Lounge<C++>

user1357851

2:00 AM

generally O(N) linear speed is the best speed you can hope for

nneonneo

NP -- the set of all problems we can verify a solution for in polynomial time

We know that any P problem is NP

because we can always verify a problem by just finding the solution independently

Rapptz

@nneonneo ?

nneonneo

sorry, what's confusing?

Rapptz

I didn't know that, seems weird.

melak47

@nneonneo calling it "reduction" has always confused me - if you can only reduce to a problem that's harder or equally as hard, it's hardly reducing our problem :p

nneonneo

2:01 AM

yeah, so mathematically P is a subset of NP

@melak47: yes, "reduction" means you always reduce to a problem that is at least as hard.

on the flip side, it means that if we solve any NP-complete problem in polynomial time

then we use that chain of reductions to solve every NP problem in polynomial time

Mysticial

@melak47 You basically show that for any given problem of type X, you show that you can solve it by solving a problem of type Y.

nneonneo

why's that? NP-complete is defined as the subset of NP problems to which any NP problem can be reduced.

melak47

@Mysticial I know :)

Rapptz

@nneonneo Ah that's clearer.

nneonneo

let me rephrase: if you have any problem in NP, then you can somehow reduce it to a problem that is NP-complete

and consequently, NP-complete problems must be, in some sense, the hardest problems in the whole NP class

user1357851

2:04 AM

I think I am off to some more meaningful deployment (continue my Android app :p)

nneonneo

because if we could solve any one of those easily, we'd solve the whole lot (but nobody, ever, has managed to do that yet)

NP-hard, by the way, means any problem to which you can reduce an NP problem

melak47

so lets get on the bomb dropping for great success!

nneonneo

so you can reduce an NP problem to anything that is NP-hard

but NP-hard doesn't restrict itself to NP, so that's like saying you can reduce any problem to the halting problem

StackedCrooked

Some examples would be nice :)

nneonneo

yeah, I konw

I'm trying to recall any nice examples of reductions from class

Mysticial

2:05 AM

graph coloring?

traveling salesman

nneonneo

TSP is kind of cool

but reducing e.g. 3SAT to TSP is totally nontrivial

Mysticial

I'm most familiar with graph coloring since it's used for register allocation.

nneonneo

you can reduce some P problem to TSP for fun, I guess...let's see

melak47

heh, for fun :p

nneonneo

well, OK, here's an easy reduction

the problem of detecting if a graph is bipartite is in P

Xeo

2:06 AM

If a graph is what?

Mysticial

@nneonneo You're gonna have to explain bipartite.

StackedCrooked

lol

Mysticial

That's a complicated term.

nneonneo

right

are you familiar with graphs in general?

nodes, edges, etc.?

Xeo

aye

Mysticial

2:07 AM

Basically if you can color a graph with only two colors and no two nodes connected nodes have the same color.

nneonneo

ok

Rapptz

There's this in SO.

Mysticial

@nneonneo Bipartite is poly right?

nneonneo

yes

Mysticial

It's 3 and up that's NP-complete.

nneonneo

2:08 AM

right

calculating the chromatic number of a graph -- the minimum number of colours you need to colour it -- is NP-complete

Xeo

Wait.. what is that colouring all about? :)

Mysticial

@nneonneo verifying that number is poly? or non-poly?

StackedCrooked

@Xeo See this image.

nneonneo

well, a proof of verification is the colouring

which of course can be verified in polytime

Mysticial

@StackedCrooked That image is confusing as fuck.

nneonneo

2:10 AM

therefore the chromatic number is in NP

Mysticial

@nneonneo But if you have just the number, (without the actual solution), is it still poly to verify?

nneonneo

OK!! Bipartite graph -- you can split the nodes into two groups such that the edges only go from one group to another. Never between nodes in the same groups

@Mysticial: No. That would be the graph colouring problem, another NP problem.

Xeo

So you have to find those groups or what?

nneonneo

@Xeo: Or just say whether you can split the graph or not.

