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/*
*
* Copyright (c) 2021 Project CHIP Authors
* All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <controller/AutoCommissioner.h>
#include <cstring>
#include <app/InteractionModelTimeout.h>
#include <controller/CHIPDeviceController.h>
#include <credentials/CHIPCert.h>
#include <lib/support/SafeInt.h>
namespace chip {
namespace Controller {
using namespace chip::app::Clusters;
using namespace chip::Crypto;
using chip::app::DataModel::MakeNullable;
using chip::app::DataModel::NullNullable;
AutoCommissioner::AutoCommissioner()
{
SetCommissioningParameters(CommissioningParameters());
}
AutoCommissioner::~AutoCommissioner()
{
ReleaseDAC();
ReleasePAI();
}
void AutoCommissioner::SetOperationalCredentialsDelegate(OperationalCredentialsDelegate * operationalCredentialsDelegate)
{
mOperationalCredentialsDelegate = operationalCredentialsDelegate;
}
// Returns true if maybeUnsafeSpan is pointing to a buffer that we're not sure
// will live for long enough. knownSafeSpan, if it has a value, points to a
// buffer that we _are_ sure will live for long enough.
template <typename SpanType>
static bool IsUnsafeSpan(const Optional<SpanType> & maybeUnsafeSpan, const Optional<SpanType> & knownSafeSpan)
{
if (!maybeUnsafeSpan.HasValue())
{
return false;
}
if (!knownSafeSpan.HasValue())
{
return true;
}
return maybeUnsafeSpan.Value().data() != knownSafeSpan.Value().data();
}
CHIP_ERROR AutoCommissioner::VerifyICDRegistrationInfo(const CommissioningParameters & params)
{
ChipLogProgress(Controller, "Checking ICD registration parameters");
if (!params.GetICDSymmetricKey().HasValue())
{
ChipLogError(Controller, "Missing ICD symmetric key!");
return CHIP_ERROR_INVALID_ARGUMENT;
}
if (params.GetICDSymmetricKey().Value().size() != sizeof(mICDSymmetricKey))
{
ChipLogError(Controller, "Invalid ICD symmetric key length!");
return CHIP_ERROR_INVALID_ARGUMENT;
}
if (!params.GetICDCheckInNodeId().HasValue())
{
ChipLogError(Controller, "Missing ICD check-in node id!");
return CHIP_ERROR_INVALID_ARGUMENT;
}
if (!params.GetICDMonitoredSubject().HasValue())
{
ChipLogError(Controller, "Missing ICD monitored subject!");
return CHIP_ERROR_INVALID_ARGUMENT;
}
if (!params.GetICDClientType().HasValue())
{
ChipLogError(Controller, "Missing ICD Client Type!");
return CHIP_ERROR_INVALID_ARGUMENT;
}
return CHIP_NO_ERROR;
}
CHIP_ERROR AutoCommissioner::SetCommissioningParameters(const CommissioningParameters & params)
{
// Make sure any members that point to buffers that we are not pointing to
// our own buffers are not going to dangle. We can skip this step if all
// the buffers pointers that we don't plan to re-point to our own buffers
// below are already pointing to the same things as our own buffer pointers
// (so that we know they have to be safe somehow).
//
// The checks are a bit painful, because Span does not have a usable
// operator==, and in any case, we want to compare for pointer equality, not
// data equality.
bool haveMaybeDanglingBufferPointers =
((params.GetNOCChainGenerationParameters().HasValue() &&
(!mParams.GetNOCChainGenerationParameters().HasValue() ||
params.GetNOCChainGenerationParameters().Value().nocsrElements.data() !=
mParams.GetNOCChainGenerationParameters().Value().nocsrElements.data() ||
params.GetNOCChainGenerationParameters().Value().signature.data() !=
mParams.GetNOCChainGenerationParameters().Value().signature.data())) ||
IsUnsafeSpan(params.GetRootCert(), mParams.GetRootCert()) || IsUnsafeSpan(params.GetNoc(), mParams.GetNoc()) ||
IsUnsafeSpan(params.GetIcac(), mParams.GetIcac()) || IsUnsafeSpan(params.GetIpk(), mParams.GetIpk()) ||
IsUnsafeSpan(params.GetAttestationElements(), mParams.GetAttestationElements()) ||
IsUnsafeSpan(params.GetAttestationSignature(), mParams.GetAttestationSignature()) ||
IsUnsafeSpan(params.GetPAI(), mParams.GetPAI()) || IsUnsafeSpan(params.GetDAC(), mParams.GetDAC()) ||
IsUnsafeSpan(params.GetTimeZone(), mParams.GetTimeZone()) ||
IsUnsafeSpan(params.GetDSTOffsets(), mParams.GetDSTOffsets()) ||
IsUnsafeSpan(params.GetICDSymmetricKey(), mParams.GetICDSymmetricKey()) ||
(params.GetDefaultNTP().HasValue() && !params.GetDefaultNTP().Value().IsNull() &&
params.GetDefaultNTP().Value().Value().data() != mDefaultNtp));
mParams = params;
mNeedIcdRegistration = false;
if (haveMaybeDanglingBufferPointers)
{
mParams.ClearExternalBufferDependentValues();
}
// For members of params that point to some sort of buffer, we have to copy
// the data over into our own buffers.
if (params.GetThreadOperationalDataset().HasValue())
{
ByteSpan dataset = params.GetThreadOperationalDataset().Value();
if (dataset.size() > CommissioningParameters::kMaxThreadDatasetLen)
{
ChipLogError(Controller, "Thread operational data set is too large");
// Make sure our buffer pointers don't dangle.
