libpEpDatatypes/test/test_nr1.cc

#include <iostream>
#include <cctype>
#include <pEp/pEpEngine.h>
#include <pEp/message_api.h>
#include <pEp/keymanagement.h>
#include <pEp/identity_list.h>
#include <pEp/utils.hh>
#include <pEp/pEpLog.hh>
#include <pEp/inspect.hh>
#include <type_traits>
#include "../examples/libc99/libc99.h"

namespace pEp {

    char* alloc_str(const std::string& str)
    {
        char* ret = strdup(str.c_str());
        pEpLog(CXX::Inspect::all(ret));
        return ret;
    }

    template<class T>
    void free(T ptr_type)
    {
        pEpLog(CXX::Inspect::all(ptr_type));
        ::pEp_free(ptr_type);
    }

    template<>
    void free(char* ptr_type)
    {
        pEpLog(CXX::Inspect::all(ptr_type));
        ::pEp_free(ptr_type);
    }

    template<>
    void free(::pEp_identity* ptr_type)
    {
        pEpLog(CXX::Inspect::all(ptr_type));
        ::pEp_free(ptr_type);
    }


//---------------------------------------------------------------------------------------------
#define EXSTR(msg) std::string(__FUNCTION__) + " - " + msg

    template<class T>
    class POD {
        static_assert(
            std::is_pod<T>::value && !std::is_pointer<T>::value,
            "only POD value types supported");

    public:
        POD()
        {
            pEpLogClass("called");
        };

        explicit POD(T* pod_p, const T& init_val)
        {
            bind(pod_p, init_val);
        }

        // Best to use this constructor, as the object is in a valid state when the wrapped
        // c_str (char*) is known
        explicit POD(T* pod_p)
        {
            bind(pod_p);
        }

        void bind(T* pod_p, const T& init_val)
        {
            bind(pod_p);
            this->operator=(init_val);
        }

        void bind(T* pod_p)
        {
            if (pod_p == nullptr) {
                throw Exception{ EXSTR("cant bind on a nullptr") };
            }

            if (_is_initialized) {
                throw Exception{ EXSTR("double initialization") };
            }
            // init
            _pod_p = pod_p;
            _is_initialized = true;
            pEpLogClass(to_string());
        }

        // make a copy
        POD& operator=(T value)
        {
            pEpLogClass("Before: " + to_string() + " - new val: '" + CXX::Inspect::val(value) + "'");
            *_pod_p = value;
            //            pEpLogClass("After:  " + to_string());
            return *this;
        }

        // return a copy
        operator T() const
        {
            return *_pod_p;
        }

        // return address of the wrappee
        T* data()
        {
            return _pod_p;
        }

        // return address of the wrappee (const)
        const T* c_data() const
        {
            return _pod_p;
        }

        std::string to_string() const
        {
            std::string ret{ "[" + CXX::Inspect::all(_pod_p) + "]" };
            return ret;
        }

        static bool log_enabled;

    private:
        bool _is_initialized{ false };
        T* _pod_p{ nullptr };

        Adapter::pEpLog::pEpLogger logger{ "pEp::POD", log_enabled };
        Adapter::pEpLog::pEpLogger& m4gic_logger_n4me = logger;

        class Exception : public std::runtime_error {
        public:
            explicit Exception(const std::string& msg) : std::runtime_error(msg) {}
        };
    };

    template<class T>
    bool pEp::POD<T>::log_enabled{ true };

    template<class T>
    std::ostream& operator<<(std::ostream& o, pEp::POD<T> pEpPOD)
    {
        return o << (T)pEpPOD;
    }

    //---------------------------------------------------------------------------------------------
    // Manages a char* to appear like a std::string
    // char* c_str
    // c_str MUST point to either:
    // * NULL - means there is no value/mem alloc yet
    // * dyn allocated memory
    // in case the mem is already allocated, there must be 2 modes
    // * take ownership (and free it)
    // * dont take ownership, only provide a C++ interface
    // There must be the option to construct the object before the wrapped c_str (char*)
    // is known. This leads to a pEp::String object in invalid state, and it must be initialized using
    // bind(). Otherwise all(most) functions will throw.
    // bind() can only be called once, will throw otherwise.
    // NON-owning mode, just does not free the string when it dies, owning mode does.
    // Thats the only difference.
    class String {
    public:
        String()
        {
            pEpLogClass("called");
        }

        // Best to use this constructor, as the object is in a valid state when the wrapped
        // c_str (char*) is known
        String(bool is_owner, char** c_str_pp)
        {
            bind(is_owner, c_str_pp);
        }

        String(bool is_owner, char** c_str_pp, const std::string& init_val)
        {
            bind(is_owner, c_str_pp, init_val);
        }

        void bind(bool is_owner, char** c_str_pp, const std::string& init_val)
        {
            bind(is_owner, c_str_pp);
            this->operator=(init_val);
        }

