mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-11-14 02:10:21 +00:00
e72ed593be
Signed-off-by: Rakshith R <rar@redhat.com>
474 lines
20 KiB
Go
474 lines
20 KiB
Go
package kmip
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import (
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"math/big"
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"github.com/gemalto/kmip-go/kmip14"
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"github.com/gemalto/kmip-go/ttlv"
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)
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// 2.1 Base Objects
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//
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// These objects are used within the messages of the protocol, but are not objects managed by the key
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// management system. They are components of Managed Objects.
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// Attribute 2.1.1 Table 2
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//
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// An Attribute object is a structure (see Table 2) used for sending and receiving Managed Object attributes.
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// The Attribute Name is a text-string that is used to identify the attribute. The Attribute Index is an index
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// number assigned by the key management server. The Attribute Index is used to identify the particular instance.
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// Attribute Indices SHALL start with 0. The Attribute Index of an attribute SHALL NOT change when other instances
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// are added or deleted. Single-instance Attributes (attributes which an object MAY only have at most one instance
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// thereof) SHALL have an Attribute Index of 0. The Attribute Value is either a primitive data type or structured
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// object, depending on the attribute.
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//
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// When an Attribute structure is used to specify or return a particular instance of an Attribute and the Attribute
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// Index is not specified it SHALL be assumed to be 0.
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type Attribute struct {
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// AttributeName should contain the canonical name of a tag, e.g. "Cryptographic Algorithm"
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AttributeName string
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// AttributeIndex is typically 0 when clients use this struct to create objects or add attributes. Clients
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// only need to set this if modifying or deleting an existing attribute.
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AttributeIndex int `ttlv:",omitempty"`
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AttributeValue interface{}
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}
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func NewAttributeFromTag(tag ttlv.Tag, idx int, val interface{}) Attribute {
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return Attribute{
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AttributeName: tag.CanonicalName(),
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AttributeIndex: idx,
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AttributeValue: val,
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}
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}
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// Credential 2.1.2 Table 3
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//
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// A Credential is a structure (see Table 3) used for client identification purposes and is not managed by the
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// key management system (e.g., user id/password pairs, Kerberos tokens, etc.). It MAY be used for authentication
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// purposes as indicated in [KMIP-Prof].
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//
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// TODO: add an unmarshal impl to Credential to handle decoding the right kind
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// of credential based on the credential type value
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type Credential struct {
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CredentialType kmip14.CredentialType
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CredentialValue interface{}
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}
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// UsernameAndPasswordCredentialValue 2.1.2 Table 4
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//
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// If the Credential Type in the Credential is Username and Password, then Credential Value is a
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// structure as shown in Table 4. The Username field identifies the client, and the Password field
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// is a secret that authenticates the client.
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type UsernameAndPasswordCredentialValue struct {
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Username string
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Password string `ttlv:",omitempty"`
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}
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// DeviceCredentialValue 2.1.2 Table 5
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//
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// If the Credential Type in the Credential is Device, then Credential Value is a structure as shown in
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// Table 5. One or a combination of the Device Serial Number, Network Identifier, Machine Identifier,
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// and Media Identifier SHALL be unique. Server implementations MAY enforce policies on uniqueness for
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// individual fields. A shared secret or password MAY also be used to authenticate the client.
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// The client SHALL provide at least one field.
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type DeviceCredentialValue struct {
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DeviceSerialNumber string `ttlv:",omitempty"`
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Password string `ttlv:",omitempty"`
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DeviceIdentifier string `ttlv:",omitempty"`
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NetworkIdentifier string `ttlv:",omitempty"`
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MachineIdentifier string `ttlv:",omitempty"`
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MediaIdentifier string `ttlv:",omitempty"`
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}
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// AttestationCredentialValue 2.1.2 Table 6
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//
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// If the Credential Type in the Credential is Attestation, then Credential Value is a structure
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// as shown in Table 6. The Nonce Value is obtained from the key management server in a Nonce Object.
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// The Attestation Credential Object can contain a measurement from the client or an assertion from a
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// third party if the server is not capable or willing to verify the attestation data from the client.
