User:Honeydurga/IP, ARM, Xscale and PXA320

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Intellectual property

Intellectual property (IP) refers to creations of the mind: inventions, literary and artistic works, and symbols, names, images, and designs used in commerce. IP is divided into two categories:

• Industrial property, which includes inventions (patents), trademarks, industrial designs, and geographic indications of source; and
• Copyright: which includes architectural designs.

ARM Holdings

ARM Holdings is the world's leading semiconductor intellectual property (IP) supplier. The ARM business model involves the designing and licensing of IP rather than the manufacturing and selling of actual semiconductor chips. They licence IP to a network of Partners, which includes the world's leading semiconductor and systems companies. These Partners utilize ARM IP designs to create and manufacture system-on-chip designs, paying ARM a license fee for the original IP and a royalty on every chip or wafer produced. In addition to processor IP, ARM Holdings provide a range of tools, physical and systems IP to enable optimized system-on-chip designs. As of 2007, about 98 percent of the more than one billion mobile phones sold each year use at least one ARM processor. As of 2009, ARM processors account for approximately 90% of all embedded 32-bit RISC processors.

The ARM is a 32-bit reduced instruction set computer (RISC) instruction set architecture (ISA) developed by ARM Holdings. ARM processors are developed by ARM and by ARM licensees. Prominent ARM processor families developed by ARM Holdings include the ARM7, ARM9, ARM11 and Cortex. Notable ARM processors developed by licensees include DEC StrongARM, Freescale i.MX, Marvell (formerly Intel) XScale, Nintendo, Nvidia Tegra, ST-Ericsson Nomadik, Qualcomm Snapdragon, the Texas Instruments OMAP product line, the Samsung Hummingbird and the Apple A4.

ARM cores

ARM provides a summary of the numerous vendors who implement ARM cores in their design.^[1] KEIL also provides a somewhat newer summary of vendors of ARM based processors.^[2] ARM further provides a chart^[3] displaying an overview of the ARM processor lineup with performance and functionality versus capabilities for the more recent ARM7, ARM9, ARM11, Cortex-M, Cortex-R and Cortex-A device families.

