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I'm curious as to the lookup time that a call to std::get<> on a std::tuple<> takes. Some brief googling (including the reference pages which usually have this information) turned up no results.

My initial intuition (and fear) is that the recursive structure of tuple (if it is implemented as a variadic template) would lead to get requiring an order of N lookups (A call to get<3>(t) looking like t.rest().rest().first(). I'm hoping I'm way off here...

Then again, I would hope the compiler would be able to optimize this to directly return the correct offset without the overhead of N of calls.

Basically what I want: is there a specced guarantee on runtime? does this restrict how std::tuple is implemented?

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3 Answers 3

up vote 9 down vote accepted

The C++ specification does not provide a guarantee on the runtime performance of any function. Even when it states asymptotic requirements, that only guarantees the relative number of operations, not the performance of those operations. O(1) doesn't mean fast, nor does O(n) mean slow.

You can either trust your compiler/optimizer/standard library implementation, or you can rewrite it all yourself to get whatever performance you want. std::get, under most reasonable compilers (with optimizations on), should perform more or less equivalently to directly accessing the value from a struct. But the spec doesn't require that at any point.

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The relevant section of the Standard here is 1.9 Program execution [intro.execution] "1 The semantic descriptions in this International Standard define a parameterized nondeterministic abstract machine. This International Standard places no requirement on the structure of conforming implementations. In particular, they need not copy or emulate the structure of the abstract machine. Rather, conforming implementations are required to emulate (only) the observable behavior of the abstract machine as explained below.5" –  TemplateRex Apr 23 '13 at 14:26

The efficiency will be comparable to accessing a member of a struct. The get<> is resolved at compile time.

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Can you point me at spec? Could you explain this in detail? What enables this? inlining? –  Anthony Sottile Apr 23 '13 at 12:58
    
This is enabled by template resolution, performed during compilation. At runtime, the code resolves to reading from the object's address + a shift (and hence similar to accessing a member of a struct). –  utnapistim Apr 23 '13 at 13:04
    
@AnthonySottile You can always check the generated assembly and see that's what it's doing. –  Collin Apr 23 '13 at 13:05
    
I don't see anything in the standard that requires std::get<> to be implemented efficiently, and I can imagine legitimate reasons why it might not be (debugging). –  hvd Apr 23 '13 at 13:13
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@hvd: There's nothing in the standard that requires anything to be implemented "efficiently" (even O(1) operations can be inefficiently implemented). If you're going to spend a lot of time second-guessing your compiler or standard library implementation, you're not going to actually get much done. It's reasonable to expect inlining and RVO to make the call little more than a struct access in an optimized build. –  Nicol Bolas Apr 23 '13 at 13:39

The answer to the first question (how long std::get takes) depends on how your library chooses to implement std::tuple and std::get. But typically, libraries will choose to use a non-recursive approach, similar to the one outlined here: http://mitchnull.blogspot.com/2012/06/c11-tuple-implementation-details-part-1.html. With that type of approach, the access time of std::get will be constant, and roughly equivalent to the time it takes to access a member of a struct.

In answer to whether the standard provides any guarantees: as others have said, no, the standard makes no guarantees here. An evil library writer could choose to make std::get exponential in N, and they'd still be standard-compliant.

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