This online utility parses English text that spells integer values and converts this text back to multi-digit integers that are then printed in the output. It supports arbitrary big integers and as an extra feature, it also understands money and currency names, which are converted to short Unicode banknote and coin signs in the output. Created by math nerds from team Browserling.
This online utility parses English text that spells integer values and converts this text back to multi-digit integers that are then printed in the output. It supports arbitrary big integers and as an extra feature, it also understands money and currency names, which are converted to short Unicode banknote and coin signs in the output. Created by math nerds from team Browserling.
With this browser-based application, you can convert words that spell out integers in natural language to actual integer values. It accepts English words, such as "one", "ten", "twenty-three" in the input and returns the corresponding integers "1", "10", "23" in the output. The spelled integers must be entered one per line. You can force plus or minus signs in front of integers if you prepend the words "plus" and "minus" before the line. For example, "minus six" will produce "-6", "plus six" will produce "+6", but simply "six" will produce "6". The app works with really big magnitudes, such as "octillion" (1027), "trigintillion" (1093), and "googol" (10100). In addition to this, you can also enter any amount of money written in words. All banknote and coin names will be converted to the matching currency symbols. For example, American money "one hundred dollars" will be printed as integer money "$100" and Japanese money "three thousand yen" will be rewritten to "¥3000". Integerabulous!
With this browser-based application, you can convert words that spell out integers in natural language to actual integer values. It accepts English words, such as "one", "ten", "twenty-three" in the input and returns the corresponding integers "1", "10", "23" in the output. The spelled integers must be entered one per line. You can force plus or minus signs in front of integers if you prepend the words "plus" and "minus" before the line. For example, "minus six" will produce "-6", "plus six" will produce "+6", but simply "six" will produce "6". The app works with really big magnitudes, such as "octillion" (1027), "trigintillion" (1093), and "googol" (10100). In addition to this, you can also enter any amount of money written in words. All banknote and coin names will be converted to the matching currency symbols. For example, American money "one hundred dollars" will be printed as integer money "$100" and Japanese money "three thousand yen" will be rewritten to "¥3000". Integerabulous!
This example loads several lines with spelled words of integers in the input and turns all this text into real integer values that are written with digits in the output. It uses a natural language processing algorithm to parse and understand the integer amounts of the written words and to produce the correct integer values. Note that if the word "plus" is used in the spelled word, then the "+" sign is placed before the integer and if the word "minus" is used, then the negative sign "-" is placed before the integer.
In this example, we have entered a very special and long integer with the order of magnitude approximately equal to 3·108. Do you know what this special integer is? Take a pause now to think. This integer is the well-known physical constant "c", which is equal to 299,792,458 meters per second and it's the speed of light in a vacuum.
In this example, we demonstrate a secret feature of this webapp. The input contains various currencies written in natural language and they get converted back to integer currencies. The currency names, "dollars", "euros", "yens", "pounds", and others gets turned into international currency glyphs "$", "€", "¥", "£".
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!