Load–store architecture

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In computer engineering, a load–store architecture (or a register–register architecture) is an instruction set architecture that divides instructions into two categories: memory access (load and store between memory and registers) and ALU operations (which only occur between registers).^[1]^: 9–12

Some RISC architectures such as PowerPC, SPARC, RISC-V, ARM, and MIPS are load–store architectures.^[1]^: 9–12

For instance, in a load–store approach both operands and destination for an ADD operation must be in registers. This differs from a register–memory architecture (for example, a CISC instruction set architecture such as x86) in which one of the operands for the ADD operation may be in memory, while the other is in a register.^[1]^: 9–12

The earliest example of a load–store architecture was the CDC 6600.^[1]^: 54–56 Almost all vector processors (including many GPUs^[2]^{[better source needed]}) use the load–store approach.^[3]

References

^ ^a ^b ^c ^d Michael J. Flynn (1995). Computer architecture: pipelined and parallel processor design. Jones & Bartlett Learning. ISBN 0867202041.
^ "AMD GCN reference" (PDF).
^ Harvey G. Cragon (1996). Memory systems and pipelined processors. Jones & Bartlett Learning. pp. 512–513. ISBN 0867204745.

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[Flynn-1] Michael J. Flynn (1995). Computer architecture: pipelined and parallel processor design. Jones & Bartlett Learning. ISBN 0867202041.

[2] "AMD GCN reference" (PDF).

[3] Harvey G. Cragon (1996). Memory systems and pipelined processors. Jones & Bartlett Learning. pp. 512–513. ISBN 0867204745.

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See also

References