Similarly to @MBo's answer, let's assume that the center is `(0,0)`

and that your initial two points are:

```
P0 = (x0, y0) and P1 = (x1, y1)
```

A point on the line `P0P1`

has the form:

```
(x, y) = c(x1 - x0, y1 - y0) + (x0, y0)
```

for some constant `c`

.

Let `(u, v)`

be the normal to the line `P0P1`

:

```
(u, v) = (y1 - y0, x1 - x0) / sqrt((x1 - x0)^2 + (y1 - y0)^2)
```

A point on any of the lines parallel to `P0P1`

has the form:

```
(x, y) = c(x1 - x0, y1 - y0) + (x0, y0) +/- (u, v)* n {eq 1}
```

where `n`

is the perpendicular distance between lines and `c`

is a constant.

What remains here is to find the values of `c`

such that `(x,y)`

is on the circle. But these can be calculated by solving the following two quadratic equations:

```
(c(x1 - x0) + x0 +/- u*n)^2 + (c(y1 - y0) + y0 +/- v*n)^2 = r^2
```

where `r`

is the radius. Note that these equations can be written as:

```
c^2(x1 - x0)^2 + 2c(x1 - x0)*(x0 +/- u*n) + (x0 +/- u*n)^2
+ c^2(y1 - y0)^2 + 2c(y1 - y0)*(y0 +/- v*n) + (y0 +/- v*n)^2 = r^2
```

or

```
A*c^2 + B*c + D = 0
```

where

```
A = (x1 - x0)^2 + (y1 - y0)^2
B = 2(x1 - x0)*(x0 +/- u*n) + 2(y1 - y0)*(y0 +/- v*n)
D = (x0 +/- u*n)^2 + (y0 +/- v*n)^2 - r^2
```

which are actually two quadratic equations one for each selection of the +/- signs. The 4 solutions of these two equations will give you the four values of `c`

from which you will get the four points using {eq 1}

**UPDATE**

Here are the two quadratic equations (I've reused the letters `A`

, `B`

and `C`

but they are different in each case):

```
A*c^2 + B*c + D = 0 {eq 2}
```

where

```
A = (x1 - x0)^2 + (y1 - y0)^2
B = 2(x1 - x0)*(x0 + u*n) + 2(y1 - y0)*(y0 + v*n)
D = (x0 + u*n)^2 + (y0 + v*n)^2 - r^2
```

```
A*c^2 + B*c + D = 0 {eq 3}
```

where

```
A = (x1 - x0)^2 + (y1 - y0)^2
B = 2(x1 - x0)*(x0 - u*n) + 2(y1 - y0)*(y0 - v*n)
D = (x0 - u*n)^2 + (y0 - v*n)^2 - r^2
```