In DOS memory management, conventional memory, also called base memory, is the first 640 kilobytes of the memory on IBM PC or compatible systems. It is the read-write memory directly addressable by the processor for use by the operating system and application programs. As memory prices rapidly declined, this design decision became a limitation in the use of large memory capacities until the introduction of operating systems and processors that made it irrelevant.

Memory areas of the IBM PC family

640 KB barrier

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IBM PC, PC/XT, 3270 PC and PCjr memory blocks[1][2]
0-block 1st 64 KB Ordinary user memory to 64 KB (low memory area)
1-block 2nd 64 KB Ordinary user memory to 128 KB
2-block 3rd 64 KB Ordinary user memory to 192 KB
3-block 4th 64 KB Ordinary user memory to 256 KB
4-block 5th 64 KB Ordinary user memory to 320 KB
5-block 6th 64 KB Ordinary user memory to 384 KB
6-block 7th 64 KB Ordinary user memory to 448 KB
7-block 8th 64 KB Ordinary user memory to 512 KB
8-block 9th 64 KB Ordinary user memory to 576 KB
9-block 10th 64 KB Ordinary user memory to 640 KB
A-block 11th 64 KB Extended video memory (EGA)
B-block 12th 64 KB Standard video memory (MDA/CGA)
C-block 13th 64 KB ROM expansion (XT, EGA, 3270 PC)
D-block 14th 64 KB other use (PCjr cartridges, LIM EMS)
E-block 15th 64 KB other use (PCjr cartridges, LIM EMS)
F-block 16th 64 KB System ROM-BIOS and ROM-BASIC

The 640 KB barrier is an architectural limitation of IBM PC compatible PCs. The Intel 8088 CPU, used in the original IBM PC, was able to address 1 MB (220 bytes), since the chip offered 20 address lines. In the design of the PC, the memory below 640 KB was for random-access memory on the motherboard or on expansion boards, and it was called the conventional memory area. The first memory segment (64 KB) of the conventional memory area is named lower memory or low memory area. The remaining 384 KB beyond the conventional memory area, called the upper memory area (UMA), was reserved for system use and optional devices. UMA was used for the ROM BIOS, additional read-only memory, BIOS extensions for fixed disk drives and video adapters, video adapter memory, and other memory-mapped input and output devices. The design of the original IBM PC placed the Color Graphics Adapter (CGA) memory map in UMA.

The need for more RAM grew faster than the needs of hardware to utilize the reserved addresses, which resulted in RAM eventually being mapped into these unused upper areas to utilize all available addressable space. This introduced a reserved "hole" (or several holes) into the set of addresses occupied by hardware that could be used for arbitrary data. Avoiding such a hole was difficult and ugly and not supported by DOS or most programs that could run on it. Later, space between the holes would be used as upper memory blocks (UMBs).

To maintain compatibility with older operating systems and applications, the 640 KB barrier remained part of the PC design even after the 8086/8088 had been replaced with the Intel 80286 processor, which could address up to 16 MB of memory in protected mode. The 1 MB barrier also remained as long as the 286 was running in real mode, since DOS required real mode which uses the segment and offset registers in an overlapped manner such that addresses with more than 20 bits are not possible. It is still present in IBM PC compatibles today if they are running in real mode such as used by DOS. Even the most modern Intel PCs still have the area between 640 and 1024 KB reserved.[3][4] This however is invisible to programs (or even most of the operating system) on newer operating systems (such as Windows, Linux, or Mac OS X) that use virtual memory, because they have no awareness of physical memory addresses at all. Instead they operate within a virtual address space, which is defined independently of available RAM addresses.[5]

Some motherboards feature a "Memory Hole at 15 Megabytes" option required for certain VGA video cards that require exclusive access to one particular megabyte for video memory. Later video cards using the AGP (PCI memory space) bus can have 256 MB memory with 1 GB aperture size.

Additional memory

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One technique used on early IBM XT computers was to install additional RAM into the video memory address range and push the limit up to the start of the Monochrome Display Adapter (MDA). Sometimes software or a custom address decoder was required for this to work. This moved the barrier to 704 KB (with MDA/HGC) or 736 KB (with CGA).[6][7]

Memory managers on 386-based systems (such as QEMM or MEMMAX (+V) in DR-DOS) could achieve the same effect, adding conventional memory at 640 KB and moving the barrier to 704 KB (up to segment B000, the start of MDA/HGC) or 736 KB (up to segment B800, the start of the CGA).[7] Only CGA could be used in this situation, because Enhanced Graphics Adapter (EGA) video memory was immediately adjacent to the conventional memory area below the 640 KB line; the same memory area could not be used both for the frame buffer of the video card and for transient programs.