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// Neither type of attestation data (Attestation Measurement or Attestation Assertion) is necessary to
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// allow the server to accept either. However, the client SHALL provide attestation data in either the
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// Attestation Measurement or Attestation Assertion fields.
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type AttestationCredentialValue struct {
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Nonce Nonce
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AttestationType kmip14.AttestationType
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AttestationMeasurement []byte `ttlv:",omitempty"`
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AttestationAssertion []byte `ttlv:",omitempty"`
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}
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// KeyBlock 2.1.3 Table 7
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//
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// A Key Block object is a structure (see Table 7) used to encapsulate all of the information that is
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// closely associated with a cryptographic key. It contains a Key Value of one of the following Key Format Types:
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//
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// · Raw – This is a key that contains only cryptographic key material, encoded as a string of bytes.
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// · Opaque – This is an encoded key for which the encoding is unknown to the key management system.
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// It is encoded as a string of bytes.
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// · PKCS1 – This is an encoded private key, expressed as a DER-encoded ASN.1 PKCS#1 object.
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// · PKCS8 – This is an encoded private key, expressed as a DER-encoded ASN.1 PKCS#8 object, supporting both
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// the RSAPrivateKey syntax and EncryptedPrivateKey.
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// · X.509 – This is an encoded object, expressed as a DER-encoded ASN.1 X.509 object.
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// · ECPrivateKey – This is an ASN.1 encoded elliptic curve private key.
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// · Several Transparent Key types – These are algorithm-specific structures containing defined values
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// for the various key types, as defined in Section 2.1.7.
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// · Extensions – These are vendor-specific extensions to allow for proprietary or legacy key formats.
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//
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// The Key Block MAY contain the Key Compression Type, which indicates the format of the elliptic curve public
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// key. By default, the public key is uncompressed.
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//
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// The Key Block also has the Cryptographic Algorithm and the Cryptographic Length of the key contained
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// in the Key Value field. Some example values are:
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//
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// · RSA keys are typically 1024, 2048 or 3072 bits in length.
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// · 3DES keys are typically from 112 to 192 bits (depending upon key length and the presence of parity bits).
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// · AES keys are 128, 192 or 256 bits in length.
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//
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// The Key Block SHALL contain a Key Wrapping Data structure if the key in the Key Value field is
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// wrapped (i.e., encrypted, or MACed/signed, or both).
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type KeyBlock struct {
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KeyFormatType kmip14.KeyFormatType
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KeyCompressionType kmip14.KeyCompressionType `ttlv:",omitempty"`
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KeyValue *KeyValue `ttlv:",omitempty"`
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CryptographicAlgorithm kmip14.CryptographicAlgorithm `ttlv:",omitempty"`
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CryptographicLength int `ttlv:",omitempty"`
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KeyWrappingData *KeyWrappingData
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}
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// KeyValue 2.1.4 Table 8
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//
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// The Key Value is used only inside a Key Block and is either a Byte String or a structure (see Table 8):
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//
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// · The Key Value structure contains the key material, either as a byte string or as a Transparent Key
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// structure (see Section 2.1.7), and OPTIONAL attribute information that is associated and encapsulated
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// with the key material. This attribute information differs from the attributes associated with Managed
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// Objects, and is obtained via the Get Attributes operation, only by the fact that it is encapsulated with
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// (and possibly wrapped with) the key material itself.
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// · The Key Value Byte String is either the wrapped TTLV-encoded (see Section 9.1) Key Value structure, or
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// the wrapped un-encoded value of the Byte String Key Material field.
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//
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// TODO: Unmarshaler impl which unmarshals correct KeyMaterial type.
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type KeyValue struct {
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// KeyMaterial should be []byte, one of the Transparent*Key structs, or a custom struct if KeyFormatType is
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// an extension.
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KeyMaterial interface{}
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Attribute []Attribute
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}
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// KeyWrappingData 2.1.5 Table 9
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//
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// The Key Block MAY also supply OPTIONAL information about a cryptographic key wrapping mechanism used
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// to wrap the Key Value. This consists of a Key Wrapping Data structure (see Table 9). It is only used
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// inside a Key Block.
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//
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// This structure contains fields for:
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//
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// · A Wrapping Method, which indicates the method used to wrap the Key Value.
