/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* 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 "WebAuthnCoseIdentifiers.h" #include "mozilla/dom/U2FHIDTokenManager.h" #include "mozilla/dom/WebAuthnUtil.h" #include "mozilla/ipc/BackgroundParent.h" #include "mozilla/StaticMutex.h" namespace mozilla { namespace dom { static StaticMutex gInstanceMutex; static U2FHIDTokenManager* gInstance; static nsIThread* gPBackgroundThread; static void u2f_register_callback(uint64_t aTransactionId, rust_u2f_result* aResult) { UniquePtr rv = MakeUnique(aTransactionId, aResult); StaticMutexAutoLock lock(gInstanceMutex); if (!gInstance || NS_WARN_IF(!gPBackgroundThread)) { return; } nsCOMPtr r(NewRunnableMethod&&>( "U2FHIDTokenManager::HandleRegisterResult", gInstance, &U2FHIDTokenManager::HandleRegisterResult, std::move(rv))); MOZ_ALWAYS_SUCCEEDS( gPBackgroundThread->Dispatch(r.forget(), NS_DISPATCH_NORMAL)); } static void u2f_sign_callback(uint64_t aTransactionId, rust_u2f_result* aResult) { UniquePtr rv = MakeUnique(aTransactionId, aResult); StaticMutexAutoLock lock(gInstanceMutex); if (!gInstance || NS_WARN_IF(!gPBackgroundThread)) { return; } nsCOMPtr r(NewRunnableMethod&&>( "U2FHIDTokenManager::HandleSignResult", gInstance, &U2FHIDTokenManager::HandleSignResult, std::move(rv))); MOZ_ALWAYS_SUCCEEDS( gPBackgroundThread->Dispatch(r.forget(), NS_DISPATCH_NORMAL)); } U2FHIDTokenManager::U2FHIDTokenManager() { StaticMutexAutoLock lock(gInstanceMutex); mozilla::ipc::AssertIsOnBackgroundThread(); MOZ_ASSERT(XRE_IsParentProcess()); MOZ_ASSERT(!gInstance); mU2FManager = rust_u2f_mgr_new(); gPBackgroundThread = NS_GetCurrentThread(); MOZ_ASSERT(gPBackgroundThread, "This should never be null!"); gInstance = this; } void U2FHIDTokenManager::Drop() { { StaticMutexAutoLock lock(gInstanceMutex); mozilla::ipc::AssertIsOnBackgroundThread(); mRegisterPromise.RejectIfExists(NS_ERROR_DOM_UNKNOWN_ERR, __func__); mSignPromise.RejectIfExists(NS_ERROR_DOM_UNKNOWN_ERR, __func__); gInstance = nullptr; } // Release gInstanceMutex before we call U2FManager::drop(). It will wait // for the work queue thread to join, and that requires the // u2f_{register,sign}_callback to lock and return. rust_u2f_mgr_free(mU2FManager); mU2FManager = nullptr; // Reset transaction ID so that queued runnables exit early. mTransaction.reset(); } // A U2F Register operation causes a new key pair to be generated by the token. // The token then returns the public key of the key pair, and a handle to the // private key, which is a fancy way of saying "key wrapped private key", as // well as the generated attestation certificate and a signature using that // certificate's private key. // // The KeyHandleFromPrivateKey and PrivateKeyFromKeyHandle methods perform // the actual key wrap/unwrap operations. // // The format of the return registration data is as follows: // // Bytes Value // 1 0x05 // 65 public key // 1 key handle length // * key handle // ASN.1 attestation certificate // * attestation signature // RefPtr U2FHIDTokenManager::Register( const WebAuthnMakeCredentialInfo& aInfo, bool aForceNoneAttestation) { mozilla::ipc::AssertIsOnBackgroundThread(); uint64_t registerFlags = 0; if (aInfo.Extra().isSome()) { const auto& extra = aInfo.Extra().ref(); const WebAuthnAuthenticatorSelection& sel = extra.AuthenticatorSelection(); UserVerificationRequirement userVerificaitonRequirement = sel.userVerificationRequirement(); bool requireUserVerification = userVerificaitonRequirement == UserVerificationRequirement::Required; bool requirePlatformAttachment = false; if (sel.authenticatorAttachment().isSome()) { const AuthenticatorAttachment authenticatorAttachment = sel.authenticatorAttachment().value(); if (authenticatorAttachment == AuthenticatorAttachment::Platform) { requirePlatformAttachment = true; } } // Set flags for credential creation. if (sel.requireResidentKey()) { registerFlags |= U2F_FLAG_REQUIRE_RESIDENT_KEY; } if (requireUserVerification) { registerFlags |= U2F_FLAG_REQUIRE_USER_VERIFICATION; } if (requirePlatformAttachment) { registerFlags |= U2F_FLAG_REQUIRE_PLATFORM_ATTACHMENT; } nsTArray coseAlgos; for (const auto& coseAlg : extra.coseAlgs()) { switch (static_cast(coseAlg.alg())) { case CoseAlgorithmIdentifier::ES256: coseAlgos.AppendElement(coseAlg); break; default: continue; } } // Only if no algorithms were specified, default to the only CTAP 1 / U2F // protocol-supported algorithm. Ultimately this logic must move into // u2f-hid-rs in a fashion that doesn't break the tests. if (extra.coseAlgs().IsEmpty()) { coseAlgos.AppendElement( static_cast(CoseAlgorithmIdentifier::ES256)); } // If there are no acceptable/supported algorithms, reject the promise. if (coseAlgos.IsEmpty()) { return U2FRegisterPromise::CreateAndReject(NS_ERROR_DOM_NOT_SUPPORTED_ERR, __func__); } } CryptoBuffer rpIdHash, clientDataHash; NS_ConvertUTF16toUTF8 rpId(aInfo.RpId()); nsresult rv = BuildTransactionHashes(rpId, aInfo.ClientDataJSON(), rpIdHash, clientDataHash); if (NS_WARN_IF(NS_FAILED(rv))) { return U2FRegisterPromise::CreateAndReject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); } ClearPromises(); mTransaction.reset(); uint64_t tid = rust_u2f_mgr_register( mU2FManager, registerFlags, (uint64_t)aInfo.TimeoutMS(), u2f_register_callback, clientDataHash.Elements(), clientDataHash.Length(), rpIdHash.Elements(), rpIdHash.Length(), U2FKeyHandles(aInfo.ExcludeList()).Get()); if (tid == 0) { return U2FRegisterPromise::CreateAndReject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); } mTransaction = Some(Transaction( tid, rpIdHash, Nothing(), aInfo.ClientDataJSON(), aForceNoneAttestation)); return mRegisterPromise.Ensure(__func__); } // A U2F Sign operation creates a signature over the "param" arguments (plus // some other stuff) using the private key indicated in the key handle argument. // // The format of the signed data is as follows: // // 32 Application parameter // 1 User presence (0x01) // 4 Counter // 32 Challenge parameter // // The format of the signature data is as follows: // // 1 User presence // 4 Counter // * Signature // RefPtr U2FHIDTokenManager::Sign( const WebAuthnGetAssertionInfo& aInfo) { mozilla::ipc::AssertIsOnBackgroundThread(); CryptoBuffer rpIdHash, clientDataHash; NS_ConvertUTF16toUTF8 rpId(aInfo.RpId()); nsresult rv = BuildTransactionHashes(rpId, aInfo.ClientDataJSON(), rpIdHash, clientDataHash); if (NS_WARN_IF(NS_FAILED(rv))) { return U2FSignPromise::CreateAndReject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); } uint64_t signFlags = 0; nsTArray> appIds; appIds.AppendElement(rpIdHash.InfallibleClone()); Maybe> appIdHashExt = Nothing(); if (aInfo.Extra().isSome()) { const auto& extra = aInfo.Extra().ref(); UserVerificationRequirement userVerificaitonReq = extra.userVerificationRequirement(); // Set flags for credential requests. if (userVerificaitonReq == UserVerificationRequirement::Required) { signFlags |= U2F_FLAG_REQUIRE_USER_VERIFICATION; } // Process extensions. for (const WebAuthnExtension& ext : extra.Extensions()) { if (ext.type() == WebAuthnExtension::TWebAuthnExtensionAppId) { appIdHashExt = Some(ext.get_WebAuthnExtensionAppId().AppId().Clone()); appIds.AppendElement(appIdHashExt->Clone()); } } } ClearPromises(); mTransaction.reset(); uint64_t tid = rust_u2f_mgr_sign( mU2FManager, signFlags, (uint64_t)aInfo.TimeoutMS(), u2f_sign_callback, clientDataHash.Elements(), clientDataHash.Length(), U2FAppIds(appIds).Get(), U2FKeyHandles(aInfo.AllowList()).Get()); if (tid == 0) { return U2FSignPromise::CreateAndReject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); } mTransaction = Some(Transaction(tid, std::move(rpIdHash), std::move(appIdHashExt), aInfo.ClientDataJSON())); return