src/crypto/tls/boring_test.go - toolchain/go - Git at Google

 // Copyright 2017 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.

 //go:build boringcrypto

 package tls

 import (
 	"crypto/ecdsa"
 	"crypto/elliptic"
 	"crypto/internal/boring/fipstls"
 	"crypto/rand"
 	"crypto/rsa"
 	"crypto/x509"
 	"crypto/x509/pkix"
 	"encoding/pem"
 	"fmt"
 	"internal/obscuretestdata"
 	"math/big"
 	"net"
 	"runtime"
 	"strings"
 	"testing"
 	"time"
 )

 func TestBoringServerProtocolVersion(t *testing.T) {
 	test := func(name string, v uint16, msg string) {
 		t.Run(name, func(t *testing.T) {
 			serverConfig := testConfig.Clone()
 			serverConfig.MinVersion = VersionSSL30
 			clientHello := &clientHelloMsg{
 				vers:               v,
 				random:             make([]byte, 32),
 				cipherSuites:       allCipherSuites(),
 				compressionMethods: []uint8{compressionNone},
 				supportedVersions:  []uint16{v},
 			}
 			testClientHelloFailure(t, serverConfig, clientHello, msg)
 		})
 	}

 	test("VersionTLS10", VersionTLS10, "")
 	test("VersionTLS11", VersionTLS11, "")
 	test("VersionTLS12", VersionTLS12, "")
 	test("VersionTLS13", VersionTLS13, "")

 	fipstls.Force()
 	defer fipstls.Abandon()
 	test("VersionSSL30", VersionSSL30, "client offered only unsupported versions")
 	test("VersionTLS10", VersionTLS10, "client offered only unsupported versions")
 	test("VersionTLS11", VersionTLS11, "client offered only unsupported versions")
 	test("VersionTLS12", VersionTLS12, "")
 	test("VersionTLS13", VersionTLS13, "client offered only unsupported versions")
 }

 func isBoringVersion(v uint16) bool {
 	return v == VersionTLS12
 }

 func isBoringCipherSuite(id uint16) bool {
 	switch id {
 	case TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256,
 		TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384,
 		TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256,
 		TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384,
 		TLS_RSA_WITH_AES_128_GCM_SHA256,
 		TLS_RSA_WITH_AES_256_GCM_SHA384:
 		return true
 	}
 	return false
 }

 func isBoringCurve(id CurveID) bool {
 	switch id {
 	case CurveP256, CurveP384, CurveP521:
 		return true
 	}
 	return false
 }

 func isECDSA(id uint16) bool {
 	for _, suite := range cipherSuites {
 		if suite.id == id {
 			return suite.flags&suiteECSign == suiteECSign
 		}
 	}
 	panic(fmt.Sprintf("unknown cipher suite %#x", id))
 }

 func isBoringSignatureScheme(alg SignatureScheme) bool {
 	switch alg {
 	default:
 		return false
 	case PKCS1WithSHA256,
 		ECDSAWithP256AndSHA256,
 		PKCS1WithSHA384,
 		ECDSAWithP384AndSHA384,
 		PKCS1WithSHA512,
 		ECDSAWithP521AndSHA512,
 		PSSWithSHA256,
 		PSSWithSHA384,
 		PSSWithSHA512:
 		// ok
 	}
 	return true
 }

 func TestBoringServerCipherSuites(t *testing.T) {
 	serverConfig := testConfig.Clone()
 	serverConfig.CipherSuites = allCipherSuites()
 	serverConfig.Certificates = make([]Certificate, 1)

 	for _, id := range allCipherSuites() {
 		if isECDSA(id) {
 			serverConfig.Certificates[0].Certificate = [][]byte{testECDSACertificate}
 			serverConfig.Certificates[0].PrivateKey = testECDSAPrivateKey
 		} else {
 			serverConfig.Certificates[0].Certificate = [][]byte{testRSACertificate}
 			serverConfig.Certificates[0].PrivateKey = testRSAPrivateKey
 		}
 		serverConfig.BuildNameToCertificate()
 		t.Run(fmt.Sprintf("suite=%#x", id), func(t *testing.T) {
 			clientHello := &clientHelloMsg{
 				vers:               VersionTLS12,
 				random:             make([]byte, 32),
 				cipherSuites:       []uint16{id},
 				compressionMethods: []uint8{compressionNone},
 				supportedCurves:    defaultCurvePreferences,
 				supportedPoints:    []uint8{pointFormatUncompressed},
 			}

 			testClientHello(t, serverConfig, clientHello)
 			t.Run("fipstls", func(t *testing.T) {
 				fipstls.Force()
 				defer fipstls.Abandon()
 				msg := ""
 				if !isBoringCipherSuite(id) {
 					msg = "no cipher suite supported by both client and server"
 				}
 				testClientHelloFailure(t, serverConfig, clientHello, msg)
 			})
 		})
 	}
 }

 func TestBoringServerCurves(t *testing.T) {
 	serverConfig := testConfig.Clone()
 	serverConfig.Certificates = make([]Certificate, 1)
 	serverConfig.Certificates[0].Certificate = [][]byte{testECDSACertificate}
 	serverConfig.Certificates[0].PrivateKey = testECDSAPrivateKey
 	serverConfig.BuildNameToCertificate()

 	for _, curveid := range defaultCurvePreferences {
 		t.Run(fmt.Sprintf("curve=%d", curveid), func(t *testing.T) {
 			clientHello := &clientHelloMsg{
 				vers:               VersionTLS12,
 				random:             make([]byte, 32),
 				cipherSuites:       []uint16{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256},
 				compressionMethods: []uint8{compressionNone},
 				supportedCurves:    []CurveID{curveid},
 				supportedPoints:    []uint8{pointFormatUncompressed},
 			}

 			testClientHello(t, serverConfig, clientHello)

 			// With fipstls forced, bad curves should be rejected.
 			t.Run("fipstls", func(t *testing.T) {
 				fipstls.Force()
 				defer fipstls.Abandon()
 				msg := ""
 				if !isBoringCurve(curveid) {
 					msg = "no cipher suite supported by both client and server"
 				}
 				testClientHelloFailure(t, serverConfig, clientHello, msg)
 			})
 		})
 	}
 }

 func boringHandshake(t *testing.T, clientConfig, serverConfig *Config) (clientErr, serverErr error) {
 	c, s := localPipe(t)
 	client := Client(c, clientConfig)
 	server := Server(s, serverConfig)
 	done := make(chan error, 1)
 	go func() {
 		done <- client.Handshake()
 		c.Close()
 	}()
 	serverErr = server.Handshake()
 	s.Close()
 	clientErr = <-done
 	return
 }

 func TestBoringServerSignatureAndHash(t *testing.T) {
 	defer func() {
 		testingOnlyForceClientHelloSignatureAlgorithms = nil
 	}()

