/* $OpenBSD: wycheproof.go,v 1.19 2018/08/24 17:37:25 tb Exp $ */ /* * Copyright (c) 2018 Joel Sing * Copyright (c) 2018 Theo Buehler * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ // Wycheproof runs test vectors from Project Wycheproof against libcrypto. package main /* #cgo LDFLAGS: -lcrypto #include #include #include #include #include #include #include #include #include #include */ import "C" import ( "bytes" "crypto/sha1" "crypto/sha256" "crypto/sha512" "encoding/hex" "encoding/json" "fmt" "hash" "io/ioutil" "log" "os" "path/filepath" "unsafe" ) const testVectorPath = "/usr/local/share/wycheproof/testvectors" type wycheproofTestGroupChaCha20Poly1305 struct { IVSize int `json:"ivSize"` KeySize int `json:"keySize"` TagSize int `json:"tagSize"` Type string `json:"type"` Tests []*wycheproofTestChaCha20Poly1305 `json:"tests"` } type wycheproofTestChaCha20Poly1305 struct { TCID int `json:"tcId"` Comment string `json:"comment"` Key string `json:"key"` IV string `json:"iv"` AAD string `json:"aad"` Msg string `json:"msg"` CT string `json:"ct"` Tag string `json:"tag"` Result string `json:"result"` Flags []string `json:"flags"` } type wycheproofDSAKey struct { G string `json:"g"` KeySize int `json:"keySize"` P string `json:"p"` Q string `json:"q"` Type string `json:"type"` Y string `json:"y"` } type wycheproofTestDSA struct { TCID int `json:"tcId"` Comment string `json:"comment"` Msg string `json:"msg"` Sig string `json:"sig"` Result string `json:"result"` Flags []string `json:"flags"` } type wycheproofTestGroupDSA struct { Key *wycheproofDSAKey `json:"key"` KeyDER string `json:"keyDer"` KeyPEM string `json:"keyPem"` SHA string `json:"sha"` Type string `json:"type"` Tests []*wycheproofTestDSA `json:"tests"` } type wycheproofECDSAKey struct { Curve string `json:"curve"` KeySize int `json:"keySize"` Type string `json:"type"` Uncompressed string `json:"uncompressed"` WX string `json:"wx"` WY string `json:"wy"` } type wycheproofTestECDSA struct { TCID int `json:"tcId"` Comment string `json:"comment"` Msg string `json:"msg"` Sig string `json:"sig"` Result string `json:"result"` Flags []string `json:"flags"` } type wycheproofTestGroupECDSA struct { Key *wycheproofECDSAKey `json:"key"` KeyDER string `json:"keyDer"` KeyPEM string `json:"keyPem"` SHA string `json:"sha"` Type string `json:"type"` Tests []*wycheproofTestECDSA `json:"tests"` } type wycheproofTestRSA struct { TCID int `json:"tcId"` Comment string `json:"comment"` Msg string `json:"msg"` Sig string `json:"sig"` Padding string `json:"padding"` Result string `json:"result"` Flags []string `json:"flags"` } type wycheproofTestGroupRSA struct { E string `json:"e"` KeyASN string `json:"keyAsn"` KeyDER string `json:"keyDer"` KeyPEM string `json:"keyPem"` KeySize int `json:"keysize"` N string `json:"n"` SHA string `json:"sha"` Type string `json:"type"` Tests []*wycheproofTestRSA `json:"tests"` } type wycheproofTestX25519 struct { TCID int `json:"tcId"` Comment string `json:"comment"` Curve string `json:"curve"` Public string `json:"public"` Private string `json:"private"` Shared string `json:"shared"` Result string `json:"result"` Flags []string `json:"flags"` } type wycheproofTestGroupX25519 struct { Curve string `json:"curve"` Tests []*wycheproofTestX25519 `json:"tests"` } type wycheproofTestVectors struct { Algorithm