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device.cpp
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device.cpp
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/*
* Copyright (c) 2021 dresden elektronik ingenieurtechnik gmbh.
* All rights reserved.
*
* The software in this package is published under the terms of the BSD
* style license a copy of which has been included with this distribution in
* the LICENSE.txt file.
*
*/
#include <QBasicTimer>
#include <QElapsedTimer>
#include <QTimer>
#include <QTimerEvent>
#include <QMetaObject>
#include <array>
#include <deconz/dbg_trace.h>
#include <deconz/node.h>
#include "device.h"
#include "device_access_fn.h"
#include "device_descriptions.h"
#include "event.h"
#include "event_emitter.h"
#include "utils/utils.h"
#include "zcl/zcl.h"
#include "zdp/zdp.h"
#define STATE_LEVEL_BINDING StateLevel1
#define STATE_LEVEL_POLL StateLevel2
#define MGMT_BIND_SUPPORT_UNKNOWN -1
#define MGMT_BIND_SUPPORTED 1
#define MGMT_BIND_NOT_SUPPORTED 0
#define DEV_INVALID_DEVICE_ID -1
typedef void (*DeviceStateHandler)(Device *, const Event &);
/*! Device state machine description can be found in the wiki:
https://github.com/dresden-elektronik/deconz-rest-plugin-v2/wiki/Device-Class#state-machine
*/
void DEV_InitStateHandler(Device *device, const Event &event);
void DEV_IdleStateHandler(Device *device, const Event &event);
void DEV_NodeDescriptorStateHandler(Device *device, const Event &event);
void DEV_ActiveEndpointsStateHandler(Device *device, const Event &event);
void DEV_SimpleDescriptorStateHandler(Device *device, const Event &event);
void DEV_BasicClusterStateHandler(Device *device, const Event &event);
void DEV_GetDeviceDescriptionHandler(Device *device, const Event &event);
static const deCONZ::SimpleDescriptor *DEV_GetSimpleDescriptorForServerCluster(const Device *device, deCONZ::ZclClusterId_t clusterId);
void DEV_BindingHandler(Device *device, const Event &event);
void DEV_BindingTableReadHandler(Device *device, const Event &event);
void DEV_BindingTableVerifyHandler(Device *device, const Event &event);
void DEV_BindingCreateHandler(Device *device, const Event &event);
void DEV_BindingRemoveHandler(Device *device, const Event &event);
void DEV_ReadReportConfigurationHandler(Device *device, const Event &event);
void DEV_ReadNextReportConfigurationHandler(Device *device, const Event &event);
void DEV_ConfigureNextReportConfigurationHandler(Device *device, const Event &event);
void DEV_ConfigureReportingHandler(Device *device, const Event &event);
void DEV_BindingIdleHandler(Device *device, const Event &event);
void DEV_PollIdleStateHandler(Device *device, const Event &event);
void DEV_PollNextStateHandler(Device *device, const Event &event);
void DEV_PollBusyStateHandler(Device *device, const Event &event);
void DEV_DeadStateHandler(Device *device, const Event &event);
// enable domain specific string literals
using namespace deCONZ::literals;
constexpr int RxOnWhenIdleResponseTime = 2000; // Expect shorter response delay for rxOnWhenIdle devices
constexpr int RxOffWhenIdleResponseTime = 8000; // 7680 ms + some space for timeout
constexpr int MaxConfirmTimeout = 20000; // If for some reason no APS-DATA.confirm is received (should almost
constexpr int BindingAutoCheckInterval = 1000 * 60 * 60;
constexpr int MaxPollItemRetries = 3;
constexpr int MaxIdleApsConfirmErrors = 16;
constexpr int MaxSubResources = 8;
static int devManaged = -1;
struct DEV_PollItem
{
explicit DEV_PollItem(const Resource *r, const ResourceItem *i, const QVariant &p) :
