go-pulse/crypto/ecies/ecies_test.go
obscuren 396f1a0a33 Add 'crypto/ecies/' from commit '7c0f4a9b18d992166452d8cd32caaefd92b26386'
git-subtree-dir: crypto/ecies
git-subtree-mainline: 49a739c8d6
git-subtree-split: 7c0f4a9b18
2015-02-13 23:45:38 +01:00

490 lines
11 KiB
Go

package ecies
import (
"bytes"
"crypto/elliptic"
"crypto/rand"
"crypto/sha256"
"flag"
"fmt"
"io/ioutil"
"testing"
)
var dumpEnc bool
func init() {
flDump := flag.Bool("dump", false, "write encrypted test message to file")
flag.Parse()
dumpEnc = *flDump
}
// Ensure the KDF generates appropriately sized keys.
func TestKDF(t *testing.T) {
msg := []byte("Hello, world")
h := sha256.New()
k, err := concatKDF(h, msg, nil, 64)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if len(k) != 64 {
fmt.Printf("KDF: generated key is the wrong size (%d instead of 64\n",
len(k))
t.FailNow()
}
}
var skLen int
var ErrBadSharedKeys = fmt.Errorf("ecies: shared keys don't match")
// cmpParams compares a set of ECIES parameters. We assume, as per the
// docs, that AES is the only supported symmetric encryption algorithm.
func cmpParams(p1, p2 *ECIESParams) bool {
if p1.hashAlgo != p2.hashAlgo {
return false
} else if p1.KeyLen != p2.KeyLen {
return false
} else if p1.BlockSize != p2.BlockSize {
return false
}
return true
}
// cmpPublic returns true if the two public keys represent the same pojnt.
func cmpPublic(pub1, pub2 PublicKey) bool {
if pub1.X == nil || pub1.Y == nil {
fmt.Println(ErrInvalidPublicKey.Error())
return false
}
if pub2.X == nil || pub2.Y == nil {
fmt.Println(ErrInvalidPublicKey.Error())
return false
}
pub1Out := elliptic.Marshal(pub1.Curve, pub1.X, pub1.Y)
pub2Out := elliptic.Marshal(pub2.Curve, pub2.X, pub2.Y)
return bytes.Equal(pub1Out, pub2Out)
}
// cmpPrivate returns true if the two private keys are the same.
func cmpPrivate(prv1, prv2 *PrivateKey) bool {
if prv1 == nil || prv1.D == nil {
return false
} else if prv2 == nil || prv2.D == nil {
return false
} else if prv1.D.Cmp(prv2.D) != 0 {
return false
} else {
return cmpPublic(prv1.PublicKey, prv2.PublicKey)
}
}
// Validate the ECDH component.
func TestSharedKey(t *testing.T) {
prv1, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
skLen = MaxSharedKeyLength(&prv1.PublicKey) / 2
prv2, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
sk1, err := prv1.GenerateShared(&prv2.PublicKey, skLen, skLen)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
sk2, err := prv2.GenerateShared(&prv1.PublicKey, skLen, skLen)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if !bytes.Equal(sk1, sk2) {
fmt.Println(ErrBadSharedKeys.Error())
t.FailNow()
}
}
// Verify that the key generation code fails when too much key data is
// requested.
func TestTooBigSharedKey(t *testing.T) {
prv1, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
prv2, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
_, err = prv1.GenerateShared(&prv2.PublicKey, skLen*2, skLen*2)
if err != ErrSharedKeyTooBig {
fmt.Println("ecdh: shared key should be too large for curve")
t.FailNow()
}
_, err = prv2.GenerateShared(&prv1.PublicKey, skLen*2, skLen*2)
if err != ErrSharedKeyTooBig {
fmt.Println("ecdh: shared key should be too large for curve")
t.FailNow()
}
}
// Ensure a public key can be successfully marshalled and unmarshalled, and
// that the decoded key is the same as the original.
func TestMarshalPublic(t *testing.T) {
prv, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
out, err := MarshalPublic(&prv.PublicKey)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
pub, err := UnmarshalPublic(out)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if !cmpPublic(prv.PublicKey, *pub) {
fmt.Println("ecies: failed to unmarshal public key")
t.FailNow()
}
}
// Ensure that a private key can be encoded into DER format, and that
// the resulting key is properly parsed back into a public key.
func TestMarshalPrivate(t *testing.T) {
prv, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
out, err := MarshalPrivate(prv)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if dumpEnc {
ioutil.WriteFile("test.out", out, 0644)
}
prv2, err := UnmarshalPrivate(out)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if !cmpPrivate(prv, prv2) {
fmt.Println("ecdh: private key import failed")
t.FailNow()
}
}
// Ensure that a private key can be successfully encoded to PEM format, and
// the resulting key is properly parsed back in.
func TestPrivatePEM(t *testing.T) {
prv, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
out, err := ExportPrivatePEM(prv)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if dumpEnc {
ioutil.WriteFile("test.key", out, 0644)
}
prv2, err := ImportPrivatePEM(out)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
} else if !cmpPrivate(prv, prv2) {
fmt.Println("ecdh: import from PEM failed")
t.FailNow()
}
}
// Ensure that a public key can be successfully encoded to PEM format, and
// the resulting key is properly parsed back in.
