Hello I have some difficulties with the ceil function in c++ :

I've got a regular grid of points, and I need to perform an interpolation over it to compute the z-values of a set of points.

In order to do that, I need, for each computed point, to get the nearest points on the grid. I do it like this :

```
y1 = dy*floor(p.y/dy);
y2 = dy*ceil(p.y/dy);
```

where dy is the space beetween two points of the grid. (y1, p.y and dy are double) If I display the results using

```
cout << static_cast<double>(p.y/dy) << ": " << y1 << ", " << y2 << endl;
```

I've got these strange results :

```
0: 0, 0
1: 0.1, 0.1
2: 0.2, 0.2
3: 0.3, 0.4
```

The three first results are OK but the last one is wrong and make an assertion fail.

I would like to know where did this strange error came and how to avoid it. Thanks.

I apologize for my English

**EDIT**

I call the function with dy = 0.1, but during the execution, it take the folowing value dy = 0.10000000000000001. p.y is initialized like that :

```
const uint N = round((x2 - x1) / dx2);
const uint M = round((y2 - y1) / dy2);
double p = persistence;
double n = number_of_octaves;
// generation of the points where the perlin noise is generated
std::vector<Vertex3d> ret;
std::vector<Vertex3d> dummy;
for (uint i=0;i<=N;++i)
{
for (uint j=0;j<=M;++j)
{
ret.push_back({.x = i*dx2, .y=j*dy2, .z=0});
dummy.push_back({.x = i*dx2, .y=j*dy2, .z=0});
}
}
```

where x1 = 0 and x2 = 1 (according gdb)

`p.y`

is 0.30000000000000004 and`dy`

is 0.10000000000000001. Obviously`p.y`

is more than 3 times`dy`

, so`p.y/dy`

is greater than three, so`ceil(p.y/dy)`

is 4, so`dy*ceil(p.y/dy)`

is (about) .4. You say “the last one is wrong”, but clearly all the math has been done correctly, and .4 is the nearest grid point above`p.y`

. So your problem description is inadequate; it does not explain why you do not want .4 for this grid point. – Eric Postpischil Mar 8 '13 at 11:20`dy`

is .1 rather than 0.10000000000000001. No, this is not possible as long as you use binary floating point. The value .1 is not exactly representable in binary floating point. One way to reduce such problems is to calculate in multiples of values that are exactly representable, such as multiples of 1 or of .125 or .0078125 other powers of two. That is, you might scale your points to match the binary values. However, since you have not shown the other arithmetic you are doing, there could be other problems. – Eric Postpischil Mar 8 '13 at 11:22