DEV: a queue with event based callables added

пре 3 година · 28bf870959
--- a/include/cont/edeque.h
+++ b/include/cont/edeque.h
@@ -56,7 +56,7 @@ namespace tbx {
 *    \c Fn
 *
 * \tparam Data_t   The char-like queued item type. Usually \c char
 * \tparam N        The size of deque
 * \tparam N        The size of edeque
 * \tparam Fn       The type of Callable
 */
 template <typename Data_t, size_t N, typename Fn = std::function<void()>>
--- a/include/cont/equeue.h
+++ b/include/cont/equeue.h
@@ -0,0 +1,144 @@
 /*!
 * \file cont/equeue.h
 * \brief
 *      A queue with event based callables based on edeque.
 *
 * \copyright Copyright (C) 2021 Christos Choutouridis <christos@choutouridis.net>
 *
 * <dl class=\"section copyright\"><dt>License</dt><dd>
 * The MIT License (MIT)
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in all
 * copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 * SOFTWARE.
 * </dd></dl>
 */

 #ifndef TBX_CONT_EQUQUE_H_
 #define TBX_CONT_EQUQUE_H_

 #include <core/core.h>
 #include <cont/edeque.h>

 namespace tbx {

 /*!
 * \class equeue
 * \brief
 *      A statically allocated queue based on edeque with size and data matching
 *      event based callables.
 *
 * We use the \ref edeque::push_back() and \ref edeque::pop_front() pair from edeque's
 * functionality, so at the \c push the increment performed after the insertion.
 * Similarly at the \c pop the decrement performed before the exctraction. This way also
 * the \ref edeque::front() and \ref edeque::back() stay the same ;)
 *
 * We also provide stream operators.
 *
 * \tparam Data_t   The char-like queued item type. Usually \c char
 * \tparam N        The size of edeque
 * \tparam Fn       The type of Callable
 */
 template <typename Data_t, size_t N, typename Fn = std::function<void()>>
 class equeue : public edeque<Data_t, N, Fn> {
    public:
        // meta-identity types
        using equeue_t              = equeue<Data_t, N>;
        using base_type             = edeque<Data_t, N, Fn>;

        // STL
        using value_type            = typename base_type::value_type;
        using reference             = typename base_type::reference;
        using const_reference       = typename base_type::const_reference;
        using pointer               = typename base_type::pointer;
        using const_pointer         = typename base_type::const_pointer;
        using iterator              = typename base_type::iterator;
        using const_iterator        = typename base_type::const_iterator;
        using reverse_iterator      = typename base_type::reverse_iterator;
        using const_reverse_iterator= typename base_type::const_reverse_iterator;

    //! \name Constructor / Destructor
    //! @{
    public:
        //! Default constructor
        constexpr equeue () noexcept : base_type() { }

        //! fill contructor
        constexpr equeue(const Data_t& value) noexcept : base_type(value) { }

        //! Initializer list contructor
        template <typename ...It>
        constexpr equeue(It&& ...it) noexcept : base_type(std::forward<It>(it)...) { }

    //! @}

    //! \name Member access
    //! @{
    public:
        //! \brief      Push an item in the back of the queue
        //! \param it   The item to push
        void push (const Data_t& it) {
            base_type::push_back(it);
        }

        //! \brief      Extract an item from the front of the queue and remove it from the queue
        //! \param it   The item to push
        Data_t pop () {
            return base_type::pop_front();
        }

        //! \brief      Push an item in the back of the queue
        //! \param it   The item to push
        equeue_t& operator<< (const Data_t& it) {
            push(it);
            return *this;
        }

        //! \brief      Push an item in the back of the queue
        //! \param it   The item to push
        equeue_t& operator>> (Data_t& it) {
            it = pop();
            return *this;
        }

    //! @}

 };

 /*!
 * \brief
 *      Pop an item from the front of the queue.
 *
 *  This definition enables the "data << equeue" syntax for pop operation
 *
 *  \tparam Data_t  The char-like queued item type. Usually \c char
 *  \tparam N       The size of queue
 *  \tparam Fn      The type of Callable
 *
 *  \param it       The item to write to
 *  \param q        The queue to read from
 *  \return         Reference to the returned item
 */
 template <typename Data_t, size_t N, typename Fn = std::function<void()>>
 Data_t& operator<< (Data_t& it, equeue<Data_t, N, Fn>& q) {
    it = q.pop();
    return it;
 }