mParams.ClearExternalBufferDependentValues();
return CHIP_ERROR_INVALID_ARGUMENT;
}
memcpy(mThreadOperationalDataset, dataset.data(), dataset.size());
ChipLogProgress(Controller, "Setting thread operational dataset from parameters");
mParams.SetThreadOperationalDataset(ByteSpan(mThreadOperationalDataset, dataset.size()));
}
if (params.GetWiFiCredentials().HasValue())
{
WiFiCredentials creds = params.GetWiFiCredentials().Value();
if (creds.ssid.size() > CommissioningParameters::kMaxSsidLen ||
creds.credentials.size() > CommissioningParameters::kMaxCredentialsLen)
{
ChipLogError(Controller, "Wifi credentials are too large");
// Make sure our buffer pointers don't dangle.
mParams.ClearExternalBufferDependentValues();
return CHIP_ERROR_INVALID_ARGUMENT;
}
memcpy(mSsid, creds.ssid.data(), creds.ssid.size());
memcpy(mCredentials, creds.credentials.data(), creds.credentials.size());
ChipLogProgress(Controller, "Setting wifi credentials from parameters");
mParams.SetWiFiCredentials(
WiFiCredentials(ByteSpan(mSsid, creds.ssid.size()), ByteSpan(mCredentials, creds.credentials.size())));
}
if (params.GetCountryCode().HasValue())
{
auto code = params.GetCountryCode().Value();
MutableCharSpan copiedCode(mCountryCode);
if (CopyCharSpanToMutableCharSpan(code, copiedCode) == CHIP_NO_ERROR)
{
mParams.SetCountryCode(copiedCode);
}
else
{
ChipLogError(Controller, "Country code is too large: %u", static_cast<unsigned>(code.size()));
// Make sure our buffer pointers don't dangle.
mParams.ClearExternalBufferDependentValues();
return CHIP_ERROR_INVALID_ARGUMENT;
}
}
// If the AttestationNonce is passed in, using that else using a random one..
if (params.GetAttestationNonce().HasValue())
{
ChipLogProgress(Controller, "Setting attestation nonce from parameters");
VerifyOrReturnError(params.GetAttestationNonce().Value().size() == sizeof(mAttestationNonce), CHIP_ERROR_INVALID_ARGUMENT);
memcpy(mAttestationNonce, params.GetAttestationNonce().Value().data(), params.GetAttestationNonce().Value().size());
}
else
{
ChipLogProgress(Controller, "Setting attestation nonce to random value");
Crypto::DRBG_get_bytes(mAttestationNonce, sizeof(mAttestationNonce));
}
mParams.SetAttestationNonce(ByteSpan(mAttestationNonce, sizeof(mAttestationNonce)));
if (params.GetCSRNonce().HasValue())
{
ChipLogProgress(Controller, "Setting CSR nonce from parameters");
VerifyOrReturnError(params.GetCSRNonce().Value().size() == sizeof(mCSRNonce), CHIP_ERROR_INVALID_ARGUMENT);
memcpy(mCSRNonce, params.GetCSRNonce().Value().data(), params.GetCSRNonce().Value().size());
}
else
{
ChipLogProgress(Controller, "Setting CSR nonce to random value");
Crypto::DRBG_get_bytes(mCSRNonce, sizeof(mCSRNonce));
}
mParams.SetCSRNonce(ByteSpan(mCSRNonce, sizeof(mCSRNonce)));
if (params.GetDSTOffsets().HasValue())
{
ChipLogProgress(Controller, "Setting DST offsets from parameters");
size_t size = std::min(params.GetDSTOffsets().Value().size(), kMaxSupportedDstStructs);
for (size_t i = 0; i < size; ++i)
{
mDstOffsetsBuf[i] = params.GetDSTOffsets().Value()[i];
}
auto list = app::DataModel::List<app::Clusters::TimeSynchronization::Structs::DSTOffsetStruct::Type>(mDstOffsetsBuf, size);
mParams.SetDSTOffsets(list);
}
if (params.GetTimeZone().HasValue())
{
ChipLogProgress(Controller, "Setting Time Zone from parameters");
size_t size = std::min(params.GetTimeZone().Value().size(), kMaxSupportedTimeZones);
for (size_t i = 0; i < size; ++i)
{
mTimeZoneBuf[i] = params.GetTimeZone().Value()[i];
if (params.GetTimeZone().Value()[i].name.HasValue() &&
params.GetTimeZone().Value()[i].name.Value().size() <= kMaxTimeZoneNameLen)
{
auto span = MutableCharSpan(mTimeZoneNames[i], kMaxTimeZoneNameLen);
// The buffer backing "span" is statically allocated and is of size kMaxSupportedTimeZones, so this should never
// fail.
CopyCharSpanToMutableCharSpan(params.GetTimeZone().Value()[i].name.Value(), span);
mTimeZoneBuf[i].name.SetValue(span);
}
else
{
mTimeZoneBuf[i].name.ClearValue();
}
}
auto list = app::DataModel::List<app::Clusters::TimeSynchronization::Structs::TimeZoneStruct::Type>(mTimeZoneBuf, size);
mParams.SetTimeZone(list);
}
if (params.GetDefaultNTP().HasValue())
{
ChipLogProgress(Controller, "Setting Default NTP from parameters");
// This parameter is an optional nullable, so we need to go two levels deep here.
if (!params.GetDefaultNTP().Value().IsNull() && params.GetDefaultNTP().Value().Value().size() <= kMaxDefaultNtpSize)
{
// The buffer backing "span" is statically allocated and is of size kMaxDefaultNtpSize.
