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/*
* Copyright (C) 2015, 2016 "IoT.bzh"
* Author "Romain Forlot" <romain.forlot@iot.bzh>
*
* 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 <float.h>
#include <string.h>
#include "signal.hpp"
#include "signal-composer.hpp"
#define USEC_TIMESTAMP_FLAG 1506514324881224
Signal::Signal()
:id_(""),
event_(""),
dependsSigV_(),
timestamp_(0.0),
value_(),
retention_(0),
frequency_(0),
unit_(""),
onReceived_(nullptr),
getSignalsArgs_(nullptr),
signalCtx_(new struct signalCBT),
subscribed_(false)
{}
Signal::Signal(const std::string& id, const std::string& event, std::vector<std::string>& depends, const std::string& unit, int retention, double frequency, CtlActionT* onReceived, json_object* getSignalsArgs)
:id_(id),
event_(event),
dependsSigV_(depends),
timestamp_(0.0),
value_(),
retention_(retention),
frequency_(frequency),
unit_(unit),
onReceived_(onReceived),
getSignalsArgs_(getSignalsArgs),
signalCtx_(new struct signalCBT),
subscribed_(false)
{}
Signal::Signal(const std::string& id,
std::vector<std::string>& depends,
const std::string& unit,
int retention,
double frequency,
CtlActionT* onReceived)
:id_(id),
event_(),
dependsSigV_(depends),
timestamp_(0.0),
value_(),
retention_(retention),
frequency_(frequency),
unit_(unit),
onReceived_(onReceived),
getSignalsArgs_(),
signalCtx_(new struct signalCBT),
subscribed_(false)
{}
Signal::~Signal()
{
delete(signalCtx_);
delete(onReceived_);
}
Signal::operator bool() const
{
if(id_.empty())
{return false;}
return true;
}
bool Signal::operator ==(const Signal& other) const
{
if(id_ == other.id_) {return true;}
return false;
}
bool Signal::operator ==(const std::string& aName) const
{
if(id_.find(aName) != std::string::npos) {return true;}
if(event_.find(aName) != std::string::npos) {return true;}
return false;
}
const std::string Signal::id() const
{
return id_;
}
/// @brief Build a JSON object with data members of Signal object
///
/// @return the built JSON object representing the Signal
json_object* Signal::toJSON() const
{
json_object* queryJ = nullptr;
std::vector<std::string> dependsSignalName;
for (const std::string& src: dependsSigV_ )
{
ssize_t sep = src.find_first_of("/");
if(sep != std::string::npos)
{
dependsSignalName.push_back(src.substr(sep+1));
}
}
json_object *nameArrayJ = json_object_new_array();
for (const std::string& lowSig: dependsSignalName)
{
json_object_array_add(nameArrayJ, json_object_new_string(lowSig.c_str()));
}
wrap_json_pack(&queryJ, "{ss,so*}",
"uid", id_.c_str(),
"getSignalsArgs", getSignalsArgs_);
if (!event_.empty())
{json_object_object_add(queryJ, "event", json_object_new_string(event_.c_str()));}
if (json_object_array_length(nameArrayJ))
{json_object_object_add(queryJ, "depends", nameArrayJ);}
else
{json_object_put(nameArrayJ);}
if (!unit_.empty()) {json_object_object_add(queryJ, "unit", json_object_new_string(unit_.c_str()));}
if (frequency_) {json_object_object_add(queryJ, "frequency", json_object_new_double(frequency_));}
if(timestamp_) {json_object_object_add(queryJ, "timestamp", json_object_new_int64(timestamp_));}
if (value_.hasBool) {json_object_object_add(queryJ, "value", json_object_new_boolean(value_.boolVal));}
else if (value_.hasNum) {json_object_object_add(queryJ, "value", json_object_new_double(value_.numVal));}
else if (value_.hasStr) {json_object_object_add(queryJ, "value", json_object_new_string(value_.strVal.c_str()));}
return queryJ;
}
/// @brief Initialize signal context if not already done and return it.
/// Signal context is a handle to be use by plugins then they can call
/// some signal object method setting signal values.
/// Also if plugin set a context it retrieve it and initiaze the pluginCtx
/// member then plugin can find a persistent memory area where to hold its
/// value.
