Intel Box Core I5 4670 3 4g BX80646I54670 User Manual

®
Desktop 4th Generation Intel  
Core™ Processor Family, Desktop  
®
®
Intel Pentium Processor  
®
Family, and Desktop Intel  
®
Celeron Processor Family  
Specification Update  
December 2013  
Revision 007  
Reference Number: 328899-007  
Contents  
4
Specification Update  
Revision History  
Revision  
Description  
Date  
001  
002  
Initial Release.  
June 2013  
No Updates. Revision number added to Revision History to maintain  
consistency with NDA Specification Update numbering.  
N/A  
August 2013  
N/A  
Errata  
003  
004  
— Added HSD59-99  
Updated Identification Information  
No Updates. Revision number added to Revision History to maintain  
consistency with NDA Specification Update numbering.  
Errata  
— Moved previous HSD99 to HSD108  
— Added HSD99-107 and HSD109-115  
Updated Identification Information  
005  
November 2013  
Identification Information  
— Updated Desktop Processor Identification table  
006  
007  
December 2013  
December 2013  
Errata  
— Added HSD116-118  
Specification Update  
5
 
Preface  
This document is an update to the specifications contained in the Affected Documents  
table below. This document is a compilation of device and documentation errata,  
specification clarifications and changes. It is intended for hardware system  
manufacturers and software developers of applications, operating systems, or tools.  
Information types defined in Nomenclature are consolidated into the specification  
update and are no longer published in other documents.  
This document may also contain information that was not previously published.  
Affected Documents  
Document Title  
Document Number  
®
®
®
®
Desktop 4th Generation Intel Core™ Processor Family, Desktop Intel Pentium Processor Family,  
328897  
®
and Desktop Intel Celeron Processor Family Datasheet – Volume 1 of 2  
®
®
®
®
Desktop 4th Generation Intel Core™ Processor Family, Desktop Intel Pentium Processor Family,  
328898  
®
and Desktop Intel Celeron Processor Family Datasheet – Volume 2 of 2  
Related Documents  
Document Number/  
Location  
Document Title  
design/processor/  
®
AP-485, Intel Processor Identification and the CPUID Instruction  
®
Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 1: Basic Architecture  
®
Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2A: Instruction Set  
Reference Manual A-M  
®
Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2B: Instruction Set  
products/processor/  
Reference Manual N-Z  
®
Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3A: System Programming  
Guide  
®
Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3B: System Programming  
Guide  
®
Intel 64 and IA-32 Intel Architecture Optimization Reference Manual  
design/processor/  
®
Intel 64 and IA-32 Architectures Software Developer’s Manual Documentation Changes  
ACPI Specifications  
6
Specification Update  
 
Nomenclature  
Errata are design defects or errors. These may cause the processor behavior to  
deviate from published specifications. Hardware and software designed to be used with  
any given stepping must assume that all errata documented for that stepping are  
present on all devices.  
S-Spec Number is a five-digit code used to identify products. Products are  
differentiated by their unique characteristics such as, core speed, L2 cache size,  
package type, etc. as described in the processor identification information table. Read  
all notes associated with each S-Spec number.  
Specification Changes are modifications to the current published specifications.  
These changes will be incorporated in any new release of the specification.  
Specification Clarifications describe a specification in greater detail or further  
highlight a specification’s impact to a complex design situation. These clarifications will  
be incorporated in any new release of the specification.  
Documentation Changes include typos, errors, or omissions from the current  
published specifications. These will be incorporated in any new release of the  
specification.  
Note:  
Errata remain in the specification update throughout the product’s lifecycle, or until a  
particular stepping is no longer commercially available. Under these circumstances,  
errata removed from the specification update are archived and available upon request.  
Specification changes, specification clarifications and documentation changes are  
removed from the specification update when the appropriate changes are made to the  
appropriate product specification or user documentation (datasheets, manuals, and so  
on).  
Specification Update  
7
Summary Tables of Changes  
The following tables indicate the errata, specification changes, specification  
clarifications, or documentation changes which apply to the processor. Intel may fix  
some of the errata in a future stepping of the component, and account for the other  
outstanding issues through documentation or specification changes as noted. These  
tables uses the following notations.  
Codes Used in Summary Tables  
Stepping  
X:  
Errata exists in the stepping indicated. Specification Change or  
Clarification that applies to this stepping.  
(No mark)  
or (Blank box):  
This erratum is fixed in listed stepping or specification change  
does not apply to listed stepping.  
Page  
(Page):  
Page location of item in this document.  
Status  
Doc:  
Document change or update will be implemented.  
This erratum may be fixed in a future stepping of the product.  
This erratum has been previously fixed.  
Plan Fix:  
Fixed:  
No Fix:  
There are no plans to fix this erratum.  
Row  
Change bar to left of a table row indicates this erratum is either new or modified from  
the previous version of the document.  
8
Specification Update  
 
Errata (Sheet 1 of 5)  
Steppings  
Number  
Status  
ERRATA  
C-0  
LBR, BTS, BTM May Report a Wrong Address when an Exception/  
Interrupt Occurs in 64-bit Mode  
HSD1  
HSD2  
X
No Fix  
No Fix  
No Fix  
EFLAGS Discrepancy on Page Faults and on EPT-Induced VM Exits after  
a Translation Change  
X
MCi_Status Overflow Bit May Be Incorrectly Set on a Single Instance of a  
DTLB Error  
HSD3  
HSD4  
HSD5  
X
X
X
No Fix LER MSRs May Be Unreliable  
MONITOR or CLFLUSH on the Local XAPIC's Address Space Results in  
No Fix  
Hang  
An Uncorrectable Error Logged in IA32_CR_MC2_STATUS May also  
Result in a System Hang  
HSD6  
HSD7  
X
X
No Fix  
#GP on Segment Selector Descriptor that Straddles Canonical Boundary  
May Not Provide Correct Exception Error Code  
No Fix  
FREEZE_WHILE_SMM Does Not Prevent Event From Pending  
PEBS During SMM  
HSD8  
HSD9  
X
X
X
No Fix  
No Fix APIC Error “Received Illegal Vector” May be Lost  
Changing the Memory Type for an In-Use Page Translation May Lead to  
Memory-Ordering Violations  
HSD10  
No Fix  
Performance Monitor Precise Instruction Retired Event May Present  
Wrong Indications  
HSD11  
HSD12  
HSD13  
X
X
X
No Fix  
No Fix CR0.CD Is Ignored in VMX Operation  
Instruction Fetch May Cause Machine Check if Page Size and Memory  
Type Was Changed Without Invalidation  
No Fix  
Execution of VAESIMC or VAESKEYGENASSIST With An Illegal Value  
for VEX.vvvv May Produce a #NM Exception  
HSD14  
HSD15  
HSD16  
X
X
X
No Fix  
No Fix Processor May Fail to Acknowledge a TLP Request  
Interrupt From Local APIC Timer May Not Be Detectable While Being  
Delivered  
No Fix  
PCIe* Root-port Initiated Compliance State Transmitter Equalization  
Settings May be Incorrect  
HSD17  
X
No Fix  
HSD18  
HSD19  
X
X
No Fix PCIe* Controller May Incorrectly Log Errors on Transition to RxL0s  
No Fix Unused PCIe* Lanes May Report Correctable Errors  
Accessing Physical Memory Space 0-640K through the Graphics  
No Fix  
HSD20  
HSD21  
HSD22  
X
X
X
Aperture May Cause Unpredictable System Behavior  
No Fix PCIe Root Port May Not Initiate Link Speed Change  
Pending x87 FPU Exceptions (#MF) May be Signaled Earlier Than  
Expected  
No Fix  
DR6.B0-B3 May Not Report All Breakpoints Matched When a MOV/POP  
SS is Followed by a Store or an MMX Instruction  
HSD23  
HSD24  
HSD25  
X
X
X
No Fix  
No Fix VEX.L is Not Ignored with VCVT*2SI Instructions  
Certain Local Memory Read / Load Retired PerfMon Events May  
Undercount  
No Fix  
Specification Update  
9
Errata (Sheet 2 of 5)  
Steppings  
Number  
Status  
ERRATA  
C-0  
Specific Graphics Blitter Instructions May Result in Unpredictable  
Graphics Controller Behavior  
HSD26  
HSD27  
HSD28  
X
No Fix  
No Fix  
No Fix  
Processor May Enter Shutdown Unexpectedly on a Second  
Uncorrectable Error  
X
X
Modified Compliance Patterns for 2.5 GT/s and 5 GT/s Transfer Rates Do  
Not Follow PCIe* Specification  
HSD29  
HSD30  
HSD31  
X
X
X
No Fix Performance Monitor Counters May Produce Incorrect Results  
No Fix Performance Monitor UOPS_EXECUTED Event May Undercount  
No Fix MSR_PERF_STATUS May Report an Incorrect Core Voltage  
PCIe* Atomic Transactions From Two or More PCIe Controllers May  
Cause Starvation  
HSD32  
HSD33  
HSD34  
X
X
X
No Fix  
The Corrected Error Count Overflow Bit in IA32_ MC0_STATUS is Not  
Updated After a UC Error is Logged  
No Fix  
An AVX Gather Instruction That Causes an EPT Violation May Not  
Update Previous Elements  
No Fix  
HSD35  
HSD36  
HSD37  
HSD38  
X
X
X
X
No Fix PLATFORM_POWER_LIMIT MSR Not Visible  
No Fix LPDDR Memory May Report Incorrect Temperature  
No Fix PCIe* Host Bridge DID May Be Incorrect  
No Fix TSC May be Incorrect After a Deep C-State Exit  
PCIe* Controller May Initiate Speed Change While in DL_Init State  
Causing Certain PCIe Devices to Fail to Train  
HSD39  
X
No Fix  
HSD40  
HSD41  
X
X
No Fix Spurious VT-d Interrupts May Occur When the PFO Bit is Set  
No Fix N/A. Erratum has been removed.  
