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/*
*
* Copyright (c) 2021-2022 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.
*/
/**
* @file
* This file implements an object for a Matter User Directed Commissioning unsolicited
* recipient (server).
*
*/
#include "UserDirectedCommissioning.h"
#include <lib/core/CHIPSafeCasts.h>
#include <system/TLVPacketBufferBackingStore.h>
#include <unistd.h>
namespace chip {
namespace Protocols {
namespace UserDirectedCommissioning {
void UserDirectedCommissioningServer::OnMessageReceived(const Transport::PeerAddress & source, System::PacketBufferHandle && msg)
{
char addrBuffer[chip::Transport::PeerAddress::kMaxToStringSize];
source.ToString(addrBuffer);
ChipLogProgress(AppServer, "UserDirectedCommissioningServer::OnMessageReceived from %s", addrBuffer);
PacketHeader packetHeader;
ReturnOnFailure(packetHeader.DecodeAndConsume(msg));
if (packetHeader.IsEncrypted())
{
ChipLogError(AppServer, "UDC encryption flag set - ignoring");
return;
}
PayloadHeader payloadHeader;
ReturnOnFailure(payloadHeader.DecodeAndConsume(msg));
ChipLogProgress(AppServer, "IdentityDeclaration DataLength()=%d", msg->DataLength());
uint8_t udcPayload[IdentificationDeclaration::kUdcTLVDataMaxBytes];
size_t udcPayloadLength = std::min<size_t>(msg->DataLength(), sizeof(udcPayload));
msg->Read(udcPayload, udcPayloadLength);
IdentificationDeclaration id;
id.ReadPayload(udcPayload, sizeof(udcPayload));
char * instanceName = (char *) id.GetInstanceName();
ChipLogProgress(AppServer, "UDC instance=%s ", id.GetInstanceName());
UDCClientState * client = mUdcClients.FindUDCClientState(instanceName);
if (client == nullptr)
{
ChipLogProgress(AppServer, "UDC new instance state received");
id.DebugLog();
CHIP_ERROR err;
err = mUdcClients.CreateNewUDCClientState(instanceName, &client);
if (err != CHIP_NO_ERROR)
{
ChipLogError(AppServer, "UDC error creating new connection state");
return;
}
if (id.HasDiscoveryInfo())
{
// if we received mDNS info, skip the commissionable lookup
ChipLogDetail(AppServer, "UDC discovery info provided");
mUdcClients.MarkUDCClientActive(client);
client->SetUDCClientProcessingState(UDCClientProcessingState::kPromptingUser);
client->SetPeerAddress(source);
id.UpdateClientState(client);
// TEST: send reply
if (id.GetCdPort() != 0)
{
CommissionerDeclaration cd;
cd.SetErrorCode(CommissionerDeclaration::CdError::kAppInstallConsentPending);
cd.SetNeedsPasscode(true);
SendCDCMessage(cd, chip::Transport::PeerAddress::UDP(source.GetIPAddress(), id.GetCdPort()));
}
// Call the registered mUserConfirmationProvider, if any.
if (mUserConfirmationProvider != nullptr)
{
mUserConfirmationProvider->OnUserDirectedCommissioningRequest(*client);
}
return;
}
// Call the registered InstanceNameResolver, if any.
if (mInstanceNameResolver != nullptr)
{
mInstanceNameResolver->FindCommissionableNode(instanceName);
}
else
{
ChipLogError(AppServer, "UserDirectedCommissioningServer::OnMessageReceived no mInstanceNameResolver registered");
}
}
mUdcClients.MarkUDCClientActive(client);
}
CHIP_ERROR UserDirectedCommissioningServer::SendCDCMessage(CommissionerDeclaration cd, chip::Transport::PeerAddress peerAddress)
{
if (mTransportMgr == nullptr)
{
ChipLogError(AppServer, "CDC: No transport manager\n");
return CHIP_ERROR_INCORRECT_STATE;
}
uint8_t idBuffer[IdentificationDeclaration::kUdcTLVDataMaxBytes];
uint32_t length = cd.WritePayload(idBuffer, sizeof(idBuffer));
if (length == 0)
{
ChipLogError(AppServer, "CDC: error writing payload\n");
return CHIP_ERROR_INTERNAL;
}
chip::System::PacketBufferHandle payload = chip::MessagePacketBuffer::NewWithData(idBuffer, length);
if (payload.IsNull())
{
ChipLogError(AppServer, "Unable to allocate packet buffer\n");
return CHIP_ERROR_NO_MEMORY;
}
ReturnErrorOnFailure(EncodeUDCMessage(payload));