 	for _, sigHash := range defaultSupportedSignatureAlgorithms {
 		t.Run(fmt.Sprintf("%v", sigHash), func(t *testing.T) {
 			serverConfig := testConfig.Clone()
 			serverConfig.Certificates = make([]Certificate, 1)

 			testingOnlyForceClientHelloSignatureAlgorithms = []SignatureScheme{sigHash}

 			sigType, _, _ := typeAndHashFromSignatureScheme(sigHash)
 			switch sigType {
 			case signaturePKCS1v15, signatureRSAPSS:
 				serverConfig.CipherSuites = []uint16{TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256}
 				serverConfig.Certificates[0].Certificate = [][]byte{testRSA2048Certificate}
 				serverConfig.Certificates[0].PrivateKey = testRSA2048PrivateKey
 			case signatureEd25519:
 				serverConfig.CipherSuites = []uint16{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256}
 				serverConfig.Certificates[0].Certificate = [][]byte{testEd25519Certificate}
 				serverConfig.Certificates[0].PrivateKey = testEd25519PrivateKey
 			case signatureECDSA:
 				serverConfig.CipherSuites = []uint16{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256}
 				serverConfig.Certificates[0].Certificate = [][]byte{testECDSACertificate}
 				serverConfig.Certificates[0].PrivateKey = testECDSAPrivateKey
 			}
 			serverConfig.BuildNameToCertificate()
 			// PKCS#1 v1.5 signature algorithms can't be used standalone in TLS
 			// 1.3, and the ECDSA ones bind to the curve used.
 			serverConfig.MaxVersion = VersionTLS12

 			clientErr, serverErr := boringHandshake(t, testConfig, serverConfig)
 			if clientErr != nil {
 				t.Fatalf("expected handshake with %#x to succeed; client error: %v; server error: %v", sigHash, clientErr, serverErr)
 			}

 			// With fipstls forced, bad curves should be rejected.
 			t.Run("fipstls", func(t *testing.T) {
 				fipstls.Force()
 				defer fipstls.Abandon()
 				clientErr, _ := boringHandshake(t, testConfig, serverConfig)
 				if isBoringSignatureScheme(sigHash) {
 					if clientErr != nil {
 						t.Fatalf("expected handshake with %#x to succeed; err=%v", sigHash, clientErr)
 					}
 				} else {
 					if clientErr == nil {
 						t.Fatalf("expected handshake with %#x to fail, but it succeeded", sigHash)
 					}
 				}
 			})
 		})
 	}
 }

 func TestBoringClientHello(t *testing.T) {
 	// Test that no matter what we put in the client config,
 	// the client does not offer non-FIPS configurations.
 	fipstls.Force()
 	defer fipstls.Abandon()

 	c, s := net.Pipe()
 	defer c.Close()
 	defer s.Close()

 	clientConfig := testConfig.Clone()
 	// All sorts of traps for the client to avoid.
 	clientConfig.MinVersion = VersionSSL30
 	clientConfig.MaxVersion = VersionTLS13
 	clientConfig.CipherSuites = allCipherSuites()
 	clientConfig.CurvePreferences = defaultCurvePreferences

 	go Client(c, clientConfig).Handshake()
 	srv := Server(s, testConfig)
 	msg, err := srv.readHandshake(nil)
 	if err != nil {
 		t.Fatal(err)
 	}
 	hello, ok := msg.(*clientHelloMsg)
 	if !ok {
 		t.Fatalf("unexpected message type %T", msg)
 	}

 	if !isBoringVersion(hello.vers) {
 		t.Errorf("client vers=%#x, want %#x (TLS 1.2)", hello.vers, VersionTLS12)
 	}
 	for _, v := range hello.supportedVersions {
 		if !isBoringVersion(v) {
 			t.Errorf("client offered disallowed version %#x", v)
 		}
 	}
 	for _, id := range hello.cipherSuites {
 		if !isBoringCipherSuite(id) {
 			t.Errorf("client offered disallowed suite %#x", id)
 		}
 	}
 	for _, id := range hello.supportedCurves {
 		if !isBoringCurve(id) {
 			t.Errorf("client offered disallowed curve %d", id)
 		}
 	}
 	for _, sigHash := range hello.supportedSignatureAlgorithms {
 		if !isBoringSignatureScheme(sigHash) {
 			t.Errorf("client offered disallowed signature-and-hash %v", sigHash)
 		}
 	}
 }

 func TestBoringCertAlgs(t *testing.T) {
 	// NaCl, arm and wasm time out generating keys. Nothing in this test is architecture-specific, so just don't bother on those.
 	if runtime.GOOS == "nacl" || runtime.GOARCH == "arm" || runtime.GOOS == "js" {
 		t.Skipf("skipping on %s/%s because key generation takes too long", runtime.GOOS, runtime.GOARCH)
 	}

 	// Set up some roots, intermediate CAs, and leaf certs with various algorithms.
 	// X_Y is X signed by Y.
 	R1 := boringCert(t, "R1", boringRSAKey(t, 2048), nil, boringCertCA|boringCertFIPSOK)
 	R2 := boringCert(t, "R2", boringRSAKey(t, 512), nil, boringCertCA)

 	M1_R1 := boringCert(t, "M1_R1", boringECDSAKey(t, elliptic.P256()), R1, boringCertCA|boringCertFIPSOK)
 	M2_R1 := boringCert(t, "M2_R1", boringECDSAKey(t, elliptic.P224()), R1, boringCertCA)

 	I_R1 := boringCert(t, "I_R1", boringRSAKey(t, 3072), R1, boringCertCA|boringCertFIPSOK)
 	I_R2 := boringCert(t, "I_R2", I_R1.key, R2, boringCertCA|boringCertFIPSOK)
 	I_M1 := boringCert(t, "I_M1", I_R1.key, M1_R1, boringCertCA|boringCertFIPSOK)
 	I_M2 := boringCert(t, "I_M2", I_R1.key, M2_R1, boringCertCA|boringCertFIPSOK)

 	L1_I := boringCert(t, "L1_I", boringECDSAKey(t, elliptic.P384()), I_R1, boringCertLeaf|boringCertFIPSOK)
 	L2_I := boringCert(t, "L2_I", boringRSAKey(t, 1024), I_R1, boringCertLeaf)

 	// client verifying server cert
 	testServerCert := func(t *testing.T, desc string, pool *x509.CertPool, key interface{}, list [][]byte, ok bool) {
 		clientConfig := testConfig.Clone()
 		clientConfig.RootCAs = pool
 		clientConfig.InsecureSkipVerify = false
 		clientConfig.ServerName = "example.com"

 		serverConfig := testConfig.Clone()
 		serverConfig.Certificates = []Certificate{{Certificate: list, PrivateKey: key}}
 		serverConfig.BuildNameToCertificate()

 		clientErr, _ := boringHandshake(t, clientConfig, serverConfig)

 		if (clientErr == nil) == ok {
 			if ok {
 				t.Logf("%s: accept", desc)
 			} else {
 				t.Logf("%s: reject", desc)
 			}
 		} else {
 			if ok {
 				t.Errorf("%s: BAD reject (%v)", desc, clientErr)
 			} else {
 				t.Errorf("%s: BAD accept", desc)
 			}
 		}
 	}