AVX Gather Instruction That Causes a Fault or VM Exit May Incorrectly  
Modify Its Destination Register  
HSD42  
X
No Fix  
Inconsistent NaN Propagation May Occur When Executing (V)DPPS  
Instruction  
HSD43  
HSD44  
HSD45  
X
X
X
No Fix  
No Fix Display May Flicker When Package C-States Are Enabled  
Certain Combinations of AVX Instructions May Cause Unpredictable  
System Behavior  
No Fix  
HSD46  
HSD47  
HSD48  
X
X
X
No Fix Processor May Incorrectly Estimate Peak Power Delivery Requirements  
No Fix IA32_PERF_CTL MSR is Incorrectly Reset  
No Fix Processor May Hang During a Function Level Reset of the Display  
AVX Gather Instruction That Should Result in #DF May Cause  
Unexpected System Behavior  
HSD49  
X
No Fix  
Throttling and Refresh Rate Maybe be Incorrect After Exiting Package C-  
HSD50  
HSD51  
HSD52  
X
X
X
No Fix  
State  
No Fix Processor May Livelock During On Demand Clock Modulation  
IA32_DEBUGCTL.FREEZE_PERFMON_ON_PMI is Incorrectly Cleared  
No Fix  
by SMI  
HSD53  
HSD54  
X
X
No Fix The From-IP for Branch Tracing May be Incorrect  
No Fix TM1 Throttling May Continue indefinitely  
10  
Specification Update  
Errata (Sheet 3 of 5)  
Steppings  
Number  
Status  
ERRATA  
C-0  
Internal Parity Errors May Incorrectly Report Overflow in The  
IA32_MCi_STATUS MSR  
HSD55  
X
No Fix  
No Fix  
Performance Monitor Events OTHER_ASSISTS.AVX_TO_SSE And  
OTHER_ASSISTS.SSE_TO_AVX May Over Count  
HSD56  
HSD57  
HSD58  
X
X
X
No Fix Processor May Run at Incorrect P-State  
Performance Monitor Event DSB2MITE_SWITCHES.COUNT May Over  
No Fix  
Count  
Performance Monitor Register UNC_PERF_GLOBAL_STATUS Not  
Restored on Package C7 Exit  
HSD59  
HSD60  
HSD61  
HSD62  
X
X
X
X
No Fix  
Processor May Not Enter Package C6 or Deeper C-states When PCIe*  
Links Are Disabled  
No Fix  
Performance Monitor Event For Outstanding Offcore Requests And  
Snoop Requests May Over Count  
No Fix  
Some Performance Monitor Event Counts May be Inaccurate During SMT  
No Fix  
Mode  
HSD63  
HSD64  
X
X
No Fix Timed MWAIT May Use Deadline of a Previous Execution  
No Fix The Upper 32 Bits of CR3 May be Incorrectly Used With 32-Bit Paging  
Performance Monitor Events HLE_RETIRED.ABORTED_MISC4 And  
No Fix  
HSD65  
X
RTM_RETIRED.ABORTED_MISC4 May Over Count  
HSD66  
HSD67  
HSD68  
HSD69  
X
X
X
X
No Fix A PCIe* LTR Update Message May Cause The Processor to Hang  
No Fix GETSEC Does Not Report Support For S-CRTM  
No Fix EPT Violations May Report Bits 11:0 of Guest Linear Address Incorrectly  
No Fix APIC Timer Might Not Signal an Interrupt While in TSC-Deadline Mode  
IA32_VMX_VMCS_ENUM MSR (48AH) Does Not Properly Report The  
Highest Index Value Used For VMCS Encoding  
HSD70  
HSD71  
X
X
No Fix  
Incorrect FROM_IP Value For an RTM Abort in BTM or BTS May be  
Observed  
No Fix  
VT-d Hardware May Perform STRP And SIRTP Operations on a Package  
C7 Exit  
HSD72  
HSD73  
HSD74  
X
X
X
No Fix  
No Fix General-Purpose Performance Counters Can Unexpectedly Increment  
Performance Monitoring Events May Report Incorrect Number of Load  
Hits or Misses to LLC  
No Fix  
Performance Monitoring Event INSTR_RETIRED.ALL May Generate  
Redundant PEBS Records For an Overflow  
HSD75  
HSD76  
HSD77  
X
X
X
No Fix  
No Fix Locked Load Performance Monitoring Events May Under Count  
Graphics Processor Ratio And C-State Transitions May Cause a System  
No Fix  
Hang  
Certain Performance Monitoring Events May Over Count Software  
Demand Loads  
HSD78  
HSD79  
X
X
No Fix  
Accessing Nonexistent Uncore Performance Monitoring MSRs May Not  
Signal a #GP  
No Fix  
HSD80  
HSD81  
X
X
No Fix Call Stack Profiling May Produce Extra Call Records  
No Fix Warm Reset May Fail or Lead to Incorrect Power Regulation  
Specification Update  
11  
Errata (Sheet 4 of 5)  
Steppings  
Number  
Status  
ERRATA  
C-0  
HSD82  
HSD83  
X
X
No Fix PCIe* Host Bridge DID May Be Incorrect  
No Fix Transactional Abort May Produce an Incorrect Branch Record  
SMRAM State-Save Area Above the 4GB Boundary May Cause  
Unpredictable System Behavior  
HSD84  
HSD85  
HSD86  
X
X
X
No Fix  
DMA Remapping Faults for the Graphics VT-d Unit May Not Properly  
Report Type of Faulted Request  
No Fix  
AVX Gather Instructions Page Faults May Report an Incorrect Faulting  
Address  
No Fix  
HSD87  
HSD88  
HSD89  
X
X
X
No Fix Intel® TSX Instructions May Cause Unpredictable System behavior  
No Fix Event Injection by VM Entry May Use an Incorrect B Flag for SS  
No Fix A Fault in SMM May Result in Unpredictable System Behavior  
Processor Frequency is Unexpectedly Limited Below Nominal P1 When  
cTDP Down is Enabled  
HSD90  
HSD91  
HSD92  
X
X
X
No Fix  
PMI May be Signaled More Than Once For Performance Monitor Counter  
Overflow  
No Fix  
Execution of FXSAVE or FXRSTOR With the VEX Prefix May Produce a  
#NM Exception  
No Fix  
RDRAND Execution in a Transactional Region May Cause a System  
HSD93  
HSD94  
HSD95  
X
X
X
No Fix  
Hang  
No Fix Uncore Clock Frequency Changes May Cause Audio/Video Glitches  
Processor May Experience a Spurious LLC-Related Machine Check  
During Periods of High Activity  
No Fix  
HSD96  
HSD97  
HSD98  
HSD99  
X
X
X
X
No Fix The Processor May Not Enter Package C7 When Using a PSR Display  
No Fix Video/Audio Distortion May Occur  
No Fix System May Hang When Audio is Enabled During Package C3  
No Fix INVPCID May Not Cause #UD in VMX Non-Root Operation  
Non-Compliant PFAT Module Base Address May Cause Unpredictable  
System Behavior  
HSD100  
HSD101  
HSD102  
HSD103  
X
X
X
X
No Fix  
Incorrect LBR Source Address May be Reported For a Transactional  
No Fix  
Abort  
Address Translation Faults for Intel® VT-d May Not be Reported for  
Display Engine Memory Accesses  
No Fix  
L3 Cache Corrected Error Count May be Inaccurate After Package C7  
No Fix  
Exit  
HSD104  
HSD105  
HSD106  
HSD107  
X
X
X
X
No Fix PCIe* Device’s SVID is Not Preserved Across The Package C7 C-State  
No Fix Warm Reset Does Not Stop GT Power Draw  
No Fix Unused PCIe* Lanes May Remain Powered After Package C7  
No Fix BMI1 And BMI2 Instruction Groups Are Not Available  
Virtual-APIC Page Accesses With 32-Bit PAE Paging May Cause a  
System Crash  
HSD108  
HSD109  
X
X
No Fix  
No Fix Processor Energy Policy Selection May Not Work as Expected  
12  
Specification Update  
Errata (Sheet 5 of 5)  
Steppings  
Number  
Status  
ERRATA  
C-0  
A PEBS Record May Contain Processor State for an Unexpected  
Instruction  
HSD110  
HSD111  
HSD112  
X
X
X
No Fix  
No Fix MSR_PP1_ENERGY_STATUS Reports Incorrect Energy Data  
x87 FPU DP May be Incorrect After Instructions That Save FP State to  
Memory  
No Fix  
HSD113  
HSD114  
HSD115  
HSD116  
HSD117  
X
X
X
X
X
No Fix Processor May Hang During Package C7 Exit  
No Fix Intel® TSX Instructions May Cause Unpredictable System behavior  
No Fix Spurious LLC Machine Check May Occur  
No Fix Page Fault May Report Incorrect Fault Information  
No Fix CATERR# Pin Assertion is Not Cleared on a Warm Reset  
Uncorrectable Machine Check Error During Core C6 Entry May Not be  
Signaled  
HSD118  
X
No Fix  
Specification Changes  
Number  
SPECIFICATION CHANGES  
None for this revision of this specification update.  
Specification Clarifications  
Number  
SPECIFICATION CLARIFICATIONS  
None for this revision of this specification update.  
Documentation Changes  
Number  
DOCUMENTATION CHANGES  
HSD1  
”On-Demand Clock Modulation Feature Clarification”  
Specification Update  
13  
Identification Information  
Component Identification using Programming Interface  
The processor stepping can be identified by the following register contents.  
®
Table 1.  
Desktop 4th Generation Intel Core™ Processor Family Component  
Identification  
Extended  
Family  
Extended  
Model  
Processor  
Type  
Family  
Code  
Model  
Number  
Stepping  
ID  
Reserved  
Reserved  
31:28  
27:20  
19:16  
0011b  
15:14  
13:12  
00b  
11:8  
7:4  
3:0  
00000000b  
0110b  
1100b  
xxxxb  
Notes:  
1.  
The Extended Family, Bits [27:20] are used in conjunction with the Family Code, specified in Bits[11:8], to  
®
®
indicate whether the processor belongs to the Intel386™, Intel486™, Pentium , Pentium 4, or Intel  
Core™ processor family.  
2.  
3.  
The Extended Model, Bits [19:16] in conjunction with the Model Number, specified in Bits [7:4], are used to  
identify the model of the processor within the processor’s family.  
The Family Code corresponds to Bits [11:8] of the EDX register after RESET, Bits [11:8] of the EAX register  
after the CPUID instruction is executed with a 1 in the EAX register, and the generation field of the Device  
ID register accessible through Boundary Scan.  
4.  
5.  
The Model Number corresponds to Bits [7:4] of the EDX register after RESET, Bits [7:4] of the EAX register  
after the CPUID instruction is executed with a 1 in the EAX register, and the model field of the Device ID  
register accessible through Boundary Scan.  
The Stepping ID in Bits [3:0] indicates the revision number of that model. See the processor Identification  
table for the processor stepping ID number in the CPUID information.  
When EAX is initialized to a value of ‘1, the CPUID instruction returns the Extended  
Family, Extended Model, Processor Type, Family Code, Model Number and Stepping ID  
value in the EAX register. Note that the EDX processor signature value after reset is  
equivalent to the processor signature output value in the EAX register.  
Cache and TLB descriptor parameters are provided in the EAX, EBX, ECX and EDX  
registers after the CPUID instruction is executed with a 2 in the EAX register.  
The processor can be identified by the following register contents.  
Host Device  
Processor Graphics  
1
4
Stepping  
Vendor ID  
Revision ID  
CRID  
2
3
ID  
Device ID  
C-0  
8086h  
0C04h  
GT2 = 0416h  
06h  
06h  
Notes:  
1.  
2.  
3.  
4.  
The Vendor ID corresponds to bits 15:0 of the Vendor ID Register located at offset 00h–01h in the PCI  
function 0 configuration space.  
The Host Device ID corresponds to bits 15:0 of the Device ID Register located at Device 0 offset 02h–  
03h in the PCI function 0 configuration space.  
The Processor Graphics Device ID (DID2) corresponds to bits 15:0 of the Device ID Register located at  
Device 2 offset 02h–03h in the PCI function 0 configuration space.  
The Revision Number corresponds to bits 7:0 of the Revision ID Register located at offset 08h in the PCI  
function 0 configuration space.  
14  
Specification Update  
 
Component Marking Information  
The processor stepping can be identified by the following component markings.  
®
Figure 1.  
Desktop 4th Generation Intel Core™ Processor Family Top-Side Markings  
Table 2.  
Desktop Processor Identification (Sheet 1 of 2)  
Max  
Thermal  
Design  
Power  
(W)  
Cache  
Size  
(MB)  
Func-  
tional  
Core  
Integrated  
Graphics  
Cores  
Turbo  
Freq.  
Rate  
Core  
Freq.  
(GHz)  
S-Spec  
Number  
Processor  
Number  
Memory  
(MHz)  
Stepping  
(GHz)  
SR147  
SR149  
SR14A  
SR14D  
SR14E  
SR14F  
SR14G  
SR14H  
SR14J  
SR14K  
SR14L  
SR14M  
SR14N  
SR14P  
SR14Q  
I7-4770K  
I7-4770  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
8
8
6
6
6
6
6
8
6
6
6
6
8
6
8
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
3.9  
3.9  
3.8  
3.8  
3.6  
3.3  
3.2  
3.9  
3.6  
3.8  
3.3  
3.2  
3.7  
3.3  
3
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
1600  
3.5  
3.4  
3.4  
3.4  
3.2  
3.1  
3
95  
95  
95  
95  
95  
95  
95  
65  
65  
65  
65  
65  
45  
45  
35  
I5-4670K  
I5-4670  
I5-4570  
I5-4440  
I5-4430  
I7-4770S  
I5-4570S  
I5-4670S  
I5-4440S  
I5-4430S  
I7-4770T  
I5-4670T  
I7-4765T  
3.1  
2.9  
3.1  
2.8  
2.7  
2.5  
2.3  
2
Specification Update  
15  
Table 2.  
