PIF (Power Source Information). SKIPPED: Test 102, Skipping test for non-existant object _PIF. Test 103 of 144: Check _PSR (Power Source). PASSED: Test 103, \_SB_.ADP1._PSR correctly returned sane looking value 0x00000000. Test 104 of 144: Check _FIF (Fan Information). SKIPPED: Test 104, Skipping test for non-existant object _FIF. Test 105 of 144: Check _FSL (Fan Set Level). SKIPPED: Test 105, Skipping test for non-existant object _FSL. Test 106 of 144: Check _FST (Fan Status). SKIPPED: Test 106, Skipping test for non-existant object _FST. Test 107 of 144: Check _ACx (Active Cooling). PASSED: Test 107, \_PR_.AAC0 correctly returned a sane looking return type. SKIPPED: Test 107, Skipping test for non-existant object AC1. SKIPPED: Test 107, Skipping test for non-existant object AC2. SKIPPED: Test 107, Skipping test for non-existant object AC3. SKIPPED: Test 107, Skipping test for non-existant object AC4. SKIPPED: Test 107, Skipping test for non-existant object AC5. SKIPPED: Test 107, Skipping test for non-existant object AC6. SKIPPED: Test 107, Skipping test for non-existant object AC7. SKIPPED: Test 107, Skipping test for non-existant object AC8. SKIPPED: Test 107, Skipping test for non-existant object AC9. Test 108 of 144: Check _CRT (Critical Trip Point). SKIPPED: Test 108, Skipping test for non-existant object _CRT. Test 109 of 144: Check _DTI (Device Temperature Indication). SKIPPED: Test 109, Skipping test for non-existant object _DTI. Test 110 of 144: Check _HOT (Hot Temperature). SKIPPED: Test 110, Skipping test for non-existant object _HOT. Test 111 of 144: Check _NTT (Notification Temp Threshold). SKIPPED: Test 111, Skipping test for non-existant object _NTT. Test 112 of 144: Check _PSV (Passive Temp). SKIPPED: Test 112, Skipping test for non-existant object _PSV. Test 113 of 144: Check _RTV (Relative Temp Values). SKIPPED: Test 113, Skipping test for non-existant object _RTV. Test 114 of 144: Check _SCP (Set Cooling Policy). SKIPPED: Test 114, Skipping test for non-existant object _DTI. Test 115 of 144: Check _TC1 (Thermal Constant 1). SKIPPED: Test 115, Skipping test for non-existant object _TC1. Test 116 of 144: Check _TC2 (Thermal Constant 2). SKIPPED: Test 116, Skipping test for non-existant object _TC2. Test 117 of 144: Check _TMP (Thermal Zone Current Temp). SKIPPED: Test 117, Skipping test for non-existant object _TMP. Test 118 of 144: Check _TPT (Trip Point Temperature). SKIPPED: Test 118, Skipping test for non-existant object _TPT. Test 119 of 144: Check _TSP (Thermal Sampling Period). SKIPPED: Test 119, Skipping test for non-existant object _TSP. Test 120 of 144: Check _TST (Temperature Sensor Threshold). SKIPPED: Test 120, Skipping test for non-existant object _TST. Test 121 of 144: Check _TZP (Thermal Zone Polling). SKIPPED: Test 121, Skipping test for non-existant object _TZP. Test 122 of 144: Check _PTS (Prepare to Sleep). Test _PTS(1). PASSED: Test 122, \_PTS returned no values as expected. Test _PTS(2). PASSED: Test 122, \_PTS returned no values as expected. Test _PTS(3). PASSED: Test 122, \_PTS returned no values as expected. Test _PTS(4). PASSED: Test 122, \_PTS returned no values as expected. Test _PTS(5). PASSED: Test 122, \_PTS returned no values as expected. Test 123 of 144: Check _TTS (Transition to State). Test _TTS(1) Transition To State S1. PASSED: Test 123, \_TTS returned no values as expected. Test _TTS(2) Transition To State S2. PASSED: Test 123, \_TTS returned no values as expected. Test _TTS(3) Transition To State S3. PASSED: Test 123, \_TTS returned no values as expected. Test _TTS(4) Transition To State S4. PASSED: Test 123, \_TTS returned no values as expected. Test _TTS(5) Transition To State S5. PASSED: Test 123, \_TTS returned no values as expected. Test 124 of 144: Check _S0 (System S0 State). SKIPPED: Test 124, Skipping test for non-existant object _S0. Test 125 of 144: Check _S1 (System S1 State). SKIPPED: Test 125, Skipping test for non-existant object _S1. Test 126 of 144: Check _S2 (System S2 State). SKIPPED: Test 126, Skipping test for non-existant object _S2. Test 127 of 144: Check _S3 (System S3 State). SKIPPED: Test 127, Skipping test for non-existant object _S3. Test 128 of 144: Check _S4 (System S4 State). SKIPPED: Test 128, Skipping test for non-existant object _S4. Test 129 of 144: Check _S5 (System S5 State). SKIPPED: Test 129, Skipping test for non-existant object _S5. Test 130 of 144: Check _WAK (System Wake). Test _WAK(1) System Wake, State S1. PASSED: Test 130, \_WAK correctly returned a sane looking package. Test _WAK(2) System Wake, State S2. PASSED: Test 130, \_WAK correctly returned a sane looking package. Test _WAK(3) System Wake, State S3. PASSED: Test 130, \_WAK correctly returned a sane looking package. Test _WAK(4) System Wake, State S4. PASSED: Test 130, \_WAK