time-to-botec/squiggle/node_modules/@stdlib/math/base/special/frexp/README.md

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# frexp

> Split a [double-precision floating-point number][ieee754] into a normalized fraction and an integer power of two.

<section class="usage">

## Usage

```javascript
var frexp = require( '@stdlib/math/base/special/frexp' );
```

#### frexp( \[out,] x )

Splits a [double-precision floating-point number][ieee754] into a normalized fraction and an integer power of two.

```javascript
var out = frexp( 4.0 );
// returns [ 0.5, 3 ]
```

By default, the function returns the normalized fraction and the exponent as a two-element `array`. The normalized fraction and exponent satisfy the relation `x = frac * 2^exp`.

```javascript
var pow = require( '@stdlib/math/base/special/pow' );

var x = 4.0;
var out = frexp( x );
// returns [ 0.5, 3 ]

var frac = out[ 0 ];
var exp = out[ 1 ];

var bool = ( x === frac * pow(2.0, exp) );
// returns true
```

To avoid unnecessary memory allocation, the function supports providing an output (destination) object.

```javascript
var Float64Array = require( '@stdlib/array/float64' );

var out = new Float64Array( 2 );

var y = frexp( out, 4.0 );
// returns <Float64Array>[ 0.5, 3 ]

var bool = ( y === out );
// returns true
```

If provided positive or negative zero, `NaN`, or positive or negative `infinity`, the function returns a two-element `array` containing the input value and an exponent equal to `0`.

```javascript
var out = frexp( 0.0 );
// returns [ 0.0, 0 ]

out = frexp( -0.0 );
// returns [ -0.0, 0 ]

out = frexp( NaN );
// returns [ NaN, 0 ]

out = frexp( Infinity );
// returns [ Infinity, 0 ]

out = frexp( -Infinity );
// returns [ -Infinity, 0 ]
```

For all other numeric input values, the [absolute value][@stdlib/math/base/special/abs] of the normalized fraction resides on the interval `[0.5,1)`.

</section>

<!-- /.usage -->

<section class="notes">

## Notes

-   Care should be taken when reconstituting a [double-precision floating-point number][ieee754] from a normalized fraction and an exponent. For example,

    ```javascript
    var pow = require( '@stdlib/math/base/special/pow' );

    var x = 8.988939926493918e+307; // x ~ 2^1023

    var out = frexp( x );
    // returns [ 0.5000263811533315, 1024 ]

    // Naive reconstitution:
    var y = out[ 0 ] * pow( 2.0, out[ 1 ] );
    // returns Infinity

    // Account for 2^1024 evaluating as infinity by recognizing 2^1024 = 2^1 * 2^1023:
    y = out[ 0 ] * pow( 2.0, out[1]-1023 ) * pow( 2.0, 1023 );
    // returns 8.988939926493918e+307
    ```

</section>

<!-- /.notes -->

<section class="examples">

## Examples

<!-- eslint no-undef: "error" -->

```javascript
var randu = require( '@stdlib/random/base/randu' );
var round = require( '@stdlib/math/base/special/round' );
var pow = require( '@stdlib/math/base/special/pow' );
var BIAS = require( '@stdlib/constants/float64/exponent-bias' );
var frexp = require( '@stdlib/math/base/special/frexp' );

var sign;
var frac;
var exp;
var x;
var f;
var v;
var i;

// Generate random numbers and break each into a normalized fraction and an integer power of two...
for ( i = 0; i < 100; i++ ) {
    if ( randu() < 0.5 ) {
        sign = -1.0;
    } else {
        sign = 1.0;
    }
    frac = randu() * 10.0;
    exp = round( randu()*616.0 ) - 308;
    x = sign * frac * pow( 10.0, exp );
    f = frexp( x );
    if ( f[ 1 ] > BIAS ) {
        v = f[ 0 ] * pow( 2.0, f[1]-BIAS ) * pow( 2.0, BIAS );
    } else {
        v = f[ 0 ] * pow( 2.0, f[ 1 ] );
    }
    console.log( '%d = %d * 2^%d = %d', x, f[ 0 ], f[ 1 ], v );
}
```

</section>

<!-- /.examples -->

<section class="links">

[ieee754]: https://en.wikipedia.org/wiki/IEEE_754-1985

[@stdlib/math/base/special/abs]: https://www.npmjs.com/package/@stdlib/math/tree/main/base/special/abs

</section>

<!-- /.links -->
feat: add the node modules Necessary in order to clearly see the squiggle hotwiring. 2022-12-03 12:44:49 +00:00			`<!--`

			`@license Apache-2.0`

			`Copyright (c) 2018 The Stdlib Authors.`

			`Licensed under the Apache License, Version 2.0 (the "License");`
			`you may not use this file except in compliance with the License.`
			`You may obtain a copy of the License at`

			`http://www.apache.org/licenses/LICENSE-2.0`

			`Unless required by applicable law or agreed to in writing, software`
			`distributed under the License is distributed on an "AS IS" BASIS,`
			`WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`See the License for the specific language governing permissions and`
			`limitations under the License.`

			`-->`

			`# frexp`

			`> Split a [double-precision floating-point number][ieee754] into a normalized fraction and an integer power of two.`

			`<section class="usage">`

			`## Usage`

			```javascript
			`var frexp = require( '@stdlib/math/base/special/frexp' );`
			```

			`#### frexp( \[out,] x )`

			`Splits a [double-precision floating-point number][ieee754] into a normalized fraction and an integer power of two.`

			```javascript
			`var out = frexp( 4.0 );`
			`// returns [ 0.5, 3 ]`
			```

			By default, the function returns the normalized fraction and the exponent as a two-element `array`. The normalized fraction and exponent satisfy the relation `x = frac * 2^exp`.