Desktop Processor Identification (Sheet 2 of 2)  
Max  
Thermal  
Design  
Power  
(W)  
Cache  
Size  
(MB)  
Func-  
tional  
Core  
Integrated  
Graphics  
Cores  
Turbo  
Freq.  
Rate  
Core  
Freq.  
(GHz)  
S-Spec  
Number  
Processor  
Number  
Memory  
(MHz)  
Stepping  
(GHz)  
SR18K  
SR18M  
SR18Q  
SR1BW  
SR1CA  
SR1CE  
SR1CG  
SR1CL  
SR1NB  
SR1NK  
SR1NL  
SR1NM  
SR1NN  
SR1NP  
I7-4770R  
I5-4670R  
I5-4570R  
I7-4771  
I5-4570T  
G3430  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
C-0  
6
4
4
8
4
3
3
3
3
4
4
4
3
3
4
4
4
4
2
2
2
2
2
2
2
2
2
2
3
3
3
2
2
1
1
1
1
2
2
2
2
2
3.9  
3.7  
3.2  
3.9  
3.6  
3.3  
3
1600  
1600  
1600  
1600  
1600  
1600  
1333  
1333  
1333  
1600  
1600  
1600  
1600  
1600  
3.2  
3
65  
65  
65  
95  
35  
65  
65  
35  
65  
35  
65  
65  
35  
65  
2.7  
3.5  
2.9  
3.3  
3
G3220  
G3220T  
G3420  
2.6  
3.2  
3
2.6  
3.2  
3
I3-4330T  
I3-4340  
I3-4330  
I3-4130T  
I3-4130  
3.6  
3.5  
2.9  
3.4  
3.6  
3.5  
2.9  
3.4  
Celeron  
G1820  
SR1CN  
SR1CP  
SR1NC  
C-0  
C-0  
C-0  
2
2
2
2
2
2
1
1
1
2.7  
2.4  
2.8  
1333  
1333  
1333  
2.7  
2.4  
2.8  
65  
35  
65  
Celeron  
G1820T  
Celeron  
G1830  
16  
Specification Update  
Errata  
HSD1.  
LBR, BTS, BTM May Report a Wrong Address when an Exception/  
Interrupt Occurs in 64-bit Mode  
Problem:  
An exception/interrupt event should be transparent to the LBR (Last Branch Record),  
BTS (Branch Trace Store) and BTM (Branch Trace Message) mechanisms. However,  
during a specific boundary condition where the exception/interrupt occurs right after  
the execution of an instruction at the lower canonical boundary (0x00007FFFFFFFFFFF)  
in 64-bit mode, the LBR return registers will save a wrong return address with bits 63  
to 48 incorrectly sign extended to all 1’s. Subsequent BTS and BTM operations which  
report the LBR will also be incorrect.  
Implication: LBR, BTS and BTM may report incorrect information in the event of an exception/  
interrupt.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD2.  
EFLAGS Discrepancy on Page Faults and on EPT-Induced VM Exits  
after a Translation Change  
Problem:  
This erratum is regarding the case where paging structures are modified to change a  
linear address from writable to non-writable without software performing an  
appropriate TLB invalidation. When a subsequent access to that address by a specific  
instruction (ADD, AND, BTC, BTR, BTS, CMPXCHG, DEC, INC, NEG, NOT, OR, ROL/ROR,  
SAL/SAR/SHL/SHR, SHLD, SHRD, SUB, XOR, and XADD) causes a page fault or an EPT-  
induced VM exit, the value saved for EFLAGS may incorrectly contain the arithmetic flag  
values that the EFLAGS register would have held had the instruction completed without  
fault or VM exit. For page faults, this can occur even if the fault causes a VM exit or if  
its delivery causes a nested fault.  
Implication: None identified. Although the EFLAGS value saved by an affected event (a page fault or  
an EPT-induced VM exit) may contain incorrect arithmetic flag values, Intel has not  
identified software that is affected by this erratum. This erratum will have no further  
effects once the original instruction is restarted because the instruction will produce the  
same results as if it had initially completed without fault or VM exit.  
Workaround: If the handler of the affected events inspects the arithmetic portion of the saved  
EFLAGS value, then system software should perform a synchronized paging structure  
modification and TLB invalidation.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD3.  
MCi_Status Overflow Bit May Be Incorrectly Set on a Single Instance  
of a DTLB Error  
Problem:  
A single Data Translation Look Aside Buffer (DTLB) error can incorrectly set the  
Overflow (bit [62]) in the MCi_Status register. A DTLB error is indicated by MCA error  
code (bits [15:0]) appearing as binary value, 000x 0000 0001 0100, in the MCi_Status  
register.  
Implication: Due to this erratum, the Overflow bit in the MCi_Status register may not be an  
accurate indication of multiple occurrences of DTLB errors. There is no other impact to  
normal processor functionality.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
17  
 
HSD4.  
LER MSRs May Be Unreliable  
Problem:  
Due to certain internal processor events, updates to the LER (Last Exception Record)  
MSRs, MSR_LER_FROM_LIP (1DDH) and MSR_LER_TO_LIP (1DEH), may happen when  
no update was expected.  
Implication: The values of the LER MSRs may be unreliable.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD5.  
MONITOR or CLFLUSH on the Local XAPIC's Address Space Results in  
Hang  
Problem:  
If the target linear address range for a MONITOR or CLFLUSH is mapped to the local  
xAPIC's address space, the processor will hang.  
Implication: When this erratum occurs, the processor will hang. The local xAPIC's address space  
must be uncached. The MONITOR instruction only functions correctly if the specified  
linear address range is of the type write-back. CLFLUSH flushes data from the cache.  
Intel has not observed this erratum with any commercially available software.  
Workaround: Do not execute MONITOR or CLFLUSH instructions on the local xAPIC address space.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD6.  
An Uncorrectable Error Logged in IA32_CR_MC2_STATUS May also  
Result in a System Hang  
Problem:  
Uncorrectable errors logged in IA32_CR_MC2_STATUS MSR (409H) may also result in a  
system hang causing an Internal Timer Error (MCACOD = 0x0400h) to be logged in  
another machine check bank (IA32_MCi_STATUS).  
Implication: Uncorrectable errors logged in IA32_CR_MC2_STATUS can further cause a system hang  
and an Internal Timer Error to be logged.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD7.  
#GP on Segment Selector Descriptor that Straddles Canonical  
Boundary May Not Provide Correct Exception Error Code  
Problem:  
During a #GP (General Protection Exception), the processor pushes an error code on to  
the exception handler’s stack. If the segment selector descriptor straddles the  
canonical boundary, the error code pushed onto the stack may be incorrect.  
Implication: An incorrect error code may be pushed onto the stack. Intel has not observed this  
erratum with any commercially available software.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
18  
Specification Update  
HSD8.  
FREEZE_WHILE_SMM Does Not Prevent Event From Pending  
PEBS During SMM  
Problem:  
In general, a PEBS record should be generated on the first count of the event after the  
counter has overflowed. However, IA32_DEBUGCTL_MSR.FREEZE_WHILE_SMM  
(MSR 1D9H, bit [14]) prevents performance counters from counting during SMM  
(System Management Mode). Due to this erratum, if  
1. A performance counter overflowed before an SMI  
2. A PEBS record has not yet been generated because another count of the event has  
not occurred  
3. The monitored event occurs during SMM  
then a PEBS record will be saved after the next RSM instruction.  
When FREEZE_WHILE_SMM is set, a PEBS should not be generated until the event  
occurs outside of SMM.  
Implication: A PEBS record may be saved after an RSM instruction due to the associated  
performance counter detecting the monitored event during SMM; even when  
FREEZE_WHILE_SMM is set.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD9.  
APIC Error “Received Illegal Vector” May be Lost  
Problem:  
APIC (Advanced Programmable Interrupt Controller) may not update the ESR (Error  
Status Register) flag Received Illegal Vector bit [6] properly when an illegal vector  
error is received on the same internal clock that the ESR is being written (as part of the  
write-read ESR access flow). The corresponding error interrupt will also not be  
generated for this case.  
Implication: Due to this erratum, an incoming illegal vector error may not be logged into ESR  
properly and may not generate an error interrupt.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD10.  
Changing the Memory Type for an In-Use Page Translation May Lead  
to Memory-Ordering Violations  
Problem:  
Under complex microarchitectural conditions, if software changes the memory type for  
data being actively used and shared by multiple threads without the use of semaphores  
or barriers, software may see load operations execute out of order.  
Implication: Memory ordering may be violated. Intel has not observed this erratum with any  
commercially available software.  
Workaround: Software should ensure pages are not being actively used before requesting their  
memory type be changed.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
19  
HSD11.  
Performance Monitor Precise Instruction Retired Event May Present  
Wrong Indications  
Problem:  
When the PDIR (Precise Distribution for Instructions Retired) mechanism is activated  
(INST_RETIRED.ALL (event C0H, umask value 00H) on Counter 1 programmed in PEBS  
mode), the processor may return wrong PEBS/PMI interrupts and/or incorrect counter  
values if the counter is reset with a SAV below 100 (Sample-After-Value is the counter  
reset value software programs in MSR IA32_PMC1[47:0] in order to control interrupt  
frequency).  
Implication: Due to this erratum, when using low SAV values, the program may get incorrect PEBS  
or PMI interrupts and/or an invalid counter state.  
Workaround: The sampling driver should avoid using SAV<100.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD12.  
CR0.CD Is Ignored in VMX Operation  
Problem:  
If CR0.CD=1, the MTRRs and PAT should be ignored and the UC memory type should  
be used for all memory accesses. Due to this erratum, a logical processor in VMX  
operation will operate as if CR0.CD=0 even if that bit is set to 1.  
Implication: Algorithms that rely on cache disabling may not function properly in VMX operation.  
Workaround: Algorithms that rely on cache disabling should not be executed in VMX root operation.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD13.  
Instruction Fetch May Cause Machine Check if Page Size and Memory  
Type Was Changed Without Invalidation  
Problem:  
This erratum may cause a machine-check error (IA32_MCi_STATUS.MCACOD=0150H)  
on the fetch of an instruction that crosses a 4-KByte address boundary. It applies only  
if (1) the 4-KByte linear region on which the instruction begins is originally translated  
using a 4-KByte page with the WB memory type; (2) the paging structures are later  
modified so that linear region is translated using a large page (2-MByte, 4-MByte, or 1-  
GByte) with the UC memory type; and (3) the instruction fetch occurs after the paging-  
structure modification but before software invalidates any TLB entries for the linear  
region.  
Implication: Due to this erratum an unexpected machine check with error code 0150H may occur,  
possibly resulting in a shutdown. Intel has not observed this erratum with any  
commercially available software.  
Workaround: Software should not write to a paging-structure entry in a way that would change, for  
any linear address, both the page size and the memory type. It can instead use the  
following algorithm: first clear the P flag in the relevant paging-structure entry (e.g.,  
PDE); then invalidate any translations for the affected linear addresses; and then  
modify the relevant paging-structure entry to set the P flag and establish the new page  
size and memory type.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
20  
Specification Update  
HSD14.  
Execution of VAESIMC or VAESKEYGENASSIST With An Illegal Value  
for VEX.vvvv May Produce a #NM Exception  
Problem:  
The VAESIMC and VAESKEYGENASSIST instructions should produce a #UD (Invalid-  
Opcode) exception if the value of the vvvv field in the VEX prefix is not 1111b. Due to  
this erratum, if CR0.TS is “1, the processor may instead produce a #NM (Device-Not-  
Available) exception.  
Implication: Due to this erratum, some undefined instruction encodings may produce a #NM instead  
of a #UD exception.  
Workaround: Software should always set the vvvv field of the VEX prefix to 1111b for instances of  
the VAESIMC and VAESKEYGENASSIST instructions.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD15.  