 }

 #endif /* TBX_CONT_EQUQUE_H_ */
--- a/include/cont/queue.h
+++ b/include/cont/queue.h
@@ -37,7 +37,7 @@
 namespace tbx {

 /*!
 * \class deque
 * \class queue
 * \brief
 *      A statically allocated queue based on deque.
 *
@@ -49,7 +49,7 @@ namespace tbx {
 * We also provide stream operators.
 *
 * \tparam Data_t   The char-like queued item type. Usually \c char
 * \tparam N        The size of deque
 * \tparam N        The size of queue
 */
 template <typename Data_t, size_t N>
 class queue : public deque<Data_t, N> {
@@ -89,34 +89,51 @@ class queue : public deque<Data_t, N> {
    public:
        //! \brief      Push an item in the back of the queue
        //! \param it   The item to push
        void push (const Data_t& it) {
        constexpr void push (const Data_t& it) {
            base_type::push_back(it);
        }

        //! \brief      Extract an item from the front of the queue and remove it from the queue
        //! \param it   The item to push
        Data_t pop () {
        constexpr Data_t pop () {
            return base_type::pop_front();
        }

        //! \brief      Push an item in the back of the queue
        //! \param it   The item to push
        queue_t& operator<< (const Data_t& it) {
        constexpr queue_t& operator<< (const Data_t& it) {
            push(it);
            return *this;
        }

        //! \brief      Push an item in the back of the queue
        //! \param it   The item to push
        queue_t& operator>> (Data_t& it) {
        //! \brief      Pop an item from the front of the queue
        //! \param it   The item to write to
        constexpr queue_t& operator>> (Data_t& it) {
            it = pop();
            return *this;
        }

    //! @}

 };

 /*!
 * \brief
 *      Pop an item from the front of the queue.
 *
 *  This definition enables the "data << queue" syntax for pop operation
 *
 *  \tparam Data_t  The char-like queued item type. Usually \c char
 *  \tparam N       The size of queue
 *
 *  \param it       The item to write to
 *  \param q        The queue to read from
 *  \return         Reference to the returned item
 */
 template <typename Data_t, size_t N>
 constexpr Data_t& operator<< (Data_t& it, queue<Data_t, N>& q) {
    it = q.pop();
    return it;
 }

 } // namespace tbx

 #endif /* TBX_CONT_QUQUE_H_ */
--- a/test/tests/edeque.cpp
+++ b/test/tests/edeque.cpp
@@ -60,10 +60,16 @@ namespace Tdeque {
        Edeque e3(Edeque::size_match::EQ, 7, vfun);
        edeque<T, 8> e4(edeque<T, 8>::size_match::EQ, 2, vfoo{});

        edeque<int, 8> q1;
        edeque<int, 8> q2(edeque<int, 8>::size_match::DISABLED, 0, nullptr);

        EXPECT_EQ (8UL, e1.capacity());
        EXPECT_EQ (8UL, e2.capacity());
        EXPECT_EQ (8UL, e3.capacity());
        EXPECT_EQ (8UL, e4.capacity());

        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (8UL, q2.capacity());
    }

    TEST (Tedeque, base_class) {
--- a/test/tests/equeue.cpp
+++ b/test/tests/equeue.cpp
@@ -0,0 +1,181 @@
 /*!
 * \file equeue.cpp
 * \brief
 *      Unit tests for equeue
 *
 * \copyright Copyright (C) 2020 Christos Choutouridis <christos@choutouridis.net>
 *
 * <dl class=\"section copyright\"><dt>License</dt><dd>
 * The MIT License (MIT)
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in all
 * copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 * SOFTWARE.
 * </dd></dl>
 *
 */
 #include <cont/equeue.h>
 #include <gtest/gtest.h>

 namespace Tequeue {
    using namespace tbx;

    int global_flag =0;

    // Callable mocks
    void vfun(void) { ++global_flag; }

    struct vfoo {
       void operator() (void) { ++global_flag; }
    };

