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# rsa-compat.js
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JavaScript RSA utils that work on Windows, Mac, and Linux with or without C compiler
In order to provide a module that "just works" everywhere, we mix and match methods
from `node.js` core, `ursa` , `forge` , and others.
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This is useful for **certbot** and **letsencrypt** .
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(in the future we'd like to provide the same API to the browser)
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Install
=======
```
# node.js
npm install --save rsa-compat
# CLI
npm install --global rsa-compat
```
Usage
=====
CLI
---
You can generate keypairs on Windows, Mac, and Linux using rsa-keygen-js:
```bash
# generates a new keypair in the current directory
rsa-keypiar-js
```
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Examples
--------
Generate an RSA Keypair:
```javascript
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var RSA = require('rsa-compat').RSA;
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var bitlen = 1024;
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var exp = 65537;
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var options = { public: true, pem: true, internal: true };
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RSA.generateKeypair(bitlen, exp, options, function (err, keypair) {
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console.log(keypair);
});
```
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Here's what the object might look like:
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`console.log(keypair)` :
```javascript
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{ publicKeyPem: '-----BEGIN RSA PUBLIC KEY-----\n/*base64 pem-encoded string*/'
, privateKeyPem: '-----BEGIN RSA PRIVATE KEY-----\n/*base64 pem-encoded string*/'
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, privateKeyJwk: {
kty: "RSA"
, n: '/*base64 modulus n = pq*/'
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, e: '/*base64 exponent (usually 65537)*/'
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, d: '/*base64 private exponent (d = e^− 1 (mod ϕ(n))/'
, p: '/*base64 first prime*/'
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, q: '/*base64 second prime*/'
, dp: '/*base64 first exponent for Chinese remainder theorem (dP = d (mod p− 1))*/'
, dq: '/*base64 Second exponent, used for CRT (dQ = d (mod q− 1))/'
, qi: '/*base64 Coefficient, used for CRT (qinv = q^− 1 (mod p))*/'
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}
, publicKeyJwk: {
kty: "RSA"
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, n: '/*base64 modulus n = pq*/'
, e: '/*base64 exponent (usually 65537)*/'
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}
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, _ursa: '/*undefined or intermediate ursa object*/'
, _ursaPublic: '/*undefined or intermediate ursa object*/'
, _forge: '/*undefined or intermediate forge object*/'
, _forgePublic: '/*undefined or intermediate forge object*/'
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}
```
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NOTE: this object is JSON safe as _ursa and _forge will be ignored
See http://crypto.stackexchange.com/questions/6593/what-data-is-saved-in-rsa-private-key to learn a little more about the meaning of the specific fields in the JWK.
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API
---
* `RSA.generateKeypair(bitlen, exp, options, cb)`
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* `RSA.import(keypair, options)`
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* `RSA.exportPrivatePem(keypair)`
* `RSA.exportPublicPem(keypair)`
* `RSA.exportPrivateJwk(keypair)`
* `RSA.exportPublicJwk(keypair)`
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* `RSA.signJws(keypair, payload, nonce)`
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* `RSA.generateCsrPem(keypair, names)`
* `RSA.generateCsrDerWeb64(keypair, names)`
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`keypair` can be any object with any of these keys `publicKeyPem, privateKeyPem, publicKeyJwk, privateKeyJwk`
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### RSA.generateKeypair(bitlen, exp, options, cb)
Create a private keypair and export it as PEM, JWK, and/or internal formats
```javascript
RSA.generateKeypair(null, null, null, function (keypair) { /*...*/ });
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RSA.generateKeypair(1024, 65537, { pem: false, public: false, internal: false }, function (keypair) { /*...*/ });
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```
`bitlen` : *1024* (default), 2048, or 4096
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`exp` : *65537* (default)
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`options` :
```javascript
{ public: false // export public keys
, pem: false // export pems
, jwk: true // export jwks
, internal: false // preserve internal intermediate formats (_ursa, _forge)
, thumbprint: false // JWK sha256 thumbprint
, fingerprint: false // NOT IMPLEMENTED (RSA key fingerprint)
}
```
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### RSA.import(keypair, options)
Imports keypair as JWKs and internal values `_ursa` and `_forge` .
```javascript
var keypair = RSA.import({ privateKeyPem: '...'});
console.log(keypair);
```
```javascript
{ privateKeyPem: ..., privateKeyJwk: ..., _ursa: ..., _forge: ... }
```
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### RSA.export*(keypair)
You put in an object like `{ privateKeyPem: '...' }` or `{ publicKeyJwk: {} }`
and you get back the keys in the format you requested.
Note:
* Private keys **can** be used to export both private and public keys
* Public keys can **NOT** be used to generate private keys
Example:
```javascript
var keypair = { privateKeyPem: '...' };
keypair.publicKeyJwk = RSA.exportPublicJwk(keypair);
console.log(keypair);
```
### RSA.signJws(keypair, payload, nonce)
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Generates a signature in JWS format (necessary for **certbot** /**letsencrypt**).
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```javascript
var message = "Hello, World!"
var nonce = crypto.randomBytes(16).toString('hex');
var jws = RSA.signJws(keypair, message, nonce);
console.log(jws);
```
The result looks like this:
```javascript
{ "header": {
"alg": "RS256",
"jwk": {
"kty": "RSA",
"n": "AMJubTfOtAarnJytLE8fhNsEI8wnpjRvBXGK/Kp0675J10ORzxyMLqzIZF3tcrUkKBrtdc79u4X0GocDUgukpfkY+2UPUS/GxehUYbYrJYWOLkoJWzxn7wfoo9X1JgvBMY6wHQnTKvnzZdkom2FMhGxkLaEUGDSfsNznTTZNBBg9",
"e": "AQAB"
}
},
"protected": "eyJub25jZSI6IjhlZjU2MjRmNWVjOWQzZWYifQ",
"payload": "JLzF1NBNCV3kfbJ5sFaFyX94fJuL2H-IzaoBN-ciiHk",
"signature": "Wb2al5SDyh5gjmkV79MK9m3sfNBBPjntSKor-34BBoGwr6n8qEnBmqB1Y4zbo-5rmvsoPmJsnRlP_hRiUY86zSAQyfbisTGrGBl0IQ7ditpkfYVm0rBWJ8WnYNqYNp8K3qcD7NW72tsy-XoWEjNlz4lWJeRdEG2Nt4CJgnREH4Y"
}
```
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### RSA.generateCsr*(keypair, names)
You can generate the CSR in human-readable or binary / base64 formats:
`RSA.generateCsrPem(keypair, names)` :
```javascript
var pem = RSA.generateCsrPem(keypair, [ 'example.com', 'www.example.com' ]);
console.log(pem);
```
web-safe base64 for **certbot** /**letsencrypt**:
`RSA.generateCsrDerWeb64(keypair, names)` :
```javascript
var web64 = RSA.generateCsrDerWeb64(keypair, [ 'example.com', 'www.example.com' ]);
console.log(web64);
```