All Computers' piggy-back add-on memory management units AllCard for XT-[8][9] and Chargecard[10] for 286/386SX-class computers, as well as MicroWay's ECM (Extended Conventional Memory) add-on-board[11] allowed normal memory to be mapped into the A0000–EFFFF (hex) address range, giving up to 952 KB for DOS programs. Programs such as Lotus 1-2-3, which accessed video memory directly, needed to be patched to handle this memory layout. Therefore, the 640 KB barrier was removed at the cost of hardware compatibility.[10]

It was also possible to use console redirection[12] (either by specifying an alternative console device like AUX: when initially invoking COMMAND.COM or by using CTTY later on) to direct output to and receive input from a dumb terminal or another computer running a terminal emulator. Assuming the System BIOS still permitted the machine to boot (which is often the case at least with BIOSes for embedded PCs), the video card in a so called headless computer could then be removed completely, and the system could provide a total of 960 KB of continuous DOS memory for programs to load.

Similar usage was possible on many DOS- but not IBM-compatible computers with a non-fragmented memory layout, for example SCP S-100 bus systems equipped with their 8086 CPU card CP-200B and up to sixteen SCP 110A memory cards (with 64 KB RAM on each of them) for a total of up to 1024 KB (without video card, but utilizing console redirection, and after mapping out the boot/BIOS ROM),[13] the Victor 9000/Sirius 1 which supported up to 896 KB, or the Apricot PC with more continuous DOS memory to be used under its custom version of MS-DOS.

DOS driver software and TSRs

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Most standard programs written for DOS did not necessarily need 640 KB or more of memory. Instead, driver software and utilities referred to as terminate-and-stay-resident programs (TSRs) could be used in addition to the standard DOS software. These drivers and utilities typically used some conventional memory permanently, reducing the total available for standard DOS programs.

Some very common DOS drivers and TSRs using conventional memory included:

  • ANSI.SYS - support for color text and different text resolutions
  • ASPIxDOS.SYS, ASPIDISK.SYS, ASPICD.SYS - all must be loaded for Adaptec SCSI drives and CDROMs to work
  • DOSKEY.EXE - permits recall of previously typed DOS commands using up-arrow
  • LSL.EXE, E100BODI.EXE (or other network driver), IPXODI.EXE, NETX.EXE - all must be loaded for NetWare file server drive letter access
  • MOUSE.EXE - support for mouse devices in DOS programs
  • MSCDEX.EXE - support for CDROM drive access and drive letter, used in combination with a separate manufacturer-specific driver. Needed in addition to above SCSI drivers for access to a SCSI CDROM device.
  • SBCONFIG.EXE - support for Sound Blaster 16 audio device; a differently-named driver was used for various other sound cards, also occupying conventional memory.
  • SMARTDRV.EXE - install drive cache to speed up disk reads and writes; although it could allocate several megabytes of memory beyond 640 KB for the drive caching, it still needed a small portion of conventional memory to function.

As can be seen above, many of these drivers and TSRs could be considered practically essential to the full-featured operation of the system. But in many cases a choice had to be made by the computer user, to decide whether to be able to run certain standard DOS programs or have all their favorite drivers and TSRs loaded. Loading the entire list shown above is likely either impractical or impossible, if the user also wants to run a standard DOS program as well.

In some cases drivers or TSRs would have to be unloaded from memory to run certain programs, and then reloaded after running the program. For drivers that could not be unloaded, later versions of DOS included a startup menu capability to allow the computer user to select various groups of drivers and TSRs to load before running certain high-memory-usage standard DOS programs.

Upper memory blocks and loading high

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As DOS applications grew larger and more complex in the late 1980s and early 1990s, it became common practice to free up conventional memory by moving the device drivers and TSR programs into upper memory blocks (UMBs) in the upper memory area (UMA) at boot, in order to maximize the conventional memory available for applications. This had the advantage of not requiring hardware changes, and preserved application compatibility.

This feature was first provided by third-party products such as QEMM, before being built into DR DOS 5.0 in 1990 then MS-DOS 5.0 in 1991. Most users used the accompanying EMM386 driver provided in MS-DOS 5, but third-party products from companies such as QEMM also proved popular.

At startup, drivers could be loaded high using the "DEVICEHIGH=" directive, while TSRs could be loaded high using the "LOADHIGH", "LH" or "HILOAD" directives. If the operation failed, the driver or TSR would automatically load into the regular conventional memory instead.

CONFIG.SYS, loading ANSI.SYS into UMBs, no EMS support enabled:

DEVICE=C:\DOS\HIMEM.SYS
DEVICE=C:\DOS\EMM386.EXE NOEMS
DEVICEHIGH=C:\DOS\ANSI.SYS

AUTOEXEC.BAT, loading MOUSE, DOSKEY, and SMARTDRV into UMBs if possible:

LH C:\DOS\MOUSE.EXE
LH C:\DOS\DOSKEY.EXE
LH C:\DOS\SMARTDRV.EXE

The ability of DOS versions 5.0 and later to move their own system core code into the high memory area (HMA) through the DOS=HIGH command gave another boost to free memory.

