Haswell-E arrives, bringing a $999 8-core desktop CPU with it. Most of Intels announcements lately have focused on low-power chips, but every now and again it throws a bone to its high-end desktop users. Today were getting our first look at Haswell-E and a new Core i7 Extreme Edition CPU, a moniker reserved for the biggest and fastest of Intels consumer and workstation CPUs (if you want something faster than that, youll need to start looking at Xeons). We already got a little bit of information on these chips back in March, when Intel made announcements related to refreshed Haswell chips (Devils Canyon) and a handful of other desktop processors. Though much of todays information has already leaked, well run down the most important stuff for those of you who dont follow every leaked slide that makes its way to the public. Intel is announcing three new chips today, the specifications for which have all leaked at this point. There are two six-core processors: the first is the $389 Core i7-5820K, which runs at 3.3GHz and Turbo Boosts up to 3.6GHz. The second is the $583 i7-5930K, which runs at 3.5GHz and Turbo Boosts to 3.7GHz. Both include HyperThreading, 15MB of L3 cache, and the same 140W TDP. The main difference aside from clock speed is that the i7-5820K only includes 28 PCI Express 3.0 lanes instead of 40. This is still more than the 16 lanes youll get with quad-core desktop CPUs, but if you want a multi-card gaming rig the lower-end CPU may not be for you (otherwise it offers by far the best cost-to-performance ratio of any of these chips). Six-core chips were top-of-the-line in the Sandy Bridge and Ivy Bridge-E families, but Haswell-E adds more in the eight-core i7-5960X, a $999 CPU with a 3.0GHz clock speed, a 3.5GHz Turbo Boost speed, and 20MB of cache. In the Sandy and Ivy Bridge families, youd need to step up to EP or EX-class Xeon chips—some workstation manufacturers did just that, with the new Mac Pro being just one prominent example. The caveat with these chips are the same as they are for any CPU that adds cores to add speed: you really need to have a heavily multi-threaded workload to take advantage of the extra cores. Intels own slide deck focuses on workloads that benefit from this kind of thing—video editing, 3D rendering, and physics calculations. Intel estimates that the eight-core Haswell-E chip can covert video in Handbrake up to 34 percent faster than a six-core Ivy Bridge-E chip and up to 69 percent faster than a standard quad-core Ivy Bridge desktop chip (the i7-4790K, in this case.) For single-threaded or lightly-multithreaded tasks, youll actually lose a little bit of clock speed here compared to Intels top-end quad-core chips, so evaluate your workload carefully before you pull the trigger. Theres also a benefit for people who are doing GPU-intensive work, since 40 PCI Express 3.0 lanes can support up to three graphics cards all by themselves (two would have access to a full 16 lanes, while one would be restricted to eight). With additional components, you could add up to five GPUs (each with access to eight lanes.) Finally, all three CPUs come unlocked, so adventurous overclockers can try to squeeze a bit more performance out of them, though the regular Haswell platform hasnt exactly been known for its overclockability. In addition to the information about the chips themselves, heres what you need to know about the associated motherboards, sockets, and chipsets. Haswell-E brings with it another version of the LGA 2011 socket used for other high-end CPUs. The original LGA 2011 is used for Sandy Bridge and Ivy Bridge E and EP parts, and LGA 2011 v1 sockets were required for top-end Ivy Bridge-EX CPUs. Haswell-E uses LGA 2011 v3. As with the jump from Ivy Bridge to Haswell on consumer desktops, Ivy Bridge-E and Haswell-E parts wont be pin-compatible. We expect the majority of Ivy Bridge-E users arent going to be upgrading these systems every single year anyway, but its something new buyers should keep in mind as they piece together components. And speaking of new components, upgraders will need to throw out their DDR3 memory, too: Haswell-E is Intels first platform to integrate support for DDR4 RAM, which we first wrote about back in 2012. Like DDR2 and DDR3 before it, DDR4 reduces voltage while increasing speeds—you step down from 1.5V of power to 1.2V, and step up from 1866MHz to 2133MHz (though increased latency may eat up some of these gains). DDR4 is already available in faster speeds and will continue to pull away from DDR3 as the technology matures, but thats the fastest speed supported by Intels new platform as of this writing. Both the Haswell-E and Ivy Bridge-E platforms support quad-channel memory, where most desktops still use dual-channel. DDR4 will come with a bit of a price premium over DDR3, but at the rated clock speeds its not too big of a hit: a glance at Newegg shows 8GB sticks of DDR3-1866 starting at $82 and sticks of DDR4-2133 starting at $110. Thats an increase of around a third, though if youre already putting down the money for the CPU and the motherboard its probably not enough to make you flinch. Finally, the glue that holds all of these parts together is Intels X99 chipset, which supports most of the same features as the more down-to-earth Z97 and H97 chipsets announced earlier this year. The platform supports a total of 14 USB ports (six USB 3.0 ports), an Intel gigabit Ethernet port, eight additional PCI Express 2.0 lanes, integrated audio support, and a total of 10 SATA III ports. Unlike the Ivy Bridge-E platform, Haswell-E is able to support Thunderbolt 2.0, but your motherboard manufacturer will still need to integrate the dedicated controller to make that happen. Intel has a lengthy list of partners lined up for the Haswell-E launch, including complete system builders like Alienware, Falcon Northwest, and CyberpowerPC; and motherboard makers like Gigabyte, Asus, and MSI. Intel can usually drum up plenty of industry support for its new platforms, so this isnt much of a surprise. All in all it looks like a reasonably compelling update to Intels high-end workstation platform, though anyone still happy with their Sandy Bridge and Ivy Bridge-E setups wont need to run out to upgrade right away. This slide from Intel drives it home pretty well: The desktop space between 2003 and 2006 experienced a flurry of growth, going from the hot single-core Pentium 4 Extreme Edition to the quad-core Core 2 Extreme CPU. In those three years, Intel increased its chips instructions-per-clock, their core counts, and their power consumption. The quad-core CPU has a TDP of 130W, just 15W higher than the single-core Pentium 4. The improvements came more quickly, and they were easier to demonstrate. The four years between the Core 2 Extreme and the first six-core i7 chip look a lot quieter by comparison, not least because the late 2000s and early 2010s saw a big shift away from the desktop in the direction of mobile. Improving top-end performance was still important and it still increases year-to-year, but power consumption is the larger concern. A similar four-year gap separates the six-core Extreme Edition and todays eight-core version. The high-end desktop platform still improves every year; its just more difficult to tell the difference between last years performance and this years than it was a decade ago. ARS Technica.
Posted on: Mon, 01 Sep 2014 12:50:40 +0000
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