Processor May Fail to Acknowledge a TLP Request  
Problem:  
When a PCIe root port’s receiver is in Receiver L0s power state and the port initiates a  
Recovery event, it will issue Training Sets to the link partner. The link partner will  
respond by initiating an L0s exit sequence. Prior to transmitting its own Training Sets,  
the link partner may transmit a TLP (Transaction Layer Packet) request. Due to this  
erratum, the root port may not acknowledge the TLP request.  
Implication: After completing the Recovery event, the PCIe link partner will replay the TLP request.  
The link partner may set a Correctable Error status bit, which has no functional effect.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD16.  
Interrupt From Local APIC Timer May Not Be Detectable While Being  
Delivered  
Problem:  
If the local-APIC timer’s CCR (current-count register) is 0, software should be able to  
determine whether a previously generated timer interrupt is being delivered by first  
reading the delivery-status bit in the LVT timer register and then reading the bit in the  
IRR (interrupt-request register) corresponding to the vector in the LVT timer register. If  
both values are read as 0, no timer interrupt should be in the process of being  
delivered. Due to this erratum, a timer interrupt may be delivered even if the CCR is 0  
and the LVT and IRR bits are read as 0. This can occur only if the DCR (Divide  
Configuration Register) is greater than or equal to 4. The erratum does not occur if  
software writes zero to the Initial Count Register before reading the LVT and IRR bits.  
Implication: Software that relies on reads of the LVT and IRR bits to determine whether a timer  
interrupt is being delivered may not operate properly.  
Workaround: Software that uses the local-APIC timer must be prepared to handle the timer  
interrupts, even those that would not be expected based on reading CCR and the LVT  
and IRR bits; alternatively, software can avoid the problem by writing zero to the Initial  
Count Register before reading the LVT and IRR bits.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
21  
HSD17.  
PCIe* Root-port Initiated Compliance State Transmitter Equalization  
Settings May be Incorrect  
Problem:  
If the processor is directed to enter PCIe Polling.Compliance at 5.0 GT/s or 8.0 GT/s  
transfer rates, it should use the Link Control 2 Compliance Preset/De-emphasis field  
(bits [15:12]) to determine the correct de-emphasis level. Due to this erratum, when  
the processor is directed to enter Polling.Compliance from 2.5 GT/s transfer rate, it  
retains 2.5 GT/s de-emphasis values.  
Implication: The processor may operate in Polling.Compliance mode with an incorrect transmitter  
de-emphasis level.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD18.  
PCIe* Controller May Incorrectly Log Errors on Transition to RxL0s  
Problem:  
Due to this erratum, if a link partner transitions to RxL0s state within 20 ns of entering  
L0 state, the PCIe controller may incorrectly log an error in “Correctable Error  
Status.Receiver Error Status” field (Bus 0, Device 2, Function 0, 1, 2 and Device 6,  
Function 0, offset 1D0H, bit 0).  
Implication: Correctable receiver errors may be incorrectly logged. Intel has not observed any  
functional impact due to this erratum with any commercially available add-in cards.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD19.  
Unused PCIe* Lanes May Report Correctable Errors  
Problem:  
Due to this erratum, during PCIe* link down configuration, unused lanes may report a  
Correctable Error Detected in Bus 0, Device 1, Function 0-2, and Device 6, Function 0,  
Offset 158H, Bit 0.  
Implication: Correctable Errors may be reported by a PCIe controller for unused lanes.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD20.  
Accessing Physical Memory Space 0-640K through the Graphics  
Aperture May Cause Unpredictable System Behavior  
Problem:  
The physical memory space 0-640K when accessed through the graphics aperture may  
result in a failure for writes to complete or reads to return incorrect results.  
Implication: A hang or functional failure may occur during graphics operation such as OGL or OCL  
conformance tests, 2D/3D games and graphics intensive application.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
22  
Specification Update  
HSD21.  
PCIe Root Port May Not Initiate Link Speed Change  
Problem:  
The PCIe Base specification requires the upstream component to maintain the PCIe link at the  
target link speed or the highest speed supported by both components on the link, whichever is  
lower. PCIe root port will not initiate the link speed change without being triggered by the software  
when the root port maximum link speed is configured to be 5.0 GT/s. System BIOS will trigger  
the link speed change under normal boot scenarios. However, BIOS is not involved in  
some scenarios such as link disable/re-enable or secondary bus reset and therefore the  
speed change may not occur unless initiated by the downstream component. This  
erratum does not affect the ability of the downstream component to initiate a link  
speed change. All known 5.0Gb/s-capable PCIe downstream components have been  
observed to initiate the link speed change without relying on the root port to do so.  
Implication: Due to this erratum, the PCIe root port may not initiate a link speed change during  
some hardware scenarios causing the PCIe link to operate at a lower than expected  
speed. Intel has not observed this erratum with any commercially available platform.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD22.  
Pending x87 FPU Exceptions (#MF) May be Signaled Earlier Than  
Expected  
Problem:  
x87 instructions that trigger #MF normally service interrupts before the #MF. Due to  
this erratum, if an instruction that triggers #MF is executed while Enhanced Intel  
SpeedStep Technology transitions, Intel Turbo Boost Technology transitions, or  
Thermal Monitor events occur, the pending #MF may be signaled before pending  
interrupts are serviced.  
®
®
Implication: Software may observe #MF being signaled before pending interrupts are serviced.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD23.  
DR6.B0-B3 May Not Report All Breakpoints Matched When a MOV/POP  
SS is Followed by a Store or an MMX Instruction  
Problem:  
Normally, data breakpoints matches that occur on a MOV SS, r/m or POP SS will not  
cause a debug exception immediately after MOV/POP SS but will be delayed until the  
instruction boundary following the next instruction is reached. After the debug  
exception occurs, DR6.B0-B3 bits will contain information about data breakpoints  
matched during the MOV/POP SS as well as breakpoints detected by the following  
instruction. Due to this erratum, DR6.B0-B3 bits may not contain information about  
data breakpoints matched during the MOV/POP SS when the following instruction is  
either an MMX instruction that uses a memory addressing mode with an index or a  
store instruction.  
Implication: When this erratum occurs, DR6 may not contain information about all breakpoints  
matched. This erratum will not be observed under the recommended usage of the MOV  
SS,r/m or POP SS instructions (i.e., following them only with an instruction that writes  
(E/R)SP).  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
23  
HSD24.  
VEX.L is Not Ignored with VCVT*2SI Instructions  
Problem:  
The VEX.L bit should be ignored for the VCVTSS2SI, VCVTSD2SI, VCVTTSS2SI, and  
VCVTTSD2SI instructions, however due to this erratum the VEX.L bit is not ignored and  
will cause a #UD.  
Implication: Unexpected #UDs will be seen when the VEX.L bit is set to 1 with VCVTSS2SI,  
VCVTSD2SI, VCVTTSS2SI, and VCVTTSD2SI instructions.  
Workaround: Software should ensure that the VEX.L bit is set to 0 for all scalar instructions.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD25.  
Certain Local Memory Read / Load Retired PerfMon Events May  
Undercount  
Problem:  
Due to this erratum, the Local Memory Read / Load Retired PerfMon events listed below  
may undercount.  
MEM_LOAD_RETIRED.L3_HIT  
MEM_LOAD_RETIRED.L3_MISS  
MEM_LOAD_L3_HIT_RETIRED.XSNP_MISS  
MEM_LOAD_L3_HIT_RETIRED.XSNP_HIT  
MEM_LOAD_L3_HIT_RETIRED.XSNP_HITM  
MEM_LOAD_L3_HIT_RETIRED.XSNP_NONE  
MEM_LOAD_L3_MISS_RETIRED.LOCAL_DRAM  
MEM_LOAD_L4_RETIRED.LOCAL_HIT  
MEM_TRANS_RETIRED.LOAD_LATENCY  
Implication: The affected events may undercount, resulting in inaccurate memory profiles. Intel has  
observed undercounts as much as 40%.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD26.  
Specific Graphics Blitter Instructions May Result in Unpredictable  
Graphics Controller Behavior  
®
Problem:  
Specific source-copy blitter instructions in Intel HD Graphics 4600 Processor may  
result in unpredictable behavior when a blit source and destination overlap.  
Implication: Due to this erratum, the processor may exhibit unpredictable graphics controller  
behavior. Intel has not observed this erratum with any commercially available software.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD27.  
Processor May Enter Shutdown Unexpectedly on a Second  
Uncorrectable Error  
Problem:  
If an IA32_MCi_STATUS MSR contains an uncorrectable error with MCACOD=0x406 and  
a second uncorrectable error occurs after warm reset but before the first error is  
cleared by zeroing the IA32_MCi_STATUS MSR, a shutdown will occur.  
Implication: When this erratum occurs, the processor will unexpectedly shut down instead of  
executing the machine check handler.  
Workaround: None identified. Software should clear IA32_MCi_STATUS MSRs as early as possible to  
minimize the possibility of this erratum occurring.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
24  
Specification Update  
HSD28.  
Modified Compliance Patterns for 2.5 GT/s and 5 GT/s Transfer Rates  
Do Not Follow PCIe* Specification  
Problem:  
The PCIe controller does not produce the PCIe specification defined sequence for the  
Modified Compliance Pattern at 2.5 GT/s and 5 GT/s transfer rates. This erratum is not  
seen at 8 GT/s transfer rates.  
Implication: Normal PCIe operation is unaffected by this erratum.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD29.  
Performance Monitor Counters May Produce Incorrect Results  
Problem:  
When operating with SMT enabled, a memory at-retirement performance monitoring  
event (from the list below) may be dropped or may increment an enabled event on the  
corresponding counter with the same number on the physical core’s other thread rather  
than the thread experiencing the event. Processors with SMT disabled in BIOS are not  
affected by this erratum.  
The list of affected memory at-retirement events is as follows:  
MEM_UOP_RETIRED.LOADS  
MEM_UOP_RETIRED.STORES  
MEM_UOP_RETIRED.LOCK  
MEM_UOP_RETIRED.SPLIT  
MEM_UOP_RETIRED.STLB_MISS  
MEM_LOAD_UOPS_RETIRED.HIT_LFB  
MEM_LOAD_UOPS_RETIRED.L1_HIT  
MEM_LOAD_UOPS_RETIRED.L2_HIT  
MEM_LOAD_UOPS_RETIRED.LLC_HIT  
MEM_LOAD_UOPS_MISC_RETIRED.LLC_MISS  
MEM_LOAD_UOPS_LLC_HIT_RETIRED.XSNP_HIT  
MEM_LOAD_UOPS_LLC_HIT_RETIRED.XSNP_HITM  
MEM_LOAD_UOPS_LLC_HIT_RETIRED.XSNP_MISS  
MEM_LOAD_UOPS_LLC_HIT_RETIRED.XSNP_NONE  
MEM_LOAD_UOPS_RETIRED.LLC_MISS  
MEM_LOAD_UOPS_LLC_MISS_RETIRED.LOCAL_DRAM  
MEM_LOAD_UOPS_LLC_MISS_RETIRED.REMOTE_DRAM  
MEM_LOAD_UOPS_RETIRED.L2_MISS  
Implication: Due to this erratum, certain performance monitoring event will produce unreliable  
results during hyper-threaded operation.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD30.  
Performance Monitor UOPS_EXECUTED Event May Undercount  
Problem:  
The performance monitor event UOPS_EXECUTED (Event B1H, any Unmask) should  
count the number of UOPs executed each cycle. However due to this erratum, when  
eight UOPs execute in one cycle, these UOPs will not be counted.  
Implication: The performance monitor event UOPS_EXECUTED may reflect a count lower than the  
actual number of events.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
25  
HSD31.  
MSR_PERF_STATUS May Report an Incorrect Core Voltage  
Problem:  
The core operating voltage can be determined by dividing MSR_PERF_STATUS MSR  
(198H) bits [47:32] by 2^13. However, due to this erratum, this calculation may report  
half the actual core voltage.  
Implication: The core operating voltage may be reported incorrectly.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD32.  
