acme/jws.go - crypto - Git at Google

 // Copyright 2015 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package acme

 import (
 	"crypto"
 	"crypto/ecdsa"
 	"crypto/hmac"
 	"crypto/rand"
 	"crypto/rsa"
 	"crypto/sha256"
 	_ "crypto/sha512" // need for EC keys
 	"encoding/asn1"
 	"encoding/base64"
 	"encoding/json"
 	"errors"
 	"fmt"
 	"math/big"
 )

 // KeyID is the account key identity provided by a CA during registration.
 type KeyID string

 // noKeyID indicates that jwsEncodeJSON should compute and use JWK instead of a KID.
 // See jwsEncodeJSON for details.
 const noKeyID = KeyID("")

 // noPayload indicates jwsEncodeJSON will encode zero-length octet string
 // in a JWS request. This is called POST-as-GET in RFC 8555 and is used to make
 // authenticated GET requests via POSTing with an empty payload.
 // See https://tools.ietf.org/html/rfc8555#section-6.3 for more details.
 const noPayload = ""

 // jsonWebSignature can be easily serialized into a JWS following
 // https://tools.ietf.org/html/rfc7515#section-3.2.
 type jsonWebSignature struct {
 	Protected string `json:"protected"`
 	Payload   string `json:"payload"`
 	Sig       string `json:"signature"`
 }

 // jwsEncodeJSON signs claimset using provided key and a nonce.
 // The result is serialized in JSON format containing either kid or jwk
 // fields based on the provided KeyID value.
 //
 // If kid is non-empty, its quoted value is inserted in the protected head
 // as "kid" field value. Otherwise, JWK is computed using jwkEncode and inserted
 // as "jwk" field value. The "jwk" and "kid" fields are mutually exclusive.
 //
 // See https://tools.ietf.org/html/rfc7515#section-7.
 func jwsEncodeJSON(claimset interface{}, key crypto.Signer, kid KeyID, nonce, url string) ([]byte, error) {
 	if key == nil {
 		return nil, errors.New("nil key")
 	}
 	alg, sha := jwsHasher(key.Public())
 	if alg == "" || !sha.Available() {
 		return nil, ErrUnsupportedKey
 	}
 	var phead string
 	switch kid {
 	case noKeyID:
 		jwk, err := jwkEncode(key.Public())
 		if err != nil {
 			return nil, err
 		}
 		phead = fmt.Sprintf(`{"alg":%q,"jwk":%s,"nonce":%q,"url":%q}`, alg, jwk, nonce, url)
 	default:
 		phead = fmt.Sprintf(`{"alg":%q,"kid":%q,"nonce":%q,"url":%q}`, alg, kid, nonce, url)
 	}
 	phead = base64.RawURLEncoding.EncodeToString([]byte(phead))
 	var payload string
 	if claimset != noPayload {
 		cs, err := json.Marshal(claimset)
 		if err != nil {
 			return nil, err
 		}
 		payload = base64.RawURLEncoding.EncodeToString(cs)
 	}
 	hash := sha.New()
 	hash.Write([]byte(phead + "." + payload))
 	sig, err := jwsSign(key, sha, hash.Sum(nil))
 	if err != nil {
 		return nil, err
 	}
 	enc := jsonWebSignature{
 		Protected: phead,
 		Payload:   payload,
 		Sig:       base64.RawURLEncoding.EncodeToString(sig),
 	}
 	return json.Marshal(&enc)
 }

 // jwsWithMAC creates and signs a JWS using the given key and the HS256
 // algorithm. kid and url are included in the protected header. rawPayload
 // should not be base64-URL-encoded.
 func jwsWithMAC(key []byte, kid, url string, rawPayload []byte) (*jsonWebSignature, error) {
 	if len(key) == 0 {
 		return nil, errors.New("acme: cannot sign JWS with an empty MAC key")
 	}
 	header := struct {
 		Algorithm string `json:"alg"`
 		KID       string `json:"kid"`
 		URL       string `json:"url,omitempty"`
 	}{
 		// Only HMAC-SHA256 is supported.
 		Algorithm: "HS256",
 		KID:       kid,
 		URL:       url,
 	}
 	rawProtected, err := json.Marshal(header)
 	if err != nil {
 		return nil, err
 	}
 	protected := base64.RawURLEncoding.EncodeToString(rawProtected)
 	payload := base64.RawURLEncoding.EncodeToString(rawPayload)

 	h := hmac.New(sha256.New, key)
 	if _, err := h.Write([]byte(protected + "." + payload)); err != nil {
 		return nil, err
 	}
 	mac := h.Sum(nil)

 	return &jsonWebSignature{
 		Protected: protected,
 		Payload:   payload,
 		Sig:       base64.RawURLEncoding.EncodeToString(mac),
 	}, nil
 }

