RH80532NC021256/SL6FN
更新时间:2024-09-18 18:15:32
品牌:INTEL
描述:RISC Microprocessor, 64-Bit, 1500MHz, CMOS, CPGA478
RH80532NC021256/SL6FN 概述
RISC Microprocessor, 64-Bit, 1500MHz, CMOS, CPGA478 微处理器
RH80532NC021256/SL6FN 规格参数
是否Rohs认证: | 符合 | 生命周期: | Obsolete |
包装说明: | SPGA, PGA478,26X26,50 | Reach Compliance Code: | unknown |
风险等级: | 5.84 | 位大小: | 64 |
JESD-30 代码: | S-XPGA-P478 | 端子数量: | 478 |
封装主体材料: | CERAMIC | 封装代码: | SPGA |
封装等效代码: | PGA478,26X26,50 | 封装形状: | SQUARE |
封装形式: | GRID ARRAY, SHRINK PITCH | 电源: | 1.3 V |
认证状态: | Not Qualified | 速度: | 1500 MHz |
子类别: | Microprocessors | 最大压摆率: | 27500 mA |
标称供电电压: | 1.3 V | 表面贴装: | NO |
技术: | CMOS | 端子形式: | PIN/PEG |
端子节距: | 1.27 mm | 端子位置: | PERPENDICULAR |
uPs/uCs/外围集成电路类型: | MICROPROCESSOR, RISC | Base Number Matches: | 1 |
RH80532NC021256/SL6FN 数据手册
通过下载RH80532NC021256/SL6FN数据手册来全面了解它。这个PDF文档包含了所有必要的细节,如产品概述、功能特性、引脚定义、引脚排列图等信息。
PDF下载R
Mobile Intel® Celeron® Processor
on .13 Micron Process in Micro-
FCPGA Package
Specification Update
September 2004
Notice: The Mobile Intel® Celeron® Processor may contain design defects or errors
known as errata which may cause the product to deviate from published specifications.
Current characterized errata are documented in this Specification Update.
Document Number: 251309-022
R
INFORMATION IN THIS DOCUMENT IS PROVIDED IN CONNECTION WITH INTEL® PRODUCTS. NO LICENSE, EXPRESS OR IMPLIED, BY
ESTOPPEL OR OTHERWISE, TO ANY INTELLECTUAL PROPERTY RIGHTS IS GRANTED BY THIS DOCUMENT. EXCEPT AS PROVIDED IN INTEL’S
TERMS AND CONDITIONS OF SALE FOR SUCH PRODUCTS, INTEL ASSUMES NO LIABILITY WHATSOEVER, AND INTEL DISCLAIMS ANY
EXPRESS OR IMPLIED WARRANTY, RELATING TO SALE AND/OR USE OF INTEL PRODUCTS INCLUDING LIABILITY OR WARRANTIES RELATING
TO FITNESS FOR A PARTICULAR PURPOSE, MERCHANTABILITY, OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL
PROPERTY RIGHT. Intel products are not intended for use in medical, life saving, or life sustaining applications.
Intel may make changes to specifications and product descriptions at any time, without notice.
Designers must not rely on the absence or characteristics of any features or instructions marked "reserved" or "undefined." Intel reserves these for future
definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them.
The Mobile Intel® Celeron® Processor may contain design defects or errors known as errata which may cause the product to deviate from published
specifications. Current characterized errata are available on request.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
Intel, Pentium, Celeron, Xeon, Intel SpeedStep technology and the Intel logo are trademarks or registered trademarks of Intel Corporation or its subsidiaries
in the United States and other countries.
*Other names and brands may be claimed as the property of others.
Copyright © 2003, Intel Corporation
2
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Contents
Revision History............................................................................................................................4
Preface .........................................................................................................................................5
Errata..........................................................................................................................................13
Specification Clarifications .........................................................................................................31
Specification Changes................................................................................................................33
Documentation Changes............................................................................................................37
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
3
R
Revision History
Revision
Number
Description
Date
June 2002
-001
-002
-003
Initial Release
Updated Identification Information table.
August 2002
Updated Documentation Change summary by removing old items that
have been incorporated into the Software Developer’s Manual; Added
errata V30-V32; Added Documentation Changes V3-V24.
September 2002
-004
-005
-006
Updated Summary of Changes; Added prefix letter W; Removed
previous errata V32 as not applicable, added new errata V32; Added
Documentation Changes V25-V32.
October 2002
Added errata V33; Added Spec Clarification V1; Added Spec Change V1;
Removed Documentation Changes that have been incorporated into the
Software Developer’s Manual; Added a note in Documentation Changes.
November 2002
December 2002
No new Errata, Documentation Change, Spec Clarification, or Spec
Change. Updated note concerning the Software Developer’s Manual.
-007
-008
-009
-010
Added Erratum V34. Updated summary tables to include C1 step.
Added Erratum V35.
January 2003
February 2003
March 2003
April 2003
Updated Erratum V34, added new Erratum V36
Updated codes used in summary tables. Updated errata summary table
entry for V27, V28, V34, & V36. Updated tables for D1-step
-011
-012
Added info for C-1 step 1.6 GHz to 2.2 GHz to Table 1.
May 2003
June 2003
Updated Erratum V33. Added identification info for D-1 step 2.4 GHz.
Updated summary table code Z.
-013
-014
-015
-016
-017
-018
-019
-020
-021
-022
Added Erratum V37.
July 2003
Added V2 Specification Change. Added Errata V38.
Added Errata V39 and V40.
Added Errata V41.
August 2003
September 2003
October 2003
November 2003
March 2004
April 2004
Updated Errata V41.
Updated Errata V42.
Updated Errata V6.
Updated Errata V11. Added Errata V43.
Added Errata V44. Updated Processor Identification Information
Added Errata V45.
May 2004
June 2004
September 2004
4
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Preface
This document is an update to the specifications contained in the following documents:
• Mobile Intel® Celeron® Processor on .13 Micron Process in Micro-FCPGA Package Datasheet,
Reference Number 251308.
Note: Documentation changes for IA-32 Intel® Architecture Software Developer’s Manual volumes 1, 2, and 3
are posted in a separate document IA-32 Intel® Architecture Software Developer’s Manual
Documentation Changes. This document has been posted to http://developer.intel.com/
It is intended for hardware system manufacturers and software developers of applications, operating
systems, or tools and contains Errata, Documentation Changes, Specification Clarifications, and
Specification Changes.
Nomenclature
S-Spec Number is a five-digit code used to identify products. Products are differentiated by their
unique characteristics, e.g., core speed, L2 cache size, package type, etc. as described in the processor
identification information table. Care should be taken to read all notes associated with each S-Spec
number.
Errata are design defects or errors. Errata may cause the mobile Intel Pentium 4 processor-m’s behavior
to deviate from published specifications. Hardware and software designed to be used with any given
processor must assume that all errata documented for that processor are present on all devices unless
otherwise noted.
Documentation Changes include typos, errors, or omissions from the current published specifications.
These changes will be incorporated in the next release of the specifications.
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 the next
release of the specifications.
Specification Changes are modifications to the current published specifications for the Intel Pentium 4
processor. These changes will be incorporated in the next release of the specifications.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
5
R
General Information
Figure 1. Mobile Intel® Celeron® Processor on .13 Micron Process (Micro-FCPGA) Markings
S-Spec #
FPO#
FFFFFFFF S/N
PRODUCT DETAIL
S-SPEC COO
INTEL
m c ‘01
LEGAL REQUIREMENTS
2D Matrix
(supplier Lot ID + SER#)
6
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Identification Information
The Mobile Intel® Celeron® Processor on .13 micron process in Micro-FCPGA package can be
identified by the following values:
Family1
Model2
Brand ID3
1111
1111
0010
0010
000010004
000011115
NOTE:
1.
