src/crypto/ecdh/ecdh.go - go - Git at Google

 // Copyright 2022 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 ecdh implements Elliptic Curve Diffie-Hellman over
 // NIST curves and Curve25519.
 package ecdh

 import (
 	"crypto"
 	"crypto/internal/boring"
 	"crypto/subtle"
 	"errors"
 	"io"
 	"sync"
 )

 type Curve interface {
 	// GenerateKey generates a new PrivateKey from rand.
 	GenerateKey(rand io.Reader) (*PrivateKey, error)

 	// NewPrivateKey checks that key is valid and returns a PrivateKey.
 	//
 	// For NIST curves, this follows SEC 1, Version 2.0, Section 2.3.6, which
 	// amounts to decoding the bytes as a fixed length big endian integer and
 	// checking that the result is lower than the order of the curve. The zero
 	// private key is also rejected, as the encoding of the corresponding public
 	// key would be irregular.
 	//
 	// For X25519, this only checks the scalar length.
 	NewPrivateKey(key []byte) (*PrivateKey, error)

 	// NewPublicKey checks that key is valid and returns a PublicKey.
 	//
 	// For NIST curves, this decodes an uncompressed point according to SEC 1,
 	// Version 2.0, Section 2.3.4. Compressed encodings and the point at
 	// infinity are rejected.
 	//
 	// For X25519, this only checks the u-coordinate length. Adversarially
 	// selected public keys can cause ECDH to return an error.
 	NewPublicKey(key []byte) (*PublicKey, error)

 	// ecdh performs a ECDH exchange and returns the shared secret. It's exposed
 	// as the PrivateKey.ECDH method.
 	//
 	// The private method also allow us to expand the ECDH interface with more
 	// methods in the future without breaking backwards compatibility.
 	ecdh(local *PrivateKey, remote *PublicKey) ([]byte, error)

 	// privateKeyToPublicKey converts a PrivateKey to a PublicKey. It's exposed
 	// as the PrivateKey.PublicKey method.
 	//
 	// This method always succeeds: for X25519, the zero key can't be
 	// constructed due to clamping; for NIST curves, it is rejected by
 	// NewPrivateKey.
 	privateKeyToPublicKey(*PrivateKey) *PublicKey
 }

 // PublicKey is an ECDH public key, usually a peer's ECDH share sent over the wire.
 //
 // These keys can be parsed with [crypto/x509.ParsePKIXPublicKey] and encoded
 // with [crypto/x509.MarshalPKIXPublicKey]. For NIST curves, they then need to
 // be converted with [crypto/ecdsa.PublicKey.ECDH] after parsing.
 type PublicKey struct {
 	curve     Curve
 	publicKey []byte
 	boring    *boring.PublicKeyECDH
 }

 // Bytes returns a copy of the encoding of the public key.
 func (k *PublicKey) Bytes() []byte {
 	// Copy the public key to a fixed size buffer that can get allocated on the
 	// caller's stack after inlining.
 	var buf [133]byte
 	return append(buf[:0], k.publicKey...)
 }

 // Equal returns whether x represents the same public key as k.
 //
 // Note that there can be equivalent public keys with different encodings which
 // would return false from this check but behave the same way as inputs to ECDH.
 //
 // This check is performed in constant time as long as the key types and their
 // curve match.
 func (k *PublicKey) Equal(x crypto.PublicKey) bool {
 	xx, ok := x.(*PublicKey)
 	if !ok {
 		return false
 	}
 	return k.curve == xx.curve &&
 		subtle.ConstantTimeCompare(k.publicKey, xx.publicKey) == 1
 }

 func (k *PublicKey) Curve() Curve {
 	return k.curve
 }

 // PrivateKey is an ECDH private key, usually kept secret.
 //
 // These keys can be parsed with [crypto/x509.ParsePKCS8PrivateKey] and encoded
 // with [crypto/x509.MarshalPKCS8PrivateKey]. For NIST curves, they then need to
 // be converted with [crypto/ecdsa.PrivateKey.ECDH] after parsing.
 type PrivateKey struct {
 	curve      Curve
 	privateKey []byte
 	boring     *boring.PrivateKeyECDH
 	// publicKey is set under publicKeyOnce, to allow loading private keys with
 	// NewPrivateKey without having to perform a scalar multiplication.
 	publicKey     *PublicKey
 	publicKeyOnce sync.Once
 }