 // jwkEncode encodes public part of an RSA or ECDSA key into a JWK.
 // The result is also suitable for creating a JWK thumbprint.
 // https://tools.ietf.org/html/rfc7517
 func jwkEncode(pub crypto.PublicKey) (string, error) {
 	switch pub := pub.(type) {
 	case *rsa.PublicKey:
 		// https://tools.ietf.org/html/rfc7518#section-6.3.1
 		n := pub.N
 		e := big.NewInt(int64(pub.E))
 		// Field order is important.
 		// See https://tools.ietf.org/html/rfc7638#section-3.3 for details.
 		return fmt.Sprintf(`{"e":"%s","kty":"RSA","n":"%s"}`,
 			base64.RawURLEncoding.EncodeToString(e.Bytes()),
 			base64.RawURLEncoding.EncodeToString(n.Bytes()),
 		), nil
 	case *ecdsa.PublicKey:
 		// https://tools.ietf.org/html/rfc7518#section-6.2.1
 		p := pub.Curve.Params()
 		n := p.BitSize / 8
 		if p.BitSize%8 != 0 {
 			n++
 		}
 		x := pub.X.Bytes()
 		if n > len(x) {
 			x = append(make([]byte, n-len(x)), x...)
 		}
 		y := pub.Y.Bytes()
 		if n > len(y) {
 			y = append(make([]byte, n-len(y)), y...)
 		}
 		// Field order is important.
 		// See https://tools.ietf.org/html/rfc7638#section-3.3 for details.
 		return fmt.Sprintf(`{"crv":"%s","kty":"EC","x":"%s","y":"%s"}`,
 			p.Name,
 			base64.RawURLEncoding.EncodeToString(x),
 			base64.RawURLEncoding.EncodeToString(y),
 		), nil
 	}
 	return "", ErrUnsupportedKey
 }

 // jwsSign signs the digest using the given key.
 // The hash is unused for ECDSA keys.
 func jwsSign(key crypto.Signer, hash crypto.Hash, digest []byte) ([]byte, error) {
 	switch pub := key.Public().(type) {
 	case *rsa.PublicKey:
 		return key.Sign(rand.Reader, digest, hash)
 	case *ecdsa.PublicKey:
 		sigASN1, err := key.Sign(rand.Reader, digest, hash)
 		if err != nil {
 			return nil, err
 		}

 		var rs struct{ R, S *big.Int }
 		if _, err := asn1.Unmarshal(sigASN1, &rs); err != nil {
 			return nil, err
 		}

 		rb, sb := rs.R.Bytes(), rs.S.Bytes()
 		size := pub.Params().BitSize / 8
 		if size%8 > 0 {
 			size++
 		}
 		sig := make([]byte, size*2)
 		copy(sig[size-len(rb):], rb)
 		copy(sig[size*2-len(sb):], sb)
 		return sig, nil
 	}
 	return nil, ErrUnsupportedKey
 }

 // jwsHasher indicates suitable JWS algorithm name and a hash function
 // to use for signing a digest with the provided key.
 // It returns ("", 0) if the key is not supported.
 func jwsHasher(pub crypto.PublicKey) (string, crypto.Hash) {
 	switch pub := pub.(type) {
 	case *rsa.PublicKey:
 		return "RS256", crypto.SHA256
 	case *ecdsa.PublicKey:
 		switch pub.Params().Name {
 		case "P-256":
 			return "ES256", crypto.SHA256
 		case "P-384":
 			return "ES384", crypto.SHA384
 		case "P-521":
 			return "ES512", crypto.SHA512
 		}
 	}
 	return "", 0
 }

