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As far as I can tell, hardware prefetchers will at the very least detect and fetch constant strides through memory. Additionally it can monitor data access patterns, whatever that really means. Which led me to wonder, do hardware prefetchers ever base their decisions on actual data stored in memory, or purely based on the behaviour a program is exhibiting?

The reason I ask is because I will occasionally use "non-native" pointers as pointers. A simple example of this would be a preallocated array of stuff, and small integers indexing this array instead of pointers. If I need to store a whole lot of such "pointers", the savings in memory can add up quickly and in turn indirectly improve cache-performance by using less memory.

But for all I know, this might interfere with how hardware prefetchers work. Or not!

I can certainly imagine, realistic or not, a prefetching unit that examines cache lines that enters L1 cache for native pointer addresses and starts fetching them into L2 or some such thing. In that case, my clever trick of saving memory suddenly seems less decidedly clever.

So, what do modern hardware prefetchers do, really? Can they be tripped up by "non-native" pointers?

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I might sound stupid but what is a non-native pointer? – Alex Nov 13 '13 at 15:47
In this question, a "native" pointer is supposed to be a value that holds a memory address in a literal sense. 0x1234 would point to the memory at 0x1234. A "non-native" pointer would be a value that refers to memory in an indirect way. 0x1234 in this context may refer to memory at some_array[0x1234], or something more complex like array = some_map[0x1234>>8]; pointer = array[0x1234&0xff]. – porgarmingduod Nov 13 '13 at 16:05
up vote 10 down vote accepted

Linked data structures (LDS) prefetching is still a known problem in computer architecture. I'm not familiar with any modern CPU that actually does that, but in theory it's possible. There have been several academy papers over the years that propose some variations over:

  1. A dedicated HW that can detect address-like values within fetched cache lines, and issue prefetches to these addresses.
  2. A compiler-assisted technique where the compiler recognized the data structure dependencies and inserts SW prefetches or other hints.

Both these methods may be affected by your technique (the first would be rendered useless, the second may work if the compiler is sufficiently clever).

Of course you'd have to actually run on such a machine so it's only theoretical, and you shouldn't have to change your practice if it works fine for you, but it goes to show that profiling should be specific per micro-architecture and system, and what helps you in one case, may be less efficient on another.
Generally speaking - don't just trust the CPU to do or not do some optimization (unless it's documented), always check you get the expected behavior.

By the way, note that even if the HW sees the content of the memory, it's still in the virtual address space - the HW would anyway have to do some sort of translation to physical address to use it, so in a sense there doesn't have to be any additional overhead.

Some bibliography:

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Accepting this as it most directly answers the question at hand: No, there are currently no known CPU that does prefetching based on linked data. – porgarmingduod Nov 13 '13 at 16:09
Well, if I ever finish my thesis i'll see if I can sell it to Intel/AMD/.. , and maybe there will be one someday :) – Leeor Nov 13 '13 at 18:30

The hardware prefetcher doesn't see pointers, it sees memory addresses. It doesn't care where the address came from, or what type it had in the C++ program you wrote. It just looks at which address the CPU is being told to read to or write from.

So no, indexing into an array is not going to be a scary new thing that the CPU has never encountered before.

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Exactly. Don't think in terms of types when trying to understand a CPU's capabilities. – Marc Claesen Nov 13 '13 at 13:06
@MarcClaesen: well, to be fair to the OP, even in terms of CPU representation there is a difference between how a memory address is represented (8 bytes on 64bits) and how an offset from "known" address is represented (maybe only 2 bytes, if it suffices). The proposed "new-fangled" optimization of prefetching memory at whatever looks like a memory address in the L1 cache seems perfectly legitimate, for example, and would be crushed by the "memory savings" offset. – Matthieu M. Nov 13 '13 at 13:31
@jalf: Of course it doesn't see types. But does see memory addresses? When does it "see" a memory address? When it is put into a register? When it is actually used as a memory address? – porgarmingduod Nov 13 '13 at 13:43
@MSalters, it's been first proposed long ago, but the idea is far from being dead. SW prefetches can't help you run ahead a linked data-structure since you still don't know the address. Pipelining also doesn't help in such cases as the fetches are dependent. In general, it's still an open problem. – Leeor Nov 13 '13 at 13:49
@MSalters - Data dependent prefetches can be implemented on lower cache levels, even in the memory controller (and "guess" the physical translation or work within page boundaries) - that's way faster then going all the way up to the Mem unit and issuing the next fetch. Anyway, this is beside the point - i'm arguing that assuming that no CPU will ever do this is a bit risky, that's all. – Leeor Nov 13 '13 at 13:59

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