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I am trying to add one vector to another vector in my C++ program and addition is coming out inexact.

This is the vector class (using cmath library):

class Vec{
    float dir, mag;
    public:
        Vec(float dir, float mag){
            this->dir = dir;
            this->mag = mag;
        }
        float getX(){
            return cos(dir)*mag;
        }
        Vec operator + (Vec v2){
            float triangleX = cos(dir)*mag+cos(v2.dir)*v2.mag;
            float triangleY = sin(dir)*mag+sin(v2.dir)*v2.mag;
            return Vec(atan2(triangleY, triangleX), sqrt(pow(triangleX,2)+pow(triangleY,2)));
    }
};

And this is the main function:

int main(){
    Vec v1(0, 3); // 0º
    Vec v2(3.14159265/2, 3); // 90º
    Vec v3(3.14159265, 3); // 180º
    std::cout.precision(15);
    std::cout<<"v1: "<<v1.getX()<<std::endl;
    std::cout<<"v1+v2: "<<(v1+v2).getX()<<std::endl;
    std::cout<<"v1+v3: "<<(v1+v3).getX()<<std::endl;
    return 0;
}

And this is the output:

v1: 3
v1+v2: 2.99999976158142
v1+v3: 1.98007097372034e-014

As you can see, the first output v1 is fine.

The second output is the addition of 0 degrees and 90 degrees (an angle that was not supposed to affect the x component), his x component is close to 3, but not exactly 3.

The third output is the addition of 2 opposite vectors with the same magnitude, it was supposed to be 0, but it is not what shows here.

What is causing these strange additions and how do I make them exact?

marked as duplicate by mhlester, WhozCraig c++ Jun 12 '14 at 3:08

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

  • 4
    I recommend to use coordinates (x,y) for an easy life. – user2249683 May 4 '14 at 13:07
  • using double is recommended, not only because it's more accurate but most modern architectures are optimized for double, not float – phuclv May 4 '14 at 13:14
  • @LưuVĩnhPhúc Do you know of a platform where using double is faster than float? Afaik all platforms support both, most are still twice as fast with float. And the memory footprint of a float is also only half that of double so that memory bound computations will perform faster with float on all platforms. Still, I'm entirely with you that double should be used as a default. – cmaster May 4 '14 at 13:26
  • @cmaster I heard many people say that they see double is faster than float. Actually I haven't done a benchmark before, but most answers on this sites state that doubles on modern platforms are at least just as fast as floats. stackoverflow.com/questions/1074474/… stackoverflow.com/questions/4584637/… – phuclv May 7 '14 at 4:15
  • @LưuVĩnhPhúc Reading the answers on the link, I can't find anybody claiming that doubles are faster than float. Rightly so, because that would be wrong. On all platforms I know, the opposite is true. But I don't know all platforms, so I can't rule out the possibility that there is this wild CPU that crunches doubles faster than floats. So, what is probably true is that doubles might be faster on some (esoteric) platforms. But that was precisely my question: Do you know of a specific platform where doubles are faster? – cmaster May 8 '14 at 5:15
1

The basic problem you're having is one of limited precision of float and the value of pi that you're using. Moving to a double will help, and since you're already including <cmath> you should use the value there which is M_PI and is accurate to at least the precision of double. With that said, you're still not going to get exact answers with this approach. (The answer from alain does a good job of explaining why.)

There are some improvements that could be made. One is a neat trick using a C++11 feature which is "user-defined string literals." If you add this definition to your code:

constexpr long double operator"" _deg(long double deg) {
    return deg*M_PI/180;
}

You can now append _deg to any long double literal and it will automatically be converted to radians at compile time. Your main function would then look like this:

int main(){
    Vec v1(0.0_deg, 3); 
    Vec v2(90.0_deg, 3); 
    Vec v3(180.0_deg, 3); 
    // ...
}

The next thing you could do would be to store the x and y coordinates and only do the trigonometric manipulations when needed. That version of Vec might look like this:

class Vec{
    double x,y;
    public:
        Vec(double dir, double mag, bool cartesian=false) : x(dir), y(mag) {
            if (!cartesian) {
                x = mag*cos(dir);
                y = mag*sin(dir);
            }
        }
        double getX() const {
            return x;
        }
        Vec operator + (const Vec &v2){
            return Vec(x+v2.x, y+v2.y, true);
        }
}

Note that I've created a bool value for the constructor which tells whether the input is to be a magnitude and direction or an x and y value. Also note that the getX() is declared const because it doesn't alter the Vec and that the argument to operator+ is also a const reference for the same reason. When I make those changes on my machine (a 64-bit machine), I get the following output:

v1: 3
v1+v2: 3
v1+v3: 0
4

v1 + v3 is almost 0.0, the code is working correctly.

Why is it not exactly 0.0?

because some numbers can not be represented exactly as doubles. see: C/C++: 1.00000 <= 1.0f = False for some explanations.

Also: Pi is an irrational number, and can not be represented exactly in any base that is a natural number.

Thus any calculation involving Pi is never completely precise.

And: sin, cos, sqrt are usually all implemented as algorithms that don't return completely exact results, for example as approximative numeric algorithms.

  • I've intended to comment about that just right before you edit the post. Also, the use of literals like that instead of PI constant is not recommended – phuclv May 4 '14 at 13:17
  • Correct me if I'm wrong, but I thought that sin & co. are only approximative when you turn on the fast-math compiler flag? – cmaster May 4 '14 at 13:28
  • @cmaster I don't know in which libraries/with which flags they are approximative, but one of the faster implementations is a table with linear interpolation. (That's actually not approximative, but not completely precise too) – alain May 4 '14 at 13:36
  • @cmaster I edited my answer to be a bit more accurate. Thanks for the input. – alain May 4 '14 at 13:45
  • @alain: To be pedantic, one could exactly represent pi as 1 base pi. – Edward May 4 '14 at 13:53

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