ARM Family	ARM Architecture	ARM Core	Feature	Cache (I/D), MMU	Typical MIPS @ MHz
ARM1	ARMv1	ARM1	First implementation	None
ARM2	ARMv2	ARM2	ARMv2 added the MUL (multiply) instruction	None	4 MIPS @ 8 MHz 0.33 DMIPS/MHz
	ARMv2a	ARM250	Integrated MEMC (MMU), Graphics and IO processor. ARMv2a added the SWP and SWPB (swap) instructions.	None, MEMC1a	7 MIPS @ 12 MHz
ARM3	ARMv2a	ARM3	First integrated memory cache.	4 KB unified	12 MIPS @ 25 MHz 0.50 DMIPS/MHz
ARM6	ARMv3	ARM60	ARMv3 first to support 32-bit memory address space (previously 26-bit)	None	10 MIPS @ 12 MHz
		ARM600	As ARM60, cache and coprocessor bus (for FPA10 floating-point unit).	4 KB unified	28 MIPS @ 33 MHz
		ARM610	As ARM60, cache, no coprocessor bus.	4 KB unified	17 MIPS @ 20 MHz 0.65 DMIPS/MHz
ARM7	ARMv3	ARM700		8 KB unified	40 MHz
		ARM710	As ARM700, no coprocessor bus.	8 KB unified	40 MHz
		ARM710a	As ARM710	8 KB unified	40 MHz 0.68 DMIPS/MHz
ARM7TDMI	ARMv4T	ARM7TDMI(-S)	3-stage pipeline, Thumb	none	15 MIPS @ 16.8 MHz 63 DMIPS @ 70 MHz
		ARM710T	As ARM7TDMI, cache	8 KB unified, MMU	36 MIPS @ 40 MHz
		ARM720T	As ARM7TDMI, cache	8 KB unified, MMU with Fast Context Switch Extension	60 MIPS @ 59.8 MHz
		ARM740T	As ARM7TDMI, cache	MPU
ARM7EJ	ARMv5TEJ	ARM7EJ-S	5-stage pipeline, Thumb, Jazelle DBX, Enhanced DSP instructions	none
ARM8	ARMv4	ARM810[4]	5-stage pipeline, static branch prediction, double-bandwidth memory	8 KB unified, MMU	84 MIPS @ 72 MHz 1.16 DMIPS/MHz
StrongARM	ARMv4	SA-1	5-stage pipeline	16 KB/8–16 KB, MMU	203–206 MHz 1.0 DMIPS/MHz
ARM9TDMI	ARMv4T	ARM9TDMI	5-stage pipeline, Thumb	none
		ARM920T	As ARM9TDMI, cache	16 KB/16 KB, MMU with FCSE (Fast Context Switch Extension)[5]	200 MIPS @ 180 MHz
		ARM922T	As ARM9TDMI, caches	8 KB/8 KB, MMU
		ARM940T	As ARM9TDMI, caches	4 KB/4 KB, MPU
ARM9E	ARMv5TE	ARM946E-S	Thumb, Enhanced DSP instructions, caches	variable, tightly coupled memories, MPU
		ARM966E-S	Thumb, Enhanced DSP instructions	no cache, TCMs
		ARM968E-S	As ARM966E-S	no cache, TCMs
	ARMv5TEJ	ARM926EJ-S	Thumb, Jazelle DBX, Enhanced DSP instructions	variable, TCMs, MMU	220 MIPS @ 200 MHz,
	ARMv5TE	ARM996HS	Clockless processor, as ARM966E-S	no caches, TCMs, MPU
ARM10E	ARMv5TE	ARM1020E	6-stage pipeline, Thumb, Enhanced DSP instructions, (VFP)	32 KB/32 KB, MMU
		ARM1022E	As ARM1020E	16 KB/16 KB, MMU
	ARMv5TEJ	ARM1026EJ-S	Thumb, Jazelle DBX, Enhanced DSP instructions, (VFP)	variable, MMU or MPU
XScale	ARMv5TE	XScale	7-stage pipeline, Thumb, Enhanced DSP instructions	32 KB/32 KB, MMU	133–400 MHz