correctly returned a sane looking package. Test _WAK(5) System Wake, State S5. PASSED: Test 130, \_WAK correctly returned a sane looking package. Test 131 of 144: Check _ADR (Return Unique ID for Device). PASSED: Test 131, \_SB_.PCI0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.MCHC._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.P0P2._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD01._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD02._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD03._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD04._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD05._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD06._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD07._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD08._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.IGPU.DD1F._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.SBUS._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.SBUS.BUS0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.SBUS.BUS1._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.LPCB._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.HDEF._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP01._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP02._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP02.CMRA._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP03._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP03.ARPT._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB0.NHI0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB0.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB0.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB3.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB4._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB4.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB5._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB3.UPS0.DSB6._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB0.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB3.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB4._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB4.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB5._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB4.UPS0.DSB6._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB5._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB1.UPS0.DSB6._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB0.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB0.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB3.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB4._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB4.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB5._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB3.UPS0.DSB6._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB0.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB3.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB4._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB4.DEV0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB5._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB4.UPS0.DSB6._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB5._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB2.UPS0.DSB6._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP05.UPSB.DSB4._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP06._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP06.SSD0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.RP06.SSD0.PRT0._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.SDMA._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.SPI1._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.HDAU._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB.HS01._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB.HS02._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB.HS03._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB.HS05._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB.SSP1._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB.SSP2._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PCI0.XHC1.RHUB.SSP3._ADR correctly returned an integer. PASSED: Test 131, \_SB_.PNLF._ADR correctly returned an integer. Test 132 of 144: Check _BCL (Query List of Brightness Control Levels Supported). Brightness levels for \_SB_.PCI0.IGPU.DD01._BCL: Level on full power : 87 Level on battery power: 53 Brightness Levels : 0, 7, 13, 20, 27, 33, 40, 47, 53, 60, 67, 73, 80, 87, 93, 100 PASSED: Test 132, \_SB_.PCI0.IGPU.DD01._BCL returned a sane package of 18 integers. Test 133 of 144: Check _BCM (Set Brightness Level). FAILED [MEDIUM] MethodShouldReturnNothing: Test 133, \_SB_.PCI0.IGPU.DD01._BCM returned values, but was expected to return nothing. Object