gotosocial/vendor/github.com/gorilla/securecookie
2024-03-25 11:00:36 +00:00
..
.editorconfig [chore]: Bump github.com/gin-contrib/sessions from 0.0.5 to 1.0.0 (#2782) 2024-03-25 11:00:36 +00:00
.gitignore [chore]: Bump github.com/gin-contrib/sessions from 0.0.5 to 1.0.0 (#2782) 2024-03-25 11:00:36 +00:00
doc.go Grand test fixup (#138) 2021-08-12 21:03:24 +02:00
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Makefile [chore]: Bump github.com/gin-contrib/sessions from 0.0.5 to 1.0.0 (#2782) 2024-03-25 11:00:36 +00:00
README.md [chore]: Bump github.com/gin-contrib/sessions from 0.0.5 to 1.0.0 (#2782) 2024-03-25 11:00:36 +00:00
securecookie.go [chore]: Bump github.com/gin-contrib/sessions from 0.0.5 to 1.0.0 (#2782) 2024-03-25 11:00:36 +00:00

gorilla/securecookie

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Gorilla Logo

securecookie encodes and decodes authenticated and optionally encrypted cookie values.

Secure cookies can't be forged, because their values are validated using HMAC. When encrypted, the content is also inaccessible to malicious eyes. It is still recommended that sensitive data not be stored in cookies, and that HTTPS be used to prevent cookie replay attacks.

Examples

To use it, first create a new SecureCookie instance:

// Hash keys should be at least 32 bytes long
var hashKey = []byte("very-secret")
// Block keys should be 16 bytes (AES-128) or 32 bytes (AES-256) long.
// Shorter keys may weaken the encryption used.
var blockKey = []byte("a-lot-secret")
var s = securecookie.New(hashKey, blockKey)

The hashKey is required, used to authenticate the cookie value using HMAC. It is recommended to use a key with 32 or 64 bytes.

The blockKey is optional, used to encrypt the cookie value -- set it to nil to not use encryption. If set, the length must correspond to the block size of the encryption algorithm. For AES, used by default, valid lengths are 16, 24, or 32 bytes to select AES-128, AES-192, or AES-256.

Strong keys can be created using the convenience function GenerateRandomKey(). Note that keys created using GenerateRandomKey() are not automatically persisted. New keys will be created when the application is restarted, and previously issued cookies will not be able to be decoded.

Once a SecureCookie instance is set, use it to encode a cookie value:

func SetCookieHandler(w http.ResponseWriter, r *http.Request) {
	value := map[string]string{
		"foo": "bar",
	}
	if encoded, err := s.Encode("cookie-name", value); err == nil {
		cookie := &http.Cookie{
			Name:  "cookie-name",
			Value: encoded,
			Path:  "/",
			Secure: true,
			HttpOnly: true,
		}
		http.SetCookie(w, cookie)
	}
}

Later, use the same SecureCookie instance to decode and validate a cookie value:

func ReadCookieHandler(w http.ResponseWriter, r *http.Request) {
	if cookie, err := r.Cookie("cookie-name"); err == nil {
		value := make(map[string]string)
		if err = s2.Decode("cookie-name", cookie.Value, &value); err == nil {
			fmt.Fprintf(w, "The value of foo is %q", value["foo"])
		}
	}
}

We stored a map[string]string, but secure cookies can hold any value that can be encoded using encoding/gob. To store custom types, they must be registered first using gob.Register(). For basic types this is not needed; it works out of the box. An optional JSON encoder that uses encoding/json is available for types compatible with JSON.

Key Rotation

Rotating keys is an important part of any security strategy. The EncodeMulti and DecodeMulti functions allow for multiple keys to be rotated in and out. For example, let's take a system that stores keys in a map:

// keys stored in a map will not be persisted between restarts
// a more persistent storage should be considered for production applications.
var cookies = map[string]*securecookie.SecureCookie{
	"previous": securecookie.New(
		securecookie.GenerateRandomKey(64),
		securecookie.GenerateRandomKey(32),
	),
	"current": securecookie.New(
		securecookie.GenerateRandomKey(64),
		securecookie.GenerateRandomKey(32),
	),
}

Using the current key to encode new cookies:

func SetCookieHandler(w http.ResponseWriter, r *http.Request) {
	value := map[string]string{
		"foo": "bar",
	}
	if encoded, err := securecookie.EncodeMulti("cookie-name", value, cookies["current"]); err == nil {
		cookie := &http.Cookie{
			Name:  "cookie-name",
			Value: encoded,
			Path:  "/",
		}
		http.SetCookie(w, cookie)
	}
}

Later, decode cookies. Check against all valid keys:

func ReadCookieHandler(w http.ResponseWriter, r *http.Request) {
	if cookie, err := r.Cookie("cookie-name"); err == nil {
		value := make(map[string]string)
		err = securecookie.DecodeMulti("cookie-name", cookie.Value, &value, cookies["current"], cookies["previous"])
		if err == nil {
			fmt.Fprintf(w, "The value of foo is %q", value["foo"])
		}
	}
}

Rotate the keys. This strategy allows previously issued cookies to be valid until the next rotation:

func Rotate(newCookie *securecookie.SecureCookie) {
	cookies["previous"] = cookies["current"]
	cookies["current"] = newCookie
}

License

BSD licensed. See the LICENSE file for details.