go-sample-webpage/vendor/github.com/lestrrat-go/jwx/jwk/okp_gen.go

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2021-11-04 01:14:51 +00:00
// This file is auto-generated. DO NOT EDIT
package jwk
import (
"bytes"
"context"
"crypto/x509"
"fmt"
"sort"
"sync"
"github.com/lestrrat-go/iter/mapiter"
"github.com/lestrrat-go/jwx/internal/base64"
"github.com/lestrrat-go/jwx/internal/iter"
"github.com/lestrrat-go/jwx/internal/json"
"github.com/lestrrat-go/jwx/internal/pool"
"github.com/lestrrat-go/jwx/jwa"
"github.com/pkg/errors"
)
const (
OKPCrvKey = "crv"
OKPDKey = "d"
OKPXKey = "x"
)
type OKPPrivateKey interface {
Key
FromRaw(interface{}) error
Crv() jwa.EllipticCurveAlgorithm
D() []byte
X() []byte
}
type okpPrivateKey struct {
algorithm *string // https://tools.ietf.org/html/rfc7517#section-4.4
crv *jwa.EllipticCurveAlgorithm
d []byte
keyID *string // https://tools.ietf.org/html/rfc7515#section-4.1.4
keyUsage *string // https://tools.ietf.org/html/rfc7517#section-4.2
keyops *KeyOperationList // https://tools.ietf.org/html/rfc7517#section-4.3
x []byte
x509CertChain *CertificateChain // https://tools.ietf.org/html/rfc7515#section-4.1.6
x509CertThumbprint *string // https://tools.ietf.org/html/rfc7515#section-4.1.7
x509CertThumbprintS256 *string // https://tools.ietf.org/html/rfc7515#section-4.1.8
x509URL *string // https://tools.ietf.org/html/rfc7515#section-4.1.5
privateParams map[string]interface{}
mu *sync.RWMutex
dc DecodeCtx
}
func NewOKPPrivateKey() OKPPrivateKey {
return newOKPPrivateKey()
}
func newOKPPrivateKey() *okpPrivateKey {
return &okpPrivateKey{
mu: &sync.RWMutex{},
privateParams: make(map[string]interface{}),
}
}
func (h okpPrivateKey) KeyType() jwa.KeyType {
return jwa.OKP
}
func (h *okpPrivateKey) Algorithm() string {
if h.algorithm != nil {
return *(h.algorithm)
}
return ""
}
func (h *okpPrivateKey) Crv() jwa.EllipticCurveAlgorithm {
if h.crv != nil {
return *(h.crv)
}
return jwa.InvalidEllipticCurve
}
func (h *okpPrivateKey) D() []byte {
return h.d
}
func (h *okpPrivateKey) KeyID() string {
if h.keyID != nil {
return *(h.keyID)
}
return ""
}
func (h *okpPrivateKey) KeyUsage() string {
if h.keyUsage != nil {
return *(h.keyUsage)
}
return ""
}
func (h *okpPrivateKey) KeyOps() KeyOperationList {
if h.keyops != nil {
return *(h.keyops)
}
return nil
}
func (h *okpPrivateKey) X() []byte {
return h.x
}
func (h *okpPrivateKey) X509CertChain() []*x509.Certificate {
if h.x509CertChain != nil {
return h.x509CertChain.Get()
}
return nil
}
func (h *okpPrivateKey) X509CertThumbprint() string {
if h.x509CertThumbprint != nil {
return *(h.x509CertThumbprint)
}
return ""
}
func (h *okpPrivateKey) X509CertThumbprintS256() string {
if h.x509CertThumbprintS256 != nil {
return *(h.x509CertThumbprintS256)
}
return ""
}
func (h *okpPrivateKey) X509URL() string {
if h.x509URL != nil {
return *(h.x509URL)
}
return ""
}
func (h *okpPrivateKey) makePairs() []*HeaderPair {
h.mu.RLock()
defer h.mu.RUnlock()
var pairs []*HeaderPair
pairs = append(pairs, &HeaderPair{Key: "kty", Value: jwa.OKP})
if h.algorithm != nil {