 // JWKThumbprint creates a JWK thumbprint out of pub
 // as specified in https://tools.ietf.org/html/rfc7638.
 func JWKThumbprint(pub crypto.PublicKey) (string, error) {
 	jwk, err := jwkEncode(pub)
 	if err != nil {
 		return "", err
 	}
 	b := sha256.Sum256([]byte(jwk))
 	return base64.RawURLEncoding.EncodeToString(b[:]), nil
 }
	// Copyright 2015 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package acme

	import (
	"crypto"
	"crypto/ecdsa"
	"crypto/hmac"
	"crypto/rand"
	"crypto/rsa"
	"crypto/sha256"
	_ "crypto/sha512" // need for EC keys
	"encoding/asn1"
	"encoding/base64"
	"encoding/json"
	"errors"
	"fmt"
	"math/big"
	)

	// KeyID is the account key identity provided by a CA during registration.
	type KeyID string

	// noKeyID indicates that jwsEncodeJSON should compute and use JWK instead of a KID.
	// See jwsEncodeJSON for details.
	const noKeyID = KeyID("")

	// noPayload indicates jwsEncodeJSON will encode zero-length octet string
	// in a JWS request. This is called POST-as-GET in RFC 8555 and is used to make
	// authenticated GET requests via POSTing with an empty payload.
	// See https://tools.ietf.org/html/rfc8555#section-6.3 for more details.
	const noPayload = ""

	// jsonWebSignature can be easily serialized into a JWS following
	// https://tools.ietf.org/html/rfc7515#section-3.2.
	type jsonWebSignature struct {
	Protected string `json:"protected"`
	Payload string `json:"payload"`
	Sig string `json:"signature"`
	}

	// jwsEncodeJSON signs claimset using provided key and a nonce.
	// The result is serialized in JSON format containing either kid or jwk
	// fields based on the provided KeyID value.
	//
	// If kid is non-empty, its quoted value is inserted in the protected head
	// as "kid" field value. Otherwise, JWK is computed using jwkEncode and inserted
	// as "jwk" field value. The "jwk" and "kid" fields are mutually exclusive.
	//
	// See https://tools.ietf.org/html/rfc7515#section-7.
	func jwsEncodeJSON(claimset interface{}, key crypto.Signer, kid KeyID, nonce, url string) ([]byte, error) {
	if key == nil {
	return nil, errors.New("nil key")
	}
	alg, sha := jwsHasher(key.Public())
	if alg == "" \|\| !sha.Available() {
	return nil, ErrUnsupportedKey
	}
	var phead string
	switch kid {
	case noKeyID:
	jwk, err := jwkEncode(key.Public())
	if err != nil {
	return nil, err
	}
	phead = fmt.Sprintf(`{"alg":%q,"jwk":%s,"nonce":%q,"url":%q}`, alg, jwk, nonce, url)
	default:
	phead = fmt.Sprintf(`{"alg":%q,"kid":%q,"nonce":%q,"url":%q}`, alg, kid, nonce, url)
	}
	phead = base64.RawURLEncoding.EncodeToString([]byte(phead))
	var payload string
	if claimset != noPayload {
	cs, err := json.Marshal(claimset)
	if err != nil {
	return nil, err
	}
	payload = base64.RawURLEncoding.EncodeToString(cs)
	}
	hash := sha.New()
	hash.Write([]byte(phead + "." + payload))
	sig, err := jwsSign(key, sha, hash.Sum(nil))
	if err != nil {
	return nil, err
	}
	enc := jsonWebSignature{
	Protected: phead,
	Payload: payload,
	Sig: base64.RawURLEncoding.EncodeToString(sig),
	}
	return json.Marshal(&enc)
	}

	// jwsWithMAC creates and signs a JWS using the given key and the HS256
	// algorithm. kid and url are included in the protected header. rawPayload
	// should not be base64-URL-encoded.
	func jwsWithMAC(key []byte, kid, url string, rawPayload []byte) (*jsonWebSignature, error) {
	if len(key) == 0 {
	return nil, errors.New("acme: cannot sign JWS with an empty MAC key")
	}
	header := struct {
	Algorithm string `json:"alg"`
	KID string `json:"kid"`
	URL string `json:"url,omitempty"`
	}{
	// Only HMAC-SHA256 is supported.
	Algorithm: "HS256",
	KID: kid,
	URL: url,
	}
	rawProtected, err := json.Marshal(header)
	if err != nil {
	return nil, err
	}
	protected := base64.RawURLEncoding.EncodeToString(rawProtected)
	payload := base64.RawURLEncoding.EncodeToString(rawPayload)

	h := hmac.New(sha256.New, key)
	if _, err := h.Write([]byte(protected + "." + payload)); err != nil {
	return nil, err
	}
	mac := h.Sum(nil)

	return &jsonWebSignature{
	Protected: protected,
	Payload: payload,
	Sig: base64.RawURLEncoding.EncodeToString(mac),
	}, nil
	}

