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x86-64

December 18, 2023

"Intel 64" redirects here. For the Intel 64-bit architecture in Itanium chips, see IA-64.
"x64" redirects here. For the New York City bus route, see X64 (New York City bus).

x86-64 (also known as x64, x86_64, AMD64, and Intel 64)[note 1] is a 64-bit version of the x86 instruction set, first announced in 1999. It introduced two new modes of operation, 64-bit mode and compatibility mode, along with a new 4-level paging mode.

AMD Opteron, the first CPU to introduce the x86-64 extensions in April 2003
The five-volume set of the x86-64 Architecture Programmer's Manual, as published and distributed by AMD in 2002

With 64-bit mode and the new paging mode, it supports vastly larger amounts of virtual memory and physical memory than was possible on its 32-bit predecessors, allowing programs to store larger amounts of data in memory. x86-64 also expands general-purpose registers to 64-bit, and expands the number of them from 8 (some of which had limited or fixed functionality, e.g. for stack management) to 16 (fully general), and provides numerous other enhancements. Floating-point arithmetic is supported via mandatory SSE2-like instructions, and x87/MMX style registers are generally not used (but still available even in 64-bit mode); instead, a set of 16 vector registers, 128 bits each, is used. (Each register can store one or two double-precision numbers or one to four single-precision numbers, or various integer formats.) In 64-bit mode, instructions are modified to support 64-bit operands and 64-bit addressing mode.

The compatibility mode defined in the architecture allows 16-bit and 32-bit user applications to run unmodified, coexisting with 64-bit applications if the 64-bit operating system supports them.[11][note 2] As the full x86 16-bit and 32-bit instruction sets remain implemented in hardware without any intervening emulation, these older executables can run with little or no performance penalty,[13] while newer or modified applications can take advantage of new features of the processor design to achieve performance improvements. Also, a processor supporting x86-64 still powers on in real mode for full backward compatibility with the 8086, as x86 processors supporting protected mode have done since the 80286.

The original specification, created by AMD and released in 2000, has been implemented by AMD, Intel, and VIA. The AMD K8 microarchitecture, in the Opteron and Athlon 64 processors, was the first to implement it. This was the first significant addition to the x86 architecture designed by a company other than Intel. Intel was forced to follow suit and introduced a modified NetBurst family which was software-compatible with AMD's specification. VIA Technologies introduced x86-64 in their VIA Isaiah architecture, with the VIA Nano.

The x86-64 architecture was quickly adopted for desktop and laptop personal computers and servers which were commonly configured for 16GB of memory or more. It has effectively replaced the discontinued Intel Itanium architecture (formerly IA-64), which was originally intended to replace the x86 architecture. x86-64 and Itanium are not compatible on the native instruction set level, and operating systems and applications compiled for one architecture cannot be run on the other natively.

AMD64 edit

 
AMD64 logo

History edit

AMD64 (also variously referred to by AMD in their literature and documentation as “AMD 64-bit Technology” and “AMD x86-64 Architecture”) was created as an alternative to the radically different IA-64 architecture designed by Intel and Hewlett-Packard, which was backward-incompatible with IA-32, the 32-bit version of the x86 architecture. AMD originally announced AMD64 in 1999[14] with a full specification available in August 2000.[15] As AMD was never invited to be a contributing party for the IA-64 architecture and any kind of licensing seemed unlikely, the AMD64 architecture was positioned by AMD from the beginning as an evolutionary way to add 64-bit computing capabilities to the existing x86 architecture while supporting legacy 32-bit x86 code, as opposed to Intel's approach of creating an entirely new, completely x86-incompatible 64-bit architecture with IA-64.

The first AMD64-based processor, the Opteron, was released in April 2003.

Implementations edit

AMD's processors implementing the AMD64 architecture include Opteron, Athlon 64, Athlon 64 X2, Athlon 64 FX, Athlon II (followed by "X2", "X3", or "X4" to indicate the number of cores, and XLT models), Turion 64, Turion 64 X2, Sempron ("Palermo" E6 stepping and all "Manila" models), Phenom (followed by "X3" or "X4" to indicate the number of cores), Phenom II (followed by "X2", "X3", "X4" or "X6" to indicate the number of cores), FX, Fusion/APU and Ryzen/Epyc.[citation needed]

Architectural features edit

The primary defining characteristic of AMD64 is the availability of 64-bit general-purpose processor registers (for example, rax), 64-bit integer arithmetic and logical operations, and 64-bit virtual addresses.[citation needed] The designers took the opportunity to make other improvements as well.

Notable changes in the 64-bit extensions include:

64-bit integer capability
All general-purpose registers (GPRs) are expanded from 32 bits to 64 bits, and all arithmetic and logical operations, memory-to-register and register-to-memory operations, etc., can operate directly on 64-bit integers. Pushes and pops on the stack default to 8-byte strides, and pointers are 8 bytes wide.
Additional registers
In addition to increasing the size of the general-purpose registers, the number of named general-purpose registers is increased from eight (i.e. eax, ecx, edx, ebx, esp, ebp, esi, edi) in x86 to 16 (i.e. rax, rcx, rdx, rbx, rsp, rbp, rsi, rdi, r8, r9, r10, r11, r12, r13, r14, r15). It is therefore possible to keep more local variables in registers rather than on the stack, and to let registers hold frequently accessed constants; arguments for small and fast subroutines may also be passed in registers to a greater extent.
AMD64 still has fewer registers than many RISC instruction sets (e.g. PA-RISC, Power ISA, and MIPS have 32 GPRs; Alpha, 64-bit ARM, and SPARC have 31) or VLIW-like machines such as the IA-64 (which has 128 registers). However, an AMD64 implementation may have far more internal registers than the number of architectural registers exposed by the instruction set (see register renaming). (For example, AMD Zen cores have 168 64-bit integer and 160 128-bit vector floating-point physical internal registers.)
Additional XMM (SSE) registers
Similarly, the number of 128-bit XMM registers (used for Streaming SIMD instructions) is also increased from 8 to 16.
The traditional x87 FPU register stack is not included in the register file size extension in 64-bit mode, compared with the XMM registers used by SSE2, which did get extended. The x87 register stack is not a simple register file although it does allow direct access to individual registers by low cost exchange operations.
Larger virtual address space
The AMD64 architecture defines a 64-bit virtual address format, of which the low-order 48 bits are used in current implementations.[11]: 120  This allows up to 256 TB (248 bytes) of virtual address space. The architecture definition allows this limit to be raised in future implementations to the full 64 bits,[11]: 2 : 3 : 13 : 117 : 120  extending the virtual address space to 16 EB (264 bytes).[16] This is compared to just 4 GB (232 bytes) for the x86.[17]
This means that very large files can be operated on by mapping the entire file into the process's address space (which is often much faster than working with file read/write calls), rather than having to map regions of the file into and out of the address space.
Larger physical address space
The original implementation of the AMD64 architecture implemented 40-bit physical addresses and so could address up to 1 TB (240 bytes) of RAM.[11]: 24  Current implementations of the AMD64 architecture (starting from AMD 10h microarchitecture) extend this to 48-bit physical addresses[18] and therefore can address up to 256 TB (248 bytes) of RAM. The architecture permits extending this to 52 bits in the future[11]: 24 [19] (limited by the page table entry format);[11]: 131  this would allow addressing of up to 4 PB of RAM. For comparison, 32-bit x86 processors are limited to 64 GB of RAM in Physical Address Extension (PAE) mode,[20] or 4 GB of RAM without PAE mode.[11]: 4 
Larger physical address space in legacy mode
When operating in legacy mode the AMD64 architecture supports Physical Address Extension (PAE) mode, as do most current x86 processors, but AMD64 extends PAE from 36 bits to an architectural limit of 52 bits of physical address. Any implementation, therefore, allows the same physical address limit as under long mode.[11]: 24 
Instruction pointer relative data access
Instructions can now reference data relative to the instruction pointer (RIP register). This makes position-independent code, as is often used in shared libraries and code loaded at run time, more efficient.
SSE instructions
The original AMD64 architecture adopted Intel's SSE and SSE2 as core instructions. These instruction sets provide a vector supplement to the scalar x87 FPU, for the single-precision and double-precision data types. SSE2 also offers integer vector operations, for data types ranging from 8bit to 64bit precision. This makes the vector capabilities of the architecture on par with those of the most advanced x86 processors of its time. These instructions can also be used in 32-bit mode. The proliferation of 64-bit processors has made these vector capabilities ubiquitous in home computers, allowing the improvement of the standards of 32-bit applications. The 32-bit edition of Windows 8, for example, requires the presence of SSE2 instructions.[21] SSE3 instructions and later Streaming SIMD Extensions instruction sets are not standard features of the architecture.
No-Execute bit
The No-Execute bit or NX bit (bit 63 of the page table entry) allows the operating system to specify which pages of virtual address space can contain executable code and which cannot. An attempt to execute code from a page tagged "no execute" will result in a memory access violation, similar to an attempt to write to a read-only page. This should make it more difficult for malicious code to take control of the system via "buffer overrun" or "unchecked buffer" attacks. A similar feature has been available on x86 processors since the 80286 as an attribute of segment descriptors; however, this works only on an entire segment at a time.
Segmented addressing has long been considered an obsolete mode of operation, and all current PC operating systems in effect bypass it, setting all segments to a base address of zero and (in their 32-bit implementation) a size of 4 GB. AMD was the first x86-family vendor to implement no-execute in linear addressing mode. The feature is also available in legacy mode on AMD64 processors, and recent Intel x86 processors, when PAE is used.
Removal of older features
A few "system programming" features of the x86 architecture were either unused or underused in modern operating systems and are either not available on AMD64 in long (64-bit and compatibility) mode, or exist only in limited form. These include segmented addressing (although the FS and GS segments are retained in vestigial form for use as extra-base pointers to operating system structures),[11]: 70  the task state switch mechanism, and virtual 8086 mode. These features remain fully implemented in "legacy mode", allowing these processors to run 32-bit and 16-bit operating systems without modifications. Some instructions that proved to be rarely useful are not supported in 64-bit mode, including saving/restoring of segment registers on the stack, saving/restoring of all registers (PUSHA/POPA), decimal arithmetic, BOUND and INTO instructions, and "far" jumps and calls with immediate operands.

Virtual address space details edit

Canonical form addresses edit

Canonical address space implementations (diagrams not to scale)
 
Current 48-bit implementation
 
57-bit implementation
 
64-bit implementation

Although virtual addresses are 64 bits wide in 64-bit mode, current implementations (and all chips that are known to be in the planning stages) do not allow the entire virtual address space of 264 bytes (16 EB) to be used. This would be approximately four billion times the size of the virtual address space on 32-bit machines. Most operating systems and applications will not need such a large address space for the foreseeable future, so implementing such wide virtual addresses would simply increase the complexity and cost of address translation with no real benefit. AMD, therefore, decided that, in the first implementations of the architecture, only the least significant 48 bits of a virtual address would actually be used in address translation (page table lookup).[11]: 120 

In addition, the AMD specification requires that the most significant 16 bits of any virtual address, bits 48 through 63, must be copies of bit 47 (in a manner akin to sign extension). If this requirement is not met, the processor will raise an exception.[11]: 131  Addresses complying with this rule are referred to as "canonical form."[11]: 130  Canonical form addresses run from 0 through 00007FFF'FFFFFFFF, and from FFFF8000'00000000 through FFFFFFFF'FFFFFFFF, for a total of 256 TB of usable virtual address space. This is still 65,536 times larger than the virtual 4 GB address space of 32-bit machines.

