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41c35b2218
The master branch includes a fix for i386, otherwise the calibration panics. See https://github.com/restic/restic/issues/676 for details.
156 lines
5.1 KiB
Markdown
156 lines
5.1 KiB
Markdown
# simple-scrypt
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[![GoDoc](https://godoc.org/github.com/elithrar/simple-scrypt?status.svg)](https://godoc.org/github.com/elithrar/simple-scrypt) [![Build Status](https://travis-ci.org/elithrar/simple-scrypt.svg?branch=master)](https://travis-ci.org/elithrar/simple-scrypt)
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simple-scrypt provides a convenience wrapper around Go's existing
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[scrypt](http://golang.org/x/crypto/scrypt) package that makes it easier to
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securely derive strong keys ("hash user passwords"). This library allows you to:
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* Generate a scrypt derived key with a crytographically secure salt and sane
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default parameters for N, r and p.
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* Upgrade the parameters used to generate keys as hardware improves by storing
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them with the derived key (the scrypt spec. doesn't allow for this by
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default).
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* Provide your own parameters (if you wish to).
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The API closely mirrors Go's [bcrypt](https://golang.org/x/crypto/bcrypt)
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library in an effort to make it easy to migrate—and because it's an easy to grok
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API.
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## Installation
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With a [working Go toolchain](https://golang.org/doc/code.html):
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```sh
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go get -u github.com/elithrar/simple-scrypt
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```
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## Example
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simple-scrypt doesn't try to re-invent the wheel or do anything "special". It
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wraps the `scrypt.Key` function as thinly as possible, generates a
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crytographically secure salt for you using Go's `crypto/rand` package, and
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returns the derived key with the parameters prepended:
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```go
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package main
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import(
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"fmt"
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"log"
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"github.com/elithrar/simple-scrypt"
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)
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func main() {
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// e.g. r.PostFormValue("password")
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passwordFromForm := "prew8fid9hick6c"
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// Generates a derived key of the form "N$r$p$salt$dk" where N, r and p are defined as per
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// Colin Percival's scrypt paper: http://www.tarsnap.com/scrypt/scrypt.pdf
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// scrypt.Defaults (N=16384, r=8, p=1) makes it easy to provide these parameters, and
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// (should you wish) provide your own values via the scrypt.Params type.
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hash, err := scrypt.GenerateFromPassword([]byte(passwordFromForm), scrypt.DefaultParams)
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if err != nil {
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log.Fatal(err)
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}
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// Print the derived key with its parameters prepended.
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fmt.Printf("%s\n", hash)
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// Uses the parameters from the existing derived key. Return an error if they don't match.
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err := scrypt.CompareHashAndPassword(hash, []byte(passwordFromForm))
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if err != nil {
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log.Fatal(err)
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}
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}
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```
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## Upgrading Parameters
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Upgrading derived keys from a set of parameters to a "stronger" set of parameters
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as hardware improves, or as you scale (and move your auth process to separate
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hardware), can be pretty useful. Here's how to do it with simple-scrypt:
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```go
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func main() {
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// SCENE: We've successfully authenticated a user, compared their submitted
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// (cleartext) password against the derived key stored in our database, and
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// now want to upgrade the parameters (more rounds, more parallelism) to
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// reflect some shiny new hardware we just purchased. As the user is logging
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// in, we can retrieve the parameters used to generate their key, and if
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// they don't match our "new" parameters, we can re-generate the key while
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// we still have the cleartext password in memory
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// (e.g. before the HTTP request ends).
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current, err := scrypt.Cost(hash)
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if err != nil {
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log.Fatal(err)
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}
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// Now to check them against our own Params struct (e.g. using reflect.DeepEquals)
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// and determine whether we want to generate a new key with our "upgraded" parameters.
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slower := scrypt.Params{
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N: 32768,
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R: 8,
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P: 2,
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SaltLen: 16,
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DKLen: 32,
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}
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if !reflect.DeepEqual(current, slower) {
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// Re-generate the key with the slower parameters
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// here using scrypt.GenerateFromPassword
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}
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}
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```
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## Automatically Determining Parameters
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Thanks to the work by [tgulacsi](https://github.com/tgulacsi), you can have simple-scrypt
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automatically determine the optimal parameters for you (time vs. memory). You should run this once
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on program startup, as calibrating parameters can be an expensive operation.
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```go
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var params scrypt.Params
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func main() {
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var err error
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// 500ms, 64MB of RAM per hash.
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params, err = scrypt.Calibrate(500*time.Millisecond, 64, Params{})
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if err != nil {
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return nil, err
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}
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...
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}
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func RegisterUserHandler(w http.ResponseWriter, r *http.Request) {
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err := r.ParseForm()
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if err != nil {
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http.Error(w, err.Error(), http.StatusBadRequest)
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return
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}
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// Make sure you validate: not empty, not too long, etc.
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email := r.PostFormValue("email")
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pass := r.PostFormValue("password")
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// Use our calibrated parameters
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hash, err := scrypt.GenerateFromPassword([]byte(pass), params)
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if err != nil {
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http.Error(w, err.Error(), http.StatusBadRequest)
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return
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}
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// Save to DB, etc.
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}
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```
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Be aware that increasing these, whilst making it harder to brute-force the resulting hash, also
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increases the risk of a denial-of-service attack against your server. A surge in authenticate
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attempts (even if legitimate!) could consume all available resources.
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## License
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MIT Licensed. See LICENSE file for details.
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