pairs = append(pairs, &HeaderPair{Key: AlgorithmKey, Value: *(h.algorithm)})
}
if h.crv != nil {
pairs = append(pairs, &HeaderPair{Key: OKPCrvKey, Value: *(h.crv)})
}
if h.d != nil {
pairs = append(pairs, &HeaderPair{Key: OKPDKey, Value: h.d})
}
if h.keyID != nil {
pairs = append(pairs, &HeaderPair{Key: KeyIDKey, Value: *(h.keyID)})
}
if h.keyUsage != nil {
pairs = append(pairs, &HeaderPair{Key: KeyUsageKey, Value: *(h.keyUsage)})
}
if h.keyops != nil {
pairs = append(pairs, &HeaderPair{Key: KeyOpsKey, Value: *(h.keyops)})
}
if h.x != nil {
pairs = append(pairs, &HeaderPair{Key: OKPXKey, Value: h.x})
}
if h.x509CertChain != nil {
pairs = append(pairs, &HeaderPair{Key: X509CertChainKey, Value: *(h.x509CertChain)})
}
if h.x509CertThumbprint != nil {
pairs = append(pairs, &HeaderPair{Key: X509CertThumbprintKey, Value: *(h.x509CertThumbprint)})
}
if h.x509CertThumbprintS256 != nil {
pairs = append(pairs, &HeaderPair{Key: X509CertThumbprintS256Key, Value: *(h.x509CertThumbprintS256)})
}
if h.x509URL != nil {
pairs = append(pairs, &HeaderPair{Key: X509URLKey, Value: *(h.x509URL)})
}
for k, v := range h.privateParams {
pairs = append(pairs, &HeaderPair{Key: k, Value: v})
}
return pairs
}
func (h *okpPrivateKey) PrivateParams() map[string]interface{} {
return h.privateParams
}
func (h *okpPrivateKey) Get(name string) (interface{}, bool) {
h.mu.RLock()
defer h.mu.RUnlock()
switch name {
case KeyTypeKey:
return h.KeyType(), true
case AlgorithmKey:
if h.algorithm == nil {
return nil, false
}
return *(h.algorithm), true
case OKPCrvKey:
if h.crv == nil {
return nil, false
}
return *(h.crv), true
case OKPDKey:
if h.d == nil {
return nil, false
}
return h.d, true
case KeyIDKey:
if h.keyID == nil {
return nil, false
}
return *(h.keyID), true
case KeyUsageKey:
if h.keyUsage == nil {
return nil, false
}
return *(h.keyUsage), true
case KeyOpsKey:
if h.keyops == nil {
return nil, false
}
return *(h.keyops), true
case OKPXKey:
if h.x == nil {
return nil, false
}
return h.x, true
case X509CertChainKey:
if h.x509CertChain == nil {
return nil, false
}
return h.x509CertChain.Get(), true
case X509CertThumbprintKey:
if h.x509CertThumbprint == nil {
return nil, false
}
return *(h.x509CertThumbprint), true
case X509CertThumbprintS256Key:
if h.x509CertThumbprintS256 == nil {
return nil, false
}
return *(h.x509CertThumbprintS256), true
case X509URLKey:
if h.x509URL == nil {
return nil, false
}
return *(h.x509URL), true
default:
v, ok := h.privateParams[name]
return v, ok
}
}
func (h *okpPrivateKey) Set(name string, value interface{}) error {
h.mu.Lock()
defer h.mu.Unlock()
return h.setNoLock(name, value)
}
func (h *okpPrivateKey) setNoLock(name string, value interface{}) error {
switch name {
case "kty":
return nil
case AlgorithmKey:
switch v := value.(type) {
case string:
h.algorithm = &v
case fmt.Stringer:
tmp := v.String()
h.algorithm = &tmp
default:
return errors.Errorf(`invalid type for %s key: %T`, AlgorithmKey, value)
}
return nil
case OKPCrvKey:
if v, ok := value.(jwa.EllipticCurveAlgorithm); ok {
h.crv = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, OKPCrvKey, value)
