/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim:set ts=2 sw=2 sts=2 et cindent: */ /* 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 "pk11pub.h" #include "cryptohi.h" #include "secerr.h" #include "ScopedNSSTypes.h" #include "jsapi.h" #include "mozilla/Telemetry.h" #include "mozilla/dom/CryptoBuffer.h" #include "mozilla/dom/CryptoKey.h" #include "mozilla/dom/KeyAlgorithmProxy.h" #include "mozilla/dom/TypedArray.h" #include "mozilla/dom/WebCryptoCommon.h" #include "mozilla/dom/WebCryptoTask.h" namespace mozilla { namespace dom { // Pre-defined identifiers for telemetry histograms enum TelemetryMethod { TM_ENCRYPT = 0, TM_DECRYPT = 1, TM_SIGN = 2, TM_VERIFY = 3, TM_DIGEST = 4, TM_GENERATEKEY = 5, TM_DERIVEKEY = 6, TM_DERIVEBITS = 7, TM_IMPORTKEY = 8, TM_EXPORTKEY = 9, TM_WRAPKEY = 10, TM_UNWRAPKEY = 11 }; enum TelemetryAlgorithm { // Please make additions at the end of the list, // to preserve comparability of histograms over time TA_UNKNOWN = 0, // encrypt / decrypt TA_AES_CBC = 1, TA_AES_CFB = 2, TA_AES_CTR = 3, TA_AES_GCM = 4, TA_RSAES_PKCS1 = 5, // NB: This algorithm has been removed TA_RSA_OAEP = 6, // sign/verify TA_RSASSA_PKCS1 = 7, TA_RSA_PSS = 8, TA_HMAC_SHA_1 = 9, TA_HMAC_SHA_224 = 10, TA_HMAC_SHA_256 = 11, TA_HMAC_SHA_384 = 12, TA_HMAC_SHA_512 = 13, // digest TA_SHA_1 = 14, TA_SHA_224 = 15, TA_SHA_256 = 16, TA_SHA_384 = 17, TA_SHA_512 = 18, // Later additions TA_AES_KW = 19, TA_ECDH = 20, TA_PBKDF2 = 21, TA_ECDSA = 22, }; // Convenience functions for extracting / converting information // OOM-safe CryptoBuffer initialization, suitable for constructors #define ATTEMPT_BUFFER_INIT(dst, src) \ if (!dst.Assign(src)) { \ mEarlyRv = NS_ERROR_DOM_UNKNOWN_ERR; \ return; \ } // OOM-safe CryptoBuffer-to-SECItem copy, suitable for DoCrypto #define ATTEMPT_BUFFER_TO_SECITEM(arena, dst, src) \ if (!src.ToSECItem(arena, dst)) { \ return NS_ERROR_DOM_UNKNOWN_ERR; \ } // OOM-safe CryptoBuffer copy, suitable for DoCrypto #define ATTEMPT_BUFFER_ASSIGN(dst, src) \ if (!dst.Assign(src)) { \ return NS_ERROR_DOM_UNKNOWN_ERR; \ } // Safety check for algorithms that use keys, suitable for constructors #define CHECK_KEY_ALGORITHM(keyAlg, algName) \ { \ if (!NORMALIZED_EQUALS(keyAlg.mName, algName)) { \ mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; \ return; \ } \ } class ClearException { public: explicit ClearException(JSContext* aCx) : mCx(aCx) {} ~ClearException() { JS_ClearPendingException(mCx); } private: JSContext* mCx; }; template static nsresult GetAlgorithmName(JSContext* aCx, const OOS& aAlgorithm, nsString& aName) { ClearException ce(aCx); if (aAlgorithm.IsString()) { // If string, then treat as algorithm name aName.Assign(aAlgorithm.GetAsString()); } else { // Coerce to algorithm and extract name JS::RootedValue value(aCx, JS::ObjectValue(*aAlgorithm.GetAsObject())); Algorithm alg; if (!alg.Init(aCx, value)) { return NS_ERROR_DOM_SYNTAX_ERR; } aName = alg.mName; } if (!NormalizeToken(aName, aName)) { return NS_ERROR_DOM_SYNTAX_ERR; } return NS_OK; } template static nsresult Coerce(JSContext* aCx, T& aTarget, const OOS& aAlgorithm) { ClearException ce(aCx); if (!aAlgorithm.IsObject()) { return NS_ERROR_DOM_SYNTAX_ERR; } JS::RootedValue value(aCx, JS::ObjectValue(*aAlgorithm.GetAsObject())); if (!aTarget.Init(aCx, value)) { return NS_ERROR_DOM_SYNTAX_ERR; } return NS_OK; } inline size_t MapHashAlgorithmNameToBlockSize(const nsString& aName) { if (aName.EqualsLiteral(WEBCRYPTO_ALG_SHA1) || aName.EqualsLiteral(WEBCRYPTO_ALG_SHA256)) { return 512; } if (aName.EqualsLiteral(WEBCRYPTO_ALG_SHA384) || aName.EqualsLiteral(WEBCRYPTO_ALG_SHA512)) { return 1024; } return 0; } inline nsresult GetKeyLengthForAlgorithm(JSContext* aCx, const ObjectOrString& aAlgorithm, size_t& aLength) { aLength = 0; // Extract algorithm name nsString algName; if (NS_FAILED(GetAlgorithmName(aCx, aAlgorithm, algName))) { return NS_ERROR_DOM_SYNTAX_ERR; } // Read AES key length from given algorithm object. if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW)) { RootedDictionary params(aCx); if (NS_FAILED(Coerce(aCx, params, aAlgorithm))) { return NS_ERROR_DOM_SYNTAX_ERR; } if (params.mLength != 128 && params.mLength != 192 && params.mLength != 256) { return NS_ERROR_DOM_DATA_ERR; } aLength = params.mLength; return NS_OK; } // Read HMAC key length from given algorithm object or // determine key length as the block size of the given hash. if (algName.EqualsLiteral(WEBCRYPTO_ALG_HMAC)) { RootedDictionary params(aCx); if (NS_FAILED(Coerce(aCx, params, aAlgorithm))) { return NS_ERROR_DOM_SYNTAX_ERR; } // Return the passed length, if any. if (params.mLength.WasPassed()) { aLength = params.mLength.Value(); return NS_OK; } nsString hashName; if (NS_FAILED(GetAlgorithmName(aCx, params.mHash, hashName))) { return NS_ERROR_DOM_SYNTAX_ERR; } // Return the given hash algorithm's block size as the key length. size_t length = MapHashAlgorithmNameToBlockSize(hashName); if (length == 0) { return NS_ERROR_DOM_SYNTAX_ERR; } aLength = length; return NS_OK; } return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } inline bool MapOIDTagToNamedCurve(SECOidTag aOIDTag, nsString& aResult) { switch (aOIDTag) { case SEC_OID_SECG_EC_SECP256R1: aResult.AssignLiteral(WEBCRYPTO_NAMED_CURVE_P256); break; case SEC_OID_SECG_EC_SECP384R1: aResult.AssignLiteral(WEBCRYPTO_NAMED_CURVE_P384); break; case SEC_OID_SECG_EC_SECP521R1: aResult.AssignLiteral(WEBCRYPTO_NAMED_CURVE_P521); break; default: return false; } return true; } // Helper function to clone data from an ArrayBuffer or ArrayBufferView object inline bool CloneData(JSContext* aCx, CryptoBuffer& aDst, JS::Handle aSrc) { MOZ_ASSERT(NS_IsMainThread()); // Try ArrayBuffer RootedTypedArray ab(aCx); if (ab.Init(aSrc)) { return !!aDst.Assign(ab); } // Try ArrayBufferView RootedTypedArray abv(aCx); if (abv.Init(aSrc)) { return !!aDst.Assign(abv); } return false; } // Implementation of WebCryptoTask methods void WebCryptoTask::FailWithError(nsresult aRv) { MOZ_ASSERT(NS_IsMainThread()); Telemetry::Accumulate(Telemetry::WEBCRYPTO_RESOLVED, false); // Blindly convert nsresult to DOMException // Individual tasks must ensure they pass the right values mResultPromise->MaybeReject(aRv); // Manually release mResultPromise while we're on the main thread mResultPromise = nullptr; Cleanup(); } nsresult WebCryptoTask::CalculateResult() { MOZ_ASSERT(!NS_IsMainThread()); if (NS_FAILED(mEarlyRv)) { return mEarlyRv; } if (isAlreadyShutDown()) { return NS_ERROR_DOM_UNKNOWN_ERR; } return DoCrypto(); } void WebCryptoTask::CallCallback(nsresult rv) { MOZ_ASSERT(NS_IsMainThread()); if (NS_FAILED(rv)) { FailWithError(rv); return; } nsresult rv2 = AfterCrypto(); if (NS_FAILED(rv2)) { FailWithError(rv2); return; } Resolve(); Telemetry::Accumulate(Telemetry::WEBCRYPTO_RESOLVED, true); // Manually release mResultPromise while we're on the main thread mResultPromise = nullptr; Cleanup(); } // Some generic utility classes class FailureTask : public WebCryptoTask { public: explicit FailureTask(nsresult aRv) { mEarlyRv = aRv; } }; class ReturnArrayBufferViewTask : public WebCryptoTask { protected: CryptoBuffer mResult; private: // Returns mResult as an ArrayBufferView, or an error virtual void Resolve() MOZ_OVERRIDE { TypedArrayCreator ret(mResult); mResultPromise->MaybeResolve(ret); } }; class DeferredData { public: template void SetData(const T& aData) { mDataIsSet = mData.Assign(aData); } protected: DeferredData() : mDataIsSet(false) {} CryptoBuffer mData; bool mDataIsSet; }; class AesTask : public ReturnArrayBufferViewTask, public DeferredData { public: AesTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, bool aEncrypt) : mSymKey(aKey.GetSymKey()) , mEncrypt(aEncrypt) { Init(aCx, aAlgorithm, aKey, aEncrypt); } AesTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const CryptoOperationData& aData, bool aEncrypt) : mSymKey(aKey.GetSymKey()) , mEncrypt(aEncrypt) { Init(aCx, aAlgorithm, aKey, aEncrypt); SetData(aData); } void Init(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, bool aEncrypt) { nsString algName; mEarlyRv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(mEarlyRv)) { return; } // Check that we got a reasonable key if ((mSymKey.Length() != 16) && (mSymKey.Length() != 24) && (mSymKey.Length() != 32)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } // Cache parameters depending on the specific algorithm TelemetryAlgorithm telemetryAlg; if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC)) { CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_AES_CBC); mMechanism = CKM_AES_CBC_PAD; telemetryAlg = TA_AES_CBC; AesCbcParams params; nsresult rv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(rv)) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } ATTEMPT_BUFFER_INIT(mIv, params.mIv) if (mIv.Length() != 16) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR)) { CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_AES_CTR); mMechanism = CKM_AES_CTR; telemetryAlg = TA_AES_CTR; AesCtrParams params; nsresult rv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(rv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } ATTEMPT_BUFFER_INIT(mIv, params.mCounter) if (mIv.Length() != 16) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } mCounterLength = params.mLength; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM)) { CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_AES_GCM); mMechanism = CKM_AES_GCM; telemetryAlg = TA_AES_GCM; AesGcmParams params; nsresult rv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(rv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } ATTEMPT_BUFFER_INIT(mIv, params.mIv) if (params.mAdditionalData.WasPassed()) { ATTEMPT_BUFFER_INIT(mAad, params.mAdditionalData.Value()) } // 32, 64, 96, 104, 112, 120 or 128 mTagLength = 128; if (params.mTagLength.WasPassed()) { mTagLength = params.mTagLength.Value(); if ((mTagLength > 128) || !