resource(r), item(i), readParameters(p) {}
size_t retry = 0;
const Resource *resource = nullptr;
const ResourceItem *item = nullptr;
QVariant readParameters;
};
// special value for ReportTracker::lastConfigureCheck during zcl configure reporting step
constexpr int64_t MarkZclConfigureBusy = 21;
struct ReportTracker
{
deCONZ::SteadyTimeRef lastReport;
deCONZ::SteadyTimeRef lastConfigureCheck;
uint16_t clusterId = 0;
uint16_t attributeId = 0;
uint8_t endpoint = 0;
};
struct BindingTracker
{
deCONZ::SteadyTimeRef tBound;
};
struct BindingContext
{
size_t bindingCheckRound = 0;
size_t bindingIter = 0;
size_t reportIter = 0;
size_t configIter = 0;
int mgmtBindSupported = MGMT_BIND_SUPPORT_UNKNOWN;
uint8_t mgmtBindStartIndex = 0;
std::vector<BindingTracker> bindingTrackers;
std::vector<DDF_Binding> bindings;
std::vector<ReportTracker> reportTrackers;
ZCL_ReadReportConfigurationParam readReportParam;
ZCL_Result zclResult;
ZDP_Result zdpResult;
};
static ReportTracker &DEV_GetOrCreateReportTracker(Device *device, uint16_t clusterId, uint16_t attrId, uint8_t endpoint);
class DevicePrivate
{
public:
void setState(DeviceStateHandler newState, DEV_StateLevel level = StateLevel0);
void startStateTimer(int IntervalMs, DEV_StateLevel level);
void stopStateTimer(DEV_StateLevel level);
bool hasRxOnWhenIdle() const;
Device *q = nullptr; //! reference to public interface
deCONZ::ApsController *apsCtrl = nullptr; //! opaque instance pointer forwarded to external functions
/*! sub-devices are not yet referenced via pointers since these may become dangling.
This is a helper to query the actual sub-device Resource* on demand via Resource::Handle.
*/
std::array<Resource::Handle, MaxSubResources> subResourceHandles;
std::vector<Resource*> subResources;
const deCONZ::Node *node = nullptr; //! a reference to the deCONZ core node
int deviceId = DEV_INVALID_DEVICE_ID;
DeviceKey deviceKey = 0; //! for physical devices this is the MAC address
/*! The currently active state handler function(s).
Indexes >0 represent sub states of StateLevel0 running in parallel.
*/
std::array<DeviceStateHandler, StateLevelMax> state{};
std::array<QBasicTimer, StateLevelMax> timer; //! internal single shot timer one for each state level
QElapsedTimer awake; //! time to track when an end-device was last awake
BindingContext binding; //! only used by binding sub state machine
std::vector<DEV_PollItem> pollItems; //! queue of items to poll
int idleApsConfirmErrors = 0;
/*! True while a new state waits for the state enter event, which must arrive first.
This is for debug asserting that the order of events is valid - it doesn't drive logic. */
bool stateEnterLock[StateLevelMax] = {};
bool managed = false; //! a managed device doesn't rely on legacy implementation of polling etc.
ZDP_Result zdpResult; //! keep track of a running ZDP request
DA_ReadResult readResult; //! keep track of a running "read" request
uint8_t zdpNeedFetchEndpointIndex = 0xFF; //! used in combination with flags.needReadSimpleDescriptors
int maxResponseTime = RxOffWhenIdleResponseTime;
struct
{
unsigned char hasDdf : 1;
unsigned char initialRun : 1;
unsigned char needZDPMaintenanceOnce : 1;
unsigned char needReadActiveEndpoints : 1;
unsigned char needReadSimpleDescriptors : 1;
unsigned char reserved : 3;
} flags{};
};
Device *DEV_ParentDevice(Resource *r)
{
if (r && r->parentResource() && r->parentResource()->prefix() == RDevices)
{
return static_cast<Device*>(r->parentResource());
}
return nullptr;
}
//! Forward device attribute changes to core.
