Itanium

Itanium
Central processing unit
Itanium2.png
Itanium 2 processor, 2003
Produced From mid 2001 to present
Common manufacturer(s) Intel
Max CPU clock 733 MHz to 1.66 GHz
FSB speeds 300 MHz to 667 MHz
Instruction set Itanium
Cores 1 or 2
Socket(s) PAC611
PAC418 (original Itanium)
Core name(s) McKinley

Madison
Hondo
Deerfield

Montecito

Itanium is the brand name for 64-bit Intel microprocessors that implement the Intel Itanium architecture (formerly called IA-64). Intel has released two processor families using the brand: the original Itanium and the Itanium 2. Starting November 1, 2007, new members of the second family are again called Itanium. The processors are marketed for use in enterprise servers and high-performance computing systems. The architecture originated at Hewlett-Packard (HP) and was later developed by HP and Intel together.

Itanium's architecture differs dramatically from the x86 architectures (and the x86-64 extensions) used in other Intel processors. The architecture is based on explicit instruction-level parallelism, in which the compiler makes the decisions about which instructions to execute in parallel. By contrast, other superscalar architectures depend on elaborate processor circuitry to keep track of instruction dependencies during runtime. This alternative approach helps current Itanium processors execute up to six instructions per clock cycle.

After a protracted development process, the first Itanium processor, codenamed Merced, was released in 2001, and more powerful Itanium processors have been released periodically. HP produces most Itanium-based systems, but several other manufacturers have also developed systems based on Itanium. As of 2007, Itanium is the fourth-most deployed microprocessor architecture for enterprise-class systems, behind x86-64, IBM POWER, and SPARC.[1] Intel released its newest Itanium, codenamed Montvale, in November 2007,[2] and has announced plans to release a quad-core Itanium processor (code-named Tukwila) to server OEMs in late 2008. Systems based on the new processor are expected to be available in early 2009,[3] more than a year later than Intel's initial projection.[4]

Contents

History

Itanium Server Sales forecast history.[5][6]

Development: 1989–2001

In 1989, HP determined that reduced instruction set computer (RISC) architectures were approaching a processing limit at one instruction per cycle. HP researchers investigated a new architecture, later named explicitly parallel instruction computing (EPIC), that allows the processor to execute multiple instructions in each clock cycle. EPIC implements a form of very long instruction word (VLIW) architecture, in which a single instruction word contains multiple instructions. With EPIC, the compiler determines in advance which instructions can be executed at the same time, so the microprocessor simply executes the instructions and does not need elaborate mechanisms to determine which instructions to execute in parallel.[7] The goal of this approach is two-fold: first, to enable deeper inspection of the code to identify additional opportunities for parallel execution; and, second, to simplify processor design and reduce energy consumption by eliminating the need for runtime scheduling circuitry.

HP determined that it was no longer cost-effective for individual enterprise systems companies such as itself to develop proprietary microprocessors, so HP partnered with Intel in 1994 to develop the IA-64 architecture, which derived from EPIC. Intel was willing to undertake a very large development effort on IA-64 in the expectation that the resulting microprocessor would be used by the majority of enterprise systems manufacturers. HP and Intel initiated a large joint development effort with a goal of delivering the first product, Merced, in 1998.[7]

During development, Intel, HP, and industry analysts predicted that IA-64 would dominate in servers, workstations, and high-end desktops, and eventually supplant RISC and complex instruction set computer (CISC) architectures for all general-purpose applications. Compaq and Silicon Graphics decided to abandon further development of the Alpha and MIPS architectures respectively in favor of migrating to IA-64.[8]

Several groups developed operating systems for the architecture, including Microsoft Windows, Linux, and UNIX variants such as HP-UX, Solaris,[9] [10] [11] Tru64 UNIX,[8] and Monterey/64[12] (the latter three were canceled before reaching the market). By 1997, it was apparent that the IA-64 architecture and the compiler were much more difficult to implement than originally thought, and the delivery of Merced began slipping.[13] Technical difficulties included the very high transistor counts needed to support the wide instruction words and the large caches. There were also structural problems within the project, as the two parts of the joint team used different methodologies and had slightly different priorities. Since Merced was the first EPIC processor, the development effort encountered more unanticipated problems than the team was accustomed to. In addition, the EPIC concept depends on compiler capabilities that had never been implemented before, so more research was needed.