 	// server verifying client cert
 	testClientCert := func(t *testing.T, desc string, pool *x509.CertPool, key interface{}, list [][]byte, ok bool) {
 		clientConfig := testConfig.Clone()
 		clientConfig.ServerName = "example.com"
 		clientConfig.Certificates = []Certificate{{Certificate: list, PrivateKey: key}}

 		serverConfig := testConfig.Clone()
 		serverConfig.ClientCAs = pool
 		serverConfig.ClientAuth = RequireAndVerifyClientCert

 		_, serverErr := boringHandshake(t, clientConfig, serverConfig)

 		if (serverErr == nil) == ok {
 			if ok {
 				t.Logf("%s: accept", desc)
 			} else {
 				t.Logf("%s: reject", desc)
 			}
 		} else {
 			if ok {
 				t.Errorf("%s: BAD reject (%v)", desc, serverErr)
 			} else {
 				t.Errorf("%s: BAD accept", desc)
 			}
 		}
 	}

 	// Run simple basic test with known answers before proceeding to
 	// exhaustive test with computed answers.
 	r1pool := x509.NewCertPool()
 	r1pool.AddCert(R1.cert)
 	testServerCert(t, "basic", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, true)
 	testClientCert(t, "basic (client cert)", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, true)
 	fipstls.Force()
 	testServerCert(t, "basic (fips)", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, false)
 	testClientCert(t, "basic (fips, client cert)", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, false)
 	fipstls.Abandon()

 	if t.Failed() {
 		t.Fatal("basic test failed, skipping exhaustive test")
 	}

 	if testing.Short() {
 		t.Logf("basic test passed; skipping exhaustive test in -short mode")
 		return
 	}

 	for l := 1; l <= 2; l++ {
 		leaf := L1_I
 		if l == 2 {
 			leaf = L2_I
 		}
 		for i := 0; i < 64; i++ {
 			reachable := map[string]bool{leaf.parentOrg: true}
 			reachableFIPS := map[string]bool{leaf.parentOrg: leaf.fipsOK}
 			list := [][]byte{leaf.der}
 			listName := leaf.name
 			addList := func(cond int, c *boringCertificate) {
 				if cond != 0 {
 					list = append(list, c.der)
 					listName += "," + c.name
 					if reachable[c.org] {
 						reachable[c.parentOrg] = true
 					}
 					if reachableFIPS[c.org] && c.fipsOK {
 						reachableFIPS[c.parentOrg] = true
 					}
 				}
 			}
 			addList(i&1, I_R1)
 			addList(i&2, I_R2)
 			addList(i&4, I_M1)
 			addList(i&8, I_M2)
 			addList(i&16, M1_R1)
 			addList(i&32, M2_R1)

 			for r := 1; r <= 3; r++ {
 				pool := x509.NewCertPool()
 				rootName := ","
 				shouldVerify := false
 				shouldVerifyFIPS := false
 				addRoot := func(cond int, c *boringCertificate) {
 					if cond != 0 {
 						rootName += "," + c.name
 						pool.AddCert(c.cert)
 						if reachable[c.org] {
 							shouldVerify = true
 						}
 						if reachableFIPS[c.org] && c.fipsOK {
 							shouldVerifyFIPS = true
 						}
 					}
 				}
 				addRoot(r&1, R1)
 				addRoot(r&2, R2)
 				rootName = rootName[1:] // strip leading comma
 				testServerCert(t, listName+"->"+rootName[1:], pool, leaf.key, list, shouldVerify)
 				testClientCert(t, listName+"->"+rootName[1:]+"(client cert)", pool, leaf.key, list, shouldVerify)
 				fipstls.Force()
 				testServerCert(t, listName+"->"+rootName[1:]+" (fips)", pool, leaf.key, list, shouldVerifyFIPS)
 				testClientCert(t, listName+"->"+rootName[1:]+" (fips, client cert)", pool, leaf.key, list, shouldVerifyFIPS)
 				fipstls.Abandon()
 			}
 		}
 	}
 }

 const (
 	boringCertCA = iota
 	boringCertLeaf
 	boringCertFIPSOK = 0x80
 )

 func boringRSAKey(t *testing.T, size int) *rsa.PrivateKey {
 	k, err := rsa.GenerateKey(rand.Reader, size)
 	if err != nil {
 		t.Fatal(err)
 	}
 	return k
 }

 func boringECDSAKey(t *testing.T, curve elliptic.Curve) *ecdsa.PrivateKey {
 	k, err := ecdsa.GenerateKey(curve, rand.Reader)
 	if err != nil {
 		t.Fatal(err)
 	}
 	return k
 }

 type boringCertificate struct {
 	name      string
 	org       string
 	parentOrg string
 	der       []byte
 	cert      *x509.Certificate
 	key       interface{}
 	fipsOK    bool
 }

 func boringCert(t *testing.T, name string, key interface{}, parent *boringCertificate, mode int) *boringCertificate {
 	org := name
 	parentOrg := ""
 	if i := strings.Index(org, "_"); i >= 0 {
 		org = org[:i]
 		parentOrg = name[i+1:]
 	}
 	tmpl := &x509.Certificate{
 		SerialNumber: big.NewInt(1),
 		Subject: pkix.Name{
 			Organization: []string{org},
 		},
 		NotBefore: time.Unix(0, 0),
 		NotAfter:  time.Unix(0, 0),

 		KeyUsage:              x509.KeyUsageKeyEncipherment | x509.KeyUsageDigitalSignature,
 		ExtKeyUsage:           []x509.ExtKeyUsage{x509.ExtKeyUsageServerAuth, x509.ExtKeyUsageClientAuth},
 		BasicConstraintsValid: true,
 	}
 	if mode&^boringCertFIPSOK == boringCertLeaf {
 		tmpl.DNSNames = []string{"example.com"}
 	} else {
 		tmpl.IsCA = true
 		tmpl.KeyUsage |= x509.KeyUsageCertSign
 	}

 	var pcert *x509.Certificate
 	var pkey interface{}
 	if parent != nil {
 		pcert = parent.cert
 		pkey = parent.key
 	} else {
 		pcert = tmpl
 		pkey = key
 	}

 	var pub interface{}
 	switch k := key.(type) {
 	case *rsa.PrivateKey:
 		pub = &k.PublicKey
 	case *ecdsa.PrivateKey:
 		pub = &k.PublicKey
 	default:
 		t.Fatalf("invalid key %T", key)
 	}

 	der, err := x509.CreateCertificate(rand.Reader, tmpl, pcert, pub, pkey)
 	if err != nil {
 		t.Fatal(err)
 	}
 	cert, err := x509.ParseCertificate(der)
 	if err != nil {
 		t.Fatal(err)
 	}

 	fipsOK := mode&boringCertFIPSOK != 0
 	return &boringCertificate{name, org, parentOrg, der, cert, key, fipsOK}
 }