func TestPublicPEM(t *testing.T) {
prv, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
out, err := ExportPublicPEM(&prv.PublicKey)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if dumpEnc {
ioutil.WriteFile("test.pem", out, 0644)
}
pub2, err := ImportPublicPEM(out)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
} else if !cmpPublic(prv.PublicKey, *pub2) {
fmt.Println("ecdh: import from PEM failed")
t.FailNow()
}
}
// Benchmark the generation of P256 keys.
func BenchmarkGenerateKeyP256(b *testing.B) {
for i := 0; i < b.N; i++ {
if _, err := GenerateKey(rand.Reader, elliptic.P256(), nil); err != nil {
fmt.Println(err.Error())
b.FailNow()
}
}
}
// Benchmark the generation of P256 shared keys.
func BenchmarkGenSharedKeyP256(b *testing.B) {
prv, err := GenerateKey(rand.Reader, elliptic.P256(), nil)
if err != nil {
fmt.Println(err.Error())
b.FailNow()
}
for i := 0; i < b.N; i++ {
_, err := prv.GenerateShared(&prv.PublicKey, skLen, skLen)
if err != nil {
fmt.Println(err.Error())
b.FailNow()
}
}
}
// Verify that an encrypted message can be successfully decrypted.
func TestEncryptDecrypt(t *testing.T) {
prv1, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
prv2, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
message := []byte("Hello, world.")
ct, err := Encrypt(rand.Reader, &prv2.PublicKey, message, nil, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
pt, err := prv2.Decrypt(rand.Reader, ct, nil, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if !bytes.Equal(pt, message) {
fmt.Println("ecies: plaintext doesn't match message")
t.FailNow()
}
_, err = prv1.Decrypt(rand.Reader, ct, nil, nil)
if err == nil {
fmt.Println("ecies: encryption should not have succeeded")
t.FailNow()
}
}
// TestMarshalEncryption validates the encode/decode produces a valid
// ECIES encryption key.
func TestMarshalEncryption(t *testing.T) {
prv1, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
out, err := MarshalPrivate(prv1)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
prv2, err := UnmarshalPrivate(out)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
message := []byte("Hello, world.")
ct, err := Encrypt(rand.Reader, &prv2.PublicKey, message, nil, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
pt, err := prv2.Decrypt(rand.Reader, ct, nil, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
if !bytes.Equal(pt, message) {
fmt.Println("ecies: plaintext doesn't match message")
t.FailNow()
}
_, err = prv1.Decrypt(rand.Reader, ct, nil, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
}
type testCase struct {
Curve elliptic.Curve
Name string
Expected bool
}
var testCases = []testCase{
testCase{
Curve: elliptic.P224(),
Name: "P224",
Expected: false,
},
testCase{
Curve: elliptic.P256(),
Name: "P256",
Expected: true,
},
testCase{
Curve: elliptic.P384(),
Name: "P384",
Expected: true,
},
testCase{
Curve: elliptic.P521(),
Name: "P521",
Expected: true,
},
}
// Test parameter selection for each curve, and that P224 fails automatic
// parameter selection (see README for a discussion of P224). Ensures that
// selecting a set of parameters automatically for the given curve works.
func TestParamSelection(t *testing.T) {
for _, c := range testCases {
testParamSelection(t, c)
}
}
func testParamSelection(t *testing.T, c testCase) {
params := ParamsFromCurve(c.Curve)
if params == nil && c.Expected {
fmt.Printf("%s (%s)\n", ErrInvalidParams.Error(), c.Name)
t.FailNow()
} else if params != nil && !c.Expected {
fmt.Printf("ecies: parameters should be invalid (%s)\n",
c.Name)
t.FailNow()
}
prv1, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Printf("%s (%s)\n", err.Error(), c.Name)
t.FailNow()
}
prv2, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Printf("%s (%s)\n", err.Error(), c.Name)
t.FailNow()
}
message := []byte("Hello, world.")
ct, err := Encrypt(rand.Reader, &prv2.PublicKey, message, nil, nil)
if err != nil {
fmt.Printf("%s (%s)\n", err.Error(), c.Name)
t.FailNow()
}
pt, err := prv2.Decrypt(rand.Reader, ct, nil, nil)
if err != nil {
fmt.Printf("%s (%s)\n", err.Error(), c.Name)
t.FailNow()
}
if !bytes.Equal(pt, message) {
fmt.Printf("ecies: plaintext doesn't match message (%s)\n",
c.Name)
t.FailNow()
}
_, err = prv1.Decrypt(rand.Reader, ct, nil, nil)
if err == nil {
fmt.Printf("ecies: encryption should not have succeeded (%s)\n",
c.Name)
t.FailNow()
}
}
// Ensure that the basic public key validation in the decryption operation
// works.
func TestBasicKeyValidation(t *testing.T) {
badBytes := []byte{0, 1, 5, 6, 7, 8, 9}
prv, err := GenerateKey(rand.Reader, DefaultCurve, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
message := []byte("Hello, world.")
ct, err := Encrypt(rand.Reader, &prv.PublicKey, message, nil, nil)
if err != nil {
fmt.Println(err.Error())
t.FailNow()
}
for _, b := range badBytes {
ct[0] = b
_, err := prv.Decrypt(rand.Reader, ct, nil, nil)
if err != ErrInvalidPublicKey {
fmt.Println("ecies: validated an invalid key")
t.FailNow()
}
}
}