Английская Википедия:Comparison of instruction set architectures
Шаблон:Short description An instruction set architecture (ISA) is an abstract model of a computer, also referred to as computer architecture. A realization of an ISA is called an implementation. An ISA permits multiple implementations that may vary in performance, physical size, and monetary cost (among other things); because the ISA serves as the interface between software and hardware. Software that has been written for an ISA can run on different implementations of the same ISA. This has enabled binary compatibility between different generations of computers to be easily achieved, and the development of computer families. Both of these developments have helped to lower the cost of computers and to increase their applicability. For these reasons, the ISA is one of the most important abstractions in computing today.
An ISA defines everything a machine language programmer needs to know in order to program a computer. What an ISA defines differs between ISAs; in general, ISAs define the supported data types, what state there is (such as the main memory and registers) and their semantics (such as the memory consistency and addressing modes), the instruction set (the set of machine instructions that comprises a computer's machine language), and the input/output model.
Base
In the early decades of computing, there were computers that used binary, decimal[1] and even ternary.[2][3] Contemporary computers are almost exclusively binary.
Bits
Computer architectures are often described as n-bit architectures. In the 20th century, n is often 8, 16, or 32, and in the 21st century, n is often 16, 32 or 64, but other sizes have been used (including 6, 12, 18, 24, 30, 36, 39, 48, 60, 128). This is actually a simplification as computer architecture often has a few more or less "natural" data sizes in the instruction set, but the hardware implementation of these may be very different. Many instruction set architectures have instructions that, on some implementations of that instruction set architecture, operate on half and/or twice the size of the processor's major internal datapaths. Examples of this are the Z80, MC68000, and the IBM System/360. On these types of implementations, a twice as wide operation typically also takes around twice as many clock cycles (which is not the case on high performance implementations). On the 68000, for instance, this means 8 instead of 4 clock ticks, and this particular chip may be described as a 32-bit architecture with a 16-bit implementation. The IBM System/360 instruction set architecture is 32-bit, but several models of the System/360 series, such as the IBM System/360 Model 30, have smaller internal data paths, while others, such as the 360/195, have larger internal data paths. The external databus width is not used to determine the width of the architecture; the NS32008, NS32016 and NS32032 were basically the same 32-bit chip with different external data buses; the NS32764 had a 64-bit bus, and used 32-bit register. Early 32-bit microprocessors often had a 24-bit address, as did the System/360 processors.
Operands
The number of operands is one of the factors that may give an indication about the performance of the instruction set. A three-operand architecture (2-in, 1-out) will allow
A := B + C
to be computed in one instruction
A two-operand architecture (1-in, 1-in-and-out) will allow
A := A + B
to be computed in one instruction, so two instructions will need to be executed to simulate a single three-operand instruction.
A := B A := A + C
Encoding length
As can be seen in the table below some instructions sets keep to a very simple fixed encoding length, and other have variable-length. Usually it is RISC architectures that have fixed encoding length and CISC architectures that have variable length, but not always.
Endianness
An architecture may use "big" or "little" endianness, or both, or be configurable to use either. Little-endian processors order bytes in memory with the least significant byte of a multi-byte value in the lowest-numbered memory location. Big-endian architectures instead arrange bytes with the most significant byte at the lowest-numbered address. The x86 architecture as well as several 8-bit architectures are little-endian. Most RISC architectures (SPARC, Power, PowerPC, MIPS) were originally big-endian (ARM was little-endian), but many (including ARM) are now configurable as either.
Endianness only applies to processors that allow individual addressing of units of data (such as bytes) that are smaller than the basic addressable machine word.
Instruction sets
The table below compares basic information about instruction set architectures.
Notes:
- Usually the number of registers is a power of two, e.g. 8, 16, 32. In some cases a hardwired-to-zero pseudo-register is included, as "part" of register files of architectures, mostly to simplify indexing modes. The column "Registers" only counts the integer "registers" usable by general instructions at any moment. Architectures always include special-purpose registers such as the program counter (PC). Those are not counted unless mentioned. Note that some architectures, such as SPARC, have register windows; for those architectures, the count indicates how many registers are available within a register window. Also, non-architected registers for register renaming are not counted.
- In the "Type" column, "Register–Register" is a synonym for a common type of architecture, "load–store", meaning that no instruction can directly access memory except some special ones, i.e. load to or store from register(s), with the possible exceptions of memory locking instructions for atomic operations.
- In the "Endianness" column, "Bi" means that the endianness is configurable.
