AMD Takes Opteron To 2.4GHz 258
EconolineCrush writes "AMD has added a series of Opteron x50 processors to its workstation and server line that push the K8 core up to 2.4GHz. The Tech Report has tested the latest single and dual-processor Opterons against more than 20 other processors, including exotic Pentim 4 Extreme Edition chips, affordable Athlon 64s, and everything in between. Even if you have no interest in AMD's latest workstation chips, the review is worth checking out to see how two dozen of the fastest workstation and PC processors stack up in rendering, scientific computing, speech recognition, and even gaming tests."
2.4ghz? (Score:3, Funny)
Re:2.4ghz? (Score:2)
Re:2.4ghz? (Score:3, Funny)
--RJ
Re:2.4ghz? (Score:2)
The Conclusion... (Score:5, Informative)
Re:The Conclusion... (Score:5, Insightful)
Thanks for the summary but can I just say I appreciate the level of detail and information provided. Way too many 'benchmarks' these days, especially those dealing with language performance are from some loser with their crappy home PC which they usually dont even know how to configure properly.
Its a relief to see a benchmark from someone competent and aware of the various factors affecting the results obtained.
Re:The Conclusion... (Score:3, Interesting)
I don't think it is puzzling at all (Score:5, Interesting)
Why is it puzzling? In their historic "Intel Inside" world, they were basically competing against themselves. Adding a bigger cache is not only easy, but a cheap way to rake in more cash without doing much R&D work.
It's not until recently that AMD has starting "schooling them" on what improvement really means. Just look at how Intel is going to use the AMD x86-64 method in the upcoming Intel 64bit platform. And now "If I were building (or, implausibly perhaps, buying) my ultimate workstation right now, I'd want a pair of Opteron 250s beating at the heart of it. The benchmarks speak volumes. For single-processor systems, the Opteron 150 looks like the fastest x86 CPU on the planet..." And this is at much lower mhz!
I believe Intel had thought they had reached monopoly status, which really they had, and the culture had become complacent. This did not happen at the underdog AMD, who has recently been able to quickly leapfrog Intel's offerings.
-Pete
Re:I don't think it is puzzling at all (Score:5, Insightful)
It's might be easy, but it isn't cheap to add more cache. Cache accounts for something like 50% of the die surface of a modern chip, and a larger die means a lower yield and less chips per wafer.
Re:I don't think it is puzzling at all (Score:3, Interesting)
Surely a pair of Xeons on shared bus ought to have this same advantage.
It's way easier to ramp up the bus speed for a single processor, since it only has to interact with one other device. It's considerably harder to increase the speed when there are three devices on the bus instead of only two. Since the Opteron uses point to point connections they don't have this same problem. In that sense it's not really puzzling at all. They pro
Re:I don't think it is puzzling at all (Score:5, Insightful)
You are forgetting a key deficiency of the P4 "netburst" architecture. Its incredibly long pipeline which makes it very susceptable to cache misses. Therefore the larger the L2 cache the less of a performance hit the processor will take if it misses an instruction or two.
It is possible that adding a bigger cache is 'cheap' but if that were the case we'd see a dramatic reduction in the price of P4EEs as they are getting schooled by AMDs. L2 Cache is not cheap to implement. And significantly adds to the manufacturing cost of the processor.
Additionally the lack of a FSB upgrade on the Xeons is troubling, but that apparantly is coming later this year, and this may reduce the advantage of the Opteron's to SOME degree. However, in the current architecture the Xeon's FSB bandwidth will always be shared - while the Opteron's get dedicated bandwidth for every processor. This is really the most remarkable advantage of 'Hammer' family of AMD CPUs over the Netburst generation of P4s/Xeons.
"I believe Intel had thought they had reached monopoly status, which really they had, and the culture had become complacent. This did not happen at the underdog AMD, who has recently been able to quickly leapfrog Intel's offerings."
Intel put a lot of money and R&D into a product line (P4 NetBurst) and honestly - even with AMD making inroads - they still do not have that large a share of the CPU market. Intel has however observed their lead eroding and have canned Tejas - successor to the Prescott. So Intel is able to step up and make the big changes even when it has sacrificed large amounts of R&D money.
Intel to formally confirm Tejas canned [theinquirer.net]
Intel may have canned Tejas... [theinquirer.net]
Re:I don't think it is puzzling at all (Score:3, Interesting)
You are forgetting a key deficiency of the P4 "netburst" architecture. Its incredibly long pipeline which makes it very susceptable to cache misses. Therefore the larger the L2 cache the less of a performance hit the processor will take if it misses an instruction or two.