cd.DebugLog();
ChipLogProgress(Inet, "Sending CDC msg");
auto err = mTransportMgr->SendMessage(peerAddress, std::move(payload));
if (err != CHIP_NO_ERROR)
{
ChipLogError(AppServer, "CDC SendMessage failed: %" CHIP_ERROR_FORMAT, err.Format());
return err;
}
ChipLogProgress(Inet, "CDC msg sent");
return CHIP_NO_ERROR;
}
CHIP_ERROR UserDirectedCommissioningServer::EncodeUDCMessage(const System::PacketBufferHandle & payload)
{
PayloadHeader payloadHeader;
PacketHeader packetHeader;
payloadHeader.SetMessageType(MsgType::IdentificationDeclaration).SetInitiator(true).SetNeedsAck(false);
VerifyOrReturnError(!payload.IsNull(), CHIP_ERROR_INVALID_ARGUMENT);
VerifyOrReturnError(!payload->HasChainedBuffer(), CHIP_ERROR_INVALID_MESSAGE_LENGTH);
VerifyOrReturnError(payload->TotalLength() <= kMaxAppMessageLen, CHIP_ERROR_MESSAGE_TOO_LONG);
ReturnErrorOnFailure(payloadHeader.EncodeBeforeData(payload));
ReturnErrorOnFailure(packetHeader.EncodeBeforeData(payload));
return CHIP_NO_ERROR;
}
CHIP_ERROR IdentificationDeclaration::ReadPayload(uint8_t * udcPayload, size_t payloadBufferSize)
{
size_t i = 0;
while (i < std::min<size_t>(sizeof(mInstanceName), payloadBufferSize) && udcPayload[i] != '\0')
{
mInstanceName[i] = (char) udcPayload[i];
i++;
}
mInstanceName[i] = '\0';
if (payloadBufferSize <= sizeof(mInstanceName))
{
ChipLogProgress(AppServer, "UDC - No TLV information in Identification Declaration");
return CHIP_NO_ERROR;
}
// advance i to the end of the fixed length block containing instance name
i = sizeof(mInstanceName);
CHIP_ERROR err;
TLV::TLVReader reader;
reader.Init(udcPayload + i, payloadBufferSize - i);
// read the envelope
ReturnErrorOnFailure(reader.Next(chip::TLV::kTLVType_Structure, chip::TLV::AnonymousTag()));
chip::TLV::TLVType outerContainerType = chip::TLV::kTLVType_Structure;
ReturnErrorOnFailure(reader.EnterContainer(outerContainerType));
while ((err = reader.Next()) == CHIP_NO_ERROR)
{
chip::TLV::Tag containerTag = reader.GetTag();
if (!TLV::IsContextTag(containerTag))
{
ChipLogError(AppServer, "Unexpected non-context TLV tag.");
return CHIP_ERROR_INVALID_TLV_TAG;
}
uint8_t tagNum = static_cast<uint8_t>(chip::TLV::TagNumFromTag(containerTag));
switch (tagNum)
{
case kVendorIdTag:
// vendorId
err = reader.Get(mVendorId);
break;
case kProductIdTag:
// productId
err = reader.Get(mProductId);
break;
case kCdPortTag:
// port
err = reader.Get(mCdPort);
break;
case kDeviceNameTag:
// deviceName
err = reader.GetString(mDeviceName, sizeof(mDeviceName));
break;
case kPairingInstTag:
// pairingInst
err = reader.GetString(mPairingInst, sizeof(mPairingInst));
break;
case kPairingHintTag:
// pairingHint
err = reader.Get(mPairingHint);
break;
case kRotatingIdTag:
// rotatingId
mRotatingIdLen = reader.GetLength();
err = reader.GetBytes(mRotatingId, sizeof(mRotatingId));
break;
case kTargetAppListTag:
// app vendor list
{
ChipLogProgress(AppServer, "TLV found an applist");
chip::TLV::TLVType listContainerType = chip::TLV::kTLVType_List;
ReturnErrorOnFailure(reader.EnterContainer(listContainerType));
while ((err = reader.Next()) == CHIP_NO_ERROR && mNumTargetAppInfos < sizeof(mTargetAppInfos))
{
containerTag = reader.GetTag();
if (!TLV::IsContextTag(containerTag))
{
ChipLogError(AppServer, "Unexpected non-context TLV tag.");
return CHIP_ERROR_INVALID_TLV_TAG;
}
tagNum = static_cast<uint8_t>(chip::TLV::TagNumFromTag(containerTag));
if (tagNum == kTargetAppTag)
{
ReturnErrorOnFailure(reader.EnterContainer(outerContainerType));
uint16_t appVendorId = 0;
uint16_t appProductId = 0;
while ((err = reader.Next()) == CHIP_NO_ERROR)
{
containerTag = reader.GetTag();
if (!TLV::IsContextTag(containerTag))
{
ChipLogError(AppServer, "Unexpected non-context TLV tag.");
return CHIP_ERROR_INVALID_TLV_TAG;
}
tagNum = static_cast<uint8_t>(chip::TLV::TagNumFromTag(containerTag));
