07:58PM EDT - The biggest part of the show are the server talks in the last session of the last day. All four talks are worth covering, and the first talk is from IBM, detailing both its newest Power9 'Scale Up' version of its processor family, as well as an introduction to PowerAXON, its new connectivity IP. The talk is set to start at 5pm PT / midnight UTC.

08:02PM EDT - Talking about Power9 and the future

08:02PM EDT - Each Power generation is a 'family'

08:02PM EDT - Form slight variations of those designs to hit spots in the market

08:02PM EDT - First gen Power9 was two years ago at Hot Chips

08:02PM EDT - Deployed in the Summit Supercomputer

08:03PM EDT - That's built around 2-socket servers

08:03PM EDT - Today is the enterprise design, up to 16 socket

08:03PM EDT - Common features in all Power9 processors

08:03PM EDT - As we get more smaller transistors, same physical distance is actually further apart

08:04PM EDT - Couple of different variations of cores

08:04PM EDT - This is the Big core

08:04PM EDT - 8-way threading

08:04PM EDT - eDRAM for cache cells

08:04PM EDT - 120MB of on-chip L3

08:04PM EDT - 12x 20-way associative cache elements

08:04PM EDT - NUCA cache

08:04PM EDT - Fed by 7 TB/s on-chip bandwidth

08:05PM EDT - 8 billion transistors

08:05PM EDT - It would have taken 5 billion more transistors in traditional SRAM

08:05PM EDT - 14nm FF from GloFo

08:05PM EDT - 17 layer metal stack

08:05PM EDT - QoS

08:05PM EDT - Workload Optimized frequency

08:05PM EDT - Lots of perimeter IO to connect to devices

08:06PM EDT - NVLink 2.0 (25G), CAPI 2.0 (PCIe G4), OpenCAPI (25G)

08:06PM EDT - 48 lanes of PCIe Gen4

08:06PM EDT - PowerAXON 25 GT/sec Link for accelerators

08:06PM EDT - 'Reach out if you have an accelerator to attach to our CPUs'

08:07PM EDT - This is all common to the big Power9 chips

08:07PM EDT - PowerAXON is the new

08:08PM EDT - AXON stands for A and X (two types of SMP links), O for OpenCapi, N for NVLink

08:08PM EDT - Scale Up differs from current Scale Out CPUs

08:08PM EDT - More memory - 8 buffered channels for 230 GB/s, up from 150

08:08PM EDT - Up to 8TB per socket

08:08PM EDT - Better RAS, Compatible with Power8

08:09PM EDT - We want to connect memory via SERDES

08:09PM EDT - Can do this with Buffered Memory

08:10PM EDT - The processor doesn't have to be built around DDR

08:10PM EDT - With DDR, you don't know if the write has completed as there is no acknowledgement. This can change with SERDES based implementations

08:11PM EDT - Can build a buffer for DDR4, DDR5, GDDR5, NRAM etc.

08:11PM EDT - See it as more important going forward

08:11PM EDT - Short range SERDES with active redrivers

08:12PM EDT - Drive it to GPUs (NVLink), CPU to CPU (SMP), or through OpenCAPI accelerator

08:12PM EDT - Customized for domain specific applications

08:13PM EDT - Scale Out is DDR based, Scale up is DMI based

08:13PM EDT - DMI is smaller silicon than DDR, so more room for PowerAXON

08:13PM EDT - More SMPs

08:14PM EDT - Swap out memory controllers

08:14PM EDT - Redrive memory controller, like a home agent bridge

08:15PM EDT - Combine CPUs with Buffers, central to design

08:15PM EDT - aiming for reliability, baked into the buffers

08:15PM EDT - On-chip accelerators, g-zip, compression

08:15PM EDT - 3 links within motherboard for SMP

08:15PM EDT - remote SMP links that talk off board through AXON

08:16PM EDT - Logic blocks talk to different protocols

08:16PM EDT - A lot of the chip area is tied up in the PHYs or the interconnect, so adding all three doesn't add a lot of silicon die area

08:17PM EDT - (So PowerAXON can run OpenCAPI, NVLink, or SMP through one die block. It's bigger than a dedicated block, but it allows configurability depending on use)

08:17PM EDT - Centaur memory buffers

08:18PM EDT - DRAM devices are deterministic latency, e.g. 13 cycles, so DMI sends early tag in advance before checking CRC to line up muxes, so data can directly forwarded in expected time frame

08:19PM EDT - Needs to be built with this in mind

08:19PM EDT - Suggested systems

08:20PM EDT - four socket is easy - SMP to each CPU

08:20PM EDT - 16 socket is slightly different

08:20PM EDT - Get to any socket in two hops

08:21PM EDT - Power E980 Server box

08:21PM EDT - Four sockets in 5 U

08:21PM EDT - 64TB of DRAM

08:21PM EDT - VRMs are redundancy

08:21PM EDT - Connectivity in the back

08:21PM EDT - 22U for 16-socket

08:21PM EDT - 8 PCIe devices

08:22PM EDT - GPU on PowerAXON example

08:22PM EDT - Plug an array of GPUs on NVLink alongside SMP

08:22PM EDT - Future

08:23PM EDT - One PHY to rule them all

08:23PM EDT - One connector for SMP, OpenCAPI, NVLINK

08:23PM EDT - Future is based on open standard buffer

08:23PM EDT - for memory over AXON

08:23PM EDT - 4 x bandwidth vs DDR4

08:24PM EDT - OpenCAPI target of 5ns

08:24PM EDT - Big tall DIMMs

08:24PM EDT - Targeting 5ns idle latency

08:24PM EDT - new buffer is a smaller chip - single port with single buffer

08:25PM EDT - Next Power9 chip with new memory technology on AXON and CAPI

08:25PM EDT - Up to 350 GB/s

08:25PM EDT - OpenCAPI 4.0

08:26PM EDT - Power10 on DDR5, up to 435GB/s on memory

08:26PM EDT - 2020+

08:26PM EDT - Q&A

08:27PM EDT - Q: We designed POWER with GPU. Didn't work with NVLINK, connecting to GPU by little-endian? A: Yes, we support both, and mixed

08:28PM EDT - Q: Power Delta on SERDES? A: Different because never idle. Based on lane count. Power in processor socket is lower at full bandwidth. From a power perf POV is great

08:29PM EDT - Only in low utilization would it be iffy

08:29PM EDT - Buffer is a handful of watts

08:29PM EDT - Q: Area of chip? A: 600-ish mm2

08:29PM EDT - Q: Latency impact of eDRAM cache? A: Minimal

08:30PM EDT - Q: Shipping? A: 2-socket was last year, these new boxes were just announced. Shipping over next few months

08:30PM EDT - Next talk is Fujitsu: https://www.anandtech.com/show/13258/hot-chips-2018-fujitsu-afx64-arm-core-live-blog