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Что (кто) такое Direct Memory Access - определение
FEATURE OF COMPUTER SYSTEMS
Direct Memory Access; DMA controller; DMA engine; DMA channel; Intel Data Direct I/O; Intel DDIO; Data Direct I/O; DDIO; DMA transfer; Third-party DMA; Linked Direct Memory Access; Linked direct memory access; Linked DMA; Programmable DMA controller; Multiplexed DMA; Multiplexed direct memory access; DMA request; DRQ (DMA); DRQ (direct memory access); Burst mode DMA; Burst mode direct memory access; DMA burst; Direct memory access burst; Cycle steal DMA; Cycle steal direct memory access; Cycle stealing DMA; Cycle stealing direct memory access; Interleaved DMA; Interleaved direct memory access
![integrated circuits]] below the middle of the image are the DMA controller (l.) and - unusual - an extra dedicated DMA controller (r.) for the [[magneto-optical disc]] used instead of a [[hard disk drive]] in the first series of this computer model.](https://commons.wikimedia.org/wiki/Special:FilePath/NeXTcube motherboard.jpg?width=200 "integrated circuits]] below the middle of the image are the DMA controller (l.) and - unusual - an extra dedicated DMA controller (r.) for the [[magneto-optical disc]] used instead of a [[hard disk drive]] in the first series of this computer model.")
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Direct Memory Access
<architecture> (DMA) A facility of some architectures which
allows a peripheral to read and write memory without
intervention by the CPU. DMA is a limited form of {bus
master}ing.
(1996-08-23)
Direct memory access
Direct memory access (DMA) is a feature of computer systems and allows certain hardware subsystems to access main system memory independently of the central processing unit (CPU).
Random access
ABILITY TO ACCESS AN ARBITRARY ELEMENT OF A SEQUENCE IN EQUAL TIME
Random-access storage; Random access file; Random-access; Random I/O; Random read; Random write; Direct access (computing)
Random access (more precisely and more generally called direct access) is the ability to access an arbitrary element of a sequence in equal time or any datum from a population of addressable elements roughly as easily and efficiently as any other, no matter how many elements may be in the set. In computer science it is typically contrasted to sequential access which requires data to be retrieved in the order it was stored.
random access
ABILITY TO ACCESS AN ARBITRARY ELEMENT OF A SEQUENCE IN EQUAL TIME
Random-access storage; Random access file; Random-access; Random I/O; Random read; Random write; Direct access (computing)
¦ noun Computing the process of transferring information to or from memory in which every memory location can be accessed directly rather than being accessed in a fixed sequence.
shadow ram
![VEB Carl Zeiss Jena]] in 1989](https://commons.wikimedia.org/wiki/Special:FilePath/Bundesarchiv Bild 183-1989-0406-022, VEB Carl Zeiss Jena, 1-Megabit-Chip.jpg?width=200 "VEB Carl Zeiss Jena]] in 1989")
.PNG?width=200 "DRAM Cell (1 Transistor and one capacitor)")
![These IBM [[tabulating machine]]s from the mid-1930s used [[mechanical counter]]s to store information](https://commons.wikimedia.org/wiki/Special:FilePath/Early SSA accounting operations.jpg?width=200 "These IBM [[tabulating machine]]s from the mid-1930s used [[mechanical counter]]s to store information")
![heatsink]]](https://commons.wikimedia.org/wiki/Special:FilePath/Random Access Memory HyperX.jpg?width=200 "heatsink]]")
.svg?width=200 "SRAM Cell (6 Transistors)")
![desktop RAM]].](https://commons.wikimedia.org/wiki/Special:FilePath/Samsung-1GB-DDR2-Laptop-RAM.jpg?width=200 "desktop RAM]].")
![server]]s.](https://commons.wikimedia.org/wiki/Special:FilePath/Swissbit 2GB PC2-5300U-555.jpg?width=200 "server]]s.")