		Bulverde	Wireless MMX, Wireless SpeedStep added	32 KB/32 KB, MMU	312–624 MHz
		Monahans[6]	Wireless MMX2 added	32 KB/32 KB (L1), optional L2 cache up to 512 KB, MMU	up to 1.25 GHz
ARM11	ARMv6	ARM1136J(F)-S[7]	8-stage pipeline, SIMD, Thumb, Jazelle DBX, (VFP), Enhanced DSP instructions	variable, MMU	740 @ 532–665 MHz (i.MX31 SoC), 400–528 MHz
	ARMv6T2	ARM1156T2(F)-S	9-stage pipeline, SIMD, Thumb-2, (VFP), Enhanced DSP instructions	variable, MPU
	ARMv6ZK	ARM1176JZ(F)-S	As ARM1136EJ(F)-S	variable, MMU + TrustZone	965 DMIPS @ 772 MHz, up to 2 600 DMIPS with four processors[8]
	ARMv6K	ARM11 MPCore	As ARM1136EJ(F)-S, 1–4 core SMP	variable, MMU
Cortex-A	ARMv7-A	Cortex-A5[9]	VFP, NEON, Jazelle RCT, Thumb/Thumb-2, 1–4 cores	variable (L1 + L2), MMU + TrustZone	1.57 DMIPS / MHz per core
		Cortex-A8	VFP, NEON, Jazelle RCT, Thumb-2, 13-stage superscalar pipeline	variable (L1 + L2), MMU + TrustZone	up to 2 000 (2.0 DMIPS/MHz in speed from 600 MHz to greater than 1 GHz)
		Cortex-A9 MPCore	Application profile, VFPv3 FPU, NEON, Thumb-2, Jazelle RCT/DBX, out-of-order speculative issue superscalar, 1–4 core SMP	32 KB/32 KB L1, up to 4 MB L2, MMU + TrustZone	2.5 DMIPS/MHz per core, 10 000 DMIPS @ 2 GHz on Performance Optimized TSMC 40G (dual core)
		Cortex-A15 MPCore	Application profile, VFPv4 FPU, NEON, Thumb-2, Jazelle RCT/DBX, out-of-order speculative issue superscalar, Large Physical Address Extensions (LPAE), Hardware virtualization, 1–4 SMP cores	32 KB/32 KB L1, up to 4 MB L2, MMU + TrustZone
Cortex-R	ARMv7-R	Cortex-R4(F)	Real-time profile, Thumb-2, (FPU)	variable cache, MPU optional	600 DMIPS @ 475 MHz
Cortex-M	ARMv6-M	Cortex-M0	Microcontroller profile, Thumb-2 subset (16-bit Thumb instructions & BL, MRS, MSR, ISB, DSB, and DMB). Hardware multiply instruction optional	No cache.	0.9 DMIPS/MHz
		Cortex-M1	FPGA targeted, Microcontroller profile, Thumb-2 subset (16-bit Thumb instructions & BL, MRS, MSR, ISB, DSB, and DMB).	None, tightly coupled memory optional.	Up to 136 DMIPS @ 170 MHz[10] (0.8 DMIPS/MHz,[11] MHz achievable FPGA-dependent)
	ARMv7-M	Cortex-M3	Microcontroller profile, Thumb-2 only. Hardware divide instruction.	no cache, MPU optional.	125 DMIPS @ 100 MHz
	ARMv7-ME	Cortex-M4	Microcontroller profile, both Thumb and Thumb-2, FPU. Hardware MAC, SIMD and divide instructions.	MPU optional.	1.25 DMIPS/MHz
ARM Family	ARM Architecture	ARM Core	Feature	Cache (I/D), MMU	Typical MIPS @ MHz

