terraform-provider-gitea/vendor/github.com/ProtonMail/go-crypto/openpgp/key_generation.go
dependabot[bot] 910ccdb092
Bump github.com/hashicorp/terraform-plugin-sdk/v2 from 2.26.1 to 2.27.0
Bumps [github.com/hashicorp/terraform-plugin-sdk/v2](https://github.com/hashicorp/terraform-plugin-sdk) from 2.26.1 to 2.27.0.
- [Release notes](https://github.com/hashicorp/terraform-plugin-sdk/releases)
- [Changelog](https://github.com/hashicorp/terraform-plugin-sdk/blob/main/CHANGELOG.md)
- [Commits](https://github.com/hashicorp/terraform-plugin-sdk/compare/v2.26.1...v2.27.0)

---
updated-dependencies:
- dependency-name: github.com/hashicorp/terraform-plugin-sdk/v2
  dependency-type: direct:production
  update-type: version-update:semver-minor
...

Signed-off-by: dependabot[bot] <support@github.com>
2023-07-03 20:21:30 +00:00

390 lines
12 KiB
Go
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

// Copyright 2011 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 openpgp
import (
"crypto"
"crypto/rand"
"crypto/rsa"
goerrors "errors"
"io"
"math/big"
"time"
"github.com/ProtonMail/go-crypto/openpgp/ecdh"
"github.com/ProtonMail/go-crypto/openpgp/ecdsa"
"github.com/ProtonMail/go-crypto/openpgp/eddsa"
"github.com/ProtonMail/go-crypto/openpgp/errors"
"github.com/ProtonMail/go-crypto/openpgp/internal/algorithm"
"github.com/ProtonMail/go-crypto/openpgp/internal/ecc"
"github.com/ProtonMail/go-crypto/openpgp/packet"
)
// NewEntity returns an Entity that contains a fresh RSA/RSA keypair with a
// single identity composed of the given full name, comment and email, any of
// which may be empty but must not contain any of "()<>\x00".
// If config is nil, sensible defaults will be used.
func NewEntity(name, comment, email string, config *packet.Config) (*Entity, error) {
creationTime := config.Now()
keyLifetimeSecs := config.KeyLifetime()
// Generate a primary signing key
primaryPrivRaw, err := newSigner(config)
if err != nil {
return nil, err
}
primary := packet.NewSignerPrivateKey(creationTime, primaryPrivRaw)
if config != nil && config.V5Keys {
primary.UpgradeToV5()
}
e := &Entity{
PrimaryKey: &primary.PublicKey,
PrivateKey: primary,
Identities: make(map[string]*Identity),
Subkeys: []Subkey{},
}
err = e.addUserId(name, comment, email, config, creationTime, keyLifetimeSecs)
if err != nil {
return nil, err
}
// NOTE: No key expiry here, but we will not return this subkey in EncryptionKey()
// if the primary/master key has expired.
err = e.addEncryptionSubkey(config, creationTime, 0)
if err != nil {
return nil, err
}
return e, nil
}
func (t *Entity) AddUserId(name, comment, email string, config *packet.Config) error {
creationTime := config.Now()
keyLifetimeSecs := config.KeyLifetime()
return t.addUserId(name, comment, email, config, creationTime, keyLifetimeSecs)
}
func (t *Entity) addUserId(name, comment, email string, config *packet.Config, creationTime time.Time, keyLifetimeSecs uint32) error {
uid := packet.NewUserId(name, comment, email)
if uid == nil {
return errors.InvalidArgumentError("user id field contained invalid characters")
}
if _, ok := t.Identities[uid.Id]; ok {
return errors.InvalidArgumentError("user id exist")
}
primary := t.PrivateKey
isPrimaryId := len(t.Identities) == 0
selfSignature := createSignaturePacket(&primary.PublicKey, packet.SigTypePositiveCert, config)
selfSignature.CreationTime = creationTime
selfSignature.KeyLifetimeSecs = &keyLifetimeSecs
selfSignature.IsPrimaryId = &isPrimaryId
selfSignature.FlagsValid = true
selfSignature.FlagSign = true
selfSignature.FlagCertify = true
selfSignature.SEIPDv1 = true // true by default, see 5.8 vs. 5.14
selfSignature.SEIPDv2 = config.AEAD() != nil
// Set the PreferredHash for the SelfSignature from the packet.Config.