 // A self-signed test certificate with an RSA key of size 2048, for testing
 // RSA-PSS with SHA512. SAN of example.golang.
 var (
 	testRSA2048Certificate []byte
 	testRSA2048PrivateKey  *rsa.PrivateKey
 )

 func init() {
 	block, _ := pem.Decode(obscuretestdata.Rot13([]byte(`
 -----ORTVA PREGVSVPNGR-----
 ZVVP/mPPNrrtNjVONtVENYUUK/xu4+4mZH9QnemORpDjQDLWXbMVuipANDRYODNj
 RwRDZN4TN1HRPuZUDJAgMFOQomNrSj0kZGNkZQRkAGN0ZQInSj0lZQRlZwxkAGN0
 ZQInZOVkRQNBOtAIONbGO0SwoJHtD28jttRvZN0TPFdTFVo3QDRONDHNN4VOQjNj
 ttRXNbVONDPs8sx0A6vrPOK4VBIVsXvgg4xTpBDYrvzPsfwddUplfZVITRgSFZ6R
 4Nl141s/7VdqJ0HgVdAo4CKuEBVQ7lQkE284kY6KoPhi/g5uC3HpruLp3uzYvlIq
 ZxMDvMJgsHHWs/1dBgZ+buAt59YEJc4q+6vK0yn1WY3RjPVpxxAwW9uDoS7Co2PF
 +RF9Lb55XNnc8XBoycpE8ZOFA38odajwsDqPKiBRBwnz2UHkXmRSK5ZN+sN0zr4P
 vbPpPEYJXy+TbA9S8sNOsbM+G+2rny4QYhB95eKE8FeBVIOu3KSBe/EIuwgKpAIS
 MXpiQg6q68I6wNXNLXz5ayw9TCcq4i+eNtZONNTwHQOBZN4TN1HqQjRO/jDRNjVS
 bQNGOtAIUFHRQQNXOtteOtRSODpQNGNZOtAIUEZONs8RNwNNZOxTN1HqRDDFZOPP
 QzI4LJ1joTHhM29fLJ5aZN0TPFdTFVo3QDROPjHNN4VONDPBbLfIpSPOuobdr3JU
 qP6I7KKKRPzawu01e8u80li0AE379aFQ3pj2Z+UXinKlfJdey5uwTIXj0igjQ81e
 I4WmQh7VsVbt5z8+DAP+7YdQMfm88iQXBefblFIBzHPtzPXSKrj+YN+rB/vDRWGe
 7rafqqBrKWRc27Rq5iJ+xzJJ3Dztyp2Tjl8jSeZQVdaeaBmON4bPaQRtgKWg0mbt
 aEjosRZNJv1nDEl5qG9XN3FC9zb5FrGSFmTTUvR4f4tUHr7wifNSS2dtgQ6+jU6f
 m9o6fukaP7t5VyOXuV7FIO/Hdg2lqW+xU1LowZpVd6ANZ5rAZXtMhWe3+mjfFtju
 TAnR
 -----RAQ PREGVSVPNGR-----`)))
 	testRSA2048Certificate = block.Bytes

 	block, _ = pem.Decode(obscuretestdata.Rot13([]byte(`
 -----ORTVA EFN CEVINGR XRL-----
 ZVVRcNVONNXPNDRNa/U5AQrbattI+PQyFUlbeorWOaQxP3bcta7V6du3ZeQPSEuY
 EHwBuBNZgrAK/+lXaIgSYFXwJ+Q14HGvN+8t8HqiBZF+y2jee/7rLG91UUbJUA4M
 v4fyKGWTHVzIeK1SPK/9nweGCdVGLBsF0IdrUshby9WJgFF9kZNvUWWQLlsLHTkr
 m29txiuRiJXBrFtTdsPwz5nKRsQNHwq/T6c8V30UDy7muQb2cgu1ZFfkOI+GNCaj
 AWahNbdNaNxF1vcsudQsEsUjNK6Tsx/gazcrNl7wirn10sRdmvSDLq1kGd/0ILL7
 I3QIEJFaYj7rariSrbjPtTPchM5L/Ew6KrY/djVQNDNONbVONDPAcZMvsq/it42u
 UqPiYhMnLF0E7FhaSycbKRfygTqYSfac0VsbWM/htSDOFNVVsYjZhzH6bKN1m7Hi
 98nVLI61QrCeGPQIQSOfUoAzC8WNb8JgohfRojq5mlbO7YLT2+pyxWxyJR73XdHd
 ezV+HWrlFpy2Tva7MGkOKm1JCOx9IjpajxrnKctNFVOJ23suRPZ9taLRRjnOrm5G
 6Zr8q1gUgLDi7ifXr7eb9j9/UXeEKrwdLXX1YkxusSevlI+z8YMWMa2aKBn6T3tS
 Ao8Dx1Hx5CHORAOzlZSWuG4Z/hhFd4LgZeeB2tv8D+sCuhTmp5FfuLXEOc0J4C5e
 zgIPgRSENbTONZRAOVSYeI2+UfTw0kLSnfXbi/DCr6UFGE1Uu2VMBAc+bX4bfmJR
 wOG4IpaVGzcy6gP1Jl4TpekwAtXVSMNw+1k1YHHYqbeKxhT8le0gNuT9mAlsJfFl
 CeFbiP0HIome8Wkkyn+xDIkRDDdJDkCyRIhY8xKnVQN6Ylg1Uchn2YiCNbTONADM
 p6Yd2G7+OkYkAqv2z8xMmrw5xtmOc/KqIfoSJEyroVK2XeSUfeUmG9CHx3QR1iMX
 Z6cmGg94aDuJFxQtPnj1FbuRyW3USVSjphfS1FWNp3cDrcq8ht6VLqycQZYgOw/C
 /5C6OIHgtb05R4+V/G3vLngztyDkGgyM0ExFI2yyNbTONYBKxXSK7nuCis0JxfQu
 hGshSBGCbbjtDT0RctJ0jEqPkrt/WYvp3yFQ0tfggDI2JfErpelJpknryEt10EzB
 38OobtzunS4kitfFihwBsvMGR8bX1G43Z+6AXfVyZY3LVYocH/9nWkCJl0f2QdQe
 pDWuMeyx+cmwON7Oas/HEqjkNbTNXE/PAj14Q+zeY3LYoovPKvlqdkIjki5cqMqm
 8guv3GApfJP4vTHEqpIdosHvaICqWvKr/Xnp3JTPrEWnSItoXNBkYgv1EO5ZxVut
 Q8rlhcOdx4J1Y1txekdfqw4GSykxjZljwy2R2F4LlD8COg6I04QbIEMfVXmdm+CS
 HvbaCd0PtLOPLKidvbWuCrjxBd/L5jeQOrMJ1SDX5DQ9J5Z8/5mkq4eqiWgwuoWc
 bBegiZqey6hcl9Um4OWQ3SKjISvCSR7wdrAdv0S21ivYkOCZZQ3HBQS6YY5RlYvE
 9I4kIZF8XKkit7ekfhdmZCfpIvnJHY6JAIOufQ2+92qUkFKmm5RWXD==
 -----RAQ EFN CEVINGR XRL-----`)))
 	var err error
 	testRSA2048PrivateKey, err = x509.ParsePKCS1PrivateKey(block.Bytes)
 	if err != nil {
 		panic(err)
 	}
 }
	// Copyright 2017 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.