PCIe* Atomic Transactions From Two or More PCIe Controllers May  
Cause Starvation  
Problem:  
On a Processor PCIe controller configuration in which two or more controllers receive  
concurrent atomic transactions, a PCIe controller may experience starvation which  
eventually can lead to a completion timeout.  
Implication: Atomic transactions from two or more PCIe controllers may lead to a completion  
timeout. Atomic transactions from only one controller will not be affected by this  
erratum. Intel has not observed this erratum with any commercially available device.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD33.  
The Corrected Error Count Overflow Bit in IA32_ MC0_STATUS is Not  
Updated After a UC Error is Logged  
Problem:  
When a UC (uncorrected) error is logged in the IA32_MC0_STATUS MSR (401H),  
corrected errors will continue to update the lower 14 bits (bits 51:38) of the Corrected  
Error Count. Due to this erratum, the sticky count overflow bit (bit 52) of the Corrected  
Error Count will not get updated after a UC error is logged.  
Implication: The Corrected Error Count Overflow indication will be lost if the overflow occurs after an  
uncorrectable error has been logged.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD34.  
An AVX Gather Instruction That Causes an EPT Violation May Not  
Update Previous Elements  
Problem:  
When execution of an AVX gather instruction causes an EPT (extended page table)  
violation due to a specific element, all previous elements should be complete. Due to  
this erratum, such an execution may fail to complete previous elements. In addition,  
the instruction's mask operand is not updated. This erratum applies only if the EPT  
violation occurs while updating an accessed or dirty flag in a paging-structure entry.  
Instructions impacted by this erratum are: VGATHERDPS, VGATHERDPD, VGATHERQPS,  
VGATHERQPD, VPGATHERDD, VPGATHERDQ, VPGATHERQD, and VPGATHERQQ.  
Implication: This erratum may prevent a gather instruction from making forward progress.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
26  
Specification Update  
HSD35.  
PLATFORM_POWER_LIMIT MSR Not Visible  
Problem:  
The PLATFORM_POWER_LIMIT MSR (615H) is used to control the PL3 (power limit 3)  
mechanism of the processor. Due to this erratum, this MSR is not visible to software.  
Implication: Software is unable to read or write the PLATFORM_POWER_LIMIT MSR. If software  
attempts to access this MSR, a general protection fault will occur.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD36.  
LPDDR Memory May Report Incorrect Temperature  
Problem:  
When any of the four possible LPDDR ranks are not populated, the unpopulated ranks  
will report a default temperature of 85C as a three bit value of 011b. If the system has  
unpopulated ranks the temperature of memory will be reported as 85C  
in PCU_CR_DDR_DIMM_HOTTEST_ABSOLUTE (MCHBAR Bus 0; Device 0; Function 0;  
offset 58B8H) in bits [5:7], until any of the populated ranks report a higher  
temperature than this.  
Implication: When the memory temperature is less than or equal to 85C it may be reported as  
85C. This erratum does not affect DDR3 and DDR3L memory types.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD37.  
PCIe* Host Bridge DID May Be Incorrect  
Problem:  
The PCIe Host Bridge DID register (Bus 0; Device 0; Offset 2H) contents may be  
incorrect after a Package C7 exit.  
Implication: Software that depends on the Host Bridge DID value may not behave as expected after  
a Package C7 exit.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD38.  
TSC May be Incorrect After a Deep C-State Exit  
Problem:  
On exiting from Package C6 or deeper, the processor may incorrectly restore the TSC  
(Time Stamp Counter).  
Implication: Software using the TSC may produce incorrect result and/or may not behave as  
expected.  
Workaround: It is possible for BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD39.  
PCIe* Controller May Initiate Speed Change While in DL_Init State  
Causing Certain PCIe Devices to Fail to Train  
Problem:  
The PCIe controller supports hardware autonomous speed change capabilities. Due to  
this erratum, the PCIe controller may initiate speed change while in the DL_Init state  
which may prevent link training for certain PCIe devices.  
Implication: Certain PCIe devices may fail to complete DL_Init causing the PCIe link to fail to train.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
27  
HSD40.  
Spurious VT-d Interrupts May Occur When the PFO Bit is Set  
Problem:  
When the PFO (Primary Fault Overflow) field (bit [0] in the VT-d FSTS [Fault Status]  
register) is set to 1, further faults should not generate an interrupt. Due to this  
erratum, further interrupts may still occur.  
Implication: Unexpected Invalidation Queue Error interrupts may occur. Intel has not observed this  
erratum with any commercially available software.  
Workaround: Software should be written to handle spurious VT-d fault interrupts.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD41.  
HSD42.  
N/A. Erratum has been removed  
AVX Gather Instruction That Causes a Fault or VM Exit May Incorrectly  
Modify Its Destination Register  
Problem:  
An execution of a 128-bit AVX gather instruction zeroes the upper 128 bits of the  
instruction's destination register unless access to the first unmasked element causes a  
fault or VM exit. Due to this erratum, these bits may be cleared even when accessing  
the first unmasked element causes a fault or VM exit. Instructions impacted by this  
erratum are: VGATHERDPS, VGATHERDPD, VGATHERQPS, VGATHERQPD,  
VPGATHERDD, VPGATHERDQ, VPGATHERQD, and VPGATHERQQ.  
Implication: Software that depends on the destination register of a 128-bit AVX gather instruction to  
remain unchanged after access of the first unmasked element results in fault or VM exit  
may not behave as expected.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD43.  
Inconsistent NaN Propagation May Occur When Executing (V)DPPS  
Instruction  
Problem:  
Upon completion of the (V)DPPS instruction with multiple different NaN encodings in  
the input elements, software may observe different NaN encodings in the destination  
elements.  
Implication: Inconsistent NaN encodings in the destination elements for the (V) DPPS instruction  
may be observed.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
28  
Specification Update  
HSD44.  
Display May Flicker When Package C-States Are Enabled  
Problem:  
When package C-States are enabled, the display may not be refreshed at the correct  
rate.  
Implication: When this erratum occurs, the user may observe flickering on the display.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD45.  
Certain Combinations of AVX Instructions May Cause Unpredictable  
System Behavior  
Problem:  
Execution of certain combinations of AVX instructions may lead to unpredictable system  
behavior.  
Implication: When this erratum occurs, unpredictable system behaviors, including system hang or  
incorrect results can occur.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD46.  
Processor May Incorrectly Estimate Peak Power Delivery  
Requirements  
Problem:  
Under certain conditions, the processor may incorrectly calculate the frequency at  
which the cores and graphics engine can operate while still meeting voltage regulator  
and power supply peak power delivery capabilities. When this occurs, combined with  
high power workloads, system shutdown may be observed.  
Implication: When this erratum occurs, system shutdown may be observed under high power  
workloads.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD47.  
IA32_PERF_CTL MSR is Incorrectly Reset  
Problem:  
The IA32_PERF_CTL MSR (199H) is not initialized correctly after a processor reset.  
Implication: If software reads the IA32_PERF_CTL MSR before writing it, software can observe an  
incorrect reset value. Although incorrect values are reported to software, the correct  
default values for this register are still used by the processor. No performance or power  
impact occurs due to this erratum.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD48.  
Processor May Hang During a Function Level Reset of the Display  
Problem:  
When package C-States are enabled, it is possible that the processor may hang when  
software performs a Function Level Reset of the display via bit 1 of the Advanced  
Features Control Register (Bus 0; Device 2; Function 0; Offset 0A8H).  
Implication: When this erratum occurs, the processor may hang.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
29  
HSD49.  
AVX Gather Instruction That Should Result in #DF May Cause  
Unexpected System Behavior  
Problem:  
Due to this erratum, an execution of a 128-bit AVX gather instruction may fail to  
generate a #DF (double fault) when expected. Instructions impacted by this erratum  
are: VGATHERDPS, VGATHERDPD, VGATHERQPS, VGATHERQPD, VPGATHERDD,  
VPGATHERDQ, VPGATHERQD, and VPGATHERQQ.  
Implication: When this erratum occurs, an operation which should cause a #DF may result in  
unexpected system behavior.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD50.  
Throttling and Refresh Rate Maybe be Incorrect After Exiting Package  
C-State  
Problem:  
When the OLTM (Open Loop Thermal Management) feature is enabled, the DIMM  
thermal status reported in DDR_THERM_PERDIMM_STATUS (MCHBAR Offset 588CH)  
may be incorrect following an exit from Package C3 or deeper.  
Implication: The incorrect DIMM thermal status may result in degraded performance from unneeded  
memory throttling and excessive DIMM refresh rates.  
Workaround: It is possible for BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD51.  
Processor May Livelock During On Demand Clock Modulation  
Problem:  
The processor may livelock when (1) a processor thread has enabled on demand clock  
modulation via bit 4 of the IA32_CLOCK_MODULATION MSR (19AH) and the clock  
modulation duty cycle is set to 12.5% (02H in bits 3:0 of the same MSR), and (2) the  
other processor thread does not have on demand clock modulation enabled and that  
thread is executing a stream of instructions with the lock prefix that either split a  
cacheline or access UC memory.  
Implication: Program execution may stall on both threads of the core subject to this erratum.  
Workaround: This erratum will not occur if clock modulation is enabled on all threads when using on  
demand clock modulation or if the duty cycle programmed in the  
IA32_CLOCK_MODULATION MSR is 18.75% or higher.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD52.  
IA32_DEBUGCTL.FREEZE_PERFMON_ON_PMI is Incorrectly Cleared by  
SMI  
Problem:  
FREEZE_PERFMON_ON_PMI (bit 12) in the IA32_DEBUGCTL MSR (1D9H) is  
erroneously cleared during delivery of an SMI (system-management interrupt).  
Implication: As a result of this erratum, the performance monitoring counters will continue to count  
after a PMI occurs in SMM (system-management Mode).  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
30  
Specification Update  
HSD53.  
The From-IP for Branch Tracing May be Incorrect  
Problem:  
BTM (Branch Trace Message) and BTS (Branch Trace Store) report the “From-IP”  
indicating the source address of the branch instruction. Due to this erratum, BTM and  
BTS may repeat the “From-IP” value previously reported. The “To-IP” value is not  
affected.  
Implication: Using BTM or BTS reports to reconstruct program execution may be unreliable.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD54.  
TM1 Throttling May Continue indefinitely  
Problem:  
TM1 (Thermal Monitor 1) throttling may continue when the processor’s temperature  
decreases below the throttling point while the processor is in Package C3 or deeper.  
Implication: The processor will continue thermal throttling but does not indicate it is hot.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD55.  
Internal Parity Errors May Incorrectly Report Overflow in The  
IA32_MCi_STATUS MSR  
Problem:  
Due to this erratum, uncorrectable internal parity error reports with an  
IA32_MCi_STATUS.MCACOD (bits [15:0]) value of 0005H and an  
IA32_MCi_STATUS.MSCOD (bits [31:16]) value of 0004H may incorrectly set the  
IA32_MCi_STATUS.OVER flag (bit 62) indicating an overflow even when only a single  
error has been observed.  
Implication: IA32_MCi_STATUS.OVER may not accurately indicate multiple occurrences of  
uncorrectable internal parity errors. There is no other impact to normal processor  
functionality.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD56.  
Performance Monitor Events OTHER_ASSISTS.AVX_TO_SSE And  
OTHER_ASSISTS.SSE_TO_AVX May Over Count  
Problem:  
The Performance Monitor events OTHER_ASSISTS.AVX_TO_SSE (Event C1H; Umask  
08H) and OTHER_ASSISTS.SSE_TO_AVX (Event C1H; Umask 10H) incorrectly  
increment and over count when an HLE (Hardware Lock Elision) abort occurs.  
Implication: The Performance Monitor Events OTHER_ASSISTS.AVX_TO_SSE And  
OTHER_ASSISTS.SSE_TO_AVX may over count.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD57.  
Processor May Run at Incorrect P-State  
Problem:  
The processor package may use stale software P-State (performance state) requests  
when one or more logical processors are idle.  
Implication: The processor package may run at a higher or lower than expected P-State. This issue  
may persist as long as any logical processor is idle.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
31  
HSD58.  