void DEV_ForwardNodeChange(Device *device, const QString &key, const QString &value)
{
if (device)
{
QMetaObject::invokeMethod(device->d->apsCtrl, "onRestNodeUpdated", Qt::DirectConnection,
Q_ARG(quint64, device->key()), Q_ARG(QString, key), Q_ARG(QString, value));
}
}
void DEV_EnqueueEvent(Device *device, const char *event)
{
Q_ASSERT(device);
Q_ASSERT(event);
emit device->eventNotify(Event(device->prefix(), event, 0, device->key()));
}
Resource *DEV_GetSubDevice(Device *device, const char *prefix, const QString &identifier)
{
if (!device)
{
return nullptr;
}
for (auto &sub : device->subDevices())
{
if (prefix && sub->prefix() != prefix)
{
continue;
}
if (sub->item(RAttrUniqueId)->toString() == identifier || sub->item(RAttrId)->toString() == identifier)
{
return sub;
}
}
return nullptr;
}
void DEV_InitStateHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
d->zdpResult = { };
if ((event.deviceKey() & 0x00212E0000000000LLU) == 0x00212E0000000000LLU)
{
if (!d->node)
{
d->node = DEV_GetCoreNode(device->key());
}
if (d->node && d->node->isCoordinator())
{
d->setState(DEV_DeadStateHandler);
return; // ignore coordinaor for now
}
}
}
else if (event.what() == REventStateLeave)
{
return;
}
if (event.what() == REventPoll ||
event.what() == REventAwake ||
event.what() == RConfigReachable ||
event.what() == RStateReachable ||
event.what() == REventStateTimeout ||
event.what() == RStateLastUpdated ||
d->flags.initialRun == 1)
{
d->flags.initialRun = 0;
d->binding.bindingCheckRound = 0;
// lazy reference to deCONZ::Node
if (!device->node())
{
d->node = DEV_GetCoreNode(device->key());
}
if (device->node())
{
{
const deCONZ::Address a = device->node()->address();
ResourceItem *ext = device->item(RAttrExtAddress);
if (!ext->lastSet().isValid() || ext->toNumber() != a.ext())
{
ext->setValue(a.ext());
}
ResourceItem *nwk = device->item(RAttrNwkAddress);
if (!nwk->lastSet().isValid() || nwk->toNumber() != a.nwk())
{
nwk->setValue(a.nwk());
}
}
// got a node, jump to verification
if (!device->node()->nodeDescriptor().isNull() || device->reachable())
{
d->setState(DEV_NodeDescriptorStateHandler);
}
}
else
{
DBG_Printf(DBG_DEV, "DEV Init no node found: " FMT_MAC "\n", FMT_MAC_CAST(event.deviceKey()));
if ((device->key() & 0xffffffff00000000LLU) == 0)
{
d->setState(DEV_DeadStateHandler);
return; // ignore ZGP for now
}
}
}
}
void DEV_CheckItemChanges(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
std::vector<Resource*> subDevices;
if (event.what() == REventAwake || event.what() == REventPoll)
{
subDevices = device->subDevices();
}
else
{
auto *sub = DEV_GetSubDevice(device, event.resource(), event.id());
if (sub)
{
subDevices.push_back(sub);
}
}
int apsEnqueued = 0;
for (auto *sub : subDevices)
{
if (sub && !sub->stateChanges().empty())
{
auto *item = sub->item(event.what());
for (auto &change : sub->stateChanges())
{
if (item)
{
change.verifyItemChange(item);
}
if (apsEnqueued == 0 && change.tick(d->deviceKey, sub, d->apsCtrl) == 1)
{
apsEnqueued++;
}
}
sub->cleanupStateChanges();
}
}
}
/*! #2 This state checks that a valid NodeDescriptor is available.
*/
void DEV_NodeDescriptorStateHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
if (!device->node()->nodeDescriptor().isNull())
{
DBG_Printf(DBG_DEV, "DEV ZDP node descriptor verified: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
d->maxResponseTime = d->hasRxOnWhenIdle() ? RxOnWhenIdleResponseTime
: RxOffWhenIdleResponseTime;
bool isSleeper = !d->hasRxOnWhenIdle();
ResourceItem *capSleeper = device->item(RCapSleeper);
if (!capSleeper->lastSet().isValid() || capSleeper->toBool() != isSleeper)
{
capSleeper->setValue(isSleeper); // can be overwritten by DDF
}
d->setState(DEV_ActiveEndpointsStateHandler);
}
else if (!device->reachable()) // can't be queried, go back to #1 init
{
d->setState(DEV_InitStateHandler);
}
else
{
d->zdpResult = ZDP_NodeDescriptorReq(d->node->address(), d->apsCtrl);
if (d->zdpResult.isEnqueued)
{
d->startStateTimer(MaxConfirmTimeout, StateLevel0);
}
else
{
d->setState(DEV_InitStateHandler);
}
}
}
else if (event.what() == REventStateLeave)
{
d->stopStateTimer(StateLevel0);
}
else if (event.what() == REventApsConfirm)
{
if (d->zdpResult.apsReqId == EventApsConfirmId(event))
{
if (EventApsConfirmStatus(event) == deCONZ::ApsSuccessStatus)
{
d->stopStateTimer(StateLevel0);
d->startStateTimer(d->maxResponseTime, StateLevel0);
}
else
{
d->setState(DEV_InitStateHandler);
}
}
}
else if (event.what() == REventNodeDescriptor) // received the node descriptor
{
d->setState(DEV_InitStateHandler); // evaluate egain from state #1 init
DEV_EnqueueEvent(device, REventAwake);
}
else if (event.what() == REventStateTimeout)
{
DBG_Printf(DBG_DEV, "DEV read ZDP node descriptor timeout: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
d->setState(DEV_InitStateHandler);
}
}
/*! #3 This state checks that active endpoints are known.
