In your example, rounding error is introduced when calculating `dot(u,v)/(norm(u)*norm(v))`

. For your test values, the calculation is effectively `2/(sqrt(2)*sqrt(2))`

. The computed value for sqrt(2) is rounded to a value slightly larger than the infinite precision value.

```
>>> math.sqrt(2)
1.4142135623730951
>>> math.sqrt(2)*math.sqrt(2)
2.0000000000000004
>>> 2/(math.sqrt(2)*math.sqrt(2))
0.9999999999999998
>>> math.acos(2/(math.sqrt(2)*math.sqrt(2)))
2.1073424255447017e-08
```

The `decimal`

module solution by @F.J calculates `2/(sqrt(2)*sqrt(2))`

to higher precision. When this value is converted to a float (by arccos), it is rounded to 1.0.

```
>>> import decimal
>>> decimal.getcontext().sqrt(2)
Decimal('1.414213562373095048801688724')
>>> decimal.getcontext().sqrt(2)**2
Decimal('1.999999999999999999999999999')
>>> 2/decimal.getcontext().sqrt(2)**2
Decimal('1.000000000000000000000000001')
>>> float(2/decimal.getcontext().sqrt(2)**2)
1.0
```

Calculating `2/(sqrt(2)*sqrt(2))`

using `decimal`

and different precisions highlights another issue.

```
>>> for i in range(10,30):
... decimal.getcontext().prec=i
... print i,2/decimal.getcontext().sqrt(2)**2
...
10 1.000000001
11 0.99999999995
12 1.00000000001
13 1
14 1
15 0.999999999999995
16 1
17 1.0000000000000001
18 1
19 0.9999999999999999995
20 1
21 1
22 0.9999999999999999999995
23 1
24 1
25 0.9999999999999999999999995
26 1.0000000000000000000000001
27 1.00000000000000000000000001
28 1.000000000000000000000000001
29 1
```

The result may be either exactly 1, less than 1, or greater than 1. This can be confusing if you could take `arccos`

without rounding to a float first. For the values greater than 1, `arccos`

is not defined so the result is a `nan`

. If seen this type of rounding error break latitude/longitude calculations when an intermediate value exceeds 1. Just increasing the precision for all calculations, say from float64 to float128, won't fix the problem. It may move the problem to a different set of values, but the rounding errors will still occur.

**Update 1**

There are a couple of other options. You can rewrite your formula as:

```
def AcuteAngle3(line1,line2):
''':: line(x1,y1,x2,y2)'''
u = (line1[2]-line1[0], line1[3]-line1[1])
v = (line2[2]-line2[0], line2[3]-line2[1])
return arccos(sqrt(abs(dot(u,v)**2/(dot(u,u)*dot(v,v)))))
```

`AcuteAngle3`

avoids your original problem but it is possible that `dot(u,u)*dot(v,v)`

is rounded to a value that is slightly smaller in magnitude than the real value and you could try to take the arccos of a value greater than 1. (But just using ROUND_UP or ROUND_DOWN for the entire expression won't work; I tried using different rounding modes in my `decimal`

example and some rounding "errors" remained.)

The following function checks for those exceptional occurrences:

```
def AcuteAngle4(line1,line2):
''':: line(x1,y1,x2,y2)'''
u = (line1[2]-line1[0], line1[3]-line1[1])
v = (line2[2]-line2[0], line2[3]-line2[1])
temp = sqrt(abs(dot(u,v)**2/(dot(u,u)*dot(v,v))))
if temp > 1:
return 0.0
else:
return arccos(temp)
```

Computing intermediate values to a higher precision and then rounding down, or selectively rounding towards or away from 0 when calculating each component of your expression, are other possibilities.

`numpy`

performance, with the minimum changes in the available code. – Developer Jun 8 '13 at 6:37