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// · Encryption Key Information, which contains the Unique Identifier (see 3.1) value of the encryption key
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// and associated cryptographic parameters.
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// · MAC/Signature Key Information, which contains the Unique Identifier value of the MAC/signature key
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// and associated cryptographic parameters.
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// · A MAC/Signature, which contains a MAC or signature of the Key Value.
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// · An IV/Counter/Nonce, if REQUIRED by the wrapping method.
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// · An Encoding Option, specifying the encoding of the Key Material within the Key Value structure of the
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// Key Block that has been wrapped. If No Encoding is specified, then the Key Value structure SHALL NOT contain
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// any attributes.
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//
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// If wrapping is used, then the whole Key Value structure is wrapped unless otherwise specified by the
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// Wrapping Method. The algorithms used for wrapping are given by the Cryptographic Algorithm attributes of
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// the encryption key and/or MAC/signature key; the block-cipher mode, padding method, and hashing algorithm used
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// for wrapping are given by the Cryptographic Parameters in the Encryption Key Information and/or MAC/Signature
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// Key Information, or, if not present, from the Cryptographic Parameters attribute of the respective key(s).
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// Either the Encryption Key Information or the MAC/Signature Key Information (or both) in the Key Wrapping Data
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// structure SHALL be specified.
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//
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// The following wrapping methods are currently defined:
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//
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// · Encrypt only (i.e., encryption using a symmetric key or public key, or authenticated encryption algorithms that use a single key).
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// · MAC/sign only (i.e., either MACing the Key Value with a symmetric key, or signing the Key Value with a private key).
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// · Encrypt then MAC/sign.
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// · MAC/sign then encrypt.
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// · TR-31.
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// · Extensions.
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//
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// The following encoding options are currently defined:
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//
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// · No Encoding (i.e., the wrapped un-encoded value of the Byte String Key Material field in the Key Value structure).
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// · TTLV Encoding (i.e., the wrapped TTLV-encoded Key Value structure).
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type KeyWrappingData struct {
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WrappingMethod kmip14.WrappingMethod
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EncryptionKeyInformation *EncryptionKeyInformation
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MACSignatureKeyInformation *MACSignatureKeyInformation
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MACSignature []byte
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IVCounterNonce []byte
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EncodingOption kmip14.EncodingOption `ttlv:",omitempty" default:"TTLVEncoding"`
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}
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// EncryptionKeyInformation 2.1.5 Table 10
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type EncryptionKeyInformation struct {
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UniqueIdentifier string
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CryptographicParameters *CryptographicParameters
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}
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// MACSignatureKeyInformation 2.1.5 Table 11
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type MACSignatureKeyInformation struct {
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UniqueIdentifier string
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CryptographicParameters *CryptographicParameters
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}
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// TransparentSymmetricKey 2.1.7.1 Table 14
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//
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// If the Key Format Type in the Key Block is Transparent Symmetric Key, then Key Material is a
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// structure as shown in Table 14.
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type TransparentSymmetricKey struct {
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Key []byte `validate:"required"`
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}
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// TransparentDSAPrivateKey 2.1.7.2 Table 15
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//
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// If the Key Format Type in the Key Block is Transparent DSA Private Key, then Key Material is a structure as
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// shown in Table 15.
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type TransparentDSAPrivateKey struct {
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// TODO: should these be pointers? big package deals entirely with pointers, but these are not optional values.
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P *big.Int `validate:"required"`
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Q *big.Int `validate:"required"`
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G *big.Int `validate:"required"`
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X *big.Int `validate:"required"`
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}
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// TransparentDSAPublicKey 2.1.7.3 Table 16
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//
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// If the Key Format Type in the Key Block is Transparent DSA Public Key, then Key Material is a structure as
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// shown in Table 16.
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type TransparentDSAPublicKey struct {
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P *big.Int `validate:"required"`
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Q *big.Int `validate:"required"`
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G *big.Int `validate:"required"`
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Y *big.Int `validate:"required"`
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}
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// TransparentRSAPrivateKey 2.1.7.4 Table 17
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//
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// If the Key Format Type in the Key Block is Transparent RSA Private Key, then Key Material is a structure
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// as shown in Table 17.