Intel announced the official name of the processor, Itanium, on October 4, 1999.[14] Within hours the name Itanic [15] had been coined in an online chat room, a reference to Titanic, the "unsinkable" ocean liner which sank in 1912. Itanic has since often been used by The Register,[16] Scott McNealy,[17] and others,[18][19] implying that the multibillion dollar investment in Itanium—and the tremendous early hype—would be followed by its relatively quick demise.

Original Itanium processor: 2001–02

Original Itanium
Central processing unit
Itanium.png
Itanium processor
Produced From June 2001 to June 2002
Common manufacturer(s) Intel
Max CPU clock 733 MHz to 800 MHz
FSB speeds 266 MT/s
Instruction set Itanium
Socket(s) PAC418
Core name(s) Merced

By the time Itanium was released in June, 2001, it was no longer superior to contemporaneous RISC and CISC processors. Itanium competed at the low-end (primarily 4-CPU and smaller systems) with servers based on x86 processors, and at the high end with IBM's POWER architecture and Sun Microsystems' SPARC architecture. Intel repositioned Itanium to focus on high-end business and HPC computing, attempting to duplicate x86's successful "horizontal" market (i.e., single architecture, multiple systems vendors). The success of this initial processor version was limited to replacing PA-RISC and Alpha in HP systems and MIPS in SGI's HPC systems, though IBM also delivered a supercomputer based on this processor.[20] POWER and SPARC remained strong, while the 32-bit x86 architecture continued to grow into the enterprise space. With economies of scale fueled by its enormous installed base, x86 has remained the preeminent "horizontal" architecture in enterprise computing.

Only a few thousand systems using the original Itanium processor were sold, due to relatively poor performance, high cost and limited software availability.[21] Recognizing that the lack of software could be a serious issue moving forward, Intel made thousands of these early systems available to independent software vendors (ISVs) to stimulate development. HP and Intel brought the next-generation Itanium 2 processor to market a year later.

Itanium processor family
Original logo Version 2 logo 2006 logo 2008 new logo

Itanium 2 processors: 2002–present

The Itanium 2 processor was released in 2002, and was marketed for enterprise servers rather than for the whole gamut of high-end computing. The initial Itanium 2 was codenamed McKinley. McKinley was manufactured using a 180 nm process technology, and relieved many of the performance problems of the original Itanium processor.[22]

In 2003, AMD released the Opteron, which implemented its 64-bit architecture (x86-64). Opteron gained rapid acceptance in the enterprise server space because it provided an easy upgrade from x86. Intel responded by implementing x86-64 in its Xeon microprocessors in 2004.[8] Intel released a new Itanium 2 family member, codenamed Madison, in 2003. Madison used a 130 nm process and was the basis of all new Itanium processors until Montecito was released in June 2006.

In March, 2005, Intel announced that it was working on a new Itanium processor, codenamed Tukwila, to be released in 2007. Tukwila would have four processor cores and would replace the Itanium bus with a new Common System Interface, which would also be used by a new Xeon processor.[4] Intel later said that Tukwila would be delivered in late 2008.[23]

In November 2005, the major Itanium server manufacturers joined with Intel and a number of software vendors to form the Itanium Solutions Alliance to promote the architecture and accelerate software porting.[24] The Alliance announced that its members would invest $10 Billion in Itanium solutions by the end of the decade.[25]

In 2006, Intel delivered Montecito, a dual-core processor that roughly doubled performance and decreased energy consumption by about 20 percent. Quad-core Tukwila processors are still expected to be available to OEMs in late 2008, with systems reaching the marketplace in early 2009.[3]