case OKPDKey:
if v, ok := value.([]byte); ok {
h.d = v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, OKPDKey, value)
case KeyIDKey:
if v, ok := value.(string); ok {
h.keyID = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, KeyIDKey, value)
case KeyUsageKey:
switch v := value.(type) {
case KeyUsageType:
switch v {
case ForSignature, ForEncryption:
tmp := v.String()
h.keyUsage = &tmp
default:
return errors.Errorf(`invalid key usage type %s`, v)
}
case string:
h.keyUsage = &v
default:
return errors.Errorf(`invalid key usage type %s`, v)
}
case KeyOpsKey:
var acceptor KeyOperationList
if err := acceptor.Accept(value); err != nil {
return errors.Wrapf(err, `invalid value for %s key`, KeyOpsKey)
}
h.keyops = &acceptor
return nil
case OKPXKey:
if v, ok := value.([]byte); ok {
h.x = v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, OKPXKey, value)
case X509CertChainKey:
var acceptor CertificateChain
if err := acceptor.Accept(value); err != nil {
return errors.Wrapf(err, `invalid value for %s key`, X509CertChainKey)
}
h.x509CertChain = &acceptor
return nil
case X509CertThumbprintKey:
if v, ok := value.(string); ok {
h.x509CertThumbprint = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, X509CertThumbprintKey, value)
case X509CertThumbprintS256Key:
if v, ok := value.(string); ok {
h.x509CertThumbprintS256 = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, X509CertThumbprintS256Key, value)
case X509URLKey:
if v, ok := value.(string); ok {
h.x509URL = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, X509URLKey, value)
default:
if h.privateParams == nil {
h.privateParams = map[string]interface{}{}
}
h.privateParams[name] = value
}
return nil
}
func (k *okpPrivateKey) Remove(key string) error {
k.mu.Lock()
defer k.mu.Unlock()
switch key {
case AlgorithmKey:
k.algorithm = nil
case OKPCrvKey:
k.crv = nil
case OKPDKey:
k.d = nil
case KeyIDKey:
k.keyID = nil
case KeyUsageKey:
k.keyUsage = nil
case KeyOpsKey:
k.keyops = nil
case OKPXKey:
k.x = nil
case X509CertChainKey:
k.x509CertChain = nil
case X509CertThumbprintKey:
k.x509CertThumbprint = nil
case X509CertThumbprintS256Key:
k.x509CertThumbprintS256 = nil
case X509URLKey:
k.x509URL = nil
default:
delete(k.privateParams, key)
}
return nil
}
func (k *okpPrivateKey) Clone() (Key, error) {
return cloneKey(k)
}
func (k *okpPrivateKey) DecodeCtx() DecodeCtx {
k.mu.RLock()
defer k.mu.RUnlock()
return k.dc
}
func (k *okpPrivateKey) SetDecodeCtx(dc DecodeCtx) {
k.mu.Lock()
defer k.mu.Unlock()
k.dc = dc
}
func (h *okpPrivateKey) UnmarshalJSON(buf []byte) error {
h.algorithm = nil
h.crv = nil
h.d = nil
h.keyID = nil
h.keyUsage = nil
h.keyops = nil
h.x = nil
h.x509CertChain = nil
h.x509CertThumbprint = nil
h.x509CertThumbprintS256 = nil
h.x509URL = nil
dec := json.NewDecoder(bytes.NewReader(buf))
LOOP:
for {
tok, err := dec.Token()
if err != nil {
return errors.Wrap(err, `error reading token`)
}
switch tok := tok.(type) {
case json.Delim:
// Assuming we're doing everything correctly, we should ONLY
// get either '{' or '}' here.
