The Haswell Review: Intel Core i7-4770K & i5-4670K Tested
by Anand Lal Shimpi on June 1, 2013 10:00 AM ESTThe Launch Lineup: Quad Cores For All
As was the case with the launch of Ivy Bridge last year, Intel is initially launching with their high-end quad core parts, and as the year passes on will progressively rollout dual cores, low voltage parts, and other lower-end parts. That means the bigger notebooks and naturally the performance desktops will arrive first, followed by the ultraportables, Ultrabooks and more affordable desktops. One change however is that Intel will be launching their first BGA (non-socketed) Haswell part right away, the Iris Pro equipped i7-4770R.
| Intel 4th Gen Core i7 Desktop Processors | ||||||
| Model | Core i7-4770K | Core i7-4770 | Core i7-4770S | Core i7-4770T | Core i7-4770R | Core i7-4765T |
| Cores/Threads | 4/8 | 4/8 | 4/8 | 4/8 | 4/8 | 4/8 |
| CPU Base Freq | 3.5 | 3.4 | 3.1 | 2.5 | 3.2 | 2.0 |
| Max Turbo | 3.9 (Unlocked) | 3.9 | 3.9 | 3.7 | 3.9 | 3.0 |
| Test TDP | 84W | 84W | 65W | 45W | 65W | 35W |
| HD Graphics | 4600 | 4600 | 4600 | 4600 | Iris Pro 5200 | 4600 |
| GPU Max Clock | 1250 | 1200 | 1200 | 1200 | 1300 | 1200 |
| L3 Cache | 8MB | 8MB | 8MB | 8MB | 6MB | 8MB |
| DDR3 Support | 1333/1600 | 1333/1600 | 1333/1600 | 1333/1600 | 1333/1600 | 1333/1600 |
| vPro/TXT/VT-d/SIPP | No | Yes | Yes | Yes | No | Yes |
| Package | LGA-1150 | LGA-1150 | LGA-1150 | LGA-1150 | BGA | LGA-1150 |
| Price | $339 | $303 | $303 | $303 | OEM | $303 |
Starting at the top of the product and performance stack, we have the desktop Core i7 parts. All of these CPUs feature Hyper-Threading Technology, so they’re the same quad-core with four virtual cores that we’ve seen since Bloomfield hit the scene. The fastest chip for most purposes remains the K-series 4770K, with its unlocked multiplier and slightly higher base clock speed. Base core clocks as well as maximum Turbo Boost clocks are basically dictated by the TDP, with the 4770S being less likely to maintain maximum turbo most likely, and the 4770T and 4765T giving up quite a bit more in clock speed in order to hit substantially lower power targets.
It’s worth pointing out that the highest “Test TDP” values are up slightly relative to the last generation Ivy Bridge equivalents—84W instead of 77W. Mobile TDPs are a different matter, and as we’ll discuss elsewhere they’re all 2W higher, but that is further offset by the improved idle power consumption Haswell brings.
Nearly all of these are GT2 graphics configurations (20 EUs), so they should be slightly faster than the last generation HD 4000 in graphics workloads. The one exception is the i7-4770R, which is also the only chip that comes in a BGA package. The reasoning here is simple if perhaps flawed: if you want the fastest iGPU configuration (GT3e with 40 EUs and embedded DRAM), you’re probably not going to have a discrete GPU and will most likely be purchasing an OEM desktop. Interestingly, the 4770R also drops the L3 cache down to 6MB, and it’s not clear whether this is due to it having no real benefit (i.e. the eDRAM functions as an even larger L4 cache), or if it’s to reduce power use slightly, or Intel may have a separate die for this particular configuration. Then again, maybe Intel is just busily creating a bit of extra market segmentation.
Not included in the above table are all the common features to the entire Core i7 line: AVX2 instructions, Quick Sync, AES-NI, PCIe 3.0, and Intel Virtualization Technology. As we’ve seen in the past, the K-series parts (and now the R-series as well) omit support for vPro, TXT, VT-d, and SIPP from the list. The 4770K is an enthusiast part with overclocking support, so that makes some sense, but the 4770R doesn’t really have the same qualification. Presumably it’s intended for the consumer market, as businesses are less likely to need the Iris Pro graphics.
