# Python code on continued fractions

I'm trying to understand what is happening in the python code below. I take the square root of 2 and divide its decimals by 1. Doing this for 5 times keeps giving the same value but the 6th and 7th time I get different values.

Why does the output change at the 6th time when the input value is the same as in the previous 5 calculations?

``````import math as M
frct = M.sqrt(2)

# 1
frct = 1 / (frct - int(frct))
print frct # 2.41421356237

# 2
frct = 1 / (frct - int(frct))
print frct # 2.41421356237

# 3
frct = 1 / (frct - int(frct))
print frct # 2.41421356237

# 4
frct = 1 / (frct - int(frct))
print frct # 2.41421356237

# 5
frct = 1 / (frct - int(frct))
print frct # 2.41421356237

# 6
frct = 1 / (frct - int(frct))
print frct # 2.41421356238

# 7
frct = 1 / (frct - int(frct))
print frct # 2.41421356235
``````
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Looks like a question for a mathematician/numerical expert. But I guess the decimal places are catching up with you... Do you re-initialize frct to √2 every time? –  BenDundee Jan 30 '13 at 23:16
You're representing an irrational number with a fixed precision string. Each iteration introduces a slight amount of error, and it just happens that it takes 6 iterations before that error accumulates to a point that it is noticeable at the precision you are displaying. –  Silas Ray Jan 30 '13 at 23:17

Short version, Python is rounding the output :)

``````import math as M
frct = M.sqrt(2)

for i in range(7):
frct = 1 / (frct - int(frct))
print 'Attempt %d: %.20f' % (i, frct)
``````

Long version, floating points don't store the real (no pun intended) value, they store an exponent and mantissa. See this wikipedia page for more info: http://en.wikipedia.org/wiki/Floating_point

Basically, a floating point number is stored like this:

``````Significant digits × base^exponent
``````

If you want a more precise version in Python, try the decimal module:

``````import decimal
context = decimal.Context(prec=100)
frct = context.sqrt(decimal.Decimal(2))

print 'Original square root:', frct

for i in range(7):
frct = context.divide(1, frct - int(frct))
print 'Attempt %d: %s' % (i, frct)
``````

Output:

``````Original square root: 1.414213562373095048801688724209698078569671875376948073176679737990732478462107038850387534327641573
Attempt 0: 2.414213562373095048801688724266222622763067167798368627068136427003657772608039155697953022512189319
Attempt 1: 2.414213562373095048801688723683379910288448158038030882339615025168647691299718507620657724911891709
Attempt 2: 2.414213562373095048801688727180436185136162216600057354932063779738350752352175486771948426117071942
Attempt 3: 2.414213562373095048801688706780941248524496874988236407630784335182989956231878308913506955872772859
Attempt 4: 2.414213562373095048801688825680854593346774866097140494471009059332623720827093783193465943198777227
Attempt 5: 2.414213562373095048801688132680869461024772261055702548455940065126184103929661474210576202848416747
Attempt 6: 2.414213562373095048801692171780866910134509900201052604731129303452089934643341550673727041448985316
``````
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Good to note that you aren't even guaranteed to retain the same mantissa, base, or exponent from 1 calculation to the next. –  Silas Ray Jan 30 '13 at 23:25
To avoid loss of precision, the subtraction `frct - int(frct)` should also use the context. (It took me some moments to work out why you were losing precision so quickly at the beginning.) –  Mark Dickinson May 5 '13 at 8:43

`print frct` shows `str(frct)` which shows fewer number of significant digits than necessary to reproduce the number exactly. Replace `print frct` with `print repr(frct)` and you'll see that the numbers are not the same the first five times, they change slowly enough (at first) for their rounded representation to remain the same:

``````2.4142135623730945
2.4142135623730985
2.414213562373075
2.414213562373212
2.4142135623724124
2.414213562377074
2.414213562349904
``````
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