 // ECDH performs a ECDH exchange and returns the shared secret. The PrivateKey
 // and PublicKey must use the same curve.
 //
 // For NIST curves, this performs ECDH as specified in SEC 1, Version 2.0,
 // Section 3.3.1, and returns the x-coordinate encoded according to SEC 1,
 // Version 2.0, Section 2.3.5. The result is never the point at infinity.
 //
 // For X25519, this performs ECDH as specified in RFC 7748, Section 6.1. If
 // the result is the all-zero value, ECDH returns an error.
 func (k *PrivateKey) ECDH(remote *PublicKey) ([]byte, error) {
 	if k.curve != remote.curve {
 		return nil, errors.New("crypto/ecdh: private key and public key curves do not match")
 	}
 	return k.curve.ecdh(k, remote)
 }

 // Bytes returns a copy of the encoding of the private key.
 func (k *PrivateKey) Bytes() []byte {
 	// Copy the private key to a fixed size buffer that can get allocated on the
 	// caller's stack after inlining.
 	var buf [66]byte
 	return append(buf[:0], k.privateKey...)
 }

 // Equal returns whether x represents the same private key as k.
 //
 // Note that there can be equivalent private keys with different encodings which
 // would return false from this check but behave the same way as inputs to ECDH.
 //
 // This check is performed in constant time as long as the key types and their
 // curve match.
 func (k *PrivateKey) Equal(x crypto.PrivateKey) bool {
 	xx, ok := x.(*PrivateKey)
 	if !ok {
 		return false
 	}
 	return k.curve == xx.curve &&
 		subtle.ConstantTimeCompare(k.privateKey, xx.privateKey) == 1
 }

 func (k *PrivateKey) Curve() Curve {
 	return k.curve
 }

 func (k *PrivateKey) PublicKey() *PublicKey {
 	k.publicKeyOnce.Do(func() {
 		if k.boring != nil {
 			// Because we already checked in NewPrivateKey that the key is valid,
 			// there should not be any possible errors from BoringCrypto,
 			// so we turn the error into a panic.
 			// (We can't return it anyhow.)
 			kpub, err := k.boring.PublicKey()
 			if err != nil {
 				panic("boringcrypto: " + err.Error())
 			}
 			k.publicKey = &PublicKey{
 				curve:     k.curve,
 				publicKey: kpub.Bytes(),
 				boring:    kpub,
 			}
 		} else {
 			k.publicKey = k.curve.privateKeyToPublicKey(k)
 		}
 	})
 	return k.publicKey
 }

 // Public implements the implicit interface of all standard library private
 // keys. See the docs of crypto.PrivateKey.
 func (k *PrivateKey) Public() crypto.PublicKey {
 	return k.PublicKey()
 }
	// Copyright 2022 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 ecdh implements Elliptic Curve Diffie-Hellman over
	// NIST curves and Curve25519.
	package ecdh

	import (
	"crypto"
	"crypto/internal/boring"
	"crypto/subtle"
	"errors"
	"io"
	"sync"
	)

	type Curve interface {
	// GenerateKey generates a new PrivateKey from rand.
	GenerateKey(rand io.Reader) (*PrivateKey, error)

	// NewPrivateKey checks that key is valid and returns a PrivateKey.
	//
	// For NIST curves, this follows SEC 1, Version 2.0, Section 2.3.6, which
	// amounts to decoding the bytes as a fixed length big endian integer and
	// checking that the result is lower than the order of the curve. The zero
	// private key is also rejected, as the encoding of the corresponding public
	// key would be irregular.
	//
	// For X25519, this only checks the scalar length.
	NewPrivateKey(key []byte) (*PrivateKey, error)

	// NewPublicKey checks that key is valid and returns a PublicKey.
	//
	// For NIST curves, this decodes an uncompressed point according to SEC 1,
	// Version 2.0, Section 2.3.4. Compressed encodings and the point at
	// infinity are rejected.
	//
	// For X25519, this only checks the u-coordinate length. Adversarially
	// selected public keys can cause ECDH to return an error.
	NewPublicKey(key []byte) (*PublicKey, error)

	// ecdh performs a ECDH exchange and returns the shared secret. It's exposed
	// as the PrivateKey.ECDH method.
	//
	// The private method also allow us to expand the ECDH interface with more
	// methods in the future without breaking backwards compatibility.
	ecdh(local PrivateKey, remote PublicKey) ([]byte, error)

	// privateKeyToPublicKey converts a PrivateKey to a PublicKey. It's exposed
	// as the PrivateKey.PublicKey method.
	//
	// This method always succeeds: for X25519, the zero key can't be
	// constructed due to clamping; for NIST curves, it is rejected by
	// NewPrivateKey.
	privateKeyToPublicKey(PrivateKey) PublicKey
	}