// If it is not the must-implement algorithm from rfc4880bis, append that.
hash, ok := algorithm.HashToHashId(config.Hash())
if !ok {
return errors.UnsupportedError("unsupported preferred hash function")
}
selfSignature.PreferredHash = []uint8{hash}
if config.Hash() != crypto.SHA256 {
selfSignature.PreferredHash = append(selfSignature.PreferredHash, hashToHashId(crypto.SHA256))
}
// Likewise for DefaultCipher.
selfSignature.PreferredSymmetric = []uint8{uint8(config.Cipher())}
if config.Cipher() != packet.CipherAES128 {
selfSignature.PreferredSymmetric = append(selfSignature.PreferredSymmetric, uint8(packet.CipherAES128))
}
// We set CompressionNone as the preferred compression algorithm because
// of compression side channel attacks, then append the configured
// DefaultCompressionAlgo if any is set (to signal support for cases
// where the application knows that using compression is safe).
selfSignature.PreferredCompression = []uint8{uint8(packet.CompressionNone)}
if config.Compression() != packet.CompressionNone {
selfSignature.PreferredCompression = append(selfSignature.PreferredCompression, uint8(config.Compression()))
}
// And for DefaultMode.
modes := []uint8{uint8(config.AEAD().Mode())}
if config.AEAD().Mode() != packet.AEADModeOCB {
modes = append(modes, uint8(packet.AEADModeOCB))
}
// For preferred (AES256, GCM), we'll generate (AES256, GCM), (AES256, OCB), (AES128, GCM), (AES128, OCB)
for _, cipher := range selfSignature.PreferredSymmetric {
for _, mode := range modes {
selfSignature.PreferredCipherSuites = append(selfSignature.PreferredCipherSuites, [2]uint8{cipher, mode})
}
}
// User ID binding signature
err := selfSignature.SignUserId(uid.Id, &primary.PublicKey, primary, config)
if err != nil {
return err
}
t.Identities[uid.Id] = &Identity{
Name: uid.Id,
UserId: uid,
SelfSignature: selfSignature,
Signatures: []*packet.Signature{selfSignature},
}
return nil
}
// AddSigningSubkey adds a signing keypair as a subkey to the Entity.
// If config is nil, sensible defaults will be used.
func (e *Entity) AddSigningSubkey(config *packet.Config) error {
creationTime := config.Now()
keyLifetimeSecs := config.KeyLifetime()
subPrivRaw, err := newSigner(config)
if err != nil {
return err
}
sub := packet.NewSignerPrivateKey(creationTime, subPrivRaw)
sub.IsSubkey = true
if config != nil && config.V5Keys {
sub.UpgradeToV5()
}
subkey := Subkey{
PublicKey: &sub.PublicKey,
PrivateKey: sub,
}
subkey.Sig = createSignaturePacket(e.PrimaryKey, packet.SigTypeSubkeyBinding, config)
subkey.Sig.CreationTime = creationTime
subkey.Sig.KeyLifetimeSecs = &keyLifetimeSecs
subkey.Sig.FlagsValid = true
subkey.Sig.FlagSign = true
subkey.Sig.EmbeddedSignature = createSignaturePacket(subkey.PublicKey, packet.SigTypePrimaryKeyBinding, config)
subkey.Sig.EmbeddedSignature.CreationTime = creationTime
err = subkey.Sig.EmbeddedSignature.CrossSignKey(subkey.PublicKey, e.PrimaryKey, subkey.PrivateKey, config)
if err != nil {
return err
}
err = subkey.Sig.SignKey(subkey.PublicKey, e.PrivateKey, config)
if err != nil {
return err
}
e.Subkeys = append(e.Subkeys, subkey)
return nil
}
// AddEncryptionSubkey adds an encryption keypair as a subkey to the Entity.
// If config is nil, sensible defaults will be used.
func (e *Entity) AddEncryptionSubkey(config *packet.Config) error {
creationTime := config.Now()
keyLifetimeSecs := config.KeyLifetime()
return e.addEncryptionSubkey(config, creationTime, keyLifetimeSecs)
}
func (e *Entity) addEncryptionSubkey(config *packet.Config, creationTime time.Time, keyLifetimeSecs uint32) error {
subPrivRaw, err := newDecrypter(config)
if err != nil {
return err
}
sub := packet.NewDecrypterPrivateKey(creationTime, subPrivRaw)
sub.IsSubkey = true
if config != nil && config.V5Keys {
sub.UpgradeToV5()
}
subkey := Subkey{
PublicKey: &sub.PublicKey,
PrivateKey: sub,
}
subkey.Sig = createSignaturePacket(e.PrimaryKey, packet.SigTypeSubkeyBinding, config)
subkey.Sig.CreationTime = creationTime
subkey.Sig.KeyLifetimeSecs = &keyLifetimeSecs
subkey.Sig.FlagsValid = true
subkey.Sig.FlagEncryptStorage = true
subkey.Sig.FlagEncryptCommunications = true
err = subkey.Sig.SignKey(subkey.PublicKey, e.PrivateKey, config)
if err != nil {
return err
}
e.Subkeys = append(e.Subkeys, subkey)
return nil
}
// Generates a signing key
