How are you compiling this example? What flags are you uisng? Can you provide the full compilable benchmark you use?

If you have a 32 bit long int you have an signed integer overflow which is undefined behavior.

@FrançoisAndrieux A 32-bit int can hold 2000000000.

@MaximEgorushkin I was looking at sum, didn't notice it was long.

The quote sounds like nonsense to me, or at best wisdom from the 1970s. The compiler knows whether you are going to use that value again. It's smart.

@FrançoisAndrieux You said yourself it's 32-bit though.

@LightnessRacesinOrbit It gets incremented by 10 2000000000 times.

@FrançoisAndrieux Right, so not noticing it was long is irrelevant :)

@LightnessRacesinOrbit My comment originally just said "If you have a 32 bit int..."

@FrançoisAndrieux Actually now I see an "edit" icon next to your comment so maybe I didn't see the original version.

I edited my answer so that it has my full code. It is a 64-bit machine, so the long can handle 2 billion summations of 10 :)

Wouldn't the microcode reveal whether it was optimized out?

@Asa Right, but we can't reproduce your results without this information. If I try I get a benchmark that optimizes out the loop. If I compile without optimizations, I get a meaningless benchmark.

As I said, I don't argue with the idea of turning on the compiler to maximum optimization and letting it do its job. I'm trying to understand how this effect appears in the first place.

"I used g++ with no compiler flags.". That's a big mistake when measuring performance. Please turn on optimization.

Can you please add addresses of instructions? We cannot see where the jumps are targeted.

I would say that the proposition of the question is wrong. You have not shown that declaring the variable in the loop is faster. The code above when compiled with optimizations will basically remove the loop. But even if you changed it to use sum you have not shown that either one is faster.

@geza I'm not trying to measure performance, I put in the timing results to show that there is a difference in speed, measured across multiple platforms and compilers (without optimization).

@MartinYork Could you further explain how I didn't demonstrate that one is faster than the other? I included my benchmarks. They aren't super accurate, but it is sufficient to show that there is a difference in speed. I tested it across multiple platforms. And yes, I do know that turning on optimizations removes the loop. I think I should remove that tag... it seems to be causing confusion. Sorry about that.

Yes, that's clear. But comparing the results is meaningless too. Current CPUs are insanely complex. With debug builds, a lot of things aren't taken care of. For example, jump target alignment. For a debug build, they are "random". If for some build they happen to be friendly to CPU, then the build would be faster. And there are a lot of other effects which could cause differences. Speed comparison questions can be interesting, in the case that they are measure optimized builds. Finding the reason of speed difference for unoptimized builds is simply doesn't worth it. Waste of time.

To reiterate, trying to measure performance from a compiler without any performance options turned on just won't work well. And as an aside, because the value in the loop is never actually changed, the compiler should just treat it as a literal 10 value and not allocate any memory nor perhaps even any registers (CPU type dependent) at all for either case.

@MichaelDorgan I think my question was unclear. I'm not trying to measure performance, I'm trying to understand why changing where a variable is declared changes the speed. According to my understanding, the value should just be dumped into a register as a literal value and than never accessed from memory again either way. Yet that doesn't seem to be the case and I don't see how that could be.

"value should just be dumped into a register as a literal value and than never accessed from memory again either way" Why do you expect that? For an unoptimized build?

@geza You are correct. I had a brain burp. The assembly line instructions are getting it out of the stack pointer and putting it into the register every iteration of the loop. The instructions should reside in the cache and I would think that is where the CPU is accessing them (The L1 cache is 32k, plenty big enough for that code). However, that doesn't really change the results. The assembly line instructions for one is executing 6 operations, whereas the instructions for the other are executing 7 operations. Yet it executes 7 instructions faster than it does 6 (2 billion times). How?

Now, that's a better question :) Instruction count alone doesn't tell too much about the speed of a code. First of all, there are instructions which needs more cycles (For example, a div is much slower than a mov). Current CPUs are pipelined, so dependencies between instructions matter, and branch prediction is important. Instructions have latency and throughput because of the pipelined architecture. There is a lot to tell about CPUs, certainly don't fit here, and I'm not an expert on this subject either. Google it, you'll find a lot of material about this.

Thank you, I think I finally understand why people aren't understanding my question. I'll continue to dig, but I'll try and reword my question so that it is more clear what I am asking. I do know somewhat about pipelining and different costs for operations, but I am also not an expert, hence the question :). Any suggestions about what tags I should include? The c++ tag doesn't seem relevant anymore...

It depends on how you reword the question. If you're interested in intel x86, then there is a tag for that.