- NetBurst (microarchitecture)
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The NetBurst microarchitecture, called P68 inside Intel, was the successor to the P6 microarchitecture in the x86 family of CPUs made by Intel. The first CPU to use this architecture was the Willamette core of the Pentium 4, released on November 20, 2000 and the first of the Pentium 4 CPUs; all subsequent Pentium 4 and Pentium D variants have also been based on NetBurst. In mid 2001, Intel released the Foster core, which was also based on NetBurst, thus switching the Xeon CPUs to the new architecture as well. Pentium 4-based Celeron CPUs also use the NetBurst architecture.
Contents
Technology
The NetBurst microarchitecture includes features such as Hyper Pipelined Technology and Rapid Execution Engine which are firsts in this particular microarchitecture.
Hyper Pipelined Technology
Intel chose this name for the 20-stage pipeline within the Willamette core. This is a significant increase in the number of stages when compared to the Pentium III, which had only 10 stages in its pipeline. The Prescott core has a 31-stage pipeline. Although a deeper pipeline has some disadvantages (primarily due to increased branch misprediction penalty) the greater number of stages in the pipeline allow the CPU to have higher clock speeds which was thought to offset any loss in performance. A smaller instructions per clock (IPC) is an indirect consequence of pipeline depth—a matter of design compromise (a small number of long pipelines has a smaller IPC than a greater number of short pipelines). Another drawback of having more stages in a pipeline is an increase in the number of stages that need to be traced back in the event that the branch predictor makes a mistake, increasing the penalty paid for a mis-prediction. To address this issue, Intel devised the Rapid Execution Engine and has invested a great deal into its branch prediction technology, which Intel claims reduces mis-predictions by 33% over Pentium III.[1]
Rapid Execution Engine
With this technology, the two ALUs in the core of the CPU are double-pumped, meaning that they actually operate at twice the core clock frequency. For example, in a 3.8 GHz processor, the ALUs will effectively be operating at 7.6 GHz. The reason behind this is to generally make up for the low IPC count; additionally this considerably enhances the integer performance of the CPU. Intel also replaced the high-speed barrel shifter with a shift/rotate execution unit that operates at the same frequency as the CPU core. The downside is that certain instructions are now much slower (relatively and absolutely) than before, making optimization for multiple target CPUs difficult. An example is shift and rotate operations, which suffer from the lack of a barrel shifter which was present on every x86 CPU beginning with the i386 (and is also present in the Athlon).
Execution Trace Cache
Within the L1 cache of the CPU, Intel incorporated its Execution Trace Cache. It stores decoded micro-operations, so that when executing a new instruction, instead of fetching and decoding the instruction again, the CPU directly accesses the decoded micro-ops from the trace cache, thereby saving considerable time. Moreover, the micro-ops are cached in their predicted path of execution, which means that when instructions are fetched by the CPU from the cache, they are already present in the correct order of execution.
Despite these enhancements, the NetBurst architecture created obstacles for engineers trying to scale up its performance. With this microarchitecture, Intel looked to attain clock speeds of 10 GHz, but because of rising clock speeds, Intel faced increasing problems with keeping power dissipation within acceptable limits. Intel reached a speed barrier of 3.8 GHz in November 2004 but encountered problems trying to achieve even that. Intel abandoned NetBurst in 2006 after the heat problems reached a level of severity and then developed Core microarchitecture, inspired by the P6 Core of the Pentium Pro to the Tualatin Pentium III-S and most directly the Pentium M.
Revisions
Main article: Pentium 4Revision Processor Brand(s) Pipeline stages Willamette (180 nm) Celeron, Pentium 4 20 Northwood (130 nm) Celeron, Pentium 4, Pentium 4 HT 20 Gallatin (130 nm) Pentium 4 HT Extreme Edition, Xeon 20 Prescott (90 nm) Celeron D, Pentium 4, Pentium 4 HT, Pentium 4 Extreme Edition 31 Cedar Mill (65 nm) Celeron D, Pentium 4 31 Smithfield (90 nm) Pentium D 31 Presler (65 nm) Pentium D 31 Intel replaced the original Willamette core with a redesigned version of the NetBurst microarchitecture called Northwood in January 2002. The Northwood design combined an increased cache size, a smaller 130 nm fabrication process, and Hyper-Threading Technology (although initially all models but the 3.06 GHz model had this feature disabled) to produce a more modern, higher-performing version of the NetBurst microarchitecture.
