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path_keys.go
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path_keys.go
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package transit
import (
"context"
"crypto/elliptic"
"crypto/x509"
"encoding/base64"
"encoding/pem"
"fmt"
"strconv"
"time"
"golang.org/x/crypto/ed25519"
"github.com/fatih/structs"
"github.com/hashicorp/errwrap"
"github.com/hashicorp/vault/sdk/framework"
"github.com/hashicorp/vault/sdk/helper/keysutil"
"github.com/hashicorp/vault/sdk/logical"
)
func (b *backend) pathListKeys() *framework.Path {
return &framework.Path{
Pattern: "keys/?$",
Callbacks: map[logical.Operation]framework.OperationFunc{
logical.ListOperation: b.pathKeysList,
},
HelpSynopsis: pathPolicyHelpSyn,
HelpDescription: pathPolicyHelpDesc,
}
}
func (b *backend) pathKeys() *framework.Path {
return &framework.Path{
Pattern: "keys/" + framework.GenericNameRegex("name"),
Fields: map[string]*framework.FieldSchema{
"name": &framework.FieldSchema{
Type: framework.TypeString,
Description: "Name of the key",
},
"type": &framework.FieldSchema{
Type: framework.TypeString,
Default: "aes256-gcm96",
Description: `
The type of key to create. Currently, "aes128-gcm96" (symmetric), "aes256-gcm96" (symmetric), "ecdsa-p256"
(asymmetric), "ecdsa-p384" (asymmetric), "ecdsa-p521" (asymmetric), "ed25519" (asymmetric), "rsa-2048" (asymmetric), "rsa-3072"
(asymmetric), "rsa-4096" (asymmetric) are supported. Defaults to "aes256-gcm96".
`,
},
"derived": &framework.FieldSchema{
Type: framework.TypeBool,
Description: `Enables key derivation mode. This
allows for per-transaction unique
keys for encryption operations.`,
},
"convergent_encryption": &framework.FieldSchema{
Type: framework.TypeBool,
Description: `Whether to support convergent encryption.
This is only supported when using a key with
key derivation enabled and will require all
requests to carry both a context and 96-bit
(12-byte) nonce. The given nonce will be used
in place of a randomly generated nonce. As a
result, when the same context and nonce are
supplied, the same ciphertext is generated. It
is *very important* when using this mode that
you ensure that all nonces are unique for a
given context. Failing to do so will severely
impact the ciphertext's security.`,
},
"exportable": &framework.FieldSchema{
Type: framework.TypeBool,
Description: `Enables keys to be exportable.
This allows for all the valid keys
in the key ring to be exported.`,
},
"allow_plaintext_backup": &framework.FieldSchema{
Type: framework.TypeBool,
Description: `Enables taking a backup of the named
key in plaintext format. Once set,
this cannot be disabled.`,
},
"context": &framework.FieldSchema{
Type: framework.TypeString,
Description: `Base64 encoded context for key derivation.