auto span = MutableCharSpan(mDefaultNtp, kMaxDefaultNtpSize);
CopyCharSpanToMutableCharSpan(params.GetDefaultNTP().Value().Value(), span);
auto default_ntp = MakeNullable(CharSpan(mDefaultNtp, params.GetDefaultNTP().Value().Value().size()));
mParams.SetDefaultNTP(default_ntp);
}
}
if (params.GetICDRegistrationStrategy() != ICDRegistrationStrategy::kIgnore && params.GetICDSymmetricKey().HasValue())
{
ReturnErrorOnFailure(VerifyICDRegistrationInfo(params));
// The values must be valid now.
memcpy(mICDSymmetricKey, params.GetICDSymmetricKey().Value().data(), params.GetICDSymmetricKey().Value().size());
mParams.SetICDSymmetricKey(ByteSpan(mICDSymmetricKey));
mParams.SetICDCheckInNodeId(params.GetICDCheckInNodeId().Value());
mParams.SetICDMonitoredSubject(params.GetICDMonitoredSubject().Value());
mParams.SetICDClientType(params.GetICDClientType().Value());
}
return CHIP_NO_ERROR;
}
const CommissioningParameters & AutoCommissioner::GetCommissioningParameters() const
{
return mParams;
}
CommissioningStage AutoCommissioner::GetNextCommissioningStage(CommissioningStage currentStage, CHIP_ERROR & lastErr)
{
auto nextStage = GetNextCommissioningStageInternal(currentStage, lastErr);
if (lastErr == CHIP_NO_ERROR)
{
ChipLogProgress(Controller, "Commissioning stage next step: '%s' -> '%s'", StageToString(currentStage),
StageToString(nextStage));
}
else
{
ChipLogProgress(Controller, "Going from commissioning step '%s' with lastErr = '%s' -> '%s'", StageToString(currentStage),
lastErr.AsString(), StageToString(nextStage));
}
return nextStage;
}
CommissioningStage AutoCommissioner::GetNextCommissioningStageNetworkSetup(CommissioningStage currentStage, CHIP_ERROR & lastErr)
{
if (IsSecondaryNetworkSupported())
{
if (TryingSecondaryNetwork())
{
// Try secondary network interface.
return mDeviceCommissioningInfo.network.wifi.endpoint == kRootEndpointId ? CommissioningStage::kThreadNetworkSetup
: CommissioningStage::kWiFiNetworkSetup;
}
// Try primary network interface
return mDeviceCommissioningInfo.network.wifi.endpoint == kRootEndpointId ? CommissioningStage::kWiFiNetworkSetup
: CommissioningStage::kThreadNetworkSetup;
}
if (mParams.GetWiFiCredentials().HasValue() && mDeviceCommissioningInfo.network.wifi.endpoint != kInvalidEndpointId)
{
return CommissioningStage::kWiFiNetworkSetup;
}
if (mParams.GetThreadOperationalDataset().HasValue() && mDeviceCommissioningInfo.network.thread.endpoint != kInvalidEndpointId)
{
return CommissioningStage::kThreadNetworkSetup;
}
ChipLogError(Controller, "Required network information not provided in commissioning parameters");
ChipLogError(Controller, "Parameters supplied: wifi (%s) thread (%s)", mParams.GetWiFiCredentials().HasValue() ? "yes" : "no",
mParams.GetThreadOperationalDataset().HasValue() ? "yes" : "no");
ChipLogError(Controller, "Device supports: wifi (%s) thread(%s)",
mDeviceCommissioningInfo.network.wifi.endpoint == kInvalidEndpointId ? "no" : "yes",
mDeviceCommissioningInfo.network.thread.endpoint == kInvalidEndpointId ? "no" : "yes");
lastErr = CHIP_ERROR_INVALID_ARGUMENT;
return CommissioningStage::kCleanup;
}
CommissioningStage AutoCommissioner::GetNextCommissioningStageInternal(CommissioningStage currentStage, CHIP_ERROR & lastErr)
{
if (mStopCommissioning)
{
return CommissioningStage::kCleanup;
}
if (lastErr != CHIP_NO_ERROR)
{
return CommissioningStage::kCleanup;
}
switch (currentStage)
{
case CommissioningStage::kSecurePairing:
return CommissioningStage::kReadCommissioningInfo;
case CommissioningStage::kReadCommissioningInfo:
if (mDeviceCommissioningInfo.general.breadcrumb > 0)
{
// If the breadcrumb is 0, the failsafe was disarmed.
// We failed on network setup or later, the node failsafe has not been re-armed and the breadcrumb has not been reset.
// Per the spec, we restart from after adding the NOC.