string `json:"algorithm"` GeneratorVersion string `json:"generatorVersion"` Notes map[string]string `json:"notes"` NumberOfTests int `json:"numberOfTests"` // Header TestGroups []json.RawMessage `json:"testGroups"` } var nids = map[string]int{ "brainpoolP224r1": C.NID_brainpoolP224r1, "brainpoolP256r1": C.NID_brainpoolP256r1, "brainpoolP320r1": C.NID_brainpoolP320r1, "brainpoolP384r1": C.NID_brainpoolP384r1, "brainpoolP512r1": C.NID_brainpoolP512r1, "brainpoolP224t1": C.NID_brainpoolP224t1, "brainpoolP256t1": C.NID_brainpoolP256t1, "brainpoolP320t1": C.NID_brainpoolP320t1, "brainpoolP384t1": C.NID_brainpoolP384t1, "brainpoolP512t1": C.NID_brainpoolP512t1, "secp224r1": C.NID_secp224r1, "secp256k1": C.NID_secp256k1, "secp384r1": C.NID_secp384r1, "secp521r1": C.NID_secp521r1, "SHA-1": C.NID_sha1, "SHA-224": C.NID_sha224, "SHA-256": C.NID_sha256, "SHA-384": C.NID_sha384, "SHA-512": C.NID_sha512, } func nidFromString(ns string) (int, error) { nid, ok := nids[ns] if ok { return nid, nil } return -1, fmt.Errorf("unknown NID %q", ns) } func hashFromString(hs string) (hash.Hash, error) { switch hs { case "SHA-1": return sha1.New(), nil case "SHA-224": return sha256.New224(), nil case "SHA-256": return sha256.New(), nil case "SHA-384": return sha512.New384(), nil case "SHA-512": return sha512.New(), nil default: return nil, fmt.Errorf("unknown hash %q", hs) } } func checkChaCha20Poly1305Open(ctx *C.EVP_AEAD_CTX, iv []byte, ivLen int, aad []byte, aadLen int, msg []byte, msgLen int, ct []byte, ctLen int, tag []byte, tagLen int, wt *wycheproofTestChaCha20Poly1305) bool { maxOutLen := ctLen + tagLen opened := make([]byte, maxOutLen) var openedMsgLen C.size_t catCtTag := append(ct, tag...) openRet := C.EVP_AEAD_CTX_open(ctx, (*C.uint8_t)(unsafe.Pointer(&opened[0])), (*C.size_t)(unsafe.Pointer(&openedMsgLen)), C.size_t(maxOutLen), (*C.uint8_t)(unsafe.Pointer(&iv[0])), C.size_t(ivLen), (*C.uint8_t)(unsafe.Pointer(&catCtTag[0])), C.size_t(len(catCtTag)), (*C.uint8_t)(unsafe.Pointer(&aad[0])), C.size_t(aadLen)) if openRet != 1 { if wt.Result == "invalid" { return true } fmt.Printf("FAIL: Test case %d (%q) - EVP_AEAD_CTX_open() = %d, want %v\n", wt.TCID, wt.Comment, int(openRet), wt.Result) return wt.Result == "invalid" } if (openedMsgLen != C.size_t(msgLen)) { fmt.Printf("FAIL: Test case %d (%q) - open length mismatch: got %d, want %d\n", wt.TCID, wt.Comment, openedMsgLen, msgLen) return false } openedMsg := opened[0:openedMsgLen] if (msgLen == 0) { msg = nil } success := false if (bytes.Equal(openedMsg, msg)) || wt.Result == "invalid" { success = true } else { fmt.Printf("FAIL: Test case %d (%q) - EVP_AEAD_CTX_open() = %d, msg match: %t; want %v\n", wt.TCID, wt.Comment, int(openRet), bytes.Equal(openedMsg, msg), wt.Result) } return success } func checkChaCha20Poly1305Seal(ctx *C.EVP_AEAD_CTX, iv []byte, ivLen int, aad []byte, aadLen int, msg []byte, msgLen int, ct []byte, ctLen int, tag []byte, tagLen int, wt *wycheproofTestChaCha20Poly1305) bool { maxOutLen := msgLen + tagLen sealed := make([]byte, maxOutLen) var sealedLen C.size_t sealRet := C.EVP_AEAD_CTX_seal(ctx, (*C.uint8_t)(unsafe.Pointer(&sealed[0])), (*C.size_t)(unsafe.Pointer(&sealedLen)), C.size_t(maxOutLen), (*C.uint8_t)(unsafe.Pointer(&iv[0])), C.size_t(ivLen), (*C.uint8_t)(unsafe.Pointer(&msg[0])), C.size_t(msgLen), (*C.uint8_t)(unsafe.Pointer(&aad[0])), C.size_t(aadLen)) if