mirror of
https://github.com/ceph/ceph-csi.git
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239 lines
7.8 KiB
Go
239 lines
7.8 KiB
Go
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package jwt
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import (
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"bytes"
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"encoding/base64"
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"encoding/json"
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"fmt"
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"strings"
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)
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type Parser struct {
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// If populated, only these methods will be considered valid.
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validMethods []string
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// Use JSON Number format in JSON decoder.
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useJSONNumber bool
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// Skip claims validation during token parsing.
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skipClaimsValidation bool
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validator *Validator
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decodeStrict bool
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decodePaddingAllowed bool
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}
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// NewParser creates a new Parser with the specified options
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func NewParser(options ...ParserOption) *Parser {
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p := &Parser{
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validator: &Validator{},
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}
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// Loop through our parsing options and apply them
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for _, option := range options {
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option(p)
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}
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return p
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}
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// Parse parses, validates, verifies the signature and returns the parsed token.
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// keyFunc will receive the parsed token and should return the key for validating.
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func (p *Parser) Parse(tokenString string, keyFunc Keyfunc) (*Token, error) {
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return p.ParseWithClaims(tokenString, MapClaims{}, keyFunc)
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}
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// ParseWithClaims parses, validates, and verifies like Parse, but supplies a default object implementing the Claims
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// interface. This provides default values which can be overridden and allows a caller to use their own type, rather
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// than the default MapClaims implementation of Claims.
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//
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// Note: If you provide a custom claim implementation that embeds one of the standard claims (such as RegisteredClaims),
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// make sure that a) you either embed a non-pointer version of the claims or b) if you are using a pointer, allocate the
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// proper memory for it before passing in the overall claims, otherwise you might run into a panic.
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func (p *Parser) ParseWithClaims(tokenString string, claims Claims, keyFunc Keyfunc) (*Token, error) {
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token, parts, err := p.ParseUnverified(tokenString, claims)
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if err != nil {
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return token, err
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}
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// Verify signing method is in the required set
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if p.validMethods != nil {
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var signingMethodValid = false
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var alg = token.Method.Alg()
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for _, m := range p.validMethods {
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if m == alg {
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signingMethodValid = true
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break
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}
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}
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if !signingMethodValid {
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// signing method is not in the listed set
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return token, newError(fmt.Sprintf("signing method %v is invalid", alg), ErrTokenSignatureInvalid)
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}
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}
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// Decode signature
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token.Signature, err = p.DecodeSegment(parts[2])
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if err != nil {
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return token, newError("could not base64 decode signature", ErrTokenMalformed, err)
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}
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text := strings.Join(parts[0:2], ".")
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// Lookup key(s)
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if keyFunc == nil {
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// keyFunc was not provided. short circuiting validation
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return token, newError("no keyfunc was provided", ErrTokenUnverifiable)
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}
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got, err := keyFunc(token)
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if err != nil {
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return token, newError("error while executing keyfunc", ErrTokenUnverifiable, err)
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}
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switch have := got.(type) {
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case VerificationKeySet:
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if len(have.Keys) == 0 {
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return token, newError("keyfunc returned empty verification key set", ErrTokenUnverifiable)
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}
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// Iterate through keys and verify signature, skipping the rest when a match is found.
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// Return the last error if no match is found.
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for _, key := range have.Keys {
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if err = token.Method.Verify(text, token.Signature, key); err == nil {
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break
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}
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}
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default:
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err = token.Method.Verify(text, token.Signature, have)
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}
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if err != nil {
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return token, newError("", ErrTokenSignatureInvalid, err)
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}
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// Validate Claims
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if !p.skipClaimsValidation {
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// Make sure we have at least a default validator
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if p.validator == nil {
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p.validator = NewValidator()
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}
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if err := p.validator.Validate(claims); err != nil {
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return token, newError("", ErrTokenInvalidClaims, err)
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}
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}
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// No errors so far, token is valid.
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token.Valid = true
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return token, nil
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}
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// ParseUnverified parses the token but doesn't validate the signature.
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//
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// WARNING: Don't use this method unless you know what you're doing.
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//
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// It's only ever useful in cases where you know the signature is valid (since it has already
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// been or will be checked elsewhere in the stack) and you want to extract values from it.