Simple example: a triangle graph is not bipartite

Xeo

Wait a sec

Mysticial

2:11 AM

@Xeo So see if it's even possible in the first place.

nneonneo

no matter how you divide up the three nodes, one of the edges will always go between two nodes in the same group

Mysticial

@Xeo Another way to think of this is: You color all the nodes in a graph either red or blue such that each node is not connected to any other node of the same color.

Xeo

k, I think I got it.

nneonneo

now, what happens if we get more colours to use?

StackedCrooked

So a graph without cycles is always bipartite?

Xeo

2:14 AM

Sometimes, if I have multiple somethings lying around together, I try to connect them without going connecting to a direct neighbour - would that also be something similar?

Mysticial

@StackedCrooked I think that's correct.

StackedCrooked

@nneonneo It becomes easier.

nneonneo

@StackedCrooked:a graph without cycles is a tree, and trees are bipartite because you can colour the odd levels red and the even levels blue

Doorknob

0

Q: vertical scroll bar in IE6

i am facing problem on div tag with vertical scroll. when i minimize the window the scroll bar does not appear in a small size window. i am using Window Server 2003 sp2 and IE6 as client. Below is my div tag.. <div style="border: 1 none Black; vertical-align: top;overflow:auto; height:470px;...

Lol... IE6?!?!

nneonneo

@StackedCrooked: in fact, a graph with no odd cycles is bipartite

heh

Mysticial

2:14 AM

So the catch is. Determining whether or not a graph is bipartite is an "easy" task. Doable in polynomial time.

StackedCrooked

Ah, and a triangle has three edges, which is an odd number, so it's no biparite.

nneonneo

yep

melak47

@Doorknob how odd..if you minimize the window, there is no scroll bar? :p

nneonneo

immediately you can think of some easy ways to solve the problem quickly

Mysticial

But when you go to 3 colors or more, it becomes "hard". NP-complete. There is no known algorithm to do it polynomial time.

Doorknob

2:15 AM

haha

nneonneo

@Mysticial: neat, there's actually a site that shows the 3SAT reduction for graph 3-colorability: shannarasite.org/kb/kbse60.html

Doorknob

our customer use IE6, so i have no choice on this. — Sweta Priya 1 min ago

ahaha

nneonneo

@Doorknob: :'(

StackedCrooked

@nneonneo Traverse the graph and keep a list of all nodes you passed. If you meet a previously encountered node then the odd or evenness of the distance between those nodes determines bipartiteness?

nneonneo

by the way, with some of this background I think en.wikipedia.org/wiki/P_versus_NP_problem can be useful for understanding P and NP

@StackedCrooked: pretty close

you can skip the "distance" check by just assigning the nodes to groups as you see them

StackedCrooked

2:19 AM

With 'distance' I mean traveled distance.

nneonneo

right

but yeah, it's not a "hard" problem

melak47

just go start coloring like mad :D

nneonneo

yeah

StackedCrooked

@nneonneo Oh, lol.

nneonneo

but once you go to 3 colourability, it gets hard

because you can't rely on odd/even to help you

StackedCrooked

2:19 AM

Dammit.

nneonneo

and assigning randomly will result in back tracking between the two other colours

because, as it turns out, 3-colourability is NP-complete

(dunh dunh dunh!)

Xeo

Btw, how can you prove something to be NP-complete?

nneonneo

you reduce some other NP-complete problem to it

that shows the problem is NP-hard

then you just have to show it is in NP by demonstrating some way to verify a solution

Mysticial

@Xeo Suppose X is known to be NP-complete. And you show that you can solve X by solving Y, then you're proved that Y is ~~NP-complete~~ NP-hard.

nneonneo

well, almost

Xeo

2:22 AM

@nneonneo what if there was no other NP-complete problem? :)

nneonneo

you've proven that Y is NP-hard

FredOverflow

@nneonneo Doesn't NP stand for "no problem"? Doesn't sound very hard to me ;)

nneonneo

@Xeo: there's a very famous theorem called Cook's theorem

which establishes the NP-completeness of a problem independently of any other NP-complete problem, by modelling a Turing machine

so, basically, they proved the first NP-complete problem

from there, they started reducing all these other problems

StackedCrooked

But how did they prove the first NP-complete problem without another NP-complete problem to reduce it to?