Example applications of ARM cores

ARM Core	Devices	Products
ARM1	ARM1	ARM Evaluation System second processor for BBC Micro
ARM2	ARM2	Acorn Archimedes, Chessmachine
ARM250	ARM250	Acorn Archimedes
ARM3	ARM3	Acorn Archimedes
ARM60	ARM60	3DO Interactive Multiplayer, Zarlink GPS Receiver
ARM610	ARM610	Acorn Risc PC 600, Apple Newton 100 series
ARM700	ARM700	Acorn Risc PC prototype CPU card
ARM710	ARM710	Acorn Risc PC 700
ARM710a	ARM7100, ARM 7500 and ARM7500FE	Acorn Risc PC 700, Apple eMate 300, Psion Series 5 (ARM7100), Acorn A7000 (ARM7500), Acorn A7000+ (ARM7500FE), Network Computer (ARM7500FE)
ARM7TDMI(-S)	Atmel AT91SAM7, NXP Semiconductors LPC2000 and LH754xx, Actel CoreMP7	Game Boy Advance, Nintendo DS, Apple iPod, Lego NXT, Juice Box, Garmin Navigation Devices (1990s – early 2000s)
ARM710T		Psion Series 5mx, Psion Revo/Revo Plus/Diamond Mako
ARM720T	NXP Semiconductors LH7952x	Zipit Wireless Messenger
StrongARM	Digital SA-110, SA-1100, SA-1110	SA-110 Apple Newton 2x00 series, Acorn Risc PC, Rebel/Corel Netwinder, Chalice CATS SA-1100 Psion netBook SA-1110 LART (computer), Intel Assabet, Ipaq H36x0, Balloon2, Zaurus SL-5x00, HP Jornada 7xx, Jornada 560 series, Palm Zire 31
ARM810		Acorn Risc PC prototype CPU card
ARM920T	Atmel AT91RM9200, AT91SAM9, Cirrus Logic EP9302, EP9307, EP9312, EP9315, Samsung S3C2442 and S3C2410	Armadillo, GP32, GP2X (first core), Tapwave Zodiac (Motorola i.MX1), Hewlett-Packard HP-49/50 Calculators, Sun SPOT, HTC TyTN, FIC Neo FreeRunner[12]), Garmin Navigation Devices (mid–late 2000s), TomTom navigation devices[13]
ARM922T	NXP Semiconductors LH7A40x
ARM940T		GP2X (second core), Meizu M6 Mini Player[14][15]
ARM926EJ-S	Texas Instruments OMAP1710, OMAP1610, OMAP1611, OMAP1612, OMAP-L137, OMAP-L138; Qualcomm MSM6100, MSM6125, MSM6225, MSM6245, MSM6250, MSM6255A, MSM6260, MSM6275, MSM6280, MSM6300, MSM6500, MSM6800; Freescale i.MX21, i.MX27, Atmel AT91SAM9, NXP Semiconductors, Samsung S3C2412 LPC30xx, NEC C10046F5-211-PN2-A SoC – undocumented core in the ATi Hollywood graphics chip used in the Wii,[16] Telechips TCC7801, TCC7901, ZiiLABS ZMS-05, Rockchip RK2806 and RK2808, NeoMagic MiMagic Family MM6, MM6+, MM8, MTV.	Mobile phones: Sony Ericsson (K, W series); Siemens and Benq (x65 series and newer); LG Arena; GPH Wiz; Squeezebox Duet Controller (Samsung S3C2412). Squeezebox Radio; Buffalo TeraStation Live (NAS); Drobo FS (NAS); Western Digital MyBook I World Edition; Western Digital MyBook II World Edition; Seagate FreeAgent DockStar STDSD10G-RK; Seagate FreeAgent GoFlex Home; Chumby Classic
ARM946E-S		Nintendo DS, Nokia N-Gage, Canon PowerShot A470, Canon EOS 5D Mark II,[17] Conexant 802.11 chips, Samsung S5L2010
ARM966E-S	STMicroelectronics STR91xF[18]
ARM968E-S	NXP Semiconductors LPC29xx
ARM1026EJ-S	Conexant so4610 and so4615 ADSL SoC
XScale	Intel 80200, 80219, PXA210, PXA250, PXA255, PXA263, PXA26x, PXA27x, PXA3xx, PXA900, IXC1100, IXP42x	80219 Thecus N2100 IOP321 Iyonix PXA210/PXA250 Zaurus SL-5600, iPAQ H3900, Sony CLIÉ NX60, NX70V, NZ90 PXA255 Gumstix basix & connex, Palm Tungsten E2, Zaurus SL-C860, Mentor Ranger & Stryder, iRex ILiad PXA263 Sony CLIÉ NX73V, NX80V PXA26x Palm Tungsten T3 PXA27x Gumstix verdex, "Trizeps-Modules", "eSOM270-Module" PXA270 COM, HTC Universal, HP hx4700, Zaurus SL-C1000, 3000, 3100, 3200, Dell Axim x30, x50, and x51 series, Motorola Q, Balloon3, Trolltech Greenphone, Palm TX, Motorola Ezx Platform A728, A780, A910, A1200, E680, E680i, E680g, E690, E895, Rokr E2, Rokr E6, Fujitsu Siemens LOOX N560, Toshiba Portégé G500, Trēo 650-755p, Zipit Z2, HP iPaq 614c Business Navigator, I-mate PDA2 PXA3XX Samsung Omnia PXA900 Blackberry 8700, Blackberry Pearl (8100) IXP42x NSLU2