func newSigner(config *packet.Config) (signer interface{}, err error) {
switch config.PublicKeyAlgorithm() {
case packet.PubKeyAlgoRSA:
bits := config.RSAModulusBits()
if bits < 1024 {
return nil, errors.InvalidArgumentError("bits must be >= 1024")
}
if config != nil && len(config.RSAPrimes) >= 2 {
primes := config.RSAPrimes[0:2]
config.RSAPrimes = config.RSAPrimes[2:]
return generateRSAKeyWithPrimes(config.Random(), 2, bits, primes)
}
return rsa.GenerateKey(config.Random(), bits)
case packet.PubKeyAlgoEdDSA:
curve := ecc.FindEdDSAByGenName(string(config.CurveName()))
if curve == nil {
return nil, errors.InvalidArgumentError("unsupported curve")
}
priv, err := eddsa.GenerateKey(config.Random(), curve)
if err != nil {
return nil, err
}
return priv, nil
case packet.PubKeyAlgoECDSA:
curve := ecc.FindECDSAByGenName(string(config.CurveName()))
if curve == nil {
return nil, errors.InvalidArgumentError("unsupported curve")
}
priv, err := ecdsa.GenerateKey(config.Random(), curve)
if err != nil {
return nil, err
}
return priv, nil
default:
return nil, errors.InvalidArgumentError("unsupported public key algorithm")
}
}
// Generates an encryption/decryption key
func newDecrypter(config *packet.Config) (decrypter interface{}, err error) {
switch config.PublicKeyAlgorithm() {
case packet.PubKeyAlgoRSA:
bits := config.RSAModulusBits()
if bits < 1024 {
return nil, errors.InvalidArgumentError("bits must be >= 1024")
}
if config != nil && len(config.RSAPrimes) >= 2 {
primes := config.RSAPrimes[0:2]
config.RSAPrimes = config.RSAPrimes[2:]
return generateRSAKeyWithPrimes(config.Random(), 2, bits, primes)
}
return rsa.GenerateKey(config.Random(), bits)
case packet.PubKeyAlgoEdDSA, packet.PubKeyAlgoECDSA:
fallthrough // When passing EdDSA or ECDSA, we generate an ECDH subkey
case packet.PubKeyAlgoECDH:
var kdf = ecdh.KDF{
Hash: algorithm.SHA512,
Cipher: algorithm.AES256,
}
curve := ecc.FindECDHByGenName(string(config.CurveName()))
if curve == nil {
return nil, errors.InvalidArgumentError("unsupported curve")
}
return ecdh.GenerateKey(config.Random(), curve, kdf)
default:
return nil, errors.InvalidArgumentError("unsupported public key algorithm")
}
}
var bigOne = big.NewInt(1)
// generateRSAKeyWithPrimes generates a multi-prime RSA keypair of the
// given bit size, using the given random source and prepopulated primes.
func generateRSAKeyWithPrimes(random io.Reader, nprimes int, bits int, prepopulatedPrimes []*big.Int) (*rsa.PrivateKey, error) {
priv := new(rsa.PrivateKey)
priv.E = 65537
if nprimes < 2 {
return nil, goerrors.New("generateRSAKeyWithPrimes: nprimes must be >= 2")
}
if bits < 1024 {
return nil, goerrors.New("generateRSAKeyWithPrimes: bits must be >= 1024")
}
primes := make([]*big.Int, nprimes)
NextSetOfPrimes:
for {
todo := bits
// crypto/rand should set the top two bits in each prime.
// Thus each prime has the form
// p_i = 2^bitlen(p_i) × 0.11... (in base 2).
// And the product is:
// P = 2^todo × α
// where α is the product of nprimes numbers of the form 0.11...
//
// If α < 1/2 (which can happen for nprimes > 2), we need to
// shift todo to compensate for lost bits: the mean value of 0.11...
// is 7/8, so todo + shift - nprimes * log2(7/8) ~= bits - 1/2
// will give good results.
if nprimes >= 7 {
todo += (nprimes - 2) / 5
}
for i := 0; i < nprimes; i++ {
var err error
if len(prepopulatedPrimes) == 0 {
primes[i], err = rand.Prime(random, todo/(nprimes-i))
if err != nil {
return nil, err
}
} else {
primes[i] = prepopulatedPrimes[0]
prepopulatedPrimes = prepopulatedPrimes[1:]
}
todo -= primes[i].BitLen()
}
// Make sure that primes is pairwise unequal.
for i, prime := range primes {
for j := 0; j < i; j++ {
if prime.Cmp(primes[j]) == 0 {
continue NextSetOfPrimes
}
}
}
n := new(big.Int).Set(bigOne)
totient := new(big.Int).Set(bigOne)
pminus1 := new(big.Int)
for _, prime := range primes {
n.Mul(n, prime)
pminus1.Sub(prime, bigOne)
totient.Mul(totient, pminus1)
}
if n.BitLen() != bits {
// This should never happen for nprimes == 2 because
// crypto/rand should set the top two bits in each prime.
// For nprimes > 2 we hope it does not happen often.
continue NextSetOfPrimes
}
priv.D = new(big.Int)
e := big.NewInt(int64(priv.E))
ok := priv.D.ModInverse(e, totient)
if ok != nil {
priv.Primes = primes
priv.N = n
break
}
}
priv.Precompute()
return priv, nil
}