(mTagLength == 32 || mTagLength == 64 || (mTagLength >= 96 && mTagLength % 8 == 0))) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } } } else { mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, telemetryAlg); } private: CK_MECHANISM_TYPE mMechanism; CryptoBuffer mSymKey; CryptoBuffer mIv; // Initialization vector CryptoBuffer mAad; // Additional Authenticated Data uint8_t mTagLength; uint8_t mCounterLength; bool mEncrypt; virtual nsresult DoCrypto() MOZ_OVERRIDE { nsresult rv; if (!mDataIsSet) { return NS_ERROR_DOM_OPERATION_ERR; } ScopedPLArenaPool arena(PORT_NewArena(DER_DEFAULT_CHUNKSIZE)); if (!arena) { return NS_ERROR_DOM_OPERATION_ERR; } // Construct the parameters object depending on algorithm SECItem param = { siBuffer, nullptr, 0 }; CK_AES_CTR_PARAMS ctrParams; CK_GCM_PARAMS gcmParams; switch (mMechanism) { case CKM_AES_CBC_PAD: ATTEMPT_BUFFER_TO_SECITEM(arena, ¶m, mIv); break; case CKM_AES_CTR: ctrParams.ulCounterBits = mCounterLength; MOZ_ASSERT(mIv.Length() == 16); memcpy(&ctrParams.cb, mIv.Elements(), 16); param.type = siBuffer; param.data = (unsigned char*) &ctrParams; param.len = sizeof(ctrParams); break; case CKM_AES_GCM: gcmParams.pIv = mIv.Elements(); gcmParams.ulIvLen = mIv.Length(); gcmParams.pAAD = mAad.Elements(); gcmParams.ulAADLen = mAad.Length(); gcmParams.ulTagBits = mTagLength; param.type = siBuffer; param.data = (unsigned char*) &gcmParams; param.len = sizeof(gcmParams); break; default: return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } // Import the key SECItem keyItem = { siBuffer, nullptr, 0 }; ATTEMPT_BUFFER_TO_SECITEM(arena, &keyItem, mSymKey); ScopedPK11SlotInfo slot(PK11_GetInternalSlot()); MOZ_ASSERT(slot.get()); ScopedPK11SymKey symKey(PK11_ImportSymKey(slot, mMechanism, PK11_OriginUnwrap, CKA_ENCRYPT, &keyItem, nullptr)); if (!symKey) { return NS_ERROR_DOM_INVALID_ACCESS_ERR; } // Initialize the output buffer (enough space for padding / a full tag) uint32_t dataLen = mData.Length(); uint32_t maxLen = dataLen + 16; if (!mResult.SetLength(maxLen)) { return NS_ERROR_DOM_UNKNOWN_ERR; } uint32_t outLen = 0; // Perform the encryption/decryption if (mEncrypt) { rv = MapSECStatus(PK11_Encrypt(symKey.get(), mMechanism, ¶m, mResult.Elements(), &outLen, maxLen, mData.Elements(), mData.Length())); } else { rv = MapSECStatus(PK11_Decrypt(symKey.get(), mMechanism, ¶m, mResult.Elements(), &outLen, maxLen, mData.Elements(), mData.Length())); } NS_ENSURE_SUCCESS(rv, NS_ERROR_DOM_OPERATION_ERR); mResult.SetLength(outLen); return rv; } }; // This class looks like an encrypt/decrypt task, like AesTask, // but it is only exposed to wrapKey/unwrapKey, not encrypt/decrypt class AesKwTask : public ReturnArrayBufferViewTask, public DeferredData { public: AesKwTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, bool aEncrypt) : mMechanism(CKM_NSS_AES_KEY_WRAP) , mSymKey(aKey.GetSymKey()) , mEncrypt(aEncrypt) { Init(aCx, aAlgorithm, aKey, aEncrypt); } AesKwTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const CryptoOperationData& aData, bool aEncrypt) : mMechanism(CKM_NSS_AES_KEY_WRAP) , mSymKey(aKey.GetSymKey()) , mEncrypt(aEncrypt) { Init(aCx, aAlgorithm, aKey, aEncrypt); SetData(aData); } void Init(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, bool aEncrypt) { CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_AES_KW); nsString algName; mEarlyRv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(mEarlyRv)) { return; } // Check that we got a reasonable key if ((mSymKey.Length() != 16) && (mSymKey.Length() != 24) && (mSymKey.Length() != 32)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, TA_AES_KW); } private: CK_MECHANISM_TYPE mMechanism; CryptoBuffer mSymKey; bool mEncrypt; virtual nsresult DoCrypto() MOZ_OVERRIDE { nsresult rv; if (!mDataIsSet) { return NS_ERROR_DOM_OPERATION_ERR; } // Check that the input is a multiple of 64 bits long if (mData.Length() == 0 || mData.Length() % 8 != 0) { return NS_ERROR_DOM_DATA_ERR; } ScopedPLArenaPool arena(PORT_NewArena(DER_DEFAULT_CHUNKSIZE)); if (!arena) { return NS_ERROR_DOM_OPERATION_ERR; } // Import the key SECItem keyItem = { siBuffer, nullptr, 0 }; ATTEMPT_BUFFER_TO_SECITEM(arena, &keyItem, mSymKey); ScopedPK11SlotInfo slot(PK11_GetInternalSlot()); MOZ_ASSERT(slot.get()); ScopedPK11SymKey symKey(PK11_ImportSymKey(slot, mMechanism, PK11_OriginUnwrap, CKA_WRAP, &keyItem, nullptr)); if (!symKey) { return NS_ERROR_DOM_INVALID_ACCESS_ERR; } // Import the data to a SECItem SECItem dataItem = { siBuffer, nullptr, 0 }; ATTEMPT_BUFFER_TO_SECITEM(arena, &dataItem, mData); // Parameters for the fake keys CK_MECHANISM_TYPE fakeMechanism = CKM_SHA_1_HMAC; CK_ATTRIBUTE_TYPE fakeOperation = CKA_SIGN; if (mEncrypt) { // Import the data into a fake PK11SymKey structure ScopedPK11SymKey keyToWrap(PK11_ImportSymKey(slot, fakeMechanism, PK11_OriginUnwrap, fakeOperation, &dataItem, nullptr)); if (!keyToWrap) { return NS_ERROR_DOM_OPERATION_ERR; } // Encrypt and return the wrapped key // AES-KW encryption results in a wrapped key 64 bits longer if (!mResult.SetLength(mData.Length() + 8)) { return NS_ERROR_DOM_OPERATION_ERR; } SECItem resultItem = {siBuffer, mResult.Elements(), (unsigned int) mResult.Length()}; rv = MapSECStatus(PK11_WrapSymKey(mMechanism, nullptr, symKey.get(), keyToWrap.get(), &resultItem)); NS_ENSURE_SUCCESS(rv, NS_ERROR_DOM_OPERATION_ERR); } else { // Decrypt the ciphertext into a temporary PK11SymKey // Unwrapped key should be 64 bits shorter int keySize = mData.Length() - 8; ScopedPK11SymKey unwrappedKey(PK11_UnwrapSymKey(symKey, mMechanism, nullptr, &dataItem, fakeMechanism, fakeOperation, keySize)); if (!unwrappedKey) { return NS_ERROR_DOM_OPERATION_ERR; } // Export the key to get the cleartext rv = MapSECStatus(PK11_ExtractKeyValue(unwrappedKey)); if (NS_FAILED(rv)) { return NS_ERROR_DOM_UNKNOWN_ERR; } ATTEMPT_BUFFER_ASSIGN(mResult, PK11_GetKeyData(unwrappedKey)); } return rv; } }; class RsaOaepTask : public ReturnArrayBufferViewTask, public DeferredData { public: RsaOaepTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, bool aEncrypt) : mPrivKey(aKey.GetPrivateKey()) , mPubKey(aKey.GetPublicKey()) , mEncrypt(aEncrypt) { Init(aCx, aAlgorithm, aKey, aEncrypt); } RsaOaepTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const CryptoOperationData& aData, bool aEncrypt) : mPrivKey(aKey.GetPrivateKey()) , mPubKey(aKey.GetPublicKey()) , mEncrypt(aEncrypt) { Init(aCx, aAlgorithm, aKey, aEncrypt); SetData(aData); } void Init(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, bool aEncrypt) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, TA_RSA_OAEP); CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_RSA_OAEP); if (mEncrypt) { if (!mPubKey) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } mStrength = SECKEY_PublicKeyStrength(mPubKey); } else { if (!mPrivKey) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } mStrength = PK11_GetPrivateModulusLen(mPrivKey); } // The algorithm could just be given as a string // in which case there would be no label specified. if (!aAlgorithm.IsString()) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } if (params.mLabel.WasPassed()) { ATTEMPT_BUFFER_INIT(mLabel, params.mLabel.Value()); } } // Otherwise mLabel remains the empty octet string, as intended // Look up the MGF based on the KeyAlgorithm. // static_cast is safe because we only get here if the algorithm name // is RSA-OAEP, and that only happens if we've constructed // an RsaHashedKeyAlgorithm. mHashMechanism = KeyAlgorithmProxy::GetMechanism(aKey.Algorithm().mRsa.mHash); switch (mHashMechanism) { case CKM_SHA_1: mMgfMechanism = CKG_MGF1_SHA1; break; case CKM_SHA256: mMgfMechanism = CKG_MGF1_SHA256; break; case CKM_SHA384: mMgfMechanism = CKG_MGF1_SHA384; break; case CKM_SHA512: mMgfMechanism = CKG_MGF1_SHA512; break; default: mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } } private: CK_MECHANISM_TYPE mHashMechanism; CK_MECHANISM_TYPE mMgfMechanism; ScopedSECKEYPrivateKey mPrivKey; ScopedSECKEYPublicKey mPubKey; CryptoBuffer mLabel; uint32_t mStrength; bool mEncrypt; virtual nsresult DoCrypto() MOZ_OVERRIDE { nsresult rv; if (!mDataIsSet) { return NS_ERROR_DOM_OPERATION_ERR; } // Ciphertext is an integer mod the modulus, so it will be // no longer than mStrength octets if (!mResult.SetLength(mStrength)) { return NS_ERROR_DOM_UNKNOWN_ERR; } CK_RSA_PKCS_OAEP_PARAMS oaepParams; oaepParams.source = CKZ_DATA_SPECIFIED; oaepParams.pSourceData = mLabel.Length() ? mLabel.Elements() : nullptr; oaepParams.ulSourceDataLen = mLabel.Length(); oaepParams.mgf = mMgfMechanism; oaepParams.hashAlg = mHashMechanism; SECItem param; param.type = siBuffer; param.data = (unsigned char*) &oaepParams; param.len = sizeof(oaepParams); uint32_t outLen = 0; if (mEncrypt) { // PK11_PubEncrypt() checks the plaintext's length and fails if it is too // long to encrypt, i.e. if it is longer than (k - 2hLen - 2) with 'k' // being the length in octets of the RSA modulus n and 'hLen' being the // output length in octets of the chosen hash function. // rv = MapSECStatus(PK11_PubEncrypt( mPubKey.get(), CKM_RSA_PKCS_OAEP, ¶m, mResult.Elements(), &outLen, mResult.Length(), mData.Elements(), mData.Length(), nullptr)); } else { rv = MapSECStatus(PK11_PrivDecrypt( mPrivKey.get(), CKM_RSA_PKCS_OAEP, ¶m, mResult.Elements(), &outLen, mResult.Length(), mData.Elements(), mData.Length())); } NS_ENSURE_SUCCESS(rv, NS_ERROR_DOM_OPERATION_ERR); mResult.SetLength(outLen); return NS_OK; } }; class HmacTask : public WebCryptoTask { public: HmacTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const CryptoOperationData& aSignature, const