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Martin Christoph Hierholzer authoredMartin Christoph Hierholzer authored
ArrayAccessor.h 6.14 KiB
/*
* ArrayAccessor.h
*
* Created on: Jun 07, 2016
* Author: Martin Hierholzer
*/
#ifndef CHIMERATK_ARRAY_ACCESSOR_H
#define CHIMERATK_ARRAY_ACCESSOR_H
#include <string>
#include <boost/smart_ptr/shared_ptr.hpp>
#include <boost/thread.hpp>
#include "Accessor.h"
namespace ChimeraTK {
/** Accessor for array variables (i.e. vectors). Note for users: Preferrably use the convenience classes
* ArrayPollInput, ArrayPushInput, ArrayOutput instead of this class directly. */
template< typename UserType >
class ArrayAccessor : public Accessor<UserType> {
public:
ArrayAccessor(Module *owner, const std::string &name, VariableDirection direction, std::string unit,
size_t nElements, UpdateMode mode, const std::string &description)
: Accessor<UserType>(owner, name, direction, unit, nElements, mode, description)
{}
/** Default constructor creates a dysfunction accessor (to be assigned with a real accessor later) */
ArrayAccessor() {}
void read() {
if(Accessor<UserType>::_mode == UpdateMode::push) {
impl->read();
boost::this_thread::interruption_point();
}
else {
/// @todo TODO empty the queue to always receive the latest value
impl->readNonBlocking();
boost::this_thread::interruption_point();
}
} // LCOV_EXCL_LINE this line somehow ends up having a negative counter in the coverage report, which leads to a failure
void write() {
impl->write();
boost::this_thread::interruption_point();
}
bool readNonBlocking() {
boost::this_thread::interruption_point();
return impl->readNonBlocking();
}
/** Get or set buffer content by [] operator.
* @attention No bounds checking is performed, use getNumberOfElements() to obtain the number of elements in
* the register.
* Note: Using the iterators is slightly more efficient than using this operator! */
UserType& operator[](unsigned int element) {
return impl->accessData(0,element);
}
/** Return number of elements/samples in the register */
unsigned int getNElements() {
return impl->getNumberOfSamples();
}
/** Access data with std::vector-like iterators */
typedef typename std::vector<UserType>::iterator iterator;
typedef typename std::vector<UserType>::const_iterator const_iterator; typedef typename std::vector<UserType>::reverse_iterator reverse_iterator;
typedef typename std::vector<UserType>::const_reverse_iterator const_reverse_iterator;
iterator begin() { return impl->accessChannel(0).begin(); }
const_iterator begin() const { return impl->accessChannel(0).cbegin(); }
const_iterator cbegin() const { return impl->accessChannel(0).cbegin(); }
iterator end() { return impl->accessChannel(0).end(); }
const_iterator end() const { return impl->accessChannel(0).cend(); }
const_iterator cend() const { return impl->accessChannel(0).cend(); }
reverse_iterator rbegin() { return impl->accessChannel(0).rbegin(); }
const_reverse_iterator rbegin() const { return impl->accessChannel(0).crbegin(); }
const_reverse_iterator crbegin() const { return impl->accessChannel(0).crbegin(); }
reverse_iterator rend() { return impl->accessChannel(0).rend(); }
const_reverse_iterator rend() const { return impl->accessChannel(0).crend(); }
const_reverse_iterator crend() const { return impl->accessChannel(0).crend(); }
/* Swap content of (cooked) buffer with std::vector */
void swap(std::vector<UserType> &x) {
if(x.size() != impl->accessChannel(0).size()) {
throw DeviceException("Swapping with a buffer of a different size is not allowed.",
DeviceException::WRONG_PARAMETER);
}
impl->accessChannel(0).swap(x);
}
/** Assignment operator */
ArrayAccessor<UserType>& operator=(const std::vector<UserType> &rightHandSide) {
impl->accessChannel(0) = rightHandSide;
return *this;
}
bool isInitialised() const {
return impl != nullptr;
}
void useProcessVariable(const boost::shared_ptr<TransferElement > &var) {
impl = boost::dynamic_pointer_cast<NDRegisterAccessor<UserType>>(var);
assert(impl);
if(Accessor<UserType>::getDirection() == VariableDirection::consuming) {
assert(impl->isReadable());
}
else {
assert(impl->isWriteable());
}
}
using Accessor<UserType>::impl;
};
/** Convenience class for input array accessors with UpdateMode::push */
template< typename UserType >
struct ArrayPushInput : public ArrayAccessor<UserType> {
ArrayPushInput(Module *owner, const std::string &name, std::string unit, size_t nElements, const std::string &description)
: ArrayAccessor<UserType>(owner, name, VariableDirection::consuming, unit, nElements, UpdateMode::push, description)
{}
ArrayPushInput() : ArrayAccessor<UserType>() {}
using ArrayAccessor<UserType>::operator=;
};
/** Convenience class for input array accessors with UpdateMode::poll */
template< typename UserType >
struct ArrayPollInput : public ArrayAccessor<UserType> {
ArrayPollInput(Module *owner, const std::string &name, std::string unit, size_t nElements, const std::string &description)
: ArrayAccessor<UserType>(owner, name, VariableDirection::consuming, unit, nElements, UpdateMode::poll, description)
{}
ArrayPollInput() : ArrayAccessor<UserType>() {}
using ArrayAccessor<UserType>::operator=;
};
/** Convenience class for output array accessors (always UpdateMode::push) */ template< typename UserType >
struct ArrayOutput : public ArrayAccessor<UserType> {
ArrayOutput(Module *owner, const std::string &name, std::string unit, size_t nElements, const std::string &description)
: ArrayAccessor<UserType>(owner, name, VariableDirection::feeding, unit, nElements, UpdateMode::push, description)
{}
ArrayOutput() : ArrayAccessor<UserType>() {}
using ArrayAccessor<UserType>::operator=;
};
} /* namespace ChimeraTK */
#endif /* CHIMERATK_ARRAY_ACCESSOR_H */