Driver and TSR optimization

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Hardware expansion boards could use any of the upper memory area for ROM addressing, so the upper memory blocks were of variable size and in different locations for each computer, depending on the hardware installed. Some windows of upper memory could be large and others small. Loading drivers and TSRs high would pick a block and try to fit the program into it, until a block was found where it fit, or it would go into conventional memory.

An unusual aspect of drivers and TSRs is that they would use different amounts of conventional and/or upper memory, based on the order they were loaded. This could be used to advantage if the programs were repeatedly loaded in different orders, and checking to see how much memory was free after each permutation. For example, if there was a 50 KB UMB and a 10 KB UMB, and programs needing 8 KB and 45 KB were loaded, the 8 KB might go into the 50 KB UMB, preventing the second from loading. Later versions of DOS allowed the use of a specific load address for a driver or TSR, to fit drivers/TSRs more tightly together.

In MS-DOS 6.0, Microsoft introduced MEMMAKER, which automated this process of block matching, matching the functionality third-party memory managers offered. This automatic optimization often still did not provide the same result as doing it by hand, in the sense of providing the greatest free conventional memory.

Also in some cases third-party companies wrote special multi-function drivers that would combine the capabilities of several standard DOS drivers and TSRs into a single very compact program that used just a few kilobytes of memory. For example, the functions of mouse driver, CD-ROM driver, ANSI support, DOSKEY command recall, and disk caching would all be combined together in one program, consuming just 1 – 2 kilobytes of conventional memory for normal driver/interrupt access, and storing the rest of the multi-function program code in EMS or XMS memory.

DOS extenders

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The barrier was only overcome with the arrival of DOS extenders, which allowed DOS applications to run in 16-bit or 32-bit protected mode, but these were not very widely used outside of computer gaming. With a 32-bit DOS extender, a game could benefit from a 32-bit flat address space and the full 32-bit instruction set without the 66h/67h operand/address override prefixes. 32-bit DOS extenders required compiler support (32-bit compilers) while XMS and EMS worked with an old compiler _targeting 16-bit real-mode DOS applications. The two most common specifications for DOS extenders were VCPI- and later DPMI-compatible with Windows 3.x.

The most notable DPMI-compliant DOS extender may be DOS/4GW, shipping with Watcom. It was very common in games for DOS. Such a game would consist of either a DOS/4GW 32-bit kernel, or a stub which loaded a DOS/4GW kernel located in the path or in the same directory and a 32-bit "linear executable". Utilities are available which can strip DOS/4GW out of such a program and allow the user to experiment with any of the several, and perhaps improved, DOS/4GW clones.

Prior to DOS extenders, if a user installed additional memory and wished to use it under DOS, they would first have to install and configure drivers to support either expanded memory specification (EMS) or extended memory specification (XMS) and run programs supporting one of these specifications.

EMS was a specification available on all PCs, including those based on the Intel 8086 and Intel 8088, which allowed add-on hardware to page small chunks of memory in and out (bank switching) of the "real mode" addressing space (0x0400–0xFFFF). This allowed 16-bit real-mode DOS programs to access several megabytes of RAM through a hole in real memory, typically (0xE000–0xEFFF). A program would then have to explicitly request the page to be accessed before using it. These memory locations could then be used arbitrarily until replaced by another page. This is very similar to modern paged virtual memory. However, in a virtual memory system, the operating system handles all paging operations, while paging was explicit with EMS.

XMS provided a basic protocol which allowed a 16-bit DOS programs to load chunks of 80286 or 80386 extended memory in low memory (address 0x0400–0xFFFF). A typical XMS driver had to switch to protected mode in order to load this memory. The problem with this approach is that while in 286 protected mode, direct DOS calls could not be made. The workaround was to implement a callback mechanism, requiring a reset of the 286. On the 286, this was a major problem. The Intel 80386, which introduced "virtual 8086 mode", allowed the guest kernel to emulate the 8086 and run the host operating system without having to actually force the processor back into "real mode". HIMEM.SYS 2.03 and higher used unreal mode on the 80386 and higher CPUs while HIMEM.SYS 2.06 and higher used LOADALL to change undocumented internal registers on the 80286, significantly improving interrupt latency by avoiding repeated real mode/protected mode switches.[14]

Windows installs its own version of HIMEM.SYS[15] on DOS 3.3 and higher. Windows HIMEM.SYS launches 32-bit protected mode XMS (n).0 services provider for the Windows Virtual Machine Manager, which then provides XMS (n-1).0 services to DOS boxes and the 16-bit Windows machine (e.g. DOS 7 HIMEM.SYS is XMS 3.0 but running 'MEM' command in a Windows 95 DOS window shows XMS 2.0 information).