CryptoOperationData& aData, bool aSign) : mMechanism(aKey.Algorithm().Mechanism()) , mSymKey(aKey.GetSymKey()) , mSign(aSign) { CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_HMAC); ATTEMPT_BUFFER_INIT(mData, aData); if (!aSign) { ATTEMPT_BUFFER_INIT(mSignature, aSignature); } // Check that we got a symmetric key if (mSymKey.Length() == 0) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } TelemetryAlgorithm telemetryAlg; switch (mMechanism) { case CKM_SHA_1_HMAC: telemetryAlg = TA_HMAC_SHA_1; break; case CKM_SHA224_HMAC: telemetryAlg = TA_HMAC_SHA_224; break; case CKM_SHA256_HMAC: telemetryAlg = TA_HMAC_SHA_256; break; case CKM_SHA384_HMAC: telemetryAlg = TA_HMAC_SHA_384; break; case CKM_SHA512_HMAC: telemetryAlg = TA_HMAC_SHA_512; break; default: telemetryAlg = TA_UNKNOWN; } Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, telemetryAlg); } private: CK_MECHANISM_TYPE mMechanism; CryptoBuffer mSymKey; CryptoBuffer mData; CryptoBuffer mSignature; CryptoBuffer mResult; bool mSign; virtual nsresult DoCrypto() MOZ_OVERRIDE { // Initialize the output buffer if (!mResult.SetLength(HASH_LENGTH_MAX)) { return NS_ERROR_DOM_UNKNOWN_ERR; } ScopedPLArenaPool arena(PORT_NewArena(DER_DEFAULT_CHUNKSIZE)); if (!arena) { return NS_ERROR_DOM_OPERATION_ERR; } // Import the key uint32_t outLen; SECItem keyItem = { siBuffer, nullptr, 0 }; ATTEMPT_BUFFER_TO_SECITEM(arena, &keyItem, mSymKey); ScopedPK11SlotInfo slot(PK11_GetInternalSlot()); MOZ_ASSERT(slot.get()); ScopedPK11SymKey symKey(PK11_ImportSymKey(slot, mMechanism, PK11_OriginUnwrap, CKA_SIGN, &keyItem, nullptr)); if (!symKey) { return NS_ERROR_DOM_INVALID_ACCESS_ERR; } // Compute the MAC SECItem param = { siBuffer, nullptr, 0 }; ScopedPK11Context ctx(PK11_CreateContextBySymKey(mMechanism, CKA_SIGN, symKey.get(), ¶m)); if (!ctx.get()) { return NS_ERROR_DOM_OPERATION_ERR; } nsresult rv = MapSECStatus(PK11_DigestBegin(ctx.get())); NS_ENSURE_SUCCESS(rv, NS_ERROR_DOM_OPERATION_ERR); rv = MapSECStatus(PK11_DigestOp(ctx.get(), mData.Elements(), mData.Length())); NS_ENSURE_SUCCESS(rv, NS_ERROR_DOM_OPERATION_ERR); rv = MapSECStatus(PK11_DigestFinal(ctx.get(), mResult.Elements(), &outLen, HASH_LENGTH_MAX)); NS_ENSURE_SUCCESS(rv, NS_ERROR_DOM_OPERATION_ERR); mResult.SetLength(outLen); return rv; } // Returns mResult as an ArrayBufferView, or an error virtual void Resolve() MOZ_OVERRIDE { if (mSign) { // Return the computed MAC TypedArrayCreator ret(mResult); mResultPromise->MaybeResolve(ret); } else { // Compare the MAC to the provided signature // No truncation allowed bool equal = (mResult.Length() == mSignature.Length()); if (equal) { int cmp = NSS_SecureMemcmp(mSignature.Elements(), mResult.Elements(), mSignature.Length()); equal = (cmp == 0); } mResultPromise->MaybeResolve(equal); } } }; class AsymmetricSignVerifyTask : public WebCryptoTask { public: AsymmetricSignVerifyTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const CryptoOperationData& aSignature, const CryptoOperationData& aData, bool aSign) : mOidTag(SEC_OID_UNKNOWN) , mPrivKey(aKey.GetPrivateKey()) , mPubKey(aKey.GetPublicKey()) , mSign(aSign) , mVerified(false) , mEcdsa(false) { ATTEMPT_BUFFER_INIT(mData, aData); if (!aSign) { ATTEMPT_BUFFER_INIT(mSignature, aSignature); } nsString algName; mEarlyRv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(mEarlyRv)) { return; } // Look up the SECOidTag if (algName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1)) { mEcdsa = false; Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, TA_RSASSA_PKCS1); CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_RSASSA_PKCS1); // For RSA, the hash name comes from the key algorithm nsString hashName = aKey.Algorithm().mRsa.mHash.mName; switch (MapAlgorithmNameToMechanism(hashName)) { case CKM_SHA_1: mOidTag = SEC_OID_PKCS1_SHA1_WITH_RSA_ENCRYPTION; break; case CKM_SHA256: mOidTag = SEC_OID_PKCS1_SHA256_WITH_RSA_ENCRYPTION; break; case CKM_SHA384: mOidTag = SEC_OID_PKCS1_SHA384_WITH_RSA_ENCRYPTION; break; case CKM_SHA512: mOidTag = SEC_OID_PKCS1_SHA512_WITH_RSA_ENCRYPTION; break; default: mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_ECDSA)) { mEcdsa = true; Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, TA_ECDSA); CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_ECDSA); // For ECDSA, the hash name comes from the algorithm parameter RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } nsString hashName; mEarlyRv = GetAlgorithmName(aCx, params.mHash, hashName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } CK_MECHANISM_TYPE hashMechanism = MapAlgorithmNameToMechanism(hashName); if (hashMechanism == UNKNOWN_CK_MECHANISM) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } switch (hashMechanism) { case CKM_SHA_1: mOidTag = SEC_OID_ANSIX962_ECDSA_SHA1_SIGNATURE; break; case CKM_SHA256: mOidTag = SEC_OID_ANSIX962_ECDSA_SHA256_SIGNATURE; break; case CKM_SHA384: mOidTag = SEC_OID_ANSIX962_ECDSA_SHA384_SIGNATURE; break; case CKM_SHA512: mOidTag = SEC_OID_ANSIX962_ECDSA_SHA512_SIGNATURE; break; default: mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } } else { // This shouldn't happen; CreateSignVerifyTask shouldn't create // one of these unless it's for the above algorithms. MOZ_ASSERT(false); } // Check that we have the appropriate key if ((mSign && !mPrivKey) || (!mSign && !mPubKey)) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } } private: SECOidTag mOidTag; ScopedSECKEYPrivateKey mPrivKey; ScopedSECKEYPublicKey mPubKey; CryptoBuffer mSignature; CryptoBuffer mData; bool mSign; bool mVerified; bool mEcdsa; virtual nsresult DoCrypto() MOZ_OVERRIDE { nsresult rv; if (mSign) { ScopedSECItem signature(::SECITEM_AllocItem(nullptr, nullptr, 0)); ScopedSGNContext ctx(SGN_NewContext(mOidTag, mPrivKey)); if (!signature.get() || !ctx.get()) { return NS_ERROR_DOM_OPERATION_ERR; } rv = MapSECStatus(SEC_SignData(signature, mData.Elements(), mData.Length(), mPrivKey, mOidTag)); if (mEcdsa) { // DER-decode the signature int signatureLength = PK11_SignatureLen(mPrivKey); ScopedSECItem rawSignature(DSAU_DecodeDerSigToLen(signature.get(), signatureLength)); if (!rawSignature.get()) { return NS_ERROR_DOM_OPERATION_ERR; } ATTEMPT_BUFFER_ASSIGN(mSignature, rawSignature); } else { ATTEMPT_BUFFER_ASSIGN(mSignature, signature); } } else { ScopedSECItem signature(::SECITEM_AllocItem(nullptr, nullptr, 0)); if (!signature.get()) { return NS_ERROR_DOM_UNKNOWN_ERR; } if (mEcdsa) { // DER-encode the signature ScopedSECItem rawSignature(::SECITEM_AllocItem(nullptr, nullptr, 0)); if (!rawSignature || !mSignature.ToSECItem(nullptr, rawSignature)) { return NS_ERROR_DOM_UNKNOWN_ERR; } rv = MapSECStatus(DSAU_EncodeDerSigWithLen(signature, rawSignature, rawSignature->len)); NS_ENSURE_SUCCESS(rv, NS_ERROR_DOM_OPERATION_ERR); } else if (!mSignature.ToSECItem(nullptr, signature)) { return NS_ERROR_DOM_UNKNOWN_ERR; } rv = MapSECStatus(VFY_VerifyData(mData.Elements(), mData.Length(), mPubKey, signature, mOidTag, nullptr)); mVerified = NS_SUCCEEDED(rv); } return NS_OK; } virtual void Resolve() MOZ_OVERRIDE { if (mSign) { TypedArrayCreator ret(mSignature); mResultPromise->MaybeResolve(ret); } else { mResultPromise->MaybeResolve(mVerified); } } }; class DigestTask : public ReturnArrayBufferViewTask { public: DigestTask(JSContext* aCx, const ObjectOrString& aAlgorithm, const CryptoOperationData& aData) { ATTEMPT_BUFFER_INIT(mData, aData); nsString algName; mEarlyRv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } TelemetryAlgorithm telemetryAlg; if (algName.EqualsLiteral(WEBCRYPTO_ALG_SHA1)) { mOidTag = SEC_OID_SHA1; telemetryAlg = TA_SHA_1; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_SHA256)) { mOidTag = SEC_OID_SHA256; telemetryAlg = TA_SHA_224; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_SHA384)) { mOidTag = SEC_OID_SHA384; telemetryAlg = TA_SHA_256; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_SHA512)) { mOidTag = SEC_OID_SHA512; telemetryAlg = TA_SHA_384; } else { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, telemetryAlg); } private: SECOidTag mOidTag; CryptoBuffer mData; virtual nsresult DoCrypto() MOZ_OVERRIDE { // Resize the result buffer uint32_t hashLen = HASH_ResultLenByOidTag(mOidTag); if (!mResult.SetLength(hashLen)) { return NS_ERROR_DOM_UNKNOWN_ERR; } // Compute the hash nsresult rv = MapSECStatus(PK11_HashBuf(mOidTag, mResult.Elements(), mData.Elements(), mData.Length())); if (NS_FAILED(rv)) { return NS_ERROR_DOM_UNKNOWN_ERR; } return rv; } }; class ImportKeyTask : public WebCryptoTask { public: void Init(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { mFormat = aFormat; mDataIsSet = false; mDataIsJwk = false; // Get the current global object from the context nsIGlobalObject *global = xpc::NativeGlobal(JS::CurrentGlobalOrNull(aCx)); if (!global) { mEarlyRv = NS_ERROR_DOM_UNKNOWN_ERR; return; } // This stuff pretty much always happens, so we'll do it here mKey = new CryptoKey(global); mKey->SetExtractable(aExtractable); mKey->ClearUsages(); for (uint32_t i = 0; i < aKeyUsages.Length(); ++i) { mEarlyRv = mKey->AddUsage(aKeyUsages[i]); if (NS_FAILED(mEarlyRv)) { return; } } mEarlyRv = GetAlgorithmName(aCx, aAlgorithm, mAlgName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } } static bool JwkCompatible(const JsonWebKey& aJwk, const CryptoKey* aKey) { // Check 'ext' if (aKey->Extractable() && aJwk.mExt.WasPassed() && !aJwk.mExt.Value()) { return false; } // Check 'alg' if (aJwk.mAlg.WasPassed() && aJwk.mAlg.Value() != aKey->Algorithm().JwkAlg()) { return false; } // Check 'key_ops' if (aJwk.mKey_ops.WasPassed()) { nsTArray usages; aKey->GetUsages(usages); for (size_t i = 0; i < usages.Length(); ++i) { if (!aJwk.mKey_ops.Value().Contains(usages[i])) { return false; } } } // Individual