2.
3.
The Family 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.
The Model 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 Brand ID corresponds to bits [7:0] of the EBX register after the CPUID instruction is executed with a
1 in the EAX register.
4.
5.
This brand id MUST be used in conjunction with CPUID = 0F24h.
This brand id MUST be used in conjunction with CPUID = 0F27h.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
7
R
Identification Information
L2
Product
Cache
Size
CPU
Bus
S-Spec
Core Frequency
Voltage
Package
Notes
Stepping
Signature
Frequency
(bytes)
SL6FM B0
256 K
256 K
256 K
256 K
256 K
256 K
256 K
256 K
256 K
256K
0F24h
0F24h
0F27h
0F27h
0F27h
0F27h
0F27h
0F27h
0F27h
0F29h
0F29h
0F29h
0F29h
0F29h
0F29h
1.4 GHz
1.5 GHz
1.4 GHz
1.5 GHz
1.6 GHz
1.7 GHz
1.8 GHz
2.0 GHz
2.2 GHz
1.2 GHz
1.70 GHz
1.80 GHz
2.00 GHz
2.20 GHz
2.40 GHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
400 MHz
1.3 V
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
Micro-FCPGA
1
SL6FN
SL6M4
SL6M5
SL6J2
SL6J3
SL6J4
B0
C1
C1
C1
C1
C1
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1.3 V
1
SL6QH C1
SL6ZW C1
SL7MG D1
SL6VG D1
2
256 K
256 K
256 K
256 K
256 K
SL6VH
SL6VJ
SL73Y
SL75J
D1
D1
D1
D1
NOTE:
1. Based on B0-Shrink process.
2. Supported by the Embedded Intel Architecture Division
8
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Summary of Changes
The following table indicates the Errata, Documentation Changes, Specification Clarifications, or
Specification Changes that apply to Intel Pentium 4 processors. Intel intends to fix some of the errata in
a future stepping of the component, and to account for the other outstanding issues through
documentation or specification changes as noted. This table uses the following notations:
Codes Used in Summary Table
Stepping
X:
Erratum, 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.
Status
Doc:
Document change or update that will be implemented.
This erratum may be fixed in a future of the product.
This erratum has been previously fixed.
PlanFix:
Fixed:
NoFix:
PKG:
There are no plans to fix this erratum.
®
®
This column refers to errata on the Intel Pentium 4 processor substrate.
AP:
APIC related erratum.
Shaded:
This item is either new or modified from the previous version of the
document.
Each Specification Update item is prefixed with a capital letter to distinguish the product. The key
below details the letters that are used in Intel’s microprocessor Specification Updates:
A = Intel® Pentium® II processor
B = Mobile Intel® Pentium® II processor
C = Intel®Celeron® processor
D = Intel® Pentium® II Xeon™ processor
E = Intel® Pentium® III processor
G = Intel® Pentium® III Xeon™ processor
H = Mobile Intel® Celeron® processor at 466/433/400/366/333/300 and 266 MHz
K = Mobile Intel® Pentium® III processor
M = Mobile Intel® Celeron® processor
N = Intel® Pentium® 4 processor
P = Intel® Xeon™ processor
T = Mobile Intel® Pentium® 4 Processor-M
V = Mobile Intel® Celeron® processor on .13 Micron Process in Micro-FCPGA Package
Y = Intel®Pentium® M processor
®
®
Z = Mobile Intel Pentium 4 processor with 533 MHz system bus
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
9
R
The Specification Updates for the Pentium® processor, Pentium® Pro processor, and other Intel products
do not use this convention
Steppings
C1
Plans
ERRATA
NO.
B0
D1
I/O restart in SMM may fail after simultaneous machine check
exception (MCE)
V1
X
X
X
X
NoFix
MCA registers may contain invalid information if RESET# occurs and
PWRGOOD is not held asserted
V2
X
X
NoFix
V3
V4
X
X
X
X
X
X
NoFix
NoFix
Transaction is not retried after BINIT#
Invalid opcode 0FFFh requires a ModRM byte
FSW may not be completely restored after page fault on FRSTOR or
FLDENV instructions
V5
X
X
X
NoFix
The Processor Signals Page-Fault Exception (#PF) Instead of
Alignment Check Exception (#AC) on an Unlocked CMPXCHG8B
Instruction
V6
X
X
X
NoFix
When in no-fill mode the memory type of large pages are incorrectly
forced to uncacheable
V7
V8
X
X
X
X
X
X
NoFix
NoFix
Processor may hang due to speculative page walks to non-existent
system memory
The IA32_MC1_STATUS register may contain incorrect information for
correctable errors
V9
X
X
X
X
X
X
X
X
X
NoFix
NoFix
NoFix
V10
V11
Debug mechanisms may not function as expected
Machine check architecture error reporting and recovery may not work
as expected
Cascading of performance counters does not work correctly when
forced overflow is enabled
V12
X
X
X
NoFix
V13
V14
X
X
X
X
X
X
NoFix
NoFix
EMON event counting of x87 loads may not work as expected
Speculative page fault may cause livelock
Incorrect data may be returned when page tables are in Write
Combining (WC) memory space
V15
V16
X
X
X
Fixed
NoFix
X
X
Processor issues inconsistent transaction size attributes for locked
operation
Multiple accesses to the same S-state L2 cache line and ECC error
combination may result in loss of cache coherency
V17
V18
V19
Fixed
Fixed
NoFix
Processor may hang when resuming from Deep Sleep state
When the processor is in the System Management Mode (SMM),
debug registers may be fully writeable
X
X
X
Associated counting logic must be configured when using Event
Selection Control (ESCR) MSR
V20
V21
V22
X
X
X
X
X
X
NoFix
NoFix
Fixed
IA32_MC0_ADDR and IA32_MC0_MISC Registers Will Contain
Invalid or Stale Data Following a Data, Address, or Response Parity
Error
CR2 May Be Incorrect or an Incorrect Page Fault Error Code May Be
Pushed Onto Stack After Execution of an LSS Instruction
X
10
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Steppings
C1
Plans
ERRATA
NO.