	// PublicKey is an ECDH public key, usually a peer's ECDH share sent over the wire.
	//
	// These keys can be parsed with [crypto/x509.ParsePKIXPublicKey] and encoded
	// with [crypto/x509.MarshalPKIXPublicKey]. For NIST curves, they then need to
	// be converted with [crypto/ecdsa.PublicKey.ECDH] after parsing.
	type PublicKey struct {
	curve Curve
	publicKey []byte
	boring *boring.PublicKeyECDH
	}

	// Bytes returns a copy of the encoding of the public key.
	func (k *PublicKey) Bytes() []byte {
	// Copy the public key to a fixed size buffer that can get allocated on the
	// caller's stack after inlining.
	var buf [133]byte
	return append(buf[:0], k.publicKey...)
	}

	// Equal returns whether x represents the same public key as k.
	//
	// Note that there can be equivalent public keys with different encodings which
	// would return false from this check but behave the same way as inputs to ECDH.
	//
	// This check is performed in constant time as long as the key types and their
	// curve match.
	func (k *PublicKey) Equal(x crypto.PublicKey) bool {
	xx, ok := x.(*PublicKey)
	if !ok {
	return false
	}
	return k.curve == xx.curve &&
	subtle.ConstantTimeCompare(k.publicKey, xx.publicKey) == 1
	}

	func (k *PublicKey) Curve() Curve {
	return k.curve
	}

	// PrivateKey is an ECDH private key, usually kept secret.
	//
	// These keys can be parsed with [crypto/x509.ParsePKCS8PrivateKey] and encoded
	// with [crypto/x509.MarshalPKCS8PrivateKey]. For NIST curves, they then need to
	// be converted with [crypto/ecdsa.PrivateKey.ECDH] after parsing.
	type PrivateKey struct {
	curve Curve
	privateKey []byte
	boring *boring.PrivateKeyECDH
	// publicKey is set under publicKeyOnce, to allow loading private keys with
	// NewPrivateKey without having to perform a scalar multiplication.
	publicKey *PublicKey
	publicKeyOnce sync.Once
	}

	// ECDH performs a ECDH exchange and returns the shared secret. The PrivateKey
	// and PublicKey must use the same curve.
	//
	// For NIST curves, this performs ECDH as specified in SEC 1, Version 2.0,
	// Section 3.3.1, and returns the x-coordinate encoded according to SEC 1,
	// Version 2.0, Section 2.3.5. The result is never the point at infinity.
	//
	// For X25519, this performs ECDH as specified in RFC 7748, Section 6.1. If
	// the result is the all-zero value, ECDH returns an error.
	func (k PrivateKey) ECDH(remote PublicKey) ([]byte, error) {
	if k.curve != remote.curve {
	return nil, errors.New("crypto/ecdh: private key and public key curves do not match")
	}
	return k.curve.ecdh(k, remote)
	}

	// Bytes returns a copy of the encoding of the private key.
	func (k *PrivateKey) Bytes() []byte {
	// Copy the private key to a fixed size buffer that can get allocated on the
	// caller's stack after inlining.
	var buf [66]byte
	return append(buf[:0], k.privateKey...)
	}

	// Equal returns whether x represents the same private key as k.
	//
	// Note that there can be equivalent private keys with different encodings which
	// would return false from this check but behave the same way as inputs to ECDH.
	//
	// This check is performed in constant time as long as the key types and their
	// curve match.
	func (k *PrivateKey) Equal(x crypto.PrivateKey) bool {
	xx, ok := x.(*PrivateKey)
	if !ok {
	return false
	}
	return k.curve == xx.curve &&
	subtle.ConstantTimeCompare(k.privateKey, xx.privateKey) == 1
	}

	func (k *PrivateKey) Curve() Curve {
	return k.curve
	}

	func (k PrivateKey) PublicKey() PublicKey {
	k.publicKeyOnce.Do(func() {
	if k.boring != nil {
	// Because we already checked in NewPrivateKey that the key is valid,
	// there should not be any possible errors from BoringCrypto,
	// so we turn the error into a panic.
	// (We can't return it anyhow.)
	kpub, err := k.boring.PublicKey()
	if err != nil {
	panic("boringcrypto: " + err.Error())
	}
	k.publicKey = &PublicKey{
	curve: k.curve,
	publicKey: kpub.Bytes(),
	boring: kpub,
	}
	} else {
	k.publicKey = k.curve.privateKeyToPublicKey(k)
	}
	})
	return k.publicKey
	}

	// Public implements the implicit interface of all standard library private
	// keys. See the docs of crypto.PrivateKey.
	func (k *PrivateKey) Public() crypto.PublicKey {
	return k.PublicKey()
	}