	//go:build boringcrypto

	package tls

	import (
	"crypto/ecdsa"
	"crypto/elliptic"
	"crypto/internal/boring/fipstls"
	"crypto/rand"
	"crypto/rsa"
	"crypto/x509"
	"crypto/x509/pkix"
	"encoding/pem"
	"fmt"
	"internal/obscuretestdata"
	"math/big"
	"net"
	"runtime"
	"strings"
	"testing"
	"time"
	)

	func TestBoringServerProtocolVersion(t *testing.T) {
	test := func(name string, v uint16, msg string) {
	t.Run(name, func(t *testing.T) {
	serverConfig := testConfig.Clone()
	serverConfig.MinVersion = VersionSSL30
	clientHello := &clientHelloMsg{
	vers: v,
	random: make([]byte, 32),
	cipherSuites: allCipherSuites(),
	compressionMethods: []uint8{compressionNone},
	supportedVersions: []uint16{v},
	}
	testClientHelloFailure(t, serverConfig, clientHello, msg)
	})
	}

	test("VersionTLS10", VersionTLS10, "")
	test("VersionTLS11", VersionTLS11, "")
	test("VersionTLS12", VersionTLS12, "")
	test("VersionTLS13", VersionTLS13, "")

	fipstls.Force()
	defer fipstls.Abandon()
	test("VersionSSL30", VersionSSL30, "client offered only unsupported versions")
	test("VersionTLS10", VersionTLS10, "client offered only unsupported versions")
	test("VersionTLS11", VersionTLS11, "client offered only unsupported versions")
	test("VersionTLS12", VersionTLS12, "")
	test("VersionTLS13", VersionTLS13, "client offered only unsupported versions")
	}

	func isBoringVersion(v uint16) bool {
	return v == VersionTLS12
	}

	func isBoringCipherSuite(id uint16) bool {
	switch id {
	case TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256,
	TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384,
	TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256,
	TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384,
	TLS_RSA_WITH_AES_128_GCM_SHA256,
	TLS_RSA_WITH_AES_256_GCM_SHA384:
	return true
	}
	return false
	}

	func isBoringCurve(id CurveID) bool {
	switch id {
	case CurveP256, CurveP384, CurveP521:
	return true
	}
	return false
	}

	func isECDSA(id uint16) bool {
	for _, suite := range cipherSuites {
	if suite.id == id {
	return suite.flags&suiteECSign == suiteECSign
	}
	}
	panic(fmt.Sprintf("unknown cipher suite %#x", id))
	}

	func isBoringSignatureScheme(alg SignatureScheme) bool {
	switch alg {
	default:
	return false
	case PKCS1WithSHA256,
	ECDSAWithP256AndSHA256,
	PKCS1WithSHA384,
	ECDSAWithP384AndSHA384,
	PKCS1WithSHA512,
	ECDSAWithP521AndSHA512,
	PSSWithSHA256,
	PSSWithSHA384,
	PSSWithSHA512:
	// ok
	}
	return true
	}

	func TestBoringServerCipherSuites(t *testing.T) {
	serverConfig := testConfig.Clone()
	serverConfig.CipherSuites = allCipherSuites()
	serverConfig.Certificates = make([]Certificate, 1)

	for _, id := range allCipherSuites() {
	if isECDSA(id) {
	serverConfig.Certificates[0].Certificate = [][]byte{testECDSACertificate}
	serverConfig.Certificates[0].PrivateKey = testECDSAPrivateKey
	} else {
	serverConfig.Certificates[0].Certificate = [][]byte{testRSACertificate}
	serverConfig.Certificates[0].PrivateKey = testRSAPrivateKey
	}
	serverConfig.BuildNameToCertificate()
	t.Run(fmt.Sprintf("suite=%#x", id), func(t *testing.T) {
	clientHello := &clientHelloMsg{
	vers: VersionTLS12,
	random: make([]byte, 32),
	cipherSuites: []uint16{id},
	compressionMethods: []uint8{compressionNone},
	supportedCurves: defaultCurvePreferences,
	supportedPoints: []uint8{pointFormatUncompressed},
	}

	testClientHello(t, serverConfig, clientHello)
	t.Run("fipstls", func(t *testing.T) {
	fipstls.Force()
	defer fipstls.Abandon()
	msg := ""
	if !isBoringCipherSuite(id) {
	msg = "no cipher suite supported by both client and server"
	}
	testClientHelloFailure(t, serverConfig, clientHello, msg)
	})
	})
	}
	}

	func TestBoringServerCurves(t *testing.T) {
	serverConfig := testConfig.Clone()
	serverConfig.Certificates = make([]Certificate, 1)
	serverConfig.Certificates[0].Certificate = [][]byte{testECDSACertificate}
	serverConfig.Certificates[0].PrivateKey = testECDSAPrivateKey
	serverConfig.BuildNameToCertificate()

	for _, curveid := range defaultCurvePreferences {
	t.Run(fmt.Sprintf("curve=%d", curveid), func(t *testing.T) {
	clientHello := &clientHelloMsg{
	vers: VersionTLS12,
	random: make([]byte, 32),
	cipherSuites: []uint16{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256},
	compressionMethods: []uint8{compressionNone},
	supportedCurves: []CurveID{curveid},
	supportedPoints: []uint8{pointFormatUncompressed},
	}

	testClientHello(t, serverConfig, clientHello)