sealRet != 1 { fmt.Printf("FAIL: Test case %d (%q) - EVP_AEAD_CTX_seal() = %d, want %v\n", wt.TCID, wt.Comment, int(sealRet), wt.Result) return false } if (sealedLen != C.size_t(maxOutLen)) { fmt.Printf("FAIL: Test case %d (%q) - seal length mismatch: got %d, want %d\n", wt.TCID, wt.Comment, sealedLen, maxOutLen) return false } sealedCt := sealed[0:msgLen] sealedTag := sealed[msgLen: maxOutLen] success := false if (bytes.Equal(sealedCt, ct) && bytes.Equal(sealedTag, tag)) || wt.Result == "invalid" { success = true } else { fmt.Printf("FAIL: Test case %d (%q) - EVP_AEAD_CTX_seal() = %d, ct match: %t, tag match: %t; want %v\n", wt.TCID, wt.Comment, int(sealRet), bytes.Equal(sealedCt, ct), bytes.Equal(sealedTag, tag), wt.Result) } return success } func runChaCha20Poly1305Test(iv_len int, key_len int, tag_len int, wt *wycheproofTestChaCha20Poly1305) bool { aead := C.EVP_aead_chacha20_poly1305() if aead == nil { log.Fatal("EVP_aead_chacha20_poly1305 failed") } key, err := hex.DecodeString(wt.Key) if err != nil { log.Fatalf("Failed to decode key %q: %v", wt.Key, err) } iv, err := hex.DecodeString(wt.IV) if err != nil { log.Fatalf("Failed to decode key %q: %v", wt.IV, err) } aad, err := hex.DecodeString(wt.AAD) if err != nil { log.Fatalf("Failed to decode AAD %q: %v", wt.AAD, err) } msg, err := hex.DecodeString(wt.Msg) if err != nil { log.Fatalf("Failed to decode msg %q: %v", wt.Msg, err) } ct, err := hex.DecodeString(wt.CT) if err != nil { log.Fatalf("Failed to decode ct %q: %v", wt.CT, err) } tag, err := hex.DecodeString(wt.Tag) if err != nil { log.Fatalf("Failed to decode tag %q: %v", wt.Tag, err) } keyLen, ivLen, aadLen, tagLen := len(key), len(iv), len(aad), len(tag) if key_len != keyLen || iv_len != ivLen || tag_len != tagLen { fmt.Printf("FAIL: Test case %d (%q) - length mismatch; key: got %d, want %d; IV: got %d, want %d; tag: got %d, want %d\n", wt.TCID, wt.Comment, keyLen, key_len, ivLen, iv_len, tagLen, tag_len) return false } msgLen, ctLen := len(msg), len(ct) if msgLen != ctLen { fmt.Printf("FAIL: Test case %d (%q) - length mismatch: msgLen = %d, ctLen = %d\n", wt.TCID, wt.Comment, msgLen, ctLen) return false } if ivLen == 0 { iv = append(iv, 0) } if aadLen == 0 { aad = append(aad, 0) } if msgLen == 0 { msg = append(msg, 0) } var ctx C.EVP_AEAD_CTX if C.EVP_AEAD_CTX_init((*C.EVP_AEAD_CTX)(unsafe.Pointer(&ctx)), aead, (*C.uchar)(unsafe.Pointer(&key[0])), C.size_t(key_len), C.size_t(tag_len), nil) != 1 { log.Fatal("Failed to initialize AEAD context") } defer C.EVP_AEAD_CTX_cleanup((*C.EVP_AEAD_CTX)(unsafe.Pointer(&ctx))) openSuccess := checkChaCha20Poly1305Open((*C.EVP_AEAD_CTX)(unsafe.Pointer(&ctx)), iv, ivLen, aad, aadLen, msg, msgLen, ct, ctLen, tag, tagLen, wt) sealSuccess := checkChaCha20Poly1305Seal((*C.EVP_AEAD_CTX)(unsafe.Pointer(&ctx)), iv, ivLen, aad, aadLen, msg, msgLen, ct, ctLen, tag, tagLen, wt) return openSuccess && sealSuccess } func runChaCha20Poly1305TestGroup(wtg *wycheproofTestGroupChaCha20Poly1305) bool { // We currently only support nonces of length 12 (96 bits) if wtg.IVSize != 96 { return true } fmt.Printf("Running ChaCha20-Poly1305 test group %v with IV size %d, key size %d, tag size %d...