I have the following traditional C++03 loop (using auto for stack overflow space efficiency only):
for (auto it = some_vector.begin(); it != some_vector.end(); ++it)
{
foobar.method(*it);
}
In C++11, I managed to rewrite this into the following for_each invocation which works perfectly wel...
@Grizzly boost::flat_map uses a linear search for find. It's hard to imagine that beating std::lower_bound even for 16 elements. It might though. I'll see.
@JohannesSchaublitb When I went to the dentist my teeth were aching. I thought I was in big trouble but the dentist just cleaned the "tooth-stone" which led to heavy bleeding of the flesh at the base of my teeth. He said I needed to brush closer to the base of my teeth and that my tooth flesh was inflammated due to the tooth stone and that caused the bleeding. I followed his advice and it healed in a week. Now my teeth no longer bleed even if I brush on the flesh.
@JohannesSchaublitb The paragraph can be read as "if there are to-be-deduced template paramters inside a templated function parameter, implicit conversions are not performed". That only seems to strengthen my point.
you cannot change a random standards paragraph in a random way and then deduce something from it. by the time you have changed the random standards paragraph, it becomes your standard. It is not the ISO Standard anymore.
A map has no duplicate entries, so of course find will be faster, because it will stop as soon as it finds the element. Vectors, on the other hand, can have duplicates, and lower_bound has to find the first of those, so there is more work to do.
@Xeo i recommend you if you want to know why you quoted the wrong paragraph, you make a SO question quoting the comments @curiousguy did. perhaps other ppl can explain better than him and me.
@FredOverflow I read it several times, std::_Tree::find doesn't stop if it finds an exact match. Because of the way predicates work, it's easy to show that would be slower at least 50% of the time, and from there, slower on average by a large margin.
@FredO: you might want to unaccept my linked answer, as I generally trust @Johannes' judgement, though I just can't seem to wrap my head around to why that paragraph isn't explaining what's happening. The other paragraphs mentioned by curiousguy only seem to allow specific cases (some pointer and derived-to-base conversions), and in all other cases, that paragraph should apply. In my theory, at least.
the text you quoted just says that in template<typename C> void f(C);, you can say f<string>("foo"); and it just works (conversions happen). Because during deduction, the function type is "void(string)", because the C is replaced by the explicit argument before deduction happens.
@JohannesSchaublitb "In general, the deduction process attempts to find template argument values that will make the deduced A identical to A [...]. However, there are three cases that allow a difference: " Those "three cases" should apply to the sentence before that, aka when the deduced A will differ from the transformed A. That doesn't seem to relate to the rest of the argument deduction process.
in c++03 it was underspecified that the same happens also for template<typename T> void f(T, typename identity<T>::type *); f(0, 0);`. some compilers rejected that. in c++11 they are all required to accept this - text was added in 14.8.2.1p4.
"[Note: as specified in 14.8.1, implicit conversions will be performed on a function argument to convert it to the type of the corresponding function parameter if the parameter contains no template-parameters that participate in template argument deduction. Such conversions are also allowed, in addition to the ones described in the preceding list. —end note]"
it refers to the text you quoted
but this is only in one direction. it does not mean that if there are parameters that participate in deduction, that then no conversions are allowed. that would directly contradict 14.8.2.1, as @curiousguy said
@Xeo So you want that question unaccepted? I did struggle accepting it, but ultimately convinced myself that the reason is that operator< is a template.
I was looking over some mock OCJP questions. I came across a really baffling syntax. Here it is.
class OddStuff {
public static void main(String[] args) {
boolean b = false;
System.out.println((b != b));// False
System.out.println((b =! b));// True
}
}
Why does ...
Xeo, Johannes: I'll just let this percolate a bit. I admit that this question had me pretty confused and that I still can't claim that the answers fully convince me, but we can revisit that later.
If you have anything to add, feel free to edit to heart's content.
@Xeo Well, if I have a game of connect four, and the user somehow tries to place a piece in a column that doesn't exist, is that a user error or a coding error?
You could argue it's the programmer's fault for not checking that the index is valid.
@Maxpm You have, in decending order of locality: 1) valid user input (program proceeds along hot path), 2) invalid user input (program proceeds along cold path), 3) critical runtime error (throw exception, recover higher up if possible), 4) broken code (fix at home).
@Maxpm You don't write exceptions, you throw them. There are enough predefined exceptions already to last you a lifetime.
@KerrekSB Err.. I'm more the fan of writing your own exception classes that simply derive and forward to the std ones, to allow better filtering of exceptions and to have nice names when they get through.
If your own code computes the index, then a wrong index is a programming error. If the index comes literally from the user, then it's a normal condition that you must handle.