Mysticial

@StackedCrooked They just defined it that way.

nneonneo

2:24 AM

@Mysticial: not really...

it's a bit abstract, but basically they proved that any algorithm that solves an NP problem can be modelled using some instance of boolean satisifiability

Mysticial

@nneonneo It doesn't matter which one you use as the "master". Most of them reduce to each other no?

melak47

tell us tell us uncle nneonneo, why did the mad evil computer scientists create this evil NP completeness?

nneonneo

@Mysticial: nope, doesn't matter

@melak47: because they needed something to do

complexity theory was getting boring

(and now that all the easy research is done, and only the impossible P=NP problem remains, it's getting a bit boring again)

Xeo

Welp, atleast I now get what this whole P=NP deal is all about. Is what I think, anyways.

nneonneo

oh yeah, that

P=NP asks -- if it's so easy to verify a solution, is it easy to find the solution in the first place? And nobody knows.

right now we just kind of assume it's hard to find the solution for an NP-complete problem

so you say "NP-complete" and we just kind of go "aww, is there at least an approximation"?

by the way, NP-complete problems vary wildly in how easy they are to approximate

Xeo

2:28 AM

Mhm. And then, if any NP-complete problem happens to be solvable in polynomial time, shit hits the fan.

Oh yeah

@Xeo yes

big time

So, the 3-colourability is NP-complete because it's easy to verify, but NP-hard to solve.

nneonneo

well, it's suspected hard to solve

it's NP-complete because it's easy to verify, and other problems reduce to it

the difficulty of solving it doesn't actually factor into it

StackedCrooked

2:29 AM

right

nneonneo

by the way, there are some problems that are strongly suspected to be not NP-complete, but also not in P

of course this is impossible if P=NP, but the existence of such "middle-ground" problems suggests that P≠NP

for example, factoring integers is suspected to be not in P

but it's also not NP-complete, as far as anyone can tell

you see, there's a great deal of uncertainty about these things :(

Xeo

Well, I can't imagine how there couldn't be. :)

melak47

@nneonneo why is it not np-complete? is it not easy to check if a given set of factors make up a number?

Xeo

There's always the chance somebody stumbles upon a new solution that changes everything

nneonneo

@melak47: It's NP

as you said, it's easy to check if a given set of factors multiply to make a number

Mysticial

2:32 AM

Nobody has been able to reduce prime-factorization into any existing NP-complete problem.

melak47

oh.

Mysticial

Despite the fact that it is still a hard problem.

nneonneo

(any NP-complete problem into factorization)

Mysticial

blah blah....

melak47

lol

nneonneo

2:33 AM

actually, proving a number is prime was thought to be one of these "not-in-P" problems for a long time

until AKS came out with the "PRIMES is in P" paper that showed that you can prove primality in polytime

that paper gives a tiny glimmer of hope that factorization might be in P

but we're not there yet

Mysticial

@nneonneo Well... the rabin-miller algorithm has arbitrarily high certainty. And if the Riemann Hypothesis held, then Rabin-Miller automatically becomes deterministic with enough iterations.

melak47

but but, if factorization is in P, doesn't that break encryption and shit? D:

Xeo

I wonder if we even want to find P=NP to be true.

Mysticial

So it was kind of a barrier that was ready to fall.

nneonneo

@Mysticial: true, but AKS shows that without requiring Riemann

though since everyone basically assumes Riemann is true (*), I guess it's a moot point

StackedCrooked

2:35 AM

If we find the answer as to whether P=NP. What will the implications be?

melak47

@StackedCrooked that computers are even more awesome than before :D

Mysticial

@StackedCrooked You get the largest e-penis in the world for about 2 weeks.

StackedCrooked

lol

nneonneo

@StackedCrooked: any solution to that problem probably involves new math

i.e. entirely new approaches to problems

Mysticial

@melak47 Yes it does.

nneonneo

2:36 AM

so even if we find P≠NP, the field of math and theoretical CS gets a big step up

of course, if we find that P=NP then everything changes

(gradually)

P=NP is an interesting case

the proof might not be constructive

melak47

@nneonneo ....if P=NP, would that mean there are no problems that aren't in P? or would we still have another class of hard problems :/

Xeo

I wonder if all this isn't moot anyways thanks to quantum computing. :)

nneonneo

in which case, it says that there is a polytime solution to an NP-complete problem, but doesn't say what the algorithm is

StackedCrooked

@Xeo I was thinking the same :)

nneonneo

@Xeo: BQP is a thing

Mysticial

2:38 AM

@Xeo Quantum computing will solve factorization. But it is not believed to solve NP-complete problems.