In comparison with its Xeon family of server processors, Itanium is not a high-volume product for Intel. Intel does not release production numbers, but one industry analyst estimated that the production rate was 200,000 processors per year in 2007.[26] According to Gartner Inc., the total number of Itanium servers sold by all vendors in 2007 was about 55,000. This compares with 417,000 RISC servers (spread across all RISC vendors) and 8.4 million x86 servers. From 2001 through 2007, IDC reports that a total of 184,000 Itanium-based systems have been sold. For the combined POWER/SPARC/Itanium systems market, IDC reports that POWER captured 42% and SPARC captured 32%, while Itanium-based system revenue reached 26% in the second quarter of 2008.[27] According to an IDC analyst, HP currently accounts for perhaps 80% of Itanium systems revenue.[28]

Architecture

The Intel Itanium architecture

Intel has extensively documented the Itanium instruction set and microarchitecture,[29] and the technical press has provided overviews.[30][13] The architecture has been renamed several times during its history. HP originally called it PA-WideWord. Intel later called it IA-64, then Itanium Processor Architecture (IPA),[31] before settling on Intel Itanium Architecture, but it is still widely referred to as IA-64. It is a 64-bit register-rich explicitly-parallel architecture. The base data word is 64 bits, byte-addressable. The logical address space is 264 bytes. The architecture implements predication, speculation, and branch prediction. It uses a hardware register renaming mechanism rather than simple register windowing for parameter passing. The same mechanism is also used to permit parallel execution of loops. Speculation, prediction, predication, and renaming are under control of the compiler: each instruction word includes extra bits for this. This approach is the distinguishing characteristic of the architecture.

The architecture implements 128 integer registers, 128 floating point registers, 64 one-bit predicates, and eight branch registers. The floating point registers are 82 bits long to preserve precision for intermediate results.

Instruction execution

Each 128-bit instruction word contains three instructions, and the fetch mechanism can read up to two instruction words per clock from the L1 cache into the pipeline. When the compiler can take maximum advantage of this, the processor can execute six instructions per clock cycle. The processor has thirty functional execution units in eleven groups. Each unit can execute a particular subset of the instruction set, and each unit executes at a rate of one instruction per cycle unless execution stalls waiting for data. While not all units in a group execute identical subsets of the instruction set, common instructions can be executed in multiple units.

The execution unit groups include:

The compiler can often group instructions into sets of six that can execute at the same time. Since the floating-point units implement a multiply-accumulate operation, a single floating point instruction can perform the work of two instructions when the application requires a multiply followed by an add: this is very common in scientific processing. When it occurs, the processor can execute four FLOPs per cycle. For example, the 800 MHz Itanium had a theoretical rating of 3.2 GFLOPS and the fastest Itanium 2, at 1.67 GHz, was rated at 6.67 GFLOPS.

Memory architecture

From 2002 to 2006, Itanium 2 processors shared a common cache hierarchy. They had 16 KB[32] of Level 1 instruction cache and 16 KB of Level 1 data cache. The L2 cache was unified (both instruction and data) and is 256 KB. The Level 3 cache was also unified and varied in size from 1.5 MB[32] to 24 MB. The 256 KB L2 cache contains sufficient logic to handle semaphore operations without disturbing the main arithmetic logic unit (ALU).

Main memory is accessed through a bus to an off-chip chipset. The Itanium 2 bus was initially called the McKinley bus, but is now usually referred to as the Itanium bus. The speed of the bus has increased steadily with new processor releases. The bus transfers 2x128 bits per clock cycle, so the 200 MHz McKinley bus transferred 6.4 GB/s[33] and the 533 MHz Montecito bus transfers 17.056 GB/s[33].[34]

Architectural changes

Itanium processors released prior to 2006 had hardware support for the IA-32 architecture to permit support for legacy server applications, but performance for IA-32 code was much worse than for native code and also worse than the performance of contemporaneous x86 processors. In 2005, Intel developed the IA-32 Execution Layer (IA-32 EL), a software emulator that provides better performance. With Montecito, Intel therefore eliminated hardware support for IA-32 code.