B0
D1
BPM[5:3]# and GHI# VIL Do Not Meet Specification
V23
V24
X
Fixed
X
X
X
Processor May Hang Under Certain Frequencies and 12.5% STPCLK#
Duty Cycle
X
NoFix
System May Hang if a Fatal Cache Error Causes Bus Write Line
(BWL) Transaction to Occur to the Same Cache Line Address as an
Outstanding Bus Read Line (BRL) or Bus Read-Invalidate Line (BRIL)
V25
X
X
NoFix
L2 Cache May Contain Stale Data in the Exclusive State
V26
V27
X
X
Fixed
Fixed
X
X
Re-mapping the APIC Base Address to a Value Less Than or Equal to
0xDC001000 may Cause IO and Special Cycle Failure
Erroneous BIST Result Found in EAX Register After Reset
V28
V29
X
X
Fixed
Fixed
Processor Does not Flag #GP on Non-zero Write to Certain MSRs
Simultaneous Assertion of A20M# and INIT# may Result in Incorrect
Data Fetch
V30
X
X
X
X
X
NoFix
V31
V32
X
X
PlanFix
Fixed
Processor Does not Respond to Break Requests From ITP
Processor Signature Returns Incorrect Number of ITLB Entries
A Write to APIC Registers Sometimes May Appear to Have Not
Occurred
V33
X
X
X
X
NoFix
V34
V35
X
X
Fixed
NoFix
Store to Load Data Forwarding may Result in Switched Data Bytes
Parity Error in the L1 Cache may Cause the Processor to Hang
X
X
The TCK Input in the Test Access Port (TAP) is Sensitive to Low
Clock Edge Rates and Prone to Noise Coupling Onto TCK’s Rising or
Falling Edges
V36
X
Fixed
The State of the Resume Flag (RF Flag) in a Task-State Segment
(TSS) May be Incorrect
V37
V38
V39
V40
X
X
X
X
X
X
NoFix
NoFix
NoFix
NoFix
Changes to CR3 Register do not Fence Pending Instruction Page
Walks
X
X
X
X
X
X
System Bus Interrupt Messages without Data that Receive a
HardFailure Response May Hang the Processor
Memory Type of the Load Lock Different from its Corresponding Store
Unlock
A 16-bit Address Wrap Resulting from a Near Branch (Jump or Call)
May Cause an Incorrect Address to Be Reported to the #GP Exception
Handler
V41
X
X
X
NoFix
Incorrect Debug Exception (#DB) May Occur When a Data Breakpoint
is set on an FP Instruction
V42
V43
V44
X
X
X
X
X
X
X
X
X
NoFix
NoFix
NoFix
xAPIC May Not Report Some Illegal Vector Errors
Memory Aliasing of Pages as Uncacheable Memory Type and Write
Back (WB) May Hang the System
A Timing Maginality in the Arithmetic Logic Unit (ALU) May Cause
Indeterminate Behavior
V45
X
Plan Fix
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
11
R
NUMBER
SPECIFICATION CHANGE
V1
V2
Context ID feature added to CPUID Feature/IA32_MISC_Enable Registers
BR0# Maximum Hold Time Specification Change
NUMBER
SPECIFICATION CLARIFICATIONS
V1
Clarifying DBI# Definition for all Processors With Intel® NetBurst™ Micro-architecture
NUMBER
DOCUMENTATION CHANGES
There are no Documentation Changes in this Specification Update revision.
12
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Errata
V1.
I/O Restart in SMM may Fail After Simultaneous Machine Check Exception
(MCE)
Problem:
If an I/O instruction (IN, INS, REP INS, OUT, OUTS, or REP OUTS) is being executed, and if the
data for this instruction becomes corrupted, the processor will signal a Machine Check Exception
(MCE). If the instruction is directed at a device that is powered down, the processor may also receive
an assertion of SMI#. Since MCEs have higher priority, the processor will call the MCE handler, and
the SMI# assertion will remain pending. However, upon attempting to execute the first instruction of
the MCE handler, the SMI# will be recognized and the processor will attempt to execute the SMM
handler. If the SMM handler is completed successfully, it will attempt to restart the I/O instruction, but
will not have the correct machine state, due to the call to the MCE handler.
Implication: A simultaneous MCE and SMI# assertion may occur for one of the I/O instructions above. The SMM
handler may attempt to restart such an I/O instruction, but will have an incorrect state due to the MCE
handler call, leading to failure of the restart and shutdown of the processor.
Workaround: If a system implementation must support both SMM and board I/O restart, the first thing the SMM
handler code should do is check for a pending MCE. If there is an MCE pending, the SMM handler
should immediately exit via an RSM instruction and allow the MCE handler to execute. If there is no
MCE pending, the SMM handler may proceed with its normal operation.
Status:
For the steppings affected, see the Summary Table of Changes.
V2.
MCA Registers may Contain Invalid Information if RESET# Occurs and
PWRGOOD is not Held Asserted
Problem:
This erratum can occur as a result either of the following events:
•
PWRGOOD is de-asserted during a RESET# assertion causing internal glitches that may result in
the possibility that the MCA registers latch invalid information.
•
Or during a reset sequence if the processor’s power remains valid regardless of the state of
PWRGOOD, and RESET# is re-asserted before the processor has cleared the MCA registers, the
processor will begin the reset process again but may not clear these registers.
Implication: When this erratum occurs, the information in the MCA registers may not be reliable.
Workaround: Ensure that PWRGOOD remains asserted throughout any RESET# assertion and that RESET# is not re-
asserted while PWRGOOD is de-asserted.
Status:
For the steppings affected, see the Summary Table of Changes.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
13
R
V3.
Transaction is not Retried After BINIT#
Problem:
If the first transaction of a locked sequence receives a HITM# and DEFER# during the snoop phase it
should be retried and the locked sequence restarted. However, if BINIT# is also asserted during this
transaction, it will not be retried.
Implication: When this erratum occurs, locked transactions will unexpectedly not be retried.
Workaround: None identified
Status:
For the steppings affected, see the Summary Table of Changes.
V4.
Invalid Opcode 0FFFh Requires a ModRM Byte
Problem:
Some invalid opcodes require a ModRM byte (or other following bytes), while others do not. The
invalid opcode 0FFFh did not require a ModRM byte in previous generation Intel architecture
processors, but does in the Intel® Pentium® 4 processor.
Implication: The use of an invalid opcode 0FFFh without the ModRM byte may result in a page or limit fault on the
Intel® Pentium® 4 processor.
Workaround: Use a ModRM byte with invalid 0FFFh opcode.
Status:
For the steppings affected, see the Summary Table of Changes.
V5.
FSW may not be Completely Restored After Page Fault on FRSTOR or FLDENV
Instructions
Problem:
If the FPU operating environment or FPU state (operating environment and register stack) being
loaded by an FLDENV or FRSTOR instruction wraps around a 64Kbyte or 4Gbyte boundary and a
page fault (#PF) or segment limit fault (#GP or #SS) occurs on the instruction near the wrap boundary,
the upper byte of the FPU status word (FSW) might not be restored. If the fault handler does not
restart program execution at the faulting instruction, stale data may exist in the FSW.
Implication: When this erratum occurs, stale data will exist in the FSW.
Workaround: Ensure that the FPU operating environment and FPU state do not cross 64Kbyte or 4Gbyte boundaries.
Alternately, ensure that the page fault handler restarts program execution at the faulting instruction after
correcting the paging problem.
Status:
For the steppings affected, see the Summary Table of Changes.
14
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V6.
The Processor Signals Page-Fault Exception (#PF) Instead of Alignment Check
Exception (#AC) on an Unlocked CMPXCHG8B Instruction
Problem:
If a Page-Fault Exception (#PF) and Alignment Check Exception (#AC) both occur for an unlocked
CMPXCHG8B instruction, then #PF will be flagged.
Implication: Software that depends on the Alignment Check Exception (#AC) before the Page-Fault Exception (#PF)
will be affected since #PF is signaled in this case.
Workaround: Remove the software’s dependency on #AC having precedence over #PF. Alternately, correct the page
fault in the page fault handler and then restart the faulting instruction.
Status:
For the steppings affected, see the Summary Table of Changes
V7.
When in No-Fill Mode the Memory Type of Large Pages are Incorrectly Forced to
Uncacheable
Problem:
When the processor is operating in No-Fill Mode (CR0.CD=1), the paging hardware incorrectly forces
the memory type of large (PSE-4M and PAE-2M) pages to uncacheable (UC) memory type regardless
of the MTRR settings. By forcing the memory type of these pages to UC, load operations, which
should hit valid data in the L1 cache, are forced to load the data from system memory. Some
applications will lose the performance advantage associated with the caching permitted by other
memory types.
Implication: This erratum may result in some performance degradation when using no-fill mode with large pages.
Workaround: None identified
Status:
For the steppings affected, see the Summary Table of Changes.
V8.
Processor may Hang due to Speculative Page Walks to Non-Existent System
Memory
Problem:
A load operation that misses the Data Translation Lookaside Buffer (DTLB) will result in a page-walk.
If the page-walk loads the Page Directory Entry (PDE) from cacheable memory and that PDE load
returns data that points to a valid Page Table Entry (PTE) in uncacheable memory the processor will
access the address referenced by the PTE. If the address referenced does not exist the processor will
hang with no response from system memory.
Implication: Processor may hang due to speculative page walks to non-existent system memory.