This feature eases later scalability to true 64-bit addressing. Many operating systems (including, but not limited to, the Windows NT family) take the higher-addressed half of the address space (named kernel space) for themselves and leave the lower-addressed half (user space) for application code, user mode stacks, heaps, and other data regions.[22] The "canonical address" design ensures that every AMD64 compliant implementation has, in effect, two memory halves: the lower half starts at 00000000'00000000 and "grows upwards" as more virtual address bits become available, while the higher half is "docked" to the top of the address space and grows downwards. Also, enforcing the "canonical form" of addresses by checking the unused address bits prevents their use by the operating system in tagged pointers as flags, privilege markers, etc., as such use could become problematic when the architecture is extended to implement more virtual address bits.

The first versions of Windows for x64 did not even use the full 256 TB; they were restricted to just 8 TB of user space and 8 TB of kernel space.[22] Windows did not support the entire 48-bit address space until Windows 8.1, which was released in October 2013.[22]

Page table structure edit

 

The 64-bit addressing mode ("long mode") is a superset of Physical Address Extensions (PAE); because of this, page sizes may be 4 KB (212 bytes) or 2 MB (221 bytes).[11]: 120  Long mode also supports page sizes of 1 GB (230 bytes).[11]: 120  Rather than the three-level page table system used by systems in PAE mode, systems running in long mode use four levels of page table: PAE's Page-Directory Pointer Table is extended from four entries to 512, and an additional Page-Map Level 4 (PML4) Table is added, containing 512 entries in 48-bit implementations.[11]: 131  A full mapping hierarchy of 4 KB pages for the whole 48-bit space would take a bit more than 512 GB of memory (about 0.195% of the 256 TB virtual space).

64 bit page table entry
Bits: 63 62 … 52 51 … 32
Content: NX reserved Bit 51…32 of base address
Bits: 31 … 12 11 … 9 8 7 6 5 4 3 2 1 0
Content: Bit 31…12 of base address ign. G PAT D A PCD PWT U/S R/W P

Intel has implemented a scheme with a 5-level page table, which allows Intel 64 processors to support a 57-bit virtual address space.[23] Further extensions may allow full 64-bit virtual address space and physical memory by expanding the page table entry size to 128-bit, and reduce page walks in the 5-level hierarchy by using a larger 64 KB page allocation size that still supports 4 KB page operations for backward compatibility.[24]

Operating system limits edit

The operating system can also limit the virtual address space. Details, where applicable, are given in the "Operating system compatibility and characteristics" section.

Physical address space details edit

Current AMD64 processors support a physical address space of up to 248 bytes of RAM, or 256 TB.[18] However, as of 2020, there were no known x86-64 motherboards that support 256 TB of RAM.[25][26][27][28][failed verification] The operating system may place additional limits on the amount of RAM that is usable or supported. Details on this point are given in the "Operating system compatibility and characteristics" section of this article.

Operating modes edit

The architecture has two primary modes of operation: long mode and legacy mode.

Operating Operating system required Type of code being run Size (in bits) No. of general-purpose registers
mode sub-mode addresses operands (default in italics)
Long mode 64-bit mode 64-bit OS, 64-bit UEFI firmware, or the previous two interacting via a 64-bit firmware's UEFI interface 64-bit 64 8, 16, 32, 64 16
Compatibility mode Bootloader or 64-bit OS 32-bit 32 8, 16, 32 8
16-bit protected mode 16 8, 16, 32 8
Legacy mode Protected mode Bootloader, 32-bit OS, 32-bit UEFI firmware, or the latter two interacting via the firmware's UEFI interface 32-bit 32 8, 16, 32 8
16-bit protected mode OS 16-bit protected mode 16 8, 16, 32[m 1] 8
Virtual 8086 mode 16-bit protected mode or 32-bit OS subset of real mode 16 8, 16, 32[m 1] 8
Unreal mode Bootloader or real mode OS real mode 16, 20, 32 8, 16, 32[m 1] 8
Real mode Bootloader, real mode OS, or any OS interfacing with a firmware's BIOS interface[29] real mode 16, 20, 21 8, 16, 32[m 1] 8
  1. ^ a b c d Note that 16-bit code written for the 80286 and below does not use 32-bit operand instructions. Code written for the 80386 and above can use the operand-size override prefix (0x66). Normally this prefix is used by protected and long mode code for the purpose of using 16-bit operands, as that code would be running in a code segment with a default operand size of 32 bits. In real mode, the default operand size is 16 bits, so the 0x66 prefix is interpreted differently, changing operand size to 32 bits.
 
State diagram of the x86-64 operating modes

Long mode edit

Main article: Long mode

Long mode is the architecture's intended primary mode of operation; it is a combination of the processor's native 64-bit mode and a combined 32-bit and 16-bit compatibility mode. It is used by 64-bit operating systems. Under a 64-bit operating system, 64-bit programs run under 64-bit mode, and 32-bit and 16-bit protected mode applications (that do not need to use either real mode or virtual 8086 mode in order to execute at any time) run under compatibility mode. Real-mode programs and programs that use virtual 8086 mode at any time cannot be run in long mode unless those modes are emulated in software.[11]: 11  However, such programs may be started from an operating system running in long mode on processors supporting VT-x or AMD-V by creating a virtual processor running in the desired mode.

Since the basic instruction set is the same, there is almost no performance penalty for executing protected mode x86 code. This is unlike Intel's IA-64, where differences in the underlying instruction set mean that running 32-bit code must be done either in emulation of x86 (making the process slower) or with a dedicated x86 coprocessor. However, on the x86-64 platform, many x86 applications could benefit from a 64-bit recompile, due to the additional registers in 64-bit code and guaranteed SSE2-based FPU support, which a compiler can use for optimization. However, applications that regularly handle integers wider than 32 bits, such as cryptographic algorithms, will need a rewrite of the code handling the huge integers in order to take advantage of the 64-bit registers.

Legacy mode edit

Legacy mode is the mode that the processor is in when it is not in long mode.[11]: 14  In this mode, the processor acts like an older x86 processor, and only 16-bit and 32-bit code can be executed. Legacy mode allows for a maximum of 32 bit virtual addressing which limits the virtual address space to 4 GB.[11]: 14 : 24 : 118  64-bit programs cannot be run from legacy mode.

Protected mode edit

Protected mode is made into a submode of legacy mode.[11]: 14  It is the submode that 32-bit operating systems and 16-bit protected mode operating systems operate in when running on an x86-64 CPU.[11]: 14 

Real mode edit

Real mode is the initial mode of operation when the processor is initialized, and is a submode of legacy mode. It is backwards compatible with the original Intel 8086 and Intel 8088 processors. Real mode is primarily used today by operating system bootloaders, which are required by the architecture to configure virtual memory details before transitioning to higher modes. This mode is also used by any operating system that needs to communicate with the system firmware with a traditional BIOS-style interface.[29]

Intel 64 edit

Intel 64 is Intel's implementation of x86-64, used and implemented in various processors made by Intel.

History edit

Historically, AMD has developed and produced processors with instruction sets patterned after Intel's original designs, but with x86-64, roles were reversed: Intel found itself in the position of adopting the ISA that AMD created as an extension to Intel's own x86 processor line.

Intel's project was originally codenamed Yamhill[30] (after the Yamhill River in Oregon's Willamette Valley). After several years of denying its existence, Intel announced at the February 2004 IDF that the project was indeed underway. Intel's chairman at the time, Craig Barrett, admitted that this was one of their worst-kept secrets.[31][32]

Intel's name for this instruction set has changed several times. The name used at the IDF was CT[33] (presumably[original research?] for Clackamas Technology, another codename from an Oregon river); within weeks they began referring to it as IA-32e (for IA-32 extensions) and in March 2004 unveiled the "official" name EM64T (Extended Memory 64 Technology). In late 2006 Intel began instead using the name Intel 64 for its implementation, paralleling AMD's use of the name AMD64.[34]

The first processor to implement Intel 64 was the multi-socket processor Xeon code-named Nocona in June 2004. In contrast, the initial Prescott chips (February 2004) did not enable this feature. Intel subsequently began selling Intel 64-enabled Pentium 4s using the E0 revision of the Prescott core, being sold on the OEM market as the Pentium 4, model F. The E0 revision also adds eXecute Disable (XD) (Intel's name for the NX bit) to Intel 64, and has been included in then current Xeon code-named Irwindale. Intel's official launch of Intel 64 (under the name EM64T at that time) in mainstream desktop processors was the N0 stepping Prescott-2M.

The first Intel mobile processor implementing Intel 64 is the Merom version of the Core 2 processor, which was released on July 27, 2006. None of Intel's earlier notebook CPUs (Core Duo, Pentium M, Celeron M, Mobile Pentium 4) implement Intel 64.

Implementations edit

Intel's processors implementing the Intel64 architecture include the Pentium 4 F-series/5x1 series, 506, and 516, Celeron D models 3x1, 3x6, 355, 347, 352, 360, and 365 and all later Celerons, all models of Xeon since "Nocona", all models of Pentium Dual-Core processors since "Merom-2M", the Atom 230, 330, D410, D425, D510, D525, N450, N455, N470, N475, N550, N570, N2600 and N2800, all versions of the Pentium D, Pentium Extreme Edition, Core 2, Core i9, Core i7, Core i5, and Core i3 processors, and the Xeon Phi 7200 series processors.

x86-S edit

x86-S is a proposed simplification of Intel 64 announced in May 2023.[35] The new architecture would remove support for 16-bit and 32-bit operating systems, while 32-bit programs will still run under a 64-bit OS. A CPU would no longer have legacy mode, and start directly in 64-bit long mode. There will be a way to switch to 5-level paging without going through the unpaged mode. Specific removed features include:[36]

  • Segmentation gates
  • 32-bit ring 0
    • VT-x will no longer emulate this feature
  • Rings 1 and 2
  • Ring 3 I/O port (IN/OUT) access; see port-mapped I/O
  • String port I/O (INS/OUTS)
  • Real mode (including huge real mode), 16-bit protected mode, VM86
  • 16-bit addressing mode
    • VT-x will no longer provide unrestricted mode
  • 8259 support; the only APIC supported would be X2APIC
  • Some unused operating system mode bits

Intel believes the change follows logically after the removal of A20 gate in 2008 and the ceasing of 16-bit and 32-bit OS support in Intel firmware in 2020. Support for legacy operating systems would be accomplished via hardware-accelerated virtualization.[36]

VIA's x86-64 implementation edit

VIA Technologies introduced their first implementation of the x86-64 architecture in 2008 after five years of development by its CPU division, Centaur Technology.[37] Codenamed "Isaiah", the 64-bit architecture was unveiled on January 24, 2008,[38] and launched on May 29 under the VIA Nano brand name.[39]

The processor supports a number of VIA-specific x86 extensions designed to boost efficiency in low-power appliances. It is expected that the Isaiah architecture will be twice as fast in integer performance and four times as fast in floating-point performance as the previous-generation VIA Esther at an equivalent clock speed. Power consumption is also expected to be on par with the previous-generation VIA CPUs, with thermal design power ranging from 5 W to 25 W.[40] Being a completely new design, the Isaiah architecture was built with support for features like the x86-64 instruction set and x86 virtualization which were unavailable on its predecessors, the VIA C7 line, while retaining their encryption extensions.