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func (p *Parser) ParseUnverified(tokenString string, claims Claims) (token *Token, parts []string, err error) {
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parts = strings.Split(tokenString, ".")
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if len(parts) != 3 {
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return nil, parts, newError("token contains an invalid number of segments", ErrTokenMalformed)
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}
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token = &Token{Raw: tokenString}
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// parse Header
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var headerBytes []byte
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if headerBytes, err = p.DecodeSegment(parts[0]); err != nil {
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return token, parts, newError("could not base64 decode header", ErrTokenMalformed, err)
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}
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if err = json.Unmarshal(headerBytes, &token.Header); err != nil {
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return token, parts, newError("could not JSON decode header", ErrTokenMalformed, err)
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}
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// parse Claims
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token.Claims = claims
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claimBytes, err := p.DecodeSegment(parts[1])
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if err != nil {
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return token, parts, newError("could not base64 decode claim", ErrTokenMalformed, err)
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}
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// If `useJSONNumber` is enabled then we must use *json.Decoder to decode
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// the claims. However, this comes with a performance penalty so only use
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// it if we must and, otherwise, simple use json.Unmarshal.
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if !p.useJSONNumber {
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// JSON Unmarshal. Special case for map type to avoid weird pointer behavior.
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if c, ok := token.Claims.(MapClaims); ok {
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err = json.Unmarshal(claimBytes, &c)
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} else {
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err = json.Unmarshal(claimBytes, &claims)
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}
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} else {
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dec := json.NewDecoder(bytes.NewBuffer(claimBytes))
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dec.UseNumber()
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// JSON Decode. Special case for map type to avoid weird pointer behavior.
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if c, ok := token.Claims.(MapClaims); ok {
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err = dec.Decode(&c)
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} else {
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err = dec.Decode(&claims)
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}
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}
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if err != nil {
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return token, parts, newError("could not JSON decode claim", ErrTokenMalformed, err)
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}
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// Lookup signature method
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if method, ok := token.Header["alg"].(string); ok {
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if token.Method = GetSigningMethod(method); token.Method == nil {
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return token, parts, newError("signing method (alg) is unavailable", ErrTokenUnverifiable)
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}
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} else {
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return token, parts, newError("signing method (alg) is unspecified", ErrTokenUnverifiable)
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}
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return token, parts, nil
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}
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// DecodeSegment decodes a JWT specific base64url encoding. This function will
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// take into account whether the [Parser] is configured with additional options,
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// such as [WithStrictDecoding] or [WithPaddingAllowed].
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func (p *Parser) DecodeSegment(seg string) ([]byte, error) {
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encoding := base64.RawURLEncoding
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if p.decodePaddingAllowed {
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if l := len(seg) % 4; l > 0 {
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seg += strings.Repeat("=", 4-l)
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}
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encoding = base64.URLEncoding
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}
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if p.decodeStrict {
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encoding = encoding.Strict()
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}
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return encoding.DecodeString(seg)
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}
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// Parse parses, validates, verifies the signature and returns the parsed token.
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// keyFunc will receive the parsed token and should return the cryptographic key
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// for verifying the signature. The caller is strongly encouraged to set the
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// WithValidMethods option to validate the 'alg' claim in the token matches the
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// expected algorithm. For more details about the importance of validating the
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// 'alg' claim, see
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// https://auth0.com/blog/critical-vulnerabilities-in-json-web-token-libraries/
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func Parse(tokenString string, keyFunc Keyfunc, options ...ParserOption) (*Token, error) {
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return NewParser(options...).Parse(tokenString, keyFunc)
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}
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// ParseWithClaims is a shortcut for NewParser().ParseWithClaims().
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//
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// Note: If you provide a custom claim implementation that embeds one of the
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// standard claims (such as RegisteredClaims), make sure that a) you either
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// embed a non-pointer version of the claims or b) if you are using a pointer,
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// allocate the proper memory for it before passing in the overall claims,
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// otherwise you might run into a panic.
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func ParseWithClaims(tokenString string, claims Claims, keyFunc Keyfunc, options ...ParserOption) (*Token, error) {
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return NewParser(options...).ParseWithClaims(tokenString, claims, keyFunc)
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}
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