/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "nsSyncJPAKE.h" #include "mozilla/ModuleUtils.h" #include #include #include #include #include #include #include #include #include #include #include using mozilla::fallible; static bool hex_from_2char(const unsigned char *c2, unsigned char *byteval) { int i; unsigned char offset; *byteval = 0; for (i=0; i<2; i++) { if (c2[i] >= '0' && c2[i] <= '9') { offset = c2[i] - '0'; *byteval |= offset << 4*(1-i); } else if (c2[i] >= 'a' && c2[i] <= 'f') { offset = c2[i] - 'a'; *byteval |= (offset + 10) << 4*(1-i); } else if (c2[i] >= 'A' && c2[i] <= 'F') { offset = c2[i] - 'A'; *byteval |= (offset + 10) << 4*(1-i); } else { return false; } } return true; } static bool fromHex(const char * str, unsigned char * p, size_t sLen) { size_t i; if (sLen & 1) return false; for (i = 0; i < sLen / 2; ++i) { if (!hex_from_2char((const unsigned char *) str + (2*i), (unsigned char *) p + i)) { return false; } } return true; } static nsresult fromHexString(const nsACString & str, unsigned char * p, size_t pMaxLen) { char * strData = (char *) str.Data(); unsigned len = str.Length(); NS_ENSURE_ARG(len / 2 <= pMaxLen); if (!fromHex(strData, p, len)) { return NS_ERROR_INVALID_ARG; } return NS_OK; } static bool toHexString(const unsigned char * str, unsigned len, nsACString & out) { static const char digits[] = "0123456789ABCDEF"; if (!out.SetCapacity(2 * len, fallible)) return false; out.SetLength(0); for (unsigned i = 0; i < len; ++i) { out.Append(digits[str[i] >> 4]); out.Append(digits[str[i] & 0x0f]); } return true; } static nsresult mapErrno() { int err = PORT_GetError(); switch (err) { case SEC_ERROR_NO_MEMORY: return NS_ERROR_OUT_OF_MEMORY; default: return NS_ERROR_UNEXPECTED; } } #define NUM_ELEM(x) (sizeof(x) / sizeof (x)[0]) static const char p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static const char q[] = "CFA0478A54717B08CE64805B76E5B14249A77A4838469DF7F7DC987EFCCFB11D"; static const char g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nsSyncJPAKE::Round1(const nsACString & aSignerID, nsACString & aGX1, nsACString & aGV1, nsACString & aR1, nsACString & aGX2, nsACString & aGV2, nsACString & aR2) { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown()) { return NS_ERROR_NOT_AVAILABLE; } NS_ENSURE_STATE(round == JPAKENotStarted); NS_ENSURE_STATE(key == nullptr); static CK_MECHANISM_TYPE mechanisms[] = { CKM_NSS_JPAKE_ROUND1_SHA256, CKM_NSS_JPAKE_ROUND2_SHA256, CKM_NSS_JPAKE_FINAL_SHA256 }; ScopedPK11SlotInfo slot(PK11_GetBestSlotMultiple(mechanisms, NUM_ELEM(mechanisms), nullptr)); NS_ENSURE_STATE(slot != nullptr); CK_BYTE pBuf[(NUM_ELEM(p) - 1) / 2]; CK_BYTE qBuf[(NUM_ELEM(q) - 1) / 2]; CK_BYTE gBuf[(NUM_ELEM(g) - 1) / 2]; CK_KEY_TYPE keyType = CKK_NSS_JPAKE_ROUND1; NS_ENSURE_STATE(fromHex(p, pBuf, (NUM_ELEM(p) - 1))); NS_ENSURE_STATE(fromHex(q, qBuf, (NUM_ELEM(q) - 1))); NS_ENSURE_STATE(fromHex(g, gBuf, (NUM_ELEM(g) - 1))); CK_ATTRIBUTE keyTemplate[] = { { CKA_NSS_JPAKE_SIGNERID, (CK_BYTE *) aSignerID.Data(), aSignerID.Length() }, { CKA_KEY_TYPE, &keyType, sizeof keyType }, { CKA_PRIME, pBuf, sizeof pBuf }, { CKA_SUBPRIME, qBuf, sizeof qBuf }, { CKA_BASE, gBuf, sizeof gBuf } }; CK_BYTE gx1Buf[NUM_ELEM(p) / 2]; CK_BYTE gv1Buf[NUM_ELEM(p) / 2]; CK_BYTE r1Buf [NUM_ELEM(p) / 2]; CK_BYTE gx2Buf[NUM_ELEM(p) / 2]; CK_BYTE gv2Buf[NUM_ELEM(p) / 2]; CK_BYTE r2Buf [NUM_ELEM(p) / 2]; CK_NSS_JPAKERound1Params rp = { { gx1Buf, sizeof gx1Buf, gv1Buf, sizeof gv1Buf, r1Buf, sizeof r1Buf }, { gx2Buf, sizeof gx2Buf, gv2Buf, sizeof gv2Buf, r2Buf, sizeof r2Buf } }; SECItem paramsItem; paramsItem.data = (unsigned char *) &rp; paramsItem.len = sizeof rp; key = PK11_KeyGenWithTemplate(slot, CKM_NSS_JPAKE_ROUND1_SHA256, CKM_NSS_JPAKE_ROUND1_SHA256, ¶msItem, keyTemplate, NUM_ELEM(keyTemplate), nullptr); nsresult rv = key != nullptr ? NS_OK : mapErrno(); if (rv == NS_OK) { NS_ENSURE_TRUE(toHexString(rp.gx1.pGX, rp.gx1.ulGXLen, aGX1) && toHexString(rp.gx1.pGV, rp.gx1.ulGVLen, aGV1) && toHexString(rp.gx1.pR, rp.gx1.ulRLen, aR1) && toHexString(rp.gx2.pGX, rp.gx2.ulGXLen, aGX2) && toHexString(rp.gx2.pGV, rp.gx2.ulGVLen, aGV2) && toHexString(rp.gx2.pR, rp.gx2.ulRLen, aR2), NS_ERROR_OUT_OF_MEMORY); round = JPAKEBeforeRound2; } return rv; } NS_IMETHODIMP nsSyncJPAKE::Round2(const nsACString & aPeerID, const nsACString & aPIN, const nsACString & aGX3, const nsACString & aGV3, const nsACString & aR3, const nsACString & aGX4, const nsACString & aGV4, const nsACString & aR4, nsACString & aA, nsACString & aGVA, nsACString & aRA) { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown()) { return NS_ERROR_NOT_AVAILABLE; } NS_ENSURE_STATE(round == JPAKEBeforeRound2); NS_ENSURE_STATE(key != nullptr); NS_ENSURE_ARG(!aPeerID.IsEmpty()); /* PIN cannot be equal to zero when converted to a bignum. NSS 3.12.9 J-PAKE assumes that the caller has already done this check. Future versions of NSS J-PAKE will do this check internally. See Bug 609068 Comment 4 */ bool foundNonZero = false; for (size_t i = 0; i < aPIN.Length(); ++i) { if (aPIN[i] != 0) { foundNonZero = true; break; } } NS_ENSURE_ARG(foundNonZero); CK_BYTE gx3Buf[NUM_ELEM(p)/2], gv3Buf[NUM_ELEM(p)/2], r3Buf [NUM_ELEM(p)/2]; CK_BYTE gx4Buf[NUM_ELEM(p)/2], gv4Buf[NUM_ELEM(p)/2], r4Buf [NUM_ELEM(p)/2]; CK_BYTE gxABuf[NUM_ELEM(p)/2], gvABuf[NUM_ELEM(p)/2], rABuf [NUM_ELEM(p)/2]; nsresult rv = fromHexString(aGX3, gx3Buf, sizeof gx3Buf); if (rv == NS_OK) rv = fromHexString(aGV3, gv3Buf, sizeof gv3Buf); if (rv == NS_OK) rv = fromHexString(aR3, r3Buf, sizeof r3Buf); if (rv == NS_OK) rv = fromHexString(aGX4, gx4Buf, sizeof gx4Buf); if (rv == NS_OK) rv = fromHexString(aGV4, gv4Buf, sizeof gv4Buf); if (rv == NS_OK) rv = fromHexString(aR4, r4Buf, sizeof r4Buf); if (rv != NS_OK) return rv; CK_NSS_JPAKERound2Params rp; rp.pSharedKey = (CK_BYTE *) aPIN.Data(); rp.ulSharedKeyLen = aPIN.Length(); rp.gx3.pGX = gx3Buf; rp.gx3.ulGXLen = aGX3.Length() / 2; rp.gx3.pGV = gv3Buf; rp.gx3.ulGVLen = aGV3.Length() / 2; rp.gx3.pR = r3Buf; rp.gx3.ulRLen = aR3 .Length() / 2; rp.gx4.pGX = gx4Buf; rp.gx4.ulGXLen = aGX4.Length() / 2; rp.gx4.pGV = gv4Buf; rp.gx4.ulGVLen = aGV4.Length() / 2; rp.gx4.pR = r4Buf; rp.gx4.ulRLen = aR4 .Length() / 2; rp.A.pGX = gxABuf; rp.A .ulGXLen = sizeof gxABuf; rp.A.pGV = gvABuf; rp.A .ulGVLen = sizeof gxABuf; rp.A.pR = rABuf; rp.A .ulRLen = sizeof gxABuf; // Bug 629090: NSS 3.12.9 J-PAKE fails to check that gx^4 != 1, so check here. bool gx4Good = false; for (unsigned i = 0; i < rp.gx4.ulGXLen; ++i) { if (rp.gx4.pGX[i] > 1 || (rp.gx4.pGX[i] != 0 && i < rp.gx4.ulGXLen - 1)) { gx4Good = true; break; } } NS_ENSURE_ARG(gx4Good); SECItem paramsItem; paramsItem.data = (unsigned char *) &rp; paramsItem.len = sizeof rp; CK_KEY_TYPE keyType = CKK_NSS_JPAKE_ROUND2; CK_ATTRIBUTE keyTemplate[] = { { CKA_NSS_JPAKE_PEERID, (CK_BYTE *) aPeerID.Data(), aPeerID.Length(), }, { CKA_KEY_TYPE, &keyType, sizeof keyType } }; ScopedPK11SymKey newKey(PK11_DeriveWithTemplate(key, CKM_NSS_JPAKE_ROUND2_SHA256, ¶msItem, CKM_NSS_JPAKE_FINAL_SHA256, CKA_DERIVE, 0, keyTemplate, NUM_ELEM(keyTemplate), false)); if (newKey != nullptr) { if (toHexString(rp.A.pGX, rp.A.ulGXLen, aA) && toHexString(rp.A.pGV, rp.A.ulGVLen, aGVA) && toHexString(rp.A.pR, rp.A.ulRLen, aRA)) { round = JPAKEAfterRound2; key = newKey.forget(); return NS_OK; } else { rv = NS_ERROR_OUT_OF_MEMORY; } } else { rv = mapErrno(); } return rv; } static nsresult setBase64(const unsigned char * data, unsigned len, nsACString & out) { nsresult rv = NS_OK; const char * base64 = BTOA_DataToAscii(data, len); if (base64 != nullptr) { size_t len = PORT_Strlen(base64); if (out.SetCapacity(len, fallible)) { out.SetLength(0); out.Append(base64, len); } else { rv = NS_ERROR_OUT_OF_MEMORY; } PORT_Free((void*) base64); } else { rv = NS_ERROR_OUT_OF_MEMORY; } return rv; } static nsresult base64KeyValue(PK11SymKey * key, nsACString & keyString) { nsresult rv = NS_OK; if (PK11_ExtractKeyValue(key) == SECSuccess) { const SECItem * value = PK11_GetKeyData(key); rv = value != nullptr && value->data != nullptr && value->len > 0 ? setBase64(value->data, value->len, keyString) : NS_ERROR_UNEXPECTED; } else { rv = mapErrno(); } return rv; } static nsresult extractBase64KeyValue(PK11SymKey * keyBlock, CK_ULONG bitPosition, CK_MECHANISM_TYPE destMech, int keySize, nsACString & keyString) { SECItem paramsItem; paramsItem.data = (CK_BYTE *) &bitPosition; paramsItem.len = sizeof bitPosition; PK11SymKey * key = PK11_Derive(keyBlock, CKM_EXTRACT_KEY_FROM_KEY, ¶msItem, destMech, CKA_SIGN, keySize); if (key == nullptr) return mapErrno(); nsresult rv = base64KeyValue(key, keyString); PK11_FreeSymKey(key); return rv; } NS_IMETHODIMP nsSyncJPAKE::Final(const nsACString & aB, const nsACString & aGVB, const nsACString & aRB, const nsACString & aHKDFInfo, nsACString & aAES256Key, nsACString & aHMAC256Key) { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown()) { return NS_ERROR_NOT_AVAILABLE; } static const unsigned AES256_KEY_SIZE = 256 / 8; static