if tok == '}' { // End of object
break LOOP
} else if tok != '{' {
return errors.Errorf(`expected '{', but got '%c'`, tok)
}
case string: // Objects can only have string keys
switch tok {
case KeyTypeKey:
val, err := json.ReadNextStringToken(dec)
if err != nil {
return errors.Wrap(err, `error reading token`)
}
if val != jwa.OKP.String() {
return errors.Errorf(`invalid kty value for RSAPublicKey (%s)`, val)
}
case AlgorithmKey:
if err := json.AssignNextStringToken(&h.algorithm, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, AlgorithmKey)
}
case OKPCrvKey:
var decoded jwa.EllipticCurveAlgorithm
if err := dec.Decode(&decoded); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, OKPCrvKey)
}
h.crv = &decoded
case OKPDKey:
if err := json.AssignNextBytesToken(&h.d, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, OKPDKey)
}
case KeyIDKey:
if err := json.AssignNextStringToken(&h.keyID, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, KeyIDKey)
}
case KeyUsageKey:
if err := json.AssignNextStringToken(&h.keyUsage, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, KeyUsageKey)
}
case KeyOpsKey:
var decoded KeyOperationList
if err := dec.Decode(&decoded); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, KeyOpsKey)
}
h.keyops = &decoded
case OKPXKey:
if err := json.AssignNextBytesToken(&h.x, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, OKPXKey)
}
case X509CertChainKey:
var decoded CertificateChain
if err := dec.Decode(&decoded); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509CertChainKey)
}
h.x509CertChain = &decoded
case X509CertThumbprintKey:
if err := json.AssignNextStringToken(&h.x509CertThumbprint, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509CertThumbprintKey)
}
case X509CertThumbprintS256Key:
if err := json.AssignNextStringToken(&h.x509CertThumbprintS256, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509CertThumbprintS256Key)
}
case X509URLKey:
if err := json.AssignNextStringToken(&h.x509URL, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509URLKey)
}
default:
if dc := h.dc; dc != nil {
if localReg := dc.Registry(); localReg != nil {
decoded, err := localReg.Decode(dec, tok)
if err == nil {
h.setNoLock(tok, decoded)
continue
}
}
}
decoded, err := registry.Decode(dec, tok)
if err == nil {
h.setNoLock(tok, decoded)
continue
}
return errors.Wrapf(err, `could not decode field %s`, tok)
}
default:
return errors.Errorf(`invalid token %T`, tok)
}
}
if h.crv == nil {
return errors.Errorf(`required field crv is missing`)
}
if h.d == nil {
return errors.Errorf(`required field d is missing`)
}
if h.x == nil {
return errors.Errorf(`required field x is missing`)
}
return nil
}
func (h okpPrivateKey) MarshalJSON() ([]byte, error) {
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
data := make(map[string]interface{})
fields := make([]string, 0, 11)
for iter := h.Iterate(ctx); iter.Next(ctx); {
pair := iter.Pair()
fields = append(fields, pair.Key.(string))
data[pair.Key.(string)] = pair.Value
}
sort.Strings(fields)
buf := pool.GetBytesBuffer()
defer pool.ReleaseBytesBuffer(buf)
buf.WriteByte('{')