///
/// @return a pointer to the signalCtx_ member initialized.
struct signalCBT* Signal::get_context()
{
if(!signalCtx_->aSignal ||
!signalCtx_->searchNsetSignalValue ||
!signalCtx_->setSignalValue)
{
signalCtx_->searchNsetSignalValue = searchNsetSignalValueHandle;
signalCtx_->setSignalValue = setSignalValueHandle;
signalCtx_->aSignal = (void*)this;
signalCtx_->pluginCtx = onReceived_ && onReceived_->type == CTL_TYPE_CB ?
onReceived_->exec.cb.plugin->context:
nullptr;
}
return signalCtx_;
}
/// @brief Set Signal timestamp and value property when an incoming
/// signal arrived. Called by a plugin because treatment can't be
/// standard as signals sources format could changes. See low-can plugin
/// example.
///
/// @param[in] timestamp - timestamp of occured signal
/// @param[in] value - value of change
void Signal::set(uint64_t timestamp, struct signalValue& value)
{
uint64_t diff = retention_+1;
value_ = value;
timestamp_ = timestamp;
history_[timestamp_] = value_;
while(diff > retention_)
{
uint64_t first = history_.begin()->first;
diff = (timestamp_ - first)/MICRO;
if(diff > retention_)
{history_.erase(history_.cbegin());}
}
}
/// @brief Observer method called when a Observable Signal has changes.
///
/// @param[in] Observable - object from which update come from
void Signal::update(Signal* sig)
{
AFB_NOTICE("Got an update from observed signal %s", sig->id().c_str());
}
/// @brief
///
/// @param[in] eventJ - json_object containing event data to process
///
/// @return 0 if ok, -1 or others if not
void Signal::defaultReceivedCB(json_object *eventJ)
{
uint64_t ts = 0;
struct signalValue sv;
json_object_iterator iter = json_object_iter_begin(eventJ);
json_object_iterator iterEnd = json_object_iter_end(eventJ);
while(!json_object_iter_equal(&iter, &iterEnd))
{
std::string name = json_object_iter_peek_name(&iter);
std::transform(name.begin(), name.end(), name.begin(), ::tolower);
json_object *value = json_object_iter_peek_value(&iter);
if (name.find("value") || name.find(id_))
{
if(json_object_is_type(value, json_type_double))
{sv = json_object_get_double(value);}
else if(json_object_is_type(value, json_type_boolean))
{sv = json_object_get_int(value);}
else if(json_object_is_type(value, json_type_string))
{sv = json_object_get_string(value);}
}
else if (name.find("timestamp"))
{
ts = json_object_is_type(value, json_type_int) ? json_object_get_int64(value):ts;
}
json_object_iter_next(&iter);
}
if(!sv.hasBool && !sv.hasNum && !sv.hasStr)
{
AFB_ERROR("No data found to set signal %s in %s", id_.c_str(), json_object_to_json_string(eventJ));
return;
}
else if(ts == 0)
{
struct timespec t_usec;
if(!::clock_gettime(CLOCK_MONOTONIC, &t_usec))
ts = (t_usec.tv_nsec / 1000ll) + (t_usec.tv_sec* 1000000ll);
}
set(ts, sv);
}
/// @brief Notify observers that there is a change and execute callback defined
/// when signal is received
///
/// @param[in] eventJ - JSON query object to transmit to callback function
///
void Signal::onReceivedCB(json_object *eventJ)
{
if(onReceived_ && onReceived_->type == CTL_TYPE_LUA)
{
json_object_iterator iter = json_object_iter_begin(eventJ);
json_object_iterator iterEnd = json_object_iter_end(eventJ);
while(!json_object_iter_equal(&iter, &iterEnd))
{
const char *name = ::strdup(json_object_iter_peek_name(&iter));
json_object *value = json_object_iter_peek_value(&iter);
if(json_object_is_type(value, json_type_int))
{
int64_t newVal = json_object_get_int64(value);
newVal = newVal > USEC_TIMESTAMP_FLAG ? newVal/MICRO:newVal;
json_object_object_del(eventJ, name);
json_object* luaVal = json_object_new_int64(newVal);
json_object_object_add(eventJ, name, luaVal);
}
json_object_iter_next(&iter);
}
}
CtlSourceT source;
source.uid = id_.c_str();
source.api = nullptr; // We use binding v2, no dynamic API.
source.request = {nullptr, nullptr};
source.context = (void*)get_context();
onReceived_ ? ActionExecOne(&source, onReceived_, eventJ) : defaultReceivedCB(eventJ);
notify();
}
/// @brief Make a Signal observer observes Signals observables
/// set in its observable vector.