algorithms may still have to check 'use' return true; } void SetKeyData(JSContext* aCx, JS::Handle aKeyData) { // First try to treat as ArrayBuffer/ABV, // and if that fails, try to initialize a JWK if (CloneData(aCx, mKeyData, aKeyData)) { mDataIsJwk = false; if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { SetJwkFromKeyData(); } } else { ClearException ce(aCx); JS::RootedValue value(aCx, JS::ObjectValue(*aKeyData)); if (!mJwk.Init(aCx, value)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } mDataIsJwk = true; } } void SetKeyData(const CryptoBuffer& aKeyData) { mKeyData = aKeyData; mDataIsJwk = false; if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { SetJwkFromKeyData(); } } void SetJwkFromKeyData() { nsDependentCSubstring utf8((const char*) mKeyData.Elements(), (const char*) (mKeyData.Elements() + mKeyData.Length())); if (!IsUTF8(utf8)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } nsString json = NS_ConvertUTF8toUTF16(utf8); if (!mJwk.Init(json)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } mDataIsJwk = true; } protected: nsString mFormat; nsRefPtr mKey; CryptoBuffer mKeyData; bool mDataIsSet; bool mDataIsJwk; JsonWebKey mJwk; nsString mAlgName; private: virtual void Resolve() MOZ_OVERRIDE { mResultPromise->MaybeResolve(mKey); } virtual void Cleanup() MOZ_OVERRIDE { mKey = nullptr; } }; class ImportSymmetricKeyTask : public ImportKeyTask { public: ImportSymmetricKeyTask(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); } ImportSymmetricKeyTask(JSContext* aCx, const nsAString& aFormat, const JS::Handle aKeyData, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); if (NS_FAILED(mEarlyRv)) { return; } SetKeyData(aCx, aKeyData); NS_ENSURE_SUCCESS_VOID(mEarlyRv); if (mDataIsJwk && !mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } } void Init(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { ImportKeyTask::Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); if (NS_FAILED(mEarlyRv)) { return; } // If this is an HMAC key, import the hash name if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_HMAC)) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } mEarlyRv = GetAlgorithmName(aCx, params.mHash, mHashName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } } } virtual nsresult BeforeCrypto() MOZ_OVERRIDE { nsresult rv; // If we're doing a JWK import, import the key data if (mDataIsJwk) { if (!mJwk.mK.WasPassed()) { return NS_ERROR_DOM_DATA_ERR; } // Import the key material rv = mKeyData.FromJwkBase64(mJwk.mK.Value()); if (NS_FAILED(rv)) { return NS_ERROR_DOM_DATA_ERR; } } // Check that we have valid key data. if (mKeyData.Length() == 0) { return NS_ERROR_DOM_DATA_ERR; } // Construct an appropriate KeyAlorithm, // and verify that usages are appropriate uint32_t length = 8 * mKeyData.Length(); // bytes to bits if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || mAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || mAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM) || mAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW)) { if (mKey->HasUsageOtherThan(CryptoKey::ENCRYPT | CryptoKey::DECRYPT | CryptoKey::WRAPKEY | CryptoKey::UNWRAPKEY)) { return NS_ERROR_DOM_DATA_ERR; } if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW) && mKey->HasUsageOtherThan(CryptoKey::WRAPKEY | CryptoKey::UNWRAPKEY)) { return NS_ERROR_DOM_DATA_ERR; } if ( (length != 128) && (length != 192) && (length != 256) ) { return NS_ERROR_DOM_DATA_ERR; } mKey->Algorithm().MakeAes(mAlgName, length); if (mDataIsJwk && mJwk.mUse.WasPassed() && !mJwk.mUse.Value().EqualsLiteral(JWK_USE_ENC)) { return NS_ERROR_DOM_DATA_ERR; } } else if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_PBKDF2)) { if (mKey->HasUsageOtherThan(CryptoKey::DERIVEKEY | CryptoKey::DERIVEBITS)) { return NS_ERROR_DOM_DATA_ERR; } mKey->Algorithm().MakeAes(mAlgName, length); if (mDataIsJwk && mJwk.mUse.WasPassed()) { // There is not a 'use' value consistent with PBKDF return NS_ERROR_DOM_DATA_ERR; }; } else if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_HMAC)) { if (mKey->HasUsageOtherThan(CryptoKey::SIGN | CryptoKey::VERIFY)) { return NS_ERROR_DOM_DATA_ERR; } mKey->Algorithm().MakeHmac(length, mHashName); if (mKey->Algorithm().Mechanism() == UNKNOWN_CK_MECHANISM) { return NS_ERROR_DOM_SYNTAX_ERR; } if (mDataIsJwk && mJwk.mUse.WasPassed() && !mJwk.mUse.Value().EqualsLiteral(JWK_USE_SIG)) { return NS_ERROR_DOM_DATA_ERR; } } else { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } mKey->SetSymKey(mKeyData); mKey->SetType(CryptoKey::SECRET); if (mDataIsJwk && !JwkCompatible(mJwk, mKey)) { return NS_ERROR_DOM_DATA_ERR; } mEarlyComplete = true; return NS_OK; } private: nsString mHashName; }; class ImportRsaKeyTask : public ImportKeyTask { public: ImportRsaKeyTask(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); } ImportRsaKeyTask(JSContext* aCx, const nsAString& aFormat, JS::Handle aKeyData, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); if (NS_FAILED(mEarlyRv)) { return; } SetKeyData(aCx, aKeyData); NS_ENSURE_SUCCESS_VOID(mEarlyRv); if (mDataIsJwk && !mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } } void Init(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { ImportKeyTask::Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); if (NS_FAILED(mEarlyRv)) { return; } // If this is RSA with a hash, cache the hash name if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1) || mAlgName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } mEarlyRv = GetAlgorithmName(aCx, params.mHash, mHashName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } } // Check support for the algorithm and hash names CK_MECHANISM_TYPE mech1 = MapAlgorithmNameToMechanism(mAlgName); CK_MECHANISM_TYPE mech2 = MapAlgorithmNameToMechanism(mHashName); if ((mech1 == UNKNOWN_CK_MECHANISM) || (mech2 == UNKNOWN_CK_MECHANISM)) { mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } } private: nsString mHashName; uint32_t mModulusLength; CryptoBuffer mPublicExponent; virtual nsresult DoCrypto() MOZ_OVERRIDE { nsNSSShutDownPreventionLock locker; // Import the key data itself ScopedSECKEYPublicKey pubKey; ScopedSECKEYPrivateKey privKey; if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI) || (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK) && !mJwk.mD.WasPassed())) { // Public key import if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI)) { pubKey = CryptoKey::PublicKeyFromSpki(mKeyData, locker); } else { pubKey = CryptoKey::PublicKeyFromJwk(mJwk, locker); } if (!pubKey) { return NS_ERROR_DOM_DATA_ERR; } mKey->SetPublicKey(pubKey.get()); mKey->SetType(CryptoKey::PUBLIC); } else if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_PKCS8) || (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK) && mJwk.mD.WasPassed())) { // Private key import if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_PKCS8)) { privKey = CryptoKey::PrivateKeyFromPkcs8(mKeyData, locker); } else { privKey = CryptoKey::PrivateKeyFromJwk(mJwk, locker); } if (!privKey) { return NS_ERROR_DOM_DATA_ERR; } mKey->SetPrivateKey(privKey.get()); mKey->SetType(CryptoKey::PRIVATE); pubKey = SECKEY_ConvertToPublicKey(privKey.get()); if (!pubKey) { return NS_ERROR_DOM_UNKNOWN_ERR; } } else { // Invalid key format return NS_ERROR_DOM_SYNTAX_ERR; } // Extract relevant information from the public key mModulusLength = 8 * pubKey->u.rsa.modulus.len; mPublicExponent.Assign(&pubKey->u.rsa.publicExponent); return NS_OK; } virtual nsresult AfterCrypto() MOZ_OVERRIDE { // Check permissions for the requested operation if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { if ((mKey->GetKeyType() == CryptoKey::PUBLIC && mKey->HasUsageOtherThan(CryptoKey::ENCRYPT | CryptoKey::WRAPKEY)) || (mKey->GetKeyType() == CryptoKey::PRIVATE && mKey->HasUsageOtherThan(CryptoKey::DECRYPT | CryptoKey::UNWRAPKEY))) { return NS_ERROR_DOM_DATA_ERR; } } else if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1)) { if ((mKey->GetKeyType() == CryptoKey::PUBLIC && mKey->HasUsageOtherThan(CryptoKey::VERIFY)) || (mKey->GetKeyType() == CryptoKey::PRIVATE && mKey->HasUsageOtherThan(CryptoKey::SIGN))) { return NS_ERROR_DOM_DATA_ERR; } } // Set an appropriate KeyAlgorithm mKey->Algorithm().MakeRsa(mAlgName, mModulusLength, mPublicExponent, mHashName); if (mDataIsJwk && !JwkCompatible(mJwk, mKey)) { return NS_ERROR_DOM_DATA_ERR; } return NS_OK; } }; class ImportEcKeyTask : public ImportKeyTask { public: ImportEcKeyTask(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { ImportKeyTask::Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); } ImportEcKeyTask(JSContext* aCx, const nsAString& aFormat, JS::Handle aKeyData, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { ImportKeyTask::Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); if (NS_FAILED(mEarlyRv)) { return; } SetKeyData(aCx, aKeyData); NS_ENSURE_SUCCESS_VOID(mEarlyRv); } private: nsString mNamedCurve; virtual nsresult DoCrypto() MOZ_OVERRIDE { // Import the key data itself ScopedSECKEYPublicKey pubKey; ScopedSECKEYPrivateKey privKey; nsNSSShutDownPreventionLock locker; if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK) && mJwk.mD.WasPassed()) { // Private key import privKey = CryptoKey::PrivateKeyFromJwk(mJwk, locker); if (!privKey) { return NS_ERROR_DOM_DATA_ERR; } mKey->SetPrivateKey(privKey.get()); mKey->SetType(CryptoKey::PRIVATE); } else if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI) || (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK) && !mJwk.mD.WasPassed())) { // Public key import if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI)) { pubKey = CryptoKey::PublicKeyFromSpki(mKeyData, locker); } else { pubKey = CryptoKey::PublicKeyFromJwk(mJwk, locker); } if (!pubKey) { return