Workaround: Page directories and page tables in UC memory space that are marked valid must point to physical
addresses that will return a data response to the processor.
Status:
For the steppings affected, see the Summary Table of Changes.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
15
R
V9.
The IA32_MC1_STATUS Register may Contain Incorrect Information for
Correctable Errors
Problem:
When a speculative load operation hits the L2 cache and receives a correctable error, the
IA32_MC1_STATUS register may be updated with incorrect information. The IA32_MC1_STATUS
register should not be updated for speculative loads.
Implication: When this erratum occurs, the IA32_MC1_STATUS register will contain incorrect information for
correctable errors.
Workaround: None identified
Status:
For the steppings affected, see the Summary Table of Changes.
V10.
Debug Mechanisms may not Function as Expected
Problem:
Certain debug mechanisms may not function as expected on the processor. The cases are as follows:
•
When the following conditions occur: 1) An FLD instruction signals a stack overflow or
underflow, 2) the FLD instruction splits a page-boundary or a 64 byte cache line boundary, 3) the
instruction matches a Debug Register on the high page or cache line respectively, and 4) the FLD
has a stack fault and a memory fault on a split access, the processor will only signal the stack fault
and the debug exception will not be taken.
•
•
When a data breakpoint is set on the ninth and/or tenth byte(s) of a floating point store using the
Extended Real data type, and an unmasked floating point exception occurs on the store, the break
point will not be captured.
When any instruction has multiple debug register matches, and any one of those debug registers is
enabled in DR7, all of the matches should be reported in DR6 when the processor goes to the
debug handler. This is not true during a REP instruction. As an example, during execution of a
REP MOVSW instruction the first iteration a load matches DR0 and DR2 and sets DR6 as
FFFF0FF5h. On a subsequent iteration of the instruction, a load matches only DR0. The DR6
register is expected to still contain FFFF0FF5h, but the processor will update DR6 to FFFF0FF1h.
•
A Data breakpoint that is set on a load to uncacheable memory may be ignored due to an internal
segment register access conflict. In this case the system will continue to execute instructions,
bypassing the intended breakpoint. Avoiding having instructions that access segment descriptor
registers, e.g., LGDT, LIDT close to the UC load, and avoiding serialized instructions before the
UC load will reduce the occurrence of this erratum.
Implication: Certain debug mechanisms do not function as expected on the processor.
Workaround: None identified
Status:
For the steppings affected, see the Summary Table of Changes.
16
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V11.
Machine Check Architecture Error Reporting and Recovery may not Work as
Expected
Problem:
When the processor detects errors it should attempt to report and/or recover from the error. In the
situations described below, the processor does not report and/or recover from the error(s) as intended.
• When a transaction is deferred during the snoop phase and subsequently receives a Hard Failure
response, the transaction should be removed from the bus queue so that the processor may proceed.
Instead, the transaction is not properly removed from the bus queue, the bus queue is blocked, and
the processor will hang.
• When a hardware prefetch results in an uncorrectable tag error in the L2 cache,
MC0_STATUS.UNCOR and MC0_STATUS.PCC are set but no Machine Check Exception
(MCE) is signaled. No data loss or corruption occurs because the data being prefetched has not
been used. If the data location with the uncorrectable tag error is subsequently accessed, an MCE
will occur. However, upon this MCE, or any other subsequent MCE, .the information for that error
will not be logged because MC0_STATUS.UNCOR has already been set and the MCA status
registers will not contain information about the error which caused the MCE assertion but instead
will contain information about the prefetch error event.
• When the reporting of errors is disabled for Machine Check Architecture (MCA) Bank 2 by setting
all MC2_CTL register bits to 0, uncorrectable errors should be logged in the IA32_MC2_STATUS
register but no machine-check exception should be generated. Uncorrectable loads on bank 2,
which would normally be logged in the IA32_MC2_STATUS register, are not logged.
• When one half of a 64 byte instruction fetch from the L2 cache has an uncorrectable error and the
other 32 byte half of the same fetch from the L2 cache has a correctable error, the processor will
attempt to correct the correctable error but cannot proceed due to the uncorrectable error. When this
occurs the processor will hang.
• When an L1 cache parity error occurs, the cache controller logic should write the physical address
of the data memory location that produced that error into the IA32_MC1_ADDR REGISTER
(MC1_ADDR). In some instances of a parity error on a load operation that hits the L1 cache, the
cache controller logic may write the physical address from a subsequent load or store operation into
the IA32_MC1_ADDR register.
• When an error exists in the tag field of a cache line such that a request for ownership (RFO) issued
by the processor hits multiple tag fields in the L2 cache (the correct tag and the tag with the error)
and the accessed data also has a correctable error, the processor will correctly log the multiple tag
match error but will hang when attempting to execute the machine check exception handler.
• If a memory access receives a machine check error on both 64 byte halves of a 128-byte L2 cache
sector, the IA32_MC0_STATUS register records this event as multiple errors, i.e., the valid error
bit and the overflow error bit are both set indicating that a machine check error occurred while the
results of a previous error were in the error-reporting bank. The IA32_MC1_STATUS register
should also record this event as multiple errors but instead records this event as only one
correctable error.
• The overflow bit should be set to indicate when more than one error has occurred. The overflow
bit being set indicates that more than one error has occurred. Because of this erratum, if any further
errors occur, the MCA overflow bit will not be updated, thereby incorrectly indicating only one
error has been received.
• If an I/O instruction (IN, INS, REP INS, OUT, OUTS, or REP OUTS) is being executed, and if the
data for this instruction becomes corrupted, the processor will signal a Machine Check Exception
(MCE). If the instruction is directed at a device that is powered down, the processor may also
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
17
R
receive an assertion of SMI#. Since MCEs have higher priority, the processor will call the MCE
handler, and the SMI# assertion will remain pending. However, while attempting to execute the
first instruction of the MCE handler, the SMI# will be recognized and the processor will attempt to
execute the SMM handler. If the SMM handler is successfully completed, it will attempt to restart
the I/O instruction, but will not have the correct machine state due to the call to the MCE handler.
This can lead to failure of the restart and shutdown of the processor.
• If PWRGOOD is de-asserted during a RESET# assertion causing internal glitches, the MCA
registers may latch invalid information.
• If RESET# is asserted, then de-asserted, and reasserted, before the processor has cleared the MCA
registers, then the information in the MCA registers may not be reliable, regardless of the state or
state transitions of PWRGOOD.
• If MCERR# is asserted by one processor and observed by another processor, the observing
processor does not log the assertion of MCERR#. The Machine Check Exception (MCE) handler
called upon assertion of MCERR# will not have any way to determine the cause of the MCE.
• The Overflow Error bit (bit 62) in the IA32_MC0_STATUS register indicates, when set, that a
machine check error occurred while the results of a previous error were still in the error reporting
bank (i.e. The Valid bit was set when the new error occurred). If an uncorrectable error is logged in
the error-reporting bank and another error occurs, the overflow bit will not be set.
• The MCA Error Code field of the IA32_MC0_STATUS register gets written by a different
mechanism than the rest of the register. For uncorrectable errors, the other fields in the
IA32_MC0_STATUS register are only updated by the first error. Any further errors that are
detected will update the MCA Error Code field without updating the rest of the register, thereby
leaving the IA32_MC0_STATUS register with stale information.
• When a speculative load operation hits the L2 cache and receives a correctable error, the
IA32_MC1_Status Register may be updated with incorrect information. The IA32_MC1_Status
Register should not be updated for speculative loads.
• The processor should only log the address for L1 parity errors in the IA32_MC1_Status register if a
valid address is available. If a valid address is not available, the Address Valid bit in the
IA32_MC1_Status register should not be set. In instances where an L1 parity error occurs and the
address is not available because the linear to physical address translation is not complete or an
internal resource conflict has occurred, the Address Valid bit is incorrectly set.