Archi- tecture |
Bits | Version | Intro- duced |
Max # operands |
Type | Design | Registers (excluding FP/vector) |
Instruction encoding | Branch evaluation | Endian- ness |
Extensions | Open | Royalty free |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|
6502 | 8 | 1975 | 1 | Register–Memory | CISC | 3 | Variable (8- to 24-bit) | Condition register | Little | ||||
6800 | 8 | 1974 | 1 | Register–Memory | CISC | 3 | Variable (8- to 32-bit) | Condition register | Big | ||||
6809 | 8 | 1978 | 1 | Register–Memory | CISC | 3 | Variable (8- to 32-bit) | Condition register | Big | ||||
680x0 | 32 | 1979 | 2 | Register–Memory | CISC | 8 data and 8 address | Variable | Condition register | Big | ||||
8080 | 8 | 1974 | 2 | Register–Memory | CISC | 7 | Variable (8 to 24 bits) | Condition register | Little | ||||
8051 | 32 (8→32) | 1977? | 1 | Register–Register | CISC | Шаблон:Ubl | Variable (8 to 24 bits) | Compare and branch | Little | ||||
x86 | 16, 32, 64 (16→32→64) |
1978 | 2 (integer) 3 (AVX)Шаблон:Efn 4 (FMA4 and VPBLENDVPx )[4] |
Register–Memory | CISC | Шаблон:Ubl | Variable (8086 ~ 80386: variable between 1 and 6 bytes /w MMU + intel SDK, 80486: 2 to 5 bytes with prefix, pentium and onward: 2 to 4 bytes with prefix, x64: 4 bytes prefix, third party x86 emulation: 1 to 15 bytes w/o prefix & MMU . SSE/MMX: 4 bytes /w prefix AVX: 8 Bytes /w prefix) | Condition code | Little | x87, IA-32, MMX, 3DNow!, SSE, SSE2, PAE, x86-64, SSE3, SSSE3, SSE4, BMI, AVX, AES, FMA, XOP, F16C |
Шаблон:No | Шаблон:No | |
Alpha | 64 | 1992 | 3 | Register–Register | RISC | 32 (including "zero") | Fixed (32-bit) | Condition register | Bi | Шаблон:Tooltip, Шаблон:Tooltip, Шаблон:Tooltip, Шаблон:Tooltip | Шаблон:No | ||
ARC | 16/32/64 (32→64) | ARCv3[5] | 1996 | 3 | Register–Register | RISC | 16 or 32 including SP user can increase to 60 |
Variable (16- or 32-bit) | Compare and branch | Bi | APEX User-defined instructions | ||
ARM/A32 | 32 | ARMv1–v9 | 1983 | 3 | Register–Register | RISC | Шаблон:Ubl | Fixed (32-bit) | Condition code | Bi | NEON, Jazelle, Шаблон:Tooltip, TrustZone, Шаблон:Abbr |
Шаблон:No | |
Thumb/T32 | 32 | ARMv4T-ARMv8 | 1994 | 3 | Register–Register | RISC | Шаблон:Ubl | Thumb: Fixed (16-bit), Thumb-2: Variable (16- or 32-bit) |
Condition code | Bi | NEON, Jazelle, Шаблон:Tooltip, TrustZone, Шаблон:Abbr |
Шаблон:No | |
Arm64/A64 | 64 | ARMv8-A[6] | 2011[7] | 3 | Register–Register | RISC | 32 (including the stack pointer/"zero" register) | Fixed (32-bit), Variable (32-bit or 64-bit for FMA4 with 32-bit prefix[8]) | Condition code | Bi | SVE and SVE2 | Шаблон:No | |
AVR | 8 | 1997 | 2 | Register–Register | RISC | 32 16 on "reduced architecture" |
Variable (mostly 16-bit, four instructions are 32-bit) | Condition register, skip conditioned on an I/O or general purpose register bit, compare and skip |
Little | ||||
AVR32 | 32 | Rev 2 | 2006 | 2–3 | RISC | 15 | Variable[9] | Big | Java virtual machine | ||||
Blackfin | 32 | 2000 | 3[10] | Register–Register | RISC[11] | 2 accumulators
8 data registers 8 pointer registers 4 index registers 4 buffer registers |
Variable (16- or 32-bit) | Condition code | Little[12] | ||||
CDC Upper 3000 series | 48 | 1963 | 3 | Register–Memory | CISC | 48-bit A reg., 48-bit Q reg., 6 15-bit B registers, miscellaneous | Variable (24- or 48-bit) | Multiple types of jump and skip | Big | ||||
