do some whitespace janitor work

master
neingeist 10 years ago
parent 0e43b30736
commit 7db74eb991

@ -14,7 +14,7 @@ struct myclass {
int main() {
int init = 100;
int numbers[] = {10,20,30};
int numbers[] = {10, 20, 30};
int res;
std::cout << "using default accumulate: ";

@ -6,12 +6,12 @@ void classic() {
int array[2];
array[0] = 1;
array[1] = 2;
array[3] = 3; // <- clang++ -Warray-bounds warns about this
array[3] = 3; // <- clang++ -Warray-bounds warns about this
int n = 10;
std::cout << array[3] << std::endl; // no warning!
std::cout << array[4] << std::endl; // no warning!
std::cout << array[n-1] << std::endl; // no warning!
std::cout << array[3] << std::endl; // no warning!
std::cout << array[4] << std::endl; // no warning!
std::cout << array[n-1] << std::endl; // no warning!
}
void std_array() {
@ -22,7 +22,7 @@ void std_array() {
// whoopsie
array[2] = 3;
for(auto &e: array) {
for (auto &e : array) {
std::cout << e << " ";
}
std::cout << std::endl;
@ -44,10 +44,10 @@ void std_vector() {
}
vector.resize(10);
vector.at(2) = 3;
vector[1] = 2; // should now work
vector[1] = 2; // should now work
// vector[3] = 3; // SEGFAULT
for(auto &e: vector) {
for (auto &e : vector) {
std::cout << e << " ";
}
std::cout << std::endl;

@ -13,9 +13,9 @@ int main() {
y = x;
std::cout << x.get() << std::endl; // Print NULL
std::cout << x.get() << std::endl; // Print NULL
assert(x.get() == NULL);
std::cout << y.get() << std::endl; // Print non-NULL address i
std::cout << y.get() << std::endl; // Print non-NULL address i
assert(y.get() != NULL);
return 0;

@ -3,11 +3,9 @@
class mybase {
protected:
std::string ids;
public:
mybase(std::string ids)
: ids(ids) {}
@ -17,16 +15,13 @@ class mybase {
};
class myclass : public mybase {
public:
myclass(std::string ids)
: mybase(ids) {}
void foo() {
std::cout << "i'm a myclass! ids: " << ids << std::endl;
}
};
void nocast(myclass* x) {
@ -40,8 +35,8 @@ void ccast(void* x) {
}
void staticcast(void* x) {
// C++ static_cast. When I *know* it's myclass*, and want to revert an implicit
// conversion.
// C++ static_cast. When I *know* it's myclass*, and want to revert an
// implicit conversion.
myclass* foo = static_cast<myclass*>(x);
foo->foo();
}
@ -64,11 +59,11 @@ int main() {
std::cout << "== ccast" << std::endl;
ccast(&a);
ccast(&base); // XXX actually works!
ccast(&base); // XXX actually works!
std::cout << "== staticcast" << std::endl;
staticcast(&a);
staticcast(&base); // XXX actually works!
staticcast(&base); // XXX actually works!
std::cout << "== dynamiccast" << std::endl;
dynamiccast(&a);

@ -63,37 +63,37 @@ int main() {
callptr(&animal);
std::cout << "== cat" << std::endl;
animal = cat; // <- lol, operator
animal = cat; // <- lol, operator
animal.makeSound();
call(cat);
callref(cat); // <- meow
callref(animal); // <- generic
callptr(&cat); // <- meow
callref(cat); // <- meow
callref(animal); // <- generic
callptr(&cat); // <- meow
std::cout << "== cow" << std::endl;
animal = cow; // <- lol, operator
animal = cow; // <- lol, operator
animal.makeSound();
call(cow);
callref(cow); // <- mooh
callptr(&cow); // <- mooh
callref(cow); // <- mooh
callptr(&cow); // <- mooh
std::cout << "== refs" << std::endl;
Animal &aref = cat;
aref.makeSound(); // <- meow
aref = cow; // <- lol, operator
aref.makeSound(); // <- meow, still
aref.makeSound(); // <- meow
aref = cow; // <- lol, operator
aref.makeSound(); // <- meow, still
std::cout << "== vector<Animal>:" << std::endl;
// Does nothing:
std::vector<Animal> animals = { cat, cow }; // <- Copies
for (auto &a: animals) {
std::vector<Animal> animals = { cat, cow }; // <- Copies
for (auto &a : animals) {
a.makeSound();
}
std::cout << "== vector<Animal*>:" << std::endl;
// Meow? Mooh.
std::vector<Animal*> animalptrs = { &cat, &cow };
for (auto &a: animalptrs) {
for (auto &a : animalptrs) {
a->makeSound();
}
}

