Counting the number of digits
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joseph Frank
el 3 de Jul. de 2011
Comentada: Steven Lord
el 14 de Jun. de 2023
Hi,
how can I compute the number of digits A=[12875] how can I get 5 as the number of digits in A?
3 comentarios
Walter Roberson
el 22 de Sept. de 2017
Fails on negative numbers because they are already lower than 1
Steven Lord
el 29 de En. de 2021
How many digits does A have in the code below?
A = Inf;
How many digits does B have?
B = NaN;
How about C?
C = 3+4i;
Respuesta aceptada
bym
el 3 de Jul. de 2011
One way:
numel(num2str(A))
10 comentarios
Walter Roberson
el 9 de Ag. de 2022
S1 = num2str(floor(pi*1e25))
numel(S1)
S2 = char(vpa(floor(pi*1e25)))
numel(S2)
S3 = char(vpa(floor(sym(pi)*1e25)))
numel(S3)
Actual answer should be 26
Más respuestas (8)
Oleg Komarov
el 3 de Jul. de 2011
To count integer part
ceil(log10(abs(A)))
Edit
floor(log10(abs(A)+1)) + 1
4 comentarios
Walter Roberson
el 15 de Jul. de 2011
Fails on 0, Jan.
Over integral values:
ceil(log10(max(1,abs(A)+1)))
Over real numbers,
ceil(log10(max(1,abs(A)*(1+eps))))
I think.
DGM
el 28 de En. de 2023
Editada: DGM
el 28 de En. de 2023
It's also necessary to handle cases where A is integer-class.
For sake of clarifying the limitations and assumptions in each suggested method:
A = [-2456 -1.45 0 0.05 0.16 1.5 10 100 35465].';
y1 = ceil(log10(abs(A))); % fails on 0, subunity fractions, powers of 10
y2 = floor(log10(abs(A)+1)) + 1; % 0 has 1 digit? yes/no?
y3 = ceil(log10(max(1,abs(A)+1))); % 0 has 0 digits, but 0.05 and 0.16 both have 1 digit?
y4 = ceil(log10(max(1,abs(A)*(1+eps)))); % fails on powers of 10
y5 = numdigits(A); % where does this one fail?
table(A,y1,y2,y3,y4,y5)
function ndigits = numdigits(x)
% NDIGITS = NUMDIGITS(X)
% A simple convenience tool to count the number of digits in
% the integer part of a number. For complex inputs, the result
% is the number of digits in the integer part of its magnitude.
%
% X is a numeric scalar or array of any class or sign.
%
% Note that the integer 0 is considered to have zero digits.
% Consequently, for numbers on the interval -1<X<1, NDIGITS is 0.
ndigits = ceil(log10(abs(double(fix(x)))+1));
end
Turner
el 16 de Ag. de 2013
Editada: Turner
el 19 de Ag. de 2013
Will do the trick for all nonzero integers:
fix(abs(log10(abs(A))))+1
For a 10,000 iteration benchmark with some above answers:
Jaymin= 1.423717 seconds; Stephanie= 0.476135 seconds; Mine= 0.000878 seconds
If you don't expect 0s to appear, this is the fastest and most accurate method. Only works for decimals that satisfy -1<A<1.
1 comentario
DGM
el 28 de En. de 2023
Editada: DGM
el 28 de En. de 2023
This doesn't actually provide meaningful results on the specified interval.
x = (-0.15:0.025:0.15).';
y1 = floor(log10(abs(x)+1))+1; % works for all integers (assumes 0 is 1 digit)
y2 = fix(abs(log10(abs(x))))+1; % works for nonzero integers
table(x,y1,y2)
Consider the case of abs(x) = 0.125. In what interpretation does this value have one digit?
Consider the case of abs(x) = 0.10. The naive interpretation of this value might suggest that it has either 1 or 2 digits (depending if you consider the leading integer 0). In reality, 0.1 is not exactly represented in floating point, so instead it's actually 0.999999999999999916 ... etc, or some similar approximation depending on how it was calculated. In base-2, 0.1 has as many digits as your floating-point approximation allows. If 0.125 has 1 digit, then no consistent interpretation would suggest that 0.10 has 2 digits.