*/
void DEV_ActiveEndpointsStateHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
if (!device->node()->endpoints().empty() && !d->flags.needReadActiveEndpoints)
{
DBG_Printf(DBG_DEV, "DEV ZDP active endpoints verified: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
d->setState(DEV_SimpleDescriptorStateHandler);
}
else if (!device->reachable())
{
d->setState(DEV_InitStateHandler);
}
else
{
d->zdpResult = ZDP_ActiveEndpointsReq(d->node->address(), d->apsCtrl);
if (d->zdpResult.isEnqueued)
{
d->startStateTimer(MaxConfirmTimeout, StateLevel0);
}
else
{
d->setState(DEV_InitStateHandler);
}
}
}
else if (event.what() == REventStateLeave)
{
d->stopStateTimer(StateLevel0);
}
else if (event.what() == REventApsConfirm)
{
if (d->zdpResult.apsReqId == EventApsConfirmId(event))
{
if (EventApsConfirmStatus(event) == deCONZ::ApsSuccessStatus)
{
d->stopStateTimer(StateLevel0);
d->startStateTimer(d->maxResponseTime, StateLevel0);
}
else
{
d->setState(DEV_InitStateHandler);
}
}
}
else if (event.what() == REventActiveEndpoints)
{
d->flags.needReadActiveEndpoints = 0;
d->setState(DEV_InitStateHandler);
DEV_EnqueueEvent(device, REventAwake);
}
else if (event.what() == REventStateTimeout)
{
DBG_Printf(DBG_DEV, "DEV read ZDP active endpoints timeout: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
d->setState(DEV_InitStateHandler);
}
}
/*! #4 This state checks that for all active endpoints simple descriptors are known.
*/
void DEV_SimpleDescriptorStateHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
quint8 needFetchEp = 0x00;
if (d->flags.needReadSimpleDescriptors) // forced read to refresh simple descriptors
{
if (d->zdpNeedFetchEndpointIndex < device->node()->endpoints().size())
{
needFetchEp = device->node()->endpoints()[d->zdpNeedFetchEndpointIndex];
}
}
else
{
for (uint8_t ep : device->node()->endpoints())
{
bool ok = false;
for (size_t i = 0; i < device->node()->simpleDescriptors().size(); i++)
{
const deCONZ::SimpleDescriptor &sd = device->node()->simpleDescriptors()[i];
if (sd.endpoint() == ep && sd.deviceId() != 0xffff)
{
ok = true;
break;
}
}
if (!ok)
{
needFetchEp = ep;
break;
}
}
}
if (needFetchEp == 0x00)
{
DBG_Printf(DBG_DEV, "DEV ZDP simple descriptors verified: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
d->flags.needReadSimpleDescriptors = 0;
d->zdpNeedFetchEndpointIndex = 0xFF;
d->setState(DEV_BasicClusterStateHandler);
}
else if (!device->reachable())
{
d->setState(DEV_InitStateHandler);
}
else
{
d->zdpResult = ZDP_SimpleDescriptorReq(d->node->address(), needFetchEp, d->apsCtrl);
if (d->zdpResult.isEnqueued)
{
d->startStateTimer(MaxConfirmTimeout, StateLevel0);
}
else
{
d->setState(DEV_InitStateHandler);
}
}
}
else if (event.what() == REventStateLeave)
{
d->stopStateTimer(StateLevel0);
}
else if (event.what() == REventApsConfirm)
{
if (d->zdpResult.apsReqId == EventApsConfirmId(event))
{
if (EventApsConfirmStatus(event) == deCONZ::ApsSuccessStatus)
{
d->stopStateTimer(StateLevel0);
d->startStateTimer(d->maxResponseTime, StateLevel0);
}
else
{
d->setState(DEV_InitStateHandler);
}
}
}
else if (event.what() == REventSimpleDescriptor)
{
if (d->flags.needReadSimpleDescriptors) // forced read to refresh simple descriptors (next EP)
{
if (d->zdpNeedFetchEndpointIndex < device->node()->endpoints().size())
{
d->zdpNeedFetchEndpointIndex += 1;
}
}
d->setState(DEV_InitStateHandler);
DEV_EnqueueEvent(device, REventAwake);
}
else if (event.what() == REventStateTimeout)
{
DBG_Printf(DBG_DEV, "DEV read ZDP simple descriptor timeout: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
d->setState(DEV_InitStateHandler);
}
}
/*! Returns the first Simple Descriptor for a given server \p clusterId or nullptr if not found.