Microarchitecture levels edit

In 2020, through a collaboration between AMD, Intel, Red Hat, and SUSE, three microarchitecture levels (or feature levels) on top of the x86-64 baseline were defined: x86-64-v2, x86-64-v3, and x86-64-v4.[41][42] These levels define specific features that can be targeted by programmers to provide compile-time optimizations. The features exposed by each level are as follows:[43]

CPU microarchitecture levels
Level CPU features Example instruction Involved microprocessors
x86-64-v1 CMOV cmov all x86-64 CPUs
CX8 cmpxchg8b
FPU fld
FXSR fxsave
MMX emms
OSFXSR fxsave
SCE syscall
SSE cvtss2si
SSE2 cvtpi2pd
x86-64-v2 CMPXCHG16B cmpxchg16b circa 2009: Nehalem and Jaguar

Also:

LAHF-SAHF lahf
POPCNT popcnt
SSE3 addsubpd
SSE4_1 blendpd
SSE4_2 pcmpestri
SSSE3 phaddd
x86-64-v3 AVX vzeroall circa 2015: Haswell and Excavator

Also:

AVX2 vpermd
BMI1 andn
BMI2 bzhi
F16C vcvtph2ps
FMA vfmadd132pd
LZCNT lzcnt
MOVBE movbe
OSXSAVE xgetbv
x86-64-v4 AVX512F kmovw AVX-512's general-purpose subset
AVX512BW vdbpsadbw
AVX512CD vplzcntd
AVX512DQ vpmullq
AVX512VL

All levels include features found in the previous levels. Instruction set extensions not concerned with general-purpose computation, including AES-NI and RDRAND, are excluded from the level requirements.

Differences between AMD64 and Intel 64 edit

Although nearly identical, there are some differences between the two instruction sets in the semantics of a few seldom used machine instructions (or situations), which are mainly used for system programming.[46] Compilers generally produce executables (i.e. machine code) that avoid any differences, at least for ordinary application programs. This is therefore of interest mainly to developers of compilers, operating systems and similar, which must deal with individual and special system instructions.

Recent implementations edit

  • Intel 64's BSF and BSR instructions act differently than AMD64's when the source is zero and the operand size is 32 bits. The processor sets the zero flag and leaves the upper 32 bits of the destination undefined.[citation needed] Note that Intel documents that the destination register has an undefined value in this case, but in practice in silicon implements the same behaviour as AMD (destination unmodified). The separate claim about maybe not preserving bits in the upper 32 has not been verified, but has only been ruled out for Core 2 and Skylake,[47] not all Intel microarchitectures like 64-bit Pentium 4 or low-power Atom.
  • AMD64 requires a different microcode update format and control MSRs (model-specific registers), while Intel 64 implements microcode update unchanged from their 32-bit only processors.
  • Intel 64 lacks some MSRs that are considered architectural in AMD64. These include SYSCFG, TOP_MEM, and TOP_MEM2.
  • Intel 64 allows SYSCALL/SYSRET only in 64-bit mode (not in compatibility mode),[48] and allows SYSENTER/SYSEXIT in both modes.[49] AMD64 lacks SYSENTER/SYSEXIT in both sub-modes of long mode.[11]: 33 
  • In 64-bit mode, near branches with the 66H (operand size override) prefix behave differently. Intel 64 ignores this prefix: the instruction has a 32-bit sign extended offset, and instruction pointer is not truncated. AMD64 uses a 16-bit offset field in the instruction, and clears the top 48 bits of instruction pointer.
  • On Intel 64 but not AMD64, the REX.W prefix can be used with the far-pointer instructions (LFS, LGS, LSS, JMP FAR, CALL FAR) to increase the size of their far pointer argument to 80 bits (64-bit offset + 16-bit segment).
  • Intel 64 lacks the ability to save and restore a reduced (and thus faster) version of the floating-point state (involving the FXSAVE and FXRSTOR instructions).[clarification needed]
  • AMD processors ever since Opteron Rev. E and Athlon 64 Rev. D have reintroduced limited support for segmentation, via the Long Mode Segment Limit Enable (LMSLE) bit, to ease virtualization of 64-bit guests.[50][51] LMLSE support was removed in the Zen 3 processor. [52]
  • When returning to a non-canonical address using SYSRET, AMD64 processors execute the general protection fault handler in privilege level 3,[53] while on Intel 64 processors it is executed in privilege level 0.[54]

Older implementations edit

  • The AMD64 processors prior to Revision F[55] (distinguished by the switch from DDR to DDR2 memory and new sockets AM2, F and S1) of 2006 lacked the CMPXCHG16B instruction, which is an extension of the CMPXCHG8B instruction present on most post-80486 processors. Similar to CMPXCHG8B, CMPXCHG16B allows for atomic operations on octa-words (128-bit values). This is useful for parallel algorithms that use compare and swap on data larger than the size of a pointer, common in lock-free and wait-free algorithms. Without CMPXCHG16B one must use workarounds, such as a critical section or alternative lock-free approaches.[56] Its absence also prevents 64-bit Windows prior to Windows 8.1 from having a user-mode address space larger than 8 TB.[57] The 64-bit version of Windows 8.1 requires the instruction.[58]
  • Early AMD64 and Intel 64 CPUs lacked LAHF and SAHF instructions in 64-bit mode. AMD introduced these instructions (also in 64-bit mode) with their 90 nm (revision D) processors, starting with Athlon 64 in October 2004.[59][60] Intel introduced the instructions in October 2005 with the 0F47h and later revisions of NetBurst.[66] The 64-bit version of Windows 8.1 requires this feature.[58]
  • Early Intel CPUs with Intel 64 also lack the NX bit of the AMD64 architecture. It was added in the stepping E0 (0F41h) Pentium 4 in October 2004.[67] This feature is required by all versions of Windows 8.
  • Early Intel 64 implementations had a 36-bit (64 GB) physical addressing of memory while original AMD64 implementations had a 40-bit (1 TB) physical addressing. Intel used the 40-bit physical addressing first on Xeon MP (Potomac), launched on 29 March 2005.[68] The difference is not a difference of the user-visible ISAs. In 2007 AMD 10h-based Opteron was the first to provide a 48-bit (256 TB) physical address space.[69][70] Intel 64's physical addressing was extended to 44 bits (16 TB) in Nehalem-EX in 2010[71] and to 46 bits (64 TB) in Sandy Bridge E in 2011.[72][73] With the Ice Lake 3rd gen Xeon Scalable processors, Intel increased the virtual addressing to 57 bits (128 PB) and physical to 52 bits (4 PB) in 2021, necessitating a 5-level paging.[74] The following year AMD64 added the same in 4th generation EPYC (Genoa).[75] Non-server CPUs retain smaller address spaces for longer.

Adoption edit

 
An area chart showing the representation of different families of microprocessors in the TOP500 supercomputer ranking list, from 1993 to 2020[76]

In supercomputers tracked by TOP500, the appearance of 64-bit extensions for the x86 architecture enabled 64-bit x86 processors by AMD and Intel to replace most RISC processor architectures previously used in such systems (including PA-RISC, SPARC, Alpha and others), as well as 32-bit x86, even though Intel itself initially tried unsuccessfully to replace x86 with a new incompatible 64-bit architecture in the Itanium processor.

As of 2020, a Fujitsu A64FX-based supercomputer called Fugaku is number one. The first ARM-based supercomputer appeared on the list in 2018[77] and, in recent years, non-CPU architecture co-processors (GPGPU) have also played a big role in performance. Intel's Xeon Phi "Knights Corner" coprocessors, which implement a subset of x86-64 with some vector extensions,[78] are also used, along with x86-64 processors, in the Tianhe-2 supercomputer.[79]

Operating system compatibility and characteristics edit

The following operating systems and releases support the x86-64 architecture in long mode.

BSD edit

DragonFly BSD edit

Preliminary infrastructure work was started in February 2004 for a x86-64 port.[80] This development later stalled. Development started again during July 2007[81] and continued during Google Summer of Code 2008 and SoC 2009.[82][83] The first official release to contain x86-64 support was version 2.4.[84]

FreeBSD edit

FreeBSD first added x86-64 support under the name "amd64" as an experimental architecture in 5.1-RELEASE in June 2003. It was included as a standard distribution architecture as of 5.2-RELEASE in January 2004. Since then, FreeBSD has designated it as a Tier 1 platform. The 6.0-RELEASE version cleaned up some quirks with running x86 executables under amd64, and most drivers work just as they do on the x86 architecture. Work is currently being done to integrate more fully the x86 application binary interface (ABI), in the same manner as the Linux 32-bit ABI compatibility currently works.

NetBSD edit

x86-64 architecture support was first committed to the NetBSD source tree on June 19, 2001. As of NetBSD 2.0, released on December 9, 2004, NetBSD/amd64 is a fully integrated and supported port. 32-bit code is still supported in 64-bit mode, with a netbsd-32 kernel compatibility layer for 32-bit syscalls. The NX bit is used to provide non-executable stack and heap with per-page granularity (segment granularity being used on 32-bit x86).

OpenBSD edit

OpenBSD has supported AMD64 since OpenBSD 3.5, released on May 1, 2004. Complete in-tree implementation of AMD64 support was achieved prior to the hardware's initial release because AMD had loaned several machines for the project's hackathon that year. OpenBSD developers have taken to the platform because of its support for the NX bit, which allowed for an easy implementation of the W^X feature.

The code for the AMD64 port of OpenBSD also runs on Intel 64 processors which contains cloned use of the AMD64 extensions, but since Intel left out the page table NX bit in early Intel 64 processors, there is no W^X capability on those Intel CPUs; later Intel 64 processors added the NX bit under the name "XD bit". Symmetric multiprocessing (SMP) works on OpenBSD's AMD64 port, starting with release 3.6 on November 1, 2004.

DOS edit

It is possible to enter long mode under DOS without a DOS extender,[85] but the user must return to real mode in order to call BIOS or DOS interrupts.

It may also be possible to enter long mode with a DOS extender similar to DOS/4GW, but more complex since x86-64 lacks virtual 8086 mode. DOS itself is not aware of that, and no benefits should be expected unless running DOS in an emulation with an adequate virtualization driver backend, for example: the mass storage interface.

Linux edit

See also: Comparison of Linux distributions § Instruction set architecture support

Linux was the first operating system kernel to run the x86-64 architecture in long mode, starting with the 2.4 version in 2001 (preceding the hardware's availability).[86][87] Linux also provides backward compatibility for running 32-bit executables. This permits programs to be recompiled into long mode while retaining the use of 32-bit programs. Current Linux distributions ship with x86-64-native kernels and userlands. Some, such as Arch Linux,[88] SUSE, Mandriva, and Debian, allow users to install a set of 32-bit components and libraries when installing off a 64-bit distribution medium, thus allowing most existing 32-bit applications to run alongside the 64-bit OS.

x32 ABI (Application Binary Interface), introduced in Linux 3.4, allows programs compiled for the x32 ABI to run in the 64-bit mode of x86-64 while only using 32-bit pointers and data fields.[89][90][91] Though this limits the program to a virtual address space of 4 GB it also decreases the memory footprint of the program and in some cases can allow it to run faster.[89][90][91]

64-bit Linux allows up to 128 TB of virtual address space for individual processes, and can address approximately 64 TB of physical memory, subject to processor and system limitations.[92]

macOS edit

Mac OS X 10.4.7 and higher versions of Mac OS X 10.4 run 64-bit command-line tools using the POSIX and math libraries on 64-bit Intel-based machines, just as all versions of Mac OS X 10.4 and 10.5 run them on 64-bit PowerPC machines. No other libraries or frameworks work with 64-bit applications in Mac OS X 10.4.[93] The kernel, and all kernel extensions, are 32-bit only.