	// jwkEncode encodes public part of an RSA or ECDSA key into a JWK.
	// The result is also suitable for creating a JWK thumbprint.
	// https://tools.ietf.org/html/rfc7517
	func jwkEncode(pub crypto.PublicKey) (string, error) {
	switch pub := pub.(type) {
	case *rsa.PublicKey:
	// https://tools.ietf.org/html/rfc7518#section-6.3.1
	n := pub.N
	e := big.NewInt(int64(pub.E))
	// Field order is important.
	// See https://tools.ietf.org/html/rfc7638#section-3.3 for details.
	return fmt.Sprintf(`{"e":"%s","kty":"RSA","n":"%s"}`,
	base64.RawURLEncoding.EncodeToString(e.Bytes()),
	base64.RawURLEncoding.EncodeToString(n.Bytes()),
	), nil
	case *ecdsa.PublicKey:
	// https://tools.ietf.org/html/rfc7518#section-6.2.1
	p := pub.Curve.Params()
	n := p.BitSize / 8
	if p.BitSize%8 != 0 {
	n++
	}
	x := pub.X.Bytes()
	if n > len(x) {
	x = append(make([]byte, n-len(x)), x...)
	}
	y := pub.Y.Bytes()
	if n > len(y) {
	y = append(make([]byte, n-len(y)), y...)
	}
	// Field order is important.
	// See https://tools.ietf.org/html/rfc7638#section-3.3 for details.
	return fmt.Sprintf(`{"crv":"%s","kty":"EC","x":"%s","y":"%s"}`,
	p.Name,
	base64.RawURLEncoding.EncodeToString(x),
	base64.RawURLEncoding.EncodeToString(y),
	), nil
	}
	return "", ErrUnsupportedKey
	}

	// jwsSign signs the digest using the given key.
	// The hash is unused for ECDSA keys.
	func jwsSign(key crypto.Signer, hash crypto.Hash, digest []byte) ([]byte, error) {
	switch pub := key.Public().(type) {
	case *rsa.PublicKey:
	return key.Sign(rand.Reader, digest, hash)
	case *ecdsa.PublicKey:
	sigASN1, err := key.Sign(rand.Reader, digest, hash)
	if err != nil {
	return nil, err
	}

	var rs struct{ R, S *big.Int }
	if _, err := asn1.Unmarshal(sigASN1, &rs); err != nil {
	return nil, err
	}

	rb, sb := rs.R.Bytes(), rs.S.Bytes()
	size := pub.Params().BitSize / 8
	if size%8 > 0 {
	size++
	}
	sig := make([]byte, size*2)
	copy(sig[size-len(rb):], rb)
	copy(sig[size*2-len(sb):], sb)
	return sig, nil
	}
	return nil, ErrUnsupportedKey
	}

	// jwsHasher indicates suitable JWS algorithm name and a hash function
	// to use for signing a digest with the provided key.
	// It returns ("", 0) if the key is not supported.
	func jwsHasher(pub crypto.PublicKey) (string, crypto.Hash) {
	switch pub := pub.(type) {
	case *rsa.PublicKey:
	return "RS256", crypto.SHA256
	case *ecdsa.PublicKey:
	switch pub.Params().Name {
	case "P-256":
	return "ES256", crypto.SHA256
	case "P-384":
	return "ES384", crypto.SHA384
	case "P-521":
	return "ES512", crypto.SHA512
	}
	}
	return "", 0
	}

	// JWKThumbprint creates a JWK thumbprint out of pub
	// as specified in https://tools.ietf.org/html/rfc7638.
	func JWKThumbprint(pub crypto.PublicKey) (string, error) {
	jwk, err := jwkEncode(pub)
	if err != nil {
	return "", err
	}
	b := sha256.Sum256([]byte(jwk))
	return base64.RawURLEncoding.EncodeToString(b[:]), nil
	}