This online utility removes certain digits from an integer and returns a modified integer without these digits in the output. You can specify which digits you want to delete and apply the deletion algorithm to any number of integers (one per line). By default, the algorithm deletes all occurrences of the specified digits but you can also use an option to delete just the first occurrence of each digit. Created by math nerds from team Browserling.
This online utility removes certain digits from an integer and returns a modified integer without these digits in the output. You can specify which digits you want to delete and apply the deletion algorithm to any number of integers (one per line). By default, the algorithm deletes all occurrences of the specified digits but you can also use an option to delete just the first occurrence of each digit. Created by math nerds from team Browserling.
With this online application, you can delete the digits that you don't like from an integer. For example, you can make an integer contain only the odd digits 13579 by deleting the even digits 02468, or if you want to make sure that all the digits in an integer are greater than 4, you can remove the digits 01234, which will leave only the digits 56789 in the output. The unnecessary digits that you want to get rid of can be entered in the "Digits to Remove" option. This option accepts a list of digits in any order that should be entered without the space separators. The program then runs through all the input integers (each value should be on a new line) and outputs modified integers that contain only the digits that aren't listed in the "Digits to Remove" option. If you need to remove only the first occurrence of the listed digits, then use the "Delete Only the First Digit" option. In addition to this option, there are two side selection radio boxes. One of them removes the first digit from the left side and the other from the right side. Integerabulous!
With this online application, you can delete the digits that you don't like from an integer. For example, you can make an integer contain only the odd digits 13579 by deleting the even digits 02468, or if you want to make sure that all the digits in an integer are greater than 4, you can remove the digits 01234, which will leave only the digits 56789 in the output. The unnecessary digits that you want to get rid of can be entered in the "Digits to Remove" option. This option accepts a list of digits in any order that should be entered without the space separators. The program then runs through all the input integers (each value should be on a new line) and outputs modified integers that contain only the digits that aren't listed in the "Digits to Remove" option. If you need to remove only the first occurrence of the listed digits, then use the "Delete Only the First Digit" option. In addition to this option, there are two side selection radio boxes. One of them removes the first digit from the left side and the other from the right side. Integerabulous!
In this example, we reveal a secret integer that's composed of the digits 1 to 5 but that has been mixed with digits 6 to 9 and 0. It would be tricky to manually find the hidden integer but by quickly removing the digits 67890, we find that the secret integer is 12345.
This example loads three integers that have been left-padded with a leading zero. The padding doesn't change the integers' value so we'd like to delete it. To remove the zero that's in front, we enter 0 in the removal list and set the option to delete only the first zero. This way, all other zeros in the integer are preserved.
In this example, the binary communication channel between two devices was noisy and the received binary data had many errors introduced during the transmission. To clean up the errors, we entered the non-binary digits 23456789 in the cleanup list, which let us extract only the binary integers 0 and 1, and the data was recovered.
You can pass input to this tool via ?input query argument and it will automatically compute output. Here's how to type it in your browser's address bar. Click to try!
Create a drawing that visualizes von Neumann hierarchy of sets.
Create a sudoku puzzle.
Create a list of neat-looking integers (called magic integers).
Generate a list of tuples of integers with n elements.
Quickly convert integers to base one.
Quickly convert base one to integers.
Quickly convert integers to base two.
Quickly convert base two to integers.
Quickly convert integers to base eight.
Quickly convert base eight to integers.
Quickly convert integers to base sixteen.
Quickly convert base sixteen to integers.
Quickly encode integers to base-64.
Quickly decode base-64 to integers.
Quickly convert integers to a custom base.
Quickly encode integers to HTML encoding.
Quickly decode HTML entities to integers.
Quickly encode integers to URL (percent) encoding.
Quickly decode URL-encoded integers.
Quickly convert a signed integer to an unsigned integer.
Quickly convert an unsigned integer to a signed integer.
Generate a list of random integers.
Check if the given integers are palindromes.
Create a matrix whose entries are all integers.
Create a vector with integer coefficients.
Quickly calculate the average value of integers.
Quickly calculate the average value of integer digits.
Quickly randomly select a digit from an integer.
Find which of the given integers is the biggest or smallest.
Limit integer values to a range.
Limit integer digit values to a range.
Create multiple copies of the input integers.
Create multiple copies of digits of input integers.
Rotate the digits of an integer to the left or right.
Move the digits of an integer to the left or right.
Quickly find the difference of a bunch of integers.
Quickly apply the bitwise AND operation to integers.
Quickly apply the bitwise OR operation to integers.
Quickly apply the bitwise XOR operation to integers.
Quickly apply the bitwise NOT operation to integers.
Quickly apply the bitwise NAND operation to integers.
Quickly apply the bitwise NOR operation to integers.
Quickly apply the bitwise NXOR operation to integers.
Quickly divide two or more integers.
Quickly divide the digits of an integer.
Add -st, -nd, -rd, -th suffixes to integers to make them ordinals.
Remove -st, -nd, -rd, -th suffixes from ordinals to make them ints.
Find integers that match a filter (greater, less, equal).
Add padding to integers on the left side.
Add padding to integers on the right side.
Position all integers so that they align on the right.
Position all integers so that they align in the middle.
Turn all integers into positive integers.
Turn all integers into negative integers.
Rewrite an integer in fractional form.
Extract the numerator and denominator from a fraction.
Search for all occurrences of an integer and replace it.
Create a regex that matches the given integers.
Create integers that match the given regular expression.
Create relatively tiny integers.
Create relatively huge integers.
Create a sequence of oscillating integers, such as 123212321.
Create multiple integer sequences at once.
Slightly change an integer so it has an error.
Slightly change integer digits so there are errors.
Apply fuzzing to integers and add perturbations.
Apply fuzzing to integer digits and add digit perturbations.
Add highlighting to certain integers.
Add highlighting to certain integer digits.
Add color to integers based on a condition.
Add color to individual digits in the given integers.
Quickly assign colors to integers and draw them as pixels.
Quickly assign integer values to pixel colors and print them.
Make the digits of an integer go in a spiral shape.
Make the digits of an integer go in a circle.
Make the digits of an integer go in a diamond shape.
Fill a box with certain width and height with digits.
Use ASCII art to convert integers to 2-dimensional drawings.
Use ASCII art to convert integers to 3-dimensional drawings.
Decompose an integer into ones, tens, hundreds, etc.
Generate an ordered list of increasing integers.
Generate an ordered list of decreasing integers.
Quickly find various information about the given integers.
Find hidden patterns of numbers in integers.
Find the Shannon entropy of an integer.
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We're Browserling — a friendly and fun cross-browser testing company powered by alien technology. At Browserling our mission is to make people's lives easier, so we created this collection of integer tools. Our tools have the simplest user interface that doesn't require advanced computer skills and they are used by millions of people every month. Our integer tools are actually powered by our programming tools that we created over the last couple of years. Check them out!