As the utility for the fractional part of the number can now be ignored, the only meaningful difference between the two methods presented is the initial offset of 1 to avoid the singularity in log(x). At that point, the distinction between floor() and fix() can be ignored, since all its inputs will be positive.
Bear in mind that for practical use, we should be considering double(x) or something equivalent, otherwise both methods will fail if x is integer-class.
Jaymin
el 13 de Dic. de 2012
Editada: Walter Roberson
el 30 de Mayo de 2020
Long, but it gets the job done.
numel(num2str(A))-numel(strfind(num2str(A),'-'))-numel(strfind(num2str(A),'.'))
1 comentario
Mayur Lad
el 8 de Oct. de 2020
Editada: Walter Roberson
el 8 de Oct. de 2020
x=input('Enter number: ');
disp(x)
sum= 0;
while x > 0
t = mod(x,10);
sum= sum+1;
x = (x-t)/10;
end
fprintf('no of digit is:\t %d',sum)
3 comentarios
manindra
el 27 de En. de 2023
If number is 0 or negative, the control doesn't even enter into the loop. Thats just a dumb question.
Daniel Dalskov
el 29 de En. de 2021
I am using a simplified version of the below to determine whether I should try to represent a number as x*pi, x*sqrt(2), x*exp(1) or a fraction. In my case I only needed to check if there are more than are 14 digits, so no for-loop needed.
It basically finds the difference between the first and last non-zero number. Sign, decimal point and exponent are not included in the count.
a = [0,12e-17,1,10,21003, round(pi,3)*1e6, round(pi,5), round(pi,10), round(pi,10)*1e-3, round(pi*1e-5,10), pi, pi*1e307, pi*1e-314];
a = [a, -a];
for i=1:length(a)
b=abs(a(i)); % sign is not important for the number of digits, but feel free to add 0>sign(a(i)) to sd
if b < 3e-323 % depending on how precise you want to be
sd = 1; % could be changed to zero depending on your usecase
else
msd=floor(log10(b)); % most significant digit
lsd=-inf;
for dp=msd:-1:-323 % again depending on how precise you want to be, numbers really close to zero gets a little ify
if mod(b,10.^dp)==0
lsd=dp-1; % least significant digit
break
end
end
sd = msd-lsd; % number of digits
end
fprintf('%d significant digits\tin\t%s\n', sd, num2str(a(i), 16))
end
0 comentarios
Aziz ur Rehman
el 14 de Jun. de 2023
The approach that i followed is in which i used a recursive function to compute the sum of digits of the integer provided such that the sum of A=[12345] is 15.
function x=digit_sum(input)
if input==0
x=0;
else
digit = rem(input,10);
input=(input-digit)/10;
x=digit+digit_sum(input);
end
end
You can see that for getting the 10th of the integer, i just divided the number by 10, and the remainder gave us the last digit, which in turn was added using a recursive function.
1 comentario
Steven Lord
el 14 de Jun. de 2023
Is this what you expected? I added one additional input to your function so it shows you the intermediary steps.
digit_sum(pi, true)
You can see the effect of the additional input on a problem where this function works:
digit_sum(12345, true)
The following behavior is what I expected for a non-finite input, since you are recursively calling digit_sum with Inf as the input each time. The same holds if you call digit_sum with NaN as input. I'm not showing the intermediate results, as I suspect the displaying of those steps would cause this code to time out in MATLAB Answers.
digit_sum(Inf, false)
Your code would also fail if input was a complex number.
function x=digit_sum(input, displaySteps)
if input==0
x=0;
else
digit = rem(input,10);
input=(input-digit)/10;
if displaySteps
fprintf("Digit is %g, input is %g\n", digit, input);
end
x=digit+digit_sum(input, displaySteps);
end
end
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