In February 2004, Intel introduced another, more radical revision of the microarchitecture codenamed Prescott. The Prescott core was produced on a 90 nm process, and included several major design changes, including the addition of an even larger cache (from 512 KB in the Northwood to 1 MB, and 2 MB in Prescott 2M), a much deeper instruction pipeline (31 stages as compared to 20 in the Northwood), a heavily improved branch predictor, the introduction of the SSE3 instructions, and later, the implementation of Intel 64, Intel's branding for their compatible implementation of the x86-64 64-bit version of the x86 microarchitecture (as with Hyper-Threading, all Prescott chips branded Pentium 4 HT have hardware to support this feature, but it was initially only enabled on the high-end Xeon processors, before being officially introduced in processors with the Pentium trademark). Despite having many new features, the Prescott often performed worse than a similarly-clocked Northwood, and many engineers felt that the real-world performance of the processor was compromised by attempting to achieve the highest clock speed possible.[citation needed] Power consumption and heat dissipation also became major issues with Prescott, which quickly became the hottest-running, and most power-hungry, of Intel's single-core x86 and x86-64 processors. Power and heat concerns have thus far prevented Intel from releasing a Prescott clocked above 3.8 GHz, along with a mobile version of the core clocked above 3.46 GHz.
Intel has also released a dual-core processor based on the NetBurst microarchitecture branded Pentium D. The first Pentium D core was codenamed Smithfield, which is actually two Prescott cores in a single die, and later Presler, which consists of two Cedar Mill cores on two separate dies (Cedar Mill being the 65 nm die-shrink of Prescott).
Successor
Intel has replaced NetBurst with the Core microarchitecture, released in July 2006, which is more directly derived from 1995's Pentium Pro than it is from NetBurst. August 8, 2008 marked the end of Intel NetBurst based processors.[citation needed] The reason for NetBurst's abandonment was the severe heat problems caused by high clock speeds. While Core- and Nehalem-based processors have higher TDPs, most processors are multi-core, so each core gives off a fraction of the maximum TDP, and the highest-clocked Core-based single-core processors give off a maximum of 27 W of heat. The fastest-clocked desktop Pentium 4 processors (single-core) had TDPs of 115 W, compared to 88 W for the fastest clocked mobile versions. Although, with the introduction of new steppings, TDPs for some models were eventually lowered.
Presler, a Pentium D core released in early 2006, is widely touted by analysts to be the last in the line of NetBurst, although the actual final NetBurst processor released was the Celeron D 365, which was released in 2007 and clocked at 3.6 GHz. The Conroe core of the first Intel Core 2 Duo processor, using the Core microarchitecture, is the successor to Presler.
The Nehalem microarchitecture, the successor to the Core microarchitecture, was actually supposed to be an evolution of NetBurst according to Intel roadmaps dating back to 2000. But due to NetBurst's abandonment, Nehalem is now a completely different project, but has some similarities with NetBurst. Nehalem reimplements the Hyper-threading Technology first introduced in the 3.06 GHz Northwood core of Pentium 4. Nehalem also implements an L3 cache in processors based on it. For a consumer processor implementation, an L3 cache was first used in the Gallatin core of Pentium 4 Extreme Edition, but was oddly missing from Prescott 2M core of the same brand.
NetBurst based chips
- Celeron (NetBurst)
- Celeron D
- Pentium 4
- Pentium 4 Extreme Edition
- Pentium D
- Pentium Extreme Edition
- Xeon, since 2001 through 2006
See also
- x86 architecture
- x86-64
- Replay system
- P5
- P6
- Core
- Nehalem
- Sandy Bridge
- List of Intel CPU microarchitectures
- List of Intel Celeron microprocessors
- List of Intel Pentium 4 microprocessors
- List of Intel Pentium D microprocessors
- List of Intel Xeon microprocessors
References
Intel processors Discontinued BCD oriented (4-bit) pre-x86 (8-bit) Early x86 (16-bit) x87 (external FPUs) IA-32 (32-bit) x86-64 (64-bit) Other Current Lists Microarchitectures P5 P5 based cores 800 nm - P5
600 nm - P54C
350 nm - P54CS
- P55C
250 nm - Tillamook
P6 P6 / Pentium M / Enhanced Pentium M based cores 500 nm 350 nm - P6
- Klamath
250 nm - Mendocino
- Dixon
- Tonga
- Covington
- Deschutes
- Katmai
- Drake
- Tanner
180 nm - Coppermine
- Coppermine T
- Timna
- Cascades
130 nm - Tualatin
- Banias
90 nm - Dothan
- Stealey
65 nm - Tolapai
- Yonah
- Sossaman
NetBurst NetBurst based cores 180 nm 130 nm 90 nm 65 nm Core Core / Penryn based cores 65 nm 45 nm - Penryn
- Penryn-QC
- Wolfdale
- Yorkfield
- Wolfdale-DP
- Harpertown
- Dunnington
Bonnell Bonnell based cores 45 nm - Silverthorne
- Diamondville
- Pineview
- Lincroft
- Tunnel Creek
- Sodaville
32 nm - Cedarview
- Cedar Trail-M
Nehalem Nehalem / Westmere based cores 45 nm - Clarksfield
- Lynnfield
- Jasper Forest
- Bloomfield
- Gainestown (Nehalem-EP)
- Beckton (Nehalem-EX)
32 nm - Arrandale
- Clarkdale
- Gulftown (Westmere-EP)
- Westmere-EX
Sandy Bridge Sandy Bridge / Ivy Bridge based cores 32 nm - Sandy Bridge
Future Categories:- Intel x86 microprocessors
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