Board:asus/kgpe-d16: Difference between revisions

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This board is automatically tested by Raptor Engineering's test stand.  For more details please visit [[AutoTest/RaptorEngineering]].
This board is automatically tested by Raptor Engineering's test stand.  For more details please visit [[AutoTest/RaptorEngineering]].
A basic system diagram is available in the official manual, which can be downloaded from ASUS directly or from [[https://www.pugetsystems.com/files/1479/parts/Motherboard/Asus-KGPE-D16-6916/e6201_kgpe-d16_v2_manual.pdf|Puget Systems]].  The diagram is available in Appendix A.1 and has been confirmed to match the hardware shipping from ASUS.  Not indicated are the PCIe lane widths for the gigabit network controller, which are both x1.  All legacy PCI devices share the same bus, and partially due to this design the SP5100 has severe issues with bridging high-bandwidth PCI peripherals.  As such, an external PCI-PCIe bridge is recommended should you need to interface a high bandwidth legacy PCI device to this system; ASMedia controllers have been verified to function correctly.
Northbridge functions are distributed between the CPU internal northbridge and the SR5690 northbridge, which is effectively a HyperTransport to ALink/PCIe translator and switch.  There is a separate SP5100 southbridge device, adjacent to the northbridge and residing under the smaller heatsink of the two.  This device provides all traditional southbridge services including the LPC bridge and SATA controllers.  All southbridge-destined messages, including CPU-originated power state control messages over HyperTransport, pass through the CPU northbridge and are routed to the southbridge via the SR5690 northbridge device. 
Incidentally, this design places the IOMMU, which is part of the SR5690, in the correct location to properly shield the main CPU from all unauthorized traffic.  If the southbridge connected directly to a HyperTransport link there would be no way to prevent unauthorized DMA from legacy PCI devices connected to the southbridge, or even from the southbridge's embedded microprocessor.


[[Category:Tutorials]]
[[Category:Tutorials]]

Revision as of 04:32, 21 January 2016

The KGPE-D16 is a relatively modern AMD Family 10h / 15h motherboard. It is well supported and stable under Coreboot, with all CPUs, RAM, and peripherals functioning normally. Family 10h processors do not currently support the isochronous mode required to enable the IOMMU, but Family 15h processors work well with the IOMMU enabled.

This board is automatically tested by Raptor Engineering's test stand. For more details please visit AutoTest/RaptorEngineering.

A basic system diagram is available in the official manual, which can be downloaded from ASUS directly or from [Systems]. The diagram is available in Appendix A.1 and has been confirmed to match the hardware shipping from ASUS. Not indicated are the PCIe lane widths for the gigabit network controller, which are both x1. All legacy PCI devices share the same bus, and partially due to this design the SP5100 has severe issues with bridging high-bandwidth PCI peripherals. As such, an external PCI-PCIe bridge is recommended should you need to interface a high bandwidth legacy PCI device to this system; ASMedia controllers have been verified to function correctly.

Northbridge functions are distributed between the CPU internal northbridge and the SR5690 northbridge, which is effectively a HyperTransport to ALink/PCIe translator and switch. There is a separate SP5100 southbridge device, adjacent to the northbridge and residing under the smaller heatsink of the two. This device provides all traditional southbridge services including the LPC bridge and SATA controllers. All southbridge-destined messages, including CPU-originated power state control messages over HyperTransport, pass through the CPU northbridge and are routed to the southbridge via the SR5690 northbridge device.

Incidentally, this design places the IOMMU, which is part of the SR5690, in the correct location to properly shield the main CPU from all unauthorized traffic. If the southbridge connected directly to a HyperTransport link there would be no way to prevent unauthorized DMA from legacy PCI devices connected to the southbridge, or even from the southbridge's embedded microprocessor.