Take `(d, e, f)`

and subtract off the projection of it onto the normalized normal to the plane (in your case `(a, b, c)`

). So:

```
v = (d, e, f)
- sum((d, e, f) *. (a, b, c)) * (a, b, c) / sum((a, b, c) *. (a, b, c))
```

Here, by `*.`

I mean the *component-wise* product. So this would mean:

```
sum([x * y for x, y in zip([d, e, f], [a, b, c])])
```

or

```
d * a + e * b + f * c
```

if you just want to be clear but pedantic

and similarly for `(a, b, c) *. (a, b, c)`

. Thus, in Python:

```
from math import sqrt
def dot_product(x, y):
return sum([x[i] * y[i] for i in range(len(x))])
def norm(x):
return sqrt(dot_product(x, x))
def normalize(x):
return [x[i] / norm(x) for i in range(len(x))]
def project_onto_plane(x, n):
d = dot_product(x, n) / norm(n)
p = [d * normalize(n)[i] for i in range(len(n))]
return [x[i] - p[i] for i in range(len(x))]
```

Then you can say:

```
p = project_onto_plane([3, 4, 5], [1, 2, 3])
```