returned: INTEGER: 0x00000000 ADVICE: This probably won't cause any errors, but it should be fixed as the AML code is not conforming to the expected behaviour as described in the ACPI specification. Test 134 of 144: Check _BQC (Brightness Query Current Level). PASSED: Test 134, \_SB_.PCI0.IGPU.DD01._BQC correctly returned an integer. Test 135 of 144: Check _DCS (Return the Status of Output Device). PASSED: Test 135, \_SB_.PCI0.IGPU.DD01._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD02._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD03._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD04._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD05._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD06._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD07._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD08._DCS correctly returned an integer. PASSED: Test 135, \_SB_.PCI0.IGPU.DD1F._DCS correctly returned an integer. Test 136 of 144: Check _DDC (Return the EDID for this Device). SKIPPED: Test 136, Skipping test for non-existant object _DDC. Test 137 of 144: Check _DSS (Device Set State). PASSED: Test 137, \_SB_.PCI0.IGPU.DD01._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD02._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD03._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD04._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD05._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD06._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD07._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD08._DSS returned no values as expected. PASSED: Test 137, \_SB_.PCI0.IGPU.DD1F._DSS returned no values as expected. Test 138 of 144: Check _DGS (Query Graphics State). PASSED: Test 138, \_SB_.PCI0.IGPU.DD01._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD02._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD03._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD04._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD05._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD06._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD07._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD08._DGS correctly returned an integer. PASSED: Test 138, \_SB_.PCI0.IGPU.DD1F._DGS correctly returned an integer. Test 139 of 144: Check _DOD (Enumerate All Devices Attached to Display Adapter). Device 0: Instance: 0 Display port attachment: 0 Type of display: 4 (Internal/Integrated Digital Flat Panel) BIOS can detect device: 0 Non-VGA device: 0 Head or pipe ID: 0 PASSED: Test 139, \_SB_.PCI0.IGPU._DOD correctly returned a sane looking package. Test 140 of 144: Check _DOS (Enable/Disable Output Switching). PASSED: Test 140, \_SB_.PCI0.IGPU._DOS returned no values as expected. Test 141 of 144: Check _GPD (Get POST Device). SKIPPED: Test 141, Skipping test for non-existant object _GPD. Test 142 of 144: Check _ROM (Get ROM Data). SKIPPED: Test 142, Skipping test for non-existant object _ROM. Test 143 of 144: Check _SPD (Set POST Device). SKIPPED: Test 143, Skipping test for non-existant object _SPD. Test 144 of 144: Check _VPO (Video POST Options). SKIPPED: Test 144, Skipping test for non-existant object _VPO. ==================================================================================================== 434 passed, 3 failed, 1 warnings, 0 aborted, 109 skipped, 0 info only. ==================================================================================================== mcfg: MCFG PCI Express* memory mapped config space. ---------------------------------------------------------------------------------------------------- Test 1 of 2: Validate MCFG table. This test tries to validate the MCFG table by comparing the first 16 bytes in the MMIO mapped config space with the 'traditional' config space of the first PCI device (root bridge). The MCFG data is only trusted if it is marked reserved in the Int 15 AX=E820 BIOS memory map Memory Map Layout ----------------- 0x0000000000000000 - 0x0000000000057fff (System RAM) 0x0000000000058000 - 0x0000000000058fff (reserved) 0x0000000000059000 - 0x000000000008efff (System RAM) 0x000000000008f000 - 0x000000000008ffff (reserved) 0x0000000000090000 - 0x000000000009fbff (System RAM) 0x000000000009fc00 - 0x00000000000bffff (reserved) 0x00000000000e0000 - 0x00000000000fffff (reserved) 0x0000000000100000 - 0x0000000082d13fff (System RAM) 0x0000000082d14000 - 0x0000000082d52fff (ACPI Non-volatile Storage) 0x0000000082d53000 - 0x0000000082d63fff (System RAM) 0x0000000082d64000 - 0x0000000082d75fff (ACPI Non-volatile Storage) 0x0000000082d76000 - 0x0000000082d76fff (System RAM) 0x0000000082d77000 - 0x0000000082d8efff (ACPI Non-volatile Storage) 0x0000000082d8f000 - 0x0000000082f5dfff (System RAM) 0x0000000082f5e000 - 0x0000000082feffff (reserved) 0x0000000082ff0000 - 0x0000000082ffffff (System RAM) 0x0000000083000000 - 0x000000008f9fffff (reserved) 0x00000000e0000000 - 0x00000000efffffff (reserved) 0x00000000fec00000 - 0x00000000fec00fff (reserved) 0x00000000fed00000 - 0x00000000fed03fff (reserved) 0x00000000fed10000 - 0x00000000fed13fff (reserved) 0x00000000fed18000 - 0x00000000fed19fff (reserved) 0x00000000fed1c000 - 0x00000000fed1ffff (reserved) 0x00000000fee00000 - 0x00000000fee00fff (reserved) 0x00000000ff800000 - 0x00000000ffffffff (reserved) 0x0000000100000000 - 0x000000026f5fffff (System RAM) MCFG table found, size is 16 bytes (excluding header) (1 entries). Configuration Entry #0: Base Address : 0xe0000000 Segment : 0 Start bus : 0 End bus : 155 PASSED: Test 1, MCFG mmio config space is reserved in memory map table. Test 2 of 2: Validate MCFG PCI config space. PASSED: Test 2, PCI config space verified. ==================================================================================================== 2 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== fan: Simple Fan Tests. ---------------------------------------------------------------------------------------------------- Test 1 of 2: Check fan status. Test how many fans there are in the system. Check for the current status of the fan(s). PASSED: Test 1, Fan cooling_device0 of type Processor has max cooling state 10 and current cooling state 0. PASSED: Test 1, Fan cooling_device1 of type LCD has max cooling state 15 and current cooling state 4. Test 2 of 2: Load system, check CPU fan status. Test how many fans there are in the system. Check for the current status of the fan(s). Loading CPUs for 20 seconds to try and get fan speeds to change. Fan cooling_device0 current state did not change from value 0 while CPUs were busy. ADVICE: Did not detect any change in the CPU related thermal cooling device states. It could be that the devices are returning static information back to the driver and/or the fan speed is automatically being controlled by firmware using System Management Mode in which case the kernel interfaces being examined may not work anyway. ==================================================================================================== 2 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== fadt: FADT SCI_EN enabled check. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check FADT SCI_EN bit is enabled. FADT Preferred PM Profile: 2 (Mobile) FADT is greater than ACPI version 1.0 PASSED: Test 1, SCI_EN bit in PM1a Control Register Block is enabled. ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== dmar: Check sane DMA Remapping (VT-d). ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check DMA Remapping. PASSED: Test 1, DMAR ACPI table has passed test. PASSED: Test 1, Found no DMAR errors in kernel log. ==================================================================================================== 2 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== cstates: Check processor C state support. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check all CPUs C-states. This test checks if all processors have the same number of C-states, if the C-state counter works and if C-state transitions happen. PASSED: Test 1, Processor 0 has reached all C-states: C1 C3 C6 C7 ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== checksum: Check ACPI table checksum. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check ACPI table checksums. PASSED: Test 1, Table RSDP has correct checksum 0x17. PASSED: Test 1, Table RSDP has correct extended checksum 0xe1. PASSED: Test 1, Table RSDT has correct checksum 0x8e. PASSED: Test 1, Table DSDT has correct checksum 0xdd. PASSED: Test 1, Table FACP has correct checksum 0xa8. PASSED: Test 1, Table HPET has correct checksum 0x8c. PASSED: Test 1, Table APIC has correct checksum 0x5f. PASSED: Test 1, Table SBST has correct checksum 0x84. PASSED: Test 1, Table ECDT has correct checksum 0x2. PASSED: Test 1, Table SSDT has correct checksum 0x6b. PASSED: Test 1, Table SSDT has correct checksum 0xbb. PASSED: Test 1, Table SSDT has correct checksum 0x9f. PASSED: Test 1, Table SSDT has correct checksum 0xc6. PASSED: Test 1, Table SSDT has correct checksum 0x25. PASSED: Test 1, Table SSDT has correct checksum 0xb3. PASSED: Test 1, Table SSDT has correct checksum 0x8. PASSED: Test 1, Table MCFG has correct checksum 0x58. PASSED: Test 1, Table DMAR has correct checksum 0xda. PASSED: Test 1, Table XSDT has correct checksum 0x50. ==================================================================================================== 19 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== apicinstance: Check for single instance of APIC/MADT table. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check single instance of APIC/MADT table. Found APIC/MADT table APIC @ 82d8a000, length 0x188 PASSED: Test 1, Found 1 APIC/MADT table(s), as expected. ==================================================================================================== 1 passed, 0 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== apicedge: APIC Edge/Level Check. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Legacy and PCI Interrupt Edge/Level trigger checks. FAILED [MEDIUM] NonLegacyIRQLevelTrig: Test 1, Non-Legacy interrupt 0 is incorrectly level triggered. FAILED [MEDIUM] NonLegacyIRQLevelTrig: Test 1, Non-Legacy interrupt 2 is incorrectly level triggered. FAILED [MEDIUM] NonLegacyIRQLevelTrig: Test 1, Non-Legacy interrupt 8 is incorrectly level triggered. ==================================================================================================== 0 passed, 3 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== acpitables: ACPI table settings sanity checks. ---------------------------------------------------------------------------------------------------- Test 1 of 1: Check ACPI tables. PASSED: Test 1, Table APIC passed. PASSED: Test 1, Table ECDT passed. FAILED [MEDIUM] FADT32And64BothDefined: Test 1, FADT 32 bit FIRMWARE_CONTROL is non-zero, and X_FIRMWARE_CONTROL is also non-zero. Section 5.2.9 of the ACPI specification states that if the FIRMWARE_CONTROL is non-zero then X_FIRMWARE_CONTROL must be set to zero. ADVICE: The FADT FIRMWARE_CTRL is a 32 bit pointer that points to the physical memory address of the Firmware ACPI Control Structure (FACS). There is also an extended 64 bit version of this, the X_FIRMWARE_CTRL pointer that also can point to the FACS. Section 5.2.9 of the ACPI specification states that if the X_FIRMWARE_CTRL field contains a non zero value then the FIRMWARE_CTRL field *must* be zero. This error is also detected by the Linux kernel. If FIRMWARE_CTRL and X_FIRMWARE_CTRL are defined, then the kernel just uses the 64 bit version of the pointer. PASSED: Test 1, Table HPET passed. PASSED: Test 1, Table MCFG passed. PASSED: Test 1, Table RSDT passed. PASSED: Test 1, Table RSDP passed. PASSED: Test 1, Table SBST passed. PASSED: Test 1, Table XSDT passed. ==================================================================================================== 8 passed, 1 failed, 0 warnings, 0 aborted, 0 skipped, 0 info only. ==================================================================================================== 625 passed, 63 failed, 26 warnings, 2 aborted, 120 skipped, 10 info only. Test Failure Summary ==================================================================================================== Critical failures: 1 method: Detected error 'Type' when evaluating '\_SB_.ADP1._PCL'. High failures: 3 dmi_decode: Out of range value 0x2e (range allowed 0x01..0x2a) while accessing entry 'Processor Information (Type 4)' @ 0x000e0000, field 'Upgrade', offset 0x19 dmi_decode: Invald header length of entry #39, length was 0x00. syntaxcheck: Assembler error in line 22 Medium failures: 50 mtrr: Memory range 0x10000 to 0x57fff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x10000 to 0x57fff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x59000 to 0x8efff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x59000 to 0x8efff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x90000 to 0x9fbff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x90000 to 0x9fbff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x100000 to 0x82d13fff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x100000 to 0x82d13fff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x82d53000 to 0x82d63fff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x82d53000 to 0x82d63fff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x82d76000 to 0x82d76fff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x82d76000 to 0x82d76fff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x82d8f000 to 0x82f5dfff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x82d8f000 to 0x82f5dfff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x82ff0000 to 0x82ffffff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x82ff0000 to 0x82ffffff (System RAM) is lacking attribute Write-Back. mtrr: Memory range 0x90000000 to 0x9fffffff (0000:02:00.0) has incorrect attribute Uncached. mtrr: Memory range 0xa0000000 to 0xafffffff (0000:00:02.0) has incorrect attribute Uncached. mtrr: Memory range 0xbcc00000 to 0xbcc0ffff (0000:0a:00.0) has incorrect attribute Uncached. mtrr: Memory range 0xbcc10000 to 0xbcc1ffff (0000:0a:00.0) has incorrect attribute Uncached. mtrr: Memory range 0x100000000 to 0x26f5fffff (System RAM) has incorrect attribute Default. mtrr: Memory range 0x100000000 to 0x26f5fffff (System RAM) is lacking attribute Write-Back. aspm: PCIe ASPM setting was not matched. dmi_decode: DMI table length was 2509 