ARM1136J(F)-S	Texas Instruments OMAP2420, Qualcomm MSM7200, MSM7201A, MSM7227, Freescale i.MX31 and MXC300-30	OMAP2420 Nokia E90, Nokia N93, Nokia N95, Nokia N82, Zune, BUGbase[19], Nokia N800, Nokia N810 MSM7200 Eten Glofiish, HTC TyTN II, HTC Nike Freescale i.MX31 original Zune 30 GB, Toshiba Gigabeat S and Kindle DX Freescale MXC300-30 Nokia E63, Nokia E71, Nokia 5800, Nokia E51, Nokia 6700 Classic, Nokia 6120 Classic, Nokia 6210 Navigator, Nokia 6220 Classic, Nokia 6290, Nokia 6710 Navigator, Nokia 6720 Classic, Nokia E75, Nokia N97, Nokia N81 Qualcomm MSM7201A HTC Dream, HTC Magic, Motorola i1, Motorola Z6, HTC Hero, Samsung SGH-i627 (Propel Pro), Sony Ericsson Xperia X10 Mini Pro Qualcomm MSM7227 ZTE Link,[20][21]
ARM1176JZ(F)-S	Conexant CX2427X, Nvidia GoForce 6100;[22] Telechips TCC9101, TCC9201, TCC8900, Fujitsu MB86H60, Samsung S3C6410, S3C6430,[23] Qualcomm MSM7627, Infineon X-GOLD 213	Apple iPhone (original and 3G), Apple iPod touch (1st and 2nd Generation), Motorola RIZR Z8, Motorola RIZR Z10, Nintendo 3DS S3C6410 Samsung Omnia II, Samsung Moment, SmartQ 5, Tablet PC Qualcomm MSM7627 Palm Pixi and Motorola Calgary/Devour
ARM11 MPCore	Nvidia APX 2500 (Tegra)
Cortex-A8	Texas Instruments OMAP3xxx series, FreeScale i.MX51-SOC, Apple A4, ZiiLABS ZMS-08, Samsung Hummingbird S5PC110 , Qualcomm Snapdragon QSD8x50(A)/MSM7x30/MSM8255	HTC Desire, SBM7000, Oregon State University OSWALD, Gumstix Overo Earth, Pandora, Apple iPhone 3GS, Apple iPod touch (3rd and 4th Generation), Apple iPad (A4), Apple iPhone 4 (A4), Archos 5, BeagleBoard, Motorola Droid, Motorola Droid X, Motorola Droid 2, Motorola Droid R2D2 Edition, Palm Pre, Samsung Omnia HD, Samsung Wave S8500, Samsung i9000 Galaxy S, Sony Ericsson Satio, Touch Book, Nokia N900, Meizu M9, Google Nexus S, Sharp PC-Z1 "Netwalker".
Cortex-A9	Texas Instruments OMAP4430/4440, ST-Ericsson U8500 / U5500, Nvidia Tegra2, Qualcomm Snapdragon QSD8672/MSM8260/MSM8660, Samsung Orion, STMicroelectronics SPEAr1310, Xilinx Extensible Processing Platform,[24] Trident PNX847x/8x/9x STB SoC,[25] Freescale i.MX6 [26]	LG Optimus 2X, Motorola Atrix 4G,Motorola DROID BIONIC
Cortex-A15	Qualcomm Snapdragon MSM8270/MSM8960, Texas Instruments OMAP5, Samsung, ST Ericsson[27] Nvidia
Cortex-R4(F)	Broadcom, Texas Instruments TMS570
Cortex-M0	NXP Semiconductors LPC11xx,[28] Triad Semiconductor,[29] Melfas,[30] Chungbuk Technopark,[31] Nuvoton,[32] austriamicrosystems,[33] Rohm[34]
Cortex-M1	Actel ProASIC3, ProASIC3L, IGLOO and Fusion PSC devices, Altera Cyclone III, other FPGA products are also supported e.g. Synplicity[35]
Cortex-M3	Texas Instruments Stellaris, STMicroelectronics STM32, NXP Semiconductors LPC17xx, Toshiba TMPM330[36], Ember EM3xx, Atmel AT91SAM3, Europe Technologies EasyBCU, Energy Micro EFM32, Actel SmartFusion, mbed microcontroller
Cortex-M4	Freescale Kinetis, NXP Semiconductors LCP4300, STMicroelectronics
ARM Core	Devices	Products