@ -6,8 +6,8 @@
#include <chrono> // std::chrono::milliseconds
// a non-optimized way of checking for prime numbers.
bool is_prime (long int x) {
for (long int i=2; i<x; ++i) {
bool is_prime(long int x) {
for (long int i = 2; i < x; ++i) {
if (x%i == 0) return false;
}
return true;
@ -35,12 +35,13 @@ void implicitly_waiting() {
long int p2 = 685102597328182763;
std::future<bool> fut = std::async(std::launch::async, is_prime, p2);
std::cout << "just getting the result, doing an implicit wait():" << std::endl;
std::cout << "just getting the result, doing an implicit wait():";
std::cout << std::endl;
bool x = fut.get();
std::cout << p2 << " " << (x?"is":"is not") << " prime." << std::endl;
}
int main () {
int main() {
explicitly_waiting();
implicitly_waiting();
return 0;

@ -7,7 +7,6 @@
using namespace std;
int main() {
// notice how the lists are nested to match the templates' parameters:
map<string, vector<pair<string, int>>> name_languages_year {
{"Dennis Ritchie", {{"B", 1969}, {"C", 1973}}},
@ -27,5 +26,4 @@ int main() {
// prints 'Lisp':
cout << name_languages_year["John McCarthy"].at(0).first << endl;
}

@ -1,12 +1,12 @@
#include <cstdio>
struct A {
A() { puts("A()"); }
A() { puts("A()"); }
~A() { puts("~A()"); }
};
struct B {
B() { puts("B()"); }
B() { puts("B()"); }
~B() { puts("~B()"); }
};

@ -1,4 +1,4 @@
/* http://en.wikipedia.org/wiki/C++14 */
// http://en.wikipedia.org/wiki/C++14
#include <cassert>
#include <iostream>

@ -32,7 +32,8 @@ class Hammer : public Tool {
}
void use(Nail nail) {
std::cout << "The nail is " << nail.getLength() << " cm long" << std::endl;
std::cout << "The nail is " << nail.getLength() << " cm long"
<< std::endl;
}
};
@ -50,7 +51,7 @@ void useSomeTool(Tool &tool) {
std::cout << "Look, it's a " << typeid(tool).name() << "!" << std::endl;
// XXX What about subclasses of Hammer?
if(typeid(tool) == typeid(Hammer)) {
if (typeid(tool) == typeid(Hammer)) {
std::cout << "Stop! ";
}
tool.use();

@ -9,7 +9,7 @@ void shared_ptr() {
std::cout << __FUNCTION__ << std::endl;
std::shared_ptr<int> p1(new int(5));
std::shared_ptr<int> p2 = p1; // Both now own the memory.
std::shared_ptr<int> p2 = p1; // Both now own the memory.
assert(p1.use_count() == 2);
// Memory still exists, due to p2:
@ -29,7 +29,7 @@ void shared_ptr_container() {
std::cout << __FUNCTION__ << std::endl;
std::shared_ptr<int> p1(new int(5));
std::shared_ptr<int> p2 = p1; // Both now own the memory.
std::shared_ptr<int> p2 = p1; // Both now own the memory.
assert(p1.use_count() == 2);
std::vector<std::shared_ptr<int>> v;
@ -49,20 +49,20 @@ void weak_ptr() {
std::cout << __FUNCTION__ << std::endl;
std::shared_ptr<int> p1(new int(5));
std::weak_ptr<int> wp1 = p1; // p1 owns the memory.
std::weak_ptr<int> wp1 = p1; // p1 owns the memory.
{
std::shared_ptr<int> p2 = wp1.lock(); //Now p1 and p2 own the memory.
std::shared_ptr<int> p2 = wp1.lock(); // Now p1 and p2 own the memory.
assert(p2 != NULL);
if (p2) { // As p2 is initialized from a weak pointer,
// you have to check if the memory still exists!
if (p2) { // As p2 is initialized from a weak pointer,
// you have to check if the memory still exists!
// Do something with p2
}
} // p2 is destroyed. Memory is owned by p1.
} // p2 is destroyed. Memory is owned by p1.
assert(wp1.lock() != NULL);
assert(wp1.use_count() == 1);
p1.reset(); // Memory is deleted.
p1.reset(); // Memory is deleted.
assert(wp1.lock() == NULL);
assert(wp1.use_count() == 0);

@ -1,8 +1,7 @@
#include <cassert>
#include <iostream>
int main()
{
int main() {
int someInteger = 256;
short someShort;
long someLong;
@ -16,7 +15,7 @@ int main()
assert(someInteger == 514);
someShort = (short) someInteger;
assert((int) someShort == 514); // (short more than 1 byte)
assert((int) someShort == 514); // (short more than 1 byte)
someLong = someShort * 10000;
assert(someLong == 5140000l);

@ -26,7 +26,7 @@ void container() {
v.push_back(std::move(q));
assert(q == NULL);
for(auto &e: v) {
for (auto &e : v) {
std::cout << *e << std::endl;
}
}

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