Mac OS X 10.5 supports 64-bit GUI applications using Cocoa, Quartz, OpenGL, and X11 on 64-bit Intel-based machines, as well as on 64-bit PowerPC machines.[94] All non-GUI libraries and frameworks also support 64-bit applications on those platforms. The kernel, and all kernel extensions, are 32-bit only.

Mac OS X 10.6 is the first version of macOS that supports a 64-bit kernel. However, not all 64-bit computers can run the 64-bit kernel, and not all 64-bit computers that can run the 64-bit kernel will do so by default.[95] The 64-bit kernel, like the 32-bit kernel, supports 32-bit applications; both kernels also support 64-bit applications. 32-bit applications have a virtual address space limit of 4 GB under either kernel.[96][97] The 64-bit kernel does not support 32-bit kernel extensions, and the 32-bit kernel does not support 64-bit kernel extensions.

OS X 10.8 includes only the 64-bit kernel, but continues to support 32-bit applications; it does not support 32-bit kernel extensions, however.

macOS 10.15 includes only the 64-bit kernel and no longer supports 32-bit applications. This removal of support has presented a problem for WineHQ (and the commercial version CrossOver), as it needs to still be able to run 32-bit Windows applications. The solution, termed wine32on64, was to add thunks that bring the CPU in and out of 32-bit compatibility mode in the nominally 64-bit application.[98][99]

macOS uses the universal binary format to package 32- and 64-bit versions of application and library code into a single file; the most appropriate version is automatically selected at load time. In Mac OS X 10.6, the universal binary format is also used for the kernel and for those kernel extensions that support both 32-bit and 64-bit kernels.

Solaris edit

See also: illumos

Solaris 10 and later releases support the x86-64 architecture.

For Solaris 10, just as with the SPARC architecture, there is only one operating system image, which contains a 32-bit kernel and a 64-bit kernel; this is labeled as the "x64/x86" DVD-ROM image. The default behavior is to boot a 64-bit kernel, allowing both 64-bit and existing or new 32-bit executables to be run. A 32-bit kernel can also be manually selected, in which case only 32-bit executables will run. The isainfo command can be used to determine if a system is running a 64-bit kernel.

For Solaris 11, only the 64-bit kernel is provided. However, the 64-bit kernel supports both 32- and 64-bit executables, libraries, and system calls.

Windows edit

x64 editions of Microsoft Windows client and server—Windows XP Professional x64 Edition and Windows Server 2003 x64 Edition—were released in March 2005.[100] Internally they are actually the same build (5.2.3790.1830 SP1),[101][102] as they share the same source base and operating system binaries, so even system updates are released in unified packages, much in the manner as Windows 2000 Professional and Server editions for x86. Windows Vista, which also has many different editions, was released in January 2007. Windows 7 was released in July 2009. Windows Server 2008 R2 was sold in only x64 and Itanium editions; later versions of Windows Server only offer an x64 edition.

Versions of Windows for x64 prior to Windows 8.1 and Windows Server 2012 R2 offer the following:

  • 8 TB of virtual address space per process, accessible from both user mode and kernel mode, referred to as the user mode address space. An x64 program can use all of this, subject to backing store limits on the system, and provided it is linked with the "large address aware" option, which is present by default.[103] This is a 4096-fold increase over the default 2 GB user-mode virtual address space offered by 32-bit Windows.[104][105]
  • 8 TB of kernel mode virtual address space for the operating system.[104] As with the user mode address space, this is a 4096-fold increase over 32-bit Windows versions. The increased space primarily benefits the file system cache and kernel mode "heaps" (non-paged pool and paged pool). Windows only uses a total of 16 TB out of the 256 TB implemented by the processors because early AMD64 processors lacked a CMPXCHG16B instruction.[106]

Under Windows 8.1 and Windows Server 2012 R2, both user mode and kernel mode virtual address spaces have been extended to 128 TB.[22] These versions of Windows will not install on processors that lack the CMPXCHG16B instruction.

The following additional characteristics apply to all x64 versions of Windows:

  • Ability to run existing 32-bit applications (.exe programs) and dynamic link libraries (.dlls) using WoW64 if WoW64 is supported on that version. Furthermore, a 32-bit program, if it was linked with the "large address aware" option,[103] can use up to 4 GB of virtual address space in 64-bit Windows, instead of the default 2 GB (optional 3 GB with /3GB boot option and "large address aware" link option) offered by 32-bit Windows.[107] Unlike the use of the /3GB boot option on x86, this does not reduce the kernel mode virtual address space available to the operating system. 32-bit applications can, therefore, benefit from running on x64 Windows even if they are not recompiled for x86-64.
  • Both 32- and 64-bit applications, if not linked with "large address aware", are limited to 2 GB of virtual address space.
  • Ability to use up to 128 GB (Windows XP/Vista), 192 GB (Windows 7), 512 GB (Windows 8), 1 TB (Windows Server 2003), 2 TB (Windows Server 2008/Windows 10), 4 TB (Windows Server 2012), or 24 TB (Windows Server 2016/2019) of physical random access memory (RAM).[108]
  • LLP64 data model: in C/C++, "int" and "long" types are 32 bits wide, "long long" is 64 bits, while pointers and types derived from pointers are 64 bits wide.
  • Kernel mode device drivers must be 64-bit versions; there is no way to run 32-bit kernel mode executables within the 64-bit operating system. User mode device drivers can be either 32-bit or 64-bit.
  • 16-bit Windows (Win16) and DOS applications will not run on x86-64 versions of Windows due to the removal of the virtual DOS machine subsystem (NTVDM) which relied upon the ability to use virtual 8086 mode. Virtual 8086 mode cannot be entered while running in long mode.
  • Full implementation of the NX (No Execute) page protection feature. This is also implemented on recent 32-bit versions of Windows when they are started in PAE mode.
  • Instead of FS segment descriptor on x86 versions of the Windows NT family, GS segment descriptor is used to point to two operating system defined structures: Thread Information Block (NT_TIB) in user mode and Processor Control Region (KPCR) in kernel mode. Thus, for example, in user mode GS:0 is the address of the first member of the Thread Information Block. Maintaining this convention made the x86-64 port easier, but required AMD to retain the function of the FS and GS segments in long mode – even though segmented addressing per se is not really used by any modern operating system.[104]
  • Early reports claimed that the operating system scheduler would not save and restore the x87 FPU machine state across thread context switches. Observed behavior shows that this is not the case: the x87 state is saved and restored, except for kernel mode-only threads (a limitation that exists in the 32-bit version as well). The most recent documentation available from Microsoft states that the x87/MMX/3DNow! instructions may be used in long mode, but that they are deprecated and may cause compatibility problems in the future.[107] (3DNow! is no longer available on AMD processors, with the exception of the PREFETCH and PREFETCHW instructions,[109] which are also supported on Intel processors as of Broadwell.)
  • Some components like Jet Database Engine and Data Access Objects will not be ported to 64-bit architectures such as x86-64 and IA-64.[110][111][112]
  • Microsoft Visual Studio can compile native applications to target either the x86-64 architecture, which can run only on 64-bit Microsoft Windows, or the IA-32 architecture, which can run as a 32-bit application on 32-bit Microsoft Windows or 64-bit Microsoft Windows in WoW64 emulation mode. Managed applications can be compiled either in IA-32, x86-64 or AnyCPU modes. Software created in the first two modes behave like their IA-32 or x86-64 native code counterparts respectively; When using the AnyCPU mode, however, applications in 32-bit versions of Microsoft Windows run as 32-bit applications, while they run as a 64-bit application in 64-bit editions of Microsoft Windows.

Video game consoles edit

Both the PlayStation 4 and Xbox One, and all variants of those consoles, incorporate AMD x86-64 processors, based on the Jaguar microarchitecture.[113][114] Firmware and games are written in x86-64 code; no legacy x86 code is involved.

The current generation, the PlayStation 5 and the Xbox Series X and Series S respectively, also incorporate AMD x86-64 processors, based on the Zen 2 microarchitecture.[115][116]

Although considered a PC, the Steam Deck uses a custom AMD x86-64 accelerated processing unit (APU), based on the Zen 2 microarchitecture.[117]

Industry naming conventions edit

Since AMD64 and Intel 64 are substantially similar, many software and hardware products use one vendor-neutral term to indicate their compatibility with both implementations. AMD's original designation for this processor architecture, "x86-64", is still used for this purpose,[2] as is the variant "x86_64".[3][4] Other companies, such as Microsoft[6] and Sun Microsystems/Oracle Corporation,[5] use the contraction "x64" in marketing material.

The term IA-64 refers to the Itanium processor, and should not be confused with x86-64, as it is a completely different instruction set.

Many operating systems and products, especially those that introduced x86-64 support prior to Intel's entry into the market, use the term "AMD64" or "amd64" to refer to both AMD64 and Intel 64.

  • amd64
    • Most BSD systems such as FreeBSD, MidnightBSD, NetBSD and OpenBSD refer to both AMD64 and Intel 64 under the architecture name "amd64".
    • Some Linux distributions such as Debian, Ubuntu, Gentoo Linux refer to both AMD64 and Intel 64 under the architecture name "amd64".
    • Microsoft Windows's x64 versions use the AMD64 moniker internally to designate various components which use or are compatible with this architecture. For example, the environment variable PROCESSOR_ARCHITECTURE is assigned the value "AMD64" as opposed to "x86" in 32-bit versions, and the system directory on a Windows x64 Edition installation CD-ROM is named "AMD64", in contrast to "i386" in 32-bit versions.[118]
    • Sun's Solaris's isalist command identifies both AMD64- and Intel 64-based systems as "amd64".
    • Java Development Kit (JDK): the name "amd64" is used in directory names containing x86-64 files.
  • x86_64

Licensing edit

x86-64/AMD64 was solely developed by AMD. AMD holds patents on techniques used in AMD64;[120][121][122] those patents must be licensed from AMD in order to implement AMD64. Intel entered into a cross-licensing agreement with AMD, licensing to AMD their patents on existing x86 techniques, and licensing from AMD their patents on techniques used in x86-64.[123] In 2009, AMD and Intel settled several lawsuits and cross-licensing disagreements, extending their cross-licensing agreements.[124][125][126]

See also edit

Notes edit

  1. ^ Various names are used for the instruction set. Prior to the launch, x86-64 and x86_64 were used, while upon the release AMD named it AMD64.[1] Intel initially used the names IA-32e and EM64T before finally settling on "Intel 64" for its implementation. Some in the industry, including Apple,[2][3][4] use x86-64 and x86_64, while others, notably Sun Microsystems[5] (now Oracle Corporation) and Microsoft,[6] use x64. The BSD family of OSs and several Linux distributions[7][8] use AMD64, as does Microsoft Windows internally.[9][10]
  2. ^ In practice, 64-bit operating systems generally do not support 16-bit applications, although modern versions of Microsoft Windows contain a limited workaround that effectively supports 16-bit InstallShield and Microsoft ACME installers by silently substituting them with 32-bit code.[12]
  1. ^ The Register reported that the stepping G1 (0F49h) of Pentium 4 will sample on October 17 and ship in volume on November 14.[64] However, Intel's document says that samples are available on September 9, whereas October 17 is the "date of first availability of post-conversion material", which Intel defines as "the projected date that a customer may expect to receive the post-conversion materials. ... customers should be prepared to receive the post-converted materials on this date".[65]