*/
static const deCONZ::SimpleDescriptor *DEV_GetSimpleDescriptorForServerCluster(const Device *device, deCONZ::ZclClusterId_t clusterId)
{
for (const auto &sd : device->node()->simpleDescriptors())
{
const auto cluster = std::find_if(sd.inClusters().cbegin(), sd.inClusters().cend(), [clusterId](const deCONZ::ZclCluster &cl)
{
return cl.id_t() == clusterId;
});
if (cluster != sd.inClusters().cend())
{
return &sd;
}
}
return nullptr;
}
/*! Try to fill \c ResourceItem value from \p subDevices if not already set.
*/
bool DEV_FillItemFromSubdevices(Device *device, const char *itemSuffix, const std::vector<Resource*> &subDevices)
{
auto *ditem = device->item(itemSuffix);
Q_ASSERT(ditem);
if (ditem->lastSet().isValid())
{
return true;
}
for (const auto rsub : subDevices)
{
auto *sitem = rsub->item(itemSuffix);
if (sitem && sitem->lastSet().isValid())
{
// copy from sub-device into device
if (ditem->setValue(sitem->toVariant()))
{
return true;
}
}
}
return false;
}
/*! Try to fill \c ResourceItem value from Basic cluster attributes if not already set.
*/
bool DEV_FillItemFromBasicCluster(Device *device, const char *itemSuffix, deCONZ::ZclClusterId_t clusterId, deCONZ::ZclAttributeId_t attrId)
{
ResourceItem *ditem = device->item(itemSuffix);
if (!ditem || !device->node())
{
return false;
}
if (ditem->lastSet().isValid())
{
return true;
}
for (const auto &sd : device->node()->simpleDescriptors())
{
const auto cl = std::find_if(sd.inClusters().cbegin(), sd.inClusters().cend(),
[clusterId](const auto &x) { return x.id_t() == clusterId; });
if (cl == sd.inClusters().cend()) { continue; }
const auto at = std::find_if(cl->attributes().cbegin(), cl->attributes().cend(),
[attrId](const auto &x){ return x.id_t() == attrId; });
if (at == cl->attributes().cend()) { continue; }
const QVariant v = at->toVariant();
if (!v.isNull() && ditem->setValue(v))
{
return true;
}
}
return false;
}
/*! Sends a ZCL Read Attributes request for \p clusterId and \p attrId.
This also configures generic read and parse handlers for an \p item if not already set.
*/
bool DEV_ZclRead(Device *device, ResourceItem *item, deCONZ::ZclClusterId_t clusterId, deCONZ::ZclAttributeId_t attrId)
{
Q_ASSERT(device);
Q_ASSERT(item);
DevicePrivate *d = device->d;
if (!device->reachable())
{
DBG_Printf(DBG_DEV, "DEV not reachable, skip read %s: " FMT_MAC "\n", item->descriptor().suffix, FMT_MAC_CAST(device->key()));
return false;
}
const auto *sd = DEV_GetSimpleDescriptorForServerCluster(device, clusterId);
if (!sd)
{
DBG_Printf(DBG_DEV, "DEV TODO cluster 0x%04X not found: " FMT_MAC "\n", static_cast<quint16>(clusterId), FMT_MAC_CAST(device->key()));
return false;
}
ZCL_Param param{};
param.valid = 1;
param.endpoint = sd->endpoint();
param.clusterId = static_cast<quint16>(clusterId);
param.attributes[0] = static_cast<quint16>(attrId);
param.attributeCount = 1;
const auto zclResult = ZCL_ReadAttributes(param, device->item(RAttrExtAddress)->toNumber(), device->item(RAttrNwkAddress)->toNumber(), d->apsCtrl);
d->readResult.isEnqueued = zclResult.isEnqueued;
d->readResult.apsReqId = zclResult.apsReqId;
d->readResult.sequenceNumber = zclResult.sequenceNumber;
return d->readResult.isEnqueued;
}
/*! #5 This state reads all common basic cluster attributes needed to match a DDF,
e.g. modelId, manufacturer name, application version, etc.