bytes (as specified by the SMBIOS header) but the DMI entries used 2098 bytes. dmi_decode: DMI table was DMI 42 entries in size (as specified by the SMBIOS header) but only 39 DMI entries were found. cpufreq: Supposedly higher frequency 900 MHz is slower (148586 bogo loops) than frequency 900 MHz (151656 bogo loops) on CPU 0. cpufreq: Supposedly higher frequency 1200 MHz is slower (151466 bogo loops) than frequency 1200 MHz (151568 bogo loops) on CPU 0. cpufreq: Supposedly higher frequency 1400 MHz is slower (148296 bogo loops) than frequency 1400 MHz (151642 bogo loops) on CPU 0. cpufreq: Supposedly higher frequency 1.65 GHz is slower (151561 bogo loops) than frequency 1.65 GHz (151610 bogo loops) on CPU 0. cpufreq: Supposedly higher frequency 2.05 GHz is slower (159613 bogo loops) than frequency 2.05 GHz (161185 bogo loops) on CPU 0. cpufreq: Supposedly higher frequency 2.15 GHz is slower (158449 bogo loops) than frequency 2.15 GHz (159613 bogo loops) on CPU 0. cpufreq: Supposedly higher frequency 2.35 GHz is slower (80503 bogo loops) than frequency 2.35 GHz (160966 bogo loops) on CPU 0. maxfreq: Maximum scaling frequency 2.301000 GHz do not match expected frequency 1.700000 GHz syntaxcheck: Assembler warning in line 84 syntaxcheck: Assembler warning in line 583 syntaxcheck: Assembler warning in line 2426 syntaxcheck: Assembler warning in line 121 syntaxcheck: Assembler warning in line 268 syntaxcheck: Assembler warning in line 339 syntaxcheck: Assembler warning in line 386 syntaxcheck: Assembler warning in line 433 syntaxcheck: Assembler warning in line 480 syntaxcheck: Assembler warning in line 527 syntaxcheck: Assembler warning in line 574 method: Method \_SB_.PCI0.RP05.UPSB.DSB0.NHI0._STR did not return ACPI_TYPE_STRING. method: \_SB_.PCI0.IGPU.DD01._BCM returned values, but was expected to return nothing. apicedge: Non-Legacy interrupt 0 is incorrectly level triggered. apicedge: Non-Legacy interrupt 2 is incorrectly level triggered. apicedge: Non-Legacy interrupt 8 is incorrectly level triggered. acpitables: FADT 32 bit FIRMWARE_CONTROL is non-zero, and X_FIRMWARE_CONTROL is also non-zero. Section 5.2.9 of the ACPI specification states that if the FIRMWARE_CONTROL is non-zero then X_FIRMWARE_CONTROL must be set to zero. Low failures: 8 klog: LOW Kernel message: [ 137.565004] ACPI Warning: 0x0000000000000830-0x000000000000083f SystemIO conflicts with Region \GPIO 1 (20121018/utaddress-251) klog: LOW Kernel message: [ 137.565012] ACPI Warning: 0x0000000000000800-0x000000000000082f SystemIO conflicts with Region \GPIO 1 (20121018/utaddress-251) klog: LOW Kernel message: [ 137.565015] ACPI Warning: 0x0000000000000800-0x000000000000082f SystemIO conflicts with Region \IO_D 2 (20121018/utaddress-251) klog: LOW Kernel message: [ 137.565018] ACPI Warning: 0x0000000000000800-0x000000000000082f SystemIO conflicts with Region \IO_T 3 (20121018/utaddress-251) maxreadreq: 2 devices have low MaxReadReq settings. Firmware may have configured these too low. dmi_decode: String index 0x03 in table entry 'Processor Information (Type 4)' @ 0x000e0000, field 'Serial Number', offset 0x20 has a default value 'To Be Filled By O.E.M.' and probably has not been updated by the BIOS vendor. dmi_decode: String index 0x05 in table entry 'Processor Information (Type 4)' @ 0x000e0000, field 'Asset Tag', offset 0x21 has a default value 'To Be Filled By O.E.M.' and probably has not been updated by the BIOS vendor. dmi_decode: Out of range string index 0x01 while accessing entry 'BIOS Language Information (Type 13)' @ 0x000e0754, field 'BIOS Language String 1', offset 0x04 Other failures: NONE Test |Pass |Fail |Abort|Warn |Skip |Info | ---------------+-----+-----+-----+-----+-----+-----+ acpiinfo | | | | | | 3| acpitables | 8| 1| | | | | apicedge | | 3| | | | | apicinstance | 1| | | | | | aspm | 7| 2| | 22| | | bios32 | | | | | | | bios_info | | | | | | 1| checksum | 19| | | | | | cpufreq | | 7| | 1| | | crs | | | | | 1| | csm | | | | | | 1| cstates | 1| | | | | | dmar | 2| | | | | | dmi_decode | 37| 7| | | | | ebda | 1| | | | | | fadt | 1| | | | | | fan | 2| | | | | | hda_audio | 2| | | | | | hpet_check | 1| | | | | | klog | | 4| | | | | maxfreq | | 1| | | | | maxreadreq | | 1| | | | | mcfg | 2| | | | | | method | 434| 3| | 1| 109| | microcode | | | 1| | | | mpcheck | | | | | 9| | msr | 89| | | | | | mtrr | 1| 22| | | 1| | nx | 2| | | | | | oops | 2| | | | | | os2gap | 1| | | | | | osilinux | | | | 2| | | pcc | | | | | | 1| pciirq | | | | | | | pnp | 2| | | | | | securebootcert | | | 1| | | | smbios | 1| | | | | | syntaxcheck | 4| 12| | | | | version | | | | | | 4| virt | 1| | | | | | wakealarm | 4| | | | | | wmi | | | | | | | ---------------+-----+-----+-----+-----+-----+-----+ Total: | 625| 63| 2| 26| 120| 10| ---------------+-----+-----+-----+-----+-----+-----+