I just finished a Computer Architecture class at the local university. While I'll probably forget 90% of what we learned in that class in another
Intel is competing as best they can (ie., poorly) (Score:3, Interesting)
Re:The Conclusion... (Score:3, Informative)
Re:The Conclusion... (Score:5, Interesting)
AMD got a little unconventional and this time it paid off on Opteron. It didn't work so well with the Athlon MP because of this wiring problem, too many wires, too expensive of a core chip, it was 1000+ pins when 600 pins was thought to be expensive.
Re:The Conclusion... Pimping (Score:2)
`-mfpmath=UNIT'
Generate floating point arithmetics for selected unit UNIT. The
choices for UNIT are:
`387'
Use the standard 387 floating point coprocessor present
majority of chips and emulated otherwise. Code compiled with
this option will run almost everywhere. The temporary
results are computed in 80bit precision instead of prec
Re:The Conclusion... Pimping (Score:2)
AMD are back (Score:5, Interesting)
Re:AMD are back (Score:5, Insightful)
--
New deal processing engine online: http://www.dealsites.net/livedeals.html [dealsites.net]
Re:AMD are back (Score:2)
Hence, hypertransport + On Chip Memory + efficient design all comming at once as opposed to intels slow and steady approach.
$0.1768 (hey I live in Canada.)
Re:AMD are back (Score:2)
Re:AMD are back (Score:3, Insightful)
I think that's an awesome strategic move! AMD had the insight to see that hey, here's a group of highly technical people that have some great ideas, and gee, we can hire them all.
Would rather have had AMD go "hmm, naaah, we don't need to hire guys with really creative and proven ideas, let's go reinvent the wheel"?
Thanks to their insight, hypertransport did not go the way of the dung heap, and superior processors design resulting in better performance, especially in multi-processor machines have resulte
Re:AMD is back (Score:2)
2.4 Rates as around PR3900+ (Score:5, Informative)
Glad to see AMD coming to the party. (Score:4, Insightful)
A. Are mainly concerned about the bottom line as far as price goes.
Which makes zero sense being AMD chips are more then competitivly priced compared to Intel.
B. Are supposedly in the know about technology.
Which is obviously not the case as many of them still think AMDs have the same cooling problems they did 5 years ago.
These chips are cheaper now then their Intel conterparts and from my experience run at the same speed if not faster. AMD is finally getting on the ball as far as putting the clock speed measured in Ghz to provide direct comparission which really needed to be done in order to compete. Combined with their dedication to inovation, i.e. the 64 bit processor that Intel has still yet to bring to market make me really suppport what the company is trying to do. I really hope to see more reviews like this that I can pass on to those in charge in hopes of getting away from an Intel only environment.
Just to clarify I do not hate Intel I just think that between the two there Intel does not always win outright and AMD should be considered before any purchases are ever made.
Re:Glad to see AMD coming to the party. (Score:2)
"You will definitly be fired for buying Intel"
But perhaps word just hasn't hit the market yet.
Re:Glad to see AMD coming to the party. (Score:2)
Compiling (Score:3, Insightful)
Re:Compiling (Score:4, Informative)
Here's [anandtech.com] one, for example.
(Of note, the Athlon FX-51 and -53 are identical to Opteron 148 and 150 processors, respectively. The Athlon 64s are similar as well, difference is they use a different socket, have only single-channel memory controllers, and use unbuffered/unregistered memory.)
Basically, the Hammers are godlike at compilation.
The lowest-rated (at the time; a 2800+ has since been released) A64 3000+ beats the fastest P4 3.4GHz Extreme Edition.
Waste of time... (Score:5, Insightful)
Re:Waste of time... (Score:2)
I wish all Intel/AMD chip benchmarks would include how they rate against the PowerPC.
Re:Waste of time... (Score:4, Informative)
Don't you ever read the BSD section?
-Jem
Re:Waste of time... (Score:2)
I could also test with GNU/Linux. SuSE makes a fine testing platform for 64 vs. 32.
-Jem
Re:Waste of time... (Score:2)
Personally, I think its a huge mistake. IF I had the money to start doing these types of reviews, that's exactly what I would do...use linux and bench against ppc as well as x86.
The reason is that linux is multi-architectural, unlike windows, a
Re:Waste of time... (Score:2)
Re:Waste of time... (Score:3, Interesting)
Not so fast, a significant problem in such a comparison is that gcc has *much* better support for x86-64 than it does for PPC64. If there was even a chance that a dual PPC970 machine was faster than a dual x86-64 machine, the likes of Yellow Dog [yellowdoglinux.com], and Momentum Computer [970eval.com] would have been all over it.