enc := json.NewEncoder(buf)
for i, f := range fields {
if i > 0 {
buf.WriteRune(',')
}
buf.WriteRune('"')
buf.WriteString(f)
buf.WriteString(`":`)
v := data[f]
switch v := v.(type) {
case []byte:
buf.WriteRune('"')
buf.WriteString(base64.EncodeToString(v))
buf.WriteRune('"')
default:
if err := enc.Encode(v); err != nil {
return nil, errors.Wrapf(err, `failed to encode value for field %s`, f)
}
buf.Truncate(buf.Len() - 1)
}
}
buf.WriteByte('}')
ret := make([]byte, buf.Len())
copy(ret, buf.Bytes())
return ret, nil
}
func (h *okpPrivateKey) Iterate(ctx context.Context) HeaderIterator {
pairs := h.makePairs()
ch := make(chan *HeaderPair, len(pairs))
go func(ctx context.Context, ch chan *HeaderPair, pairs []*HeaderPair) {
defer close(ch)
for _, pair := range pairs {
select {
case <-ctx.Done():
return
case ch <- pair:
}
}
}(ctx, ch, pairs)
return mapiter.New(ch)
}
func (h *okpPrivateKey) Walk(ctx context.Context, visitor HeaderVisitor) error {
return iter.WalkMap(ctx, h, visitor)
}
func (h *okpPrivateKey) AsMap(ctx context.Context) (map[string]interface{}, error) {
return iter.AsMap(ctx, h)
}
type OKPPublicKey interface {
Key
FromRaw(interface{}) error
Crv() jwa.EllipticCurveAlgorithm
X() []byte
}
type okpPublicKey struct {
algorithm *string // https://tools.ietf.org/html/rfc7517#section-4.4
crv *jwa.EllipticCurveAlgorithm
keyID *string // https://tools.ietf.org/html/rfc7515#section-4.1.4
keyUsage *string // https://tools.ietf.org/html/rfc7517#section-4.2
keyops *KeyOperationList // https://tools.ietf.org/html/rfc7517#section-4.3
x []byte
x509CertChain *CertificateChain // https://tools.ietf.org/html/rfc7515#section-4.1.6
x509CertThumbprint *string // https://tools.ietf.org/html/rfc7515#section-4.1.7
x509CertThumbprintS256 *string // https://tools.ietf.org/html/rfc7515#section-4.1.8
x509URL *string // https://tools.ietf.org/html/rfc7515#section-4.1.5
privateParams map[string]interface{}
mu *sync.RWMutex
dc DecodeCtx
}
func NewOKPPublicKey() OKPPublicKey {
return newOKPPublicKey()
}
func newOKPPublicKey() *okpPublicKey {
return &okpPublicKey{
mu: &sync.RWMutex{},
privateParams: make(map[string]interface{}),
}
}
func (h okpPublicKey) KeyType() jwa.KeyType {
return jwa.OKP
}
func (h *okpPublicKey) Algorithm() string {
if h.algorithm != nil {
return *(h.algorithm)
}
return ""
}
func (h *okpPublicKey) Crv() jwa.EllipticCurveAlgorithm {
if h.crv != nil {
return *(h.crv)
}
return jwa.InvalidEllipticCurve
}
func (h *okpPublicKey) KeyID() string {
if h.keyID != nil {
return *(h.keyID)
}
return ""
}
func (h *okpPublicKey) KeyUsage() string {
if h.keyUsage != nil {
return *(h.keyUsage)
}
return ""
}
func (h *okpPublicKey) KeyOps() KeyOperationList {
if h.keyops != nil {
return *(h.keyops)
}
return nil
}
func (h *okpPublicKey) X() []byte {
return h.x
}
func (h *okpPublicKey) X509CertChain() []*x509.Certificate {
if h.x509CertChain != nil {
return h.x509CertChain.Get()
}
return nil
}
func (h *okpPublicKey) X509CertThumbprint() string {
if h.x509CertThumbprint != nil {
return *(h.x509CertThumbprint)
}
return ""
}
func (h *okpPublicKey) X509CertThumbprintS256() string {