	// With fipstls forced, bad curves should be rejected.
	t.Run("fipstls", func(t *testing.T) {
	fipstls.Force()
	defer fipstls.Abandon()
	msg := ""
	if !isBoringCurve(curveid) {
	msg = "no cipher suite supported by both client and server"
	}
	testClientHelloFailure(t, serverConfig, clientHello, msg)
	})
	})
	}
	}

	func boringHandshake(t testing.T, clientConfig, serverConfig Config) (clientErr, serverErr error) {
	c, s := localPipe(t)
	client := Client(c, clientConfig)
	server := Server(s, serverConfig)
	done := make(chan error, 1)
	go func() {
	done <- client.Handshake()
	c.Close()
	}()
	serverErr = server.Handshake()
	s.Close()
	clientErr = <-done
	return
	}

	func TestBoringServerSignatureAndHash(t *testing.T) {
	defer func() {
	testingOnlyForceClientHelloSignatureAlgorithms = nil
	}()

	for _, sigHash := range defaultSupportedSignatureAlgorithms {
	t.Run(fmt.Sprintf("%v", sigHash), func(t *testing.T) {
	serverConfig := testConfig.Clone()
	serverConfig.Certificates = make([]Certificate, 1)

	testingOnlyForceClientHelloSignatureAlgorithms = []SignatureScheme{sigHash}

	sigType, _, _ := typeAndHashFromSignatureScheme(sigHash)
	switch sigType {
	case signaturePKCS1v15, signatureRSAPSS:
	serverConfig.CipherSuites = []uint16{TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256}
	serverConfig.Certificates[0].Certificate = [][]byte{testRSA2048Certificate}
	serverConfig.Certificates[0].PrivateKey = testRSA2048PrivateKey
	case signatureEd25519:
	serverConfig.CipherSuites = []uint16{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256}
	serverConfig.Certificates[0].Certificate = [][]byte{testEd25519Certificate}
	serverConfig.Certificates[0].PrivateKey = testEd25519PrivateKey
	case signatureECDSA:
	serverConfig.CipherSuites = []uint16{TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256}
	serverConfig.Certificates[0].Certificate = [][]byte{testECDSACertificate}
	serverConfig.Certificates[0].PrivateKey = testECDSAPrivateKey
	}
	serverConfig.BuildNameToCertificate()
	// PKCS#1 v1.5 signature algorithms can't be used standalone in TLS
	// 1.3, and the ECDSA ones bind to the curve used.
	serverConfig.MaxVersion = VersionTLS12

	clientErr, serverErr := boringHandshake(t, testConfig, serverConfig)
	if clientErr != nil {
	t.Fatalf("expected handshake with %#x to succeed; client error: %v; server error: %v", sigHash, clientErr, serverErr)
	}

	// With fipstls forced, bad curves should be rejected.
	t.Run("fipstls", func(t *testing.T) {
	fipstls.Force()
	defer fipstls.Abandon()
	clientErr, _ := boringHandshake(t, testConfig, serverConfig)
	if isBoringSignatureScheme(sigHash) {
	if clientErr != nil {
	t.Fatalf("expected handshake with %#x to succeed; err=%v", sigHash, clientErr)
	}
	} else {
	if clientErr == nil {
	t.Fatalf("expected handshake with %#x to fail, but it succeeded", sigHash)
	}
	}
	})
	})
	}
	}

	func TestBoringClientHello(t *testing.T) {
	// Test that no matter what we put in the client config,
	// the client does not offer non-FIPS configurations.
	fipstls.Force()
	defer fipstls.Abandon()

	c, s := net.Pipe()
	defer c.Close()
	defer s.Close()

	clientConfig := testConfig.Clone()
	// All sorts of traps for the client to avoid.
	clientConfig.MinVersion = VersionSSL30
	clientConfig.MaxVersion = VersionTLS13
	clientConfig.CipherSuites = allCipherSuites()
	clientConfig.CurvePreferences = defaultCurvePreferences

	go Client(c, clientConfig).Handshake()
	srv := Server(s, testConfig)
	msg, err := srv.readHandshake(nil)
	if err != nil {
	t.Fatal(err)
	}
	hello, ok := msg.(*clientHelloMsg)
	if !ok {
	t.Fatalf("unexpected message type %T", msg)
	}

	if !isBoringVersion(hello.vers) {
	t.Errorf("client vers=%#x, want %#x (TLS 1.2)", hello.vers, VersionTLS12)
	}
	for _, v := range hello.supportedVersions {
	if !isBoringVersion(v) {
	t.Errorf("client offered disallowed version %#x", v)
	}
	}
	for _, id := range hello.cipherSuites {
	if !isBoringCipherSuite(id) {
	t.Errorf("client offered disallowed suite %#x", id)
	}
	}
	for _, id := range hello.supportedCurves {
	if !isBoringCurve(id) {
	t.Errorf("client offered disallowed curve %d", id)
	}
	}
	for _, sigHash := range hello.supportedSignatureAlgorithms {
	if !isBoringSignatureScheme(sigHash) {
	t.Errorf("client offered disallowed signature-and-hash %v", sigHash)
	}
	}
	}

	func TestBoringCertAlgs(t *testing.T) {
	// NaCl, arm and wasm time out generating keys. Nothing in this test is architecture-specific, so just don't bother on those.
	if runtime.GOOS == "nacl" \|\| runtime.GOARCH == "arm" \|\| runtime.GOOS == "js" {
	t.Skipf("skipping on %s/%s because key generation takes too long", runtime.GOOS, runtime.GOARCH)
	}

	// Set up some roots, intermediate CAs, and leaf certs with various algorithms.
	// X_Y is X signed by Y.
	R1 := boringCert(t, "R1", boringRSAKey(t, 2048), nil, boringCertCA\|boringCertFIPSOK)
	R2 := boringCert(t, "R2", boringRSAKey(t, 512), nil, boringCertCA)

	M1_R1 := boringCert(t, "M1_R1", boringECDSAKey(t, elliptic.P256()), R1, boringCertCA\|boringCertFIPSOK)
	M2_R1 := boringCert(t, "M2_R1", boringECDSAKey(t, elliptic.P224()), R1, boringCertCA)

	I_R1 := boringCert(t, "I_R1", boringRSAKey(t, 3072), R1, boringCertCA\|boringCertFIPSOK)
	I_R2 := boringCert(t, "I_R2", I_R1.key, R2, boringCertCA\|boringCertFIPSOK)
	I_M1 := boringCert(t, "I_M1", I_R1.key, M1_R1, boringCertCA\|boringCertFIPSOK)
	I_M2 := boringCert(t, "I_M2", I_R1.key, M2_R1, boringCertCA\|boringCertFIPSOK)

	L1_I := boringCert(t, "L1_I", boringECDSAKey(t, elliptic.P384()), I_R1, boringCertLeaf\|boringCertFIPSOK)
	L2_I := boringCert(t, "L2_I", boringRSAKey(t, 1024), I_R1, boringCertLeaf)

	// client verifying server cert
	testServerCert := func(t testing.T, desc string, pool x509.CertPool, key interface{}, list [][]byte, ok bool) {
	clientConfig := testConfig.Clone()
	clientConfig.RootCAs = pool
	clientConfig.InsecureSkipVerify = false
	clientConfig.ServerName = "example.com"

	serverConfig := testConfig.Clone()
	serverConfig.Certificates = []Certificate{{Certificate: list, PrivateKey: key}}
	serverConfig.BuildNameToCertificate()

	clientErr, _ := boringHandshake(t, clientConfig, serverConfig)

	if (clientErr == nil) == ok {
	if ok {
	t.Logf("%s: accept", desc)
	} else {
	t.Logf("%s: reject", desc)
	}
	} else {
	if ok {
	t.Errorf("%s: BAD reject (%v)", desc, clientErr)
	} else {
	t.Errorf("%s: BAD accept", desc)
	}
	}
	}