When reading a key with key derivation enabled,
if the key type supports public keys, this will
return the public key for the given context.`,
},
},
Callbacks: map[logical.Operation]framework.OperationFunc{
logical.UpdateOperation: b.pathPolicyWrite,
logical.DeleteOperation: b.pathPolicyDelete,
logical.ReadOperation: b.pathPolicyRead,
},
HelpSynopsis: pathPolicyHelpSyn,
HelpDescription: pathPolicyHelpDesc,
}
}
func (b *backend) pathKeysList(ctx context.Context, req *logical.Request, d *framework.FieldData) (*logical.Response, error) {
entries, err := req.Storage.List(ctx, "policy/")
if err != nil {
return nil, err
}
return logical.ListResponse(entries), nil
}
func (b *backend) pathPolicyWrite(ctx context.Context, req *logical.Request, d *framework.FieldData) (*logical.Response, error) {
name := d.Get("name").(string)
derived := d.Get("derived").(bool)
convergent := d.Get("convergent_encryption").(bool)
keyType := d.Get("type").(string)
exportable := d.Get("exportable").(bool)
allowPlaintextBackup := d.Get("allow_plaintext_backup").(bool)
if !derived && convergent {
return logical.ErrorResponse("convergent encryption requires derivation to be enabled"), nil
}
polReq := keysutil.PolicyRequest{
Upsert: true,
Storage: req.Storage,
Name: name,
Derived: derived,
Convergent: convergent,
Exportable: exportable,
AllowPlaintextBackup: allowPlaintextBackup,
}
switch keyType {
case "aes128-gcm96":
polReq.KeyType = keysutil.KeyType_AES128_GCM96
case "aes256-gcm96":
polReq.KeyType = keysutil.KeyType_AES256_GCM96
case "chacha20-poly1305":
polReq.KeyType = keysutil.KeyType_ChaCha20_Poly1305
case "ecdsa-p256":
polReq.KeyType = keysutil.KeyType_ECDSA_P256
case "ecdsa-p384":
polReq.KeyType = keysutil.KeyType_ECDSA_P384
case "ecdsa-p521":
polReq.KeyType = keysutil.KeyType_ECDSA_P521
case "ed25519":
polReq.KeyType = keysutil.KeyType_ED25519
case "rsa-2048":
polReq.KeyType = keysutil.KeyType_RSA2048
case "rsa-3072":
polReq.KeyType = keysutil.KeyType_RSA3072
case "rsa-4096":
polReq.KeyType = keysutil.KeyType_RSA4096
default:
return logical.ErrorResponse(fmt.Sprintf("unknown key type %v", keyType)), logical.ErrInvalidRequest
}
p, upserted, err := b.lm.GetPolicy(ctx, polReq, b.GetRandomReader())
if err != nil {
return nil, err
}
if p == nil {
return nil, fmt.Errorf("error generating key: returned policy was nil")
}
if b.System().CachingDisabled() {
p.Unlock()
}
resp := &logical.Response{}
if !upserted {
resp.AddWarning(fmt.Sprintf("key %s already existed", name))
}
return nil, nil
}
// Built-in helper type for returning asymmetric keys
type asymKey struct {
Name string `json:"name" structs:"name" mapstructure:"name"`
PublicKey string `json:"public_key" structs:"public_key" mapstructure:"public_key"`
CreationTime time.Time `json:"creation_time" structs:"creation_time" mapstructure:"creation_time"`
}
func (b *backend) pathPolicyRead(ctx context.Context, req *logical.Request, d *framework.FieldData) (*logical.Response, error) {
name := d.Get("name").(string)
p, _, err := b.lm.GetPolicy(ctx, keysutil.PolicyRequest{
Storage: req.Storage,
Name: name,
}, b.GetRandomReader())
if err != nil {
return nil, err
}
if p == nil {
return nil, nil
}
if !b.System().CachingDisabled() {
p.Lock(false)
}
defer p.Unlock()
// Return the response
resp := &logical.Response{
Data: map[string]interface{}{
"name": p.Name,
"type": p.Type.String(),
"derived": p.Derived,
"deletion_allowed": p.DeletionAllowed,
"min_available_version": p.MinAvailableVersion,
"min_decryption_version": p.MinDecryptionVersion,
"min_encryption_version": p.MinEncryptionVersion,
"latest_version": p.LatestVersion,
"exportable": p.Exportable,
"allow_plaintext_backup": p.AllowPlaintextBackup,
"supports_encryption": p.Type.EncryptionSupported(),
"supports_decryption": p.Type.DecryptionSupported(),
"supports_signing": p.Type.SigningSupported(),
