Cell’s In-Order Architecture

We have mentioned that both the PPE and SPEs are in-order cores, but in order to understand the impact of an in-order core on performance, there’s a bit of background knowledge that we have to go over first.

Dependencies, Instruction Ordering and Parallelism

What are Dependencies?

In many of our past CPU articles, we’ve brought up this idea of dependencies as seen by the CPU.   At the very basic level, a CPU is fed a stream of instructions that are generally of the form:

OP destination, source1, source2, ... , source n

The instruction format will vary from one CPU ISA to the next, but the general idea is that the CPU is sent an operation (OP), a destination to store the result of the operation, and one or more sources on which to get data to perform the operation.   Depending on the architecture, the destination and sources can be memory locations or registers.   For the sake of simplicity, let’s just assume that for now, all destinations and sources are registers.

Let’s take a look at an example with some data filled in:

ADD R10, R1, R2

The above line of assembly would be sent to the CPU, telling it to add the values stored in R1 (Register #1) and R2 and store the result in R10.   Simple enough.   Now, let’s give the CPU another operation to crunch on:

MUL R11, R10, R3

This time, we’re multiplying the values stored in R10 and R3, and storing the result in R11.   As a single line of assembly, the above code is easily executed, but when placed directly after our first example, we’ve created a bit of a problem:
  1.      ADD R10, R1, R2
  2.      MUL R11, R10, R3
  3.      ADD R9, R11, R4
Line 1 writes to R10, while Line 2 reads from R10.   Under no circumstances can the CPU begin executing line 2 before line 1 completes - the same goes for lines 3 and 2.   What we’ve created here is what is known as a RAW dependency, Read After Write.   There are many more types of dependencies, but understanding this basic example is more than enough to take us to the next topic at hand - the impact of such dependencies.

The problem with a dependency is that it limits what can be executed in parallel.   Take the Athlon 64, for example.  It has three integer execution units, all of which are equally capable of executing the code (in a slightly revised, x86 assembly format, of course) that we used above.   In theory, the Athlon 64 could execute three lines integer operations in parallel at the same time - assuming that no dependencies existed between the operations.   In executing the above code, two of the Athlon 64’s integer execution units would go idle until the first line of code was executed.

Dependencies, such as the simple one that we talked about above, hinder the ability of modern day microprocessors to function to the best of their abilities.   It’s like having three hands, but only being able to clean your room by picking up one item at a time; frustratingly inefficient.

Cell's On-Die Memory Controller In-Order Architectures
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  • Houdani - Friday, March 18, 2005 - link

    I think I missed something fundamental.

    Can the SPEs be addressed directly by software, or do they have to be fed all of their instructions by the PPE?

    If they DO have to be fed be the PPE, I fail to see how the PPE can possibly feed them enough to keep them all working concurrently.

    Someone throw me a bone here.
  • suryad - Friday, March 18, 2005 - link

    I thought the G5 was a POWER5 proc. But I could of course be wrong. All I can say is the Cell definitely intriguing as it may be will have a rough road ahead of it and I am quite surprised that these large corporations invested so much in it, cutting edge though it might be. And as for the current forseeable future, I think when multi-core FX processors from AMD comes out, I do not believe there will be anything more devastating than that. Especially once they hit the 3 Ghz barrier with multi-cores enabled and faster DDR2-3 or even RAMBUS memory capabilities.
  • tipoo - Thursday, December 3, 2015 - link

    No, G5 was 970 based.
  • Questar - Friday, March 18, 2005 - link

    #50,
    Yes the G5 is a POWER4 derivitive.

    Since you were wrong on that, don't think that you know what is significant about the design of POWER5. There were major architechture changes made to the processor.
  • fitten - Friday, March 18, 2005 - link

    The only things new about Cell is its target market and being a single chip. The article mentions the TI DSP chip, but there were other similar architectures as well. One example that I'm familiar with is the MAP1310 board by CSPI. Back then, processes weren't good enough to put all the cores on a single chip but the basic architecture is the same - a PPC core to do the 'normal' stuff and two quad-core DSPs (SHARC) to do the 'work'. This board wasn't successful because it was considered too hard to program to get the performance it promised.... and this opinion is from people who live/breathe real-time systems and multiprocessing codes.

