<b>Updated</b> CPU Cheatsheet - Seven Years of Covert CPU Operations
by Jarred Walton on August 28, 2004 9:00 AM EST- Posted in
- CPUs
Intel Cheat Sheet
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| Intel IA32/EM64T Processors | |||||||||||
| Covington | Cel | Slot 1 | 266/300 | 8K+8K | 7.5 | 350 | 118 | 66 | |||
| Mendocino | Cel ("A") | Slot 1 | 266-433 | 16K+16K | 128K | 19 | 250 | 154 | 66 | 1-2 | |
| Mendocino | Cel ("A") | 370 | 233-533 | 16K+16K | 128K | 19 | 250 | 154 | 66 | 1-2 | |
| Coppermine-128 | Cel ("A") | 370 | 533-766 | 16K+16K | 128K | 28* | 180 | 106 | 66 | ||
| Coppermine-128 | Cel ("A") | 370 | 800-1100 | 16K+16K | 128K | 28* | 180 | 106 | 100 | ||
| Klamath | P II | Slot 1 | 233-333 | 16K+16K | 512K | 7.5+37.2 | 350 | 203+L2 | 66 | 1-2 | |
| Deschutes | P II | Slot 1 | 266-333 | 16K+16K | 512K | 7.5+37.2 | 250 | 118+L2 | 66 | 1-2 | |
| Deschutes | P II | Slot 1 | 350-450 | 16K+16K | 512K | 7.5+37.2 | 250 | 118+L2 | 100 | 1-2 | |
| Deschutes | P II Xeon | Slot 2 | 400-450 | 16K+16K | 512K | 7.5+37.2 | 250 | 118+L2 | 100 | 1-2 | |
| Deschutes | P II Xeon | Slot 2 | 400-450 | 16K+16K | 1M | 7.5+74.4 | 250 | 118+L2 | 100 | 1-2 | |
| Deschutes | P II Xeon | Slot 2 | 450 | 16K+16K | 2M | 7.5+148.8 | 250 | 118+L2 | 100 | 1-2 | |
| Katmai | P III | Slot 1 | 450-600 | 16K+16K | 512K | 9.5+37.2 | 250 | 131+L2 | 100 | 1-2 | |
| Katmai | P III B | Slot 1 | 533-600 | 16K+16K | 512K | 9.5+37.2 | 250 | 131+L2 | 133 | 1-2 | |
| Tanner | P III Xeon | Slot 2 | 500, 550 | 16K+16K | 512K | 9.5+37.2 | 250 | 128+L2 | 100 | 1-8 | |
| Tanner | P III Xeon | Slot 2 | 500, 550 | 16K+16K | 1M | 9.5+74.4 | 250 | 128+L2 | 100 | 1-8 | |
| Tanner | P III Xeon | Slot 2 | 500, 550 | 16K+16K | 2M | 9.5+148.8 | 250 | 128+L2 | 100 | 1-8 | |
| Cascades** | P III Xeon | Slot 2 | 600-1000 | 16K+16K | 256K | 28.1 | 180 | 106-90 | 133 | 1-2 | |
| Cascades | P III Xeon | Slot 2 | 700 | 16K+16K | 1M | 180 | 210? | 100 | 1-4 | ||
| Cascades | P III Xeon | Slot 2 | 700, 900 | 16K+16K | 2M | 180 | 385 | 100 | 1-4 | ||
| Coppermine** | P III | Slot 1 | 550-1000 | 16K+16K | 256K | 28.1 | 180 | 106-90 | 100 | 1-2 | |
| Coppermine** | P III B | Slot 1 | 533-1000 | 16K+16K | 256K | 28.1 | 180 | 106-90 | 133 | 1-2 | |
| Coppermine** | P III E | 370 | 500-1100 | 16K+16K | 256K | 28.1 | 180 | 106-90 | 100 | 1-2 | |
| Coppermine** | P III EB | 370 | 533-1133 | 16K+16K | 256K | 28.1 | 180 | 106-90 | 133 | 1-2 | |
| Tualatin | Cel ("A") | 370 | 1000-1400 | 16K+16K | 256K | 28.1 | 130 | 80 | 100 | ||
| Tualatin | P III | 370 | 1000-1333 | 16K+16K | 256K | 28.1 | 130 | 80 | 133 | 1-2 | |
| Tualatin | P III S | 370 | 1133-1400 | 16K+16K | 512K | 45.9 | 130 | 110? | 133 | 1-2 | |
| Willamette | Cel-128 | 478 | 1700-1800 | 12Ku+8K | 128K | 36.5 | 180 | 217* | 100 | ||
| Willamette | P 4 | 423 | 1300-2000 | 12Ku+8K | 256K | 42 | 180 | 217 | 100 | ||
| Willamette | P 4 | 478 | 1500-2400 | 12Ku+8K | 256K | 42 | 180 | 217 | 100 | ||