	// server verifying client cert
	testClientCert := func(t testing.T, desc string, pool x509.CertPool, key interface{}, list [][]byte, ok bool) {
	clientConfig := testConfig.Clone()
	clientConfig.ServerName = "example.com"
	clientConfig.Certificates = []Certificate{{Certificate: list, PrivateKey: key}}

	serverConfig := testConfig.Clone()
	serverConfig.ClientCAs = pool
	serverConfig.ClientAuth = RequireAndVerifyClientCert

	_, serverErr := boringHandshake(t, clientConfig, serverConfig)

	if (serverErr == nil) == ok {
	if ok {
	t.Logf("%s: accept", desc)
	} else {
	t.Logf("%s: reject", desc)
	}
	} else {
	if ok {
	t.Errorf("%s: BAD reject (%v)", desc, serverErr)
	} else {
	t.Errorf("%s: BAD accept", desc)
	}
	}
	}

	// Run simple basic test with known answers before proceeding to
	// exhaustive test with computed answers.
	r1pool := x509.NewCertPool()
	r1pool.AddCert(R1.cert)
	testServerCert(t, "basic", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, true)
	testClientCert(t, "basic (client cert)", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, true)
	fipstls.Force()
	testServerCert(t, "basic (fips)", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, false)
	testClientCert(t, "basic (fips, client cert)", r1pool, L2_I.key, [][]byte{L2_I.der, I_R1.der}, false)
	fipstls.Abandon()

	if t.Failed() {
	t.Fatal("basic test failed, skipping exhaustive test")
	}

	if testing.Short() {
	t.Logf("basic test passed; skipping exhaustive test in -short mode")
	return
	}

	for l := 1; l <= 2; l++ {
	leaf := L1_I
	if l == 2 {
	leaf = L2_I
	}
	for i := 0; i < 64; i++ {
	reachable := map[string]bool{leaf.parentOrg: true}
	reachableFIPS := map[string]bool{leaf.parentOrg: leaf.fipsOK}
	list := [][]byte{leaf.der}
	listName := leaf.name
	addList := func(cond int, c *boringCertificate) {
	if cond != 0 {
	list = append(list, c.der)
	listName += "," + c.name
	if reachable[c.org] {
	reachable[c.parentOrg] = true
	}
	if reachableFIPS[c.org] && c.fipsOK {
	reachableFIPS[c.parentOrg] = true
	}
	}
	}
	addList(i&1, I_R1)
	addList(i&2, I_R2)
	addList(i&4, I_M1)
	addList(i&8, I_M2)
	addList(i&16, M1_R1)
	addList(i&32, M2_R1)

	for r := 1; r <= 3; r++ {
	pool := x509.NewCertPool()
	rootName := ","
	shouldVerify := false
	shouldVerifyFIPS := false
	addRoot := func(cond int, c *boringCertificate) {
	if cond != 0 {
	rootName += "," + c.name
	pool.AddCert(c.cert)
	if reachable[c.org] {
	shouldVerify = true
	}
	if reachableFIPS[c.org] && c.fipsOK {
	shouldVerifyFIPS = true
	}
	}
	}
	addRoot(r&1, R1)
	addRoot(r&2, R2)
	rootName = rootName[1:] // strip leading comma
	testServerCert(t, listName+"->"+rootName[1:], pool, leaf.key, list, shouldVerify)
	testClientCert(t, listName+"->"+rootName[1:]+"(client cert)", pool, leaf.key, list, shouldVerify)
	fipstls.Force()
	testServerCert(t, listName+"->"+rootName[1:]+" (fips)", pool, leaf.key, list, shouldVerifyFIPS)
	testClientCert(t, listName+"->"+rootName[1:]+" (fips, client cert)", pool, leaf.key, list, shouldVerifyFIPS)
	fipstls.Abandon()
	}
	}
	}
	}

	const (
	boringCertCA = iota
	boringCertLeaf
	boringCertFIPSOK = 0x80
	)

	func boringRSAKey(t testing.T, size int) rsa.PrivateKey {
	k, err := rsa.GenerateKey(rand.Reader, size)
	if err != nil {
	t.Fatal(err)
	}
	return k
	}

	func boringECDSAKey(t testing.T, curve elliptic.Curve) ecdsa.PrivateKey {
	k, err := ecdsa.GenerateKey(curve, rand.Reader)
	if err != nil {
	t.Fatal(err)
	}
	return k
	}

	type boringCertificate struct {
	name string
	org string
	parentOrg string
	der []byte
	cert *x509.Certificate
	key interface{}
	fipsOK bool
	}

	func boringCert(t testing.T, name string, key interface{}, parent boringCertificate, mode int) *boringCertificate {
	org := name
	parentOrg := ""
	if i := strings.Index(org, "_"); i >= 0 {
	org = org[:i]
	parentOrg = name[i+1:]
	}
	tmpl := &x509.Certificate{
	SerialNumber: big.NewInt(1),
	Subject: pkix.Name{
	Organization: []string{org},
	},
	NotBefore: time.Unix(0, 0),
	NotAfter: time.Unix(0, 0),

	KeyUsage: x509.KeyUsageKeyEncipherment \| x509.KeyUsageDigitalSignature,
	ExtKeyUsage: []x509.ExtKeyUsage{x509.ExtKeyUsageServerAuth, x509.ExtKeyUsageClientAuth},
	BasicConstraintsValid: true,
	}
	if mode&^boringCertFIPSOK == boringCertLeaf {
	tmpl.DNSNames = []string{"example.com"}
	} else {
	tmpl.IsCA = true
	tmpl.KeyUsage \|= x509.KeyUsageCertSign
	}

	var pcert *x509.Certificate
	var pkey interface{}
	if parent != nil {
	pcert = parent.cert
	pkey = parent.key
	} else {
	pcert = tmpl
	pkey = key
	}

	var pub interface{}
	switch k := key.(type) {
	case *rsa.PrivateKey:
	pub = &k.PublicKey
	case *ecdsa.PrivateKey:
	pub = &k.PublicKey
	default:
	t.Fatalf("invalid key %T", key)
	}

	der, err := x509.CreateCertificate(rand.Reader, tmpl, pcert, pub, pkey)
	if err != nil {
	t.Fatal(err)
	}
	cert, err := x509.ParseCertificate(der)
	if err != nil {
	t.Fatal(err)
	}

	fipsOK := mode&boringCertFIPSOK != 0
	return &boringCertificate{name, org, parentOrg, der, cert, key, fipsOK}
	}