    // Test construction
    TEST(Tequeue, contruct) {
        using Equeue = equeue<int, 8>;
        struct T { int a,b; };
        int local{};

        Equeue e1(Equeue::size_match::GE, 3, [](){
            ++global_flag;
        });
        Equeue e2(Equeue::size_match::GE, 3, [&](){
            ++local;
        });
        Equeue e3(Equeue::size_match::EQ, 7, vfun);
        equeue<T, 8> e4(equeue<T, 8>::size_match::EQ, 2, vfoo{});

        equeue<int, 8> q1;
        equeue<int, 8> q2(equeue<int, 8>::size_match::DISABLED, 0, nullptr);

        EXPECT_EQ (8UL, e1.capacity());
        EXPECT_EQ (8UL, e2.capacity());
        EXPECT_EQ (8UL, e3.capacity());
        EXPECT_EQ (8UL, e4.capacity());

        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (8UL, q2.capacity());
    }

    // simple push-pop functionality
    TEST(Tequeue, base_class) {
        using Equeue = equeue<int, 8>;

        Equeue e1(Equeue::size_match::GE, 3, [](){
            ++global_flag;
        });

        // Access of base class functionality
        EXPECT_EQ (8UL, e1.capacity());
        EXPECT_EQ (0UL, e1.size());
        EXPECT_EQ (true, e1.empty());
        EXPECT_EQ (false, e1.full());

        e1.push(42);
        EXPECT_EQ (42, e1.front());
        EXPECT_EQ (42, e1.back());
        EXPECT_EQ (42, e1.pop());

        e1.push(1);
        e1.push(2);
        e1.push(3);

        int check_it=1;
        for (auto it = e1.begin() ; it != e1.end() ; ++it)
            EXPECT_EQ(*it, check_it++);
        EXPECT_EQ(4, check_it);         // run through all

    }

    // trigger functionality
    TEST (Tequeue, set_clear_check_trigger) {
        using Equeue = equeue<int, 8>;
        bool flag{};

        Equeue e1(Equeue::size_match::GE, 1, [&](){ flag = true; });

        flag = false;
        e1.clear_trigger();
        EXPECT_EQ (false, flag);
        e1.push_back(1);            // 1,  no-trigger cleared
        EXPECT_EQ (false, flag);

        flag = false;
        e1.clear();
        e1.clear_trigger();
        EXPECT_EQ (false, flag);    // no spurious triggers
        e1.push_back(1);            // 1
        e1.push_back(2);            // 2
        e1.set_trigger(Equeue::size_match::GE, 1, [&](){ flag = true; });
        EXPECT_EQ (false, flag);    // no spurious triggers
        e1.check_trigger();         // manual trigger
        EXPECT_EQ (true, flag);

        flag = false;
        e1.check_trigger();         // manual trigger attempt
        EXPECT_EQ (false, flag);    // [SIZE triggers are auto clear]

        Equeue e2(Equeue::data_match::MATCH, 42, [&](){ flag = true; });
        flag = false;
        e2.clear_trigger();
        EXPECT_EQ (false, flag);
        e2.push_back(42);           // push 42, no-trigger cleared
        EXPECT_EQ (false, flag);
        e2.set_trigger(Equeue::data_match::MATCH, 42, [&](){ flag = true; });
        EXPECT_EQ (false, flag);    // no spurious triggers
        e2.pop_back();              // pop 42, trigger
        EXPECT_EQ (true, flag);

        flag = false;
        e2.push_back(42);           // push 42, re-trigger [DATA re-triggers]
        EXPECT_EQ (true, flag);
    }

    // stream push-pop
    TEST(Tequeue, stream_push_pop) {
        equeue<int, 8> q1;

        q1 << 1 << 2 << 3 << 4 << 5 << 6 << 7 << 8;
        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (8UL, q1.size());
        EXPECT_EQ (false, q1.empty());
        EXPECT_EQ (true, q1.full());

        q1 << 9;                        // try to insert in full queue
        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (8UL, q1.size());
        EXPECT_EQ (false, q1.empty());
        EXPECT_EQ (true, q1.full());

        int check_it=1;
        for (auto it = q1.begin() ; it != q1.end() ; ++it)
            EXPECT_EQ(*it, check_it++);
        EXPECT_EQ(9, check_it);         // run through all