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External links edit

  • AMD Developer Guides, Manuals & ISA Documents
  • x86-64: Extending the x86 architecture to 64-bits – technical talk by the architect of AMD64 (), and second talk by the same speaker ()
  • Intel tweaks EM64T for full AMD64 compatibility
  • Analyst: Intel Reverse-Engineered AMD64
  • Early report of differences between Intel IA32e and AMD64
  • Porting to 64-bit GNU/Linux Systems, by Andreas Jaeger from GCC Summit 2003. An excellent paper explaining almost all practical aspects for a transition from 32-bit to 64-bit.
  • Intel 64 Architecture
  • Memory Limits for Windows Releases

December 18, 2023
intel, redirects, here, intel, architecture, itanium, chips, redirects, here, york, city, route, york, city, also, known, amd64, intel, note, version, instruction, first, announced, 1999, introduced, modes, operation, mode, compatibility, mode, along, with, le. Intel 64 redirects here For the Intel 64 bit architecture in Itanium chips see IA 64 x64 redirects here For the New York City bus route see X64 New York City bus x86 64 also known as x64 x86 64 AMD64 and Intel 64 note 1 is a 64 bit version of the x86 instruction set first announced in 1999 It introduced two new modes of operation 64 bit mode and compatibility mode along with a new 4 level paging mode AMD Opteron the first CPU to introduce the x86 64 extensions in April 2003The five volume set of the x86 64 Architecture Programmer s Manual as published and distributed by AMD in 2002With 64 bit mode and the new paging mode it supports vastly larger amounts of virtual memory and physical memory than was possible on its 32 bit predecessors allowing programs to store larger amounts of data in memory x86 64 also expands general purpose registers to 64 bit and expands the number of them from 8 some of which had limited or fixed functionality e g for stack management to 16 fully general and provides numerous other enhancements Floating point arithmetic is supported via mandatory SSE2 like instructions and x87 MMX style registers are generally not used but still available even in 64 bit mode instead a set of 16 vector registers 128 bits each is used Each register can store one or two double precision numbers or one to four single precision numbers or various integer formats In 64 bit mode instructions are modified to support 64 bit operands and 64 bit addressing mode The compatibility mode defined in the architecture allows 16 bit and 32 bit user applications to run unmodified coexisting with 64 bit applications if the 64 bit operating system supports them 11 note 2 As the full x86 16 bit and 32 bit instruction sets remain implemented in hardware without any intervening emulation these older executables can run with little or no performance penalty 13 while newer or modified applications can take advantage of new features of the processor design to achieve performance improvements Also a processor supporting x86 64 still powers on in real mode for full backward compatibility with the 8086 as x86 processors supporting protected mode have done since the 80286 The original specification created by AMD and released in 2000 has been implemented by AMD Intel and VIA The AMD K8 microarchitecture in the Opteron and Athlon 64 processors was the first to implement it This was the first significant addition to the x86 architecture designed by a company other than Intel Intel was forced to follow suit and introduced a modified NetBurst family which was software compatible with AMD s specification VIA Technologies introduced x86 64 in their VIA Isaiah architecture with the VIA Nano The x86 64 architecture was quickly adopted for desktop and laptop personal computers and servers which were commonly configured for 16GB of memory or more It has effectively replaced the discontinued Intel Itanium architecture formerly IA 64 which was originally intended to replace the x86 architecture x86 64 and Itanium are not compatible on the native instruction set level and operating systems and applications compiled for one architecture cannot be run on the other natively Contents 1 AMD64 1 1 History 1 2 Implementations 1 3 Architectural features 1 4 Virtual address space details 1 4 1 Canonical form addresses 1 4 2 Page table structure 1 4 3 Operating system limits 1 5 Physical address space details 1 6 Operating modes 1 6 1 Long mode 1 6 2 Legacy mode 1 6 2 1 Protected mode 1 6 2 2 Real mode 2 Intel 64 2 1 History 2 2 Implementations 2 3 x86 S 3 VIA s x86 64 implementation 4 Microarchitecture levels 5 Differences between AMD64 and Intel 64 5 1 Recent implementations 5 2 Older implementations 6 Adoption 7 Operating system compatibility and characteristics 7 1 BSD 7 1 1 DragonFly BSD 7 1 2 FreeBSD 7 1 3 NetBSD 7 1 4 OpenBSD 7 2 DOS 7 3 Linux 7 4 macOS 7 5 Solaris 7 6 Windows 8 Video game consoles 9 Industry naming conventions 10 Licensing 11 See also 12 Notes 13 References 14 External linksAMD64 edit nbsp AMD64 logoHistory edit AMD64 also variously referred to by AMD in their literature and documentation as AMD 64 bit Technology and AMD x86 64 Architecture was created as an alternative to the radically different IA 64 architecture designed by Intel and Hewlett Packard which was backward incompatible with IA 32 the 32 bit version of the x86 architecture AMD originally announced AMD64 in 1999 14 with a full specification available in August 2000 15 As AMD was never invited to be a contributing party for the IA 64 architecture and any kind of licensing seemed unlikely the AMD64 architecture was positioned by AMD from the beginning as an evolutionary way to add 64 bit computing capabilities to the existing x86 architecture while supporting legacy 32 bit x86 code as opposed to Intel s approach of creating an entirely new completely x86 incompatible 64 bit architecture with IA 64 The first AMD64 based processor the Opteron was released in April 2003 Implementations edit AMD s processors implementing the AMD64 architecture include Opteron Athlon 64 Athlon 64 X2 Athlon 64 FX Athlon II followed by X2 X3 or X4 to indicate the number of cores and XLT models Turion 64 Turion 64 X2 Sempron Palermo E6 stepping and all Manila models Phenom followed by X3 or X4 to indicate the number of cores Phenom II followed by X2 X3 X4 or X6 to indicate the number of cores FX Fusion APU and Ryzen Epyc citation needed Architectural features edit The primary defining characteristic of AMD64 is the availability of 64 bit general purpose processor registers for example rax 64 bit integer arithmetic and logical operations and 64 bit virtual addresses citation needed The designers took the opportunity to make other improvements as well Notable changes in the 64 bit extensions include 64 bit integer capability All general purpose registers GPRs are expanded from 32 bits to 64 bits and all arithmetic and logical operations memory to register and register to memory operations etc can operate directly on 64 bit integers Pushes and pops on the stack default to 8 byte strides and pointers are 8 bytes wide Additional registers In addition to increasing the size of the general purpose registers the number of named general purpose registers is increased from eight i e eax ecx edx ebx esp ebp esi edi in x86 to 16 i e rax rcx rdx rbx rsp rbp rsi rdi r8 r9 r10 r11 r12 r13 r14 r15 It is therefore possible to keep more local variables in registers rather than on the stack and to let registers hold frequently accessed constants arguments for small and fast subroutines may also be passed in registers to a greater extent AMD64 still has fewer registers than many RISC instruction sets e g PA RISC Power ISA and MIPS have 32 GPRs Alpha 64 bit ARM and SPARC have 31 or VLIW like machines such as the IA 64 which has 128 registers However an AMD64 implementation may have far more internal registers than the number of architectural registers exposed by the instruction set see register renaming For example AMD Zen cores have 168 64 bit integer and 160 128 bit vector floating point physical internal registers Additional XMM SSE registers Similarly the number of 128 bit XMM registers used for Streaming SIMD instructions is also increased from 8 to 16 The traditional x87 FPU register stack is not included in the register file size extension in 64 bit mode compared with the XMM registers used by SSE2 which did get extended The x87 register stack is not a simple register file although it does allow direct access to individual registers by low cost exchange operations Larger virtual address space The AMD64 architecture defines a 64 bit virtual address format of which the low order 48 bits are used in current implementations 11 120 This allows up to 256 TB 248 bytes of virtual address space The architecture definition allows this limit to be raised in future implementations to the full 64 bits 11 2 3 13 117 120 extending the virtual address space to 16 EB 264 bytes 16 This is compared to just 4 GB 232 bytes for the x86 17 This means that very large files can be operated on by mapping the entire file into the process s address space which is often much faster than working with file read write calls rather than having to map regions of the file into and out of the address space Larger physical address space The original implementation of the AMD64 architecture implemented 40 bit physical addresses and so could address up to 1 TB 240 bytes of RAM 11 24 Current implementations of the AMD64 architecture starting from AMD 10h microarchitecture extend this to 48 bit physical addresses 18 and therefore can address up to 256 TB 248 bytes of RAM The architecture permits extending this to 52 bits in the future 11 24 19 limited by the page table entry format 11 131 this would allow addressing of up to 4 PB of RAM For comparison 32 bit x86 processors are limited to 64 GB of RAM in Physical Address Extension PAE mode 20 or 4 GB of RAM without PAE mode 11 4 Larger physical address space in legacy mode When operating in legacy mode the AMD64 architecture supports Physical Address Extension PAE mode as do most current x86 processors but AMD64 extends PAE from 36 bits to an architectural limit of 52 bits of physical address Any implementation therefore allows the same physical address limit as under long mode 11 24 Instruction pointer relative data access Instructions can now reference data relative to the instruction pointer RIP register This makes position independent code as is often used in shared libraries and code loaded at run time more efficient SSE instructions The original AMD64 architecture adopted Intel s SSE and SSE2 as core instructions These instruction sets provide a vector supplement to the scalar x87 FPU for the single precision and double precision data types SSE2 also offers integer vector operations for data types ranging from 8bit to 64bit precision This makes the vector capabilities of the architecture on par with those of the most advanced x86 processors of its time These instructions can also be used in 32 bit mode The proliferation of 64 bit processors has made these vector capabilities ubiquitous in home computers allowing the improvement of the standards of 32 bit applications The 32 bit edition of Windows 8 for example requires the presence of SSE2 instructions 21 SSE3 instructions and later Streaming SIMD Extensions instruction sets are not standard features of the architecture No Execute bit The No Execute bit or NX bit bit 63 of the page table entry allows the operating system to specify which pages of virtual address space can contain executable code and which cannot An attempt to execute code from a page tagged no execute will result in a memory access violation similar to an attempt to write to a read only page This should make it more difficult for malicious code to take control of the system via buffer overrun or unchecked buffer attacks A similar feature has been available on x86 processors since the 80286 as an attribute of segment descriptors however this works only on an entire segment at a time Segmented addressing has long been considered an obsolete mode of operation and all current PC operating systems in effect bypass it setting all segments to a base address of zero and in their 32 bit implementation a size of 4 GB AMD was the first x86 family vendor to implement no execute in linear addressing mode The feature is also available in legacy mode on AMD64 processors and recent Intel x86 processors when PAE is used Removal of older features A few system programming features of the x86 architecture were either unused or underused in modern operating systems and are either not available on AMD64 in long 64 bit and compatibility mode or exist only in limited form These include segmented addressing although the FS and GS segments are retained in vestigial form for use as extra base pointers to operating system structures 11 70 the task state switch mechanism and virtual 8086 mode