        // bind and set ownership
        void bind(bool is_owner, char** c_str_pp)
        {
            if (c_str_pp == nullptr) {
                throw Exception{ EXSTR("cant bind on a nullptr") };
            }

            if (_is_bound) {
                throw Exception{ EXSTR("double initialization") };
            }

            // init
            _c_str_pp = c_str_pp;
            _c_str_p = *_c_str_pp;
            _is_bound = true;
            pEpLogClass(to_string());
            set_owner(is_owner);
        }

        ~String()
        {
            if (_is_owner) {
                _free();
            }
        }

        // make a copy
        String& operator=(const std::string& str)
        {
            pEpLogClass("Before: " + to_string() + " - new val: '" + pEp::Utils::clip(str, 30) + "'");
            if (_c_str_pp == nullptr) {
                throw Exception{ EXSTR("invalid state") };
            }

            // DEALLOCATION
            _free();

            // ALLOCATION
            if (str.empty()) {
                // if the new value is empty str, lets point to nothing
                *_c_str_pp = nullptr;
                _c_str_p = *_c_str_pp;
            } else {
                *_c_str_pp = pEp::alloc_str(str);
                _c_str_p = *_c_str_pp;
            }
            pEpLogClass("After:  " + to_string());
            return *this;
        }

        // return a copy of whatever c_str currently is (maybe created by us, maybe changed meanwhile)
        operator std::string() const
        {
            if (_c_str_pp == nullptr) {
                throw Exception{ EXSTR("invalid state") };
            }

            if (*_c_str_pp != nullptr) {
                return { *_c_str_pp };
            }
            return {};
        }

        char** data()
        {
            return _c_str_pp;
        }

        const char* c_data() const
        {
            if (_c_str_pp == nullptr) {
                throw Exception{ EXSTR("invalid state") };
            }
            return *_c_str_pp;
        }

        bool operator==(const pEp::String& pstr) const
        {
            return *(pstr.c_data()) == (*c_data());
        }

        bool operator!=(const pEp::String& pstr) const
        {
            return !(*this == pstr);
        }

        std::string to_string() const
        {

            if (_c_str_pp == nullptr) {
                throw Exception{ EXSTR("invalid state") };
            }

            std::string ret{ "[" + CXX::Inspect::all(_c_str_pp) + " / " +
                             CXX::Inspect::all(*_c_str_pp) + "]" };
            return ret;
        }

        void set_owner(bool is_owner)
        {
            pEpLogClass(std::to_string(is_owner));
            _is_owner = is_owner;
        }

        bool is_owner() const
        {
            return _is_owner;
        }

        static bool log_enabled;

    private:
        // TODO: this is dodgy, do we really need _c_str_pp AND _c_str_p???
        void _free()
        {
            pEpLogClass("called");
            // if the c_str points to a different address now, than the one we created
            if (*_c_str_pp != _c_str_p) {
                // a new string has been created, and we need to free it as well
                pEpLogClass("raw access string change detected");
                pEp::free(*_c_str_pp);
            } else {
                // WE ASSUME THAT:
                // if the char* has been replaced, it has been freed, as well
                if (_c_str_p != nullptr) {
                    pEp::free(_c_str_p);
                }
            }
        }

        bool _is_bound{ false };
        bool _is_owner{ false };
        char** _c_str_pp{ nullptr };
        char* _c_str_p{ nullptr };

        Adapter::pEpLog::pEpLogger logger{ "pEp::String", log_enabled };
        Adapter::pEpLog::pEpLogger& m4gic_logger_n4me = logger;

        class Exception : public std::runtime_error {
        public:
            explicit Exception(const std::string& msg) : std::runtime_error(msg) {}
        };
    };

    bool pEp::String::log_enabled{ true };

    std::ostream& operator<<(std::ostream& o, const pEp::String& pEpStr)
    {
        return o << std::string(pEpStr);
    }

} // namespace pEp

void test_getters(int* c_int_p, pEp::POD<int>& pint, int expected)
{
    pEpLog("to_string(): " + pint.to_string());
    // compare addresses
    pEpLog("addresses == c_int_p");
    assert(pint.c_data() == c_int_p);
    assert(pint.data() == c_int_p);

    // compare values
    if (c_int_p != nullptr) {
        pEpLog("operator int(): " + std::to_string(pint));
        assert(pint == *c_int_p);
        assert(pint == expected);