Architecture

From 1995 onwards, the ARM Architecture Reference Manual has been the primary source of documentation on the ARM processor architecture and instruction set, distinguishing interfaces that all ARM processors are required to support (such as instruction semantics) from implementation details that may vary. The architecture has evolved over time, and starting with the Cortex series of cores, three "profiles" are defined:

• "Application" profile: Cortex-A series
• "Real-time" profile: Cortex-R series
• "Microcontroller" profile: Cortex-M series

Profiles are allowed to subset the architecture. For example the ARMv7-M profile used by the Cortex-M3 core is notable in that it supports only the Thumb-2 instruction set, and the ARMv6-M profile (used by the Cortex-M0) is a subset of the ARMv7-M profile (supporting fewer instructions).

Pipelines and other implementation issues

The ARM7 and earlier implementations have a three stage pipeline; the stages being fetch, decode, and execute. Higher performance designs, such as the ARM9, have deeper pipelines: Cortex-A8 has thirteen stages. Additional implementation changes for higher performance include a faster adder, and more extensive branch prediction logic. The difference between the ARM7DI and ARM7DMI cores, for example, was an improved multiplier (hence the added "M").

Coprocessors

The architecture provides a non-intrusive way of extending the instruction set using "coprocessors" which can be addressed using MCR, MRC, MRRC, MCRR, and similar instructions. The coprocessor space is divided logically into 16 coprocessors with numbers from 0 to 15, coprocessor 15 (cp15) being reserved for some typical control functions like managing the caches and MMU operation (on processors that have one).

In ARM-based machines, peripheral devices are usually attached to the processor by mapping their physical registers into ARM memory space or into the coprocessor space or connecting to another device (a bus) which in turn attaches to the processor. Coprocessor accesses have lower latency so some peripherals (for example XScale interrupt controller) are designed to be accessible in both ways (through memory and through coprocessors). In other cases, chip designers only integrate hardware using the coprocessor mechanism. For example, an image processing engine might be a small ARM7TDMI core combined with a coprocessor that has specialized operations to support a specific set of HDTV transcoding primitives.

Debugging

All modern ARM processors include hardware debugging facilities; without them, software debuggers could not perform basic operations like halting, stepping, and breakpointing of code starting from reset. These facilities are built using JTAG support, though some newer cores optionally support ARM's own two-wire "SWD" protocol. In ARM7TDMI cores, the "D" represented JTAG debug support, and the "I" represented presence of an "EmbeddedICE" debug module. For ARM7 and ARM9 core generations, EmbeddedICE over JTAG was a de-facto debug standard, although it was not architecturally guaranteed.

The ARMv7 architecture defines basic debug facilities at an architectural level. These include breakpoints, watchpoints, and instruction execution in a "Debug Mode"; similar facilities were also available with EmbeddedICE. Both "halt mode" and "monitor" mode debugging are supported. The actual transport mechanism used to access the debug facilities is not architecturally specified, but implementations generally include JTAG support.

There is a separate ARM "CoreSight" debug architecture, which is not architecturally required by ARMv7 processors.

DSP enhancement instructions

To improve the ARM architecture for digital signal processing and multimedia applications, a few new instructions were added to the set.^[37] These are signified by an "E" in the name of the ARMv5TE and ARMv5TEJ architectures. E-variants also imply T,D,M and I.

The new instructions are common in digital signal processor architectures. They are variations on signed multiply-accumulate, saturated add and subtract, and count leading zeros.

Thumb

To improve compiled code-density, processors since the ARM7TDMI have featured the Thumb instruction set state. (The "T" in "TDMI" indicates the Thumb feature.) When in this state, the processor executes the Thumb instruction set, a variable-length instruction set providing 32-bit and 16-bit instructions. Most of the Thumb instructions are directly mapped to normal ARM instructions. The space-saving comes from making some of the instruction operands implicit and limiting the number of possibilities compared to the ARM instructions executed in the ARM instruction set state.

In Thumb, the 16-bit opcodes have less functionality. For example, only branches can be conditional, and many opcodes are restricted to accessing only half of all of the CPU's general purpose registers. The shorter opcodes give improved code density overall, even though some operations require extra instructions. In situations where the memory port or bus width is constrained to less than 32 bits, the shorter Thumb opcodes allow increased performance compared with 32-bit ARM code, as less program code may need to be loaded into the processor over the constrained memory bandwidth.

