gcc/testsuite/gdc.test/runnable/template2.d - gcc - Git at Google

 // original post to the D newsgroup:
 //    https://www.digitalmars.com/d/archives/10510.html#N10554
 // Test to manipulate 3D vectors, in D!
 // by Sean L Palmer (seanpalmer@directvinternet.com)
 // This code is released without any warranty.  Use at your own risk.
 import core.stdc.stdio;
 import core.math : sqrt;

 template VecTemplate(tfloat, int dim:3)
 {
  struct Vector
  {
   tfloat[dim] d;

   version(none)
   {
    // sets the vector to the value of the given array
    void set(tfloat[dim] r) { d[] = r[]; }
    // comparison (a == b, a != b)
    bool opEquals(Vector b) { for (int i=0; i<dim; ++i) if (d[i] != b.d[i]) return
 false; return true; }
    // negate (-a)
    Vector opUnary(string op : "-")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = -d[i]; return
 r;  }
    // complement (~a)
    Vector opUnary(string op : "~")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[(i+1)%dim];
 d[0] = -d[0]; return r;  }
    // add (a + b)
    Vector opBinary(string op : "+")(Vector b) { Vector r; r.d[] = d[] + b.d[]; return r;  }
    // addto (a += b)
    Vector opOpAssign(string op : "+")(Vector b) { d[] += b.d[]; return r;  }
    // subtract (a - b)
    Vector opBinary(string op : "-")(Vector b) { Vector r; r.d[] = d[] - b.d[]; return r;  }
    // multiply by scalar (a * 2.0)
    Vector opBinary(string op : "*")(tfloat b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i]
 * b; return r;  }
    // divide by scalar (a / b)
    Vector opBinary(string op : "/")(tfloat b) { return *this * (1/b);  }
    // dot product (a * b)
    tfloat opBinary(string op : "*")(Vector b) { tfloat r=0; for (int i=0; i<dim; ++i) r += d[i];
 return r;  }
    // outer product (a ^ b)
    //Vector opXor(Vector b) { Vector r; for (int i=0; i<dim; ++i) r += d[i]; return r;  }
   }

   void set(tfloat[dim] r) { for (int i=0; i<dim; ++i) d[i] = r[i]; }
   // comparison (a == b, a != b)
   const bool opEquals(ref const Vector b) { for (int i=0; i<dim; ++i) if (d[i] != b.d[i]) return
 false; return true; }
   // negate (-a)
   Vector opUnary(string op : "-")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = -d[i]; return
 r;  }
   // complement (~a)
   Vector opUnary(string op : "~")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[(i+1)%dim];
 d[0] = -d[0]; return r;  }
   // add (a + b)
   Vector opBinary(string op : "+")(Vector b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i] +
 b.d[i]; return r;  }
   // addto (a += b)
   Vector opOpAssign(string op : "+")(Vector b) { for (int i=0; i<dim; ++i) d[i] += b.d[i]; return
 this; }
   // subtract (a - b)
   Vector opBinary(string op : "-")(Vector b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i] -
 b.d[i]; return r;  }
   // multiply by scalar (a * 2.0)
   Vector opBinary(string op : "*")(tfloat b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i] *
 b; return r;  }
   // divide by scalar (a / b)
   Vector opBinary(string op : "/")(tfloat b) { return this * (1/b);  }
   // dot product (a * b)
   tfloat opBinary(string op : "*")(Vector b) { tfloat r=0; for (int i=0; i<dim; ++i) r += d[i];
 return r;  }
   // outer product (a ^ b)
   //Vector opXor(Vector b) { Vector r; for (int i=0; i<dim; ++i) r += d[i]; return r;  }

   void print() { for (int i=0; i<dim; ++i) printf("%f ", d[i]);
 printf("\n"); }
  }

  tfloat abs(Vector v)
  {
   return sqrt(sqr(v));
  }

  tfloat sqr(Vector v)
  {
   return v * v;
  }
 }

 alias VecTemplate!(float, 3) VcT;

 float[3] up = [ 0, 1, 0 ];

 int main(char[][] args)
 {
  printf("running\n");
  with (VcT)         // try this, I dare ya!!  crashes DMD 0.51
  {
   VcT.Vector a,b,c;
   c.set(up);
   b.set(up);
   a = b + c;
   a.print();
   printf("b * c = %f\n",b * c);
   printf("abs(a) = %f\n",VcT.abs(a));
   printf("sqr(a) = %f\n",VcT.sqr(a));
  }
  printf("closing\n");
  return 0;
 }
	// original post to the D newsgroup:
	// https://www.digitalmars.com/d/archives/10510.html#N10554
	// Test to manipulate 3D vectors, in D!
	// by Sean L Palmer (seanpalmer@directvinternet.com)
	// This code is released without any warranty. Use at your own risk.
	import core.stdc.stdio;
	import core.math : sqrt;