• The processor may hang when an instruction code fetch receives a hard failure response from the
system bus. This occurs because the bus control logic does not return data to the core, leaving the
processor empty. IA32_MC0_STATUS MSR does indicate that a hard fail response occurred.
• The processor may hang when the following events occur and the machine check exception is
enabled, CR4.MCE=1. A processor that has it's STPCLK# pin asserted will internally enter the
Stop Grant State and finally issue a Stop Grant Acknowledge special cycle to the bus. If an
uncorrectable error is generated during the Stop Grant process it is possible for the Stop Grant
special cycle to be issued to the bus before the processor vectors to the machine check handler.
Once the chipset receives its last Stop Grant special cycle it is allowed to ignore any bus activity
from the processors. As a result, processor accesses to the machine check handler may not be
acknowledged, resulting in a processor hang.
Implication: The processor is unable to correctly report and/or recover from certain errors
Workaround: None identified.
Status:
For the steppings affected, see the Summary Table of Changes
18
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V12.
Cascading of Performance Counters does not Work Correctly When Forced
Overflow is Enabled
Problem:
The performance counters are organized into pairs. When the CASCADE bit of the Counter
Configuration Control Register (CCCR) is set, a counter that overflows will continue to count in the
other counter of the pair. The FORCE_OVF bit forces the counters to overflow on every non-zero
increment. When the FORCE_OVF bit is set, the counter overflow bit will be set but the counter no
longer cascades.
Implication: The performance counters do not cascade when the FORCE_OVF bit is set.
Workaround: None identified
Status:
For the steppings affected, see the Summary Table of Changes.
V13.
EMON Event Counting of x87 Loads may not Work as Expected
Problem:
If a performance counter is set to count x87 loads and floating point exceptions are unmasked, the
FPU Operand Data Pointer (FDP) may become corrupted.
Implication: When this erratum occurs, the FPU Operand Data Pointer (FDP) may become corrupted.
Workaround: This erratum will not occur with floating point exceptions masked. If floating point exceptions are
unmasked, then performance counting of x87 loads should be disabled.
Status:
For the steppings affected, see the Summary Table of Changes.
V14.
Speculative Page Fault may Cause Livelock
Problem:
If the processor detects a page fault which is corrected before the operating system page fault handler
can be called e.g. DMA activity modifies the page tables and the corrected page tables are left in a
non-accessed or not dirty state, the processor may livelock. Intel has not been able to reproduce this
erratum with commercial software.
Implication: Should this erratum be encountered the processor will livelock resulting in a system hang or operating
system failure.
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.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
19
R
V15.
Incorrect Data May be Returned When Page Tables Are In Write Combining
Memory (WC) Space
Problem:
If page directories and/or page tables are located in Write Combining (WC) memory, speculative loads
to cacheable memory may complete with incorrect data.
Implication: Cacheable loads to memory mapped using page tables located in write combining memory may return
incorrect data. Intel has not been able to reproduce this erratum with commercially available software.
Workaround: Do not place page directories and/or page tables in WC memory.
Status:
For the steppings affected, see the Summary Table of Changes.
V16.
Processor Issues Inconsistent Transaction Size Attributes for Locked Operation
Problem:
When the processor is in the Page Address Extension (PAE) mode and detects the need to set the
Access and/or Dirty bits in the page directory or page table entries, the processor sends an 8 byte load
lock onto the system bus. A subsequent 8 byte store unlock is expected, but instead a 4 byte store
unlock occurs. Correct data is provided since only the lower bytes change, however external logic
monitoring the data transfer may be expecting an 8 byte store unlock.
Implication: No known commercially available chipsets are affected by this erratum.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Table of Changes.
V17.
Multiple Accesses to the Same S-State L2 Cache Line and ECC Error
Combination May Result in Loss of Cache Coherency
Problem:
When a Read for Ownership (RFO) cycle has a 64 bit address match with an outstanding read hit on a
line in the L2 cache which is in the S-state AND that line contains an ECC error, the processor should
recycle the RFO until the ECC error is handled. Due to this erratum, the processor does not recycle the
RFO and attempts to service both the RFO and the read hit at the same time.
Implication: When this erratum occurs, cache may become incoherent.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Table of Changes.
20
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V18.
Processor May Hang When Resuming From Deep Sleep State
Problem:
When resuming from the Deep Sleep state the address strobe signals (ADSTB[1:0]#) may become out
of phase with respect to the system bus clock (BCLK).
Implication: When this erratum occurs, the processor will hang.
Workaround: The system BIOS should prevent the processor from going to the Deep Sleep state.
Status:
For the steppings affected, see the Summary Table of Changes.
V19.
When the Processor is in the System Management Mode (SMM), Debug
Registers May be Fully Writeable
Problem:
When in System Management Mode (SMM), the processor executes code and stores data in the
SMRAM space. When the processor is in this mode and writes are made to DR6 and DR7, the
processor should block writes to the reserved bit locations. Due to this erratum, the processor may not
block these writes. This may result in invalid data in the reserved bit locations.
Implication: Reserved bit locations within DR6 and DR7 may become invalid.
Workaround:Software may perform a read/modify/write when writing to DR6 and DR7 to ensure that the values in
the reserved bits are maintained.
Status:
For the steppings affected, see the Summary Table of Changes.
V20.
Associated Counting Logic Must be Configured When Using Event Selection
Control (ESCR) MSR
Problem:
ESCR MSRs allow software to select specific events to be counted, with each ESCR usually
associated with a pair of performance counters. ESCRs may also be used to qualify the detection of at-
retirement events that support precise-event-based sampling (PEBS). A number of performance
metrics that support PEBS require a 2nd ESCR to tag uops for the qualification of at-retirement events.
(The first ESCR is required to program the at-retirement event.) Counting is enabled via counter
configuration control registers (CCCR) while the event count is read from one of the associated
counters. When counting logic is configured for the subset of at-retirement events that require a 2nd
ESCR to tag uops, at least one of the CCCRs in the same group of the 2nd ESCR must be enabled.
Implication: If no CCCR/counter is enabled in a given group, the ESCR in that group that is programmed for tagging
uops will have no effect. Hence a subset of performance metrics that require a 2nd ESCR for tagging
uops may result in 0 count.
Workaround: Ensure that at least one CCCR/counter in the same group as the tagging ESCR is enabled for those
performance metrics that require two ESCRs and tagging uops for at-retirement counting.
Status:
For the steppings affected, see the Summary Table of Changes.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
21
R
V21.
IA32_MC0_ADDR and IA32_MC0_MISC Registers Will Contain Invalid or Stale
Data Following a Data, Address, or Response Parity Error
Problem:
If the processor experiences a data, address, or response parity error, the ADDRV and MISCV bits of
the IA32_MC0_STATUS register are set, but the IA32_MC0_ADDR and IA32_MC0_MISC registers
are not loaded with data regarding the error.
Implication: When this erratum occurs, the IA32_MC0_ADDR and IA32_MC0_MISC registers will contain invalid
or stale data.
Workaround: Ignore any information in the IA32_MC0_ADDR and IA32_MC0_MISC registers after a data, address
or response parity error.
Status:
For the steppings affected, see the Summary Table of Changes.
V22.
CR2 May Be Incorrect or an Incorrect Page Fault Error Code May Be Pushed
onto Stack After Execution of an LSS Instruction
Problem:
Under certain timing conditions, the internal load of the selector portion of the LSS instruction may
complete with potentially incorrect speculative data before the load of the offset portion of the address
completes. The incorrect data is corrected before the completion of the LSS instruction but the value
of CR2 and the error code pushed on the stack are reflective of the speculative state. Intel has not
observed this erratum with commercially available software.