Sunny Dubey
Re:Waste of time... (Score:2)
Not so fast, a significant problem in such a comparison is that gcc has *much* better support for x86-64 than it does for PPC64.
Well, lots of reviews trashing ppc64 sounds like a good incentive for apple to help out the gcc project then. BTW, doesn't apple use gcc as the system compiler for OS X? In that case, you can't even dismiss gcc performance as only something those dirty GNU/hippies care about.
Re:Waste of time... (Score:2)
Maple/Mathematica benchies while at it... (Score:2, Informative)
Sad times when a
Dell Precision 650, 4X3.06GHz Xeon, 512KB L2, 4GB, Win XP Pro V5.1 [35]:
is slower than a
Athlon 2800+, 512 KB cache, 333 MHz FSB, Win XP Pro
A word of caution (Score:5, Informative)
I went to take the heat sink off the other day, and the vacuum that formed between the heat spreader and heat sink caused the chip to get yanked right out of the closed ZIF socket when I tried to get the heat sink off.
Then, after reinstalling the chip, apparently the heat spreader has become disconnected from the core internally, because the CMOS reports rising temperature up to 120C, but even the heat spreader isn't warm if I turn the system off and get the heat sink off again.
So be very careful. It takes about 10 minutes to take the heat sink off the heat spreader if you used a coating of grease that covers the whole top of the chip, even if you used a thin coat. You have to wiggle the heat sink and gently pull up for quite a while before that vacuum is broken. It doesn't help that the heat sink design makes it impossible to see the chip or slide the heat sink to the side.
And be aware that it doesn't take a whole lot of force to yank the chip right from the ZIF, possibly damaging things in the process.
Re:A word of caution (Score:5, Informative)
Exactly. (Score:2)
Actually (Score:2)
Re:A word of caution (Score:2)
Re:A word of caution (Score:3, Insightful)
AMD's Cool 'n Quiet (Score:5, Interesting)
I know I might be nitpicking here, but I really wish the Opteron series of chips incorporated AMD's Cool 'n Quite technology.
From what I read on their website, with a supporting motherboard and driver (2.6.5 has a native driver) the Athlon 64 can scale down to 800Mhz, cool enough for the system to shut the HSF and case fans completely offoff.
One demo I saw online had a Athlon 64 SFF computer playing a DVD while the AMD cool 'n quite app was shoing the the CPU at 80hz and the system was totally silent.
Coudn't server rooms benfit from the reduced electricuty bill also?
Re:AMD's Cool 'n Quiet (Score:2)
80Hz ????
Re:AMD's Cool 'n Quiet (Score:2)
Sorry for the typo.
Think of the power savings for those who like to leave their PC's on for filesharing or whatnot.
Would also make for a better nights sleep, if the ATX case is in your bedroom.
Re:AMD's Cool 'n Quiet (Score:2)
This is the reason I went with the A64. In trying to make the quietest system I could, the CnQ feature is great.
Re:AMD's Cool 'n Quiet (Score:2)
Great, but how fast can they compile the kernel? (Score:4, Funny)
Re:Great, but how fast can they compile the kernel (Score:2)
I remember the days when I could at least drink a good cup of coffee and catch up with the local newspaper while waiting for my kernel compile to finish...
Sigh...
Hmm.. Pushing the top end... (Score:3, Insightful)
My needs are simple, Most of my systems would do just fine with a Duron 800MHz or even slower CPUs. With the advent of new high end chips heralds lower prices at the low end.
It's gotten to the point where only a few popular niches need to even bother with anything but the absolute bottom end chips. I.e. Gaming, video encoding and servers (Faster chips mean more users on a server).
Scientific Computing clusters, Compiling lots of code everyday etc.. are other niches worth noteing. For Web browsing, Office productivity, educational apps and old games I advise you to buy the chip so far behind the curve it won't be available in a few weeks.
Re:Hmm.. Pushing the top end... (Score:2)
I realize it's partly due to the fact that far fewer companies manufacture the older RAM, but either way, paying high prices for outdated hardware seems kind of odd if you ask me...
