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README.md
kind-of
Get the native type of a value.
Install
Install with npm:
$ npm install --save kind-of
Install
Install with bower
$ bower install kind-of --save
Usage
es5, browser and es6 ready
var kindOf = require('kind-of');
kindOf(undefined);
//=> 'undefined'
kindOf(null);
//=> 'null'
kindOf(true);
//=> 'boolean'
kindOf(false);
//=> 'boolean'
kindOf(new Boolean(true));
//=> 'boolean'
kindOf(new Buffer(''));
//=> 'buffer'
kindOf(42);
//=> 'number'
kindOf(new Number(42));
//=> 'number'
kindOf('str');
//=> 'string'
kindOf(new String('str'));
//=> 'string'
kindOf(arguments);
//=> 'arguments'
kindOf({});
//=> 'object'
kindOf(Object.create(null));
//=> 'object'
kindOf(new Test());
//=> 'object'
kindOf(new Date());
//=> 'date'
kindOf([]);
//=> 'array'
kindOf([1, 2, 3]);
//=> 'array'
kindOf(new Array());
//=> 'array'
kindOf(/foo/);
//=> 'regexp'
kindOf(new RegExp('foo'));
//=> 'regexp'
kindOf(function () {});
//=> 'function'
kindOf(function * () {});
//=> 'function'
kindOf(new Function());
//=> 'function'
kindOf(new Map());
//=> 'map'
kindOf(new WeakMap());
//=> 'weakmap'
kindOf(new Set());
//=> 'set'
kindOf(new WeakSet());
//=> 'weakset'
kindOf(Symbol('str'));
//=> 'symbol'
kindOf(new Int8Array());
//=> 'int8array'
kindOf(new Uint8Array());
//=> 'uint8array'
kindOf(new Uint8ClampedArray());
//=> 'uint8clampedarray'
kindOf(new Int16Array());
//=> 'int16array'
kindOf(new Uint16Array());
//=> 'uint16array'
kindOf(new Int32Array());
//=> 'int32array'
kindOf(new Uint32Array());
//=> 'uint32array'
kindOf(new Float32Array());
//=> 'float32array'
kindOf(new Float64Array());
//=> 'float64array'
Benchmarks
Benchmarked against typeof and type-of.
Note that performaces is slower for es6 features Map
, WeakMap
, Set
and WeakSet
.
#1: array
current x 23,329,397 ops/sec ±0.82% (94 runs sampled)
lib-type-of x 4,170,273 ops/sec ±0.55% (94 runs sampled)
lib-typeof x 9,686,935 ops/sec ±0.59% (98 runs sampled)
#2: boolean
current x 27,197,115 ops/sec ±0.85% (94 runs sampled)
lib-type-of x 3,145,791 ops/sec ±0.73% (97 runs sampled)
lib-typeof x 9,199,562 ops/sec ±0.44% (99 runs sampled)
#3: date
current x 20,190,117 ops/sec ±0.86% (92 runs sampled)
lib-type-of x 5,166,970 ops/sec ±0.74% (94 runs sampled)
lib-typeof x 9,610,821 ops/sec ±0.50% (96 runs sampled)
#4: function
current x 23,855,460 ops/sec ±0.60% (97 runs sampled)
lib-type-of x 5,667,740 ops/sec ±0.54% (100 runs sampled)
lib-typeof x 10,010,644 ops/sec ±0.44% (100 runs sampled)
#5: null
current x 27,061,047 ops/sec ±0.97% (96 runs sampled)
lib-type-of x 13,965,573 ops/sec ±0.62% (97 runs sampled)
lib-typeof x 8,460,194 ops/sec ±0.61% (97 runs sampled)
#6: number
current x 25,075,682 ops/sec ±0.53% (99 runs sampled)
lib-type-of x 2,266,405 ops/sec ±0.41% (98 runs sampled)
lib-typeof x 9,821,481 ops/sec ±0.45% (99 runs sampled)
#7: object
current x 3,348,980 ops/sec ±0.49% (99 runs sampled)
lib-type-of x 3,245,138 ops/sec ±0.60% (94 runs sampled)
lib-typeof x 9,262,952 ops/sec ±0.59% (99 runs sampled)
#8: regex
current x 21,284,827 ops/sec ±0.72% (96 runs sampled)
lib-type-of x 4,689,241 ops/sec ±0.43% (100 runs sampled)
lib-typeof x 8,957,593 ops/sec ±0.62% (98 runs sampled)
#9: string
current x 25,379,234 ops/sec ±0.58% (96 runs sampled)
lib-type-of x 3,635,148 ops/sec ±0.76% (93 runs sampled)
lib-typeof x 9,494,134 ops/sec ±0.49% (98 runs sampled)
#10: undef
current x 27,459,221 ops/sec ±1.01% (93 runs sampled)
lib-type-of x 14,360,433 ops/sec ±0.52% (99 runs sampled)
lib-typeof x 23,202,868 ops/sec ±0.59% (94 runs sampled)
Optimizations
In 7 out of 8 cases, this library is 2x-10x faster than other top libraries included in the benchmarks. There are a few things that lead to this performance advantage, none of them hard and fast rules, but all of them simple and repeatable in almost any code library:
- Optimize around the fastest and most common use cases first. Of course, this will change from project-to-project, but I took some time to understand how and why
typeof
checks were being used in my own libraries and other libraries I use a lot. - Optimize around bottlenecks - In other words, the order in which conditionals are implemented is significant, because each check is only as fast as the failing checks that came before it. Here, the biggest bottleneck by far is checking for plain objects (an object that was created by the
Object
constructor). I opted to make this check happen by process of elimination rather than brute force up front (e.g. by using something likeval.constructor.name
), so that every other type check would not be penalized it. - Don't do uneccessary processing - why do
.slice(8, -1).toLowerCase();
just to get the wordregex
? It's much faster to doif (type === '[object RegExp]') return 'regex'
About
Related projects
- is-glob: Returns
true
if the given string looks like a glob pattern or an extglob pattern… more | homepage - is-number: Returns true if the value is a number. comprehensive tests. | homepage
- is-primitive: Returns
true
if the value is a primitive. | homepage
Contributing
Pull requests and stars are always welcome. For bugs and feature requests, please create an issue.
Contributors
Commits | Contributor |
---|---|
59 | jonschlinkert |
2 | miguelmota |
1 | dtothefp |
1 | ksheedlo |
1 | pdehaan |
1 | laggingreflex |
Building docs
(This project's readme.md is generated by verb, please don't edit the readme directly. Any changes to the readme must be made in the .verb.md readme template.)
To generate the readme, run the following command:
$ npm install -g verbose/verb#dev verb-generate-readme && verb
Running tests
Running and reviewing unit tests is a great way to get familiarized with a library and its API. You can install dependencies and run tests with the following command:
$ npm install && npm test
Author
Jon Schlinkert
License
Copyright © 2017, Jon Schlinkert. Released under the MIT License.
This file was generated by verb-generate-readme, v0.6.0, on May 16, 2017.