SxsnPC/node_modules/sha.js/test/test.js

'use strict';

var crypto = require('crypto');
var tape = require('tape');
var Buffer = require('safe-buffer').Buffer;

var Sha1 = require('../').sha1;

var nodeSupportsUint16 = false;
try {
	crypto.createHash('sha1').update(new Uint16Array());
	nodeSupportsUint16 = true;
} catch (err) {}

var inputs = [
	['', 'ascii'],
	['abc', 'ascii'],
	['123', 'ascii'],
	['123456789abcdef123456789abcdef123456789abcdef123456789abcdef', 'ascii'],
	['123456789abcdef123456789abcdef123456789abcdef123456789abc', 'ascii'],
	['123456789abcdef123456789abcdef123456789abcdef123456789ab', 'ascii'],
	['0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcde', 'ascii'],
	['0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef', 'ascii'],
	['foobarbaz', 'ascii'],
	[Buffer.from('buffer')],
	nodeSupportsUint16 ? [new Uint16Array([1, 2, 3])] : null
].filter(Boolean);

tape("hash is the same as node's crypto", function (t) {
	inputs.forEach(function (v) {
		var a = new Sha1().update(v[0], v[1]).digest('hex');
		var e = crypto.createHash('sha1').update(v[0], v[1]).digest('hex');
		t.equal(a, e, a + ' == ' + e);
	});

	t.end();
});

tape('call update multiple times', function (t) {
	inputs.forEach(function (v) {
		var hash = new Sha1();
		var sha1hash = crypto.createHash('sha1');

		for (var i = 0; i < v[0].length; i = (i + 1) * 2) {
			var s = v[0].slice(i, (i + 1) * 2);
			hash.update(s, v[1]);
			sha1hash.update(s, v[1]);
		}

		var a = hash.digest('hex');
		var e = sha1hash.digest('hex');
		t.equal(a, e, a + ' == ' + e);
	});
	t.end();
});

tape('call update twice', function (t) {
	var sha1hash = crypto.createHash('sha1');
	var hash = new Sha1();

	sha1hash.update('foo', 'ascii');
	hash.update('foo', 'ascii');

	sha1hash.update('bar', 'ascii');
	hash.update('bar', 'ascii');

	sha1hash.update('baz', 'ascii');
	hash.update('baz', 'ascii');

	var a = hash.digest('hex');
	var e = sha1hash.digest('hex');

	t.equal(a, e);
	t.end();
});

tape('hex encoding', function (t) {
	inputs.forEach(function (v) {
		var hash = new Sha1();
		var sha1hash = crypto.createHash('sha1');

		for (var i = 0; i < v[0].length; i = (i + 1) * 2) {
			var s = v[0].slice(i, (i + 1) * 2);
			hash.update(Buffer.from(s, 'ascii').toString('hex'), 'hex');
			sha1hash.update(Buffer.from(s, 'ascii').toString('hex'), 'hex');
		}
		var a = hash.digest('hex');
		var e = sha1hash.digest('hex');

		t.equal(a, e, a + ' == ' + e);
	});

	t.end();
});

tape('throws on invalid input', function (t) {
	var invalid = [
		{}, // non-arrayish
		{ length: 20 }, // undefined values
		[NaN], // non-numbers
		[[]], // non-numbers
		[1, 1.5], // non-integers
		[1, 256], // out of bounds
		[-1, 0] // out of bounds
	];

	invalid.forEach(function (input) {
		var hash = new Sha1();

		t['throws'](function () {
			hash.update(input);
			hash.digest('hex');
		});
	});

	t.end();
});

tape('call digest for more than MAX_UINT32 bits of data', function (t) {
	var sha1hash = crypto.createHash('sha1');
	var hash = new Sha1();
	var bigData;
	try {
		bigData = Buffer.alloc(0x1ffffffff / 8);
	} catch (err) {
		// node < 3 has a lower buffer size limit than node 3+. node 0.10 requires the `/8`, 0.12 - 2 are fine with `-8`
		bigData = Buffer.alloc(0x3fffffff / 8);
	}

	hash.update(bigData);
	sha1hash.update(bigData);

	var a = hash.digest('hex');
	var e = sha1hash.digest('hex');

	t.equal(a, e, a + ' == ' + e);
	t.end();
});