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//
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// One of the following SHALL be present (refer to [PKCS#1]):
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//
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// · Private Exponent,
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// · P and Q (the first two prime factors of Modulus), or
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// · Prime Exponent P and Prime Exponent Q.
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type TransparentRSAPrivateKey struct {
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Modulus *big.Int `validate:"required"`
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PrivateExponent, PublicExponent *big.Int
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P, Q *big.Int
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PrimeExponentP, PrimeExponentQ *big.Int
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CRTCoefficient *big.Int
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}
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// TransparentRSAPublicKey 2.1.7.5 Table 18
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//
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// If the Key Format Type in the Key Block is Transparent RSA Public Key, then Key Material is a structure
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// as shown in Table 18.
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type TransparentRSAPublicKey struct {
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Modulus *big.Int `validate:"required"`
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PublicExponent *big.Int `validate:"required"`
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}
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// TransparentDHPrivateKey 2.1.7.6 Table 19
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//
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// If the Key Format Type in the Key Block is Transparent DH Private Key, then Key Material is a structure as shown
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// in Table 19.
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type TransparentDHPrivateKey struct {
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P *big.Int `validate:"required"`
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Q *big.Int
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G *big.Int `validate:"required"`
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J *big.Int
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X *big.Int `validate:"required"`
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}
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// TransparentDHPublicKey 2.1.7.7 Table 20
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//
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// If the Key Format Type in the Key Block is Transparent DH Public Key, then Key Material is a structure as
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// shown in Table 20.
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//
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// P, G, and Y are required.
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type TransparentDHPublicKey struct {
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P *big.Int `validate:"required"`
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Q *big.Int
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G *big.Int `validate:"required"`
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J *big.Int
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Y *big.Int `validate:"required"`
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}
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// TransparentECDSAPrivateKey 2.1.7.8 Table 21
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//
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// The Transparent ECDSA Private Key structure is deprecated as of version 1.3 of this
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// specification and MAY be removed from subsequent versions of the specification. The
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// Transparent EC Private Key structure SHOULD be used as a replacement.
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//
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// If the Key Format Type in the Key Block is Transparent ECDSA Private Key, then Key Material is a
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// structure as shown in Table 21.
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type TransparentECDSAPrivateKey struct {
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RecommendedCurve kmip14.RecommendedCurve
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D *big.Int `validate:"required"`
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}
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// TransparentECDSAPublicKey 2.1.7.9 Table 22
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//
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// The Transparent ECDSA Public Key structure is deprecated as of version 1.3 of this specification and
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// MAY be removed from subsequent versions of the specification. The Transparent EC Public Key structure
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// SHOULD be used as a replacement.
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//
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// If the Key Format Type in the Key Block is Transparent ECDSA Public Key, then Key Material is a
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// structure as shown in Table 22.
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type TransparentECDSAPublicKey struct {
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RecommendedCurve kmip14.RecommendedCurve
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QString []byte `validate:"required"`
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}
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// TransparentECDHPrivateKey 2.1.7.10 Table 23
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//
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// The Transparent ECDH Private Key structure is deprecated as of version 1.3 of this specification and
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// MAY be removed from subsequent versions of the specification. The Transparent EC Private Key structure
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// SHOULD be used as a replacement.
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//
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// If the Key Format Type in the Key Block is Transparent ECDH Private Key, then Key Material is a structure
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// as shown in Table 23.
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type TransparentECDHPrivateKey TransparentECPrivateKey
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// TransparentECDHPublicKey 2.1.7.11 Table 24
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//
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// The Transparent ECDH Public Key structure is deprecated as of version 1.3 of this specification and MAY
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// be removed from subsequent versions of the specification. The Transparent EC Public Key structure SHOULD
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// be used as a replacement.
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//
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// If the Key Format Type in the Key Block is Transparent ECDH Public Key, then Key Material is a structure as
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// shown in Table 24.
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type TransparentECDHPublicKey TransparentECPublicKey
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// TransparentECMQVPrivateKey 2.1.7.12 Table 25
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//
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// The Transparent ECMQV Private Key structure is deprecated as of version 1.3 of this specification and MAY
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// be removed from subsequent versions of the specification. The Transparent EC Private Key structure SHOULD
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// be used as a replacement.
