rasha-fork/lib/asn1.js
2018-11-22 23:41:39 -07:00

211 lines
6 KiB
JavaScript

'use strict';
//
// A dumbed-down, minimal ASN.1 parser / packer combo
//
// Note: generally I like to write congruent code
// (i.e. output can be used as input and vice-versa)
// However, this seemed to be more readable and easier
// to use written as-is, asymmetrically.
// (I also generally prefer to export objects rather
// functions but, yet again, asthetics one in this case)
var Enc = require('./encoding.js');
//
// Packer
//
// Almost every ASN.1 type that's important for CSR
// can be represented generically with only a few rules.
var ASN1 = module.exports = function ASN1(/*type, hexstrings...*/) {
var args = Array.prototype.slice.call(arguments);
var typ = args.shift();
var str = args.join('').replace(/\s+/g, '').toLowerCase();
var len = (str.length/2);
var lenlen = 0;
var hex = typ;
// We can't have an odd number of hex chars
if (len !== Math.round(len)) {
throw new Error("invalid hex");
}
// The first byte of any ASN.1 sequence is the type (Sequence, Integer, etc)
// The second byte is either the size of the value, or the size of its size
// 1. If the second byte is < 0x80 (128) it is considered the size
// 2. If it is > 0x80 then it describes the number of bytes of the size
// ex: 0x82 means the next 2 bytes describe the size of the value
// 3. The special case of exactly 0x80 is "indefinite" length (to end-of-file)
if (len > 127) {
lenlen += 1;
while (len > 255) {
lenlen += 1;
len = len >> 8;
}
}
if (lenlen) { hex += Enc.numToHex(0x80 + lenlen); }
return hex + Enc.numToHex(str.length/2) + str;
};
// The Integer type has some special rules
ASN1.UInt = function UINT() {
var str = Array.prototype.slice.call(arguments).join('');
var first = parseInt(str.slice(0, 2), 16);
// If the first byte is 0x80 or greater, the number is considered negative
// Therefore we add a '00' prefix if the 0x80 bit is set
if (0x80 & first) { str = '00' + str; }
return ASN1('02', str);
};
// The Bit String type also has a special rule
ASN1.BitStr = function BITSTR() {
var str = Array.prototype.slice.call(arguments).join('');
// '00' is a mask of how many bits of the next byte to ignore
return ASN1('03', '00' + str);
};
//
// Parser
//
ASN1.ELOOP = "uASN1.js Error: iterated over 15+ elements (probably a malformed file)";
ASN1.EDEEP = "uASN1.js Error: element nested 10+ layers deep (probably a malformed file)";
// Container Types are Sequence 0x30, Octect String 0x04, Array? (0xA0, 0xA1)
// Value Types are Integer 0x02, Bit String 0x03, Null 0x05, Object ID 0x06,
// Sometimes Bit String is used as a container (RSA Pub Spki)
ASN1.VTYPES = [ 0x02, 0x03, 0x05, 0x06 ];
ASN1.parse = function parseAsn1(buf, depth) {
if (depth >= 10) { throw new Error(ASN1.EDEEP); }
var index = 2; // we know, at minimum, data starts after type (0) and lengthSize (1)
var asn1 = { type: buf[0], lengthSize: 0, length: buf[1] };
var child;
var iters = 0;
var adjust = 0;
var adjustedLen;
// Determine how many bytes the length uses, and what it is
if (0x80 & asn1.length) {
asn1.lengthSize = 0x7f & asn1.length;
// I think that buf->hex->int solves the problem of Endianness... not sure
asn1.length = parseInt(Enc.bufToHex(buf.slice(index, index + asn1.lengthSize)), 16);
index += asn1.lengthSize;
}
// High-order bit Integers have a leading 0x00 to signify that they are positive.
// Bit Streams use the first byte to signify padding, which x.509 doesn't use.
if (0x00 === buf[index] && (0x02 === asn1.type || 0x03 === asn1.type)) {
// However, 0x00 on its own is a valid number
if (asn1.length > 1) {
index += 1;
adjust = -1;
}
}
adjustedLen = asn1.length + adjust;
// this is a primitive value type
if (-1 !== ASN1.VTYPES.indexOf(asn1.type)) {
asn1.value = buf.slice(index, index + adjustedLen);
return asn1;
}
asn1.children = [];
while (iters < 15 && index <= asn1.length) {
iters += 1;
child = ASN1.parse(buf.slice(index, index + adjustedLen), (depth || 0) + 1);
index += (2 + child.lengthSize + child.length);
asn1.children.push(child);
}
if (iters >= 15) { throw new Error(ASN1.ELOOP); }
return asn1;
};
/*
ASN1._stringify = function(asn1) {
//console.log(JSON.stringify(asn1, null, 2));
//console.log(asn1);
var ws = '';
function write(asn1) {
console.log(ws, 'ch', Buffer.from([asn1.type]).toString('hex'), asn1.length);
if (!asn1.children) {
return;
}
asn1.children.forEach(function (a) {
ws += '\t';
write(a);
ws = ws.slice(1);
});
}
write(asn1);
};
*/
ASN1.tpl = function (asn1) {
//console.log(JSON.stringify(asn1, null, 2));
//console.log(asn1);
var ws = '\t';
var i = 0;
var vars = [];
var str = ws;
function write(asn1, k) {
str += "\n" + ws;
var val;
if ('number' !== typeof k) {
// ignore
} else {
str += ', ';
}
if (0x02 === asn1.type) {
str += "ASN1.UInt(";
} else if (0x03 === asn1.type) {
str += "ASN1.BitStr(";
} else {
str += "ASN1('" + Enc.numToHex(asn1.type) + "'";
}
if (!asn1.children) {
if (0x05 !== asn1.type) {
if (0x06 !== asn1.type) {
val = Buffer.from(asn1.value || '');
vars.push("// 0x" + Enc.numToHex(val.byteLength) + " (" + val.byteLength + " bytes)\nopts.tpl" + i + " = '"
+ Enc.bufToHex(val) + "';");
if (0x02 !== asn1.type && 0x03 !== asn1.type) {
str += ", ";
}
str += "Enc.bufToHex(opts.tpl" + i + ")";
} else {
str += ", '" + Enc.bufToHex(asn1.value) + "'";
}
}
str += ")";
return ;
}
asn1.children.forEach(function (a, j) {
i += 1;
ws += '\t';
write(a, j);
ws = ws.slice(1);
});
str += "\n" + ws + ")";
}
write(asn1);
console.log('var opts = {};');
console.log(vars.join('\n') + '\n');
console.log();
console.log('function buildSchema(opts) {');
console.log('\treturn Enc.hexToBuf(' + str.slice(3) + ');');
console.log('}');
};
module.exports = ASN1;