///
/// @param[in] composer - bindinApp instance
void Signal::attachToSourceSignals(Composer& composer)
{
for (const std::string& srcSig: dependsSigV_)
{
if(srcSig.find("/") == std::string::npos)
{
std::vector<std::shared_ptr<Signal>> observables = composer.searchSignals(srcSig);
if(observables[0])
{
AFB_NOTICE("Attaching %s to %s", id_.c_str(), srcSig.c_str());
observables[0]->addObserver(this);
continue;
}
AFB_WARNING("Can't attach. Is %s exists ?", srcSig.c_str());
}
}
}
/// @brief Make an average over the last X 'seconds'
///
/// @param[in] seconds - period to calculate the average
///
/// @return Average value
double Signal::average(int seconds) const
{
uint64_t begin = history_.begin()->first;
uint64_t end = seconds ?
begin+(seconds*MICRO) :
history_.rbegin()->first;
double total = 0.0;
int nbElt = 0;
for (const auto& val: history_)
{
if(val.first >= end)
{break;}
if(val.second.hasNum)
{
total += val.second.numVal;
nbElt++;
}
else
{
AFB_ERROR("There isn't numerical value to compare with in that signal '%s'. Stored value : bool %d, num %lf, str: %s",
id_.c_str(),
val.second.boolVal,
val.second.numVal,
val.second.strVal.c_str());
break;
}
}
return total / nbElt;
}
/// @brief Find minimum in the recorded values
///
/// @param[in] seconds - period to find the minimum
///
/// @return Minimum value contained in the history
double Signal::minimum(int seconds) const
{
uint64_t begin = history_.begin()->first;
uint64_t end = seconds ?
begin+(seconds*MICRO) :
history_.rbegin()->first;
double min = DBL_MAX;
for (auto& v : history_)
{
if(v.first >= end)
{break;}
else if(v.second.hasNum && v.second.numVal < min)
{min = v.second.numVal;}
else
{
AFB_ERROR("There isn't numerical value to compare with in that signal '%s'. Stored value : bool %d, num %lf, str: %s",
id_.c_str(),
v.second.boolVal,
v.second.numVal,
v.second.strVal.c_str());
break;
}
}
return min;
}
/// @brief Find maximum in the recorded values
///
/// @param[in] seconds - period to find the maximum
///
/// @return Maximum value contained in the history
double Signal::maximum(int seconds) const
{
uint64_t begin = history_.begin()->first;
uint64_t end = seconds ?
begin+(seconds*MICRO) :
history_.rbegin()->first;
double max = 0.0;
for (auto& v : history_)
{
if(v.first >= end)
{break;}
else if(v.second.hasNum && v.second.hasNum > max)
{max = v.second.numVal;}
else
{
AFB_ERROR("There isn't numerical value to compare with in that signal '%s'. Stored value : bool %d, num %lf, str: %s",
id_.c_str(),
v.second.boolVal,
v.second.numVal,
v.second.strVal.c_str());
break;
}
}
return max;
}
/// @brief Return last value recorded
///
/// @return Last value
struct signalValue Signal::last() const
{
if(history_.empty()) {return signalValue();}
return history_.rbegin()->second;
}
/// @brief Recursion check to ensure that there is no infinite loop
/// in the Observers/Observables structure.
/// This will check that observer signal is not the same than itself
/// then trigger the check against the following eventuals observers
///
/// @return 0 if no infinite loop detected, -1 if not.
int Signal::initialRecursionCheck()
{
for (auto& obs: observerList_)
{
if(obs == this)
{return -1;}
if(static_cast<Signal*>(obs)->recursionCheck(static_cast<Signal*>(obs)))
{return -1;}
}
return 0;
}
/// @brief Inner recursion check. Argument is the Signal id coming
/// from the original Signal that made a recursion check.
///
/// @param[in] origId - name of the origine of the recursion check
///
/// @return 0 if no infinite loop detected, -1 if not.
int Signal::recursionCheck(Signal* parentSig)
{
for (const auto& obs: observerList_)
{
Signal* obsSig = static_cast<Signal*>(obs);
if(parentSig->id() == static_cast<Signal*>(obsSig)->id())
{return -1;}
if(! obsSig->recursionCheck(obsSig))
{return -1;}
}
return 0;
}
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