Flat memory model or linear memory model refers to a

memory address In computing, a memory address is a reference to a specific memory location used at various levels by software and hardware. Memory addresses are fixed-length sequences of digits conventionally displayed and manipulated as unsigned integers. ...

ing paradigm in which "

memory Memory is the faculty of the mind by which data or information is encoded, stored, and retrieved when needed. It is the retention of information over time for the purpose of influencing future action. If past events could not be remembered ...

appears to the program as a single contiguous address space." The CPU can directly (and linearly)

address An address is a collection of information, presented in a mostly fixed format, used to give the location of a building, apartment, or other structure or a plot of land, generally using political boundaries and street names as references, along ...

all of the available

locations without having to resort to any sort of

memory segmentation Memory segmentation is an operating system memory management technique of division of a computer's primary memory into segments or sections. In a computer system using segmentation, a reference to a memory location includes a value that identifi ...

paging In computer operating systems, memory paging is a memory management scheme by which a computer stores and retrieves data from secondary storage for use in main memory. In this scheme, the operating system retrieves data from secondary storage ...

schemes. Memory management and address translation can still be implemented ''on top of'' a flat memory model in order to facilitate the

operating system An operating system (OS) is system software that manages computer hardware, software resources, and provides common services for computer programs. Time-sharing operating systems schedule tasks for efficient use of the system and may also i ...

's functionality, resource protection, multitasking or to increase the memory capacity beyond the limits imposed by the processor's physical address space, but the key feature of a flat memory model is that the entire memory space is linear, sequential and contiguous. In a simple controller, or in a ''single tasking'' embedded application, where memory management is not needed nor desirable, the flat memory model is the most appropriate, because it provides the simplest interface from the programmer's point of view, with direct access to all memory locations and minimum design complexity. In a general purpose computer system, which requires multitasking, resource allocation, and protection, the flat memory system must be augmented by some memory management scheme, which is typically implemented through a combination of dedicated hardware (inside or outside the CPU) and software built into the operating system. The flat memory model (at the physical addressing level) still provides the greatest flexibility for implementing this type of memory management. The majority of processor architectures implement a flat memory design, including all early 8-bit processors, the Motorola 68000 series, etc. One exception was the original

8086 The 8086 (also called iAPX 86) is a 16-bit microprocessor chip designed by Intel between early 1976 and June 8, 1978, when it was released. The Intel 8088, released July 1, 1979, is a slightly modified chip with an external 8-bit data bus (allowi ...

, Intel's first 16-bit microprocessor, which implemented a crude ''segmented'' memory model which allowed access to more than 64 KiB of memory without the cost of extending all addresses to more than 16-bits.

Memory models

Most modern memory models fall into one of three categories:

Flat memory model

*Simple interface for programmers, clean design *Greatest flexibility due to uniform access speed (segmented memory page switches usually incur varied latency due to longer accesses of other pages, either due to extra CPU logic in changing page, or hardware requirements) *Minimum hardware and CPU real estate for simple controller applications *Maximum execution speed, Simply there isn't any latency due to CPU or logic. *Not suitable for general computing or multitasking operating systems unless enhanced with additional memory management hardware/software; but this is almost always the case in modern CISC processors, which implement advanced memory management and protection technology over a flat memory model.

Linux Linux ( or ) is a family of open-source Unix-like operating systems based on the Linux kernel, an operating system kernel first released on September 17, 1991, by Linus Torvalds. Linux is typically packaged as a Linux distribution, w ...

e.g. uses a flat memory model, see x86 memory segmentation#Practices.

Paged memory model

*Suitable for multitasking, general operating system design, resource protection and allocation *Suitable for virtual memory implementation *More CPU real estate, somewhat lower speed *More complex to program *Rigid page boundaries, not always the most memory efficient *This is the memory model

Pentium Pro The Pentium Pro is a sixth-generation x86 microprocessor developed and manufactured by Intel and introduced on November 1, 1995. It introduced the P6 microarchitecture (sometimes termed i686) and was originally intended to replace the original ...

and newer x86 CPUs use in 32-bit addressing mode when addressing memory using 36-bit addresses. It's called

Physical Address Extension In computing, Physical Address Extension (PAE), sometimes referred to as Page Address Extension, is a memory management feature for the x86 architecture. PAE was first introduced by Intel in the Pentium Pro, and later by AMD in the Athlon proces ...

X86 segmented memory model

*Similar to paged memory, but paging is achieved by the implicit addition of two relatively shifted registers: segment:offset *Variable page boundaries, more efficient and flexible than the paged memory model *Quite complex and awkward from a programmer's point of view *More difficult for compilers *Pages can overlap / poor resource protection and isolation *Many to one address translation correspondence: Many segment:offset combinations resolve to the same physical address *Greater chance of programming errors *Implemented in the original Intel 8086,

8088 The Intel 8088 ("''eighty-eighty-eight''", also called iAPX 88) microprocessor is a variant of the Intel 8086. Introduced on June 1, 1979, the 8088 has an eight-bit external data bus instead of the 16-bit bus of the 8086. The 16-bit registers a ...

80186 The Intel 80186, also known as the iAPX 186, or just 186, is a microprocessor and microcontroller introduced in 1982. It was based on the Intel 8086 and, like it, had a 16-bit external data bus multiplexed with a 20-bit address bus. The 80188 ...

80286 The Intel 80286 (also marketed as the iAPX 286 and often called Intel 286) is a 16-bit microprocessor that was introduced on February 1, 1982. It was the first 8086-based CPU with separate, non- multiplexed address and data buses and also the ...

, and supported by 80386 and all subsequent

x86 x86 (also known as 80x86 or the 8086 family) is a family of complex instruction set computer (CISC) instruction set architectures initially developed by Intel based on the Intel 8086 microprocessor and its 8088 variant. The 8086 was intr ...

machines through to present day

Pentium Pentium is a brand used for a series of x86 architecture-compatible microprocessors produced by Intel. The original Pentium processor from which the brand took its name was first released on March 22, 1993. After that, the Pentium II and P ...

and Core 2 processors. This memory model has remained ever since in the x86 machines, which now provide multi-mode operation and rarely operate in the compatible segmented mode. See

x86 memory segmentation x86 memory segmentation refers to the implementation of memory segmentation in the Intel x86 computer instruction set architecture. Segmentation was introduced on the Intel 8086 in 1978 as a way to allow programs to address more than 64 KB ...

for details. Within the x86 architectures, when operating in the real mode (or emulation), physical address is computed as:General description of Real Mode
"The physical address can be calculated as Value_in_segment_register 16 + Value_in_offset_register." :Address = 16 × segment + offset (I.e., the 16-bit segment register is shifted left by 4 bits and added to a 16-bit offset, resulting in a 20-bit address.)

References

{{Reflist Computer memory

Memory models

Flat memory model

Paged memory model

X86 segmented memory model

See also

References