	// A self-signed test certificate with an RSA key of size 2048, for testing
	// RSA-PSS with SHA512. SAN of example.golang.
	var (
	testRSA2048Certificate []byte
	testRSA2048PrivateKey *rsa.PrivateKey
	)

	func init() {
	block, _ := pem.Decode(obscuretestdata.Rot13([]byte(`
	-----ORTVA PREGVSVPNGR-----
	ZVVP/mPPNrrtNjVONtVENYUUK/xu4+4mZH9QnemORpDjQDLWXbMVuipANDRYODNj
	RwRDZN4TN1HRPuZUDJAgMFOQomNrSj0kZGNkZQRkAGN0ZQInSj0lZQRlZwxkAGN0
	ZQInZOVkRQNBOtAIONbGO0SwoJHtD28jttRvZN0TPFdTFVo3QDRONDHNN4VOQjNj
	ttRXNbVONDPs8sx0A6vrPOK4VBIVsXvgg4xTpBDYrvzPsfwddUplfZVITRgSFZ6R
	4Nl141s/7VdqJ0HgVdAo4CKuEBVQ7lQkE284kY6KoPhi/g5uC3HpruLp3uzYvlIq
	ZxMDvMJgsHHWs/1dBgZ+buAt59YEJc4q+6vK0yn1WY3RjPVpxxAwW9uDoS7Co2PF
	+RF9Lb55XNnc8XBoycpE8ZOFA38odajwsDqPKiBRBwnz2UHkXmRSK5ZN+sN0zr4P
	vbPpPEYJXy+TbA9S8sNOsbM+G+2rny4QYhB95eKE8FeBVIOu3KSBe/EIuwgKpAIS
	MXpiQg6q68I6wNXNLXz5ayw9TCcq4i+eNtZONNTwHQOBZN4TN1HqQjRO/jDRNjVS
	bQNGOtAIUFHRQQNXOtteOtRSODpQNGNZOtAIUEZONs8RNwNNZOxTN1HqRDDFZOPP
	QzI4LJ1joTHhM29fLJ5aZN0TPFdTFVo3QDROPjHNN4VONDPBbLfIpSPOuobdr3JU
	qP6I7KKKRPzawu01e8u80li0AE379aFQ3pj2Z+UXinKlfJdey5uwTIXj0igjQ81e
	I4WmQh7VsVbt5z8+DAP+7YdQMfm88iQXBefblFIBzHPtzPXSKrj+YN+rB/vDRWGe
	7rafqqBrKWRc27Rq5iJ+xzJJ3Dztyp2Tjl8jSeZQVdaeaBmON4bPaQRtgKWg0mbt
	aEjosRZNJv1nDEl5qG9XN3FC9zb5FrGSFmTTUvR4f4tUHr7wifNSS2dtgQ6+jU6f
	m9o6fukaP7t5VyOXuV7FIO/Hdg2lqW+xU1LowZpVd6ANZ5rAZXtMhWe3+mjfFtju
	TAnR
	-----RAQ PREGVSVPNGR-----`)))
	testRSA2048Certificate = block.Bytes

	block, _ = pem.Decode(obscuretestdata.Rot13([]byte(`
	-----ORTVA EFN CEVINGR XRL-----
	ZVVRcNVONNXPNDRNa/U5AQrbattI+PQyFUlbeorWOaQxP3bcta7V6du3ZeQPSEuY
	EHwBuBNZgrAK/+lXaIgSYFXwJ+Q14HGvN+8t8HqiBZF+y2jee/7rLG91UUbJUA4M
	v4fyKGWTHVzIeK1SPK/9nweGCdVGLBsF0IdrUshby9WJgFF9kZNvUWWQLlsLHTkr
	m29txiuRiJXBrFtTdsPwz5nKRsQNHwq/T6c8V30UDy7muQb2cgu1ZFfkOI+GNCaj
	AWahNbdNaNxF1vcsudQsEsUjNK6Tsx/gazcrNl7wirn10sRdmvSDLq1kGd/0ILL7
	I3QIEJFaYj7rariSrbjPtTPchM5L/Ew6KrY/djVQNDNONbVONDPAcZMvsq/it42u
	UqPiYhMnLF0E7FhaSycbKRfygTqYSfac0VsbWM/htSDOFNVVsYjZhzH6bKN1m7Hi
	98nVLI61QrCeGPQIQSOfUoAzC8WNb8JgohfRojq5mlbO7YLT2+pyxWxyJR73XdHd
	ezV+HWrlFpy2Tva7MGkOKm1JCOx9IjpajxrnKctNFVOJ23suRPZ9taLRRjnOrm5G
	6Zr8q1gUgLDi7ifXr7eb9j9/UXeEKrwdLXX1YkxusSevlI+z8YMWMa2aKBn6T3tS
	Ao8Dx1Hx5CHORAOzlZSWuG4Z/hhFd4LgZeeB2tv8D+sCuhTmp5FfuLXEOc0J4C5e
	zgIPgRSENbTONZRAOVSYeI2+UfTw0kLSnfXbi/DCr6UFGE1Uu2VMBAc+bX4bfmJR
	wOG4IpaVGzcy6gP1Jl4TpekwAtXVSMNw+1k1YHHYqbeKxhT8le0gNuT9mAlsJfFl
	CeFbiP0HIome8Wkkyn+xDIkRDDdJDkCyRIhY8xKnVQN6Ylg1Uchn2YiCNbTONADM
	p6Yd2G7+OkYkAqv2z8xMmrw5xtmOc/KqIfoSJEyroVK2XeSUfeUmG9CHx3QR1iMX
	Z6cmGg94aDuJFxQtPnj1FbuRyW3USVSjphfS1FWNp3cDrcq8ht6VLqycQZYgOw/C
	/5C6OIHgtb05R4+V/G3vLngztyDkGgyM0ExFI2yyNbTONYBKxXSK7nuCis0JxfQu
	hGshSBGCbbjtDT0RctJ0jEqPkrt/WYvp3yFQ0tfggDI2JfErpelJpknryEt10EzB
	38OobtzunS4kitfFihwBsvMGR8bX1G43Z+6AXfVyZY3LVYocH/9nWkCJl0f2QdQe
	pDWuMeyx+cmwON7Oas/HEqjkNbTNXE/PAj14Q+zeY3LYoovPKvlqdkIjki5cqMqm
	8guv3GApfJP4vTHEqpIdosHvaICqWvKr/Xnp3JTPrEWnSItoXNBkYgv1EO5ZxVut
	Q8rlhcOdx4J1Y1txekdfqw4GSykxjZljwy2R2F4LlD8COg6I04QbIEMfVXmdm+CS
	HvbaCd0PtLOPLKidvbWuCrjxBd/L5jeQOrMJ1SDX5DQ9J5Z8/5mkq4eqiWgwuoWc
	bBegiZqey6hcl9Um4OWQ3SKjISvCSR7wdrAdv0S21ivYkOCZZQ3HBQS6YY5RlYvE
	9I4kIZF8XKkit7ekfhdmZCfpIvnJHY6JAIOufQ2+92qUkFKmm5RWXD==
	-----RAQ EFN CEVINGR XRL-----`)))
	var err error
	testRSA2048PrivateKey, err = x509.ParsePKCS1PrivateKey(block.Bytes)
	if err != nil {
	panic(err)
	}
	}