The cosine of the angle gives you the steps to take in the x-direction, and the sine of the angle gives you the steps to take in the y-direction. It's better to take this approach rather than finding the gradient of the line because for a vertical line the gradient is infinite.

You can't find *all* points on a computer, because there are an infinite number of them, so you have to decide on a step-size and the number of steps. This is illustrated in the Python program below which chooses a step-size of 1 and 100 steps.

```
import math, matplotlib.pyplot as plt
def pts(x0,y0,theta):
t = range(101) # t=0,1,2,3,4,5...,100
x = [x0 + tt*math.cos(theta) for tt in t]
y = [y0 + tt*math.sin(theta) for tt in t]
return x,y
def degrees2radians(degrees):
return degrees * math.pi/180
degrees = 45
x,y=pts(-100,-100, degrees2radians(degrees))
plt.plot(x, y, label='{} degrees'.format(degrees))
degrees = 90
x,y=pts(100,100, degrees2radians(degrees))
plt.plot(x, y, label='{} degrees'.format(degrees))
plt.xlim(-100,300)
plt.ylim(-100,300)
plt.legend()
plt.show()
```

and outputs

The R program below takes a similar approach.

```
drawline=function(x0,y0,theta) {
t=0:100 # t = 0,1,2,3,4,5,...,100
# x formed by stepping by cos theta each time
x=x0 + t*cos(theta)
# y formed by stepping by sin theta each time
y=y0 + t*sin(theta)
# plot
rng=c(min(x,y),max(x,y)) # range
plot(y~x,xlim=rng,ylim=rng,type="l")
}
```

Here, `theta`

is in radians. So `drawline(-100,-100,pi/4)`

corresponds to 45 degrees and gives the first plot, whereas `drawline(100,100,pi/2)`

corresponds to 90 degrees and gives the vertical line shown on the left of the second plot.

`drawLine(x0,y0,x0+r *cos(angle),y0 + r* sin(angle))`

. – Salix alba Apr 2 at 13:49