\n", wtg.Type, wtg.IVSize, wtg.KeySize, wtg.TagSize) success := true for _, wt := range wtg.Tests { if !runChaCha20Poly1305Test(wtg.IVSize / 8, wtg.KeySize / 8, wtg.TagSize / 8, wt) { success = false } } return success } func runDSATest(dsa *C.DSA, h hash.Hash, wt *wycheproofTestDSA) bool { msg, err := hex.DecodeString(wt.Msg) if err != nil { log.Fatalf("Failed to decode message %q: %v", wt.Msg, err) } h.Reset() h.Write(msg) msg = h.Sum(nil) sig, err := hex.DecodeString(wt.Sig) if err != nil { log.Fatalf("Failed to decode signature %q: %v", wt.Sig, err) } msgLen, sigLen := len(msg), len(sig) if msgLen == 0 { msg = append(msg, 0) } if sigLen == 0 { sig = append(msg, 0) } ret := C.DSA_verify(0, (*C.uchar)(unsafe.Pointer(&msg[0])), C.int(msgLen), (*C.uchar)(unsafe.Pointer(&sig[0])), C.int(sigLen), dsa) success := true if (ret == 1) != (wt.Result == "valid") { fmt.Printf("FAIL: Test case %d (%q) - DSA_verify() = %d, want %v\n", wt.TCID, wt.Comment, ret, wt.Result) success = false } return success } func runDSATestGroup(wtg *wycheproofTestGroupDSA) bool { fmt.Printf("Running DSA test group %v, key size %d and %v...\n", wtg.Type, wtg.Key.KeySize, wtg.SHA) dsa := C.DSA_new() if dsa == nil { log.Fatal("DSA_new failed") } defer C.DSA_free(dsa) var bnG *C.BIGNUM wg := C.CString(wtg.Key.G) if C.BN_hex2bn(&bnG, wg) == 0 { log.Fatal("Failed to decode g") } var bnP *C.BIGNUM wp := C.CString(wtg.Key.P) if C.BN_hex2bn(&bnP, wp) == 0 { log.Fatal("Failed to decode p") } var bnQ *C.BIGNUM wq := C.CString(wtg.Key.Q) if C.BN_hex2bn(&bnQ, wq) == 0 { log.Fatal("Failed to decode q") } ret := C.DSA_set0_pqg(dsa, bnP, bnQ, bnG) if ret != 1 { log.Fatalf("DSA_set0_pqg returned %d", ret) } var bnY *C.BIGNUM wy := C.CString(wtg.Key.Y) if C.BN_hex2bn(&bnY, wy) == 0 { log.Fatal("Failed to decode y") } ret = C.DSA_set0_key(dsa, bnY, nil) if ret != 1 { log.Fatalf("DSA_set0_key returned %d", ret) } h, err := hashFromString(wtg.SHA) if err != nil { log.Fatalf("Failed to get hash: %v", err) } der, err := hex.DecodeString(wtg.KeyDER) if err != nil { log.Fatalf("Failed to decode DER encoded key: %v", err) } derLen := len(der) if derLen == 0 { der = append(der, 0) } Cder := (*C.uchar)(C.malloc((C.ulong)(derLen))) if Cder == nil { log.Fatal("malloc failed") } C.memcpy(unsafe.Pointer(Cder), unsafe.Pointer(&der[0]), C.ulong(derLen)) p := (*C.uchar)(Cder) dsaDER := C.d2i_DSA_PUBKEY(nil, (**C.uchar)(&p), C.long(derLen)) defer C.DSA_free(dsaDER) C.free(unsafe.Pointer(Cder)) /// XXX audit acceptable cases success := true for _, wt := range wtg.Tests { if !runDSATest(dsa, h, wt) { success = false } if !runDSATest(dsaDER, h, wt) { success = false } } return success } func runECDSATest(ecKey *C.EC_KEY, nid int, h hash.Hash, wt *wycheproofTestECDSA) bool { msg, err := hex.DecodeString(wt.Msg) if err != nil { log.Fatalf("Failed to decode message %q: %v", wt.Msg, err) } h.Reset() h.Write(msg) msg = h.Sum(nil) sig, err := hex.DecodeString(wt.Sig) if err != nil { log.Fatalf("Failed to decode signature %q: %v", wt.Sig, err) } msgLen, sigLen := len(msg), len(sig) if msgLen == 0 { msg = append(msg, 0) } if sigLen == 0 { sig = append(sig, 0) } ret := C.ECDSA_verify(0, (*C.uchar)(unsafe.Pointer(&msg[0])), C.int(msgLen), (*C.uchar)(unsafe.Pointer(&sig[0])), C.int(sigLen), ecKey) // XXX audit acceptable cases... success := true if (ret == 1) != (wt.Result == "valid") && wt.Result != "acceptable" { fmt.Printf("FAIL: Test case %d (%q) - ECDSA_verify() = %d, want %v\n", wt.TCID, wt.Comment, int(ret), wt.Result) success = false } return success } func runECDSATestGroup(wtg *wycheproofTestGroupECDSA) bool { // No secp256r1 support. if wtg.Key.Curve == "secp256r1" { return true } fmt.Printf("Running ECDSA test group %v with curve %v, key size %d and %v...