/** @fileOverview Arrays of bits, encoded as arrays of Numbers. * * @author Emily Stark * @author Mike Hamburg * @author Dan Boneh */ /** @namespace Arrays of bits, encoded as arrays of Numbers. * * @description *
* These objects are the currency accepted by SJCL's crypto functions. *
* ** Most of our crypto primitives operate on arrays of 4-byte words internally, * but many of them can take arguments that are not a multiple of 4 bytes. * This library encodes arrays of bits (whose size need not be a multiple of 8 * bits) as arrays of 32-bit words. The bits are packed, big-endian, into an * array of words, 32 bits at a time. Since the words are double-precision * floating point numbers, they fit some extra data. We use this (in a private, * possibly-changing manner) to encode the number of bits actually present * in the last word of the array. *
* ** Because bitwise ops clear this out-of-band data, these arrays can be passed * to ciphers like AES which want arrays of words. *
*/ sjcl.bitArray = { /** * Array slices in units of bits. * @param {bitArray} a The array to slice. * @param {Number} bstart The offset to the start of the slice, in bits. * @param {Number} bend The offset to the end of the slice, in bits. If this is undefined, * slice until the end of the array. * @return {bitArray} The requested slice. */ bitSlice: function (a, bstart, bend) { a = sjcl.bitArray._shiftRight(a.slice(bstart/32), 32 - (bstart & 31)).slice(1); return (bend === undefined) ? a : sjcl.bitArray.clamp(a, bend-bstart); }, /** * Extract a number packed into a bit array. * @param {bitArray} a The array to slice. * @param {Number} bstart The offset to the start of the slice, in bits. * @param {Number} length The length of the number to extract. * @return {Number} The requested slice. */ extract: function(a, bstart, blength) { // FIXME: this Math.floor is not necessary at all, but for some reason // seems to suppress a bug in the Chromium JIT. var x, sh = Math.floor((-bstart-blength) & 31); if ((bstart + blength - 1 ^ bstart) & -32) { // it crosses a boundary x = (a[bstart/32|0] << (32 - sh)) ^ (a[bstart/32+1|0] >>> sh); } else { // within a single word x = a[bstart/32|0] >>> sh; } return x & ((1<