StackedCrooked

Will NP problems be solvable with quantum computing?

Oh.

nneonneo

BQP: the class of problems solvable by a bounded-error quantum computer in P time

StackedCrooked

@nneonneo Right.

nneonneo

It is suspected that not all NP problems can be solved by BQP

in which case quantum computers don't magically give us the ability to solve NP-complete problems in polytime

quantum computing, by the way, is mind bending

you do crazy stuff like compute quantum fourier transforms (QFTs) to find integer roots

Mysticial

Shor's algorithm for factorization is pretty crazy.

nneonneo

2:40 AM

@melak47: if P=NP, all NP problems are in P

Mysticial

Quantum fourier transform to extract the modular repetition frequency.

nneonneo

there is another class of harder problems

melak47

@nneonneo but, there are more problems, right?

nneonneo

yes

PSPACE, EXPSPACE, ALL

Mysticial

Once you have that frequency, then you do continued fractions to construct it...

nneonneo

2:41 AM

and dozens of complexity classes in between

melak47

some day they are going to look back at this as the dark ages of cs... they couldn't even figure out if P=NP!

nneonneo

complexityzoo.uwaterloo.ca/Complexity_Zoo

@Mysticial: isn't it repeated squaring? the way they taught it in QC was that the algorithm's postprocessing amounted to repeatedly doubling a very tiny angle

Mysticial

@nneonneo It's a bit different than what I read.

nneonneo

effectively, the solution shows up as an absolutely minute bump in one of the fourier coefficients, so you basically square the whole thing repeatedly (which has the same effect as doubling the phase angle) until the thing aligns with an axis you can easily read off

it's bonkers

Mysticial

IIRC, you evaluate the power modulus to every power simutaneously. And perform a quantum FFT on it. Because modulus is periodic, it will show up as a spike in the frequency domain.

nneonneo

2:44 AM

ja

Mysticial

You measure that spike to get the frequency. And use continued fractions to construct it back into an integer ratio.

And that is essentially the factor.

melak47

bahnhof is all I'm getting here :p

nneonneo

hm. my notes from QC are somewhere...

StackedCrooked

Just checking: P means time required is upper bound by input_size^a_constant. So if a problem requires input_size^input_size time then it's not P, and thus NP. (Unless it's one of those middle cases?)

nneonneo

An Introduction to Quantum Computing by Kaye, LaFlamme and Mosca

@StackedCrooked: something like O(n^n) is probably NP-complete.

probably.

remember, any practical problem you are likely to run into is NP-complete

except those crazy PSPACE-complete things like generalized Go

StackedCrooked

2:46 AM

The go board game?

nneonneo

yeah

generalized Go is played on an arbitrarily big surface

the question "who wins" is PSPACE-complete

melak47

what problem class would you say does writing a standard compliant C++ compiler fall in? :v:

nneonneo

@melak47: well, a C++ compiler can calculate basically anything by virtue of template metaprogramming

writing the compiler is a solved problem

Mysticial

and TMP is turing complete

nneonneo

tmp?

StackedCrooked

2:49 AM

template meta-programming

melak47

template metaprogramming :p

nneonneo

oh yeah

Mysticial

template ~~masturbation~~ meta programming.

nneonneo

durr

yeah, TMP is turing complete

there's a whole interesting discussion in there

Xeo

constexpr is turing-complete too~

Mysticial

2:49 AM

Your mom is turing complete.

melak47

too obvious :p

Xeo

I wonder if the CPP is turing-complete too.

Which would mean we got 4 touring-complete languages in 1. Who can beat that deal?

StackedCrooked

TMP can do selection and recursion. I think this fulfills the Turing completeness requirements?