@KerrekSB In this case, the index will be calculated from a user's mouse click position. My own code will pass it all the way from the GUI to the bare-bones logic class. I'm designing the latter as if it were a public API, though, if that matters.
In computer science, a fixed-point combinator (or fixpoint combinator ) is a higher-order function that computes a fixed point of other functions. A fixed point of a function f is a value x such that x = f(x). For example, 0 and 1 are fixed points of the function f(x) = x2, because 0 = 02 and 1 = 12. Whereas a fixed-point of a first-order function (a function on "simple" values such as integers) is a first-order value, a fixed point of a higher-order function f is another function p such that p = f(p). A fixed-point combinator, then, is a function g which produces such a fixed point p for...
Y g = g (Y g)
In programming practice, the Y combinator is useful only in those languages that provide a call-by-name evaluation strategy, since (Y g) diverges (for any g) in call-by-value settings.
@R.MartinhoFernandes So is Haskell's fix a Y combinator?
Couldn't you argue, though, that every invalid index is beyond the given module's control? Let's say I take away the GUI part and just have my logic class. It has no idea what's being passed to it, and it's expected that some arguments will be invalid. Why wouldn't I throw exceptions for that?
I disagree. I have an array with ten elements. Accessing array[10] is invalid, as is array[11], array[12] and so on, but I expect someone to try to do just that.
@Maxpm It's never an exception. An invalid click is a normal operation, so it has to be handled like that. Either you specify your library to require valid input, in which case it's an assertion in your code (client wrote it wrong), or you handle it in your code (e.g. discard it silently). But in the latter case you would take mouse coordinates as input, not indexes. If you're getting cooked indexes already, tell the cooker to give you only valid indexes.
It's just that they, as far as I can tell, do the same thing. Assertions are a little less verbose. Everyone seems to define the distinction differently.
5.3.4 [expr.new] of the C++11 Feb draft gives the example:
new(2,f) T[5] results in a call of operator new[](sizeof(T)*5+y,2,f).
Here, x and y are non-negative unspecified values representing array allocation overhead; the result of the new-expression will be offset by this amount from ...
@MooingDuck Yeah, I saw that. I first thought that I should be the one deserving all those boats, but to be honest I wouldn't be able to formulate that question as clearly as you did.
@maxpm I came late to the party, but read back some of the discussion. Assertions are for debugging. They're not intended to make it through to the final product. Exceptions are final product error handling suckas. http://www.cplusplus.com/reference/clibrary/cassert/assert/
@JohannesSchaublitb Would you have any thoughts on how to reduce this bugs minimal testcase (gcc.gnu.org/bugzilla/show_bug.cgi?id=51829)? It is pretty small, but in preprocessed form it is still considerable.
@CatPlusPlus In my company the code you write can be modified later by anyone working on something related to it. I don't want people seeing vectors and screwing around my code resizing them.
I've got one of the best positions of all my prom and actually one which I wouldn't be able to get with my education. I'm not going to switch because people could resize my vectors.
@kbok For the record, I'm with the same company for 14 years and counting. I complain a lot, but I won't go and subvert pragmatic programming style just to avoid to fix things/straighten collegues out, or because I'm so possessive about 'my code'
O. M. G. What do 'the (eee) people (ooo) outside of my team' (with scary paws?) have to do with 'your vectors'? The whole notion of 'they can touch my vectors' seems... childish and a bit off-the-mark
I mean, we have tests, (unit, integration, acceptance, regression, the whole lot) and they will catch any unwarranted rummaging with vectors. And we do tell the culprits not to repeat that
@kbok Precisely. Soooo they can resize your vectors. Document it ('dont resize the vector') or... the best way is not to expose the vector. Expose an iterator range - make std::begin()/std::end() work with them and there is no need to worry
@sehe We have many classes with sets of data stored in several vectors. The global assumption is that they all have the same size. Is someone were to resize one of them, that would lead to errors. Surely not fatal, because we have quality process and so on, but the real problem here is that vectors carry the semantic of being resizable which is wrong.
@kbok You're worried that someone will open your class's source file to make changes and think that the private vector member variable can be resized, right?
@kbok Mmm not so very, but ok, rereading my messages I have to admit I'm apparently venting a bit after trying to minimize a bugreport for gcc 4.6/4.7. Sorry if that surprised you.... There was a hint though: "I complain a lot"
+1 And learn to trust yourself. You sound a bit to paranoid, like I used to (and sometimes still do). Accept that you will make mistakes, but solve it by designing for simplicity and documenting the invariants.
True, but in practice, special-casing too many things often leads to complicating the code, leading to more errors... There is a solid reason why highlevel programming languages love their highlevel libraries: everybody knows them well, and they are designed for flexibility