\n", wtg.Type, wtg.Key.Curve, wtg.Key.KeySize, wtg.SHA) nid, err := nidFromString(wtg.Key.Curve) if err != nil { log.Fatalf("Failed to get nid for curve: %v", err) } ecKey := C.EC_KEY_new_by_curve_name(C.int(nid)) if ecKey == nil { log.Fatal("EC_KEY_new_by_curve_name failed") } defer C.EC_KEY_free(ecKey) var bnX *C.BIGNUM wx := C.CString(wtg.Key.WX) if C.BN_hex2bn(&bnX, wx) == 0 { log.Fatal("Failed to decode WX") } C.free(unsafe.Pointer(wx)) defer C.BN_free(bnX) var bnY *C.BIGNUM wy := C.CString(wtg.Key.WY) if C.BN_hex2bn(&bnY, wy) == 0 { log.Fatal("Failed to decode WY") } C.free(unsafe.Pointer(wy)) defer C.BN_free(bnY) if C.EC_KEY_set_public_key_affine_coordinates(ecKey, bnX, bnY) != 1 { log.Fatal("Failed to set EC public key") } nid, err = nidFromString(wtg.SHA) if err != nil { log.Fatalf("Failed to get MD NID: %v", err) } h, err := hashFromString(wtg.SHA) if err != nil { log.Fatalf("Failed to get hash: %v", err) } success := true for _, wt := range wtg.Tests { if !runECDSATest(ecKey, nid, h, wt) { success = false } } return success } func runRSATest(rsa *C.RSA, nid int, h hash.Hash, wt *wycheproofTestRSA) bool { msg, err := hex.DecodeString(wt.Msg) if err != nil { log.Fatalf("Failed to decode message %q: %v", wt.Msg, err) } h.Reset() h.Write(msg) msg = h.Sum(nil) sig, err := hex.DecodeString(wt.Sig) if err != nil { log.Fatalf("Failed to decode signature %q: %v", wt.Sig, err) } msgLen, sigLen := len(msg), len(sig) if msgLen == 0 { msg = append(msg, 0) } if sigLen == 0 { sig = append(sig, 0) } ret := C.RSA_verify(C.int(nid), (*C.uchar)(unsafe.Pointer(&msg[0])), C.uint(msgLen), (*C.uchar)(unsafe.Pointer(&sig[0])), C.uint(sigLen), rsa) // XXX audit acceptable cases... success := true if (ret == 1) != (wt.Result == "valid") && wt.Result != "acceptable" { fmt.Printf("FAIL: Test case %d (%q) - RSA_verify() = %d, want %v\n", wt.TCID, wt.Comment, int(ret), wt.Result) success = false } return success } func runRSATestGroup(wtg *wycheproofTestGroupRSA) bool { fmt.Printf("Running RSA test group %v with key size %d and %v...\n", wtg.Type, wtg.KeySize, wtg.SHA) rsa := C.RSA_new() if rsa == nil { log.Fatal("RSA_new failed") } defer C.RSA_free(rsa) e := C.CString(wtg.E) if C.BN_hex2bn(&rsa.e, e) == 0 { log.Fatal("Failed to set RSA e") } C.free(unsafe.Pointer(e)) n := C.CString(wtg.N) if C.BN_hex2bn(&rsa.n, n) == 0 { log.Fatal("Failed to set RSA n") } C.free(unsafe.Pointer(n)) nid, err := nidFromString(wtg.SHA) if err != nil { log.Fatalf("Failed to get MD NID: %v", err) } h, err := hashFromString(wtg.SHA) if err != nil { log.Fatalf("Failed to get hash: %v", err) } success := true for _, wt := range wtg.Tests { if !runRSATest(rsa, nid, h, wt) { success = false } } return success } func runX25519Test(wt *wycheproofTestX25519) bool { public, err := hex.DecodeString(wt.Public) if err != nil { log.Fatalf("Failed to decode public %q: %v", wt.Public, err) } private, err := hex.DecodeString(wt.Private) if err != nil { log.Fatalf("Failed to decode