Getting back to your original topic, another good thing about new CPUs getting faster is the
Re:Hmm.. Pushing the top end... (Score:2)
Question about itanium2 - Opteron (Score:2, Interesting)
Re:Question about itanium2 - Opteron (Score:2)
Re:Question about itanium2 - Opteron (Score:5, Informative)
Itanium servers are out of your league. A decent 1.5Ghz Itanium chip with 3Mb of on-die cache will set you back around $3,000. Not including memory, hard disks, etc. Just for ONE chip.
Xeon are way cheaper, but in most cases are more expensive than Opterons, do not scale very well when used in 2-way or higher configurations, and can only use 4Gb in flat mode. To access above 4Gb, you need to use PAE, which greatly hampers the performance (PAE is akin to the "high-memory" window trick they used back in the DOS days).
Opterons, on the other hand, are usually cheaper than Xeons, much cheaper than Itanium, almost always have better performance that Xeons, scale much better (in fact, a 2-way server performs better than a 1-way times 2!) and are only beat by Itanium in floating point performance, and then only barely.
There's another thing. Opterons are going to become dual-core in less than 2 years, with the same pinout as today. That means that if you have a lowly 2-way server that you're thinking about dumping, you can buy new dual-core Opterons and instantly get a 4-way out of your old 2-way server. Also, Opterons can access linearly up to 1Tb of physical RAM (that's 1,024 Gb), and up to 256Tb of virtual memory. And, finally, it's the only 64-bit processor you can get today that works with all your 32-bit x86 software. Finally, Opterons consume less energy than equivalent Xeons or Itaniums, and this becomes very important when thinking about A/C, UPS, standby power generators, etc.
I'd recommend you go with Opteron. Check out some well known tier-2 vendors such as Angstrom, Appro or Verari. They all make excellent quality Opteron servers and workstations. If you want brand names (and are willing to pay for it), check out Sun, Hewlett Packard or IBM for 2-way servers, or HP for a 4-way. IBM even has a dual Opteron workstation, if that's what you want.
Good Luck,
Marcos
Re:Question about itanium2 - Opteron (Score:5, Interesting)
Even if the pinouts stay the same, the system boards you can buy now might not support the processors being sold in 2 years.
Why upgrade the CPU only in 2 years and skip the other improvements available at that time?
I have very infrequently had a CPU upgrade that was worth it, while updating other components (disk, network, added RAM, video, ...) usually do give a reasonable boost. Most of the time the modest real performance increase from swapping in a new CPU -- one that is bound to the limits of the existing system board-bound -- isn't worth the time or money.
The only exception I can think of is if you buy behind the bleeding edge and upgrade every 6-9 months to a processor that is substantially better (2x) but not bleading edge.
To do this properly usually requires getting an advanced system board that can handle the higher end components and then turning around and being cheap on the CPU. While this can be a good idea, it usually isn't and the situation is very specific to the system board.
If you expect a payoff in a future upgrade, make sure that the hardware you buy now is also what you need today and do not depend on a future promise. If it works out, HOO-RA! If not, you haven't lost a thing.
Re:Question about itanium2 - Opteron (Score:5, Informative)
This problem does not arise however when we use 'double long' formats, or 64-bit floats, because these are way more precise and still can go a long way when 32-bit doubles already jump to zero, thus causing the problems.
On the x86 architecture, "long double" is 80-bit, and not 64-bit, which is plain "double". "float" is 32-bit.
However, note that the x86 does all floating point operations with 80-bit precision. So you don't get any performance advantage from using only single precision variables (other than lower memory bandwidth usage). Thus, a good rule of thumb is to always use double (long double might be better but isn't portable, and SSE doesn't support it if you want to use that). Single precision is mainly useful when you want to store large amounts of data (remember to cast the part of the data you're working on to double before calculating).
As others have pointed out, currently the Opteron is quite unbeatable in price/performance. 10000 EUR should certainly get you a 2 cpu system. Probably not 4 cpu:s though? Given that you need lots of memory, especially avoid the Xeon (or some other 32-bit architecture). Linux can only give 3 GB to one process with it's default configuration (I guess windows is similar?). With the so-called 4g/4g patch you can allow 4 GB for each process, but the price is lower performance. With a 64-bit architecture all those problems disappear.
Re:Question about itanium2 - Opteron (Score:2)
64bit AMD only benched with 32bit OS and software? (Score:4, Insightful)
Robert
For real 64bit performance visit VooDoo software tuning [nvidia.com] and download the 64bit 2004 Longsword Gamez Demo [unrealtournament.com]. The Download of UT2004 64-bit English Linux Demo [xs4all.nl] is around 200Mb.
But the price... (Score:5, Informative)
Re:But the price... (Score:2)
I would love to have a pair of opterons, but the prices are ridiculous.