*/
void DEV_BasicClusterStateHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
struct _item {
const char *suffix;
deCONZ::ZclClusterId_t clusterId;
deCONZ::ZclAttributeId_t attrId;
};
const std::array<_item, 2> items = {
_item{ RAttrManufacturerName, 0x0000_clid, 0x0004_atid },
_item{ RAttrModelId, 0x0000_clid, 0x0005_atid }
};
size_t okCount = 0;
const auto &subDevices = device->subDevices();
for (const auto &it : items)
{
if (DEV_FillItemFromSubdevices(device, it.suffix, subDevices))
{
okCount++;
continue;
}
else if (DEV_FillItemFromBasicCluster(device, it.suffix, it.clusterId, it.attrId))
{
okCount++;
continue;
}
if (DEV_ZclRead(device, device->item(it.suffix), it.clusterId, it.attrId))
{
d->startStateTimer(MaxConfirmTimeout, StateLevel0);
return; // keep state and wait for REventStateTimeout or response
}
DBG_Printf(DBG_DEV, "DEV failed to read %s: " FMT_MAC "\n", it.suffix, FMT_MAC_CAST(device->key()));
break;
}
if (okCount != items.size())
{
d->setState(DEV_InitStateHandler);
}
else
{
DBG_Printf(DBG_DEV, "DEV modelId: %s, " FMT_MAC "\n", qPrintable(device->item(RAttrModelId)->toString()), FMT_MAC_CAST(device->key()));
d->setState(DEV_GetDeviceDescriptionHandler);
}
}
else if (event.what() == REventStateLeave)
{
d->stopStateTimer(StateLevel0);
}
else if (event.what() == REventApsConfirm)
{
if (d->readResult.apsReqId == EventApsConfirmId(event))
{
if (EventApsConfirmStatus(event) == deCONZ::ApsSuccessStatus)
{
d->stopStateTimer(StateLevel0);
d->startStateTimer(d->maxResponseTime, StateLevel0);
}
else
{
d->setState(DEV_InitStateHandler);
}
}
}
else if (event.what() == RAttrManufacturerName || event.what() == RAttrModelId)
{
DBG_Printf(DBG_DEV, "DEV received %s: " FMT_MAC "\n", event.what(), FMT_MAC_CAST(device->key()));
d->setState(DEV_InitStateHandler); // ok re-evaluate
DEV_EnqueueEvent(device, REventAwake);
}
else if (event.what() == REventStateTimeout)
{
DBG_Printf(DBG_DEV, "DEV read basic cluster timeout: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
d->setState(DEV_InitStateHandler);
}
}
/*! Forward device attributes to core to show it in the GUI.
*/
void DEV_PublishToCore(Device *device)
{
struct CoreItem
{
const char *suffix;
const char *mapped;
};
std::array<CoreItem, 4> coreItems = {
{
{ RAttrName, "name" },
{ RAttrModelId, "modelid" },
{ RAttrManufacturerName, "vendor" },
{ RAttrSwVersion, "version" }
}
};
const auto subDevices = device->subDevices();
if (!subDevices.empty())
{
for (const CoreItem &i : coreItems)
{
const auto *item = subDevices.front()->item(i.suffix);
if (item && !item->toString().isEmpty())
{
DEV_ForwardNodeChange(device, QLatin1String(i.mapped), item->toString());
}
}
}
}
/*! #6 This state checks if for the device a device description file (DDF) is available.
In that case the device is initialised (or updated) based on the JSON description.
The actual processing is delegated to \c DeviceDescriptions class. This is done async
so thousands of DDF files can be lazy loaded.
