Ten Year Anniversary of Core 2 Duo and Conroe: Moore’s Law is Dead, Long Live Moore’s Law
by Ian Cutress on July 27, 2016 10:30 AM EST- Posted in
- CPUs
- Intel
- Core 2 Duo
- Conroe
- ITRS
- Nostalgia
- Time To Upgrade
Core: Load Me Up
When discussing the size of the reorder buffer, I mentioned that for some ops relying on the data of others, the order in which they need to be processed has to remain consistent – the load for the second op has to follow the store from the first in order for the calculation to be correct. This works for data that is read from and written to the same location in the same data stream, however with other operations, the memory addresses for loads and stores are not known until they pass the address generation units (AGUs).
This makes reordering a problem at a high level. You ultimately do not want a memory location to be written and stored by two different operations at the same time, or for the same memory address to be used by different ops while one of those ops is sitting in the reorder queue. When a load micro-op enters the buffer, the memory addresses of previous stores are not known until they pass the AGUs. Note, that this applies to memory addresses in the caches as well as main memory. However, if one can speed up loads and load latency in the buffers, this typically has a positive impact in most software scenarios.
With Core, Intel introduced a ‘New Memory Disambiguation’. For lack of a better analogy, this means that the issue of loads preceding stores is given a ‘do it and we’ll clean up after’ approach. Intel stated at the time that the risk that a load will load a value out of an address that is being written to by a store that has yet to be finished is pretty small (1-2%), and the chance decreases with larger caches. So by allowing loads to go head of stores, this allows a speedup but there has to be a catch net for when it goes wrong. To avoid this, a predictor is used to help. The dynamic alias predictor tries to spot this issue. If it happens, the load will have to be repeated, with a penalty of about 20-cycles.
Unofficial AnandTech Diagram
The predictor gives permission for a load to move ahead of a store, and after execution the conflict logic scans the buffer in the Memory reOrder Buffer (MOB) to detect an issue. If it happens, then the load is reprocessed back up the chain. In the worst case scenario, this might reduce performance, but as Johan said back in 2006: ‘realistically it is four steps forward and one step back, resulting in a net performance boost’.
Using this memory disambiguation technique, Intel reported a 40% performance boost purely on allowing loads to be more flexible in a number of synthetic loads (or 10-20% in real world), along with L1 and L2 performance boosts. It is worth noting that this feature affects INT workloads more often than FP workloads, purely on the basis that FP workloads tend to be more ordered by default. This is why AMD’s K8 lost ground to Intel on INT workloads, despite having a lower latency memory system and more INT resources, but stayed on track with FP.
Core: No Hyper-Threading, No Integrated Memory Controller
In 2016, HT and an integrated memory controller (IMC) are now part of the fundamental x86 microarchitecture in the processors we can buy. It can be crazy to think that one of the most fundamental upticks in x86 performance in the last decade lacked these two features. At the time, Intel gave reasons for both.
Simultaneous Hyper-Threading, the act of having two threads funnel data through a single core, requires large buffers to cope with the potential doubling of data and arguably halves resources in the caches, producing more cache pressure. However, Intel gave different reasons at the time – while SMT gave a 40% performance boost, it was only seen as a positive by Intel in server applications. Intel said that SMT makes hotspots even hotter as well, meaning that consumer devices would become power hungry and hot without any reasonable performance improvement.
On the IMC, Intel stated at the time that they had two options: an IMC, or a larger L2 cache. Which one would be better is a matter for debate, but Intel in the end went with a 4 MB L2 cache. Such a cache uses less power than an IMC, and leaving the IMC on the chipset allows for a wider support range of memory types (in this case DDR2 for consumers and FB-DIMM for servers). However, having an IMC on die improves memory latency significantly, and Intel stated that techniques such as memory disambiguation and improved prefetch logic can soak up this disparity.
As we know know, on-die IMCs are the big thing.
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Dobson123 - Wednesday, July 27, 2016 - link
I'm getting old.3ogdy - Wednesday, July 27, 2016 - link
That's what I thought about when I read "TEN year anniversary". It certainly doesn't feel like it was yesterday...but it certainly feels as old as "last month" is in my mind and that's mostly thanks to i7s, FXs, IPS, SSDs and some other things that proved to be more or less of a landmark in tech history.close - Thursday, July 28, 2016 - link
I just realized I have an old HP desktop with a C2D E6400 that will turn 10 in a few months and it's still humming along nicely every day. It ran XP until this May when I switched it to Win10 (and a brand new SSD). The kind of performance it offers in day to day work even to this day amazes me and sometimes it even makes me wonder why people with very basic workloads would buy more expensive stuff than this.junky77 - Thursday, July 28, 2016 - link
marketing, misinformation, lies and the need to feel secure and have something "better"Solandri - Friday, July 29, 2016 - link
How do you think those of us old enough to remember the 6800 and 8088 feel?JimmiG - Sunday, July 31, 2016 - link
Well my first computer had a 6510 running at 1 MHz.Funnily enough, I never owned a Core 2 CPU. I had an AM2+ motherboard and I went the route of the Athlon X2, Phenom and then Phenom II before finally switching to Intel with a Haswell i7.
Core 2 really changed the CPU landscape. For the first time in several years, Intel firmly beat AMD in efficiency and raw performance, something AMD has still not recovered from.
oynaz - Friday, August 19, 2016 - link
We miss or C64s and AmigasArtShapiro - Tuesday, August 23, 2016 - link
What about those of us who encountered vacuum tube computers?AndrewJacksonZA - Wednesday, July 27, 2016 - link
I'm still using my E6750... :-)just4U - Thursday, July 28, 2016 - link
I just retired my dads E6750. It was actually still trucking along in a Asus Nvidia board that I had figured would be dodgy because the huge aluminum heatsink on the chipset was just nasty.. Made the whole system a heatscore. Damned if that thing didn't last right into 2016. Surprised the hell out of me.