return GetNextCommissioningStage(CommissioningStage::kSendNOC, lastErr);
}
return CommissioningStage::kReadCommissioningInfo2;
case CommissioningStage::kReadCommissioningInfo2:
return CommissioningStage::kArmFailsafe;
case CommissioningStage::kArmFailsafe:
return CommissioningStage::kConfigRegulatory;
case CommissioningStage::kConfigRegulatory:
if (mDeviceCommissioningInfo.requiresUTC)
{
return CommissioningStage::kConfigureUTCTime;
}
else
{
// Time cluster is not supported, move right to DA
return CommissioningStage::kSendPAICertificateRequest;
}
case CommissioningStage::kConfigureUTCTime:
if (mDeviceCommissioningInfo.requiresTimeZone && mParams.GetTimeZone().HasValue())
{
return kConfigureTimeZone;
}
else
{
return GetNextCommissioningStageInternal(CommissioningStage::kConfigureTimeZone, lastErr);
}
case CommissioningStage::kConfigureTimeZone:
if (mNeedsDST && mParams.GetDSTOffsets().HasValue())
{
return CommissioningStage::kConfigureDSTOffset;
}
else
{
return GetNextCommissioningStageInternal(CommissioningStage::kConfigureDSTOffset, lastErr);
}
case CommissioningStage::kConfigureDSTOffset:
if (mDeviceCommissioningInfo.requiresDefaultNTP && mParams.GetDefaultNTP().HasValue())
{
return CommissioningStage::kConfigureDefaultNTP;
}
else
{
return GetNextCommissioningStageInternal(CommissioningStage::kConfigureDefaultNTP, lastErr);
}
case CommissioningStage::kConfigureDefaultNTP:
return CommissioningStage::kSendPAICertificateRequest;
case CommissioningStage::kSendPAICertificateRequest:
return CommissioningStage::kSendDACCertificateRequest;
case CommissioningStage::kSendDACCertificateRequest:
return CommissioningStage::kSendAttestationRequest;
case CommissioningStage::kSendAttestationRequest:
return CommissioningStage::kAttestationVerification;
case CommissioningStage::kAttestationVerification:
return CommissioningStage::kAttestationRevocationCheck;
case CommissioningStage::kAttestationRevocationCheck:
return CommissioningStage::kSendOpCertSigningRequest;
case CommissioningStage::kSendOpCertSigningRequest:
return CommissioningStage::kValidateCSR;
case CommissioningStage::kValidateCSR:
return CommissioningStage::kGenerateNOCChain;
case CommissioningStage::kGenerateNOCChain:
return CommissioningStage::kSendTrustedRootCert;
case CommissioningStage::kSendTrustedRootCert:
return CommissioningStage::kSendNOC;
case CommissioningStage::kSendNOC:
if (mDeviceCommissioningInfo.requiresTrustedTimeSource && mParams.GetTrustedTimeSource().HasValue())
{
return CommissioningStage::kConfigureTrustedTimeSource;
}
else
{
return GetNextCommissioningStageInternal(CommissioningStage::kConfigureTrustedTimeSource, lastErr);
}
case CommissioningStage::kConfigureTrustedTimeSource:
if (mNeedIcdRegistration)
{
if (mParams.GetICDCheckInNodeId().HasValue() && mParams.GetICDMonitoredSubject().HasValue() &&
mParams.GetICDSymmetricKey().HasValue())
{
return CommissioningStage::kICDRegistration;
}
return CommissioningStage::kICDGetRegistrationInfo;
}
return GetNextCommissioningStageInternal(CommissioningStage::kICDRegistration, lastErr);
case CommissioningStage::kICDGetRegistrationInfo:
return CommissioningStage::kICDRegistration;
case CommissioningStage::kICDRegistration:
// TODO(cecille): device attestation casues operational cert provisioning to happen, This should be a separate stage.
// For thread and wifi, this should go to network setup then enable. For on-network we can skip right to finding the
// operational network because the provisioning of certificates will trigger the device to start operational advertising.
if (mNeedsNetworkSetup)
{
// if there is a WiFi or a Thread endpoint, then perform scan
if (IsScanNeeded())
{
// Perform Scan (kScanNetworks) and collect credentials (kNeedsNetworkCreds) right before configuring network.
// This order of steps allows the workflow to return to collect credentials again if network enablement fails.
return CommissioningStage::kScanNetworks;
}
ChipLogProgress(Controller, "No NetworkScan enabled or WiFi/Thread endpoint not specified, skipping ScanNetworks");
return GetNextCommissioningStageNetworkSetup(currentStage, lastErr);
}
else
{
SetCASEFailsafeTimerIfNeeded();
if (mParams.GetSkipCommissioningComplete().ValueOr(false))
{
return CommissioningStage::kCleanup;
}
return CommissioningStage::kEvictPreviousCaseSessions;
}
case CommissioningStage::kScanNetworks:
return CommissioningStage::kNeedsNetworkCreds;
case CommissioningStage::kNeedsNetworkCreds:
return GetNextCommissioningStageNetworkSetup(currentStage, lastErr);
case CommissioningStage::kWiFiNetworkSetup:
return CommissioningStage::kFailsafeBeforeWiFiEnable;
case CommissioningStage::kThreadNetworkSetup:
return CommissioningStage::kFailsafeBeforeThreadEnable;
case CommissioningStage::kFailsafeBeforeWiFiEnable:
return CommissioningStage::kWiFiNetworkEnable;
case CommissioningStage::kFailsafeBeforeThreadEnable:
return CommissioningStage::kThreadNetworkEnable;
case CommissioningStage::kWiFiNetworkEnable:
if (mParams.GetSkipCommissioningComplete().ValueOr(false))
{
SetCASEFailsafeTimerIfNeeded();
return CommissioningStage::kCleanup;
}
else
{
SetCASEFailsafeTimerIfNeeded();
return CommissioningStage::kEvictPreviousCaseSessions;
}
case CommissioningStage::kThreadNetworkEnable:
SetCASEFailsafeTimerIfNeeded();
if (mParams.GetSkipCommissioningComplete().ValueOr(false))
{
return CommissioningStage::kCleanup;
}
return CommissioningStage::kEvictPreviousCaseSessions;
case CommissioningStage::kEvictPreviousCaseSessions:
return CommissioningStage::kFindOperationalForStayActive;
case CommissioningStage::kPrimaryOperationalNetworkFailed:
return CommissioningStage::kDisablePrimaryNetworkInterface;
case CommissioningStage::kDisablePrimaryNetworkInterface:
return GetNextCommissioningStageNetworkSetup(currentStage, lastErr);
case CommissioningStage::kFindOperationalForStayActive:
return CommissioningStage::kICDSendStayActive;
case CommissioningStage::kICDSendStayActive:
return CommissioningStage::kFindOperationalForCommissioningComplete;
case CommissioningStage::kFindOperationalForCommissioningComplete:
return CommissioningStage::kSendComplete;
case CommissioningStage::kSendComplete:
return CommissioningStage::kCleanup;
// Neither of these have a next stage so return kError;
case CommissioningStage::kCleanup:
case CommissioningStage::kError:
return CommissioningStage::kError;
}
return CommissioningStage::kError;
}
// No specific actions to take when an error happens since this command can fail and commissioning can still succeed.