These features remain fully implemented in legacy mode allowing these processors to run 32 bit and 16 bit operating systems without modifications Some instructions that proved to be rarely useful are not supported in 64 bit mode including saving restoring of segment registers on the stack saving restoring of all registers PUSHA POPA decimal arithmetic BOUND and INTO instructions and far jumps and calls with immediate operands Virtual address space details edit Canonical form addresses edit Canonical address space implementations diagrams not to scale nbsp Current 48 bit implementation nbsp 57 bit implementation nbsp 64 bit implementation Although virtual addresses are 64 bits wide in 64 bit mode current implementations and all chips that are known to be in the planning stages do not allow the entire virtual address space of 264 bytes 16 EB to be used This would be approximately four billion times the size of the virtual address space on 32 bit machines Most operating systems and applications will not need such a large address space for the foreseeable future so implementing such wide virtual addresses would simply increase the complexity and cost of address translation with no real benefit AMD therefore decided that in the first implementations of the architecture only the least significant 48 bits of a virtual address would actually be used in address translation page table lookup 11 120 In addition the AMD specification requires that the most significant 16 bits of any virtual address bits 48 through 63 must be copies of bit 47 in a manner akin to sign extension If this requirement is not met the processor will raise an exception 11 131 Addresses complying with this rule are referred to as canonical form 11 130 Canonical form addresses run from 0 through 00007FFF FFFFFFFF and from FFFF8000 00000000 through FFFFFFFF FFFFFFFF for a total of 256 TB of usable virtual address space This is still 65 536 times larger than the virtual 4 GB address space of 32 bit machines This feature eases later scalability to true 64 bit addressing Many operating systems including but not limited to the Windows NT family take the higher addressed half of the address space named kernel space for themselves and leave the lower addressed half user space for application code user mode stacks heaps and other data regions 22 The canonical address design ensures that every AMD64 compliant implementation has in effect two memory halves the lower half starts at 00000000 00000000 and grows upwards as more virtual address bits become available while the higher half is docked to the top of the address space and grows downwards Also enforcing the canonical form of addresses by checking the unused address bits prevents their use by the operating system in tagged pointers as flags privilege markers etc as such use could become problematic when the architecture is extended to implement more virtual address bits The first versions of Windows for x64 did not even use the full 256 TB they were restricted to just 8 TB of user space and 8 TB of kernel space 22 Windows did not support the entire 48 bit address space until Windows 8 1 which was released in October 2013 22 Page table structure edit nbsp The 64 bit addressing mode long mode is a superset of Physical Address Extensions PAE because of this page sizes may be 4 KB 212 bytes or 2 MB 221 bytes 11 120 Long mode also supports page sizes of 1 GB 230 bytes 11 120 Rather than the three level page table system used by systems in PAE mode systems running in long mode use four levels of page table PAE s Page Directory Pointer Table is extended from four entries to 512 and an additional Page Map Level 4 PML4 Table is added containing 512 entries in 48 bit implementations 11 131 A full mapping hierarchy of 4 KB pages for the whole 48 bit space would take a bit more than 512 GB of memory about 0 195 of the 256 TB virtual space 64 bit page table entry Bits 63 62 52 51 32Content NX reserved Bit 51 32 of base addressBits 31 12 11 9 8 7 6 5 4 3 2 1 0Content Bit 31 12 of base address ign G PAT D A PCD PWT U S R W PIntel has implemented a scheme with a 5 level page table which allows Intel 64 processors to support a 57 bit virtual address space 23 Further extensions may allow full 64 bit virtual address space and physical memory by expanding the page table entry size to 128 bit and reduce page walks in the 5 level hierarchy by using a larger 64 KB page allocation size that still supports 4 KB page operations for backward compatibility 24 Operating system limits edit The operating system can also limit the virtual address space Details where applicable are given in the Operating system compatibility and characteristics section Physical address space details edit Current AMD64 processors support a physical address space of up to 248 bytes of RAM or 256 TB 18 However as of 2020 update there were no known x86 64 motherboards that support 256 TB of RAM 25 26 27 28 failed verification The operating system may place additional limits on the amount of RAM that is usable or supported Details on this point are given in the Operating system compatibility and characteristics section of this article Operating modes edit The architecture has two primary modes of operation long mode and legacy mode Operating Operating system required Type of code being run Size in bits No of general purpose registersmode sub mode addresses operands default in italics Long mode 64 bit mode 64 bit OS 64 bit UEFI firmware or the previous two interacting via a 64 bit firmware s UEFI interface 64 bit 64 8 16 32 64 16Compatibility mode Bootloader or 64 bit OS 32 bit 32 8 16 32 816 bit protected mode 16 8 16 32 8Legacy mode Protected mode Bootloader 32 bit OS 32 bit UEFI firmware or the latter two interacting via the firmware s UEFI interface 32 bit 32 8 16 32 816 bit protected mode OS 16 bit protected mode 16 8 16 32 m 1 8Virtual 8086 mode 16 bit protected mode or 32 bit OS subset of real mode 16 8 16 32 m 1 8Unreal mode Bootloader or real mode OS real mode 16 20 32 8 16 32 m 1 8Real mode Bootloader real mode OS or any OS interfacing with a firmware s BIOS interface 29 real mode 16 20 21 8 16 32 m 1 8 a b c d Note that 16 bit code written for the 80286 and below does not use 32 bit operand instructions Code written for the 80386 and above can use the operand size override prefix 0x66 Normally this prefix is used by protected and long mode code for the purpose of using 16 bit operands as that code would be running in a code segment with a default operand size of 32 bits In real mode the default operand size is 16 bits so the 0x66 prefix is interpreted differently changing operand size to 32 bits nbsp State diagram of the x86 64 operating modesLong mode edit Main article Long mode Long mode is the architecture s intended primary mode of operation it is a combination of the processor s native 64 bit mode and a combined 32 bit and 16 bit compatibility mode It is used by 64 bit operating systems Under a 64 bit operating system 64 bit programs run under 64 bit mode and 32 bit and 16 bit protected mode applications that do not need to use either real mode or virtual 8086 mode in order to execute at any time run under compatibility mode Real mode programs and programs that use virtual 8086 mode at any time cannot be run in long mode unless those modes are emulated in software 11 11 However such programs may be started from an operating system running in long mode on processors supporting VT x or AMD V by creating a virtual processor running in the desired mode Since the basic instruction set is the same there is almost no performance penalty for executing protected mode x86 code This is unlike Intel s IA 64 where differences in the underlying instruction set mean that running 32 bit code must be done either in emulation of x86 making the process slower or with a dedicated x86 coprocessor However on the x86 64 platform many x86 applications could benefit from a 64 bit recompile due to the additional registers in 64 bit code and guaranteed SSE2 based FPU support which a compiler can use for optimization However applications that regularly handle integers wider than 32 bits such as cryptographic algorithms will need a rewrite of the code handling the huge integers in order to take advantage of the 64 bit registers Legacy mode edit Legacy mode is the mode that the processor is in when it is not in long mode 11 14 In this mode the processor acts like an older x86 processor and only 16 bit and 32 bit code can be executed Legacy mode allows for a maximum of 32 bit virtual addressing which limits the virtual address space to 4 GB 11 14 24 118 64 bit programs cannot be run from legacy mode Protected mode edit Protected mode is made into a submode of legacy mode 11 14 It is the submode that 32 bit operating systems and 16 bit protected mode operating systems operate in when running on an x86 64 CPU 11 14 Real mode edit Real mode is the initial mode of operation when the processor is initialized and is a submode of legacy mode It is backwards compatible with the original Intel 8086 and Intel 8088 processors Real mode is primarily used today by operating system bootloaders which are required by the architecture to configure virtual memory details before transitioning to higher modes This mode is also used by any operating system that needs to communicate with the system firmware with a traditional BIOS style interface 29 Intel 64 editIntel 64 is Intel s implementation of x86 64 used and implemented in various processors made by Intel History edit Historically AMD has developed and produced processors with instruction sets patterned after Intel s original designs but with x86 64 roles were reversed Intel found itself in the position of adopting the ISA that AMD created as an extension to Intel s own x86 processor line Intel s project was originally codenamed Yamhill 30 after the Yamhill River in Oregon s Willamette Valley After several years of denying its existence Intel announced at the February 2004 IDF that the project was indeed underway Intel s chairman at the time Craig Barrett admitted that this was one of their worst kept secrets 31 32 Intel s name for this instruction set has changed several times The name used at the IDF was CT 33 presumably original research for Clackamas Technology another codename from an Oregon river within weeks they began referring to it as IA 32e for IA 32 extensions and in March 2004 unveiled the official name EM64T Extended Memory 64 Technology In late 2006 Intel began instead using the name Intel 64 for its implementation paralleling AMD s use of the name AMD64 34 The first processor to implement Intel 64 was the multi socket processor Xeon code named Nocona in June 2004 In contrast the initial Prescott chips February 2004 did not enable this feature Intel subsequently began selling Intel 64 enabled Pentium 4s using the E0 revision of the Prescott core being sold on the OEM market as the Pentium 4 model F The E0 revision also adds eXecute Disable XD Intel s name for the NX bit to Intel 64 and has been included in then current Xeon code named Irwindale Intel s official launch of Intel 64 under the name EM64T at that time in mainstream desktop processors was the N0 stepping Prescott 2M The first Intel mobile processor implementing Intel 64 is the Merom version of the Core 2 processor which was released on July 27 2006 None of Intel s earlier notebook CPUs Core Duo Pentium M Celeron M Mobile Pentium 4 implement Intel 64 Implementations edit Intel s processors implementing the Intel64 architecture include the Pentium 4 F series 5x1 series 506 and 516 Celeron D models 3x1 3x6 355 347 352 360 and 365 and all later Celerons all models of Xeon since Nocona all models of Pentium Dual Core processors since Merom 2M the Atom 230 330 D410 D425 D510 D525 N450 N455 N470 N475 N550 N570 N2600 and N2800 all versions of the Pentium D Pentium Extreme Edition Core 2 Core i9 Core i7 Core i5 and Core i3 processors and the Xeon Phi 7200 series processors x86 S edit x86 S is a proposed simplification of Intel 64 announced in May 2023 35 The new architecture would remove support for 16 bit and 32 bit operating systems while 32 bit programs will still run under a 64 bit OS A CPU would no longer have legacy mode and start directly in 64 bit long mode There will be a way to switch to 5 level paging without going through the unpaged mode Specific removed features include 36 Segmentation gates 32 bit ring 0 VT x will no longer emulate this feature Rings 1 and 2 Ring 3 I O port IN OUT access see port mapped I O String port I O INS OUTS Real mode including huge real mode 16 bit protected mode VM86 16 bit addressing mode VT x will no longer provide unrestricted mode 8259 support the only APIC supported would be X2APIC Some unused operating system mode bits Intel believes the change follows logically after the removal of A20 gate in 2008 and the ceasing of 16 bit and 32 bit OS