FORM OF COMPUTER DATA STORAGE
R.A.M.; Shadow Random Access Memory; Memory wall; Shadow ram; Shadow RAM; Shadow random access memory; Random-Access Memory; RAM chip; Random Access Memory; RAM (memory); Sigmaquad; Random access memory; Single sided RAM; Single-sided RAM; Single sided random access memory; Single-sided random access memory; RAM memory; Computer RAM memory; RAM; Memory bottleneck; History of random-access memory; RAM IC; RAM stick
random-access memory
FORM OF COMPUTER DATA STORAGE
R.A.M.; Shadow Random Access Memory; Memory wall; Shadow ram; Shadow RAM; Shadow random access memory; Random-Access Memory; RAM chip; Random Access Memory; RAM (memory); Sigmaquad; Random access memory; Single sided RAM; Single-sided RAM; Single sided random access memory; Single-sided random access memory; RAM memory; Computer RAM memory; RAM; Memory bottleneck; History of random-access memory; RAM IC; RAM stick
<storage> (RAM) (Previously "direct-access memory"). A data
storage device for which the order of access to different
locations does not affect the speed of access. This is in
contrast to, say, a magnetic disk, magnetic tape or a
mercury delay line where it is very much quicker to access
data sequentially because accessing a non-sequential location
requires physical movement of the storage medium rather than
just electronic switching.
In the 1970s magnetic core memory was used and some
old-timers still call RAM "core". The most common form of RAM
in use today is semiconductor integrated circuits, which
can be either static random-access memory (SRAM) or {dynamic
random-access memory} (DRAM).
The term "RAM" has gained the additional meaning of
read-write. Most kinds of semiconductor read-only memory
(ROM) are actually "random access" in the above sense but are
never referred to as RAM. Furthermore, memory referred to as
RAM can usually be read and written equally quickly
(approximately), in contrast to the various kinds of
programmable read-only memory. Finally, RAM is usually
volatile though non-volatile random-access memory is also
used.
Interestingly, some DRAM devices are not truly random access
because various kinds of "page mode" or "column mode" mean
that sequential access is faster than random access.
The humorous expansion "Rarely Adequate Memory" refers to the
fact that programs and data always seem to expand to fill the
memory available.
(2007-10-12)
MDRAM
RANDOM-ACCESS MEMORY THAT STORES EACH BIT OF DATA IN A SEPARATE CAPACITOR WITHIN AN INTEGRATED CIRCUIT
DRAM (memory); Pseudostatic RAM; PSRAM; Pseudostatic Random Access Memory; Window RAM; Dynamic RAM; EDO RAM; Fast Page Mode DRAM; FPM RAM; FPM DRAM; Fast Page Mode RAM; BEDO (RAM); MDRAM; Row Access Strobe; Column Access Strobe; CAS access time; Precharge interval; Row address select; Column address select; 1T DRAM; DDRAM; D-RAM; EDO DRAM; Fast page mode; Page mode memory; Extended Data Out RAM; BEDO RAM; Burst EDO; Multibank DRAM; Intel 1102; Burst EDO DRAM; Memory Timing; Dynamic Random Access Memory; FPRAM; Dynamic random access memory; Extended data out DRAM; Extended Data Out DRAM; Dynamic Random access memory; Static column RAM; Memory row; DRAM row; Row activation; WRAM (memory); 1T1C; 1t1c; 3T1C; Page mode RAM; Page mode DRAM; DRAM; D. R. A. M.; D.R.A.M.; DRAM memory; Asynchronous DRAM; EDO memory; Fast page mode DRAM; Window DRAM; Video DRAM; Nibble mode; EDO SGRAM
Multibank Dynamic Random Access Memory (Reference: RAM, DRAM, IC)
FPM DRAM
RANDOM-ACCESS MEMORY THAT STORES EACH BIT OF DATA IN A SEPARATE CAPACITOR WITHIN AN INTEGRATED CIRCUIT
DRAM (memory); Pseudostatic RAM; PSRAM; Pseudostatic Random Access Memory; Window RAM; Dynamic RAM; EDO RAM; Fast Page Mode DRAM; FPM RAM; FPM DRAM; Fast Page Mode RAM; BEDO (RAM); MDRAM; Row Access Strobe; Column Access Strobe; CAS access time; Precharge interval; Row address select; Column address select; 1T DRAM; DDRAM; D-RAM; EDO DRAM; Fast page mode; Page mode memory; Extended Data Out RAM; BEDO RAM; Burst EDO; Multibank DRAM; Intel 1102; Burst EDO DRAM; Memory Timing; Dynamic Random Access Memory; FPRAM; Dynamic random access memory; Extended data out DRAM; Extended Data Out DRAM; Dynamic Random access memory; Static column RAM; Memory row; DRAM row; Row activation; WRAM (memory); 1T1C; 1t1c; 3T1C; Page mode RAM; Page mode DRAM; DRAM; D. R. A. M.; D.R.A.M.; DRAM memory; Asynchronous DRAM; EDO memory; Fast page mode DRAM; Window DRAM; Video DRAM; Nibble mode; EDO SGRAM