const unsigned HMAC_SHA256_KEY_SIZE = 256 / 8; CK_EXTRACT_PARAMS aesBitPosition = 0; CK_EXTRACT_PARAMS hmacBitPosition = aesBitPosition + (AES256_KEY_SIZE * 8); NS_ENSURE_STATE(round == JPAKEAfterRound2); NS_ENSURE_STATE(key != nullptr); CK_BYTE gxBBuf[NUM_ELEM(p)/2], gvBBuf[NUM_ELEM(p)/2], rBBuf [NUM_ELEM(p)/2]; nsresult rv = fromHexString(aB, gxBBuf, sizeof gxBBuf); if (rv == NS_OK) rv = fromHexString(aGVB, gvBBuf, sizeof gvBBuf); if (rv == NS_OK) rv = fromHexString(aRB, rBBuf, sizeof rBBuf); if (rv != NS_OK) return rv; CK_NSS_JPAKEFinalParams rp; rp.B.pGX = gxBBuf; rp.B.ulGXLen = aB .Length() / 2; rp.B.pGV = gvBBuf; rp.B.ulGVLen = aGVB.Length() / 2; rp.B.pR = rBBuf; rp.B.ulRLen = aRB .Length() / 2; SECItem paramsItem; paramsItem.data = (unsigned char *) &rp; paramsItem.len = sizeof rp; ScopedPK11SymKey keyMaterial(PK11_Derive(key, CKM_NSS_JPAKE_FINAL_SHA256, ¶msItem, CKM_NSS_HKDF_SHA256, CKA_DERIVE, 0)); ScopedPK11SymKey keyBlock; if (keyMaterial == nullptr) rv = mapErrno(); if (rv == NS_OK) { CK_NSS_HKDFParams hkdfParams; hkdfParams.bExtract = CK_TRUE; hkdfParams.pSalt = nullptr; hkdfParams.ulSaltLen = 0; hkdfParams.bExpand = CK_TRUE; hkdfParams.pInfo = (CK_BYTE *) aHKDFInfo.Data(); hkdfParams.ulInfoLen = aHKDFInfo.Length(); paramsItem.data = (unsigned char *) &hkdfParams; paramsItem.len = sizeof hkdfParams; keyBlock = PK11_Derive(keyMaterial, CKM_NSS_HKDF_SHA256, ¶msItem, CKM_EXTRACT_KEY_FROM_KEY, CKA_DERIVE, AES256_KEY_SIZE + HMAC_SHA256_KEY_SIZE); if (keyBlock == nullptr) rv = mapErrno(); } if (rv == NS_OK) { rv = extractBase64KeyValue(keyBlock, aesBitPosition, CKM_AES_CBC, AES256_KEY_SIZE, aAES256Key); } if (rv == NS_OK) { rv = extractBase64KeyValue(keyBlock, hmacBitPosition, CKM_SHA256_HMAC, HMAC_SHA256_KEY_SIZE, aHMAC256Key); } if (rv == NS_OK) { SECStatus srv = PK11_ExtractKeyValue(keyMaterial); NS_ENSURE_TRUE(srv == SECSuccess, NS_ERROR_UNEXPECTED); SECItem * keyMaterialBytes = PK11_GetKeyData(keyMaterial); NS_ENSURE_TRUE(keyMaterialBytes != nullptr, NS_ERROR_UNEXPECTED); } return rv; } NS_GENERIC_FACTORY_CONSTRUCTOR(nsSyncJPAKE) NS_DEFINE_NAMED_CID(NS_SYNCJPAKE_CID); nsSyncJPAKE::nsSyncJPAKE() : round(JPAKENotStarted), key(nullptr) { } nsSyncJPAKE::~nsSyncJPAKE() { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown()) { return; } destructorSafeDestroyNSSReference(); shutdown(calledFromObject); } void nsSyncJPAKE::virtualDestroyNSSReference() { destructorSafeDestroyNSSReference(); } void nsSyncJPAKE::destructorSafeDestroyNSSReference() { key.dispose(); } static const mozilla::Module::CIDEntry kServicesCryptoCIDs[] = { { &kNS_SYNCJPAKE_CID, false, nullptr, nsSyncJPAKEConstructor }, { nullptr } }; static const mozilla::Module::ContractIDEntry kServicesCryptoContracts[] = { { NS_SYNCJPAKE_CONTRACTID, &kNS_SYNCJPAKE_CID }, { nullptr } }; static const mozilla::Module kServicesCryptoModule = { mozilla::Module::kVersion, kServicesCryptoCIDs, kServicesCryptoContracts }; NSMODULE_DEFN(nsServicesCryptoModule) = &kServicesCryptoModule;