Performance Monitor Event DSB2MITE_SWITCHES.COUNT May Over  
Count  
Problem:  
The Performance Monitor Event DSB2MITE_SWITCHES.COUNT (Event ABH; Umask  
01H) should count the number of DSB (Decode Stream Buffer) to MITE (Macro  
Instruction Translation Engine) switches. Due to this erratum, the  
DSB2MITE_SWITCHES.COUNT event will count speculative switches and cause the  
count to be higher than expected.  
Implication: The Performance Monitor Event DSB2MITE_SWITCHES.COUNT may report count higher  
than expected.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD59.  
Performance Monitor Register UNC_PERF_GLOBAL_STATUS Not  
Restored on Package C7 Exit  
Problem:  
MSR_UNC_PERF_GLOBAL_STATUS (392H) is a global status register which indicates  
the overflow of uncore performance monitor counters. The content of this register is  
lost in package C7 state.  
Implication: If any uncore performance monitor counter has overflowed before entering the  
package C7 state, the MSR_UNC_PERF_GLOBAL_STATUS register will no longer reflect  
the overflow after exiting C7 state.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD60.  
Processor May Not Enter Package C6 or Deeper C-states When PCIe*  
Links Are Disabled  
Problem:  
If the PCIe links are disabled via Link Disable (Bus 0, Device 1, Functions [2:1], Offset  
B0h, bit 4) and the PCIe controller is enabled (Bus 0, Device 0, Function 0, Offset 54h,  
bits [2:1] = ’11), then the processor will be unable to enter Package C6 or deeper C-  
states.  
Implication: Due to this erratum, the process will not enter Package C6 or deeper C-states.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD61.  
Performance Monitor Event For Outstanding Offcore Requests And  
Snoop Requests May Over Count  
Problem:  
The performance monitor event OFFCORE_REQUESTS_OUTSTANDING (Event 60H, any  
Umask Value) should count the number of offcore outstanding transactions each cycle.  
Due to this erratum, the counts may be higher than actual number of events.  
Implication: The performance monitor events OFFCORE_REQUESTS_OUTSTANDING may reflect  
counts higher than the actual number of events.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
32  
Specification Update  
HSD62.  
Some Performance Monitor Event Counts May be Inaccurate During  
SMT Mode  
Problem:  
The performance monitor event OFFCORE_REQUESTS_OUTSTANDING (Event 60H, any  
Umask Value) should count the number of occurrences that loads or stores stay in the  
super queue each cycle. The performance monitor event  
CYCLE_ACTIVITY.CYCLES_L2_PENDING (Event A3H, Umask 01H) should count the  
number of cycles that demand loads stay in the super queue. However, due to this  
erratum, these events may count inaccurately during SMT mode.  
Implication: The performance monitor events OFFCORE_REQUESTS_OUTSTANDING and  
CYCLE_ACTIVITY.L2_ PENDING may be unreliable during SMT Mode.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD63.  
Timed MWAIT May Use Deadline of a Previous Execution  
Problem:  
A timed MWAIT instruction specifies a TSC deadline for execution resumption. If a wake  
event causes execution to resume before the deadline is reached, a subsequent timed  
MWAIT instruction may incorrectly use the deadline of the previous timed MWAIT when  
that previous deadline is earlier than the new one.  
Implication: A timed MWAIT may end earlier than expected.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD64.  
The Upper 32 Bits of CR3 May be Incorrectly Used With 32-Bit Paging  
Problem:  
When 32-bit paging is in use, the processor should use a page directory located at the  
32-bit physical address specified in bits 31:12 of CR3; the upper 32 bits of CR3 should  
be ignored. Due to this erratum, the processor will use a page directory located at the  
64-bit physical address specified in bits 63:12 of CR3.  
Implication: The processor may use an unexpected page directory or, if EPT (Extended Page Tables)  
is in use, cause an unexpected EPT violation. This erratum applies only if software  
enters 64-bit mode, loads CR3 with a 64-bit value, and then returns to 32-bit paging  
without changing CR3. Intel has not observed this erratum with any commercially  
available software.  
Workaround: Software that has executed in 64-bit mode should reload CR3 with a 32-bit value  
before returning to 32-bit paging.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD65.  
Performance Monitor Events HLE_RETIRED.ABORTED_MISC4 And  
RTM_RETIRED.ABORTED_MISC4 May Over Count  
Problem:  
The Performance Monitor Events HLE_RETIRED.ABORTED_MISC4 (Event C8H; Umask  
40H) and RTM_RETIRED.ABORTED_MISC4 (Event C9H; Umask 40H) are defined to  
count the number of transactional aborts due to incompatible memory types. Due to  
this erratum, they may count additional unrelated transactional aborts.  
Implication: The Performance Monitor Events HLE_RETIRED.ABORTED_MISC4 and  
RTM_RETIRED.ABORTED_MISC4 counts may be greater than the number of aborts due  
to incompatible memory types. This can result in nonzero counts when all memory  
types are compatible.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
33  
HSD66.  
A PCIe* LTR Update Message May Cause The Processor to Hang  
Problem:  
If a PCIe device sends an LTR (Latency Tolerance Report) update message while the  
processor is in a package C6 or deeper, the processor may hang.  
Implication: Due to this Erratum the processor may hang if a PCIe LTR update message is received  
while in a Package C6 or deeper.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD67.  
GETSEC Does Not Report Support For S-CRTM  
®
Problem:  
Processors with Intel Boot Guard Technology that has GETSEC[PARAMETERS] leaf 5  
EAX bit 5 set indicates support for processor rooted S-CTRM (Static Core Root of Trust  
for Measurement). Due to this erratum, that bit will not be set even though processor  
rooted S-CRTM is supported.  
Implication: Software may be unaware of support for processor rooted S-CTRM.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD68.  
EPT Violations May Report Bits 11:0 of Guest Linear Address  
Incorrectly  
Problem:  
If a memory access to a linear address requires the processor to update an accessed or  
dirty flag in a paging-structure entry and if that update causes an EPT violation, the  
processor should store the linear address into the “guest linear address” field in the  
VMCS. Due to this erratum, the processor may store an incorrect value into bits 11:0 of  
this field. (The processor correctly stores the guest-physical address of the paging-  
structure entry into the “guest-physical address” field in the VMCS.)  
Implication: Software may not be easily able to determine the page offset of the original memory  
access that caused the EPT violation. Intel has not observed this erratum to impact the  
operation of any commercially available software.  
Workaround: Software requiring the page offset of the original memory access address can derive it  
by simulating the effective address computation of the instruction that caused the EPT  
violation.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD69.  
APIC Timer Might Not Signal an Interrupt While in TSC-Deadline Mode  
Problem:  
If the APIC timer is in TSC-deadline mode and is armed when a timed MWAIT  
instruction is executed, the timer expiration might not cause an interrupt.  
Implication: Software depending on APIC timer TSC-deadline mode interrupts may not behave as  
expected.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
34  
Specification Update  
HSD70.  
IA32_VMX_VMCS_ENUM MSR (48AH) Does Not Properly Report The  
Highest Index Value Used For VMCS Encoding  
Problem:  
IA32_VMX_VMCS_ENUM MSR (48AH) bits 9:1 report the highest index value used for  
any VMCS encoding. Due to this erratum, the value 21 is returned in bits 9:1 although  
there is a VMCS field whose encoding uses the index value 23.  
Implication: Software that uses the value reported in IA32_VMX_VMCS_ENUM[9:1] to read and  
write all VMCS fields may omit one field.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD71.  
Incorrect FROM_IP Value For an RTM Abort in BTM or BTS May be  
Observed  
Problem:  
During RTM (Restricted Transactional Memory) operation when branch tracing is  
enabled using BTM (Branch Trace Message) or BTS (Branch Trace Store), the incorrect  
EIP value (From_IP pointer) may be observed for an RTM abort.  
Implication: Due to this erratum, the From_IP pointer may be the same as that of the immediately  
preceding taken branch.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD72.  
VT-d Hardware May Perform STRP And SIRTP Operations on a Package  
C7 Exit  
Problem:  
On a package C7 exit, VT-d hardware may spuriously perform SRTP (Set Root Table  
Pointer) and SIRTP (Set Interrupt Remapping Table Pointer) operations. A package C7  
exit can cause the value programmed by software in the RTA_REG (IRTA_REG) to be  
visible to hardware before software executes a GCMD.SRTP command. This will result in  
hardware using the new values for the DMA and interrupt translation page-walks,  
possibly before they are intended to be used by software.  
Implication: If software has updated the root table pointer but has not executed the SRTP command  
then the root table pointer update will happen unexpectedly, causing the VMM to walk  
incorrect or non-existent tables. Intel has not observed this erratum with any  
commercially available software.  
Workaround: Privileged software should not execute a MWAIT (because it can trigger a package C7  
entry/exit) between writing to RTA_REG (IRTA_REG) and GCMD_REG.SRTP  
(GCMD_REG.SIRTP) registers.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD73.  
General-Purpose Performance Counters Can Unexpectedly Increment  
Problem:  
A performance monitor event programmed in a general-purpose performance counter  
should count the number of occurrences of the event selected in IA32_PERFEVTSEL{0-  
7} MSR (186H-18DH). If INV (invert, bit 23) is set to 1 and a non-zero CMASK  
(Counter Mask) bits [31:24] value is used, due to this erratum, the event may over  
count in the case that either of OS (Operating System mode, bit 17) or USR (User  
mode, bit 16) is selected. Over counting will occur for the cycles spent in the non-  
matching CPL.  
Implication: General-purpose performance counters may reflect counts higher than the actual  
number of events when the INV bit is set, CMASK is a non-zero value and either the OS  
or USR bit is set.  
Workaround: None identified.  
Specification Update  
35  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD74.  
Performance Monitoring Events May Report Incorrect Number of Load  
Hits or Misses to LLC  
Problem:  
The following performance monitor events should count the numbers of loads hitting or  
missing LLC. However due to this erratum, The L3_hit related events may over count  
and the L3_miss related events may undercount.  
MEM_LOAD_RETIRED.L3_HIT (Event D1H, Umask 40H)  
MEM_LOAD_RETIRED.L3_MISS (Event D1H, Umask 20H)  
MEM_LOAD_L3_HIT_RETIRED. XSNP_NONE (Event D2H, Umask 08H)  
MEM_LOAD_LLC_MISS_RETIRED. LOCAL_DRAM (Event D3H, Umask 01H)  
Implication: The listed performance monitoring events may be inaccurate.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD75.  
Performance Monitoring Event INSTR_RETIRED.ALL May Generate  
Redundant PEBS Records For an Overflow  
Problem:  
Due to this erratum, the performance monitoring feature PDIR (Precise Distribution of  
Instructions Retired) for INSTR_RETIRED.ALL (Event C0H; Umask 01H) will generate  
redundant PEBS (Precise Event Based Sample) records for a counter overflow. This can  
occur if the lower 6 bits of the performance monitoring counter are not initialized or  
reset to 0, in the PEBS counter reset field of the DS Buffer Management Area.  
Implication: The above event count will under count on locked loads hitting the L2 cache.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD76.  
Locked Load Performance Monitoring Events May Under Count  
Problem:  
The performance monitoring events MEM_TRANS_RETIRED.LOAD_LATENCY (Event  
CDH; Umask 01H), MEM_LOAD_RETIRED.L2_HIT (Event D1H; Umask 02H), and  
MEM_UOPS_RETIRED.LOCKED (Event DOH; Umask 20H) should count the number of  
locked loads. Due to this erratum, these events may under count for locked  
transactions that hit the L2 cache.  
Implication: The above event count will under count on locked loads hitting the L2 cache.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD77.  
Graphics Processor Ratio And C-State Transitions May Cause a System  
Hang  
Problem:  
If ratio or C-state changes involving the processor core and processor graphics occur at  
the same time or while processor graphics are active, under certain internal conditions  
the ratio change may not complete.  