| Foster | Xeon DP | 603 | 1400-2000 | 12Ku+8K | 256K | 42 | 180 | 217 | 100 | 1-2 | |
| Foster | Xeon MP | 603 | 1400, 1500 | 12Ku+8K | 256K | 512K | 42+37? | 180 | 100 | 1-4 | |
| Foster | Xeon MP | 603 | 1600 | 12Ku+8K | 256K | 1M | 42+74? | 180 | 100 | 1-4 | |
| Northwood | Cel | 478 | 1400-2800 | 12Ku+8K | 128K | 36.5 | 130 | 131? | 100 | ||
| Northwood | Mob. Cel. | 478 | 1400-2800 | 12Ku+8K | 256K | 130 | 100 | ||||
| Northwood** | P 4 | 478 | 1800-2600 | 12Ku+8K | 512K | 55 | 130 | 146-131 | 100 | ||
| Northwood** | P 4 "B" | 478 | 2267-2800 | 12Ku+8K | 512K | 55 | 130 | 146-131 | 133 | ||
| Northwood** | P 4 HTT | 478 | 3067 | 12Ku+8K | 512K | 55 | 130 | 146-131 | 133 | ||
| Northwood** | P 4 "C" | 478 | 2400-3400 | 12Ku+8K | 512K | 55 | 130 | 146-131 | 200 | ||
| Gallatin** | P 4 EE | 478 | 3200-3400 | 12Ku+8K | 512K | 2M | 55+123 | 130 | 231-237? | 200 | |
| Prestonia | Xeon DP | 603 | 1600-3000 | 12Ku+8K | 512K | 55 | 130 | 100 | 1-2 | ||
| Prestonia | Xeon DP | 604 | 2000-3067 | 12Ku+8K | 512K | 55 | 130 | 133 | 1-2 | ||
| Prestonia | Xeon DP | 604 | 3067-3200 | 12Ku+8K | 512K | 1M | 55+61 | 130 | 133 | 1-2 | |
| Gallatin | Xeon MP | 603 | 1500-2800 | 12Ku+8K | 512K | 1M | 55+61 | 130 | 100 | 1-4 | |
| Gallatin** | Xeon MP | 603 | 2000-2700 | 12Ku+8K | 512K | 2M | 55+123 | 130 | 231-237? | 100 | 1-4 |
| Gallatin | Xeon MP | 603 | 3000 | 12Ku+8K | 512K | 4M | 55+246? | 130 | 100 | 1-4 | |
| Prescott 256? | Cel D | 478/775 | 2400-3200 | 12Ku+16K | 256K | 90 | 133 | ||||
| Prescott | P 4 "A" | 478 | 2400-2800 | 12Ku+16K | 1M | 125 | 90 | 112 | 133 | ||
| Prescott | P 4 "E" | 478 | 2800-3400 | 12Ku+16K | 1M | 125 | 90 | 112 | 200 | ||
| Prescott | P 4 "E" | T/775 | 2800-??? | 12Ku+16K | 1M | 125 | 90 | 112 | 200 | ||
| Prescott | P 4 "E" | T/775 | ???-??? | 12Ku+16K | 2M | 90 | 200/266 | ||||
| Nocona | Xeon | T/775? | 2800-3600+ | 12Ku+16K | 1M | 125 | 90 | 112? | 200 | 1-2 | |
| Irindale | 2M | 90 | 200? | ||||||||
| Banias | Cel M | 478M | 1300-1500 | 32K+32K | 512K | 130 | 100 | ||||
| Banias | P M | 478M | 900-1800 | 32K+32K | 1M | 130 | 100 | ||||
| Dothan | Cel M | 478M | 900-1500 | 32K+32K | 1M | 90 | 100/133 | ||||
| Dothan | P M | 478M | 1000-2400 | 32K+32K | 2M | 90 | 100/133 | ||||
| Potomac | 65 | ||||||||||
| Smithfield | 2C | ||||||||||
| Jonah | P M? | 65? | 2C | ||||||||
| Tulsa | |||||||||||
| Merom | |||||||||||
| Conroe | |||||||||||
| Gilo | |||||||||||
| Whitefield | |||||||||||
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| Intel IA64 Processors | |||||||||||
| Merced**** | Itanium1 | PAC-418 | 733-800 | 16K+16K | 96K | 2-4M | 25+300 | 180 | 300 | 66 | 512 |
| McKinley+ | Itanium2 | PAC-611 | 900-1000 | 16K+16K | 256K | 1.5-3M | 221 | 180 | 421 | 100 | 512 |
| Deerfield | Itanium2 | PAC-611 | 1000, 1500? | 16K+16K | 256K | 1.5M? | 130 | 266? | 100 | 512 | |
| Madison++ | Itanium2 | PAC-611 | 1300-1500? | 16K+16K | 256K | 2-6M | 477 | 130 | 374 | 100 | 512 |
