/**
 * @module ol/math
 */
/**
 * Takes a number and clamps it to within the provided bounds.
 * @param {number} value The input number.
 * @param {number} min The minimum value to return.
 * @param {number} max The maximum value to return.
 * @return {number} The input number if it is within bounds, or the nearest
 *     number within the bounds.
 */
export function clamp(value: number, min: number, max: number): number;
/**
 * Returns the square of the closest distance between the point (x, y) and the
 * line segment (x1, y1) to (x2, y2).
 * @param {number} x X.
 * @param {number} y Y.
 * @param {number} x1 X1.
 * @param {number} y1 Y1.
 * @param {number} x2 X2.
 * @param {number} y2 Y2.
 * @return {number} Squared distance.
 */
export function squaredSegmentDistance(x: number, y: number, x1: number, y1: number, x2: number, y2: number): number;
/**
 * Returns the square of the distance between the points (x1, y1) and (x2, y2).
 * @param {number} x1 X1.
 * @param {number} y1 Y1.
 * @param {number} x2 X2.
 * @param {number} y2 Y2.
 * @return {number} Squared distance.
 */
export function squaredDistance(x1: number, y1: number, x2: number, y2: number): number;
/**
 * Solves system of linear equations using Gaussian elimination method.
 *
 * @param {Array<Array<number>>} mat Augmented matrix (n x n + 1 column)
 *                                     in row-major order.
 * @return {Array<number>} The resulting vector.
 */
export function solveLinearSystem(mat: Array<Array<number>>): Array<number>;
/**
 * Converts radians to to degrees.
 *
 * @param {number} angleInRadians Angle in radians.
 * @return {number} Angle in degrees.
 */
export function toDegrees(angleInRadians: number): number;
/**
 * Converts degrees to radians.
 *
 * @param {number} angleInDegrees Angle in degrees.
 * @return {number} Angle in radians.
 */
export function toRadians(angleInDegrees: number): number;
/**
 * Returns the modulo of a / b, depending on the sign of b.
 *
 * @param {number} a Dividend.
 * @param {number} b Divisor.
 * @return {number} Modulo.
 */
export function modulo(a: number, b: number): number;
/**
 * Calculates the linearly interpolated value of x between a and b.
 *
 * @param {number} a Number
 * @param {number} b Number
 * @param {number} x Value to be interpolated.
 * @return {number} Interpolated value.
 */
export function lerp(a: number, b: number, x: number): number;
/**
 * Returns a number with a limited number of decimal digits.
 * @param {number} n The input number.
 * @param {number} decimals The maximum number of decimal digits.
 * @return {number} The input number with a limited number of decimal digits.
 */
export function toFixed(n: number, decimals: number): number;
/**
 * Rounds a number to the nearest integer value considering only the given number
 * of decimal digits (with rounding on the final digit).
 * @param {number} n The input number.
 * @param {number} decimals The maximum number of decimal digits.
 * @return {number} The nearest integer.
 */
export function round(n: number, decimals: number): number;
/**
 * Rounds a number to the next smaller integer considering only the given number
 * of decimal digits (with rounding on the final digit).
 * @param {number} n The input number.
 * @param {number} decimals The maximum number of decimal digits.
 * @return {number} The next smaller integer.
 */
export function floor(n: number, decimals: number): number;
/**
 * Rounds a number to the next bigger integer considering only the given number
 * of decimal digits (with rounding on the final digit).
 * @param {number} n The input number.
 * @param {number} decimals The maximum number of decimal digits.
 * @return {number} The next bigger integer.
 */
export function ceil(n: number, decimals: number): number;
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