static void OnFailsafeFailureForCASE(void * context, CHIP_ERROR error)
{
ChipLogProgress(Controller, "ExtendFailsafe received failure response %s\n", chip::ErrorStr(error));
}
// No specific actions to take upon success.
static void
OnExtendFailsafeSuccessForCASE(void * context,
const app::Clusters::GeneralCommissioning::Commands::ArmFailSafeResponse::DecodableType & data)
{
ChipLogProgress(Controller, "ExtendFailsafe received ArmFailSafe response errorCode=%u", to_underlying(data.errorCode));
}
void AutoCommissioner::SetCASEFailsafeTimerIfNeeded()
{
// if there is a final fail-safe timer configured then, send it
if (mParams.GetCASEFailsafeTimerSeconds().HasValue() && mCommissioneeDeviceProxy != nullptr)
{
// send the command via the PASE session (mCommissioneeDeviceProxy) since the CASE portion of commissioning
// might be done by a different service (ex. PASE is done by a phone app and CASE is done by a Hub).
// Also, we want the CASE failsafe timer to apply for the time it takes the Hub to perform operational discovery,
// CASE establishment, and receipt of the commissioning complete command.
// We know that the mCommissioneeDeviceProxy is still valid at this point since it gets cleared during cleanup
// and SetCASEFailsafeTimerIfNeeded is always called before that stage.
//
// A false return from ExtendArmFailSafe is fine; we don't want to make
// the fail-safe shorter here.
mCommissioner->ExtendArmFailSafe(mCommissioneeDeviceProxy, mCommissioner->GetCommissioningStage(),
mParams.GetCASEFailsafeTimerSeconds().Value(),
GetCommandTimeout(mCommissioneeDeviceProxy, CommissioningStage::kArmFailsafe),
OnExtendFailsafeSuccessForCASE, OnFailsafeFailureForCASE);
}
}
EndpointId AutoCommissioner::GetEndpoint(const CommissioningStage & stage) const
{
switch (stage)
{
case CommissioningStage::kWiFiNetworkSetup:
case CommissioningStage::kWiFiNetworkEnable:
return mDeviceCommissioningInfo.network.wifi.endpoint;
case CommissioningStage::kThreadNetworkSetup:
case CommissioningStage::kThreadNetworkEnable:
return mDeviceCommissioningInfo.network.thread.endpoint;
case CommissioningStage::kDisablePrimaryNetworkInterface:
return kRootEndpointId;
default:
return kRootEndpointId;
}
}
CHIP_ERROR AutoCommissioner::StartCommissioning(DeviceCommissioner * commissioner, CommissioneeDeviceProxy * proxy)
{
if (commissioner == nullptr)
{
ChipLogError(Controller, "Invalid DeviceCommissioner");
return CHIP_ERROR_INVALID_ARGUMENT;
}
if (proxy == nullptr || !proxy->GetSecureSession().HasValue())
{
ChipLogError(Controller, "Device proxy secure session error");
return CHIP_ERROR_INVALID_ARGUMENT;
}
mStopCommissioning = false;
mCommissioner = commissioner;
mCommissioneeDeviceProxy = proxy;
auto transportType =
mCommissioneeDeviceProxy->GetSecureSession().Value()->AsSecureSession()->GetPeerAddress().GetTransportType();
mNeedsNetworkSetup = (transportType == Transport::Type::kBle);
#if CHIP_DEVICE_CONFIG_ENABLE_WIFIPAF
mNeedsNetworkSetup = mNeedsNetworkSetup || (transportType == Transport::Type::kWiFiPAF);
#endif
CHIP_ERROR err = CHIP_NO_ERROR;
CommissioningStage nextStage = GetNextCommissioningStage(CommissioningStage::kSecurePairing, err);
mCommissioner->PerformCommissioningStep(mCommissioneeDeviceProxy, nextStage, mParams, this, GetEndpoint(nextStage),
GetCommandTimeout(mCommissioneeDeviceProxy, nextStage));
return CHIP_NO_ERROR;
}
Optional<System::Clock::Timeout> AutoCommissioner::GetCommandTimeout(DeviceProxy * device, CommissioningStage stage) const
{
// Network clusters can indicate the time required to connect, so if we are
// connecting, use that time as our "how long it takes to process server
// side" time. Otherwise pick a time that should be enough for the command
// processing: 7s for slow steps that can involve crypto, the default IM
// timeout otherwise.