See also

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References

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  1. ^ Norton, Peter (1986). Inside the IBM PC, Revised and Enlarged, Brady. ISBN 0-89303-583-1, p. 108.
  2. ^ U.S. patent 4,926,322 - Software emulation of bank-switched memory using a virtual DOS monitor and paged memory management, Fig. 1
  3. ^ Yao, Jiewen; Zimmer, Vincent J. (February 2015). "White Paper: A Tour beyond BIOS Memory Map Design in UEFI BIOS" (PDF). Intel Corporation. Archived from the original (PDF) on 2015-09-30. Retrieved 2016-08-25.
  4. ^ Russinovich, Mark Eugene; Solomon, David A.; Ionescu, Alex (2012). Windows Internals. Vol. Part 2 (6th ed.). Microsoft Press. p. 322. Note the gap in the memory address range from page 9F000 to page 100000...
  5. ^ Richter, Jeffrey. Programming Applications for Microsoft Windows. pp. 435 ff.
  6. ^ Atkinson, Cy (2001). "What is High Memory, why do i care, and how can I use it?". San Jose, CA, USA. Archived from the original on 2016-03-03. Retrieved 2017-03-13.
  7. ^ a b Paul, Matthias R. (1997-07-30). NWDOS-TIPs — Tips & Tricks rund um Novell DOS 7, mit Blick auf undokumentierte Details, Bugs und Workarounds [NWDOSTIPs — Tips & tricks for Novell DOS 7, with special focus on undocumented details, bugs and workarounds]. MPDOSTIP (in German) (3 ed.). Archived from the original on 2016-06-06. Retrieved 2016-06-06. (NB. NWDOSTIP.TXT is a comprehensive work on Novell DOS 7 and OpenDOS 7.01, including the description of many undocumented features and internals. It is part of the author's yet larger MPDOSTIP.ZIP collection maintained up to 2001 and distributed on many sites at the time. The provided link points to a HTML-converted older version of the NWDOSTIP.TXT file.)
  8. ^ Petzold, Charles (1986). "More Options For Enlarging the Dimensions of Memory". PC Magazine. Vol. 5, no. 11. ISSN 0888-8507.
  9. ^ "AllCard review". Personal Computer World. September 1986. p. 138.
  10. ^ a b Zerbe, Klaus (November 1987). Burgwitz, Andreas (ed.). "Speicher-Kredit - All Chargecard für ATs". c't - magazin für computertechnik. Prüfstand (in German). Vol. 1987, no. 11. Verlag Heinz Heise GmbH & Co. KG. pp. 58, 60. ISSN 0724-8679.
  11. ^ Petzold, Charles (1986-09-16). "Number Smasher/ECM". PC Magazine. Accelerator Boards. Vol. 5, no. 15. pp. 148, 150. ISSN 0888-8507. Archived from the original on 2020-03-03. Retrieved 2020-03-03.
  12. ^ Kontron User's Guide - COMe-cBTi6R. Document Revision 1.0. Kontron. 2021. pp. 37, 60, 64. Archived from the original on 2023-09-23. Retrieved 2023-09-23. (89 pages)
  13. ^ Paterson, Tim (2007-11-24). "The First DOS Machine". DosMan Drivel. Archived from the original on 2021-09-18. Retrieved 2021-12-23. IBM also reintroduced memory limitations that I had specifically avoided in designing the 8086 CPU [card]. For S-100 computers, a low-cost alternative to using a regular computer terminal was to use a video card. The video card, however, used up some of the memory address space. The boot ROM would normally use up address space as well. SCP systems were designed to be used with a terminal, and the boot ROM could be disabled after boot-up. This made the entire 1 MB of memory address space available for RAM. IBM, on the other hand, had limited the address space in their PC to 640 KB of RAM due to video and boot/BIOS ROM. This limitation has been called the "DOS 640K barrier", but it had nothing to do with DOS. Microsoft took full advantage of the SCP system capability. In 1988, years after SCP had shut down, they were still using the SCP system for one task only it could perform ("linking the linker"). Their machine was equipped with the full 1 MB of RAM – 16 of the 64 KB cards. That machine could not be retired until 32-bit software tools were developed for Intel's 386 microprocessor.
  14. ^ "HIMEM.SYS, unreal mode, and LOADALL". OS/2 Museum.
  15. ^ "Overview of Memory-Management Functionality in MS-DOS". Microsoft Support. 2003-05-12. Archived from the original on 2007-02-12. Retrieved 2012-08-13.

Further reading

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  NODES
Bugs 2
INTERN 3
Note 2
USERS 1