Implication: The system may hang during C-state or ratio changes.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
36  
Specification Update  
HSD78.  
Certain Performance Monitoring Events May Over Count Software  
Demand Loads  
Problem:  
The following performance monitor events should count the number of software  
demand loads. However due to this erratum, they may also include requests from the  
Next Page Prefetcher and over count.  
OFFCORE_REQUESTS_OUTSTANDING.DEMAND_DATA (Event 60H; Umask 01H)  
OFFCORE_REQUESTS.DEMAND_DATA (Event B0H; Umask 01H)  
CYCLE_ACTIVITY.L2_Pending (Event A3H; Umask 01H)  
L2_HIT_MISS.LOAD (Event 24H; Umask 01H)  
Implication: The listed performance monitoring events may reflect a count higher than the actual  
number of events.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD79.  
Accessing Nonexistent Uncore Performance Monitoring MSRs May Not  
Signal a #GP  
Problem:  
An access to an uncore Performance Monitor MSR beyond the number reported in the  
MSR_UNC_CBO_CONFIG MSR (396H) bits[3:0] should signal a #GP (general-  
protection exception); due to this erratum, the processor may hang instead of signaling  
#GP.  
Implication: When software accesses nonexistent uncore performance monitoring MSRs, the logical  
processor may hang instead of signaling a #GP.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD80.  
Call Stack Profiling May Produce Extra Call Records  
Problem:  
The performance monitoring Call Stack Profiling function should not generate call  
records for “zero length calls” (call instructions targeting the location following the  
instruction). However, due to this erratum, the processor will produce call records for  
zero length calls.  
Implication: The performance monitoring LBR call stack MSRs are incorrect in the presence of “zero  
length calls” because calls and returns do not match.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD81.  
Warm Reset May Fail or Lead to Incorrect Power Regulation  
Problem:  
Due to this erratum, after a warm reset, the processor may fail to boot properly or may  
cause power to be regulated to an incorrect level.  
Implication: The processor may not be able to control the VR (Voltage Regulator) to advertised  
specifications, leading to in a system hang, a machine check, or improper power  
regulation.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
37  
HSD82.  
PCIe* Host Bridge DID May Be Incorrect  
Problem:  
The PCIe Host Bridge DID register (Bus 0; Device 0; Function 0; Offset 2H) contents  
may be incorrect.  
Implication: Software that depends on the Host Bridge DID value may not behave as expected.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD83.  
Transactional Abort May Produce an Incorrect Branch Record  
®
Problem:  
If an Intel TSX transactional abort event occurs during a string instruction, the From-  
IP in the LBR (Last Branch Record) is not correctly reported.  
Implication: Due to this erratum, an incorrect From-IP on the LBR stack may be observed.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD84.  
SMRAM State-Save Area Above the 4GB Boundary May Cause  
Unpredictable System Behavior  
Problem:  
If BIOS uses the RSM instruction to load the SMBASE register with a value that would  
cause any part of the SMRAM state-save area to have an address above 4-GBytes,  
subsequent transitions into and out of SMM (system-management mode) might save  
and restore processor state from incorrect addresses.  
Implication: This erratum may cause unpredictable system behavior. Intel has not observed this  
erratum with any commercially available system.  
Workaround: Ensure that the SMRAM state-save area is located entirely below the 4GB address  
boundary.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD85.  
DMA Remapping Faults for the Graphics VT-d Unit May Not Properly  
Report Type of Faulted Request  
Problem:  
When a fault occurs during DMA remapping of Graphics accesses at the Graphics VT-d  
unit, the type of faulted request (read or write) should be reported in bit 126 of the  
FRCD_REG register in the remapping hardware memory map register set. Due to this  
erratum, the request type may not be reported correctly.  
Implication: Software processing the DMA remapping faults may not be able to determine the type  
of faulting graphics device DMA request.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD86.  
AVX Gather Instructions Page Faults May Report an Incorrect Faulting  
Address  
Problem:  
If software modifies a paging-structure entry to relax the access rights for a linear address  
and does not perform a TLB invalidation, a subsequent execution of an AVX gather  
instruction that accesses that address may generate a page fault that loads CR2 (which  
should containing the faulting linear address) with an incorrect value.  
Implication: Software handling an affected page fault may not operate correctly.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
38  
Specification Update  
®
HSD87.  
Intel TSX Instructions May Cause Unpredictable System behavior  
Problem:  
Under certain system conditions, Intel TSX (Transactional Synchronization Extensions)  
instructions may result in unpredictable system behavior.  
Implication: Due to this erratum, use of Intel TSX may result in unpredictable behavior.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD88.  
Event Injection by VM Entry May Use an Incorrect B Flag for SS  
Problem:  
The stack accesses made by VM-entry event injection may use an incorrect value for  
the B flag (default stack-pointer size and upper bound) for the stack segment (SS).  
Implication: An affected stack access may use an incorrect address or an incorrect segment upper  
bound. This may result in unpredictable system behavior.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD89.  
A Fault in SMM May Result in Unpredictable System Behavior  
Problem:  
The value of the SS register as well as the current privilege level (CPL) may be  
incorrect following a fault in SMM (system-management mode). The erratum can occur  
only if a fault occurs following an SMI (system-management interrupt) and before  
software has loaded the SS register (e.g., with the MOV SS instruction).  
Implication: This erratum may cause unpredictable system behavior. Intel has not observed this  
erratum with any commercially available software.  
Workaround: None identified  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD90.  
Processor Frequency is Unexpectedly Limited Below Nominal P1 When  
cTDP Down is Enabled  
Problem:  
When cTDP (Configurable Thermal Design Power) Down is enabled on a processor  
®
®
branded as Core i3 or Pentium , the processor frequency will be limited to cTDP  
Down P1 frequency (Max Non-Turbo Frequency) when it should be able to operate  
between the cTDP Down frequency P1 and the nominal P1 frequency.  
Implication: When cTDP is enabled, the processor cannot achieve expected frequencies.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD91.  
PMI May be Signaled More Than Once For Performance Monitor  
Counter Overflow  
Problem:  
Due to this erratum, PMI (Performance Monitoring Interrupt) may be repeatedly issued  
until the counter overflow bit is cleared in the overflowing counter.  
Implication: Multiple PMIs may be received when a performance monitor counter overflows.  
Workaround: None identified. If the PMI is programmed to generate an NMI, software may delay the  
EOI (end-of- Interrupt) register write for the interrupt until after the overflow  
indications have been cleared.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
39  
HSD92.  
Execution of FXSAVE or FXRSTOR With the VEX Prefix May Produce a  
#NM Exception  
Problem:  
Attempt to use FXSAVE or FXRSTOR with a VEX prefix should produce a #UD (Invalid-  
Opcode) exception. If either the TS or EM flag bits in CR0 are set, a #NM (device-not-  
available) exception will be raised instead of #UD exception.  
Implication: Due to this erratum a #NM exception may be signaled instead of a #UD exception on  
an FXSAVE or an FXRSTOR with a VEX prefix.  
Workaround: Software should not use FXSAVE or FXRSTOR with the VEX prefix.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD93.  
RDRAND Execution in a Transactional Region May Cause a System  
Hang  
®
Problem:  
Execution of the RDRAND (Random number generator) instruction inside an Intel TSX  
transactional region may cause the logical processor to hang.  
Implication: A system hang may occur as a result of this erratum.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD94.  
Uncore Clock Frequency Changes May Cause Audio/Video Glitches  
Problem:  
On some processors, the time required to change the uncore clock frequency may be  
large enough to significantly lengthen the latency of I/O Requests to memory, possibly  
resulting in audio or video glitches.  
Implication: Audio/Video glitches may occur during uncore ratio changes.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD95.  
Processor May Experience a Spurious LLC-Related Machine Check  
During Periods of High Activity  
Problem:  
Due to certain internal conditions while running core and memory intensive operations,  
some processors may incorrectly report an LLC (last level cache) related machine check  
with a IA32_MCi_STATUS.MCACOD value of 110AH.  
Implication: Due to this erratum, the processor may experience a machine check.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD96.  
The Processor May Not Enter Package C7 When Using a PSR Display  
Problem:  
The processor datasheet specifies that entering package C7 requires enabling PSR  
(Panel Self Refresh) for certain display resolutions, along with other conditions. Due to  
this erratum, the processor may not enter package C7 when connected to a PSR-  
enabled display even if all of the required conditions are met.  
Implication: Due to this erratum, the processor may not enter package C7.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
40  
Specification Update  
HSD97.  
Video/Audio Distortion May Occur  
Problem:  
Due to this erratum, internal processor operations can occasionally delay the  
completion of memory read requests enough to cause video or audio streaming  
underrun.  
Implication: Visible artifacts such as flickering on a video device or glitches on audio may occur.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD98.  
System May Hang When Audio is Enabled During Package C3  
Problem:  
When audio is enabled while in package C3 state or deeper, audio memory traffic  
continues to be generated. Due to this erratum, the processor logic required for  
memory traffic may be powered down.  
Implication: When this erratum occurs, the processor logic required for audio memory traffic may  
not be operational resulting in a system hang.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD99.  
INVPCID May Not Cause #UD in VMX Non-Root Operation  
Problem:  
The INVPCID instruction should cause an invalid opcode exception (#UD) in VMX non-  
root operation if either bit 31 of the primary processor-based VM-execution controls  
(activate secondary controls) or bit 12 of the secondary processor-based VM-execution  
controls (enable INVPCID) is 0. Due to this erratum, the INVPCID instruction will not  
cause #UD if “activate secondary controls” is 0 and “enable INVPCID” is 1. Instead, the  
instruction will either execute normally or cause a VM exit if the “INVLPG exiting” VM-  
execution control is 1.  
Implication: The processor may cause a VM exit that software does not expect. Intel has not observed  
this erratum with any commercially available software.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD100.  
Non-Compliant PFAT Module Base Address May Cause Unpredictable  
System Behavior  
Problem:  
PFAT (Platform Firmware Armoring Technology) requires the PFAT module base address  
be 256KB aligned and reside in the first 4GB of memory. If BIOS does not comply with  
these requirements when setting up the PFAT module, the processor should GP# at  
PFAT launch. Due to this erratum, a #GP fault may not be generated.  
Implication: A PFAT module that does not follow the PFAT module base address requirements may  
result in unpredictable system behavior.  
Workaround: It is possible for the BIOS to contain a workaround for this issue.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
41  
HSD101.  
Incorrect LBR Source Address May be Reported For a Transactional  
Abort  
Problem:  
If the fetch of an instruction in a transactional region causes a fault, a transactional abort  
occurs. If LBRs are enabled, the source address recorded for such a transactional abort  
is the address of the instruction being fetched. If that instruction was itself the target of an  
earlier branch instruction, this erratum may erroneously record the address of the branch  
instruction as the source address for the transactional abort  
Implication: Trace reconstruction software that uses LBR information may fail when this erratum  
occurs  
Workaround: None identified  
Status:  
For the steppings affected, see the Summary Table of Changes.  
®
HSD102.  
Address Translation Faults for Intel VT-d May Not be Reported for  
Display Engine Memory Accesses  
®
®
Problem:  
The Intel VT-d (Intel Virtualization Technology for Directed I/O) hardware unit  
supporting the Processor Graphics device (Bus 0; Device 2; Function 0) may not report  
address translation faults detected on Display Engine memory accesses when the  
Context Cache is disabled or during time periods when Context Cache is being  
invalidated.  
Implication: Due to this erratum, Display Engine accesses that fault are correctly aborted but may  
not be reported in the FSTS_REG fault reporting register (GFXVTDBAR offset 034H).  
Workaround: None identified  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD103.  
L3 Cache Corrected Error Count May be Inaccurate After Package C7  
Exit  
Problem:  
The corrected error count for L3 cache errors reported in IA32_MCi_STATUS.Corrected  
Error Count (bits [52:38]) with an MCACOD of 0001 0001 xxxx xxxx (x can be 0 or 1) may  
be incorrectly restored to a smaller value during exit from Package C7.  
