// Copyright 2012 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package packet import ( "crypto" "crypto/rand" "io" "math/big" "time" ) // Config collects a number of parameters along with sensible defaults. // A nil *Config is valid and results in all default values. type Config struct { // Rand provides the source of entropy. // If nil, the crypto/rand Reader is used. Rand io.Reader // DefaultHash is the default hash function to be used. // If zero, SHA-256 is used. DefaultHash crypto.Hash // DefaultCipher is the cipher to be used. // If zero, AES-128 is used. DefaultCipher CipherFunction // Time returns the current time as the number of seconds since the // epoch. If Time is nil, time.Now is used. Time func() time.Time // DefaultCompressionAlgo is the compression algorithm to be // applied to the plaintext before encryption. If zero, no // compression is done. DefaultCompressionAlgo CompressionAlgo // CompressionConfig configures the compression settings. CompressionConfig *CompressionConfig // S2KCount is only used for symmetric encryption. It // determines the strength of the passphrase stretching when // the said passphrase is hashed to produce a key. S2KCount // should be between 1024 and 65011712, inclusive. If Config // is nil or S2KCount is 0, the value 65536 used. Not all // values in the above range can be represented. S2KCount will // be rounded up to the next representable value if it cannot // be encoded exactly. When set, it is strongly encrouraged to // use a value that is at least 65536. See RFC 4880 Section // 3.7.1.3. S2KCount int // RSABits is the number of bits in new RSA keys made with NewEntity. // If zero, then 2048 bit keys are created. RSABits int // The public key algorithm to use - will always create a signing primary // key and encryption subkey. Algorithm PublicKeyAlgorithm // Some known primes that are optionally prepopulated by the caller RSAPrimes []*big.Int // Curve configures the desired packet.Curve if the Algorithm is PubKeyAlgoECDSA, // PubKeyAlgoEdDSA, or PubKeyAlgoECDH. If empty Curve25519 is used. Curve Curve // AEADConfig configures the use of the new AEAD Encrypted Data Packet, // defined in the draft of the next version of the OpenPGP specification. // If a non-nil AEADConfig is passed, usage of this packet is enabled. By // default, it is disabled. See the documentation of AEADConfig for more // configuration options related to AEAD. // **Note: using this option may break compatibility with other OpenPGP // implementations, as well as future versions of this library.** AEADConfig *AEADConfig // V5Keys configures version 5 key generation. If false, this package still // supports version 5 keys, but produces version 4 keys. V5Keys bool // "The validity period of the key. This is the number of seconds after // the key creation time that the key expires. If this is not present // or has a value of zero, the key never expires. This is found only on // a self-signature."" // https://tools.ietf.org/html/rfc4880#section-5.2.3.6 KeyLifetimeSecs uint32 // "The validity period of the signature. This is the number of seconds // after the signature creation time that the signature expires. If // this is not present or has a value of zero, it never expires." // https://tools.ietf.org/html/rfc4880#section-5.2.3.10 SigLifetimeSecs uint32 // SigningKeyId is used to specify the signing key to use (by Key ID). // By default, the signing key is selected automatically, preferring // signing subkeys if available. SigningKeyId uint64 // SigningIdentity is used to specify a user ID (packet Signer's User ID, type 28) // when producing a generic certification signature onto an existing user ID. // The identity must be present in the signer Entity. SigningIdentity string } func (c *Config) Random() io.Reader { if c == nil || c.Rand == nil { return rand.Reader } return c.Rand } func (c *Config) Hash() crypto.Hash { if c == nil || uint(c.DefaultHash) == 0 { return crypto.SHA256 } return c.DefaultHash } func (c *Config) Cipher() CipherFunction { if c == nil || uint8(c.DefaultCipher) == 0 { return CipherAES128 } return c.DefaultCipher } func (c *Config) Now() time.Time { if c == nil || c.Time == nil { return time.Now() } return c.Time() } // KeyLifetime returns the validity period of the key. func (c *Config) KeyLifetime() uint32 { if c == nil { return 0 } return c.KeyLifetimeSecs } // SigLifetime returns the validity period of the signature. func (c *Config) SigLifetime() uint32 { if c == nil { return 0 } return c.SigLifetimeSecs } func (c *Config) Compression() CompressionAlgo { if c == nil { return CompressionNone } return c.DefaultCompressionAlgo } func (c *Config) PasswordHashIterations() int { if c == nil || c.S2KCount == 0 { return 0 } return c.S2KCount } func (c *Config) RSAModulusBits() int { if c == nil || c.RSABits == 0 { return 2048 } return c.RSABits } func (c *Config) PublicKeyAlgorithm() PublicKeyAlgorithm { if c == nil || c.Algorithm == 0 { return PubKeyAlgoRSA } return c.Algorithm } func (c *Config) CurveName() Curve { if c == nil || c.Curve == "" { return Curve25519 } return c.Curve } func (c *Config) AEAD() *AEADConfig { if c == nil { return nil } return c.AEADConfig } func (c *Config) SigningKey() uint64 { if c == nil { return 0 } return c.SigningKeyId } func (c *Config) SigningUserId() string { if c == nil { return "" } return c.SigningIdentity }