A file can include itself, so you can have iteration. And you also have selection with #if and #ifdef.

melak47

a file can include itself? o.O

Xeo

BOOST_PP_ITERATE <3

nneonneo

2:52 AM

30

A: Is the C99 preprocessor Turing complete?

Well macros don't directly expand recursively, but there are ways we can work around this. The easiest way of doing recursion in the preprocessor is to use a deferred expression. A deferred expression is an expression that requires more scans to fully expand: #define EMPTY() #define DEFER(id) i...

basically, the answer is "probably".

yeah, C++ is insane

@melak47: yeah, files can include themselves. popularly abused by IOCCC entrants

there are some really clever IOCCC entries that cause cpp to take up ungodly amounts of time or space through recursive includes

Xeo

@nneonneo Well, Boost.Preprocessor is awesome after all.

nneonneo

yeah, that too

Xeo

And the facilities there suggest that it is indeed turing complete

ThePhD

Turing complete in a very messy, ass-backwards kind of way.

Xeo

room topic changed to Lounge<C++>: Try and beat our 4-in-1 turing-complete languages deal. [c++] [c++11] [c++-faq] [no-helpdesk]

ThePhD

2:55 AM

By turing-complete nonetheless.

StackedCrooked

I think it's not Turing complete. The expansion must stop at one point.

Unless you use __COUNTER__ perhaps.

Xeo

@StackedCrooked That's just like we have finite memory.

In practice, nothing is turing-complete.

But in theory, all 4 sublanguages of C++ are.

ThePhD

4?

There's only 3: template metawankery, preprocessor, and then the language itself.

Xeo

CPP, Core, constexpr, TMP

ThePhD

Oh.

melak47

2:58 AM

Core?

Xeo

@melak47 Well, just C++ itself

The "runtime" part, so to speak

melak47

@Xeo oh - CPP == pre processor

Xeo

Yes

StackedCrooked

Heh, why does this increment in step 2?

Oh. I see it.

Xeo

#if N < 10
N

StackedCrooked

2:59 AM

I'm printing N.

Xeo

@StackedCrooked Btw, clicking "edit" should give you the command line from the link

StackedCrooked

@Xeo Yeah.

sehe

Ohai. Trivia: what does the following print (no cheating!)

#include <complex>
#include <iostream>

// imaginary numbers
std::complex<long double> operator "" _i(long double d) // cooked form
{
    return std::complex<long double>(0, d);
}

int main(int argc, const char *argv[])
{
    auto val = 2._i; // val = complex<long double>(0, 2)
    val *= -val;
    std::cout << val << '\n';
    val *= -val;
    std::cout << val << '\n';
}

Xeo

@sehe If you did that in a loop, you'd get a kind of spiral, right?

Welp, or not

sehe

Ah welp. I think we both had the same thinko: val *= -val :)

Anyways, look what I found in t.co/dmjeCZJkDt (it's on slide #28)

I can no longer maintain I'm never present at technical conferences

nneonneo

3:10 AM

@sehe: 4, then -16?

sehe

@nneonneo You get the mixer

nneonneo

sorry, my american culture is not good

what is mixer ?

sehe

I'm not american :)

nneonneo

that...is an eggbeater.

sehe

It's funny for "you get a lousy prize"

nneonneo

3:13 AM

aha

Sleep well!

..?

4:13 am here

night

Same

G'night :)

melak47

3:14 AM

night

Xeo

And thanks @nneonneo @Mysticial for enlightening me. ;)

Rapptz

Can you explain why it's (4,-0) before you go? :|

nneonneo

4, -0?

Mysticial

@Xeo night

Xeo

@Rapptz think of the i part as rotation and scaling

nneonneo

3:14 AM

wh?

oh, what it outputs

...it's like they don't teach imaginary numbers anymore?

Xeo

the sign determines whether you rotate CCW (+) or CW (-) on the imaginary plane

Rapptz

@nneonneo eh?

Xeo

the number determines the scale applied.

Rapptz

@nneonneo ??

nneonneo

what was this about a spiral?

ok, why is val *= -val confusing?

Rapptz

3:17 AM

It isn't?

nneonneo

ok

...