NS_ERROR_DOM_DATA_ERR; } if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI)) { if (!CheckEncodedECParameters(&pubKey->u.ec.DEREncodedParams)) { return NS_ERROR_DOM_OPERATION_ERR; } // Construct the OID tag. SECItem oid = { siBuffer, nullptr, 0 }; oid.len = pubKey->u.ec.DEREncodedParams.data[1]; oid.data = pubKey->u.ec.DEREncodedParams.data + 2; // Find a matching and supported named curve. if (!MapOIDTagToNamedCurve(SECOID_FindOIDTag(&oid), mNamedCurve)) { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } } mKey->SetPublicKey(pubKey.get()); mKey->SetType(CryptoKey::PUBLIC); } else { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } // Extract 'crv' parameter from JWKs. if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { if (!NormalizeToken(mJwk.mCrv.Value(), mNamedCurve)) { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } } return NS_OK; } virtual nsresult AfterCrypto() MOZ_OVERRIDE { uint32_t privateAllowedUsages = 0, publicAllowedUsages = 0; if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_ECDH)) { privateAllowedUsages = CryptoKey::DERIVEBITS | CryptoKey::DERIVEKEY; publicAllowedUsages = CryptoKey::DERIVEBITS | CryptoKey::DERIVEKEY; } else if (mAlgName.EqualsLiteral(WEBCRYPTO_ALG_ECDSA)) { privateAllowedUsages = CryptoKey::SIGN; publicAllowedUsages = CryptoKey::VERIFY; } // Check permissions for the requested operation if ((mKey->GetKeyType() == CryptoKey::PRIVATE && mKey->HasUsageOtherThan(privateAllowedUsages)) || (mKey->GetKeyType() == CryptoKey::PUBLIC && mKey->HasUsageOtherThan(publicAllowedUsages))) { return NS_ERROR_DOM_DATA_ERR; } mKey->Algorithm().MakeEc(mAlgName, mNamedCurve); if (mDataIsJwk && !JwkCompatible(mJwk, mKey)) { return NS_ERROR_DOM_DATA_ERR; } return NS_OK; } }; class ImportDhKeyTask : public ImportKeyTask { public: ImportDhKeyTask(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); } ImportDhKeyTask(JSContext* aCx, const nsAString& aFormat, JS::Handle aKeyData, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); if (NS_SUCCEEDED(mEarlyRv)) { SetKeyData(aCx, aKeyData); NS_ENSURE_SUCCESS_VOID(mEarlyRv); } } void Init(JSContext* aCx, const nsAString& aFormat, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { ImportKeyTask::Init(aCx, aFormat, aAlgorithm, aExtractable, aKeyUsages); if (NS_FAILED(mEarlyRv)) { return; } if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_RAW)) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } CryptoBuffer prime; ATTEMPT_BUFFER_INIT(mPrime, params.mPrime); CryptoBuffer generator; ATTEMPT_BUFFER_INIT(mGenerator, params.mGenerator); } } private: CryptoBuffer mPrime; CryptoBuffer mGenerator; virtual nsresult DoCrypto() MOZ_OVERRIDE { // Import the key data itself ScopedSECKEYPublicKey pubKey; nsNSSShutDownPreventionLock locker; if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_RAW) || mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI)) { // Public key import if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_RAW)) { pubKey = CryptoKey::PublicDhKeyFromRaw(mKeyData, mPrime, mGenerator, locker); } else if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI)) { pubKey = CryptoKey::PublicKeyFromSpki(mKeyData, locker); } else { MOZ_ASSERT(false); } if (!pubKey) { return NS_ERROR_DOM_DATA_ERR; } if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI)) { ATTEMPT_BUFFER_ASSIGN(mPrime, &pubKey->u.dh.prime); ATTEMPT_BUFFER_ASSIGN(mGenerator, &pubKey->u.dh.base); } mKey->SetPublicKey(pubKey.get()); mKey->SetType(CryptoKey::PUBLIC); } else { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } return NS_OK; } virtual nsresult AfterCrypto() MOZ_OVERRIDE { // Check permissions for the requested operation if (mKey->HasUsageOtherThan(CryptoKey::DERIVEBITS | CryptoKey::DERIVEKEY)) { return NS_ERROR_DOM_DATA_ERR; } mKey->Algorithm().MakeDh(mAlgName, mPrime, mGenerator); return NS_OK; } }; class ExportKeyTask : public WebCryptoTask { public: ExportKeyTask(const nsAString& aFormat, CryptoKey& aKey) : mFormat(aFormat) , mSymKey(aKey.GetSymKey()) , mPrivateKey(aKey.GetPrivateKey()) , mPublicKey(aKey.GetPublicKey()) , mKeyType(aKey.GetKeyType()) , mExtractable(aKey.Extractable()) , mAlg(aKey.Algorithm().JwkAlg()) { aKey.GetUsages(mKeyUsages); } protected: nsString mFormat; CryptoBuffer mSymKey; ScopedSECKEYPrivateKey mPrivateKey; ScopedSECKEYPublicKey mPublicKey; CryptoKey::KeyType mKeyType; bool mExtractable; nsString mAlg; nsTArray mKeyUsages; CryptoBuffer mResult; JsonWebKey mJwk; private: virtual void ReleaseNSSResources() MOZ_OVERRIDE { mPrivateKey.dispose(); mPublicKey.dispose(); } virtual nsresult DoCrypto() MOZ_OVERRIDE { nsNSSShutDownPreventionLock locker; if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_RAW)) { if (mPublicKey && mPublicKey->keyType == dhKey) { nsresult rv = CryptoKey::PublicDhKeyToRaw(mPublicKey, mResult, locker); if (NS_FAILED(rv)) { return NS_ERROR_DOM_OPERATION_ERR; } return NS_OK; } mResult = mSymKey; if (mResult.Length() == 0) { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } return NS_OK; } else if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_PKCS8)) { if (!mPrivateKey) { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } switch (mPrivateKey->keyType) { case rsaKey: CryptoKey::PrivateKeyToPkcs8(mPrivateKey.get(), mResult, locker); return NS_OK; default: return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } } else if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI)) { if (!mPublicKey) { return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } return CryptoKey::PublicKeyToSpki(mPublicKey.get(), mResult, locker); } else if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { if (mKeyType == CryptoKey::SECRET) { nsString k; nsresult rv = mSymKey.ToJwkBase64(k); if (NS_FAILED(rv)) { return NS_ERROR_DOM_OPERATION_ERR; } mJwk.mK.Construct(k); mJwk.mKty = NS_LITERAL_STRING(JWK_TYPE_SYMMETRIC); } else if (mKeyType == CryptoKey::PUBLIC) { if (!mPublicKey) { return NS_ERROR_DOM_UNKNOWN_ERR; } nsresult rv = CryptoKey::PublicKeyToJwk(mPublicKey, mJwk, locker); if (NS_FAILED(rv)) { return NS_ERROR_DOM_OPERATION_ERR; } } else if (mKeyType == CryptoKey::PRIVATE) { if (!mPrivateKey) { return NS_ERROR_DOM_UNKNOWN_ERR; } nsresult rv = CryptoKey::PrivateKeyToJwk(mPrivateKey, mJwk, locker); if (NS_FAILED(rv)) { return NS_ERROR_DOM_OPERATION_ERR; } } if (!mAlg.IsEmpty()) { mJwk.mAlg.Construct(mAlg); } mJwk.mExt.Construct(mExtractable); if (!mKeyUsages.IsEmpty()) { mJwk.mKey_ops.Construct(); mJwk.mKey_ops.Value().AppendElements(mKeyUsages); } return NS_OK; } return NS_ERROR_DOM_SYNTAX_ERR; } // Returns mResult as an ArrayBufferView or JWK, as appropriate virtual void Resolve() MOZ_OVERRIDE { if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { mResultPromise->MaybeResolve(mJwk); return; } TypedArrayCreator ret(mResult); mResultPromise->MaybeResolve(ret); } }; class GenerateSymmetricKeyTask : public WebCryptoTask { public: GenerateSymmetricKeyTask(JSContext* aCx, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { nsIGlobalObject* global = xpc::NativeGlobal(JS::CurrentGlobalOrNull(aCx)); if (!global) { mEarlyRv = NS_ERROR_DOM_UNKNOWN_ERR; return; } // Create an empty key and set easy attributes mKey = new CryptoKey(global); mKey->SetExtractable(aExtractable); mKey->SetType(CryptoKey::SECRET); // Extract algorithm name nsString algName; mEarlyRv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } // Construct an appropriate KeyAlorithm uint32_t allowedUsages = 0; if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW)) { mEarlyRv = GetKeyLengthForAlgorithm(aCx, aAlgorithm, mLength); if (NS_FAILED(mEarlyRv)) { return; } mKey->Algorithm().MakeAes(algName, mLength); allowedUsages = CryptoKey::ENCRYPT | CryptoKey::DECRYPT | CryptoKey::WRAPKEY | CryptoKey::UNWRAPKEY; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_HMAC)) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } nsString hashName; mEarlyRv = GetAlgorithmName(aCx, params.mHash, hashName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } if (params.mLength.WasPassed()) { mLength = params.mLength.Value(); } else { mLength = MapHashAlgorithmNameToBlockSize(hashName); } if (mLength == 0) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } mKey->Algorithm().MakeHmac(mLength, hashName); allowedUsages = CryptoKey::SIGN | CryptoKey::VERIFY; } else { mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } // Add key usages mKey->ClearUsages(); for (uint32_t i = 0; i < aKeyUsages.Length(); ++i) { mEarlyRv = mKey->AddUsageIntersecting(aKeyUsages[i], allowedUsages); if (NS_FAILED(mEarlyRv)) { return; } } mLength = mLength >> 3; // bits to bytes mMechanism = mKey->Algorithm().Mechanism(); // SetSymKey done in Resolve, after we've done the keygen } private: nsRefPtr mKey; size_t mLength; CK_MECHANISM_TYPE mMechanism; CryptoBuffer mKeyData; virtual nsresult DoCrypto() MOZ_OVERRIDE { ScopedPK11SlotInfo slot(PK11_GetInternalSlot()); MOZ_ASSERT(slot.get()); ScopedPK11SymKey symKey(PK11_KeyGen(slot.get(), mMechanism, nullptr, mLength, nullptr)); if (!symKey) { return NS_ERROR_DOM_UNKNOWN_ERR; } nsresult rv = MapSECStatus(PK11_ExtractKeyValue(symKey)); if (NS_FAILED(rv)) { return NS_ERROR_DOM_UNKNOWN_ERR; } // This doesn't leak, because the SECItem* returned by PK11_GetKeyData // just refers to a buffer managed by symKey. The assignment copies the // data, so mKeyData manages one copy, while symKey manages another. ATTEMPT_BUFFER_ASSIGN(mKeyData, PK11_GetKeyData(symKey)); return NS_OK; } virtual void Resolve() { mKey->SetSymKey(mKeyData); mResultPromise->MaybeResolve(mKey); } virtual void Cleanup() { mKey = nullptr; } }; class GenerateAsymmetricKeyTask : public WebCryptoTask { public: GenerateAsymmetricKeyTask(JSContext* aCx, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { nsIGlobalObject* global = xpc::NativeGlobal(JS::CurrentGlobalOrNull(aCx)); if (!global) { mEarlyRv = NS_ERROR_DOM_UNKNOWN_ERR; return; } mArena = PORT_NewArena(DER_DEFAULT_CHUNKSIZE); if (!mArena) { mEarlyRv = NS_ERROR_DOM_UNKNOWN_ERR; return; } // Create an empty key and set easy attributes mKeyPair.mPrivateKey = new CryptoKey(global); mKeyPair.mPublicKey = new CryptoKey(global); // Extract algorithm name nsString algName; mEarlyRv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } // Construct an appropriate KeyAlorithm uint32_t privateAllowedUsages = 0, publicAllowedUsages = 0; if (algName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1) || algName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } // Pull relevant info uint32_t modulusLength = params.mModulusLength; CryptoBuffer publicExponent; ATTEMPT_BUFFER_INIT(publicExponent, params.mPublicExponent); nsString hashName; mEarlyRv = GetAlgorithmName(aCx, params.mHash, hashName); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } // Create algorithm mKeyPair.mPublicKey.get()->Algorithm().MakeRsa(algName, modulusLength, publicExponent, hashName); mKeyPair.mPrivateKey.get()->Algorithm().MakeRsa(algName, modulusLength, publicExponent, hashName); mMechanism = CKM_RSA_PKCS_KEY_PAIR_GEN; // Set up params struct mRsaParams.keySizeInBits = modulusLength; bool converted = publicExponent.GetBigIntValue(mRsaParams.pe); if (!converted) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_ECDH) || algName.EqualsLiteral(WEBCRYPTO_ALG_ECDSA)) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } if (!NormalizeToken(params.mNamedCurve, mNamedCurve)) { mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } // Create algorithm. mKeyPair.mPublicKey.get()->Algorithm().MakeEc(algName, mNamedCurve); mKeyPair.mPrivateKey.get()->Algorithm().MakeEc(algName, mNamedCurve); mMechanism = CKM_EC_KEY_PAIR_GEN; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_DH)) { RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } CryptoBuffer prime; ATTEMPT_BUFFER_INIT(prime, params.mPrime); CryptoBuffer generator; ATTEMPT_BUFFER_INIT(generator, params.mGenerator); // Set up params. if (!prime.ToSECItem(mArena, &mDhParams.prime) || !generator.ToSECItem(mArena, &mDhParams.base)) { mEarlyRv = NS_ERROR_DOM_UNKNOWN_ERR; return; } // Create algorithm. mKeyPair.mPublicKey.get()->Algorithm().MakeDh(algName, prime, generator); mKeyPair.mPrivateKey.get()->Algorithm().MakeDh(algName, prime, generator); mMechanism = CKM_DH_PKCS_KEY_PAIR_GEN; } else { mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } // Set key usages. if (algName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1) || algName.EqualsLiteral(WEBCRYPTO_ALG_ECDSA)) { privateAllowedUsages = CryptoKey::SIGN; publicAllowedUsages = CryptoKey::VERIFY; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { privateAllowedUsages = CryptoKey::DECRYPT | CryptoKey::UNWRAPKEY; publicAllowedUsages = CryptoKey::ENCRYPT | CryptoKey::WRAPKEY; } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_ECDH) || algName.EqualsLiteral(WEBCRYPTO_ALG_DH)) { privateAllowedUsages = CryptoKey::DERIVEKEY | CryptoKey::DERIVEBITS; publicAllowedUsages = 0; } mKeyPair.mPrivateKey.get()->SetExtractable(aExtractable); mKeyPair.mPrivateKey.get()->SetType(CryptoKey::PRIVATE); mKeyPair.mPublicKey.get()->SetExtractable(true); mKeyPair.mPublicKey.get()->SetType(CryptoKey::PUBLIC); mKeyPair.mPrivateKey.get()->ClearUsages(); mKeyPair.mPublicKey.get()->ClearUsages(); for (uint32_t i=0; i < aKeyUsages.Length(); ++i) { mEarlyRv = mKeyPair.mPrivateKey.get()->AddUsageIntersecting(aKeyUsages[i], privateAllowedUsages); if (NS_FAILED(mEarlyRv)) { return; } mEarlyRv = mKeyPair.mPublicKey.get()->AddUsageIntersecting(aKeyUsages[i], publicAllowedUsages); if (NS_FAILED(mEarlyRv)) { return; } } // If no usages ended up being allowed, DataError if (!mKeyPair.mPublicKey.get()->HasAnyUsage() && !mKeyPair.mPrivateKey.get()->HasAnyUsage()) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } } private: ScopedPLArenaPool mArena; CryptoKeyPair mKeyPair; CK_MECHANISM_TYPE mMechanism; PK11RSAGenParams mRsaParams; SECKEYDHParams mDhParams; ScopedSECKEYPublicKey mPublicKey; ScopedSECKEYPrivateKey mPrivateKey; nsString mNamedCurve; virtual void ReleaseNSSResources() MOZ_OVERRIDE { mPublicKey.dispose(); mPrivateKey.dispose(); } virtual nsresult DoCrypto() MOZ_OVERRIDE { ScopedPK11SlotInfo slot(PK11_GetInternalSlot()); MOZ_ASSERT(slot.get()); void* param; switch (mMechanism) { case CKM_RSA_PKCS_KEY_PAIR_GEN: param = &mRsaParams; break; case CKM_DH_PKCS_KEY_PAIR_GEN: param = &mDhParams; break; case CKM_EC_KEY_PAIR_GEN: { param = CreateECParamsForCurve(mNamedCurve, mArena); if (!param) { return NS_ERROR_DOM_UNKNOWN_ERR; } break; } default: return NS_ERROR_DOM_NOT_SUPPORTED_ERR; } SECKEYPublicKey* pubKey = nullptr; mPrivateKey = PK11_GenerateKeyPair(slot.get(), mMechanism, param, &pubKey, PR_FALSE, PR_FALSE, nullptr); mPublicKey = pubKey; if (!mPrivateKey.get() || !mPublicKey.get()) { return NS_ERROR_DOM_UNKNOWN_ERR; } mKeyPair.mPrivateKey.get()->SetPrivateKey(mPrivateKey); mKeyPair.mPublicKey.get()->SetPublicKey(mPublicKey); return NS_OK; } virtual void Resolve() MOZ_OVERRIDE { mResultPromise->MaybeResolve(mKeyPair); } }; class DerivePbkdfBitsTask : public ReturnArrayBufferViewTask { public: DerivePbkdfBitsTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, uint32_t aLength) : mSymKey(aKey.GetSymKey()) { Init(aCx, aAlgorithm, aKey, aLength); } DerivePbkdfBitsTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const ObjectOrString& aTargetAlgorithm) : mSymKey(aKey.GetSymKey()) { size_t length; mEarlyRv = GetKeyLengthForAlgorithm(aCx, aTargetAlgorithm, length); if (NS_SUCCEEDED(mEarlyRv)) { Init(aCx, aAlgorithm, aKey, length); } } void Init(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, uint32_t aLength) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, TA_PBKDF2); CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_PBKDF2); // Check that we got a symmetric key if (mSymKey.Length() == 0) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } // length must be a multiple of 8 bigger than zero. if (aLength == 0 || aLength % 8) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } // Extract the hash algorithm. nsString hashName; mEarlyRv = GetAlgorithmName(aCx, params.mHash, hashName); if (NS_FAILED(mEarlyRv)) { return; } // Check the given hash algorithm. switch (MapAlgorithmNameToMechanism(hashName)) { case CKM_SHA_1: mHashOidTag = SEC_OID_HMAC_SHA1; break; case CKM_SHA256: mHashOidTag = SEC_OID_HMAC_SHA256; break; case CKM_SHA384: mHashOidTag = SEC_OID_HMAC_SHA384; break; case CKM_SHA512: mHashOidTag = SEC_OID_HMAC_SHA512; break; default: mEarlyRv = NS_ERROR_DOM_NOT_SUPPORTED_ERR; return; } ATTEMPT_BUFFER_INIT(mSalt, params.mSalt) mLength = aLength >> 3; // bits to bytes mIterations = params.mIterations; } private: size_t mLength; size_t mIterations; CryptoBuffer mSalt; CryptoBuffer mSymKey; SECOidTag mHashOidTag; virtual nsresult DoCrypto() MOZ_OVERRIDE { ScopedPLArenaPool arena(PORT_NewArena(DER_DEFAULT_CHUNKSIZE)); if (!arena) { return NS_ERROR_DOM_OPERATION_ERR; } SECItem salt = { siBuffer, nullptr, 0 }; ATTEMPT_BUFFER_TO_SECITEM(arena, &salt, mSalt); // Always pass in cipherAlg=SEC_OID_HMAC_SHA1 (i.e. PBMAC1) as this // parameter is unused for key generation. It is currently only used // for PBKDF2 authentication or key (un)wrapping when specifying an // encryption algorithm (PBES2). ScopedSECAlgorithmID alg_id(PK11_CreatePBEV2AlgorithmID( SEC_OID_PKCS5_PBKDF2, SEC_OID_HMAC_SHA1, mHashOidTag, mLength, mIterations, &salt)); if (!alg_id.get()) { return NS_ERROR_DOM_OPERATION_ERR; } ScopedPK11SlotInfo slot(PK11_GetInternalSlot()); if (!slot.get()) { return NS_ERROR_DOM_OPERATION_ERR; } SECItem keyItem = { siBuffer, nullptr, 0 }; ATTEMPT_BUFFER_TO_SECITEM(arena, &keyItem, mSymKey); ScopedPK11SymKey symKey(PK11_PBEKeyGen(slot, alg_id, &keyItem, false, nullptr)); if (!symKey.get()) { return NS_ERROR_DOM_OPERATION_ERR; } nsresult rv = MapSECStatus(PK11_ExtractKeyValue(symKey)); if (NS_FAILED(rv)) { return NS_ERROR_DOM_OPERATION_ERR; } // This doesn't leak, because the SECItem* returned by PK11_GetKeyData // just refers to a buffer managed by symKey. The assignment copies the // data, so mResult manages one copy, while symKey manages another. ATTEMPT_BUFFER_ASSIGN(mResult, PK11_GetKeyData(symKey)); return NS_OK; } }; template class DeriveKeyTask : public DeriveBitsTask { public: DeriveKeyTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aBaseKey, const ObjectOrString& aDerivedKeyType, bool aExtractable, const Sequence& aKeyUsages) : DeriveBitsTask(aCx, aAlgorithm, aBaseKey, aDerivedKeyType) , mResolved(false) { if (NS_FAILED(this->mEarlyRv)) { return; } NS_NAMED_LITERAL_STRING(format, WEBCRYPTO_KEY_FORMAT_RAW); mTask = new ImportSymmetricKeyTask(aCx, format, aDerivedKeyType, aExtractable, aKeyUsages); } protected: nsRefPtr mTask; bool mResolved; private: virtual void Resolve() MOZ_OVERRIDE { mTask->SetKeyData(this->mResult); mTask->DispatchWithPromise(this->mResultPromise); mResolved = true; } virtual void Cleanup() MOZ_OVERRIDE { if (mTask && !mResolved) { mTask->Skip(); } mTask = nullptr; } }; class DeriveEcdhBitsTask : public ReturnArrayBufferViewTask { public: DeriveEcdhBitsTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, uint32_t aLength) : mLength(aLength), mPrivKey(aKey.GetPrivateKey()) { Init(aCx, aAlgorithm, aKey); } DeriveEcdhBitsTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const ObjectOrString& aTargetAlgorithm) : mPrivKey(aKey.GetPrivateKey()) { mEarlyRv = GetKeyLengthForAlgorithm(aCx, aTargetAlgorithm, mLength); if (NS_SUCCEEDED(mEarlyRv)) { Init(aCx, aAlgorithm, aKey); } } void