// TODO: is this a reasonable estimate for the slow-crypto cases?
constexpr System::Clock::Timeout kSlowCryptoProcessingTime = System::Clock::Seconds16(7);
System::Clock::Timeout timeout;
switch (stage)
{
case CommissioningStage::kWiFiNetworkEnable:
ChipLogProgress(Controller, "Setting wifi connection time min = %u",
mDeviceCommissioningInfo.network.wifi.minConnectionTime);
timeout = System::Clock::Seconds16(mDeviceCommissioningInfo.network.wifi.minConnectionTime);
break;
case CommissioningStage::kThreadNetworkEnable:
timeout = System::Clock::Seconds16(mDeviceCommissioningInfo.network.thread.minConnectionTime);
break;
case CommissioningStage::kSendNOC:
case CommissioningStage::kSendOpCertSigningRequest:
timeout = kSlowCryptoProcessingTime;
break;
default:
timeout = app::kExpectedIMProcessingTime;
break;
}
// Adjust the timeout for our session transport latency, if we have access
// to a session.
auto sessionHandle = device->GetSecureSession();
if (sessionHandle.HasValue())
{
timeout = sessionHandle.Value()->ComputeRoundTripTimeout(timeout);
}
// Enforce the spec minimal timeout. Maybe this enforcement should live in
// the DeviceCommissioner?
if (timeout < kMinimumCommissioningStepTimeout)
{
timeout = kMinimumCommissioningStepTimeout;
}
return MakeOptional(timeout);
}
CHIP_ERROR AutoCommissioner::NOCChainGenerated(ByteSpan noc, ByteSpan icac, ByteSpan rcac, IdentityProtectionKeySpan ipk,
NodeId adminSubject)
{
// Reuse ICA Cert buffer for temporary store Root Cert.
MutableByteSpan rootCert = MutableByteSpan(mICACertBuffer);
ReturnErrorOnFailure(Credentials::ConvertX509CertToChipCert(rcac, rootCert));
mParams.SetRootCert(rootCert);
MutableByteSpan noCert = MutableByteSpan(mNOCertBuffer);
ReturnErrorOnFailure(Credentials::ConvertX509CertToChipCert(noc, noCert));
mParams.SetNoc(noCert);
CommissioningStage nextStage = CommissioningStage::kSendTrustedRootCert;
mCommissioner->PerformCommissioningStep(mCommissioneeDeviceProxy, nextStage, mParams, this, 0,
GetCommandTimeout(mCommissioneeDeviceProxy, nextStage));
// Trusted root cert has been sent, so we can re-use the icac buffer for the icac.
if (!icac.empty())
{
MutableByteSpan icaCert = MutableByteSpan(mICACertBuffer);
ReturnErrorOnFailure(Credentials::ConvertX509CertToChipCert(icac, icaCert));
mParams.SetIcac(icaCert);
}
else
{
mParams.SetIcac(ByteSpan());
}
mParams.SetIpk(ipk);
mParams.SetAdminSubject(adminSubject);
return CHIP_NO_ERROR;
}
CHIP_ERROR AutoCommissioner::CommissioningStepFinished(CHIP_ERROR err, CommissioningDelegate::CommissioningReport report)
{
CompletionStatus completionStatus;
completionStatus.err = err;
if (err != CHIP_NO_ERROR)
{
ChipLogError(Controller, "Error on commissioning step '%s': '%s'", StageToString(report.stageCompleted), err.AsString());
completionStatus.failedStage = MakeOptional(report.stageCompleted);
if (report.Is<AttestationErrorInfo>())
{
completionStatus.attestationResult = MakeOptional(report.Get<AttestationErrorInfo>().attestationResult);
if ((report.Get<AttestationErrorInfo>().attestationResult ==
Credentials::AttestationVerificationResult::kDacProductIdMismatch) ||
(report.Get<AttestationErrorInfo>().attestationResult ==
Credentials::AttestationVerificationResult::kDacVendorIdMismatch))
{
ChipLogError(Controller,
"Failed device attestation. Device vendor and/or product ID do not match the IDs expected. "
"Verify DAC certificate chain and certification declaration to ensure spec rules followed.");
}
if (report.stageCompleted == CommissioningStage::kAttestationVerification)
{
ChipLogError(Controller, "Failed verifying attestation information. Now checking DAC chain revoked status.");
// don't error out until we check for DAC chain revocation status
err = CHIP_NO_ERROR;
}
}
else if (report.Is<CommissioningErrorInfo>())
{
completionStatus.commissioningError = MakeOptional(report.Get<CommissioningErrorInfo>().commissioningError);
}
else if (report.Is<NetworkCommissioningStatusInfo>())
{
// This report type is used when an error happens in either NetworkConfig or ConnectNetwork commands
completionStatus.networkCommissioningStatus =
MakeOptional(report.Get<NetworkCommissioningStatusInfo>().networkCommissioningStatus);
// If we are configured to scan networks, then don't error out.
// Instead, allow the app to try another network.
if (IsScanNeeded())
{
if (completionStatus.err == CHIP_NO_ERROR)
{
completionStatus.err = err;
}
err = CHIP_NO_ERROR;
// Walk back the completed stage to kScanNetworks.
// This will allow the app to try another network.
report.stageCompleted = CommissioningStage::kScanNetworks;
}
}
if (err != CHIP_NO_ERROR && IsSecondaryNetworkSupported() && !TryingSecondaryNetwork() &&
completionStatus.failedStage.HasValue() && completionStatus.failedStage.Value() >= kWiFiNetworkSetup &&
completionStatus.failedStage.Value() <= kICDSendStayActive)
{
// Primary network failed, disable primary network interface and try secondary network interface.