Implication: When this erratum occurs, the contents of CR2 may be off by two, or an incorrect page fault error code
may be pushed onto the stack.
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.
V23.
BPM[5:3]# and GHI# VIL does not Meet Specification
Problem:
The VIL for BPM[5:3]# and GHI# is specified as 0.9 * GTLREF [V]. Due to this erratum the VIL for
these signals is 0.9 * GTLREF - .075 [V].
Implication: The processor requires a lower input voltage than specified to recognize a low voltage on the
BPM[5:3]# and GHI# signals.
Workaround: When intending to drive the BPM[5:3]# or GHI# signals low, ensure that the system provides a voltage
lower than 0.9 * GTLREF - .075 [V].
Status:
For the steppings affected, see the Summary Table of Changes.
22
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V24.
Processor May Hang Under Certain Frequencies and 12.5% STPCLK# Duty
Cycle
Problem:
If a system de-asserts STPCLK# at a 12.5% duty cycle, the processor is running below 2 GHz, and the
processor thermal control circuit (TCC) on-demand clock modulation is active, the processor may
hang. This erratum does not occur under the automatic mode of the TCC.
Implication: When this erratum occurs, the processor will hang.
Workaround: If use of the on-demand mode of the processor's TCC is desired in conjunction with STPCLK#
modulation, then assure that STPCLK# is not asserted at a 12.5% duty cycle.
Status:
For the steppings affected, see the Summary Table of Changes.
V25.
System May Hang if a Fatal Cache Error Causes Bus Write Line (BWL)
Transaction to Occur to the Same Cache Line Address as an Outstanding Bus
Read Line (BRL) or Bus Read-Invalidate Line (BRIL)
Problem:
A processor internal cache fatal data ECC error may cause the processor to issue a BWL transaction to
the same cache line address as an outstanding BRL or BRIL. As it is not typical behavior for a single
processor to have a BWL and a BRL/BRIL concurrently outstanding to the same address, this may
represent an unexpected scenario to system logic within the chipset.
Implication: The processor may not be able to fully execute the machine check handler in response to the fatal cache
error if system logic does not ensure forward progress on the system bus under this scenario.
Workaround: System logic should ensure completion of the outstanding transactions. Note that during recovery from
a fatal data ECC error, memory image coherency of the BWL with respect to BRL/BRIL transactions is
not important. Forward progress is the primary requirement.
Status:
For the steppings affected, see the Summary Table of Changes.
V26.
L2 Cache May Contain Stale Data in the Exclusive State
Problem:
If a cacheline (A) is in Modified (M) state in the write-combining (WC) buffers and in the Invalid (I)
state in the L2 cache and its adjacent sector (B) is in the Invalid (I) state and the following scenario
occurs:
1. A read to B misses in the L2 cache and allocates cacheline B and its associated second-sector pre-
fetch into an almost full bus queue,
2. A Bus Read Line (BRL) to cacheline B completes with HIT# and fills data in Shared (S) state,
The bus queue full condition causes the prefetch to cacheline A to be cancelled, cacheline A will remain
M in the WC buffers and I in the L2 while cacheline B will be in the S state.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
23
R
Then, if the further conditions occur:
1. Cacheline A is evicted from the WC Buffers to the bus queue which is still almost full,
2. A hardware prefetch Read for Ownership (RFO) to cacheline B, hits the S state in the L2 and
observes cacheline A in the I state, allocates both cachelines,
3. An RFO to cacheline A completes before the WC Buffers write modified data back, filling the L2
with stale data,
4. The writeback from the WC Buffers completes leaving stale data, for cacheline A, in the
Exclusive (E) state in the L2 cache.
Implication: Stale data may be consumed leading to unpredictable program execution. Intel has not been able to
reproduce this erratum with commercial software.
Workaround: It is possible for BIOS to contain a workaround for this erratum.
Status:
For the steppings affected, see the Summary Table of Changes.
V27.
Re-mapping the APIC Base Address to a Value Less Than or Equal to
0xDC001000 may Cause IO and Special Cycle Failure
Problem:
Remapping the APIC base address from its default can cause conflicts with either I/O or special cycle
bus transactions.
Implication: Either I/O or special cycle bus transactions can be redirected to the APIC, instead of appearing on the
front-side bus.
Workaround: Use any APIC base addresses above 0xDC001000 as the relocation address.
Status:
For the steppings affected, see the Summary Table of Changes.
V28.
Erroneous BIST Result Found in EAX Register After Reset
Problem:
The processor may show an erroneous BIST (built-in self test) result in the EAX register bit 0 after
reset.
Implication: When this erratum occurs, an erroneous BIST failure will be reported in the EAX register bit 0, however
this failure can be ignored since it is not accurate.
Workaround: It is possible for BIOS to workaround this issue by masking off bit 0 in the EAX register where BIST
results are written.
Status:
For the steppings affected, see the Summary Table of Changes.
24
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V29.
Processor Does not Flag #GP on Non-zero Write to Certain MSRs
Problem:
When a non-zero write occurs to the upper 32 bits of IA32_CR_SYSENTER_EIP or
IA32_CR_SYSENTER_ESP, the processor should indicate a general protection fault by flagging #GP.
Due to this erratum, the processor does not flag #GP.
Implication: The processor unexpectedly does not flag #GP on a non-zero write to the upper 32 bits of
IA32_CR_SYSENTER_EIP or IA32_CR_SYSENTER_ESP. No known commercially available
operating system has been identified to be affected by this erratum.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Table of Changes.
V30.
Simultaneous Assertion of A20M# and INIT# may Result in Incorrect Data Fetch
Problem:
If A20M# and INIT# are simultaneously asserted by software, followed by a data access to the
0xFFFFFXXX memory region, with A20M# still asserted, incorrect data will be accessed. With
A20M# asserted, an access to 0xFFFFFXXX should result in a load from physical address
0xFFEFFXXX. However, in the case of A20M# and INIT# being asserted together, the data load will
actually be from the physical address 0xFFFFFXXX. Code accesses are not effected by this erratum.
Implication: Processor may fetch incorrect data, resulting in BIOS failure.
Workaround: Deasserting and reasserting A20M# prior to the data access will workaround this erratum.
Status:
For the steppings affected, see the Summary Table of Changes.
V31.
Processor Does not Respond to Break Requests From ITP
Problem:
On power-up and low-power state transitions, the processor’s TAP circuitry may remain in the Tap-
Logic-Reset(TLR) state.
Implication: The ITP is unable to cause a break on reset in the processor, which may prevent the loading of processor
and chipset registers, or affect the ability to debug from cold boot and low power transitions.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Table of Changes.
V32.
CPUID Instruction Returns Incorrect Number of ITLB Entries
Problem:
When CPUID is executed with EAX = 2 it should return a value of 51h in EAX[15:8] to indicate that
the Instruction Translation Lookaside Buffer (ITLB) has 128 entries. Due to this erratum, the
processor returns 50h (64 entries).
Implication: Software may incorrectly report the number of ITLB entries. Operation of the processor is not affected.
Workaround: None identified.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
25
R
Status:
For the steppings affected, see the Summary Table of Changes.
V33.
A Write to APIC Registers Sometimes May Appear to Have Not Occurred
Problem:
In respect to the retirement of instructions, stores to the uncacheable memory-based APIC register
space are handled in a non-synchronized way. For example if an instruction that masks the interrupt
flag, e.g. CLI, is executed soon after an uncacheable write to the Task Priority Register (TPR) that
lowers the APIC priority, the interrupt masking operation may take effect before the actual priority has
been lowered. This may cause interrupts whose priority is lower than the initial TPR, but higher than
the final TPR, to not be serviced until the interrupt flag is finally cleared, i.e. by STI instruction.
Interrupts will remain pending and are not lost.
