Implementation of parts of C's & C++'s numerics libraries in TypeScript/JavaScript.
These functions accept either a bigint or an integer number:
abscountl_oneascreate_countl_one, which is used this way:import { create_countl_one } from "cmath-js"; const countl_one_u16 = create_countl_one({ bits: 16 }); const integer = 0xF0_00; // Prints "1111000000000000 has 4 leading one bits." console.log(`${integer.toString(2).padStart(16, "0")} has ${countl_one_u16(integer)} leading one bits.`);
countl_zeroascreate_countl_zerocountr_oneascreate_countr_onecountr_zeroascreate_countr_zerodivgcd. Example:import { gcd } from "cmath-js"; // Prints "The greatest common divisor of 24 and 32 is 8." console.log(`The greatest common divisor of 24 and 32 is ${gcd(24, 32)}.`);
lcmpopcount
- Constants in the
std::numbersnamespace are available from thenumbers.jssubpath export. Example:import { sqrt3 } from "cmath-js/numbers.js"; console.log(`The square root of 3 is ${sqrt3}.`);
The test coverage is a perfect 100% and enforced by the publishing and pull request verification workflows.
Contributions are welcomed! Feel free to make a pull request. Please add your name to contributors in package.json and run npm run build-and-verify before submitting your PR. By making a pull request you agree to license your contribution under the CC0 license unless otherwise specified.
ESLint is used to enforce code quality and consistent formatting (with the help of Prettier). If ESLint complains when you run npm run build-and-verify, you can run npm run lint-fix to apply automatic fixes and then fix the rest of the errors manually. I recommend configuring your IDE for ESLint and Prettier. If you are using Visual Studio Code, simply installing Microsoft's ESLint extension and the official Prettier extension takes care of that.