if h.x509CertThumbprintS256 != nil {
return *(h.x509CertThumbprintS256)
}
return ""
}
func (h *okpPublicKey) X509URL() string {
if h.x509URL != nil {
return *(h.x509URL)
}
return ""
}
func (h *okpPublicKey) makePairs() []*HeaderPair {
h.mu.RLock()
defer h.mu.RUnlock()
var pairs []*HeaderPair
pairs = append(pairs, &HeaderPair{Key: "kty", Value: jwa.OKP})
if h.algorithm != nil {
pairs = append(pairs, &HeaderPair{Key: AlgorithmKey, Value: *(h.algorithm)})
}
if h.crv != nil {
pairs = append(pairs, &HeaderPair{Key: OKPCrvKey, Value: *(h.crv)})
}
if h.keyID != nil {
pairs = append(pairs, &HeaderPair{Key: KeyIDKey, Value: *(h.keyID)})
}
if h.keyUsage != nil {
pairs = append(pairs, &HeaderPair{Key: KeyUsageKey, Value: *(h.keyUsage)})
}
if h.keyops != nil {
pairs = append(pairs, &HeaderPair{Key: KeyOpsKey, Value: *(h.keyops)})
}
if h.x != nil {
pairs = append(pairs, &HeaderPair{Key: OKPXKey, Value: h.x})
}
if h.x509CertChain != nil {
pairs = append(pairs, &HeaderPair{Key: X509CertChainKey, Value: *(h.x509CertChain)})
}
if h.x509CertThumbprint != nil {
pairs = append(pairs, &HeaderPair{Key: X509CertThumbprintKey, Value: *(h.x509CertThumbprint)})
}
if h.x509CertThumbprintS256 != nil {
pairs = append(pairs, &HeaderPair{Key: X509CertThumbprintS256Key, Value: *(h.x509CertThumbprintS256)})
}
if h.x509URL != nil {
pairs = append(pairs, &HeaderPair{Key: X509URLKey, Value: *(h.x509URL)})
}
for k, v := range h.privateParams {
pairs = append(pairs, &HeaderPair{Key: k, Value: v})
}
return pairs
}
func (h *okpPublicKey) PrivateParams() map[string]interface{} {
return h.privateParams
}
func (h *okpPublicKey) Get(name string) (interface{}, bool) {
h.mu.RLock()
defer h.mu.RUnlock()
switch name {
case KeyTypeKey:
return h.KeyType(), true
case AlgorithmKey:
if h.algorithm == nil {
return nil, false
}
return *(h.algorithm), true
case OKPCrvKey:
if h.crv == nil {
return nil, false
}
return *(h.crv), true
case KeyIDKey:
if h.keyID == nil {
return nil, false
}
return *(h.keyID), true
case KeyUsageKey:
if h.keyUsage == nil {
return nil, false
}
return *(h.keyUsage), true
case KeyOpsKey:
if h.keyops == nil {
return nil, false
}
return *(h.keyops), true
case OKPXKey:
if h.x == nil {
return nil, false
}
return h.x, true
case X509CertChainKey:
if h.x509CertChain == nil {
return nil, false
}
return h.x509CertChain.Get(), true
case X509CertThumbprintKey:
if h.x509CertThumbprint == nil {
return nil, false
}
return *(h.x509CertThumbprint), true
case X509CertThumbprintS256Key:
if h.x509CertThumbprintS256 == nil {
return nil, false
}
return *(h.x509CertThumbprintS256), true
case X509URLKey:
if h.x509URL == nil {
return nil, false
}
return *(h.x509URL), true
default:
v, ok := h.privateParams[name]
return v, ok
}
}
func (h *okpPublicKey) Set(name string, value interface{}) error {
h.mu.Lock()
defer h.mu.Unlock()
return h.setNoLock(name, value)
}
func (h *okpPublicKey) setNoLock(name string, value interface{}) error {
switch name {
case "kty":
return nil
case AlgorithmKey:
switch v := value.(type) {
case string:
h.algorithm = &v
case fmt.Stringer:
tmp := v.String()
h.algorithm = &tmp
default:
return errors.Errorf(`invalid type for %s key: %T`, AlgorithmKey, value)
}
return nil
case OKPCrvKey:
if v, ok := value.(jwa.EllipticCurveAlgorithm); ok {
h.crv = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, OKPCrvKey, value)
case KeyIDKey:
if v, ok := value.(string); ok {
h.keyID = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, KeyIDKey, value)
case KeyUsageKey:
switch v := value.(type) {
case KeyUsageType:
switch v {
case ForSignature, ForEncryption:
tmp := v.String()
h.keyUsage = &tmp
default:
return errors.Errorf(`invalid key usage type %s`, v)
}
case string:
h.keyUsage = &v
default:
return errors.Errorf(`invalid key usage type %s`, v)
}
case KeyOpsKey:
var acceptor KeyOperationList
if err := acceptor.Accept(value); err != nil {
return errors.Wrapf(err, `invalid value for %s key`, KeyOpsKey)
}
h.keyops = &acceptor
return nil
case OKPXKey:
if v, ok := value.([]byte); ok {
h.x = v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, OKPXKey, value)
case X509CertChainKey:
var acceptor CertificateChain
if err := acceptor.Accept(value); err != nil {
return errors.Wrapf(err, `invalid value for %s key`, X509CertChainKey)
}
h.x509CertChain = &acceptor
return nil
case X509CertThumbprintKey:
if v, ok := value.(string); ok {
h.x509CertThumbprint = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, X509CertThumbprintKey, value)
case X509CertThumbprintS256Key:
if v, ok := value.(string); ok {
h.x509CertThumbprintS256 = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, X509CertThumbprintS256Key, value)
case X509URLKey:
if v, ok := value.(string); ok {
h.x509URL = &v
return nil
}
return errors.Errorf(`invalid value for %s key: %T`, X509URLKey, value)
default:
if h.privateParams == nil {
h.privateParams = map[string]interface{}{}
}
h.privateParams[name] = value
}
return nil
}
func (k *okpPublicKey) Remove(key string) error {
k.mu.Lock()
defer k.mu.Unlock()
switch key {
case AlgorithmKey:
k.algorithm = nil
case OKPCrvKey:
k.crv = nil
case KeyIDKey:
k.keyID = nil
case KeyUsageKey:
k.keyUsage = nil
case KeyOpsKey:
k.keyops = nil
case OKPXKey:
k.x = nil
case X509CertChainKey:
k.x509CertChain = nil
case X509CertThumbprintKey:
k.x509CertThumbprint = nil
case X509CertThumbprintS256Key:
k.x509CertThumbprintS256 = nil
case X509URLKey:
k.x509URL = nil
default:
delete(k.privateParams, key)
}
return nil
}
func (k *okpPublicKey) Clone() (Key, error) {
return cloneKey(k)
}
func (k *okpPublicKey) DecodeCtx() DecodeCtx {
k.mu.RLock()
defer k.mu.RUnlock()
return k.dc
}
func (k *okpPublicKey) SetDecodeCtx(dc DecodeCtx) {
k.mu.Lock()
defer k.mu.Unlock()
k.dc = dc
}
func (h *okpPublicKey) UnmarshalJSON(buf []byte) error {
h.algorithm = nil
h.crv = nil
h.keyID = nil
h.keyUsage = nil
h.keyops = nil
h.x = nil
h.x509CertChain = nil
h.x509CertThumbprint = nil
h.x509CertThumbprintS256 = nil
h.x509URL = nil
dec := json.NewDecoder(bytes.NewReader(buf))
LOOP:
for {
tok, err := dec.Token()
if err != nil {
return errors.Wrap(err, `error reading token`)
}
switch tok := tok.(type) {
case json.Delim:
// Assuming we're doing everything correctly, we should ONLY
// get either '{' or '}' here.