In 2006, with the release of Montecito, Intel made a number of enhancements to the basic processor architecture including:[35]

Hardware support

Systems

Server Manufacturers' Itanium Products
Company latest product
name from to name CPUs
Compaq 2001 2001 Proliant 590 1-4
IBM 2001 2005 x455 1-16
Dell 2001 2005 PowerEdge 7250 1-4
HP 2001 now Integrity 1-128
SGI 2001 now Altix 4000 1-2048
Hitachi 2001 now BladeSymphony
1000		 1-8
Bull 2002 now NovaScale 1-32
Unisys 2002 now ES7000/one 1-32
NEC 2002 now Express5800
/1000		 1-32
Fujitsu 2005 now PRIMEQUEST 1-32

As of 2008, several manufacturers offer Itanium systems, including HP, SGI, NEC, Fujitsu, Unisys, Hitachi, and Groupe Bull. In addition, Intel offers a chassis[36] that can be used by system integrators to build Itanium systems. HP, the only one of the industry's top four server manufacturers to offer Itanium-based systems today, manufactures at least 80% of all Itanium systems. HP sold 7200 systems in the first quarter of 2006.[37] The bulk of systems sold are enterprise servers and machines for large-scale technical computing, with an average selling price per system in excess of US$200,000. A typical system uses eight or more Itanium processors.

Chipsets

The Itanium bus interfaces to the rest of the system via a chipset. Enterprise server manufacturers differentiate their systems by designing and developing chipsets that interface the processor to memory, interconnections, and peripheral controllers. The chipset is the heart of the system-level architecture for each system design. Development of a chipset costs tens of millions of dollars and represents a major commitment to the use of the Itanium. Currently, modern chipsets for Itanium are manufactured by HP, Fujitsu, SGI, NEC, Hitachi, and Unisys. IBM created a chipset in 2003, and Intel in 2002, but neither of them has developed chipsets to support newer technologies such as DDR2 or PCI Express.[38]

The upcoming Itanium processor (Tukwila) has been designed to share a common chipset with the Intel Xeon processor EX (Intel’s Xeon processor designed for four processor and larger servers). The goal is to provide system development and cost-saving synergies for server OEMs, many of whom develop both Itanium- and Xeon-based servers.

Software support

In order to allow more software to run on the Itanium, Intel supported the development of effective compilers for its platform, especially its own suite of compilers.[39][40] GCC,[41][42] Open64 and MS Visual Studio 2005 (and later)[43] are also able to produce machine code for Itanium. As of 2008, Itanium is supported by Windows Server 2003 and Windows Server 2008, multiple Linux distributions (including Debian, Red Hat and Novell SuSE), FreeBSD,[44] and HP-UX, OpenVMS, and NonStop from HP, all natively. HP also sells a virtualization technology for Itanium called Integrity Virtual Machines. Itanium also supports mainframe environment GCOS from Groupe Bull and several IA-32 operating systems via Instruction Set Simulators. Using QuickTransit, application binary software for IRIX/MIPS and Solaris/SPARC can run via "dynamic binary translation" on Linux/Itanium. According to the Itanium Solutions Alliance, as of early 2008, over 13,000 applications are available for Itanium based systems,[45] though Sun has contested Itanium application counts in the past.[46] The ISA also supports Gelato, an Itanium HPC user group and developer community that ports and supports open source software for Itanium.[47]

The software requirements for Itanium were criticized by Donald Knuth who said: "... The Itanium approach ... was supposed to be so terrific—until it turned out that the wished-for compilers were basically impossible to write" [1].

Competition

The Itanium 2 competes in the enterprise server and high-performance computing (HPC) markets. Itanium's major competitors include Sun Microsystems' UltraSPARC IV+, Fujitsu's SPARC64, IBM's POWER6, AMD's Opteron, and Intel's own Xeon servers.