support in Intel firmware in 2020 Support for legacy operating systems would be accomplished via hardware accelerated virtualization 36 VIA s x86 64 implementation editVIA Technologies introduced their first implementation of the x86 64 architecture in 2008 after five years of development by its CPU division Centaur Technology 37 Codenamed Isaiah the 64 bit architecture was unveiled on January 24 2008 38 and launched on May 29 under the VIA Nano brand name 39 The processor supports a number of VIA specific x86 extensions designed to boost efficiency in low power appliances It is expected that the Isaiah architecture will be twice as fast in integer performance and four times as fast in floating point performance as the previous generation VIA Esther at an equivalent clock speed Power consumption is also expected to be on par with the previous generation VIA CPUs with thermal design power ranging from 5 W to 25 W 40 Being a completely new design the Isaiah architecture was built with support for features like the x86 64 instruction set and x86 virtualization which were unavailable on its predecessors the VIA C7 line while retaining their encryption extensions Microarchitecture levels editIn 2020 through a collaboration between AMD Intel Red Hat and SUSE three microarchitecture levels or feature levels on top of the x86 64 baseline were defined x86 64 v2 x86 64 v3 and x86 64 v4 41 42 These levels define specific features that can be targeted by programmers to provide compile time optimizations The features exposed by each level are as follows 43 CPU microarchitecture levels Level CPU features Example instruction Involved microprocessorsx86 64 v1 CMOV cmov all x86 64 CPUsCX8 cmpxchg8bFPU fldFXSR fxsaveMMX emmsOSFXSR fxsaveSCE syscallSSE cvtss2siSSE2 cvtpi2pdx86 64 v2 CMPXCHG16B cmpxchg16b circa 2009 Nehalem and Jaguar Also Atom Silvermont 2013 VIA Nano and Eden C 2015 LAHF SAHF lahfPOPCNT popcntSSE3 addsubpdSSE4 1 blendpdSSE4 2 pcmpestriSSSE3 phadddx86 64 v3 AVX vzeroall circa 2015 Haswell and Excavator Also Atom Gracemont 2021 QEMU emulation as of version 7 2 44 45 AVX2 vpermdBMI1 andnBMI2 bzhiF16C vcvtph2psFMA vfmadd132pdLZCNT lzcntMOVBE movbeOSXSAVE xgetbvx86 64 v4 AVX512F kmovw AVX 512 s general purpose subset Skylake X Skylake SP 2017 Zen 4 2022 AVX512BW vdbpsadbwAVX512CD vplzcntdAVX512DQ vpmullqAVX512VL All levels include features found in the previous levels Instruction set extensions not concerned with general purpose computation including AES NI and RDRAND are excluded from the level requirements Differences between AMD64 and Intel 64 editAlthough nearly identical there are some differences between the two instruction sets in the semantics of a few seldom used machine instructions or situations which are mainly used for system programming 46 Compilers generally produce executables i e machine code that avoid any differences at least for ordinary application programs This is therefore of interest mainly to developers of compilers operating systems and similar which must deal with individual and special system instructions Recent implementations edit Intel 64 s BSF and BSR instructions act differently than AMD64 s when the source is zero and the operand size is 32 bits The processor sets the zero flag and leaves the upper 32 bits of the destination undefined citation needed Note that Intel documents that the destination register has an undefined value in this case but in practice in silicon implements the same behaviour as AMD destination unmodified The separate claim about maybe not preserving bits in the upper 32 has not been verified but has only been ruled out for Core 2 and Skylake 47 not all Intel microarchitectures like 64 bit Pentium 4 or low power Atom AMD64 requires a different microcode update format and control MSRs model specific registers while Intel 64 implements microcode update unchanged from their 32 bit only processors Intel 64 lacks some MSRs that are considered architectural in AMD64 These include SYSCFG TOP MEM and TOP MEM2 Intel 64 allows SYSCALL SYSRET only in 64 bit mode not in compatibility mode 48 and allows SYSENTER SYSEXIT in both modes 49 AMD64 lacks SYSENTER SYSEXIT in both sub modes of long mode 11 33 In 64 bit mode near branches with the 66H operand size override prefix behave differently Intel 64 ignores this prefix the instruction has a 32 bit sign extended offset and instruction pointer is not truncated AMD64 uses a 16 bit offset field in the instruction and clears the top 48 bits of instruction pointer On Intel 64 but not AMD64 the REX W prefix can be used with the far pointer instructions LFS LGS LSS JMP FAR CALL FAR to increase the size of their far pointer argument to 80 bits 64 bit offset 16 bit segment Intel 64 lacks the ability to save and restore a reduced and thus faster version of the floating point state involving the FXSAVE and FXRSTOR instructions clarification needed AMD processors ever since Opteron Rev E and Athlon 64 Rev D have reintroduced limited support for segmentation via the Long Mode Segment Limit Enable LMSLE bit to ease virtualization of 64 bit guests 50 51 LMLSE support was removed in the Zen 3 processor 52 When returning to a non canonical address using SYSRET AMD64 processors execute the general protection fault handler in privilege level 3 53 while on Intel 64 processors it is executed in privilege level 0 54 Older implementations edit This section needs to be updated The reason given is future tense relating to processors that have been out for years dates with day and month but no year Please help update this article to reflect recent events or newly available information January 2023 The AMD64 processors prior to Revision F 55 distinguished by the switch from DDR to DDR2 memory and new sockets AM2 F and S1 of 2006 lacked the CMPXCHG16B instruction which is an extension of the CMPXCHG8B instruction present on most post 80486 processors Similar to CMPXCHG8B CMPXCHG16B allows for atomic operations on octa words 128 bit values This is useful for parallel algorithms that use compare and swap on data larger than the size of a pointer common in lock free and wait free algorithms Without CMPXCHG16B one must use workarounds such as a critical section or alternative lock free approaches 56 Its absence also prevents 64 bit Windows prior to Windows 8 1 from having a user mode address space larger than 8 TB 57 The 64 bit version of Windows 8 1 requires the instruction 58 Early AMD64 and Intel 64 CPUs lacked LAHF and SAHF instructions in 64 bit mode AMD introduced these instructions also in 64 bit mode with their 90 nm revision D processors starting with Athlon 64 in October 2004 59 60 Intel introduced the instructions in October 2005 with the 0F47h and later revisions of NetBurst 66 The 64 bit version of Windows 8 1 requires this feature 58 Early Intel CPUs with Intel 64 also lack the NX bit of the AMD64 architecture It was added in the stepping E0 0F41h Pentium 4 in October 2004 67 This feature is required by all versions of Windows 8 Early Intel 64 implementations had a 36 bit 64 GB physical addressing of memory while original AMD64 implementations had a 40 bit 1 TB physical addressing Intel used the 40 bit physical addressing first on Xeon MP Potomac launched on 29 March 2005 68 The difference is not a difference of the user visible ISAs In 2007 AMD 10h based Opteron was the first to provide a 48 bit 256 TB physical address space 69 70 Intel 64 s physical addressing was extended to 44 bits 16 TB in Nehalem EX in 2010 71 and to 46 bits 64 TB in Sandy Bridge E in 2011 72 73 With the Ice Lake 3rd gen Xeon Scalable processors Intel increased the virtual addressing to 57 bits 128 PB and physical to 52 bits 4 PB in 2021 necessitating a 5 level paging 74 The following year AMD64 added the same in 4th generation EPYC Genoa 75 Non server CPUs retain smaller address spaces for longer Adoption edit nbsp An area chart showing the representation of different families of microprocessors in the TOP500 supercomputer ranking list from 1993 to 2020 76 In supercomputers tracked by TOP500 the appearance of 64 bit extensions for the x86 architecture enabled 64 bit x86 processors by AMD and Intel to replace most RISC processor architectures previously used in such systems including PA RISC SPARC Alpha and others as well as 32 bit x86 even though Intel itself initially tried unsuccessfully to replace x86 with a new incompatible 64 bit architecture in the Itanium processor As of 2020 update a Fujitsu A64FX based supercomputer called Fugaku is number one The first ARM based supercomputer appeared on the list in 2018 77 and in recent years non CPU architecture co processors GPGPU have also played a big role in performance Intel s Xeon Phi Knights Corner coprocessors which implement a subset of x86 64 with some vector extensions 78 are also used along with x86 64 processors in the Tianhe 2 supercomputer 79 Operating system compatibility and characteristics editThe following operating systems and releases support the x86 64 architecture in long mode BSD edit DragonFly BSD edit Preliminary infrastructure work was started in February 2004 for a x86 64 port 80 This development later stalled Development started again during July 2007 81 and continued during Google Summer of Code 2008 and SoC 2009 82 83 The first official release to contain x86 64 support was version 2 4 84 FreeBSD edit FreeBSD first added x86 64 support under the name amd64 as an experimental architecture in 5 1 RELEASE in June 2003 It was included as a standard distribution architecture as of 5 2 RELEASE in January 2004 Since then FreeBSD has designated it as a Tier 1 platform The 6 0 RELEASE version cleaned up some quirks with running x86 executables under amd64 and most drivers work just as they do on the x86 architecture Work is currently being done to integrate more fully the x86 application binary interface ABI in the same manner as the Linux 32 bit ABI compatibility currently works NetBSD edit x86 64 architecture support was first committed to the NetBSD source tree on June 19 2001 As of NetBSD 2 0 released on December 9 2004 NetBSD amd64 is a fully integrated and supported port 32 bit code is still supported in 64 bit mode with a netbsd 32 kernel compatibility layer for 32 bit syscalls The NX bit is used to provide non executable stack and heap with per page granularity segment granularity being used on 32 bit x86 OpenBSD edit OpenBSD has supported AMD64 since OpenBSD 3 5 released on May 1 2004 Complete in tree implementation of AMD64 support was achieved prior to the hardware s initial release because AMD had loaned several machines for the project s hackathon that year OpenBSD developers have taken to the platform because of its support for the NX bit which allowed for an easy implementation of the W X feature The code for the AMD64 port of OpenBSD also runs on Intel 64 processors which contains cloned use of the AMD64 extensions but since Intel left out the page table NX bit in early Intel 64 processors there is no W X capability on those Intel CPUs later Intel 64 processors added the NX bit under the name XD bit Symmetric multiprocessing SMP works on OpenBSD s AMD64 port starting with release 3 6 on November 1 2004 DOS edit This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources X86 64 news newspapers books scholar JSTOR December 2022 Learn how and when to remove this template message It is possible to enter long mode under DOS without a DOS extender 85 but the user must return to real mode in order to call BIOS or DOS interrupts It may also be possible to enter long mode with a DOS extender similar to DOS 4GW but more complex since x86 64 lacks virtual 8086 mode DOS itself is not aware of that and no benefits should be expected unless running DOS in an emulation with an adequate virtualization driver backend for example the mass storage interface Linux edit See also Comparison of Linux distributions Instruction set architecture support Linux was the first operating system kernel to run the x86 64 architecture in long mode starting with the 2 4 version in 2001 preceding the hardware s availability 86 87 Linux also provides backward compatibility for running 32 bit executables This permits programs to be recompiled into long mode while retaining the use of 32 bit programs Current Linux distributions ship with x86 64 native kernels and userlands Some such as Arch Linux 88 SUSE Mandriva and Debian allow users to install a set of 32 bit components and libraries when installing off a 64 bit distribution medium thus allowing most existing 32 bit applications to run alongside the 64 bit OS x32 ABI Application Binary Interface introduced in Linux 3 4 allows programs compiled for the x32 ABI to run in the 64 bit mode of x86 64 while only using 32 bit pointers and data fields 89 90 91 Though this limits the program to a virtual address space of 4 GB it also decreases the memory footprint of the program and in some