CDC 6000 Central Processor (CP) |
60 | 1964 | 3 | Register–Register | n/aШаблон:Efn | 24 (8 18-bit address reg., 8 18-bit index reg., 8 60-bit operand reg.) |
Variable (15-, 30-, or 60-bit) | Compare and branch | n/aШаблон:Efn | Compare/Move Unit | Шаблон:No | Шаблон:No | |
CDC 6000 Peripheral Processor (PP) |
12 | 1964 | 1 or 2 | Register–Memory | CISC | 1 18-bit A register, locations 1–63 serve as index registers for some instructions | Variable (12- or 24-bit) | Test A register, test channel | n/aШаблон:Efn | additional Peripheral Processing Units | Шаблон:No | Шаблон:No | |
Crusoe (native VLIW) |
32[13] | 2000 | 1 | Register–Register | VLIW[13][14] | Шаблон:Ubl | Variable (64- or 128-bit in native mode, 15 bytes in x86 emulation)[14] | Condition code[13] | Little | ||||
Elbrus 2000 (native VLIW) |
64 | v6 | 2007 | 1 | Register–Register[13] | VLIW | 8–64 | 64 | Condition code | Little | Just-in-time dynamic translation: x87, IA-32, MMX, SSE, SSE2, x86-64, SSE3, AVX |
Шаблон:No | Шаблон:No |
DLX | 32 | Шаблон:Dunno | 1990 | 3 | Шаблон:Dunno | RISC | 32 | Fixed (32-bit) | Шаблон:Dunno | Big | Шаблон:Dunno | Шаблон:Yes | Шаблон:Dunno |
eSi-RISC | 16/32 | 2009 | 3 | Register–Register | RISC | 8–72 | Variable (16- or 32-bit) | Compare and branch and condition register |
Bi | User-defined instructions | Шаблон:No | Шаблон:No | |
iAPX 432[15] | 32 | 1981 | 3 | Stack machine | CISC | 0 | Variable (6 to 321 bits) | Шаблон:No | Шаблон:No | ||||
Itanium (IA-64) |
64 | 2001 | Register–Register | EPIC | 128 | Fixed (128-bit bundles with 5-bit template tag and 3 instructions, each 41-bit long) | Condition register | Bi (selectable) |
Intel Virtualization Technology | Шаблон:No | Шаблон:No | ||
LoongArch | 32, 64 | 2021 | 4 | Register–Register | RISC | 32 (including "zero") | Fixed (32-bit) | Little | Шаблон:No | Шаблон:No | |||
M32R | 32 | 1997 | 3 | Register–Register | RISC | 16 | Variable (16- or 32-bit) | Condition register | Bi | ||||
m88k | 32 | 1988 | 3 | Register–Register | RISC | Fixed (32-bit) | Big | ||||||
Mico32 | 32 | Шаблон:Dunno | 2006 | 3 | Register–Register | RISC | 32[16] | Fixed (32-bit) | Compare and branch | Big | User-defined instructions | Шаблон:Yes[17] | Шаблон:Yes |
MIPS | 64 (32→64) | 6[18][19] | 1981 | 1–3 | Register–Register | RISC | 4–32 (including "zero") | Fixed (32-bit) | Condition register | Bi | MDMX, MIPS-3D | Шаблон:No | Шаблон:No[20][21] |
MMIX | 64 | Шаблон:Dunno | 1999 | 3 | Register–Register | RISC | 256 | Fixed (32-bit) | Condition register | Big | Шаблон:Dunno | Шаблон:Yes | Шаблон:Yes |
Nios II | 32 | Шаблон:Dunno | 2000 | 3 | Register–Register | RISC | 32 | Fixed (32-bit) | Condition register | Little | Soft processor that can be instantiated on an Altera FPGA device | Шаблон:No | Шаблон:Partial |
NS320xx | 32 | 1982 | 5 | Memory–Memory | CISC | 8 | Variable Huffman coded, up to 23 bytes long | Condition code | Little | BitBlt instructions | |||
OpenRISC | 32, 64 | 1.4[22] | 2000 | 3 | Register–Register | RISC | 16 or 32 | Fixed | Condition code | Bi | Шаблон:Dunno | Шаблон:Yes | Шаблон:Yes |
PA-RISC (HP/PA) |
64 (32→64) | 2.0 | 1986 | 3 | Register–Register | RISC | 32 | Fixed (32-bit) | Compare and branch | Big → Bi | MAX | Шаблон:No | |
PDP-8[23] | 12 | 1966 | Register–Memory | CISC | 1 accumulator
1 multiplier quotient register |
Fixed (12-bit) | Condition register
Test and branch |