| Intel 4th Gen Core i5 Desktop Processors | ||||||
| Model | Core i5-4670K | Core i5-4670 | Core i5-4670S | Core i5-4670T | Core i5-4570 | Core i5-4570S |
| Cores/Threads | 4/4 | 4/4 | 4/4 | 4/4 | 4/4 | 4/4 |
| CPU Base Freq | 3.4 | 3.4 | 3.1 | 2.3 | 3.2 | 2.9 |
| Max Turbo | 3.8 (Unlocked) | 3.8 | 3.8 | 3.3 | 3.6 | 3.6 |
| Test TDP | 84W | 84W | 65W | 45W | 84W | 65W |
| HD Graphics | 4600 | 4600 | 4600 | 4600 | 4600 | 4600 |
| GPU Max Clock | 1200 | 1200 | 1200 | 1200 | 1150 | 1150 |
| L3 Cache | 6MB | 6MB | 6MB | 6MB | 6MB | 6MB |
| DDR3 Support | 1333/1600 | 1333/1600 | 1333/1600 | 1333/1600 | 1333/1600 | 1333/1600 |
| vPro/TXT/VT-d/SIPP | No | Yes | Yes | Yes | Yes | Yes |
| Package | LGA-1150 | LGA-1150 | LGA-1150 | LGA-1150 | LGA-1150 | LGA-1150 |
| Price | $242 | $213 | $213 | $213 | $192 | $192 |
The Core i5 lineup basically rehashes the above story, only now without Hyper-Threading. For many users, Core i5 is the sweet spot of price and performance, delivering nearly all the performance of the i7 models at 2/3 the price. There aren’t any Iris or Iris Pro Core i5 desktop parts, at least not yet, and all of the above CPUs are using the GT2 graphics configuration. As above, the K-series part also lacks vPro/TXT/VT-d support but comes with an unlocked multiplier.
Obviously we’re still missing all of the Core i3 parts, which are likely to be dual-core once more, along with some dual-core i5 parts as well. These are probably going to come in another quarter, or at least a month or two out, as there’s no real need for Intel to launch their lower cost parts right now. Similarly, we don’t have any Celeron or Pentium Haswell derivatives launching yet, and judging by the Ivy Bridge rollout I suspect it may be a couple quarters before Intel pushes out ultra-budget Haswell chips. For now, the Ivy Bridge Celeron/Pentium parts are likely as low as Intel wants to go down the food chain for their “big core” architectures.
For those interested in the mobile side of things, we’ve broken out those parts into a separate Pipeline article.
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chizow - Saturday, June 1, 2013 - link
The other big problem with the CPU space besides the problems with power consumption and frequency, is the fact Intel has stopped using it's extra transistor budget from a new process node on the actual CPU portion of the die long ago. Most of the increased transistor budget afforded by a new process goes right to the GPU. We will probably not see a stop to this for some time until Intel reaches discrete performance equivalency.Jaybus - Monday, June 3, 2013 - link
Well, I don't know. Cache sizes have increased dramatically.chizow - Monday, June 3, 2013 - link
Not per core, these parts are still 4C 8MB, same as my Nehalem-based i7. Some of the SB-E boards have more cache per core, 4C 10MB on the 3820, 6C 15MB on the 3960/3970, but the extra bit results in a negligible difference over the 2MB per core on the 3930K.Boissez - Sunday, June 2, 2013 - link
I think you've misunderstood me.I'm merely pointing out that, in the past 2½ years we've barely seen any performance improvements in the 250-300$ market from Intel. And that is in stark contrast to the developments in mobileland. They too, are bound by the constraints you mention.
And please, stop the pompous know-it-all attitude. For the record, power consumption actually rises *linearly* with clock speed and *quadratically* with voltage. If your understanding of Joule's law and Ohm's law where better developed you would know.
klmccaughey - Monday, June 3, 2013 - link
Exactly. And it won't change until we see optical/biological chips or some other such future-tech breakthrough. As it is the electrons are starting to behave in light/waveform fashion at higher frequencies if I remember correctly from my semiconductor classes (of some years ago I might add).Jaybus - Monday, June 3, 2013 - link
Yes, but we will first see hybrid approaches. Intel, IBM, and others have been working on them and are getting close. Sure, optical interconnects have been available for some time, but not as an integrated on-chip feature which is now being called "silicon photonics". Many of the components are already there; micro-scale lenses, waveguides, and other optical components, avalanche photodiode detectors able to detect a very tiny photon flux, etc. All of those can be crafted with existing CMOS processes. The missing link is a cheaply made micro-scale laser.Think about it. An on-chip optical transceiver at THz frequencies allows optical chip-to-chip data transfer at on-chip electronic bus speeds, or faster. There is no need for L2 or L3 cache. Multiple small dies can be linked together to form a larger virtual die, increasing productivity and reducing cost. What if you could replace a 256 trace memory bus on a GPU with a single optical signal? There are huge implications both for performance and power use, even long before there are photonic transistors. Don't know about biological, but optical integration could make a difference in the not-so-far-off future.
tipoo - Saturday, June 1, 2013 - link
It's easier to move upwards from where ARM chips started a few years back. A bit like a developing economy showing growth numbers you would never see in a developed one.Genx87 - Saturday, June 1, 2013 - link
Interesting review. But finding it hard to justify replacing my i2500K. I guess next summer on the next iteration?kyuu - Saturday, June 1, 2013 - link
Agreed, especially considering Haswell seems to be an even poorer overclocker than Ivy Bridge. My i5-2500k @ 4.6GHz will be just fine for some time to come, it seems.klmccaughey - Monday, June 3, 2013 - link
Me too. I have a 2500k @ 4.3Ghz @ 1.28v and I am starting to wonder if even the next tick/tock will tempt me to upgrade.Maybe if they start doing a K chip with no onboard GPU and use the extra silicon for extra cores? Even then the cores aren't currently used well @ 4. But maybe concurrency adoption will increase as time goes by.