	template VecTemplate(tfloat, int dim:3)
	{
	struct Vector
	{
	tfloat[dim] d;

	version(none)
	{
	// sets the vector to the value of the given array
	void set(tfloat[dim] r) { d[] = r[]; }
	// comparison (a == b, a != b)
	bool opEquals(Vector b) { for (int i=0; i<dim; ++i) if (d[i] != b.d[i]) return
	false; return true; }
	// negate (-a)
	Vector opUnary(string op : "-")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = -d[i]; return
	r; }
	// complement (~a)
	Vector opUnary(string op : "~")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[(i+1)%dim];
	d[0] = -d[0]; return r; }
	// add (a + b)
	Vector opBinary(string op : "+")(Vector b) { Vector r; r.d[] = d[] + b.d[]; return r; }
	// addto (a += b)
	Vector opOpAssign(string op : "+")(Vector b) { d[] += b.d[]; return r; }
	// subtract (a - b)
	Vector opBinary(string op : "-")(Vector b) { Vector r; r.d[] = d[] - b.d[]; return r; }
	// multiply by scalar (a * 2.0)
	Vector opBinary(string op : "*")(tfloat b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i]
	* b; return r; }
	// divide by scalar (a / b)
	Vector opBinary(string op : "/")(tfloat b) { return this (1/b); }
	// dot product (a * b)
	tfloat opBinary(string op : "*")(Vector b) { tfloat r=0; for (int i=0; i<dim; ++i) r += d[i];
	return r; }
	// outer product (a ^ b)
	//Vector opXor(Vector b) { Vector r; for (int i=0; i<dim; ++i) r += d[i]; return r; }
	}

	void set(tfloat[dim] r) { for (int i=0; i<dim; ++i) d[i] = r[i]; }
	// comparison (a == b, a != b)
	const bool opEquals(ref const Vector b) { for (int i=0; i<dim; ++i) if (d[i] != b.d[i]) return
	false; return true; }
	// negate (-a)
	Vector opUnary(string op : "-")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = -d[i]; return
	r; }
	// complement (~a)
	Vector opUnary(string op : "~")() { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[(i+1)%dim];
	d[0] = -d[0]; return r; }
	// add (a + b)
	Vector opBinary(string op : "+")(Vector b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i] +
	b.d[i]; return r; }
	// addto (a += b)
	Vector opOpAssign(string op : "+")(Vector b) { for (int i=0; i<dim; ++i) d[i] += b.d[i]; return
	this; }
	// subtract (a - b)
	Vector opBinary(string op : "-")(Vector b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i] -
	b.d[i]; return r; }
	// multiply by scalar (a * 2.0)
	Vector opBinary(string op : "")(tfloat b) { Vector r; for (int i=0; i<dim; ++i) r.d[i] = d[i]
	b; return r; }
	// divide by scalar (a / b)
	Vector opBinary(string op : "/")(tfloat b) { return this * (1/b); }
	// dot product (a * b)
	tfloat opBinary(string op : "*")(Vector b) { tfloat r=0; for (int i=0; i<dim; ++i) r += d[i];
	return r; }
	// outer product (a ^ b)
	//Vector opXor(Vector b) { Vector r; for (int i=0; i<dim; ++i) r += d[i]; return r; }

	void print() { for (int i=0; i<dim; ++i) printf("%f ", d[i]);
	printf("\n"); }
	}

	tfloat abs(Vector v)
	{
	return sqrt(sqr(v));
	}

	tfloat sqr(Vector v)
	{
	return v * v;
	}
	}

	alias VecTemplate!(float, 3) VcT;

	float[3] up = [ 0, 1, 0 ];

	int main(char[][] args)
	{
	printf("running\n");
	with (VcT) // try this, I dare ya!! crashes DMD 0.51
	{
	VcT.Vector a,b,c;
	c.set(up);
	b.set(up);
	a = b + c;
	a.print();
	printf("b * c = %f\n",b * c);
	printf("abs(a) = %f\n",VcT.abs(a));
	printf("sqr(a) = %f\n",VcT.sqr(a));
	}
	printf("closing\n");
	return 0;
	}