TrySecondaryNetwork();
err = CHIP_NO_ERROR;
report.stageCompleted = CommissioningStage::kPrimaryOperationalNetworkFailed;
}
}
else
{
ChipLogProgress(Controller, "Successfully finished commissioning step '%s'", StageToString(report.stageCompleted));
switch (report.stageCompleted)
{
case CommissioningStage::kReadCommissioningInfo:
break;
case CommissioningStage::kReadCommissioningInfo2: {
mDeviceCommissioningInfo = report.Get<ReadCommissioningInfo>();
if (!mParams.GetFailsafeTimerSeconds().HasValue() && mDeviceCommissioningInfo.general.recommendedFailsafe > 0)
{
mParams.SetFailsafeTimerSeconds(mDeviceCommissioningInfo.general.recommendedFailsafe);
}
mParams.SetRemoteVendorId(mDeviceCommissioningInfo.basic.vendorId)
.SetRemoteProductId(mDeviceCommissioningInfo.basic.productId)
.SetDefaultRegulatoryLocation(mDeviceCommissioningInfo.general.currentRegulatoryLocation)
.SetLocationCapability(mDeviceCommissioningInfo.general.locationCapability);
// Don't send DST unless the device says it needs it
mNeedsDST = false;
mParams.SetSupportsConcurrentConnection(mDeviceCommissioningInfo.supportsConcurrentConnection);
if (mParams.GetCheckForMatchingFabric())
{
NodeId nodeId = mDeviceCommissioningInfo.remoteNodeId;
if (nodeId != kUndefinedNodeId)
{
mParams.SetRemoteNodeId(nodeId);
}
}
if (mParams.GetICDRegistrationStrategy() != ICDRegistrationStrategy::kIgnore)
{
if (mDeviceCommissioningInfo.icd.isLIT && mDeviceCommissioningInfo.icd.checkInProtocolSupport)
{
mNeedIcdRegistration = true;
ChipLogDetail(Controller, "AutoCommissioner: ICD supports the check-in protocol.");
}
else if (mParams.GetICDStayActiveDurationMsec().HasValue())
{
ChipLogDetail(Controller, "AutoCommissioner: Clear ICD StayActiveDurationMsec");
mParams.ClearICDStayActiveDurationMsec();
}
}
break;
}
case CommissioningStage::kConfigureTimeZone:
mNeedsDST = report.Get<TimeZoneResponseInfo>().requiresDSTOffsets;
break;
case CommissioningStage::kSendPAICertificateRequest:
SetPAI(report.Get<RequestedCertificate>().certificate);
break;
case CommissioningStage::kSendDACCertificateRequest:
SetDAC(report.Get<RequestedCertificate>().certificate);
break;
case CommissioningStage::kSendAttestationRequest: {
auto & elements = report.Get<AttestationResponse>().attestationElements;
auto & signature = report.Get<AttestationResponse>().signature;
if (elements.size() > sizeof(mAttestationElements))
{
ChipLogError(Controller, "AutoCommissioner attestationElements buffer size %u larger than cache size %u",
static_cast<unsigned>(elements.size()), static_cast<unsigned>(sizeof(mAttestationElements)));
return CHIP_ERROR_MESSAGE_TOO_LONG;
}
memcpy(mAttestationElements, elements.data(), elements.size());
mAttestationElementsLen = static_cast<uint16_t>(elements.size());
mParams.SetAttestationElements(ByteSpan(mAttestationElements, elements.size()));
ChipLogDetail(Controller, "AutoCommissioner setting attestationElements buffer size %u/%u",
static_cast<unsigned>(elements.size()),
static_cast<unsigned>(mParams.GetAttestationElements().Value().size()));
if (signature.size() > sizeof(mAttestationSignature))
{
ChipLogError(Controller,
"AutoCommissioner attestationSignature buffer size %u larger than "
"cache size %u",
static_cast<unsigned>(signature.size()), static_cast<unsigned>(sizeof(mAttestationSignature)));
return CHIP_ERROR_MESSAGE_TOO_LONG;
}
memcpy(mAttestationSignature, signature.data(), signature.size());
mAttestationSignatureLen = static_cast<uint16_t>(signature.size());
mParams.SetAttestationSignature(ByteSpan(mAttestationSignature, signature.size()));
// TODO: Does this need to be done at runtime? Seems like this could be done earlier and we wouldn't need to hold a
// reference to the operational credential delegate here
if (mOperationalCredentialsDelegate != nullptr)
{
MutableByteSpan nonce(mCSRNonce);
ReturnErrorOnFailure(mOperationalCredentialsDelegate->ObtainCsrNonce(nonce));
mParams.SetCSRNonce(ByteSpan(mCSRNonce, sizeof(mCSRNonce)));
}
break;
}
case CommissioningStage::kSendOpCertSigningRequest: {
NOCChainGenerationParameters nocParams;
nocParams.nocsrElements = report.Get<CSRResponse>().nocsrElements;
nocParams.signature = report.Get<CSRResponse>().signature;
mParams.SetNOCChainGenerationParameters(nocParams);
}
break;
case CommissioningStage::kGenerateNOCChain:
// For NOC chain generation, we re-use the buffers. NOCChainGenerated triggers the next stage before
// storing the returned certs, so just return here without triggering the next stage.
return NOCChainGenerated(report.Get<NocChain>().noc, report.Get<NocChain>().icac, report.Get<NocChain>().rcac,
report.Get<NocChain>().ipk, report.Get<NocChain>().adminSubject);
case CommissioningStage::kICDGetRegistrationInfo:
// Noting to do. The ICD registation info is handled elsewhere.
break;
case CommissioningStage::kICDRegistration:
// Noting to do. DevicePairingDelegate will handle this.
