I don't know any interesting bugs in symbolic algebra packages but I know a true, enlightening and entertaining story about something that looked like a bug but wasn't.$\def\sinc{\operatorname{sinc}}$
Define $\sinc x = (\sin x)/x$.
Someone found the following result in an algebra package:
$\int...
You could use a and b to trigger a template instantiation that is only defined if a == b. Otherwise you get a linker error. That linker error will show the values of a and b.
I'd like to learn how to make an application take occasional self-benchmarking samples while running in the field. And get it to report the results somewhat cleanly.
You can do a running average? But certainly a higher level of granularity might be better. I think this is a solved problem BUT nobody here knows the answer.
@Voyska No, it was not reported as a bug, just as an 'oddity' (or something like that). Jon was not mean, but playful in a devious way. He will be missed. — Jacques Carette3 hours ago
Bulldozer was among the biggest CPU failures, they thought that nobody cared about FPU performance and attempted to compete on integer. They ended up with a chip that was cheaper, but nobody wants the cheap stuff.
I've been expecting Zen to have dual-issue 256-bit SIMD. That would make it even with the current Intel chips. But the latest slides have me doubing that.
Right now, an Intel processor can easily sustain 4 scalar integer inst/cycle. And 2-3 256-bit SIMD/cycle. (used to be 2, now learning towards 3 with Skylake)
I had trouble getting over 2 inst/cycle on my FX-8350.
When I was programming for the FX-8350, there were two major problems that fucked everything up: 1. 256-bit AVX stores were 1 every 20 cycles. (that's a CPU bug which they fixed later) 2. Every other store to memory was delayed by bank or aliasing conflict.
If I had 2 streams writing to memory, it was fast. (~2 cycles/store)
At 3 streams, it went up to like 10. At 4 streams, it was like 40. At 5 streams, it was 170.
Agner Fog also noticed this.
Basically, if you need 170 cycles to store something, you're in pretty deep shit.
Other than that, the main execution engine was actually pretty good. Worse than Intel, but it didn't suck.
He believes that Bulldozer's memory disambiguation unit is completely fucked up.
And if you can't reorder newer loads with older stores, you won't be able to parallelism across loop iterations for common loops.
That last one is actually really important. Consider this trivial (but common) loop:
for (int c = 0; c < N; c++){
A[c] += x;
}
The compiler will see the instruction stream as:
read A[0]
add
write to A[0]
read A[1]
add
write to A[1]
read A[2]
add
write to A[2]
@Aaron3468 The memory locations. The processor needs to determine that a later load is to a different address to an earlier store. Otherwise, it can't do the load early.
@Aaron3468 Memory disambiguation is a very difficult thing to do. In a lot of cases, you don't know the address of later load until the last moment (think linked list).
If you only ever reorder when you know the addresses, you'll lose a lot of performance. So what modern processors do is they guess. Yes branch-prediction for memory accesses. For each load you guess (using the same techniques as branch prediction) at whether it will have a conflict with an earlier store.
If you guess no, go ahead and do the load early. If it turns out that there is a conflict. Rollback the pipeline like you do with a normal branch misprediction.
@Morwenn This just in time greeting/evening greeting brought to you by the letter P. Remember P-code boys and girls. No, I did not say to pee on my boot young man!
@CaptainGiraffe Actual giraffes spend enough time with their tongues sticking out to eat that they have melanin in their tongues. The tip usually gets a really dark tan (just like a person who sun-tans a lot) but the back (exposed to less sun) is pink. Somewhere in between, the two mix, and can produce an almost purplish color.
@CaptainGiraffe This rerito guy? Please don't tell me there's more than one!
@Darkrifts If I said you couldn't, that might be a challenge. Crashing it isn't much of a challenge at all. If you have any trouble, I'm pretty sure @ThePhD can help.
@Aaron3468 Probably, but that's a lot of work. Mutually recursive templates let you do the job with a lot less code (and if you're careful, you can get the compiler to waste a ridiculous amount before it gives up).
Why is it that overflows are UB? I imagine that of all things, defining them fixes many bugs. Even if it means having a flag to temporarily switch behaviour when necessary (between clamping and wrapping).