Init(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_ALG, TA_ECDH); CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_ECDH); // Check that we have a private key. if (!mPrivKey) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } // Length must be a multiple of 8 bigger than zero. if (mLength == 0 || mLength % 8) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } mLength = mLength >> 3; // bits to bytes // Retrieve the peer's public key. RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } CryptoKey* publicKey = params.mPublic; mPubKey = publicKey->GetPublicKey(); if (!mPubKey) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } CHECK_KEY_ALGORITHM(publicKey->Algorithm(), WEBCRYPTO_ALG_ECDH); // Both keys must use the same named curve. nsString curve1 = aKey.Algorithm().mEc.mNamedCurve; nsString curve2 = publicKey->Algorithm().mEc.mNamedCurve; if (!curve1.Equals(curve2)) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } } private: size_t mLength; ScopedSECKEYPrivateKey mPrivKey; ScopedSECKEYPublicKey mPubKey; virtual nsresult DoCrypto() MOZ_OVERRIDE { // CKM_SHA512_HMAC and CKA_SIGN are key type and usage attributes of the // derived symmetric key and don't matter because we ignore them anyway. ScopedPK11SymKey symKey(PK11_PubDeriveWithKDF( mPrivKey, mPubKey, PR_FALSE, nullptr, nullptr, CKM_ECDH1_DERIVE, CKM_SHA512_HMAC, CKA_SIGN, 0, CKD_NULL, nullptr, nullptr)); if (!symKey.get()) { return NS_ERROR_DOM_OPERATION_ERR; } nsresult rv = MapSECStatus(PK11_ExtractKeyValue(symKey)); if (NS_FAILED(rv)) { return NS_ERROR_DOM_OPERATION_ERR; } // This doesn't leak, because the SECItem* returned by PK11_GetKeyData // just refers to a buffer managed by symKey. The assignment copies the // data, so mResult manages one copy, while symKey manages another. ATTEMPT_BUFFER_ASSIGN(mResult, PK11_GetKeyData(symKey)); if (mLength > mResult.Length()) { return NS_ERROR_DOM_DATA_ERR; } if (!mResult.SetLength(mLength)) { return NS_ERROR_DOM_UNKNOWN_ERR; } return NS_OK; } }; class DeriveDhBitsTask : public ReturnArrayBufferViewTask { public: DeriveDhBitsTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, uint32_t aLength) : mLength(aLength), mPrivKey(aKey.GetPrivateKey()) { Init(aCx, aAlgorithm, aKey); } DeriveDhBitsTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const ObjectOrString& aTargetAlgorithm) : mPrivKey(aKey.GetPrivateKey()) { mEarlyRv = GetKeyLengthForAlgorithm(aCx, aTargetAlgorithm, mLength); if (NS_SUCCEEDED(mEarlyRv)) { Init(aCx, aAlgorithm, aKey); } } void Init(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey) { CHECK_KEY_ALGORITHM(aKey.Algorithm(), WEBCRYPTO_ALG_DH); // Check that we have a private key. if (!mPrivKey) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } mLength = mLength >> 3; // bits to bytes // Retrieve the peer's public key. RootedDictionary params(aCx); mEarlyRv = Coerce(aCx, params, aAlgorithm); if (NS_FAILED(mEarlyRv)) { mEarlyRv = NS_ERROR_DOM_SYNTAX_ERR; return; } CryptoKey* publicKey = params.mPublic; mPubKey = publicKey->GetPublicKey(); if (!mPubKey) { mEarlyRv = NS_ERROR_DOM_INVALID_ACCESS_ERR; return; } KeyAlgorithmProxy alg1 = publicKey->Algorithm(); CHECK_KEY_ALGORITHM(alg1, WEBCRYPTO_ALG_DH); // Both keys must use the same prime and generator. KeyAlgorithmProxy alg2 = aKey.Algorithm(); if (alg1.mDh.mPrime != alg2.mDh.mPrime || alg1.mDh.mGenerator != alg2.mDh.mGenerator) { mEarlyRv = NS_ERROR_DOM_DATA_ERR; return; } } private: size_t mLength; ScopedSECKEYPrivateKey mPrivKey; ScopedSECKEYPublicKey mPubKey; virtual nsresult DoCrypto() MOZ_OVERRIDE { // CKM_SHA512_HMAC and CKA_SIGN are key type and usage attributes of the // derived symmetric key and don't matter because we ignore them anyway. ScopedPK11SymKey symKey(PK11_PubDeriveWithKDF( mPrivKey, mPubKey, PR_FALSE, nullptr, nullptr, CKM_DH_PKCS_DERIVE, CKM_SHA512_HMAC, CKA_SIGN, 0, CKD_NULL, nullptr, nullptr)); if (!symKey.get()) { return NS_ERROR_DOM_OPERATION_ERR; } nsresult rv = MapSECStatus(PK11_ExtractKeyValue(symKey)); if (NS_FAILED(rv)) { return NS_ERROR_DOM_OPERATION_ERR; } // This doesn't leak, because the SECItem* returned by PK11_GetKeyData // just refers to a buffer managed by symKey. The assignment copies the // data, so mResult manages one copy, while symKey manages another. ATTEMPT_BUFFER_ASSIGN(mResult, PK11_GetKeyData(symKey)); if (mLength > mResult.Length()) { return NS_ERROR_DOM_DATA_ERR; } if (!mResult.SetLength(mLength)) { return NS_ERROR_DOM_UNKNOWN_ERR; } return NS_OK; } }; template class WrapKeyTask : public ExportKeyTask { public: WrapKeyTask(JSContext* aCx, const nsAString& aFormat, CryptoKey& aKey, CryptoKey& aWrappingKey, const ObjectOrString& aWrapAlgorithm) : ExportKeyTask(aFormat, aKey) , mResolved(false) { if (NS_FAILED(mEarlyRv)) { return; } mTask = new KeyEncryptTask(aCx, aWrapAlgorithm, aWrappingKey, true); } private: nsRefPtr mTask; bool mResolved; virtual nsresult AfterCrypto() MOZ_OVERRIDE { // If wrapping JWK, stringify the JSON if (mFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { nsAutoString json; if (!mJwk.ToJSON(json)) { return NS_ERROR_DOM_OPERATION_ERR; } NS_ConvertUTF16toUTF8 utf8(json); mResult.Assign((const uint8_t*) utf8.BeginReading(), utf8.Length()); } return NS_OK; } virtual void Resolve() MOZ_OVERRIDE { mTask->SetData(mResult); mTask->DispatchWithPromise(mResultPromise); mResolved = true; } virtual void Cleanup() MOZ_OVERRIDE { if (mTask && !mResolved) { mTask->Skip(); } mTask = nullptr; } }; template class UnwrapKeyTask : public KeyEncryptTask { public: UnwrapKeyTask(JSContext* aCx, const ArrayBufferViewOrArrayBuffer& aWrappedKey, CryptoKey& aUnwrappingKey, const ObjectOrString& aUnwrapAlgorithm, ImportKeyTask* aTask) : KeyEncryptTask(aCx, aUnwrapAlgorithm, aUnwrappingKey, aWrappedKey, false) , mTask(aTask) , mResolved(false) {} private: nsRefPtr mTask; bool mResolved; virtual void Resolve() MOZ_OVERRIDE { mTask->SetKeyData(KeyEncryptTask::mResult); mTask->DispatchWithPromise(KeyEncryptTask::mResultPromise); mResolved = true; } virtual void Cleanup() MOZ_OVERRIDE { if (mTask && !mResolved) { mTask->Skip(); } mTask = nullptr; } }; // Task creation methods for WebCryptoTask // Note: We do not perform algorithm normalization as a monolithic process, // as described in the spec. Instead: // * Each method handles its slice of the supportedAlgorithms structure // * Task constructors take care of: // * Coercing the algorithm to the proper concrete type // * Cloning subordinate data items // * Cloning input data as needed // // Thus, support for different algorithms is determined by the if-statements // below, rather than a data structure. // // This results in algorithm normalization coming after some other checks, // and thus slightly more steps being done synchronously than the spec calls // for. But none of these steps is especially time-consuming. WebCryptoTask* WebCryptoTask::CreateEncryptDecryptTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const CryptoOperationData& aData, bool aEncrypt) { TelemetryMethod method = (aEncrypt)? TM_ENCRYPT : TM_DECRYPT; Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, method); Telemetry::Accumulate(Telemetry::WEBCRYPTO_EXTRACTABLE_ENC, aKey.Extractable()); // Ensure key is usable for this operation if ((aEncrypt && !aKey.HasUsage(CryptoKey::ENCRYPT)) || (!aEncrypt && !aKey.HasUsage(CryptoKey::DECRYPT))) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } nsString algName; nsresult rv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM)) { return new AesTask(aCx, aAlgorithm, aKey, aData, aEncrypt); } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { return new RsaOaepTask(aCx, aAlgorithm, aKey, aData, aEncrypt); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } WebCryptoTask* WebCryptoTask::CreateSignVerifyTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, const CryptoOperationData& aSignature, const CryptoOperationData& aData, bool aSign) { TelemetryMethod method = (aSign)? TM_SIGN : TM_VERIFY; Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, method); Telemetry::Accumulate(Telemetry::WEBCRYPTO_EXTRACTABLE_SIG, aKey.Extractable()); // Ensure key is usable for this operation if ((aSign && !aKey.HasUsage(CryptoKey::SIGN)) || (!aSign && !aKey.HasUsage(CryptoKey::VERIFY))) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } nsString algName; nsresult rv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (algName.EqualsLiteral(WEBCRYPTO_ALG_HMAC)) { return new HmacTask(aCx, aAlgorithm, aKey, aSignature, aData, aSign); } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1) || algName.EqualsLiteral(WEBCRYPTO_ALG_ECDSA)) { return new AsymmetricSignVerifyTask(aCx, aAlgorithm, aKey, aSignature, aData, aSign); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } WebCryptoTask* WebCryptoTask::CreateDigestTask(JSContext* aCx, const ObjectOrString& aAlgorithm, const CryptoOperationData& aData) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_DIGEST); nsString algName; nsresult rv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (algName.EqualsLiteral(WEBCRYPTO_ALG_SHA1) || algName.EqualsLiteral(WEBCRYPTO_ALG_SHA256) || algName.EqualsLiteral(WEBCRYPTO_ALG_SHA384) || algName.EqualsLiteral(WEBCRYPTO_ALG_SHA512)) { return new DigestTask(aCx, aAlgorithm, aData); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } WebCryptoTask* WebCryptoTask::CreateImportKeyTask(JSContext* aCx, const nsAString& aFormat, JS::Handle aKeyData, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_IMPORTKEY); Telemetry::Accumulate(Telemetry::WEBCRYPTO_EXTRACTABLE_IMPORT, aExtractable); // Verify that the format is recognized if (!aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_RAW) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_PKCS8) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { return new FailureTask(NS_ERROR_DOM_SYNTAX_ERR); } // Verify that aKeyUsages does not contain an unrecognized value if (!CryptoKey::AllUsagesRecognized(aKeyUsages)) { return new FailureTask(NS_ERROR_DOM_SYNTAX_ERR); } nsString algName; nsresult rv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(rv)) { return new FailureTask(rv); } // SPEC-BUG: PBKDF2 is not supposed to be supported for this operation. // However, the spec should be updated to allow it. if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW) || algName.EqualsLiteral(WEBCRYPTO_ALG_PBKDF2) || algName.EqualsLiteral(WEBCRYPTO_ALG_HMAC)) { return new ImportSymmetricKeyTask(aCx, aFormat, aKeyData, aAlgorithm, aExtractable, aKeyUsages); } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1) || algName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { return new ImportRsaKeyTask(aCx, aFormat, aKeyData, aAlgorithm, aExtractable, aKeyUsages); } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_ECDH) || algName.EqualsLiteral(WEBCRYPTO_ALG_ECDSA)) { return new ImportEcKeyTask(aCx, aFormat, aKeyData, aAlgorithm, aExtractable, aKeyUsages); } else if (algName.EqualsLiteral(WEBCRYPTO_ALG_DH)) { return new ImportDhKeyTask(aCx, aFormat, aKeyData, aAlgorithm, aExtractable, aKeyUsages); } else { return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } } WebCryptoTask* WebCryptoTask::CreateExportKeyTask(const nsAString& aFormat, CryptoKey& aKey) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_EXPORTKEY); // Verify that the format is recognized if (!aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_RAW) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_PKCS8) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { return new FailureTask(NS_ERROR_DOM_SYNTAX_ERR); } // Verify that the key is extractable if (!aKey.Extractable()) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } // Verify that the algorithm supports export // SPEC-BUG: PBKDF2 is not supposed to be supported for this operation. // However, the spec should be updated to allow it. nsString algName = aKey.Algorithm().mName; if (algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM) || algName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW) || algName.EqualsLiteral(WEBCRYPTO_ALG_PBKDF2) || algName.EqualsLiteral(WEBCRYPTO_ALG_HMAC) || algName.EqualsLiteral(WEBCRYPTO_ALG_RSASSA_PKCS1) || algName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP) || algName.EqualsLiteral(WEBCRYPTO_ALG_ECDH) || algName.EqualsLiteral(WEBCRYPTO_ALG_DH)) { return new ExportKeyTask(aFormat, aKey); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } WebCryptoTask* WebCryptoTask::CreateGenerateKeyTask(JSContext* aCx, const ObjectOrString& aAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_GENERATEKEY); Telemetry::Accumulate(Telemetry::WEBCRYPTO_EXTRACTABLE_GENERATE, aExtractable); // Verify that aKeyUsages does not contain an unrecognized value // SPEC-BUG: Spec says that this should be InvalidAccessError, but that // is inconsistent with other analogous points in the spec if (!CryptoKey::AllUsagesRecognized(aKeyUsages)) { return new FailureTask(NS_ERROR_DOM_SYNTAX_ERR); } nsString algName; nsresult rv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (algName.EqualsASCII(WEBCRYPTO_ALG_AES_CBC) || algName.EqualsASCII(WEBCRYPTO_ALG_AES_CTR) || algName.EqualsASCII(WEBCRYPTO_ALG_AES_GCM) || algName.EqualsASCII(WEBCRYPTO_ALG_AES_KW) || algName.EqualsASCII(WEBCRYPTO_ALG_HMAC)) { return new GenerateSymmetricKeyTask(aCx, aAlgorithm, aExtractable, aKeyUsages); } else if (algName.EqualsASCII(WEBCRYPTO_ALG_RSASSA_PKCS1) || algName.EqualsASCII(WEBCRYPTO_ALG_RSA_OAEP) || algName.EqualsASCII(WEBCRYPTO_ALG_ECDH) || algName.EqualsASCII(WEBCRYPTO_ALG_ECDSA) || algName.EqualsASCII(WEBCRYPTO_ALG_DH)) { return new GenerateAsymmetricKeyTask(aCx, aAlgorithm, aExtractable, aKeyUsages); } else { return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } } WebCryptoTask* WebCryptoTask::CreateDeriveKeyTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aBaseKey, const ObjectOrString& aDerivedKeyType, bool aExtractable, const Sequence& aKeyUsages) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_DERIVEKEY); // Ensure baseKey is usable for this operation if (!aBaseKey.HasUsage(CryptoKey::DERIVEKEY)) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } // Verify that aKeyUsages does not contain an unrecognized value if (!CryptoKey::AllUsagesRecognized(aKeyUsages)) { return new FailureTask(NS_ERROR_DOM_SYNTAX_ERR); } nsString algName; nsresult rv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (algName.EqualsASCII(WEBCRYPTO_ALG_PBKDF2)) { return new DeriveKeyTask(aCx, aAlgorithm, aBaseKey, aDerivedKeyType, aExtractable, aKeyUsages); } if (algName.EqualsASCII(WEBCRYPTO_ALG_ECDH)) { return new DeriveKeyTask(aCx, aAlgorithm, aBaseKey, aDerivedKeyType, aExtractable, aKeyUsages); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } WebCryptoTask* WebCryptoTask::CreateDeriveBitsTask(JSContext* aCx, const ObjectOrString& aAlgorithm, CryptoKey& aKey, uint32_t aLength) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_DERIVEBITS); // Ensure baseKey is usable for this operation if (!aKey.HasUsage(CryptoKey::DERIVEBITS)) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } nsString algName; nsresult rv = GetAlgorithmName(aCx, aAlgorithm, algName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (algName.EqualsASCII(WEBCRYPTO_ALG_PBKDF2)) { return new DerivePbkdfBitsTask(aCx, aAlgorithm, aKey, aLength); } if (algName.EqualsASCII(WEBCRYPTO_ALG_ECDH)) { return new DeriveEcdhBitsTask(aCx, aAlgorithm, aKey, aLength); } if (algName.EqualsASCII(WEBCRYPTO_ALG_DH)) { return new DeriveDhBitsTask(aCx, aAlgorithm, aKey, aLength); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } WebCryptoTask* WebCryptoTask::CreateWrapKeyTask(JSContext* aCx, const nsAString& aFormat, CryptoKey& aKey, CryptoKey& aWrappingKey, const ObjectOrString& aWrapAlgorithm) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_WRAPKEY); // Verify that the format is recognized if (!aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_RAW) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_SPKI) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_PKCS8) && !aFormat.EqualsLiteral(WEBCRYPTO_KEY_FORMAT_JWK)) { return new FailureTask(NS_ERROR_DOM_SYNTAX_ERR); } // Ensure wrappingKey is usable for this operation if (!aWrappingKey.HasUsage(CryptoKey::WRAPKEY)) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } // Ensure key is extractable if (!aKey.Extractable()) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } nsString wrapAlgName; nsresult rv = GetAlgorithmName(aCx, aWrapAlgorithm, wrapAlgName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (wrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || wrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || wrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM)) { return new WrapKeyTask(aCx, aFormat, aKey, aWrappingKey, aWrapAlgorithm); } else if (wrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW)) { return new WrapKeyTask(aCx, aFormat, aKey, aWrappingKey, aWrapAlgorithm); } else if (wrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { return new WrapKeyTask(aCx, aFormat, aKey, aWrappingKey, aWrapAlgorithm); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } WebCryptoTask* WebCryptoTask::CreateUnwrapKeyTask(JSContext* aCx, const nsAString& aFormat, const ArrayBufferViewOrArrayBuffer& aWrappedKey, CryptoKey& aUnwrappingKey, const ObjectOrString& aUnwrapAlgorithm, const ObjectOrString& aUnwrappedKeyAlgorithm, bool aExtractable, const Sequence& aKeyUsages) { Telemetry::Accumulate(Telemetry::WEBCRYPTO_METHOD, TM_UNWRAPKEY); // Ensure key is usable for this operation if (!aUnwrappingKey.HasUsage(CryptoKey::UNWRAPKEY)) { return new FailureTask(NS_ERROR_DOM_INVALID_ACCESS_ERR); } // Verify that aKeyUsages does not contain an unrecognized value if (!CryptoKey::AllUsagesRecognized(aKeyUsages)) { return new FailureTask(NS_ERROR_DOM_SYNTAX_ERR); } nsString keyAlgName; nsresult rv = GetAlgorithmName(aCx, aUnwrappedKeyAlgorithm, keyAlgName); if (NS_FAILED(rv)) { return new FailureTask(rv); } CryptoOperationData dummy; nsRefPtr importTask; if (keyAlgName.EqualsASCII(WEBCRYPTO_ALG_AES_CBC) || keyAlgName.EqualsASCII(WEBCRYPTO_ALG_AES_CTR) || keyAlgName.EqualsASCII(WEBCRYPTO_ALG_AES_GCM) || keyAlgName.EqualsASCII(WEBCRYPTO_ALG_HMAC)) { importTask = new ImportSymmetricKeyTask(aCx, aFormat, aUnwrappedKeyAlgorithm, aExtractable, aKeyUsages); } else if (keyAlgName.EqualsASCII(WEBCRYPTO_ALG_RSASSA_PKCS1) || keyAlgName.EqualsASCII(WEBCRYPTO_ALG_RSA_OAEP)) { importTask = new ImportRsaKeyTask(aCx, aFormat, aUnwrappedKeyAlgorithm, aExtractable, aKeyUsages); } else { return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } nsString unwrapAlgName; rv = GetAlgorithmName(aCx, aUnwrapAlgorithm, unwrapAlgName); if (NS_FAILED(rv)) { return new FailureTask(rv); } if (unwrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_CBC) || unwrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_CTR) || unwrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_GCM)) { return new UnwrapKeyTask(aCx, aWrappedKey, aUnwrappingKey, aUnwrapAlgorithm, importTask); } else if (unwrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_AES_KW)) { return new UnwrapKeyTask(aCx, aWrappedKey, aUnwrappingKey, aUnwrapAlgorithm, importTask); } else if (unwrapAlgName.EqualsLiteral(WEBCRYPTO_ALG_RSA_OAEP)) { return new UnwrapKeyTask(aCx, aWrappedKey, aUnwrappingKey, aUnwrapAlgorithm, importTask); } return new FailureTask(NS_ERROR_DOM_NOT_SUPPORTED_ERR); } } // namespace dom } // namespace mozilla