break;
case CommissioningStage::kFindOperationalForStayActive:
case CommissioningStage::kFindOperationalForCommissioningComplete:
mOperationalDeviceProxy = report.Get<OperationalNodeFoundData>().operationalProxy;
break;
case CommissioningStage::kCleanup:
if (IsSecondaryNetworkSupported() && TryingSecondaryNetwork())
{
ResetTryingSecondaryNetwork();
}
ReleasePAI();
ReleaseDAC();
mCommissioneeDeviceProxy = nullptr;
mOperationalDeviceProxy = OperationalDeviceProxy();
mDeviceCommissioningInfo = ReadCommissioningInfo();
mNeedsDST = false;
return CHIP_NO_ERROR;
default:
break;
}
}
CommissioningStage nextStage = GetNextCommissioningStage(report.stageCompleted, err);
if (nextStage == CommissioningStage::kError)
{
return CHIP_ERROR_INCORRECT_STATE;
}
// If GetNextCommissioningStage indicated a failure, don't lose track of
// that. But don't overwrite any existing failures we had hanging
// around.
if (completionStatus.err == CHIP_NO_ERROR)
{
completionStatus.err = err;
}
mParams.SetCompletionStatus(completionStatus);
return PerformStep(nextStage);
}
DeviceProxy * AutoCommissioner::GetDeviceProxyForStep(CommissioningStage nextStage)
{
if (nextStage == CommissioningStage::kSendComplete || nextStage == CommissioningStage::kICDSendStayActive ||
(nextStage == CommissioningStage::kCleanup && mOperationalDeviceProxy.GetDeviceId() != kUndefinedNodeId))
{
return &mOperationalDeviceProxy;
}
return mCommissioneeDeviceProxy;
}
CHIP_ERROR AutoCommissioner::PerformStep(CommissioningStage nextStage)
{
DeviceProxy * proxy = GetDeviceProxyForStep(nextStage);
if (proxy == nullptr)
{
ChipLogError(Controller, "Invalid device for commissioning");
return CHIP_ERROR_INCORRECT_STATE;
}
// Perform any last minute parameter adjustments before calling the commissioner object
switch (nextStage)
{
case CommissioningStage::kConfigureTimeZone:
if (mParams.GetTimeZone().Value().size() > mDeviceCommissioningInfo.maxTimeZoneSize)
{
mParams.SetTimeZone(app::DataModel::List<app::Clusters::TimeSynchronization::Structs::TimeZoneStruct::Type>(
mParams.GetTimeZone().Value().SubSpan(0, mDeviceCommissioningInfo.maxTimeZoneSize)));
}
break;
case CommissioningStage::kConfigureDSTOffset:
if (mParams.GetDSTOffsets().Value().size() > mDeviceCommissioningInfo.maxDSTSize)
{
mParams.SetDSTOffsets(app::DataModel::List<app::Clusters::TimeSynchronization::Structs::DSTOffsetStruct::Type>(
mParams.GetDSTOffsets().Value().SubSpan(0, mDeviceCommissioningInfo.maxDSTSize)));
}
break;
default:
break;
}
mCommissioner->PerformCommissioningStep(proxy, nextStage, mParams, this, GetEndpoint(nextStage),
GetCommandTimeout(proxy, nextStage));
return CHIP_NO_ERROR;
}
void AutoCommissioner::ReleaseDAC()
{
if (mDAC != nullptr)
{
Platform::MemoryFree(mDAC);
}
mDACLen = 0;
mDAC = nullptr;
}
CHIP_ERROR AutoCommissioner::SetDAC(const ByteSpan & dac)
{
if (dac.size() == 0)
{
ReleaseDAC();
return CHIP_NO_ERROR;
}
VerifyOrReturnError(dac.size() <= Credentials::kMaxDERCertLength, CHIP_ERROR_INVALID_ARGUMENT);
if (mDACLen != 0)
{
ReleaseDAC();
}
VerifyOrReturnError(CanCastTo<uint16_t>(dac.size()), CHIP_ERROR_INVALID_ARGUMENT);
if (mDAC == nullptr)
{
mDAC = static_cast<uint8_t *>(chip::Platform::MemoryAlloc(dac.size()));
}
VerifyOrReturnError(mDAC != nullptr, CHIP_ERROR_NO_MEMORY);
mDACLen = static_cast<uint16_t>(dac.size());
memcpy(mDAC, dac.data(), mDACLen);
mParams.SetDAC(ByteSpan(mDAC, mDACLen));
return CHIP_NO_ERROR;
}
void AutoCommissioner::ReleasePAI()
{
if (mPAI != nullptr)
{
chip::Platform::MemoryFree(mPAI);
}
mPAILen = 0;
mPAI = nullptr;
}
CHIP_ERROR AutoCommissioner::SetPAI(const chip::ByteSpan & pai)
{
if (pai.size() == 0)
{
ReleasePAI();
return CHIP_NO_ERROR;
}
VerifyOrReturnError(pai.size() <= Credentials::kMaxDERCertLength, CHIP_ERROR_INVALID_ARGUMENT);
if (mPAILen != 0)
{
ReleasePAI();
}
VerifyOrReturnError(CanCastTo<uint16_t>(pai.size()), CHIP_ERROR_INVALID_ARGUMENT);
if (mPAI == nullptr)
{
mPAI = static_cast<uint8_t *>(chip::Platform::MemoryAlloc(pai.size()));
}
VerifyOrReturnError(mPAI != nullptr, CHIP_ERROR_NO_MEMORY);
mPAILen = static_cast<uint16_t>(pai.size());
memcpy(mPAI, pai.data(), mPAILen);
mParams.SetPAI(ByteSpan(mPAI, mPAILen));
return CHIP_NO_ERROR;
}
} // namespace Controller
} // namespace chip