In implementing most algorithms (sort, search, graph traversal, etc.), there is frequently a trade-off that can be made in reducing memory accesses at the cost of additional ordinary operations.

Knuth has a useful method for comparing the complexity of various algorithm implementations by abstracting it from particular processors and only distinguishing between ordinary operations (oops) and memory operations (mems).

In compiled programs, one typically lets the compiler organise the low level operations, and hopes that the operating system will handle the question of whether data is held in cache memory (faster) or in virtual memory (slower). Furthermore, the exact number / cost of instructions is encapsulated by the compiler.

With Forth, there is no longer such encapsulation, and one is much closer to the machine, albeit perhaps to a stack machine running on top of a register processor.

Ignoring the effect of an operating system (so no memory stalls, etc.), and assuming for the moment a simple processor,

(1) Can anyone advise on how the ordinary stack operations in Forth (e.g. dup, rot, over, swap, etc.) compare with the cost of Forth's memory access fetch (@) or store (!) ?

(2) Is there a rule of thumb I can use to decide how many ordinary operations to trade-off against saving a memory access?

What I'm looking for is something like 'memory access costs as much as 50 ordinary ops, or 500 ordinary ops, or 5 ordinary ops' Ballpark is absolutely fine.

I'm trying to get a sense of the relative expense of fetch and store vs. rot, swap, dup, drop, over, correct to an order of magnitude.

  • A few things that sprung to mind while reading: (1) The OS has very little (for most purposes, nothing) to do with the CPU cache. (2) Instruction costs always depends on the exact CPU. Without talking about a specific family of processors, you can't say much beyond "for most machines, X is probably faster than Y". – user395760 Mar 17 '13 at 18:28
  • @delnan: Re: (1) Doesn't the OS determines how memory is used by / made available to applications? And doesn't the OS determine when a block of memory is to be shunted into virtual memory and when restored back to cache memory? I though it was the OS that controlled these things... (if not, then what does?) Re: (2) Yes, exact costs depend on the exact CPU, but surely something can be said to within an order of magnitude without requiring to specify an exact CPU? I don't know of any algorithmic complexity analysis that specifies the exact CPU -- there would be no theory otherwise? – Assad Ebrahim Mar 17 '13 at 18:43
  • RE cache: Yes, the OS manages virtual memory, but IIUC the cache is (almost) entirely transparent -- stuff doesn't get moved between cache and virtual memory, the cache maintains and works with a copy (and eventually updates the part of RAM it came from) but the code still addresses it by its memory address. – user395760 Mar 17 '13 at 19:14
  • About the only thing the OS can do with the cache is flushing it. – n.m. Mar 17 '13 at 21:49
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    stackoverflow.com/questions/3142779/… for some rule of thumb, but basically stack/cache access is much better. For extreme end of scale, see PFOR compression which attempts to compress main memory access to increase bandwidth and cache relative effectiveness. – rlb Mar 18 '13 at 0:05

This article How much time does it take to fetch one word from memory? talks about main memory stall times, with some rule of thumb type numbers, but basically you can do lots of instructions while stalling for main memory. As others have said, the numbers vary a lot between systems.

Main memory stalls is a big area of interest, especially as CPUs have more cores, but typically not much faster memory bandwidth. There is some research going on around compressing data in main memory too, so that the CPU can take advantage of 'spare' cycles and tightly packed cache lines http://oai.cwi.nl/oai/asset/15564/15564B.pdf

For those who are really interested in the details, most CPU manufacturers publish in depth guides on memory optimisations etc. mostly aimed at high end and compiler writers, but readable by all 2gl and 3gl programmers.

Ps. Go Forth.

  • Great references. Corrected a blindspot in my understanding of the 'simple' mathematical models of computing, that clearly no longer account for essential elements of modern computers. – Assad Ebrahim Mar 18 '13 at 8:13

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