Throughout its history, Itanium has had the best floating point performance relative to fixed-point performance of any general-purpose microprocessor. This capability is useful in HPC systems but is not needed for most enterprise server workloads.

By 2005, Itanium systems accounted for about 14% of HPC systems revenue, but the percentage has declined as the industry shifts to x86-64 clusters for this application.[48]

Supercomputers & HPC

Percentage of Top500 systems (x86 includes x86-64)

An Itanium-based computer first appeared on list of the TOP500 supercomputers in November 2001.[20] The best position ever achieved by an Itanium 2 based system in the list was #2, achieved in June 2004, when Thunder (LLNL) entered the list with an Rmax of 19.94 Teraflops. In November 2004, Columbia entered the list at #2 with 51.8 Teraflops, and there was at least one Itanium-based computer in the top 10 from then until June 2007. The peak number of Itanium-based machines on the list occurred in the November 2004 list, at 84 systems (16.8%); by November 2008, this had dropped to nine systems (1.8%).[49]

New Itanium implementations in high performance computing (HPC) are primarily for research areas (such as biochemical research) where typical workloads perform better on large, shared memory systems rather than distributed clusters. These systems typically have 16 to 64 processors, and are not comparable in size to the supercomputers on the TOP500 list.

Processors

Released processors

The Itanium processors show a steady progression in capability. Merced was a proof of concept. McKinley dramatically improved the memory hierarchy and allowed Itanium to become reasonably competitive. Madison, with the shift to a 130 nm process, allowed for enough cache space to overcome the major performance bottlenecks. Montecito, with a 90 nm process, allowed for a dual-core implementation and a major improvement in performance per watt. Montvale added three new features: core-level lockstep, demand-based switching and front-side bus frequency of up to 667 MHz.

Codename
process		 released Clock L2 Cache/
core[32]		 L3 Cache/
core[32]		 Bus dies/
device		 cores/
die		 watts/
device		 comments
Itanium
Merced
180 nm		 2001-06 733 MHz 96 KB none 266 MHz 1 1 116 2MB off-die L3 cache
800 MHz none 130 4MB off-die L3 cache
Itanium 2
McKinley
180 nm		 2002-07-08 900 MHz 256 KB 1.5 MB 400 MHz 1 1 130 HW branchlong
1 GHz 3 MB 130
Madison
130 nm		 2003-06-30 1.3 GHz 3 MB 130
1.4 GHz 4 MB 130
1.5 GHz 6 MB 130
2003-09-08 1.4 GHz 1.5 MB 130
2004-04 1.4 GHz 3 MB 130
1.6 GHz 3 MB 130
Deerfield
130 nm		 2003-09-08 1.0 GHz 1.5 MB 62 Low voltage
Hondo
130 nm		 2004-Q1 1.1 GHz 4 MB 400 MHz 2 1 260 32 MB L4
Fanwood
130 nm		 2004-11-08 1.6 GHz 3 MB 533 MHz 1 1 130
1.3 GHz 3 MB 400 MHz 62? Low voltage
Madison 9M
130 nm		 2004-11-08 1.6 GHz 9 MB 400 MHz 130
2005-07-05 1.67 GHz 6 MB 667 MHz 130
2005-07-18 1.67 GHz 9 MB 667 MHz 130
Montecito
90 nm		 2006-07-18 1.4 GHz 256 KB+
1 MB		 12 MB 400 MHz 1 2 104 Virtualization,
Multithread,
no HW IA-32
1.6 GHz 12 MB 533 MHz 1 2 104
Montvale
90 nm		 2007-10-31 1.66 GHz 4-18 MB 400-667 MHz 1 1-2 75-104 Core-level lockstep,
demand-based switching

Future processors

According to Gartner, "...the future roadmap for Itanium looks as strong as that of any RISC peer like Power or SPARC."[50] Based on available information, the future of the Itanium processor family apparently lies in multi-core chips. As of May 2008, some information is known for the following:

Timeline

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