if (tagNum == kAppVendorIdTag)
{
err = reader.Get(appVendorId);
}
else if (tagNum == kAppProductIdTag)
{
err = reader.Get(appProductId);
}
}
if (err == CHIP_END_OF_TLV)
{
ChipLogProgress(AppServer, "TLV end of struct TLV");
ReturnErrorOnFailure(reader.ExitContainer(outerContainerType));
}
if (appVendorId != 0)
{
mTargetAppInfos[mNumTargetAppInfos].vendorId = appVendorId;
mTargetAppInfos[mNumTargetAppInfos].productId = appProductId;
mNumTargetAppInfos++;
}
}
else
{
ChipLogError(AppServer, "unrecognized tag %d", tagNum);
}
}
if (err == CHIP_END_OF_TLV)
{
ChipLogProgress(AppServer, "TLV end of array");
ReturnErrorOnFailure(reader.ExitContainer(listContainerType));
}
}
break;
case kNoPasscodeTag:
err = reader.Get(mNoPasscode);
break;
case kCdUponPasscodeDialogTag:
err = reader.Get(mCdUponPasscodeDialog);
break;
case kCommissionerPasscodeTag:
err = reader.Get(mCommissionerPasscode);
break;
case kCommissionerPasscodeReadyTag:
err = reader.Get(mCommissionerPasscodeReady);
break;
case kCancelPasscodeTag:
err = reader.Get(mCancelPasscode);
break;
}
if (err != CHIP_NO_ERROR)
{
ChipLogError(AppServer, "IdentificationDeclaration::ReadPayload read error %" CHIP_ERROR_FORMAT, err.Format());
}
}
if (err == CHIP_END_OF_TLV)
{
// Exiting container
ReturnErrorOnFailure(reader.ExitContainer(outerContainerType));
}
else
{
ChipLogError(AppServer, "IdentificationDeclaration::ReadPayload exiting early error %" CHIP_ERROR_FORMAT, err.Format());
}
ChipLogProgress(AppServer, "UDC TLV parse complete");
return CHIP_NO_ERROR;
}
/**
* Reset the connection state to a completely uninitialized status.
*/
uint32_t CommissionerDeclaration::WritePayload(uint8_t * payloadBuffer, size_t payloadBufferSize)
{
CHIP_ERROR err;
chip::TLV::TLVWriter writer;
writer.Init(payloadBuffer, payloadBufferSize);
chip::TLV::TLVType outerContainerType = chip::TLV::kTLVType_Structure;
VerifyOrExit(CHIP_NO_ERROR ==
(err = writer.StartContainer(chip::TLV::AnonymousTag(), chip::TLV::kTLVType_Structure, outerContainerType)),
LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR == (err = writer.Put(chip::TLV::ContextTag(kErrorCodeTag), GetErrorCode())), LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR == (err = writer.PutBoolean(chip::TLV::ContextTag(kNeedsPasscodeTag), mNeedsPasscode)),
LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR == (err = writer.PutBoolean(chip::TLV::ContextTag(kNoAppsFoundTag), mNoAppsFound)),
LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR ==
(err = writer.PutBoolean(chip::TLV::ContextTag(kPasscodeDialogDisplayedTag), mPasscodeDialogDisplayed)),
LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR == (err = writer.PutBoolean(chip::TLV::ContextTag(kCommissionerPasscodeTag), mCommissionerPasscode)),
LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR == (err = writer.PutBoolean(chip::TLV::ContextTag(kQRCodeDisplayedTag), mQRCodeDisplayed)),
LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR == (err = writer.EndContainer(outerContainerType)), LogErrorOnFailure(err));
VerifyOrExit(CHIP_NO_ERROR == (err = writer.Finalize()), LogErrorOnFailure(err));
ChipLogProgress(AppServer, "TLV write done");
return writer.GetLengthWritten();
exit:
return 0;
}
void UserDirectedCommissioningServer::SetUDCClientProcessingState(char * instanceName, UDCClientProcessingState state)
{
UDCClientState * client = mUdcClients.FindUDCClientState(instanceName);
if (client == nullptr)
{
CHIP_ERROR err;
err = mUdcClients.CreateNewUDCClientState(instanceName, &client);
if (err != CHIP_NO_ERROR)
{
ChipLogError(AppServer,
"UserDirectedCommissioningServer::SetUDCClientProcessingState error creating new connection state");
return;
}
}
ChipLogDetail(AppServer, "SetUDCClientProcessingState instance=%s new state=%d", StringOrNullMarker(instanceName), (int) state);