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//
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// If the Key Format Type in the Key Block is Transparent ECMQV Private Key, then Key Material is a structure
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// as shown in Table 25.
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type TransparentECMQVPrivateKey TransparentECPrivateKey
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// TransparentECMQVPublicKey 2.1.7.13 Table 26
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//
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// The Transparent ECMQV Public Key structure is deprecated as of version 1.3 of this specification and MAY be
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// removed from subsequent versions of the specification. The Transparent EC Public Key structure SHOULD be used as
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// a replacement.
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//
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// If the Key Format Type in the Key Block is Transparent ECMQV Public Key, then Key Material is a structure as shown
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// in Table 26.
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type TransparentECMQVPublicKey TransparentECPublicKey
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// TransparentECPrivateKey 2.1.7.14 Table 27
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//
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// If the Key Format Type in the Key Block is Transparent EC Private Key, then Key Material is a structure as shown
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// in Table 27.
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type TransparentECPrivateKey struct {
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RecommendedCurve kmip14.RecommendedCurve
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D *big.Int `validate:"required"`
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}
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// TransparentECPublicKey 2.1.7.15 Table 28
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//
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// If the Key Format Type in the Key Block is Transparent EC Public Key, then Key Material is a structure as
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// shown in Table 28.
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type TransparentECPublicKey struct {
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RecommendedCurve kmip14.RecommendedCurve
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QString []byte `validate:"required"`
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}
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// TemplateAttribute 2.1.8 Table 29
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//
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// The Template Managed Object is deprecated as of version 1.3 of this specification and MAY be removed from
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// subsequent versions of the specification. Individual Attributes SHOULD be used in operations which currently
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// support use of a Name within a Template-Attribute to reference a Template.
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//
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// These structures are used in various operations to provide the desired attribute values and/or template
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// names in the request and to return the actual attribute values in the response.
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//
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// The Template-Attribute, Common Template-Attribute, Private Key Template-Attribute, and Public Key
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// Template-Attribute structures are defined identically as follows:
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// type TemplateAttribute struct {
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// Attribute []Attribute
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// }
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type TemplateAttribute struct {
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Name []Name
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Attribute []Attribute
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}
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// Get returns a reference to the first Attribute in the list matching the name.
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// Returns nil if not found.
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func (t *TemplateAttribute) Get(s string) *Attribute {
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if t == nil {
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return nil
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}
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for i := range t.Attribute {
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if t.Attribute[i].AttributeName == s {
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return &t.Attribute[i]
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}
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}
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return nil
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}
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// GetIdx returns a reference to the Attribute in the list matching the name and index.
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// Returns nil if not found.
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func (t *TemplateAttribute) GetIdx(s string, idx int) *Attribute {
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if t == nil {
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return nil
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}
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for i := range t.Attribute {
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if t.Attribute[i].AttributeName == s && t.Attribute[i].AttributeIndex == idx {
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return &t.Attribute[i]
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}
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}
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return nil
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}
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// GetTag returns a reference to the first Attribute in the list matching the tag.
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// Returns nil if not found.
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func (t *TemplateAttribute) GetTag(tag ttlv.Tag) *Attribute {
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return t.Get(tag.String())
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}
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// GetTagIdx returns a reference to the first Attribute in the list matching the tag and index.
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// Returns nil if not found.
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func (t *TemplateAttribute) GetTagIdx(tag ttlv.Tag, idx int) *Attribute {
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return t.GetIdx(tag.String(), idx)
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}
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func (t *TemplateAttribute) GetAll(s string) []Attribute {
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if t == nil {
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return nil
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}
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var ret []Attribute
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for i := range t.Attribute {
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if t.Attribute[i].AttributeName == s {
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||
ret = append(ret, t.Attribute[i])
|
||
}
|
||
}
|
||
|
||
return ret
|
||
}
|
||
|
||
func (t *TemplateAttribute) Append(tag ttlv.Tag, value interface{}) {
|
||
t.Attribute = append(t.Attribute, NewAttributeFromTag(tag, 0, value))
|
||
}
|
||
|
||
func (t *TemplateAttribute) GetAllTag(tag ttlv.Tag) []Attribute {
|
||
return t.GetAll(tag.String())
|
||
}
|