EAE (Extended Arithmetic Element) | |||||
PDP-11 | 16 | 1970 | 2 | Memory–Memory | CISC | 8 (includes program counter and stack pointer, though any register can act as stack pointer) | Variable (16-, 32-, or 48-bit) | Condition code | Little | Floating Point, Commercial Instruction Set |
Шаблон:No | Шаблон:No | |
POWER, PowerPC, Power ISA | 32/64 (32→64) | 3.1[24] | 1990 | 3 (mostly). FMA, LD/ST-Update | Register–Register | RISC | 32 GPR, 8 4-bit Condition Fields, Link Register, Counter Register | Fixed (32-bit), Variable (32- or 64-bit with the 32-bit prefix[24]) | Condition code, Branch-Counter auto-decrement | Bi | AltiVec, APU, VSX, Cell, Floating-point, Matrix Multiply Assist | Шаблон:Yes | Шаблон:Yes |
RISC-V | 32, 64, 128 | 20191213[25] | 2010 | 3 | Register–Register | RISC | 32 (including "zero") | Variable | Compare and branch | Little | Шаблон:Dunno | Шаблон:Yes | Шаблон:Yes |
RX | 64/32/16 | 2000 | 3 | Memory–Memory | CISC | 4 integer + 4 address | Variable | Compare and branch | Little | Шаблон:No | |||
S+core | 16/32 | 2005 | RISC | Little | |||||||||
SPARC | 64 (32→64) | OSA2017[26] | 1985 | 3 | Register–Register | RISC | 32 (including "zero") | Fixed (32-bit) | Condition code | Big → Bi | VIS | Шаблон:Yes | Шаблон:Yes[27] |
SuperH (SH) | 32 | Шаблон:Dunno | 1994 | 2 | Register–Register Register–Memory |
RISC | 16 | Fixed (16- or 32-bit), Variable | Condition code (single bit) |
Bi | Шаблон:Dunno | Шаблон:Yes | Шаблон:Yes |
System/360 System/370 z/Architecture |
64 (32→64) | 1964 | 2 (most) 3 (FMA, distinct operand facility) 4 (some vector inst.) |
Register–Memory Memory–Memory Register–Register |
CISC | 16 general 16 control (S/370 and later) 16 access (ESA/370 and later) |
Variable (16-, 32-, or 48-bit) | Condition code, compare and branch auto increment, Branch-Counter auto-decrement | Big | Шаблон:No | Шаблон:No | ||
TMS320 C6000 series | 32 | 1983 | 3 | Register-Register | VLIW | 32 on C67x 64 on C67x+ |
Fixed (256-bit bundles with 8 instructions, each 32-bit long) | Condition register | Bi | Шаблон:No | Шаблон:No | ||
Transputer | 32 (4→64) | 1987 | 1 | Stack machine | MISC | 3 (as stack) | Fixed (8-bit) | Compare and branch | Little | ||||
VAX | 32 | 1977 | 6 | Memory–Memory | CISC | 16 | Variable | Condition code, compare and branch | Little | Шаблон:No | |||
Z80 | 8 | 1976 | 2 | Register–Memory | CISC | 17 | Variable (8 to 32 bits) | Condition register | Little | ||||
Archi- tecture |
Bits | Version | Intro- duced |
Max # operands |
Type | Design | Registers (excluding FP/vector) |
Instruction encoding | Branch evaluation | Endian- ness |
Extensions | Open | Royalty free |
See also
- Central processing unit (CPU)
- Processor design
- Comparison of CPU microarchitectures
- Instruction set architecture
- Microprocessor
- Benchmark (computing)
Notes
References
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite book.
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ 13,0 13,1 13,2 13,3 Шаблон:Cite web
- ↑ 14,0 14,1 Шаблон:Cite web
- ↑ Шаблон:Cite book
- ↑ Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ MIPS64 Architecture for Programmers: Release 6
- ↑ MIPS32 Architecture for Programmers: Release 6
- ↑ MIPS Open
- ↑ Шаблон:Cite web
- ↑ OpenRISC Architecture Revisions
- ↑ Шаблон:Cite web
- ↑ 24,0 24,1 Шаблон:Cite web
- ↑ Шаблон:Cite web
- ↑ Oracle SPARC Processor Documentation
- ↑ SPARC Architecture License