*/
void DEV_GetDeviceDescriptionHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
// if there is a IAS Zone Cluster add the RAttrZoneType
if (DEV_GetSimpleDescriptorForServerCluster(device, 0x0500_clid))
{
device->addItem(DataTypeUInt16, RAttrZoneType);
}
DEV_EnqueueEvent(device, REventDDFInitRequest);
}
else if (event.what() == REventDDFInitResponse)
{
DEV_PublishToCore(device);
if (event.num() == 1 || event.num() == 3)
{
d->managed = true;
d->flags.hasDdf = 1;
d->setState(DEV_IdleStateHandler);
// TODO(mpi): temporary forward this info here, gets replaced by device actor later
if (event.num() == 1)
{
DEV_ForwardNodeChange(device, QLatin1String("hasddf"), QLatin1String("1"));
}
else if (event.num() == 3)
{
DEV_ForwardNodeChange(device, QLatin1String("hasddf"), QLatin1String("2"));
}
}
else
{
d->managed = false;
d->flags.hasDdf = 0;
d->setState(DEV_DeadStateHandler);
}
}
}
void DEV_CheckReachable(Device *device)
{
DevicePrivate *d = device->d;
bool devReachable = device->reachable();
for (Resource *r : d->subResources)
{
ResourceItem *item = r->item(RConfigReachable);
if (!item)
{
item = r->item(RStateReachable);
}
if (item && ((item->toBool() != devReachable) || !item->lastSet().isValid()))
{
r->setValue(item->descriptor().suffix, devReachable);
}
}
}
/*! #7 In this state the device is operational and runs sub states
In parallel.
IdleState : Bindings | Polling | ItemChange
*/
void DEV_IdleStateHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
DEV_CheckReachable(device);
d->binding.bindingIter = 0;
d->setState(DEV_BindingHandler, STATE_LEVEL_BINDING);
d->setState(DEV_PollIdleStateHandler, STATE_LEVEL_POLL);
return;
}
else if (event.what() == REventStateLeave)
{
d->setState(nullptr, STATE_LEVEL_BINDING);
d->setState(nullptr, STATE_LEVEL_POLL);
d->stopStateTimer(STATE_LEVEL_BINDING);
d->stopStateTimer(STATE_LEVEL_POLL);
return;
}
else if (event.what() == REventApsConfirm)
{
if (EventApsConfirmStatus(event) == deCONZ::ApsSuccessStatus)
{
d->idleApsConfirmErrors = 0;
}
else
{
d->idleApsConfirmErrors++;
if (d->idleApsConfirmErrors > MaxIdleApsConfirmErrors && device->item(RStateReachable)->toBool())
{
d->idleApsConfirmErrors = 0;
DBG_Printf(DBG_DEV, "DEV Idle max APS confirm errors: " FMT_MAC "\n", FMT_MAC_CAST(device->key()));
device->item(RStateReachable)->setValue(false);
DEV_CheckReachable(device);
}
}
}
else if (event.what() != RAttrLastSeen && event.what() != REventPoll)
{
// DBG_Printf(DBG_DEV, "DEV Idle event %s/0x%016llX/%s\n", event.resource(), event.deviceKey(), event.what());
if (event.what() == RAttrSwVersion || event.what() == RAttrName)
{
DEV_PublishToCore(device);
}
}
if (!device->reachable() && !device->item(RCapSleeper)->toBool())
{
DBG_Printf(DBG_DEV, "DEV (NOT reachable) Idle event %s/" FMT_MAC "/%s\n", event.resource(), FMT_MAC_CAST(event.deviceKey()), event.what());
}
DEV_CheckItemChanges(device, event);
// process parallel states
for (int i = StateLevel1; i < StateLevelMax; i++)
{
device->handleEvent(event, DEV_StateLevel(i));
}
}
/*! Bindings sub state machien is described in:
https://github.com/dresden-elektronik/deconz-rest-plugin-v2/wiki/Device-Class#bindings-sub-state-machine
*/
void DEV_BindingHandler(Device *device, const Event &event)
{
DevicePrivate *d = device->d;
if (event.what() == REventStateEnter)
{
DBG_Printf(DBG_DEV, "DEV Binding enter %s/" FMT_MAC "\n", event.resource(), FMT_MAC_CAST(event.deviceKey()));
}
else if (event.what() == REventPoll || event.what() == REventAwake || event.what() == REventBindingTick)
{
if (DA_ApsUnconfirmedRequests() > 4)
{
// wait
}
else
{
d->binding.bindingIter = 0;
if (d->binding.mgmtBindSupported == MGMT_BIND_NOT_SUPPORTED)
{
d->setState(DEV_BindingTableVerifyHandler, STATE_LEVEL_BINDING);
}
else
{
d->setState(DEV_BindingTableReadHandler, STATE_LEVEL_BINDING);
}
}
}
else if (event.what() == REventBindingTable)
{
if (event.num() == deCONZ::ZdpSuccess)
{
d->binding.mgmtBindSupported = MGMT_BIND_SUPPORTED;