Rapptz

my guess was 4, -16

I've never used std::complex

Xeo

(0, 2) * (-0,-2) -> the point (0, 2) is on the Y axis, if you will, and rotates CW (negative imaginary part) -> (2, -0) -> the 2 scales by 2 -> (4, -0)

nneonneo

wait, the output is 4, -0? that would surprise me

Rapptz

@nneonneo Yes

nneonneo

3:18 AM

...

Rapptz

4, -0 and -16, 0

Xeo

@Rapptz -16

Rapptz

my bad

Oh I forgot to apply - to the zero.

nneonneo

oh haha

I see

Xeo

and after (4, -0), you multiply again, this time by (-4, 0), which means no rotation and times -4 for scaling.

nneonneo

3:19 AM

I didn't quite understand how std::complex would be output

so yeah, (4,-0) is just 4-0j

and (-16,0) is -16+0j

in other words, 4 and -16

Rapptz

yeah

Xeo

Y U j :P

nneonneo

hey, it's the standard in engineering

and I'm a Python programmer, where it's typically j

>>> 4+2j
(4+2j)

and all that

Xeo

And once you are on negative X, -val will give a positive scaling, meaning you just scale farther into negative X.

Rapptz

I just forgot to distribute the negative to the zero

nneonneo

3:21 AM

@Rapptz: to be perfectly fair, I don't think you normally have to do that in math

predicting when zeros will sprout negatives in C++ is not that much fun, I think

@Xeo: so how do you interpret (1+1j) * (1+1j)?

Rapptz

(i+1)^2 = 2i?

nneonneo

mhm

actually isn't that hard to see when you view it as a scaling+rotation

Xeo

I just find it easier to visualize arithmetic with complex numbers that way

I just view them as some kind of bastardized child of points and 2D vectors.

nneonneo

hm

y'know, I still don't understand quaternions

Xeo

Me neither. They're dicks. :<

ThePhD

3:29 AM

A range is responsible for keeping track of its current position in the range, right?

Much like an Enumerator from C# ?

@nneonneo Quaternions are the fucking devil and should die in a horrific fire.

Xeo

What kind of range are you talking about?

ThePhD

All the ranges.

nneonneo

@ThePhD: how else do you do free-space rotation transforms without horrific singularities?

ThePhD

@nneonneo Changing the reference vector, yo.

Xeo

@ThePhD In current C++, you get the iterators from the ranges, and go from there. The range does nothing.

nneonneo

3:32 AM

@ThePhD and how do you rotate the reference vector?

ThePhD

@nneonneo You select a second reference vector and use that when you're not swirling about the first one.

nneonneo

then a third for z...so you are just constantly rotating the reference frame around?

ThePhD

Yep.

:D

nneonneo

ah. I see that would be easier.

ThePhD

Of course. :D

melak47

3:38 AM

so basically you're what, storing a rotation matrix?

ThePhD

A vector.

Or maybe I'm not?!

Who knoooows?!

StackedCrooked

@ThePhD lol

Xeo

Alright, time to really get to sleep.

ThePhD

And do more sleep-talking?

nneonneo

@Xeo: night

Xeo

3:48 AM

It's close to 5am here now, and I only stayed awake till now because of the turing-completeness stuff

G'night everyone

melak47

night, for real :p

Rapptz

4:03 AM

0

Q: The differences between Java and C++ in efficiency

I have learnt the entry knowledge of both Java and C++, the auto release memory function from Java is amazing and the structure of class of Java is more decent (it is only my own opinion, please ignore it if you disagree with it). I understand why Java is said to be more programmer friendly than ...

java c++ compare

Rapptz

4:30 AM

docs.google.com/presentation/d/…

Games Brainiac

4:55 AM

So, anyone here running for mod?

Pubby

@GamesBrainiac Flexo is

Games Brainiac

@Pubby Who is flexo?

Pubby

Flexo

28.9k 9 43 84

c++ swig c java python linux c++11

Games Brainiac

Since Mooing Duck is not running, I guess I really am not voting for anyone.

Inisheer

I thought about it, but I know I wouldn't make it since I would ban all the @$$-hats that flame new SO users with "uhhh google dude" comments. So basically, SO would have only 3-5 remaining users.

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