        for (int i =1 ; i <= 8 ; ++i) {
            check_it << q1;
            EXPECT_EQ(i, check_it);
        }
        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (0UL, q1.size());
        EXPECT_EQ (true, q1.empty());
        EXPECT_EQ (false, q1.full());

        q1 >> check_it;
        EXPECT_EQ (int{}, check_it);
    }

 }
--- a/test/tests/queue.cpp
+++ b/test/tests/queue.cpp
@@ -39,12 +39,17 @@ namespace Tqueue {
    TEST(Tqueue, contruct) {
        queue<int, 8> q1;
        queue<int, 8> q2{1, 2, 3, 4, 5, 6, 7, 8};
        queue<int, 8> q3{1, 2, 3, 4, 5};

        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (0UL, q1.size());
        EXPECT_EQ (8UL, q2.capacity());
        EXPECT_EQ (8UL, q2.size());
        EXPECT_EQ (8UL, q3.capacity());
        EXPECT_EQ (5UL, q3.size());
    }

    // simple push-pop functionality
    // base class functionality check
    TEST(Tqueue, base_class) {

        queue<int, 8> q1;
@@ -55,34 +60,10 @@ namespace Tqueue {
        EXPECT_EQ (true, q1.empty());
        EXPECT_EQ (false, q1.full());

        q1.push_back(7);
        EXPECT_EQ (7, q1.front());
        EXPECT_EQ (7, q1.back());
        EXPECT_EQ (7, q1.pop_front());

        q1.push_front(42);
        q1.push(42);
        EXPECT_EQ (42, q1.front());
        EXPECT_EQ (42, q1.back());
        EXPECT_EQ (42, q1.pop_back());

        q1.push_back(1);
        q1.push_back(2);
        q1.push_back(3);

        int check_it=1;
        for (auto it = q1.begin() ; it != q1.end() ; ++it)
            EXPECT_EQ(*it, check_it++);
        EXPECT_EQ(4, check_it);         // run through all
    }

    // push-pop
    TEST(Tqueue, front_back) {
        queue<int, 8> q1;

        q1.push(7);
        EXPECT_EQ (7, q1.front());
        EXPECT_EQ (7, q1.back());
        EXPECT_EQ (7, q1.pop());
        EXPECT_EQ (42, q1.pop());

        q1.push(1);
        q1.push(2);
@@ -92,28 +73,40 @@ namespace Tqueue {
        for (auto it = q1.begin() ; it != q1.end() ; ++it)
            EXPECT_EQ(*it, check_it++);
        EXPECT_EQ(4, check_it);         // run through all

    }

    // stream operations
    TEST(Tqueue, capacity) {
    // stream push-pop
    TEST(Tqueue, stream_push_pop) {
        queue<int, 8> q1;

        // stream 5 items
        q1 << 1 << 2 << 3 << 4 << 5;
        q1 << 1 << 2 << 3 << 4 << 5 << 6 << 7 << 8;
        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (8UL, q1.size());
        EXPECT_EQ (false, q1.empty());
        EXPECT_EQ (true, q1.full());

        q1 << 9;                        // try to insert in full queue
        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (8UL, q1.size());
        EXPECT_EQ (false, q1.empty());
        EXPECT_EQ (true, q1.full());

        int check_it=1;
        for (auto it = q1.begin() ; it != q1.end() ; ++it)
            EXPECT_EQ(*it, check_it++);
        EXPECT_EQ (6, check_it);         // run through all
        EXPECT_EQ(9, check_it);         // run through all

        // get all back
        int it;
        for (int check_it=1 ; check_it<=5 ; ++check_it) {
            q1 >> it;
            EXPECT_EQ (check_it, it);
        for (int i =1 ; i <= 8 ; ++i) {
            check_it << q1;
            EXPECT_EQ(i, check_it);
        }
        EXPECT_EQ (8UL, q1.capacity());
        EXPECT_EQ (0UL, q1.size());
        EXPECT_EQ (true, q1.empty());
        EXPECT_EQ (false, q1.full());

        q1 >> check_it;
        EXPECT_EQ (int{}, check_it);
    }

 }