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ARMv8

ARM architectures
ARM logo.svg
The ARM logo
Designer ARM Holdings
Bits 32-bit, 64-bit
Introduced 1985; 32 years ago (1985)
Design RISC
Type Register-Register
Branching Condition code, compare and branch
Open Proprietary
64/32-bit architecture
Introduced 2011
Version ARMv8-A, ARMv8.1-A, ARMv8.2-A
Encoding AArch64/A64 and AArch32/A32 use 32-bit instructions, T32 (Thumb-2) uses mixed 16- and 32-bit instructions. ARMv7 user-space compatibility
Endianness Bi (little as default)
Extensions All mandatory: Thumb-2, NEON, Jazelle, VFPv4-D16, VFPv4
Registers
General purpose 31× 64-bit integer registers
Floating point 32× 128-bit registers for scalar 32- and 64-bit FP or SIMD FP or integer; or cryptography
32-bit architectures (Cortex)
Version ARMv8-R, ARMv8-M, ARMv7-A, ARMv7-R, ARMv7E-M, ARMv7-M, ARMv6-M
Encoding 32-bit except Thumb-2 extensions use mixed 16- and 32-bit instructions.
Endianness Bi (little as default); Cortex-M is fixed and can't change on the fly.
Extensions Thumb-2, NEON, Jazelle, DSP, Saturated, FPv4-SP, FPv5
Registers
General purpose 15× 32-bit integer registers; R15 is PC (26-bit addressing in older), R14 is link register.
Floating point Up to 32× 64-bit registers, SIMD/floating-point (optional)
32-bit architectures (legacy)
Version ARMv6, ARMv5, ARMv4T, ARMv3, ARMv2
Encoding 32-bit except Thumb extension uses mixed 16- and 32-bit instructions.
Endianness Bi (little as default) in ARMv3 and above
Extensions Thumb, Jazelle
Registers
General purpose 15× 32-bit integer registers; R15 is PC (26-bit addressing in older), R14 is link register.

ARM, originally Acorn RISC Machine, later Advanced RISC Machine, is a family of reduced instruction set computing (RISC) architectures for computer processors, configured for various environments. British company ARM Holdings develops the architecture and licenses it to other companies, who design their own products that implement one of those architectures—​​including systems-on-chips (SoC) that incorporate memory, interfaces, radios, etc. It also designs cores that implement this instruction set and licenses these designs to a number of companies that incorporate those core designs into their own products.

A RISC-based computer design approach means processors require fewer transistors than typical complex instruction set computing (CISC) x86 processors in most personal computers. This approach reduces costs, heat and power use. These characteristics are desirable for light, portable, battery-powered devices—​​including smartphones, laptops and tablet computers, and other embedded systems. For supercomputers, which consume large amounts of electricity, ARM could also be a power-efficient solution.

ARM Holdings periodically releases updates to its cores. All of them support a 32-bit address space (only pre-ARMv3 chips, made before ARM Holdings was formed, as in original Acorn Archimedes, had smaller) and 32-bit arithmetic; the ARMv8-A architecture, announced in October 2011, adds support for a 64-bit address space and 64-bit arithmetic. Instructions for ARM Holdings' cores have 32-bit fixed-length instructions, but later versions of the architecture also support a variable-length instruction set that provides both 32- and 16-bit instructions for improved code density. Some cores can also provide hardware execution of Java bytecodes.


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