| Fanwood | Itanium2 | PAC-611 | 1500-1667? | 16K+16K | 256K | 9M | 130 | 100/166 | 512 | ||
| Montecito | Itanium2? | 24M? | 1700? | 90 | 2C? | ||||||
| Millington | Itanium2? | ||||||||||
| Dimona | Itanium2? | 2C | |||||||||
| Montvale | Itanium2? | ||||||||||
| Tukwila | Itanium2? | 16C? | |||||||||
| Foxton | Itanium2? | ||||||||||
| Pellston | Itanium2? | ||||||||||
| * Die Size and/or transistor count is based off a larger CPU core with a portion of the die disabled. | |||||||||||
| ** Various steppings/sources listed different die sizes. | |||||||||||
| *** The bus speed on the P4, PM, CM, and Itanium is quad-pumped, but the CPU multiplier is based off the listed speed. | |||||||||||
| **** Figures for Merced based off of 4M L3 cache version. | |||||||||||
| + Figures for McKinley based off 3M L3 cache version. | |||||||||||
| ++ Figures for Madison based off 6M L3 cache version. | |||||||||||
| +++ All Itaniums are said to be 512-way SMP capable, but this is more a factor of the motherboard and system design than the chip itself (I think). | |||||||||||
Notes on the Intel side of things are similar to the AMD side. There are again a couple cores that have an asterisk, indicating that the core was a "downgraded" version of a faster core, mostly with the Celeron processors. The double-asterisks are for chips that had varying die sizes in the various steppings. This probably occurs to a small degree in most chips, but in the Cascades, Coppermine, and Northwood cores, the changes were well documented and rather drastic. Thoroughbred A to B in AMD was only a 4 mm2 die size increase, while Coppermine fluctuated between 106 mm2 to 90 mm2, and Northwood went from 146 mm2 to 131 mm2. My guess is that it was due in part to hand-optimizing the layouts of the cores, but if anyone has precise details on the hows and whys of the decreases, I would like to hear them.
In order to make the charts fit nicely within the space constraints, x86-64 was removed from the column lists. As of now, the only Intel CPUs that are known to include x86-64 support are the Nocona and Potomac cores. There will almost certainly be more in the future. The L1 cache of the P4 chips includes a trace cache, which stores decoded micro-ops, abbreviated uops. In the chart above, the trace cache corresponds to the L1 instruction cache found in typical CPUs, and 12Ku+16K means the cache has the ability to store 12,000 micro-ops as well as a standard 16KB of L1 data cache.
You can see that Intel also has 2C (dual core) designs in their roadmap, as well as a highly speculative 16C (sixteen core!) Itanium. Whether or not Tukwila will ever see the light of day is anyone's guess - it could simply be a mythical design that some hardware sites fantasize about. Transistor count on such a chips would likely be several BILLION transistors. (On a different note, I was recently up in Tukwila, WA purchasing a mountain bike from a pawn shop. They didn't have any processors for sale, unfortunately.)