private %q: %v", wt.Private, err) } shared, err := hex.DecodeString(wt.Shared) if err != nil { log.Fatalf("Failed to decode shared %q: %v", wt.Shared, err) } got := make([]byte, C.X25519_KEY_LENGTH) result := true if C.X25519((*C.uint8_t)(unsafe.Pointer(&got[0])), (*C.uint8_t)(unsafe.Pointer(&private[0])), (*C.uint8_t)(unsafe.Pointer(&public[0]))) != 1 { result = false } else { result = bytes.Equal(got, shared) } // XXX audit acceptable cases... success := true if result != (wt.Result == "valid") && wt.Result != "acceptable" { fmt.Printf("FAIL: Test case %d (%q) - X25519(), want %v\n", wt.TCID, wt.Comment, wt.Result) success = false } return success } func runX25519TestGroup(wtg *wycheproofTestGroupX25519) bool { fmt.Printf("Running X25519 test group with curve %v...\n", wtg.Curve) success := true for _, wt := range wtg.Tests { if !runX25519Test(wt) { success = false } } return success } func runTestVectors(path string) bool { b, err := ioutil.ReadFile(path) if err != nil { log.Fatalf("Failed to read test vectors: %v", err) } wtv := &wycheproofTestVectors{} if err := json.Unmarshal(b, wtv); err != nil { log.Fatalf("Failed to unmarshal JSON: %v", err) } fmt.Printf("Loaded Wycheproof test vectors for %v with %d tests from %q\n", wtv.Algorithm, wtv.NumberOfTests, filepath.Base(path)) var wtg interface{} switch wtv.Algorithm { case "CHACHA20-POLY1305": wtg = &wycheproofTestGroupChaCha20Poly1305{} case "DSA": wtg = &wycheproofTestGroupDSA{} case "ECDSA": wtg = &wycheproofTestGroupECDSA{} case "RSASig": wtg = &wycheproofTestGroupRSA{} case "X25519": wtg = &wycheproofTestGroupX25519{} default: log.Fatalf("Unknown test vector algorithm %q", wtv.Algorithm) } success := true for _, tg := range wtv.TestGroups { if err := json.Unmarshal(tg, wtg); err != nil { log.Fatalf("Failed to unmarshal test groups JSON: %v", err) } switch wtv.Algorithm { case "CHACHA20-POLY1305": if !runChaCha20Poly1305TestGroup(wtg.(*wycheproofTestGroupChaCha20Poly1305)) { success = false } case "DSA": if !runDSATestGroup(wtg.(*wycheproofTestGroupDSA)) { success = false } case "ECDSA": if !runECDSATestGroup(wtg.(*wycheproofTestGroupECDSA)) { success = false } case "RSASig": if !runRSATestGroup(wtg.(*wycheproofTestGroupRSA)) { success = false } case "X25519": if !runX25519TestGroup(wtg.(*wycheproofTestGroupX25519)) { success = false } default: log.Fatalf("Unknown test vector algorithm %q", wtv.Algorithm) } } return success } func main() { if _, err := os.Stat(testVectorPath); os.IsNotExist(err) { fmt.Printf("package wycheproof-testvectors is required for this regress\n") fmt.Printf("SKIPPING\n") os.Exit(0) } // AES, ECDH, RSA-PSS tests := []struct { name string pattern string }{ {"ChaCha20-Poly1305", "chacha20_poly1305_test.json"}, {"DSA", "dsa_test.json"}, {"ECDSA", "ecdsa_[^w]*test.json"}, // Skip ecdsa_webcrypto_test.json for now. {"RSA signature", "rsa_signature_*test.json"}, {"X25519", "x25519_*test.json"}, } success := true for _, test := range tests { tvs, err := filepath.Glob(filepath.Join(testVectorPath, test.pattern)) if err != nil { log.Fatalf("Failed to glob %v test vectors: %v", test.name, err) } if len(tvs) == 0 { log.Fatalf("Failed to find %v test vectors at %q\n", test.name, testVectorPath) } for _, tv := range tvs { if !runTestVectors(tv) { success = false } } } if !success { os.Exit(1) } }