client->SetUDCClientProcessingState(state);
mUdcClients.MarkUDCClientActive(client);
}
void UserDirectedCommissioningServer::OnCommissionableNodeFound(const Dnssd::DiscoveredNodeData & nodeData)
{
if (nodeData.resolutionData.numIPs == 0)
{
ChipLogError(AppServer, "OnCommissionableNodeFound no IP addresses returned for instance name=%s",
nodeData.commissionData.instanceName);
return;
}
if (nodeData.resolutionData.port == 0)
{
ChipLogError(AppServer, "OnCommissionableNodeFound no port returned for instance name=%s",
nodeData.commissionData.instanceName);
return;
}
UDCClientState * client = mUdcClients.FindUDCClientState(nodeData.commissionData.instanceName);
if (client != nullptr && client->GetUDCClientProcessingState() == UDCClientProcessingState::kDiscoveringNode)
{
ChipLogDetail(AppServer, "OnCommissionableNodeFound instance: name=%s old_state=%d new_state=%d", client->GetInstanceName(),
(int) client->GetUDCClientProcessingState(), (int) UDCClientProcessingState::kPromptingUser);
client->SetUDCClientProcessingState(UDCClientProcessingState::kPromptingUser);
#if INET_CONFIG_ENABLE_IPV4
// prefer IPv4 if its an option
bool foundV4 = false;
for (unsigned i = 0; i < nodeData.resolutionData.numIPs; ++i)
{
if (nodeData.resolutionData.ipAddress[i].IsIPv4())
{
foundV4 = true;
client->SetPeerAddress(
chip::Transport::PeerAddress::UDP(nodeData.resolutionData.ipAddress[i], nodeData.resolutionData.port));
break;
}
}
// use IPv6 as last resort
if (!foundV4)
{
client->SetPeerAddress(
chip::Transport::PeerAddress::UDP(nodeData.resolutionData.ipAddress[0], nodeData.resolutionData.port));
}
#else // INET_CONFIG_ENABLE_IPV4
// if we only support V6, then try to find a v6 address
bool foundV6 = false;
for (unsigned i = 0; i < nodeData.resolutionData.numIPs; ++i)
{
if (nodeData.resolutionData.ipAddress[i].IsIPv6())
{
foundV6 = true;
client->SetPeerAddress(
chip::Transport::PeerAddress::UDP(nodeData.resolutionData.ipAddress[i], nodeData.resolutionData.port));
break;
}
}
// last resort, try with what we have
if (!foundV6)
{
ChipLogError(AppServer, "OnCommissionableNodeFound no v6 returned for instance name=%s",
nodeData.commissionData.instanceName);
client->SetPeerAddress(
chip::Transport::PeerAddress::UDP(nodeData.resolutionData.ipAddress[0], nodeData.resolutionData.port));
}
#endif // INET_CONFIG_ENABLE_IPV4
client->SetDeviceName(nodeData.commissionData.deviceName);
client->SetLongDiscriminator(nodeData.commissionData.longDiscriminator);
client->SetVendorId(nodeData.commissionData.vendorId);
client->SetProductId(nodeData.commissionData.productId);
client->SetRotatingId(nodeData.commissionData.rotatingId, nodeData.commissionData.rotatingIdLen);
// Call the registered mUserConfirmationProvider, if any.
if (mUserConfirmationProvider != nullptr)
{
mUserConfirmationProvider->OnUserDirectedCommissioningRequest(*client);
}
}
}
void UserDirectedCommissioningServer::PrintUDCClients()
{
for (uint8_t i = 0; i < kMaxUDCClients; i++)
{
UDCClientState * state = GetUDCClients().GetUDCClientState(i);
if (state == nullptr)
{
ChipLogProgress(AppServer, "UDC Client[%d] null", i);
}
else
{
char addrBuffer[chip::Transport::PeerAddress::kMaxToStringSize];
state->GetPeerAddress().ToString(addrBuffer);
char rotatingIdString[chip::Dnssd::kMaxRotatingIdLen * 2 + 1] = "";
Encoding::BytesToUppercaseHexString(state->GetRotatingId(), chip::Dnssd::kMaxRotatingIdLen, rotatingIdString,
sizeof(rotatingIdString));
ChipLogProgress(AppServer, "UDC Client[%d] instance=%s deviceName=%s address=%s, vid/pid=%d/%d disc=%d rid=%s", i,
state->GetInstanceName(), state->GetDeviceName(), addrBuffer, state->GetVendorId(),
state->GetProductId(), state->GetLongDiscriminator(), rotatingIdString);
}
}
}
} // namespace UserDirectedCommissioning
} // namespace Protocols
} // namespace chip