			```javascript
			`var pow = require( '@stdlib/math/base/special/pow' );`

			`var x = 4.0;`
			`var out = frexp( x );`
			`// returns [ 0.5, 3 ]`

			`var frac = out[ 0 ];`
			`var exp = out[ 1 ];`

			`var bool = ( x === frac * pow(2.0, exp) );`
			`// returns true`
			```

			`To avoid unnecessary memory allocation, the function supports providing an output (destination) object.`

			```javascript
			`var Float64Array = require( '@stdlib/array/float64' );`

			`var out = new Float64Array( 2 );`

			`var y = frexp( out, 4.0 );`
			`// returns <Float64Array>[ 0.5, 3 ]`

			`var bool = ( y === out );`
			`// returns true`
			```

			If provided positive or negative zero, `NaN`, or positive or negative `infinity`, the function returns a two-element `array` containing the input value and an exponent equal to `0`.

			```javascript
			`var out = frexp( 0.0 );`
			`// returns [ 0.0, 0 ]`

			`out = frexp( -0.0 );`
			`// returns [ -0.0, 0 ]`

			`out = frexp( NaN );`
			`// returns [ NaN, 0 ]`

			`out = frexp( Infinity );`
			`// returns [ Infinity, 0 ]`

			`out = frexp( -Infinity );`
			`// returns [ -Infinity, 0 ]`
			```

			For all other numeric input values, the [absolute value][@stdlib/math/base/special/abs] of the normalized fraction resides on the interval `[0.5,1)`.

			`</section>`

			`<!-- /.usage -->`

			`<section class="notes">`

			`## Notes`

			`- Care should be taken when reconstituting a [double-precision floating-point number][ieee754] from a normalized fraction and an exponent. For example,`

			```javascript
			`var pow = require( '@stdlib/math/base/special/pow' );`

			`var x = 8.988939926493918e+307; // x ~ 2^1023`

			`var out = frexp( x );`
			`// returns [ 0.5000263811533315, 1024 ]`

			`// Naive reconstitution:`
			`var y = out[ 0 ] * pow( 2.0, out[ 1 ] );`
			`// returns Infinity`

			`// Account for 2^1024 evaluating as infinity by recognizing 2^1024 = 2^1 * 2^1023:`
			`y = out[ 0 ] * pow( 2.0, out[1]-1023 ) * pow( 2.0, 1023 );`
			`// returns 8.988939926493918e+307`
			```

			`</section>`

			`<!-- /.notes -->`

			`<section class="examples">`

			`## Examples`

			`<!-- eslint no-undef: "error" -->`

			```javascript
			`var randu = require( '@stdlib/random/base/randu' );`
			`var round = require( '@stdlib/math/base/special/round' );`
			`var pow = require( '@stdlib/math/base/special/pow' );`
			`var BIAS = require( '@stdlib/constants/float64/exponent-bias' );`
			`var frexp = require( '@stdlib/math/base/special/frexp' );`

			`var sign;`
			`var frac;`
			`var exp;`
			`var x;`
			`var f;`
			`var v;`
			`var i;`

			`// Generate random numbers and break each into a normalized fraction and an integer power of two...`
			`for ( i = 0; i < 100; i++ ) {`
			`if ( randu() < 0.5 ) {`
			`sign = -1.0;`
			`} else {`
			`sign = 1.0;`
			`}`
			`frac = randu() * 10.0;`
			`exp = round( randu()*616.0 ) - 308;`
			`x = sign * frac * pow( 10.0, exp );`
			`f = frexp( x );`
			`if ( f[ 1 ] > BIAS ) {`
			`v = f[ 0 ] * pow( 2.0, f[1]-BIAS ) * pow( 2.0, BIAS );`
			`} else {`
			`v = f[ 0 ] * pow( 2.0, f[ 1 ] );`
			`}`
			`console.log( '%d = %d * 2^%d = %d', x, f[ 0 ], f[ 1 ], v );`
			`}`
			```

			`</section>`

			`<!-- /.examples -->`

			`<section class="links">`

			`[ieee754]: https://en.wikipedia.org/wiki/IEEE_754-1985`

			`[@stdlib/math/base/special/abs]: https://www.npmjs.com/package/@stdlib/math/tree/main/base/special/abs`

			`</section>`

			`<!-- /.links -->`