Burst EDO
RANDOM-ACCESS MEMORY THAT STORES EACH BIT OF DATA IN A SEPARATE CAPACITOR WITHIN AN INTEGRATED CIRCUIT
DRAM (memory); Pseudostatic RAM; PSRAM; Pseudostatic Random Access Memory; Window RAM; Dynamic RAM; EDO RAM; Fast Page Mode DRAM; FPM RAM; FPM DRAM; Fast Page Mode RAM; BEDO (RAM); MDRAM; Row Access Strobe; Column Access Strobe; CAS access time; Precharge interval; Row address select; Column address select; 1T DRAM; DDRAM; D-RAM; EDO DRAM; Fast page mode; Page mode memory; Extended Data Out RAM; BEDO RAM; Burst EDO; Multibank DRAM; Intel 1102; Burst EDO DRAM; Memory Timing; Dynamic Random Access Memory; FPRAM; Dynamic random access memory; Extended data out DRAM; Extended Data Out DRAM; Dynamic Random access memory; Static column RAM; Memory row; DRAM row; Row activation; WRAM (memory); 1T1C; 1t1c; 3T1C; Page mode RAM; Page mode DRAM; DRAM; D. R. A. M.; D.R.A.M.; DRAM memory; Asynchronous DRAM; EDO memory; Fast page mode DRAM; Window DRAM; Video DRAM; Nibble mode; EDO SGRAM
EDO DRAM
RANDOM-ACCESS MEMORY THAT STORES EACH BIT OF DATA IN A SEPARATE CAPACITOR WITHIN AN INTEGRATED CIRCUIT
DRAM (memory); Pseudostatic RAM; PSRAM; Pseudostatic Random Access Memory; Window RAM; Dynamic RAM; EDO RAM; Fast Page Mode DRAM; FPM RAM; FPM DRAM; Fast Page Mode RAM; BEDO (RAM); MDRAM; Row Access Strobe; Column Access Strobe; CAS access time; Precharge interval; Row address select; Column address select; 1T DRAM; DDRAM; D-RAM; EDO DRAM; Fast page mode; Page mode memory; Extended Data Out RAM; BEDO RAM; Burst EDO; Multibank DRAM; Intel 1102; Burst EDO DRAM; Memory Timing; Dynamic Random Access Memory; FPRAM; Dynamic random access memory; Extended data out DRAM; Extended Data Out DRAM; Dynamic Random access memory; Static column RAM; Memory row; DRAM row; Row activation; WRAM (memory); 1T1C; 1t1c; 3T1C; Page mode RAM; Page mode DRAM; DRAM; D. R. A. M.; D.R.A.M.; DRAM memory; Asynchronous DRAM; EDO memory; Fast page mode DRAM; Window DRAM; Video DRAM; Nibble mode; EDO SGRAM
Википедия
Direct memory access
Direct memory access (DMA) is a feature of computer systems that allows certain hardware subsystems to access main system memory independently of the central processing unit (CPU).
Without DMA, when the CPU is using programmed input/output, it is typically fully occupied for the entire duration of the read or write operation, and is thus unavailable to perform other work. With DMA, the CPU first initiates the transfer, then it does other operations while the transfer is in progress, and it finally receives an interrupt from the DMA controller (DMAC) when the operation is done. This feature is useful at any time that the CPU cannot keep up with the rate of data transfer, or when the CPU needs to perform work while waiting for a relatively slow I/O data transfer. Many hardware systems use DMA, including disk drive controllers, graphics cards, network cards and sound cards. DMA is also used for intra-chip data transfer in multi-core processors. Computers that have DMA channels can transfer data to and from devices with much less CPU overhead than computers without DMA channels. Similarly, a processing circuitry inside a multi-core processor can transfer data to and from its local memory without occupying its processor time, allowing computation and data transfer to proceed in parallel.
DMA can also be used for "memory to memory" copying or moving of data within memory. DMA can offload expensive memory operations, such as large copies or scatter-gather operations, from the CPU to a dedicated DMA engine. An implementation example is the I/O Acceleration Technology. DMA is of interest in network-on-chip and in-memory computing architectures.