mSignPromise.Ensure(__func__); } void U2FHIDTokenManager::Cancel() { mozilla::ipc::AssertIsOnBackgroundThread(); ClearPromises(); rust_u2f_mgr_cancel(mU2FManager); mTransaction.reset(); } void U2FHIDTokenManager::HandleRegisterResult(UniquePtr&& aResult) { mozilla::ipc::AssertIsOnBackgroundThread(); if (mTransaction.isNothing() || aResult->GetTransactionId() != mTransaction.ref().mId) { return; } MOZ_ASSERT(!mRegisterPromise.IsEmpty()); if (aResult->IsError()) { mRegisterPromise.Reject(aResult->GetError(), __func__); return; } nsTArray registration; if (!aResult->CopyRegistration(registration)) { mRegisterPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } // Decompose the U2F registration packet CryptoBuffer pubKeyBuf; CryptoBuffer keyHandle; CryptoBuffer attestationCertBuf; CryptoBuffer signatureBuf; CryptoBuffer regData; regData.Assign(registration); // Only handles attestation cert chains of length=1. nsresult rv = U2FDecomposeRegistrationResponse( regData, pubKeyBuf, keyHandle, attestationCertBuf, signatureBuf); if (NS_WARN_IF(NS_FAILED(rv))) { mRegisterPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } CryptoBuffer rpIdHashBuf; if (!rpIdHashBuf.Assign(mTransaction.ref().mRpIdHash)) { mRegisterPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } CryptoBuffer attObj; rv = AssembleAttestationObject( rpIdHashBuf, pubKeyBuf, keyHandle, attestationCertBuf, signatureBuf, mTransaction.ref().mForceNoneAttestation, attObj); if (NS_FAILED(rv)) { mRegisterPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } nsTArray extensions; WebAuthnMakeCredentialResult result(mTransaction.ref().mClientDataJSON, attObj, keyHandle, regData, extensions); mRegisterPromise.Resolve(std::move(result), __func__); } void U2FHIDTokenManager::HandleSignResult(UniquePtr&& aResult) { mozilla::ipc::AssertIsOnBackgroundThread(); if (mTransaction.isNothing() || aResult->GetTransactionId() != mTransaction.ref().mId) { return; } MOZ_ASSERT(!mSignPromise.IsEmpty()); if (aResult->IsError()) { mSignPromise.Reject(aResult->GetError(), __func__); return; } nsTArray hashChosenByAuthenticator; if (!aResult->CopyAppId(hashChosenByAuthenticator)) { mSignPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } nsTArray keyHandle; if (!aResult->CopyKeyHandle(keyHandle)) { mSignPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } nsTArray signature; if (!aResult->CopySignature(signature)) { mSignPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } CryptoBuffer rawSignatureBuf; if (!rawSignatureBuf.Assign(signature)) { mSignPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } nsTArray extensions; if (mTransaction.ref().mAppIdHash.isSome()) { bool usedAppId = (hashChosenByAuthenticator == mTransaction.ref().mAppIdHash.ref()); extensions.AppendElement(WebAuthnExtensionResultAppId(usedAppId)); } CryptoBuffer signatureBuf; CryptoBuffer counterBuf; uint8_t flags = 0; nsresult rv = U2FDecomposeSignResponse(rawSignatureBuf, flags, counterBuf, signatureBuf); if (NS_WARN_IF(NS_FAILED(rv))) { mSignPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } CryptoBuffer chosenAppIdBuf; if (!chosenAppIdBuf.Assign(hashChosenByAuthenticator)) { mSignPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } // Preserve the two LSBs of the flags byte, UP and RFU1. // See flags &= 0b11; CryptoBuffer emptyAttestationData; CryptoBuffer authenticatorData; rv = AssembleAuthenticatorData(chosenAppIdBuf, flags, counterBuf, emptyAttestationData, authenticatorData); if (NS_WARN_IF(NS_FAILED(rv))) { mSignPromise.Reject(NS_ERROR_DOM_UNKNOWN_ERR, __func__); return; } nsTArray userHandle; WebAuthnGetAssertionResult result(mTransaction.ref().mClientDataJSON, keyHandle, signatureBuf, authenticatorData, extensions, rawSignatureBuf, userHandle); mSignPromise.Resolve(std::move(result), __func__); } } // namespace dom } // namespace mozilla