Embedded hardware, such as the Game Boy Advance, typically have a small amount of RAM accessible with a full 32-bit datapath; the majority is accessed via a 16 bit or narrower secondary datapath. In this situation, it usually makes sense to compile Thumb code and hand-optimise a few of the most CPU-intensive sections using full 32-bit ARM instructions, placing these wider instructions into the 32-bit bus accessible memory.

The first processor with a Thumb instruction decoder was the ARM7TDMI. All ARM9 and later families, including XScale, have included a Thumb instruction decoder.

VFP

VFP (Vector Floating Point) technology is a coprocessor extension to the ARM architecture. It provides low-cost single-precision and double-precision floating-point computation fully compliant with the ANSI/IEEE Std 754-1985 Standard for Binary Floating-Point Arithmetic. VFP provides floating-point computation suitable for a wide spectrum of applications such as PDAs, smartphones, voice compression and decompression, three-dimensional graphics and digital audio, printers, set-top boxes, and automotive applications. The VFP architecture also supports execution of short vector instructions but these operate on each vector element sequentially and thus do not offer the performance of true SIMD (Single Instruction Multiple Data) parallelism. This mode can still be useful in graphics and signal-processing applications, however, as it allows a reduction in code size and instruction fetch and decode overhead.

Other floating-point and/or SIMD coprocessors found in ARM-based processors include FPA, FPE, iwMMXt. They provide some of the same functionality as VFP but are not opcode-compatible with it.

Advanced SIMD (NEON)

The Advanced SIMD extension, marketed as NEON technology, is a combined 64- and 128-bit single instruction multiple data (SIMD) instruction set that provides standardized acceleration for media and signal processing applications. NEON can execute MP3 audio decoding on CPUs running at 10 MHz and can run the GSM AMR (Adaptive Multi-Rate) speech codec at no more than 13 MHz. It features a comprehensive instruction set, separate register files and independent execution hardware. NEON supports 8-, 16-, 32- and 64-bit integer and single-precision (32-bit) floating-point data and operates in SIMD operations for handling audio and video processing as well as graphics and gaming processing. In NEON, the SIMD supports up to 16 operations at the same time. The NEON hardware shares the same floating-point registers as used in VFP.

Operating systems

Acorn systems

The very first ARM-based Acorn Archimedes personal computers ran an interim operating system called Arthur, which evolved into RISC OS, used on later ARM-based systems from Acorn and other vendors.

Embedded operating systems

The ARM architecture is supported by a large number of embedded and real-time operating systems, including Windows CE, Symbian OS, FreeRTOS, eCos, INTEGRITY, Nucleus PLUS, MicroC/OS-II, QNX, RTXC Quadros, ThreadX and VxWorks.^[38]

Unix-like

The ARM architecture is supported by Unix and Unix-like operating systems such as GNU/Linux, BSD, Plan 9 from Bell Labs, Inferno, Solaris, Apple iOS, WebOS and Android.

Linux

The following Linux distributions support ARM processors:

• Arch Linux^[39]
• Ångström
• Chrome OS
• DSLinux
• Debian^[40]
• ELinOS^[41]
• Fedora^[42]
• Gentoo^[43]
• GoboLinux^[44]
• iPodLinux
• Maemo
• MeeGo
• MontaVista^[45]
• Slackware^[46]
• T2 SDE^[47]
• Ubuntu^[48][49]
• webOS
• Wind River Linux^[50]

BSD

The following BSD derivatives support ARM processors:

• RISC iX (Acorn ARM2/ARM3-based systems only)
• FreeBSD^[51]
• NetBSD^[52]
• OpenBSD^[53]
• iOS

Solaris

• OpenSolaris^[54]

Windows

Microsoft announced on 5 January 2011 that the next major version of the Windows NT family will include support for ARM processors. Microsoft demonstrated a preliminary version of Windows (version 6.2.7867) running on an ARM-based computer at the 2011 Consumer Electronics Show.<ref name="windows-ces2011">Microsoft demonstrates early build of Windows 8

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