"supports_derivation": p.Type.DerivationSupported(),
},
}
if p.BackupInfo != nil {
resp.Data["backup_info"] = map[string]interface{}{
"time": p.BackupInfo.Time,
"version": p.BackupInfo.Version,
}
}
if p.RestoreInfo != nil {
resp.Data["restore_info"] = map[string]interface{}{
"time": p.RestoreInfo.Time,
"version": p.RestoreInfo.Version,
}
}
if p.Derived {
switch p.KDF {
case keysutil.Kdf_hmac_sha256_counter:
resp.Data["kdf"] = "hmac-sha256-counter"
resp.Data["kdf_mode"] = "hmac-sha256-counter"
case keysutil.Kdf_hkdf_sha256:
resp.Data["kdf"] = "hkdf_sha256"
}
resp.Data["convergent_encryption"] = p.ConvergentEncryption
if p.ConvergentEncryption {
resp.Data["convergent_encryption_version"] = p.ConvergentVersion
}
}
contextRaw := d.Get("context").(string)
var context []byte
if len(contextRaw) != 0 {
context, err = base64.StdEncoding.DecodeString(contextRaw)
if err != nil {
return logical.ErrorResponse("failed to base64-decode context"), logical.ErrInvalidRequest
}
}
switch p.Type {
case keysutil.KeyType_AES128_GCM96, keysutil.KeyType_AES256_GCM96, keysutil.KeyType_ChaCha20_Poly1305:
retKeys := map[string]int64{}
for k, v := range p.Keys {
retKeys[k] = v.DeprecatedCreationTime
}
resp.Data["keys"] = retKeys
case keysutil.KeyType_ECDSA_P256, keysutil.KeyType_ECDSA_P384, keysutil.KeyType_ECDSA_P521, keysutil.KeyType_ED25519, keysutil.KeyType_RSA2048, keysutil.KeyType_RSA3072, keysutil.KeyType_RSA4096:
retKeys := map[string]map[string]interface{}{}
for k, v := range p.Keys {
key := asymKey{
PublicKey: v.FormattedPublicKey,
CreationTime: v.CreationTime,
}
if key.CreationTime.IsZero() {
key.CreationTime = time.Unix(v.DeprecatedCreationTime, 0)
}
switch p.Type {
case keysutil.KeyType_ECDSA_P256:
key.Name = elliptic.P256().Params().Name
case keysutil.KeyType_ECDSA_P384:
key.Name = elliptic.P384().Params().Name
case keysutil.KeyType_ECDSA_P521:
key.Name = elliptic.P521().Params().Name
case keysutil.KeyType_ED25519:
if p.Derived {
if len(context) == 0 {
key.PublicKey = ""
} else {
ver, err := strconv.Atoi(k)
if err != nil {
return nil, errwrap.Wrapf(fmt.Sprintf("invalid version %q: {{err}}", k), err)
}
derived, err := p.DeriveKey(context, ver, 32)
if err != nil {
return nil, fmt.Errorf("failed to derive key to return public component")
}
pubKey := ed25519.PrivateKey(derived).Public().(ed25519.PublicKey)
key.PublicKey = base64.StdEncoding.EncodeToString(pubKey)
}
}
key.Name = "ed25519"
case keysutil.KeyType_RSA2048, keysutil.KeyType_RSA3072, keysutil.KeyType_RSA4096:
key.Name = "rsa-2048"
if p.Type == keysutil.KeyType_RSA3072 {
key.Name = "rsa-3072"
}
if p.Type == keysutil.KeyType_RSA4096 {
key.Name = "rsa-4096"
}
// Encode the RSA public key in PEM format to return over the
// API
derBytes, err := x509.MarshalPKIXPublicKey(v.RSAKey.Public())
if err != nil {
return nil, errwrap.Wrapf("error marshaling RSA public key: {{err}}", err)
}
pemBlock := &pem.Block{
Type: "PUBLIC KEY",
Bytes: derBytes,
}
pemBytes := pem.EncodeToMemory(pemBlock)
if pemBytes == nil || len(pemBytes) == 0 {
return nil, fmt.Errorf("failed to PEM-encode RSA public key")
}
key.PublicKey = string(pemBytes)
}
retKeys[k] = structs.New(key).Map()
}
resp.Data["keys"] = retKeys
}
return resp, nil
}
func (b *backend) pathPolicyDelete(ctx context.Context, req *logical.Request, d *framework.FieldData) (*logical.Response, error) {
name := d.Get("name").(string)
// Delete does its own locking
err := b.lm.DeletePolicy(ctx, req.Storage, name)
if err != nil {
return logical.ErrorResponse(fmt.Sprintf("error deleting policy %s: %s", name, err)), err
}
return nil, nil
}
const pathPolicyHelpSyn = `Managed named encryption keys`
const pathPolicyHelpDesc = `
This path is used to manage the named keys that are available.
Doing a write with no value against a new named key will create
it using a randomly generated key.
`