if tok == '}' { // End of object
break LOOP
} else if tok != '{' {
return errors.Errorf(`expected '{', but got '%c'`, tok)
}
case string: // Objects can only have string keys
switch tok {
case KeyTypeKey:
val, err := json.ReadNextStringToken(dec)
if err != nil {
return errors.Wrap(err, `error reading token`)
}
if val != jwa.OKP.String() {
return errors.Errorf(`invalid kty value for RSAPublicKey (%s)`, val)
}
case AlgorithmKey:
if err := json.AssignNextStringToken(&h.algorithm, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, AlgorithmKey)
}
case OKPCrvKey:
var decoded jwa.EllipticCurveAlgorithm
if err := dec.Decode(&decoded); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, OKPCrvKey)
}
h.crv = &decoded
case KeyIDKey:
if err := json.AssignNextStringToken(&h.keyID, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, KeyIDKey)
}
case KeyUsageKey:
if err := json.AssignNextStringToken(&h.keyUsage, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, KeyUsageKey)
}
case KeyOpsKey:
var decoded KeyOperationList
if err := dec.Decode(&decoded); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, KeyOpsKey)
}
h.keyops = &decoded
case OKPXKey:
if err := json.AssignNextBytesToken(&h.x, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, OKPXKey)
}
case X509CertChainKey:
var decoded CertificateChain
if err := dec.Decode(&decoded); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509CertChainKey)
}
h.x509CertChain = &decoded
case X509CertThumbprintKey:
if err := json.AssignNextStringToken(&h.x509CertThumbprint, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509CertThumbprintKey)
}
case X509CertThumbprintS256Key:
if err := json.AssignNextStringToken(&h.x509CertThumbprintS256, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509CertThumbprintS256Key)
}
case X509URLKey:
if err := json.AssignNextStringToken(&h.x509URL, dec); err != nil {
return errors.Wrapf(err, `failed to decode value for key %s`, X509URLKey)
}
default:
if dc := h.dc; dc != nil {
if localReg := dc.Registry(); localReg != nil {
decoded, err := localReg.Decode(dec, tok)
if err == nil {
h.setNoLock(tok, decoded)
continue
}
}
}
decoded, err := registry.Decode(dec, tok)
if err == nil {
h.setNoLock(tok, decoded)
continue
}
return errors.Wrapf(err, `could not decode field %s`, tok)
}
default:
return errors.Errorf(`invalid token %T`, tok)
}
}
if h.crv == nil {
return errors.Errorf(`required field crv is missing`)
}
if h.x == nil {
return errors.Errorf(`required field x is missing`)
}
return nil
}
func (h okpPublicKey) MarshalJSON() ([]byte, error) {
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
data := make(map[string]interface{})
fields := make([]string, 0, 10)
for iter := h.Iterate(ctx); iter.Next(ctx); {
pair := iter.Pair()
fields = append(fields, pair.Key.(string))
data[pair.Key.(string)] = pair.Value
}
sort.Strings(fields)
buf := pool.GetBytesBuffer()
defer pool.ReleaseBytesBuffer(buf)
buf.WriteByte('{')
enc := json.NewEncoder(buf)
for i, f := range fields {
if i > 0 {
buf.WriteRune(',')
}
buf.WriteRune('"')
buf.WriteString(f)
buf.WriteString(`":`)
v := data[f]
switch v := v.(type) {
case []byte:
buf.WriteRune('"')
buf.WriteString(base64.EncodeToString(v))
buf.WriteRune('"')
default:
if err := enc.Encode(v); err != nil {
return nil, errors.Wrapf(err, `failed to encode value for field %s`, f)
}
buf.Truncate(buf.Len() - 1)
}
}
buf.WriteByte('}')
ret := make([]byte, buf.Len())
copy(ret, buf.Bytes())
return ret, nil
}
func (h *okpPublicKey) Iterate(ctx context.Context) HeaderIterator {
pairs := h.makePairs()
ch := make(chan *HeaderPair, len(pairs))
go func(ctx context.Context, ch chan *HeaderPair, pairs []*HeaderPair) {
defer close(ch)
for _, pair := range pairs {
select {
case <-ctx.Done():
return
case ch <- pair:
}
}
}(ctx, ch, pairs)
return mapiter.New(ch)
}
func (h *okpPublicKey) Walk(ctx context.Context, visitor HeaderVisitor) error {
return iter.WalkMap(ctx, h, visitor)
}
func (h *okpPublicKey) AsMap(ctx context.Context) (map[string]interface{}, error) {
return iter.AsMap(ctx, h)
}