Implication: In this example the processor may allow interrupts to be accepted but may delay their service.
Workaround: This non-synchronization can be avoided by issuing an APIC register read after the APIC register write.
This will force the store to the APIC register before any subsequent instructions are executed. No
commercial operating system is known to be impacted by this erratum.
Status:
For the steppings affected, see the Summary Table of Changes.
V34.
Store to Load Data Forwarding may Result in Switched Data Bytes
Problem:
If in a short window after an instruction that updates a segment register has executed but not yet
retired, there is a load occurring to an address matches a recent previous store operation but the data
size is smaller than the store, the resulting data forwarded from the store to the load may have some of
the lower bytes switched.
Implication: If this erratum occurs, the processor may execute with incorrect data.
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.
V35.
Parity Error in the L1 Cache may Cause the Processor to Hang
Problem:
If a locked operation accesses a line in the L1 cache that has a parity error, it is possible that the
processor may hang while trying to evict the line.
Implication: If this erratum occurs, it may result in a system hang. Intel has not observed this erratum with any
commercially available software.
Workaround: None.
Status:
For the steppings affected, see the Summary Table of Changes.
26
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V36.
The TCK Input in the Test Access Port (TAP) is Sensitive to Low Clock Edge
Rates and Prone to Noise Coupling Onto TCK's Rising or Falling Edges
Problem:
TCK is susceptible to double clocking when low-amplitude noise is riding on TCK edge, while it is
crossing the receiver's transition region. TAP failures tend to increase with increases in background
system noise.
Implication: This only impacts JTAG/TAP accesses to the processor. Other bus accesses are not affected.
Workaround: To minimize the effects of this issue, reduce noise on the TCK-net at the processor relative to ground,
and position TCK relative to BCLK to minimize the TAP error rate. Decreasing rise times to under
800ps reduced the failure rate but does not stop all failures.
Status:
For the steppings affected, see the Summary Table of Changes.
V37.
The State of the Resume Flag (RF Flag) in a Task-State Segment (TSS) may be
Incorrect
Problem:
After executing a JMP instruction to the next (or other) task through a hardware task switch, it is
possible for the state of the RF flag (in the EFLAGS register image) to be incorrect.
Implication: The RF flag is normally used for code breakpoint management during debug of an application. It is not
typically used during normal program execution. Code breakpoints or single step debug behavior in the
presence of hardware task switches, therefore, may be unpredictable as a result of this erratum. This
erratum has not been observed in commercially available software.
Workaround: None.
Status:
For the steppings affected, see the Summary Table of Changes.
V38.
Changes to CR3 Register do not Fence Pending Instruction Page Walks
Problem:
When software writes to the CR3 register, it is expected that all previous/outstanding code, data
accesses and page walks are completed using the previous value in CR3 register. Due to this erratum,
it is possible that a pending instruction page walk is still in progress, resulting in an access (to the PDE
portion of the page table) that may be directed to an incorrect memory address.
Implication: The results of the access to the PDE will not be consumed by the processor so the return of incorrect
data is benign. However, the system may hang if the access to the PDE does not complete with data (e.g.
infinite number of retries).
Workaround: It is possible for the BIOS to have a workaround for this erratum.
Status:
For the steppings affected, see the Summary Table of Changes.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
27
R
V39.
System Bus Interrupt Messages without Data that Receive a HardFailure
Response May Hang the Processor
Problem:
When a system bus agent (processor or chipset) issues an interrupt transaction without data onto the
system bus and the transaction receives a HardFailure response, a potential processor hang can occur.
The processor, which generates an inter-processor interrupt (IPI) that receives the HardFailure
response, will still log the MCA error event cause as HardFailure, even if the APIC causes a hang.
Other processors, which are true targets of the IPI, will also hang on hardfail-without-data, but will not
record an MCA HardFailure event as the cause. If a HardFailure response occurs on a system bus
interrupt message with data, the APIC will complete the operation so as not to hang the processor.
Implication: The processor may hang.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Tables of Changes.
V40.
Memory Type of the Load Lock Different from its Corresponding Store Unlock
Problem:
A use-once protocol is employed to ensure that the processor in a multi-agent system may access
data that is loaded into its cache on a Read-for-Ownership operation at least once before it is snooped
out by another agent. This protocol is necessary to avoid a multi-agent livelock scenario in which the
processor cannot gain ownership of a line and modify it before that data is snooped out by another
agent. In the case of this erratum, split load lock instructions incorrectly trigger the use-once protocol.
A load lock operation accesses data that splits across a page boundary with both pages of WB memory
type. The use-once protocol activates and the memory type for the split halves get forced to UC. Since
use-once does not apply to stores, the store unlock instructions go out as WB memory type. The full
sequence on the bus is: locked partial read (UC), partial read (UC), partial write (WB), locked partial
write (WB). The use-once protocol should not be applied to load locks.
Implication: When this erratum occurs, the memory type of the load lock will be different than the memory type of
the store unlock operation. This behavior (load locks and store unlocks having different memory types)
does not introduce any functional failures such as system hangs or memory corruption.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Tables of Changes.
V41.
A 16-bit Address Wrap Resulting from a Near Branch (Jump or Call) May Cause
an Incorrect Address to Be Reported to the #GP Exception Handler
Problem:
If a 16-bit application executes a branch instruction that causes an address wrap to a target address
outside of the code segment, the address of the branch instruction should be provided to the general
protection exception handler. It is possible that, as a result of this erratum, that the general protection
handler may be called with the address of the branch target.
Implication: The 16-bit software environment which is affected by this erratum, will see that the address reported by
the exception handler points to the target of the branch, rather than the address of the branch instruction.
Workaround: None identified
Status:
For the steppings affected, see the Summary Tables of Changes.
28
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
V42.
FOPCODE Routine signals Debug Exception (#DB) if a Data Breakpoint is set on
an FP Instruction
Problem:
The default Microcode Floating Point Event Handler routine executes a series of loads to obtain data
about the FP instruction that is causing the FP event. If a data breakpoint is set on the instruction
causing the FP event, the load in the microcode routine will trigger the data breakpoint resulting in a
Debug Exception.
Implication: An incorrect Debug Exception (#DB) may occur if data breakpoint is placed on an FP instruction. Intel
has not observed this erratum with any commercially available software or system.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Table of Changes
V43.
xAPIC May Not Report Some Illegal Vector Errors
Problem:
The local xAPIC has an Error Status Register, which records all errors. The bit 6 (the Receive Illegal
Vector bit) of this register, is set when the local xAPIC detects an illegal vector in a received message.
When an illegal vector error is received on the same internal clock that the error status register is being
written (due to a previous error), bit 6 does not get set and illegal vector errors are not flagged.
Implication: The xAPIC may not report some Illegal Vector errors when they occur at approximately the same time
as other xAPIC errors. The other xAPIC errors will continue to be reported.
Workaround: None identified.
Status:
For the steppings affected, see the Summary Table of Changes.
V44.
Memory Aliasing of Pages as Uncacheable Memory Type and Write Back (WB)
May Hang the System
Problem:
When a page is being accessed as either Uncacheable (UC) or Write Combining (WC) and WB, under
certain bus and memory timing conditions, the system may loop in a continual sequence of UC fetch,
implicit writeback, and Request For Ownership (RFO) retries.
Implication: This erratum has not been observed in any commercially available operating system or application. The
aliasing of memory regions, a condition necessary for this erratum to occur, is documented as being
unsupported in the IA-32 Intel® Architecture Software Developer's Manual, Volume 3, section 10.12.4,
Programming the PAT. However, if this erratum occurs the system may hang.
Workaround: The pages should not be mapped as either UC or WC and WB at the same time.
Status:
For the steppings affected, see the Summary Table of Changes.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
29
R
V45.