In contrast to AMD, Intel has had several major architecture revisions during the past seven or so years. AMD pretty much stuck with the K7/Athlon core for all their processors, which was admittedly a very good design. Intel, with its deeper pockets, attacked on numerous fronts. First was the Pentium III line, which more or less ended in a draw with their rival AMD. Prompted by marketing - because "clockspeed sells" - Intel came up with a radical new architecture dubbed NetBurst, the basis of the Pentium 4. NetBurst was a success on the desktop, but it really was too power hungry for laptops, so Intel decided to pursue a completely separate architecture for its mobile processors, which is now also penetrating Blade and other low voltage markets. Finally, shortly after the launch of the Athlon 64, Intel countered with their reworked NetBurst architecture and the Prescott line of processors. Add to this the long-awaited launch of IA-64 (roughly ten years in the making!) which was a completely new architecture that was even more radical than NetBurst. Intel has been busy, needless to say.
For their desktop chips, SMP was available both officially and unnofficially. The Celeron chips were not intended for SMP use and were never validated (by Intel) to work in such configurations. However, enterprising motherboard makers like Abit with their BP6 board allowed users to run early Celerons in dual CPU configurations. Intel put a stop to that with Coppermine-128 and Tualatin-256 (if you can call it that) Celerons. The P3 Xeon chips were all "multi-processor" configurations, capable of up to 8-way SMP. Such support was more dependent on the motherboard and chipset, though, so most setups topped out at 4-way SMP. Intel had a chipset that linked two 4-way buses together for their 8-way configuration, while ServerWorks created a chipset and motherboard that supported 8-way directly. In theory, they could have even followed Intel's example and linked two buses together to have a 16-way SMP setup, although at that point motherboard size becomes a difficult issue.
Itanium and SMP is a special case that needs further clarification. SMP is not always listed in the above chart, but all Itaniums are said to be capable of 512-way SMP. This is really more of a factor of the motherboard(s) and system design than the chip itself. For example, special high-end clustered systems have been built using AMD Athlon MP and Opteron CPUs as well as Xeon chips that have as many as 128 chips in a "single" system. Itanium is a similar case with SMP. Motherboards with up to eight sockets exist for Itanium, but 512-way SMP requires special hardware beyond the motherboard. (Please feel free to correct me if that's wrong, but I'm pretty sure this is the case. I can't imagine what a motherboard for 512 Itaniums would even look like if it were to exist - 8x8 feet in size?)
Update: A couple people pointed out issues with the naming of the Celeron processors. At the time, Intel used "A" to designate processors that overlapped an existing model. So there were cacheless Celeron 266/300 processors, and the 266/300 with 128K L2 cache had an "A" suffix. This occurred again with the Celeron 533, and once more with the Celeron 1000/1100. In a similar vein, the Klamath core was only 350 nm, while Deschutes was 250 nm. It was initially listed as 350/250 as there were certain Deschutes cores that were released as a pseudo-Klamath, for instance the P2 300 MHz SL2W8. There was not any way to actually tell (other that word of mouth) which P2 chips had the Klamath core and which had the Deschutes core. The chart has now been corrected by putting in a 250 nm 266-333 Deschutes line.
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JarredWalton - Friday, August 27, 2004 - link
Regarding pipeline lengths on Intel products, there are numerous sources that state the P6 core was a 12 stage design. Perhaps the Interger pipeline was shorter and the FP was longer? I don't know for sure, but the majority of information I have read says P6 (PPro, P2, P3, Cel, Cel-2) were all the same core and were all 12 stages. Here's a link to one of the more authoritative CPU information guys that I have read, Jon "Hannibal" Stokes:http://arstechnica.com/cpu/004/pentium-1/pentium-1...
http://arstechnica.com/cpu/004/pentium-2/pentium-2...
Those contain a histort of the Pentium architecture. Unless you can provide a more definitive source for pipeline lengths, I tend to believe Hannibal. I also heard at the time the original P4 launched that it had "as few as 20 and as many as 28 stages, depending on the instruction being executed and other factors." Something like that. Most people stuck with the "20 stage" figure, but it has become increasingly clear that it was not a straight 20-stage design.