Well, there are a couple of factors to consider. First, AMD is the only company right now that offers 64-bit x86. Second, the price is going to be pretty high since these were just released. Models that are a couple of notches down from top-of-the-line are better values. Third, these are server chips, so you should probably be wondering when dual processor Athlon64's will be coming out.
Re:But the price... (Score:3, Informative)
Re:But the price... (Score:2)
The regular A64 is much better bang for the buck, quite competive with P4. Not to mention the "old" Athlon XP's still here and still beats the living daylights of any other CPU on price/performance ratio.
Re:But the price... (Score:3, Insightful)
I've worked in the rendering graphics world where dropping $15k on an SGI, SUN, or ALPHA workstation in the past was nothing. The renderfarm alone was $3.2M of ALPHA servers back in the day.
Funny thing now is it was replaced last summer with $750k worth of IBM blade servers that nearly quadrupled the number of processors in half the space.
Anyway, AMD
Lots of performance variables.. (Score:2)
A benchmark with a Quad Opteron, like the Tyan Thunder K8QS [tyan.com] would be interesting. It has memory hanging off of each of the four CPU's. (Which opens a lot of questions about how that memory is managed.. Is there some sort of memory affinity per processor? What is the performance hit if one CPU needs
Re:Lots of performance variables.. (Score:2)
Which opens a lot of questions about how that memory is managed.. Is there some sort of memory affinity per processor?
It's called a NUMA. Google for the term and ye shall find.
The memory manager of the kernel has to take NUMA into account, or performance will suck.
Re:Lots of performance variables.. (Score:2)
I think of NUMA more like the BBN Butterfly I worked on in college, where many CPU boards are connected by a relatively slow bus, and each CPU board has its own locally addressed memory. So, each CPU is a node, and for any decent performance it must use its own local memory.
In the Opteron case, the memory is still relatively local, and based on the benchmarks in the article the performance hit for accessing another CPU's memory is not huge. In general, I
Re:Lots of performance variables.. (Score:2)
But, it's not a typical NUMA architecture, is it?
I'm no expert on this, but I guess you're right.
In the Opteron case, the memory is still relatively local, and based on the benchmarks in the article the performance hit for accessing another CPU's memory is not huge.
Remember that the Opteron has an on-chip memory manager (MMU). Consider a system with two cpus, CPU#0 and CPU#1. The architecture, AFAIK, is that each CPU has one HyperTransport link to its own memory, and another HyperTransport link to
Re:Lots of performance variables.. (Score:2)
Not quite.
MC = Memory Controller
Think CPU0 > FSB0 > MC0 > DDR
This is the same path as any system with a northbridge, except that the FSB runs at the same clock as the CPU, and is physically much shorter.
Connecting to another CPU is as follows:
MC = Memory/HyperTransport Controller
HT = HyperTransport
CPU0 > FSB0 > MC0 > HT > MC1 > DDR
Not as low-latency as a typical northbridge arrangement, but not bad.
Remember that memory ban
Power, Heat, Noise (Score:3, Informative)
Re:Power, Heat, Noise (Score:3, Informative)
Re:Power, Heat, Noise (Score:2)
Quad Opterons? (Score:2, Interesting)
Re:Think it's time to seriously consider AMD (Score:2)
Re:Think it's time to seriously consider AMD (Score:5, Informative)
It will be interesting to see how Intel responds to these challenges - c't speculates that the future Pentiums will use the architecture they have in the Pentium M line (developed in Israel). If they're smart they'll introduce a dual core CPU based on the Pentium M architecture, if AMD is smart they'll modify their existing designs and beat intel to the punch again.
Speaking as a business user, I'd welcome an emphasis on ergonomics and environmental concerns over raw speed. I'd rather have silent systems that do not overload the air conditioning with enormous amounts of heat than screamers which spend 99.9 % of their time waiting for the user to press a key anyway.
Re:Think it's time to seriously consider AMD (Score:2, Informative)
Funny enough, that is exactly what Intel has planned. They will also be shooting for dual-core, and then quad-core CPUs in the next 2-3 years.
Re:Think it's time to seriously consider AMD (Score:2)
Re:Think it's time to seriously consider AMD (Score:2)
It was faster than P2 in some things, but due to that FPU, even Celeron badly beat it in the one area that values speeds over anything - games.
K6-3 was fast, but they never managed to run it beyond 450MHz, and even that was too late.
