Access to advanced cryptographic functionalities. The Crypto class allows you to access some more advanced cryptographic functionalities in Godot. For now, this includes generating cryptographically secure random bytes, RSA keys and self-signed X509 certificates generation, asymmetric key encryption/decryption, and signing/verification. [codeblock] extends Node var crypto = Crypto.new() var key = CryptoKey.new() var cert = X509Certificate.new() func _ready(): # Generate new RSA key. key = crypto.generate_rsa(4096) # Generate new self-signed certificate with the given key. cert = crypto.generate_self_signed_certificate(key, "CN=mydomain.com,O=My Game Company,C=IT") # Save key and certificate in the user folder. key.save("user://generated.key") cert.save("user://generated.crt") # Encryption var data = "Some data" var encrypted = crypto.encrypt(key, data.to_utf8()) # Decryption var decrypted = crypto.decrypt(key, encrypted) # Signing var signature = crypto.sign(HashingContext.HASH_SHA256, data.sha256_buffer(), key) # Verifying var verified = crypto.verify(HashingContext.HASH_SHA256, data.sha256_buffer(), signature, key) # Checks assert(verified) assert(data.to_utf8() == decrypted) [/codeblock] [b]Note:[/b] Not available in HTML5 exports. Compares two [PoolByteArray]s for equality without leaking timing information in order to prevent timing attacks. See [url=https://paragonie.com/blog/2015/11/preventing-timing-attacks-on-string-comparison-with-double-hmac-strategy]this blog post[/url] for more information. Decrypt the given [code]ciphertext[/code] with the provided private [code]key[/code]. [b]Note:[/b] The maximum size of accepted ciphertext is limited by the key size. Encrypt the given [code]plaintext[/code] with the provided public [code]key[/code]. [b]Note:[/b] The maximum size of accepted plaintext is limited by the key size. Generates a [PoolByteArray] of cryptographically secure random bytes with given [code]size[/code]. Generates an RSA [CryptoKey] that can be used for creating self-signed certificates and passed to [method StreamPeerSSL.accept_stream]. Generates a self-signed [X509Certificate] from the given [CryptoKey] and [code]issuer_name[/code]. The certificate validity will be defined by [code]not_before[/code] and [code]not_after[/code] (first valid date and last valid date). The [code]issuer_name[/code] must contain at least "CN=" (common name, i.e. the domain name), "O=" (organization, i.e. your company name), "C=" (country, i.e. 2 lettered ISO-3166 code of the country the organization is based in). A small example to generate an RSA key and a X509 self-signed certificate. [codeblock] var crypto = Crypto.new() # Generate 4096 bits RSA key. var key = crypto.generate_rsa(4096) # Generate self-signed certificate using the given key. var cert = crypto.generate_self_signed_certificate(key, "CN=example.com,O=A Game Company,C=IT") [/codeblock] Generates an [url=https://en.wikipedia.org/wiki/HMAC]HMAC[/url] digest of [code]msg[/code] using [code]key[/code]. The [code]hash_type[/code] parameter is the hashing algorithm that is used for the inner and outer hashes. Currently, only [constant HashingContext.HASH_SHA256] and [constant HashingContext.HASH_SHA1] are supported. Sign a given [code]hash[/code] of type [code]hash_type[/code] with the provided private [code]key[/code]. Verify that a given [code]signature[/code] for [code]hash[/code] of type [code]hash_type[/code] against the provided public [code]key[/code].