Intel S1400SP4 DBS1400SP4 Manual De Usuario
Los códigos de productos
DBS1400SP4
Intel® Server Board S1400SP TPS
Functional Architecture
Revision 1.0
Intel order number G64248-001
21
Note: Some server operating systems do not display the total physical memory installed. What
is displayed is the amount of physical memory minus the approximate memory space used by
system BIOS components. These BIOS components include, but are not limited to:
is displayed is the amount of physical memory minus the approximate memory space used by
system BIOS components. These BIOS components include, but are not limited to:
1. ACPI (may vary depending on the number of PCI devices detected in the system)
2. ACPI NVS table
3. Processor microcode
4. Memory Mapped I/O (MMIO)
5. Manageability Engine (ME)
6. BIOS flash
2. ACPI NVS table
3. Processor microcode
4. Memory Mapped I/O (MMIO)
5. Manageability Engine (ME)
6. BIOS flash
3.2.2.4
RAS Features
The server board supports the following memory RAS modes:
Independent Channel Mode
Rank Sparing Mode
Mirrored Channel Mode
Lockstep Channel Mode
Single Device Data Correction (SDDC)
Error Correction Code (ECC) Memory
Demand Scrubbing for ECC Memory
Patrol Scrubbing for ECC Memory
Regardless of RAS mode, the requirements for populating within a channel given in the section
3.2.2.2 must be met at all times. Note that support of RAS modes that require matching DIMM
population between channels (Mirrored and Lockstep) require that ECC DIMMs be populated.
Independent Channel Mode is the only mode that supports non-ECC DIMMs in addition to ECC
DIMMs.
3.2.2.2 must be met at all times. Note that support of RAS modes that require matching DIMM
population between channels (Mirrored and Lockstep) require that ECC DIMMs be populated.
Independent Channel Mode is the only mode that supports non-ECC DIMMs in addition to ECC
DIMMs.
For RAS modes that require matching populations, the same slot positions across channels
must hold the same DIMM type with regards to size and organization. DIMM timings do not
have to match but timings will be set to support all DIMMs populated (that is, DIMMs with slower
timings will force faster DIMMs to the slower common timing modes).
must hold the same DIMM type with regards to size and organization. DIMM timings do not
have to match but timings will be set to support all DIMMs populated (that is, DIMMs with slower
timings will force faster DIMMs to the slower common timing modes).
3.2.2.4.1
Independent Channel Mode
In non-ECC and x4 SDDC configurations, each channel is running independently (nonlock-
step), that is, each cache-line from memory is provided by a channel. To deliver the 64-byte
cache-line of data, each channel is bursting eight 8-byte chunks. Back to back data transfer in
the same direction and within the same rank can be sent back-to-back without any dead-cycle.
The independent channel mode is the recommended method to deliver most efficient power and
bandwidth as long as the x8 SDDC is not required.
step), that is, each cache-line from memory is provided by a channel. To deliver the 64-byte
cache-line of data, each channel is bursting eight 8-byte chunks. Back to back data transfer in
the same direction and within the same rank can be sent back-to-back without any dead-cycle.
The independent channel mode is the recommended method to deliver most efficient power and
bandwidth as long as the x8 SDDC is not required.
3.2.2.4.2
Rank Sparing Mode
In Rank Sparing Mode, one rank is a spare of the other ranks on the same channel. The spare
rank is held in reserve and is not available as system memory. The spare rank must have
identical or larger memory capacity than all the other ranks (sparing source ranks) on the same
channel. After sparing, the sparing source rank will be lost.
rank is held in reserve and is not available as system memory. The spare rank must have
identical or larger memory capacity than all the other ranks (sparing source ranks) on the same
channel. After sparing, the sparing source rank will be lost.