Implication: The corrected error count for L3 cache errors in IA32_MCi_STATUS may be inaccurate  
after Package C7 exit.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD104.  
PCIe* Device’s SVID is Not Preserved Across The Package C7 C-State  
Problem:  
Bus 0, Device 7, Function 0’s SVID register (Subsystem Vendor Identification, Offset  
2CH) is not preserved across package C7 C-State transitions.  
Implication: This may cause the operating system to think the device has been replaced with a  
different device.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
42  
Specification Update  
HSD105.  
Warm Reset Does Not Stop GT Power Draw  
Problem:  
Due to this erratum, if GT is enabled prior to a warm reset, it will remain powered after the  
warm reset. The processor will make incorrect power management decisions because it  
assumes the GT is not drawing power after a warm reset.  
Implication: The processor may draw more current than expected from an external VR (Voltage  
Regulator). The processor may also put the external VR into a low power state where it  
will be unable to supply the sufficient power resulting in unpredictable system behavior.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD106.  
Unused PCIe* Lanes May Remain Powered After Package C7  
Problem:  
If a PCIe controller is enabled and either has unused lanes or no PCIe device is present,  
the link and/or unused lanes should enter a low power state. Due to this erratum, after  
exiting Package C7, the unused link and/or unused lanes may remain powered.  
Implication: Power consumption may be greater than expected.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD107.  
BMI1 And BMI2 Instruction Groups Are Not Available  
Problem:  
Feature flags BMI1 and BMI2 (CPUID leaf 7, sub-leaf 0, EBX bits 3 and 8) report these  
two groups of bit manipulation instructions are not present for the Intel Core™ i3-4330TE  
®
but these instruction groups should be available. An attempt to execute any of these  
instructions will generate a #UD fault.  
Implication: Software attempting to use any of instructions in the BMI1 and BMI2 groups will result in a  
#UD fault.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD108.  
Virtual-APIC Page Accesses With 32-Bit PAE Paging May Cause a  
System Crash  
Problem:  
If a logical processor has EPT (Extended Page Tables) enabled, is using 32-bit PAE paging, and  
accesses the virtual-APIC page then a complex sequence of internal processor micro-architectural  
events may cause an incorrect address translation or machine check on either logical processor.  
Implication: This erratum may result in unexpected faults, an uncorrectable TLB error logged in  
IA32_MCi_STATUS.MCACOD (bits [15:0]) with a value of 0000_0000_0001_xxxxb  
(where x stands for 0 or 1), a guest or hypervisor crash, or other unpredictable system  
behavior.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
Specification Update  
43  
HSD109.  
Processor Energy Policy Selection May Not Work as Expected  
Problem:  
When the IA32_ENERGY_PERF_BIAS MSR (1B0H) is set to a value of 4 or more, the  
processor will try to increase the energy efficiency of Turbo mode. However, this  
functionality is effectively disabled if the software requested P-state exceeds the  
maximum P-state supported by the processer. This has the effect of decreasing the  
energy efficiency of the processor while in Turbo mode.  
Implication: When this erratum occurs, reduced battery life and reduced energy efficiency may  
occur.  
Workaround: BIOS should set the max ACPI _PST object to the max supported turbo ratio, ensuring  
that the software P-state request does not exceed the maximum ratio supported by the  
processor. Note that this workaround will disable Core Ratio Overclocking.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD110.  
A PEBS Record May Contain Processor State for an Unexpected  
Instruction  
Problem:  
If a performance counter has overflowed and is configured for PEBS (precise event-  
based sampling), the processor will arm the PEBS hardware within a bounded number  
of cycles called the skid (see the discussion of skid and related topics in the Precise  
®
Distribution of Instructions Retired section of the Intel 64 and IA-32 Architectures  
Software Developer Manual). Once the PEBS hardware is armed, the processor should  
capture processor state in a PEBS record following the execution of the next instruction  
that causes the counter to increment (a “triggering” instruction). Due to this erratum,  
the capture of processor state may occur at an instruction after the first triggering  
instruction following the skid but not beyond the second triggering instruction after the  
skid.  
Implication: A PEBS record may contain processor state (including instruction pointer) not  
associated with the triggering instruction.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD111.  
MSR_PP1_ENERGY_STATUS Reports Incorrect Energy Data  
Problem:  
The MSR_PP1_ENERGY_STATUS MSR (641H) bits [31:0] reports incorrect energy data.  
Implication: Due to this erratum, reported Intel Integrated Graphics domain energy consumption  
may not be accurate.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD112.  
x87 FPU DP May be Incorrect After Instructions That Save FP State to  
Memory  
Problem:  
Under certain conditions, the value of the x87 FPU DP (Floating Point Unit Data Pointer)  
saved by the FSAVE/FNSAVE, FSTENV/FNSTENV, FXSAVE, XSAVE, or XSAVEOPT  
instructions may be incorrect.  
Implication: Due to this erratum, the x87 FPU DP may be incorrect.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
44  
Specification Update  
HSD113.  
Processor May Hang During Package C7 Exit  
Problem:  
Under certain internal timing conditions, the processor might not properly exit package  
C7 leading to a hang.  
Implication: Due to this erratum, the package C7 state may not be reliable. Intel has not observed  
this erratum with any commercially available system.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
®
HSD114.  
Intel TSX Instructions May Cause Unpredictable System behavior  
Problem:  
Under a complex set of internal timing conditions and system events, software using  
the Intel TSX (Transactional Synchronization Extensions) instructions may observe  
unpredictable system behavior.  
Implication: This erratum may result in unpredictable system behavior. Intel has not observed this  
erratum with any commercially available system.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD115.  
Spurious LLC Machine Check May Occur  
Problem:  
Under certain stressful conditions while running at ring ratios higher than 30, the  
processor may experience a spurious LLC machine check as indicated by  
IA32_MCi_STATUS.MCACOD (bits [15:0]) with value 000x 0001 0000 1010 (where x is  
0 or 1).  
Implication: When this erratum occurs, an uncorrectable LLC error will be logged and the system  
may hang or restart.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD116.  
Page Fault May Report Incorrect Fault Information  
Problem:  
Under the following conditions:  
1. A read-modify-write instruction’s memory source/destination (e.g., ADD memory, reg)  
crossing a cache line boundary.  
2. That instruction executing without fault.  
3. While the read-modify-write instruction is executing, one or more of the following page  
table attributes associated with its memory operand are modified:  
a. the D (dirty) flag was 0 when the instruction was initiated but was concurrently set to 1, and/  
or  
b. one of the relevant R/W flags was 0 when the instruction was initiated but was  
concurrently set to 1, and/or  
c. if the read-modify-write instruction executes at CPL = 3 and one of the relevant U/  
S flags was 0 when the instruction was initiated but was concurrently set to 1.  
4. A subsequent instruction executing within a narrow timing window that experiences a  
page fault  
5. There is no serializing instruction between the read-modify-write instruction and the  
faulting instruction.  
Specification Update  
45  
The page fault (in #4) may report an incorrect error code and faulting linear address;  
these would describe the read-modify-write instruction’s memory access instead of that  
of the faulting instruction. (The address of the faulting instruction is reported correctly.)  
Implication: The erratum makes it appear that the page fault resulted from an access that occurred  
prior to the faulting instruction. Because the earlier access completed without faulting,  
a page-fault handler may identify the page fault as transient (or spurious) and re-  
execute the faulting instruction (e.g., by executing IRET). In such cases, the erratum  
will not recur; the page fault on the later access will recur and will be reported  
correctly. If the page-fault handler does not re-execute the faulting instruction, this  
erratum may result in unpredictable system behavior. Intel has not observed this  
erratum with any commercially available software.  
Workaround: None identified.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD117.  
CATERR# Pin Assertion is Not Cleared on a Warm Reset  
Problem:  
If the CATERR# pin is held asserted to indicate a fatal error, a subsequent warm reset  
event will not cause the CATERR# pin to de-assert.  
Implication: When this erratum occurs, platforms that monitor the CATERR# pin may be unable to  
detect a fatal error after a warm reset or may incorrectly respond to a CATERR# pin  
assertion although an error may not have occurred subsequent to the warm reset  
event.  
Workaround: The CATERR# pin can be de-asserted by a cold reset event.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
HSD118.  
Uncorrectable Machine Check Error During Core C6 Entry May Not be  
Signaled  
Problem:  
Machine Check exceptions occurring during core C6 entry may be ignored.  
Implication: When this erratum occurs, incorrect state may be saved during core C6 entry and  
subsequently restored during core C6 exit resulting in unpredictable system behavior.  
Workaround: It is possible for the BIOS to contain a workaround for this erratum.  
Status:  
For the steppings affected, see the Summary Table of Changes.  
§ §  
46  
Specification Update  
Specification Changes  
The Specification Changes listed in this section apply to the following documents:  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 1: Basic  
Architecture  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2A:  
Instruction Set Reference Manual A-M  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2B:  
Instruction Set Reference Manual N-Z  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3A:  
System Programming Guide  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3B:  
System Programming Guide  
There are no new Specification Changes in this Specification Update revision.  
§ §  
Specification Update  
47  
 
Specification Clarifications  
The Specification Clarifications listed in this section may apply to the following  
documents:  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 1: Basic  
Architecture  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2A:  
Instruction Set Reference Manual A-M  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2B:  
Instruction Set Reference Manual N-Z  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3A:  
System Programming Guide  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3B:  
System Programming Guide  
There are no new Specification Changes in this Specification Update revision.  
§ §  
48  
Specification Update  
 
Documentation Changes  
The Documentation Changes listed in this section apply to the following documents:  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 1: Basic  
Architecture  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2A:  
Instruction Set Reference Manual A-M  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 2B:  
Instruction Set Reference Manual N-Z  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3A:  
System Programming Guide  
®
• Intel 64 and IA-32 Architectures Software Developer’s Manual, Volume 3B:  
System Programming Guide  
All Documentation Changes will be incorporated into a future version of the appropriate  
Processor documentation.  
®
Note:  
Documentation changes for Intel 64 and IA-32 Architecture Software Developer's  
®
Manual volumes 1, 2A, 2B, 3A, and 3B will be posted in a separate document, Intel 64  
and IA-32 Architecture Software Developer's Manual Documentation Changes. Use the  
processor/manuals/index.htm  
There are no new Documentation Changes in this Specification Update revision.  
HSD1.  
On-Demand Clock Modulation Feature Clarification  
®
Software Controlled Clock Modulation section of the Intel 64 and IA-32 Architectures  
Software Developer's Manual, Volume 3B: System Programming Guide will be modified  
to differentiate On-demand clock modulation feature on different processors. The  
clarification will state:  
For Hyper-Threading Technology enabled processors, the IA32_CLOCK_MODULATION  
register is duplicated for each logical processor. In order for the On-demand clock  
modulation feature to work properly, the feature must be enabled on all the logical  
processors within a physical processor. If the programmed duty cycle is not identical for  
all the logical processors, the processor clock will modulate to the highest duty cycle  
programmed for processors if the CPUID DisplayFamily_DisplayModel signatures is  
listed in Table 14-2. For all other processors, if the programmed duty cycle is not  
identical for all logical processors in the same core, the processor will modulate at the  
lowest programmed duty cycle.  
For multiple processor cores in a physical package, each core can modulate to a  
programmed duty cycle independently.  
For the P6 family processors, on-demand clock modulation was implemented through  
the chipset, which controlled clock modulation through the processor’s STPCLK# pin.  
Table 14-2. CPUID Signatures for Legacy Processors That Resolve to Higher  
Performance Setting of Conflicting Duty Cycle Requests  
Specification Update  
49  
 
Display Family Display  
Model  
Display Family Display  
Model  
Display Family Display  
Model  
Display Family Display  
Model  
0F_xx  
06_1F  
06_2C  
06_36  
06_1C  
06_25  
06_2E  
06_1A  
06_26  
06_2F  
06_1E  
06_27  
06_35  
§ §  
50  
Specification Update  

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