A Timing Marginality in the Arithmetic Logic Unit (ALU) May Cause
Indeterminate Behavior
Problem:
A timing marginality may exist in the clocking of the ALU which leads to a slowdown in the speed of
the circuit’s operation. This could lead to incorrect behavior of the ALU.
Implication: When this erratum occurs, unpredictable application behavior and/or system hang 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.
30
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Specification Clarifications
The Specification Clarifications listed in this section apply to the following documents:
•
Mobile Intel® Celeron® Processor on .13 Micron Process in Micro-FCPGA Package Datasheet
(Order Number 251308)
All Specification Clarifications will be incorporated into a future version of the appropriate mobile Intel
Celeron processor on 0.13 micron process in Micro-FCPGA Package documentation.
1.
Clarifying DBI# Definition for all Processors With Intel® NetBurst™ Micro-
architecture
The definition of DBI# signals will be clarified for Intel® Pentium 4 Processors with Intel NetBurst
Micro-architecture. The new definition states:DBI[3:0]# are source synchronous and indicate the
polarity of the D[63:0]# signals. The DBI[3:0]# signals are activated when the data on the data bus is
inverted. If more than half of the data bits, within a 16-bit group, would have been asserted electrically
low, the bus agent may invert the data bus signals for that particular sub-phase for that 16-bit group.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
31
R
This page is left intentionally blank.
32
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Specification Changes
The Specification Changes listed in this section apply to the following documents:
•
Mobile Intel® Celeron® Processor on .13 Micron Process in Micro-FCPGA Package Datasheet
(Order Number 251308)
All Specification Changes will be incorporated into a future version of the appropriate mobile Intel
Celeron processor on 0.13 micron process in Micro-FCPGA package documentation.
1.
Context ID Feature Added to the CPUID Instruction Feature
Flags/IA32_MISC_Enable Registers
IA32_MISC_ENABLE register, bit 24 status has changed from Reserved to the following definition:
IA32_MISC_ENABLE – Miscellaneous Enables Register, bit # 24
MSR Address:
Default Value:
01A0h Accessed as a Qword
High Dword XXXX XXXXh
Low Dword XXXX XXXX XXXX XXXX XXXX XX00 X0X0 0001b
Access:
Type:
Read/Write
Shared
IA32_MISC_ENABLE is a 64-bit register accessed only when referenced as a Qword through a
RDMSR or WRMSR instruction.
Bit 24 of the IA32_MISC_ENABLE status has changed from Reserved to the following:
Bit
Descriptions
24
L1 Data Cache Context Mode (R/W). When set to a ‘1’ this bit places the L1 Data Cache into
shared mode. When set to a ‘0’ (default) this bit places the L1 Data Cache into adaptive mode.
When this bit is set to a ‘0’, adaptive mode, the Page Directory Base Register contained in CR3
must be identical across all logical processors.
Note: If the Context ID feature flag, ECX[10], is not set to a ‘1’ after executing the CPUID
instruction with EAX = 1, then this feature is not supported and BIOS must not alter the contents
of this bit location.
In the CPUID instruction function 1 feature information, bit 10 of ECX register (ECX[10]) has been
assigned flag to identify “Context ID feature” . The status has changed from Reserved to the following:
ECX [Bits]
Descriptions of Feature Flag Value
10
Context ID. A value of 1 indicates the L1 data cache mode can be set to either adaptive
mode or shared mode. A value of 0 indicates this feature is not supported.
See definition of the IA32_MISC_ENABLE MSR Bit 24 (L1 Data Cache Context Mode)
for more details.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
33
R
2.
BR0# Maximum Hold Time Specification Change
The BR0# maximum hold time has changed to 2 BCLKs. This change will be shown in the “System
Bus AC Specifications (Reset Conditions)” table and “System Bus Reset and Configuration Timings”
figure of the Mobile Intel® Celeron® Processor on .13 Micron Process in Micro-FCPGA Package
Datasheet. This change will be incorporated in the next revision of the datasheet.
Currently it states:
Table 21. System Bus AC Specifications (Reset Conditions)
T# Parameter
Min
Max
Unit
Figure
Notes
T45: Reset Configuration Signals (A[31:3]#, BR0# INIT#, SMI#)
Setup Time
4
BCLKs
13
1
T46: Reset Configuration Signals (A[31:3]#, BR0# INIT#, SMI#)
Hold Time
2
20
BCLKs
13
2
NOTES:
Before the deassertion of RESET#.
After clock that deasserts RESET#.
It should state:
Table 21. System Bus AC Specifications (Reset Conditions)
T# Parameter
Min
Max
Unit
Figure
Notes
T45: Reset Configuration Signals (A[31:3]#, BR0# INIT#,
SMI#) Setup Time
4
BCLKs
13
1
T46:Reset Configuration Signals (A[31:3]#,INIT#, SMI#)
Hold Time
2
2
20
2
BCLKs
BCLKs
13
13
2
2
T47: Reset Configuration Signal BR0# Hold Time
NOTES:
Before the deassertion of RESET#.
After clock that deasserts RESET#.
34
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
The following figure is modified to reflect this change:
Figure 12. System Bus Reset and Configuration Timings
BCLK
Tt
Reset
Ty
Tv
Tx
Tw
Configuration
A[31:3], SMI#,
INIT#
Valid
Valid
Configuration
BR0#
Tv = T13 (RESET# Pulse Width)
Tw = T45 (Reset Configuration Signals Setup Time)
Tx = T46 (Reset Configuration Signals A[31:3], SMI#, and INIT# Hold Time)
Ty = T47 (Reset Configuration signal BR0# Hold Time)
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
35
R
This page is left intentionally blank.
36
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
R
Documentation Changes
The documentation changes listed in this section apply to the following documents:
•
Mobile Intel® Celeron® Processor on .13 Micron Process in Micro-FCPGA Package Datasheet
(Order Number 251308)
Note: Documentation changes for IA-32 Intel(R) Architecture Software Developer’s Manual volumes 1, 2,
and 3 are posted in a separate document - IA-32 Intel(R) Architecture Software Developer’s Manual
Documentation Changes. This document is posted on http://developer.intel.com/
All documentation changes will be incorporated into a future version of the appropriate Mobile Intel®
Celeron® Processor on 0.13 micron process in Micro-FCPGA package documentation.
There are no documentation changes.
Mobile Intel® Celeron® Processor .13 Micron Process
Micro-FCPGA Package Specification Update
37
RH80532NC021256/SL6FN 相关器件
型号 | 制造商 | 描述 | 价格 | 文档 |
RH80532NC025256 | ETC | Microprocessor | 获取价格 | |
RH80532NC029256 | ETC | Microprocessor | 获取价格 | |
RH80532NC029256/SL6VG | INTEL | RISC Microprocessor, 64-Bit, 1700MHz, CMOS, CPGA478 | 获取价格 | |
RH80532NC033256 | ETC | Microprocessor | 获取价格 | |
RH80532NC033256/SL6J4 | INTEL | RISC Microprocessor, 64-Bit, 1800MHz, CMOS, CPGA478 | 获取价格 | |
RH80532NC033256/SL6VH | INTEL | RISC Microprocessor, 64-Bit, 1800MHz, CMOS, CPGA478 | 获取价格 | |
RH80532NC041256 | INTEL | Microprocessor | 获取价格 | |
RH80532NC041256/SL6VJ | INTEL | Microprocessor | 获取价格 | |
RH80532NC049256/SL6ZW | INTEL | Microprocessor | 获取价格 | |
RH80532NC049256/SL8SB | INTEL | Microprocessor | 获取价格 |
RH80532NC021256/SL6FN 相关文章
- 2024-09-20
- 5
- 2024-09-20
- 8
- 2024-09-20
- 8
- 2024-09-20
- 6