I prefer an approach which uses already implemented algorithms. While a lot of other solution use recursive divisions by 10
, I think it's better to make use of 10-base logarithms, which have O(1)
complexity, so that the whole solution complexity is O(1)
.
Let us split the problem into two parts.
First part will handle the case when the number * 10^n
is between min
and max
for at least one n
. This would let us check for example if number = 12
and min,max = 11225,13355
, that x = 12000 = 12*10^3
is between min
and max
. If this test checks out, it means the result is True
.
Second part will handle the cases when number
is beginning of either min
or max
. For example if number = 12
and min,max = 12325,14555
, the first test will fail, as 12000
is not between min
and max
(as well as will fail all other numbers 12*10^n
for any n
). But second test will find that 12
is the beginning of 12325
and return True
.
First
Let's check, if the first x = number*10^n
, which is equal or larger than min
, is smaller or equal than max
(so min <= x <= max, where x is number*10^n for any integer n
). If it's bigger than max
, than all other x
es will be bigger, as we took the smallest.
log(number*10^n) > log(min)
log(number) + log(10^n) > log(min)
log(number) + n > log(min)
n > log(min) - log(number)
n > log(min/number)
To get the number to compare with, we just calculate the first satisfactory n
:
n = ceil(log(min/number))
And calculate then number x
:
x = number*10^n
Second
We should check if our number is a literal beginning of either boundary.
We just calculate x
beginning with the same digits as number
and padded with 0
s on the end, having the same length as min
:
magnitude = 10**(floor(log10(min)) - floor(log10(number)))
x = num*magnitude
And then check if min
's and x
difference (in magnitude scale) is less than 1
and bigger or equal to 0
:
0 <= (min-x)/magnitude < 1
So, if number
is 121
and min
is 132125
, then magnitude
is 1000
, x = number*magnitude
would be 121000
. min - x
gives 132125-121000 = 11125
, which should be smaller than 1000
(otherwise min
beginning would be bigger than 121
), so we compare it with magnitude
by dividing by it's value and comparing to 1
. And it's OK if min
is 121000
, but not OK if min
is 122000
, that is why 0 <=
and < 1
.
The same algorithm is for max
.
Pseudo code
Incorporating it all in pseudo code gives this algorithm:
def check(num,min,max):
# num*10^n is between min and max
#-------------------------------
x = num*10**(ceil(log10(min/num)))
if x>=min and x<=max:
return True
# if num is prefix substring of min
#-------------------------------
magnitude = 10**(floor(log10(min)) - floor(log10(num)))
if 0 <= (min-num*magnitude)/magnitude < 1:
return True
# if num is prefix substring of max
#-------------------------------
magnitude = 10**(floor(log10(max)) - floor(log10(num)))
if 0 <= (max-num*magnitude)/magnitude < 1:
return True
return False
This code could be optimized by avoiding repeated calculations of log10(num)
. Also, in final solution I would go from float to integer scope (magnitude = 10**int(floor(log10(max)) - floor(log10(num)))
) and then perform all comparisons without division, i.e. 0 <= (max-num*magnitude)/magnitude < 1
-> 0 <= max-num*magnitude < magnitude
. This would alleviate possibilities of round-off errors.
Also, it may be possible to replace magnitude = 10**(floor(log10(min)) - floor(log10(num)))
with magnitude = 10**(floor(log10(min/num)))
, where log10
is calculated only once. But I can't prove that it will always bring correct results, nor can I disprove it. If anybody could prove it, I would be very grateful.
Tests (in Python): http://ideone.com/N5R2j (you could edit input to add another tests).
<, >, <=, >=
?C
orC++
(the answer will be different, depending upon the required language.)2 in range(11, 13)
returnTrue
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