    The only thing new about Cell is that a) it's all on one chip now and b) the target market is a general marketplace and not a niche.
  • scrotemaninov - Friday, March 18, 2005 - link

    #48. OK, I was under the impression that the G5 was based on the POWER5. You're saying it's based on the POWER4 instead?

    And the POWER4 and POWER5 aren't really "completely different chips" in the same way that the P4 and P3 are different chips, or in the way that the P4 and the Opteron are different chips. I can give you a list of the differences if you want. Start at http://www.elet.polimi.it/upload/sami/architetture...

    The POWER5 is designed to not only be completely compatible with the POWER4 but to also to support all the optimisations from the POWER4. The only things of significance they've done is a) move the L3 cache controller on chip; b) change the various branch predictors to bimodal instead of 1-bit; c) increase the associativity and size of the caches.

    Anyway, this is going off topic now...
  • Jacmert - Friday, March 18, 2005 - link

    Rofl. Computer engineering and VLSI design. Gotta love those NMOS/PMOS transistor circuits.

    I never thought that I'd see stuff from my textbook explained on anandtech.com
  • saratoga - Friday, March 18, 2005 - link

    "#38. You're right that the G5 is a derivative of the POWER5. The POWER5 is dual core, each core with 2way SMT giving a total of 4 'visible' cpus to the OS. The G5 is simply a single core version of the same thing."

    Err no its not. POWER4 != POWER5. Hence the different names ;)

    They're completely different chips.

    "Well scrotemaninov I am not disputing that the POWER architecture by IBM is brilliantly done. IBM is definitely one of those companies churning out brilliant and elegant technology always in the background.

    But my problem with the POWER technology is from what I understand very limitedly, is that the POWER processors in the Mac machines are a derivative of that architecture right? Why the heck are they so damn slow then?

    I mean you can buy an AMD FX 55 based on the crappy legacy x86 arch and it smokes the dual 2.5 GHz Macs easily!! Is it cause of the OS? Because so far from what I have seen, if the Macs are any indication of the performance capabilities of the POWER architecture, the Cell will not be a big hit.

    I did read though at www.aceshardware.com benchmark reviews of the POWER5 architecture with some insane number of cores if I recall correctly and the benchmarks were of the charts. They are definitely not what the Macs have installed in them..."

    There are slow memeory systems and then theres the one used on the G5. I've heard that you can put 8 Opterons together and still get average access times across all 8 cores that are better then a single G5. Thats probably a good part of the reason the G5 was so much slower then many people thought it would be. The rest is mainly IBM's trouble making them, and their inability to ramp clock speed like they planned on.
  • scrotemaninov - Friday, March 18, 2005 - link

    #38. You're right that the G5 is a derivative of the POWER5. The POWER5 is dual core, each core with 2way SMT giving a total of 4 'visible' cpus to the OS. The G5 is simply a single core version of the same thing.

    As for the performance, Opteron is pretty much unbeatable for integer-bound applications. Itanium2 is unbeatable for FP applications. POWER5 is somewhere in the middle.

    Most desktop applications are going to be integer bound. So it's not at all surprising that you find the G5 'slow' in that respect in comparison to the FX55. Plus, and this is the whole problem with the CELL, there's no point putting dual CPUs in there unless you can utilise them properly. If you have one process going flat out trying to run a heavy application and it's single threaded then you're only using about 1/4 of the CPUs you've bought for that application (for a dual G5 2.5), whereas the Opterons and FX55 stuff is more designed around quick, single threaded applications.
  • dmens - Friday, March 18, 2005 - link

    psuedo-pmos wtf? That's domino logic, it's been around forever, and it's definitely not efficient in terms of power. Oh, and it takes forever to verify timing.

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