cases can allow it to run faster 89 90 91 64 bit Linux allows up to 128 TB of virtual address space for individual processes and can address approximately 64 TB of physical memory subject to processor and system limitations 92 macOS edit Mac OS X 10 4 7 and higher versions of Mac OS X 10 4 run 64 bit command line tools using the POSIX and math libraries on 64 bit Intel based machines just as all versions of Mac OS X 10 4 and 10 5 run them on 64 bit PowerPC machines No other libraries or frameworks work with 64 bit applications in Mac OS X 10 4 93 The kernel and all kernel extensions are 32 bit only Mac OS X 10 5 supports 64 bit GUI applications using Cocoa Quartz OpenGL and X11 on 64 bit Intel based machines as well as on 64 bit PowerPC machines 94 All non GUI libraries and frameworks also support 64 bit applications on those platforms The kernel and all kernel extensions are 32 bit only Mac OS X 10 6 is the first version of macOS that supports a 64 bit kernel However not all 64 bit computers can run the 64 bit kernel and not all 64 bit computers that can run the 64 bit kernel will do so by default 95 The 64 bit kernel like the 32 bit kernel supports 32 bit applications both kernels also support 64 bit applications 32 bit applications have a virtual address space limit of 4 GB under either kernel 96 97 The 64 bit kernel does not support 32 bit kernel extensions and the 32 bit kernel does not support 64 bit kernel extensions OS X 10 8 includes only the 64 bit kernel but continues to support 32 bit applications it does not support 32 bit kernel extensions however macOS 10 15 includes only the 64 bit kernel and no longer supports 32 bit applications This removal of support has presented a problem for WineHQ and the commercial version CrossOver as it needs to still be able to run 32 bit Windows applications The solution termed wine32on64 was to add thunks that bring the CPU in and out of 32 bit compatibility mode in the nominally 64 bit application 98 99 macOS uses the universal binary format to package 32 and 64 bit versions of application and library code into a single file the most appropriate version is automatically selected at load time In Mac OS X 10 6 the universal binary format is also used for the kernel and for those kernel extensions that support both 32 bit and 64 bit kernels Solaris edit See also illumos Solaris 10 and later releases support the x86 64 architecture For Solaris 10 just as with the SPARC architecture there is only one operating system image which contains a 32 bit kernel and a 64 bit kernel this is labeled as the x64 x86 DVD ROM image The default behavior is to boot a 64 bit kernel allowing both 64 bit and existing or new 32 bit executables to be run A 32 bit kernel can also be manually selected in which case only 32 bit executables will run The isainfo command can be used to determine if a system is running a 64 bit kernel For Solaris 11 only the 64 bit kernel is provided However the 64 bit kernel supports both 32 and 64 bit executables libraries and system calls Windows edit x64 editions of Microsoft Windows client and server Windows XP Professional x64 Edition and Windows Server 2003 x64 Edition were released in March 2005 100 Internally they are actually the same build 5 2 3790 1830 SP1 101 102 as they share the same source base and operating system binaries so even system updates are released in unified packages much in the manner as Windows 2000 Professional and Server editions for x86 Windows Vista which also has many different editions was released in January 2007 Windows 7 was released in July 2009 Windows Server 2008 R2 was sold in only x64 and Itanium editions later versions of Windows Server only offer an x64 edition Versions of Windows for x64 prior to Windows 8 1 and Windows Server 2012 R2 offer the following 8 TB of virtual address space per process accessible from both user mode and kernel mode referred to as the user mode address space An x64 program can use all of this subject to backing store limits on the system and provided it is linked with the large address aware option which is present by default 103 This is a 4096 fold increase over the default 2 GB user mode virtual address space offered by 32 bit Windows 104 105 8 TB of kernel mode virtual address space for the operating system 104 As with the user mode address space this is a 4096 fold increase over 32 bit Windows versions The increased space primarily benefits the file system cache and kernel mode heaps non paged pool and paged pool Windows only uses a total of 16 TB out of the 256 TB implemented by the processors because early AMD64 processors lacked a CMPXCHG16B instruction 106 Under Windows 8 1 and Windows Server 2012 R2 both user mode and kernel mode virtual address spaces have been extended to 128 TB 22 These versions of Windows will not install on processors that lack the CMPXCHG16B instruction The following additional characteristics apply to all x64 versions of Windows Ability to run existing 32 bit applications exe programs and dynamic link libraries dlls using WoW64 if WoW64 is supported on that version Furthermore a 32 bit program if it was linked with the large address aware option 103 can use up to 4 GB of virtual address space in 64 bit Windows instead of the default 2 GB optional 3 GB with 3GB boot option and large address aware link option offered by 32 bit Windows 107 Unlike the use of the 3GB boot option on x86 this does not reduce the kernel mode virtual address space available to the operating system 32 bit applications can therefore benefit from running on x64 Windows even if they are not recompiled for x86 64 Both 32 and 64 bit applications if not linked with large address aware are limited to 2 GB of virtual address space Ability to use up to 128 GB Windows XP Vista 192 GB Windows 7 512 GB Windows 8 1 TB Windows Server 2003 2 TB Windows Server 2008 Windows 10 4 TB Windows Server 2012 or 24 TB Windows Server 2016 2019 of physical random access memory RAM 108 LLP64 data model in C C int and long types are 32 bits wide long long is 64 bits while pointers and types derived from pointers are 64 bits wide Kernel mode device drivers must be 64 bit versions there is no way to run 32 bit kernel mode executables within the 64 bit operating system User mode device drivers can be either 32 bit or 64 bit 16 bit Windows Win16 and DOS applications will not run on x86 64 versions of Windows due to the removal of the virtual DOS machine subsystem NTVDM which relied upon the ability to use virtual 8086 mode Virtual 8086 mode cannot be entered while running in long mode Full implementation of the NX No Execute page protection feature This is also implemented on recent 32 bit versions of Windows when they are started in PAE mode Instead of FS segment descriptor on x86 versions of the Windows NT family GS segment descriptor is used to point to two operating system defined structures Thread Information Block NT TIB in user mode and Processor Control Region KPCR in kernel mode Thus for example in user mode GS 0 is the address of the first member of the Thread Information Block Maintaining this convention made the x86 64 port easier but required AMD to retain the function of the FS and GS segments in long mode even though segmented addressing per se is not really used by any modern operating system 104 Early reports claimed that the operating system scheduler would not save and restore the x87 FPU machine state across thread context switches Observed behavior shows that this is not the case the x87 state is saved and restored except for kernel mode only threads a limitation that exists in the 32 bit version as well The most recent documentation available from Microsoft states that the x87 MMX 3DNow instructions may be used in long mode but that they are deprecated and may cause compatibility problems in the future 107 3DNow is no longer available on AMD processors with the exception of the PREFETCH and PREFETCHW instructions 109 which are also supported on Intel processors as of Broadwell Some components like Jet Database Engine and Data Access Objects will not be ported to 64 bit architectures such as x86 64 and IA 64 110 111 112 Microsoft Visual Studio can compile native applications to target either the x86 64 architecture which can run only on 64 bit Microsoft Windows or the IA 32 architecture which can run as a 32 bit application on 32 bit Microsoft Windows or 64 bit Microsoft Windows in WoW64 emulation mode Managed applications can be compiled either in IA 32 x86 64 or AnyCPU modes Software created in the first two modes behave like their IA 32 or x86 64 native code counterparts respectively When using the AnyCPU mode however applications in 32 bit versions of Microsoft Windows run as 32 bit applications while they run as a 64 bit application in 64 bit editions of Microsoft Windows Video game consoles editBoth the PlayStation 4 and Xbox One and all variants of those consoles incorporate AMD x86 64 processors based on the Jaguar microarchitecture 113 114 Firmware and games are written in x86 64 code no legacy x86 code is involved The current generation the PlayStation 5 and the Xbox Series X and Series S respectively also incorporate AMD x86 64 processors based on the Zen 2 microarchitecture 115 116 Although considered a PC the Steam Deck uses a custom AMD x86 64 accelerated processing unit APU based on the Zen 2 microarchitecture 117 Industry naming conventions editSince AMD64 and Intel 64 are substantially similar many software and hardware products use one vendor neutral term to indicate their compatibility with both implementations AMD s original designation for this processor architecture x86 64 is still used for this purpose 2 as is the variant x86 64 3 4 Other companies such as Microsoft 6 and Sun Microsystems Oracle Corporation 5 use the contraction x64 in marketing material The term IA 64 refers to the Itanium processor and should not be confused with x86 64 as it is a completely different instruction set Many operating systems and products especially those that introduced x86 64 support prior to Intel s entry into the market use the term AMD64 or amd64 to refer to both AMD64 and Intel 64 amd64 Most BSD systems such as FreeBSD MidnightBSD NetBSD and OpenBSD refer to both AMD64 and Intel 64 under the architecture name amd64 Some Linux distributions such as Debian Ubuntu Gentoo Linux refer to both AMD64 and Intel 64 under the architecture name amd64 Microsoft Windows s x64 versions use the AMD64 moniker internally to designate various components which use or are compatible with this architecture For example the environment variable PROCESSOR ARCHITECTURE is assigned the value AMD64 as opposed to x86 in 32 bit versions and the system directory on a Windows x64 Edition installation CD ROM is named AMD64 in contrast to i386 in 32 bit versions 118 Sun s Solaris s isalist command identifies both AMD64 and Intel 64 based systems as amd64 Java Development Kit JDK the name amd64 is used in directory names containing x86 64 files x86 64 The Linux kernel 119 and the GNU Compiler Collection refers to 64 bit architecture as x86 64 Some Linux distributions such as Fedora openSUSE Arch Linux Gentoo Linux refer to this 64 bit architecture as x86 64 Apple macOS refers to 64 bit architecture as x86 64 or x86 64 as seen in the Terminal command arch 3 and in their developer documentation 2 4 Breaking with most other BSD systems DragonFly BSD refers to 64 bit architecture as x86 64 Haiku refers to 64 bit architecture as x86 64 Licensing editx86 64 AMD64 was solely developed by AMD AMD holds patents on techniques used in AMD64 120 121 122 those patents must be licensed from AMD in order to implement AMD64 Intel entered into a cross licensing agreement with AMD 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2012 Smith Ryan November 12 2009 AMD and Intel Settle Their Differences AMD Gets To Go Fabless AnandTech Archived from the original on May 13 2010 External links editAMD Developer Guides Manuals amp ISA Documents x86 64 Extending the x86 architecture to 64 bits technical talk by the architect of AMD64 video archive and second talk by the same speaker video archive AMD s Enhanced Virus Protection Intel tweaks EM64T for full AMD64 compatibility Analyst Intel Reverse Engineered AMD64 Early report of differences between Intel IA32e and AMD64 Porting to 64 bit GNU Linux Systems by Andreas Jaeger from GCC Summit 2003 An excellent paper explaining almost all practical aspects for a transition from 32 bit to 64 bit Intel 64 Architecture Intel Software Network 64 bits TurboIRC COM tutorials including examples of how to of enter protected and long mode the raw way from DOS Seven Steps of Migrating a Program to a 64 bit System Memory Limits for Windows Releases Retrieved from https en wikipedia org w index php title X86 64 amp oldid 1189759887, wikipedia, wiki, book, books, library,

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