And Pentium wasn't "same day", but previous generation, so of course it was slower. Nor were there any that were same speed, the last pentium was 233MHz and K6-2 started from 300.
Re:Ho Hum (Score:5, Insightful)
In a purely dollar/performance comparison, nothing beats x86.
Re:Ho Hum (Score:5, Insightful)
Something tells me if the billions of dollars per year in R&D were spent on a fully-RISC system, externally and internally, it would be much faster, saving a stage or two of decoding and other internal mangagement, saving a lot of design and testing hassles.
For over half a decade, DEC held its own against Intel with $70M / year CPU development budget, when Intel was spending $2B. They only got tripped up with poor marketing and problems and delays in fabbing the EV6 and EV7.
For one, being fully RISC made it far easier to validate the chip design because it didn't involve lots of work disassembling instructions and keeping track of the results, predicting properly and so on.
Re:Ho Hum (Score:2)
Go back... (Score:3, Informative)
If you want to make a computer performing anything close to modern standards, you're going to have to deal with interdependency of the RISC instructions anyway (pipelining,
Re:Ho Hum (Score:4, Insightful)
If PowerPC (for example) is SOOOO much better, why doesn't it wipe the floor with x86? Sure, it's competetive, but it does not annihilate x86
As to being register-starved... Again, that doesn't seem to hurt the performance of these chips that much. And if you use Opteron/Athlon64 with an 64bit OS, you get double the number of GP/SSE-registers (instead of 8, you get 16).
As to CISC... Modern x86-CPU's are very much RISCue in the inside. And being RISC does not automatically mean that it's somehow better. You can have kick-ass CISC-CPU's, and you can have crappy RISC-CPU's.
Re:Ho Hum (Score:2)
I am pretty sure that in any modern x86 design the actual operation of the processor's registers is virtualized and accessing them is no faster or slower than accessing cached stack memory.
Re:Ho Hum (Score:2)
Well, apparently x86 is crappy. It's "70's technology". If it's so damn crappy, why aren't any of the "better" CPU's wiping the floor with x86? I'm not talking about popularity here, I'm talking about performance. If x86 is so damn crappy, how come it performs so well with so lit
Re:Ho Hum (Score:2)
For some time, better CPUs did wipe the floor with the x86 family CPUs of their time, but didn't have the advantage of the Wintel monopoly. As for now... if you gave Intel's R&D budget to Motorola to spend on developing the PowerPC, I bet it would improve considerably.
Re:Ho Hum (Score:2)
Also the PPC isn't just suitable for running PS filters... it was always known as the best CPU for running emulators, for reasons I'll never know (hey I'm not a programmer nor did I even care to emulate old video games), plus it's always been a pretty respected CPU. I doubt the cost of the PPC is any higher than x86, but the rest of the Apple-unique ha
Re:Ho Hum (Score:2)
Why? Take a Linux distro (Gentoo), recompile it for both architectures, run some application benchmarks that represent what you typically do with your computer (i.e. an MP3/Ogg/Divx encoder, Mozilla, OpenOffice...). The thing is, x86 usually wins those types of comparisons. I think that was the point the parent was trying to make.
Re:Ho Hum (Score:3, Informative)
The Opterons have 1 MB (8 Mb) L2 cache where the G5 has .5 MB (4 Mb) L2.
At similar clockspeeds I think the performance is fairly similar, though the Opterons may do better in a dual-CPU configuration since they have on-chip memory controllers and thus more total memory bandwidth.
I'd like to see a head-to-head shootout using top compilers (an often overlo
Re:Ho Hum (Score:2)
You admitted it yourself - it's AMD/Intels fault. They make the chips. Blame them. Microsoft are as much to blame as Linus is in thi
Re:Ho Hum (Score:3, Insightful)
This aging architecture has maintained an incredible price/performance ratio. At this price level, the only thing that compares is the G5. A comparable UltraSPARC, Itanium, POWER, or PA-RISC system will cost much more.
As for registers, AMD64 doubled the number of general-purpose registers, which are already subject to register renaming.
Re:Ho Hum (Score:2)
Re:Ho Hum (Score:2)
Re:Ho Hum (Score:2, Interesting)
Re:OK so it has a nice metal cap (Score:2)
31 rows * 31 cols = 961
Pins missing at the four corners total 13 (3 at each corner plus an extra keying pin at the bottom right). There are 4 'gaps' of 2 pins missing within the grid itself. This means:
961 - 13 - 8 = 940 pins
Re:OK so it has a nice metal cap (Score:2)
Re:OK so it has a nice metal cap (Score:2)