IntelUser2000 - Friday, August 27, 2004 - link
Another correction: the article states 12-stage pipeline for P6 cores? No, its 10, I don't know why some people say P6 cores and its related processors have 12 stage pipelines(exception being PM, because they ARE a different architecture, just not radical as P4), when its 10!!!IntelUser2000 - Friday, August 27, 2004 - link
First, some corrections.mostlyprudent, P4 Willamette is only available up to 2000. They are actually available from 1300-2000. Over 2000 is Northwood cores, which have 512KB L2 cache and is 0.13 micron process.
Second, why don't anybody seem to notice the pipeline numbers for Prescott on Page 6?
"The Prescott further extended the NetBurst pipeline to 23 stages in addition to the 8 fetch/decode stages. For whatever reason, Intel generally describes the pipeline of the Prescott as 31 stages while only calling the earlier design a 20 stage pipeline."
What the hell? Is it actually true? Can the writer, Jarred Walton, please answer this question? Did you just get the facts wrong or is it true that Prescott does have 23 stage pipelines?
FlameDeer - Tuesday, August 24, 2004 - link
Thanks Jarred, very good article! Very useful and helpful processor performance comparison, much better than Intel "BMW" naming! :)Some small correction at page 3 Intel Cheat Sheet table:
Entry no.3 Mendocino is 250nm, 154mm2 only
Entry no.7 Deschutes Bus Speed is 66 MHz
JarredWalton - Tuesday, August 24, 2004 - link
#36 - I suppose I should have been consistent with the bus speeds. Intel's really is quad-pumped and AMD's really is double pumped. Somehow along the way I redid the Intel side to have the quad pumped bus speed and I didn't redo the AMD side. The Netburst architecture likely benefits a little more from the increased bus speed, but if AMD certainly benefits as well. I'll include that in my updated version later this week. (My left wrist needs a rest. I don't want to risk carpal tunnel syndrome.)On the HyperTransport side of things, I really don't regard the HT bus speed as being that important. The old style bus (Athlon Socket A) was a 64-bit 400 MHz bus (200 MHz double-pumped - at least on the 3200+) while HyperTransport is a 16-bit 800 MHz bus. I think that's right, anyway. So 16-bit * 800 MHz (bidirectional) is the same as 400 MHz * 400 MHz (unidirectional). Bleh. Whatever the case, I'm pretty sure the HT bus doesn't really make for the A64 being faster. It helps out tremendously in the Opteron with multiple processors, but that's different.
johnsonx - Tuesday, August 24, 2004 - link
to #38There are two Thoroughbred B AXP 2600's. 133/266FSB @ 2133 Mhz (multiplier 15), and 166/333FSB at 2083Mhz (multiplier 12.5). Yours sounds like a 166/333FSB model.
mrmorris - Tuesday, August 24, 2004 - link
#15My 2600+ AMD XP runs 2083MHz and its Thoroughbred-B!
magratton - Monday, August 23, 2004 - link
#34 - Sweet. The article made me remember all those years, and that post gave me a great chuckle. Peace! Being an avid comments reader (though not so much a contributor) it is good to finally put a name to a.. well.. a name. Peace!mlittl3 - Monday, August 23, 2004 - link
JarredDon't mean to be persistent but I was wondering what your thoughts about the bus speed listings were.
Should AMD Athlon processors be listed with bus speeds like 100, 133, 166, 200 MHz or should it be 200, 266, 333, 400 MHz? Likewise for the AMD Athlon 64, FX, Opteron. They use hypertransport running anywhere from 600 to 1000 MHz and don't advertise a bus speed since the memory controller is integrated (even though everyone knows its 200 MHz X multiplier).
If the current listed speeds are the way it should be written, what about the Intel bus speeds of 400, 533, 800 and 1066 MHz? These really are 100, 133, 200 and 266 MHz when calculating the actual processor speed.
Do the Intel quad speed bus speeds really reflect the actual bus speed wherease the AMD double bus speed do not?
Just wanted to be clear. Thanks. Can't wait for the GPU cheat sheet.
Mark
JarredWalton - Monday, August 23, 2004 - link
Umm... crap, sort of let the cat out of the bag there. If the "JW" at the end of the other name didn't clue you in, it should be blatantly obvious who I am now. (Although only people that read the news and article comments are likely to have seen the name.)