        // will segfault with nullptr, and this is correct
        pEpLog("data(): " + std::to_string(*pint.data()));
        assert(*pint.data() == *c_int_p);
        assert(*pint.data() == expected);

        pEpLog("c_data(): " + std::to_string(*pint.c_data()));
        assert(*pint.c_data() == *c_int_p);
        assert(*pint.c_data() == expected);
    }
}

void test_assign(int* c_int_p, pEp::POD<int>& pint)
{
    {
        pEpLogH2("assign operator");
        int new_val = 23;
        pint = new_val;
        test_getters(c_int_p, pint, new_val);
    }
    {
        pEpLogH2("raw c_str assign");
        int new_val = 23;
        *c_int_p = new_val;
        test_getters(c_int_p, pint, new_val);
    }
}


void test_getters(char** c_str_p, pEp::String& pstr, const std::string& expected)
{
    pEpLog("to_string(): " + pstr.to_string());
    // compare addresses
    pEpLog("addresses == c_str_p");
    assert(pstr.c_data() == *c_str_p);
    assert(pstr.data() == c_str_p);

    // compare values
    if (*c_str_p != nullptr) {
        pEpLog("operator std::string(): " + std::string(pstr));
        assert(std::string(pstr) == std::string(*c_str_p));
        assert(std::string(pstr) == expected);

        // will segfault with nullptr, and this is correct
        pEpLog("data(): " + std::string(*pstr.data()));
        assert(std::string(*pstr.data()) == std::string(*c_str_p));
        assert(std::string(*pstr.data()) == expected);

        pEpLog("c_data(): " + std::string(pstr.c_data()));
        assert(std::string(pstr.c_data()) == std::string(*c_str_p));
        assert(std::string(pstr.c_data()) == expected);
    } else {
        std::string tmp{ pstr };
        pEpLog("operator std::string(): " + tmp);
        assert(tmp.empty());
    }
}

void test_assign(char** c_str_p, pEp::String& pstr)
{
    {
        pEpLogH2("assign operator");
        std::string new_val{ "assign operator" };
        pstr = new_val;
        test_getters(c_str_p, pstr, new_val);
    }
    {
        pEpLogH2("raw c_str assign");
        std::string new_val{ "raw c_str assign" };
        free(*c_str_p);
        *c_str_p = strdup(new_val.c_str());
        test_getters(c_str_p, pstr, new_val);
    }
}


namespace pEp {
    // TOOD:
    // ctor not exception safe
    class TestStruct1 {
    public:
        // Create a new instance
        TestStruct1(int i, Test_enum e, const std::string& str)
        {
            pEpLogClass("called");
            _c_struct_p = ::new_test_struct(0, ONE, nullptr); //dont use raw-setters
            bind(true, &_c_struct_p);
            // need to use these setter because of value conversions
            this->c_int = i;
            this->c_enum = e;
            this->c_str = str;
        }

        // Wrap an existing instance
        TestStruct1()
        {
            pEpLogClass("called");
        }

        // Best to use this constructor, as the object is in a valid state when the wrapped
        // c_struct_pp is known
        TestStruct1(bool is_owner, Test_struct1** c_struct_pp)
        {
            pEpLogClass("called");
            bind(is_owner, c_struct_pp);
        }

        void bind(bool is_owner, Test_struct1** c_struct_pp)
        {
            if (c_struct_pp == nullptr) {
                throw Exception{ EXSTR("cant bind on a nullptr") };
            }

            if (_is_bound) {
                throw Exception{ EXSTR("double initialization") };
            }

            // init
            _c_struct_pp = c_struct_pp;
            _c_struct_p = *_c_struct_pp;
            _is_bound = true;
            pEpLogClass(to_string());
            _bind_members();
            set_owner(is_owner);
        }

        ~TestStruct1()
        {
            if (_is_owner) {
                _free();
            }
        }

        operator ::Test_struct1*()
        {
            return _c_struct_p;
        }

        std::string to_string() const
        {
            std::string ret{ "[" + CXX::Inspect::all(_c_struct_p) + "]" };
            return ret;
        }

        void set_owner(bool is_owner)
        {
            pEpLogClass(std::to_string(is_owner));
            _is_owner = is_owner;
        }

        bool is_owner() const
        {
            return _is_owner;
        }

        pEp::POD<int> c_int{};
        pEp::POD<Test_enum> c_enum{};
        pEp::String c_str{};

        static bool log_enabled;

    private:
        void _bind_members()
        {
            this->c_int.bind(&_c_struct_p->c_int);
            this->c_enum.bind(&_c_struct_p->c_enum);
            this->c_str.bind(false, &_c_struct_p->c_str);
        }

        void _free()
        {
            pEpLogClass("called");
            ::free_test_struct(_c_struct_p);
        }
        bool _is_bound{ false };
        bool _is_owner{ false };
        ::Test_struct1** _c_struct_pp{ nullptr };
        ::Test_struct1* _c_struct_p{ nullptr };

        Adapter::pEpLog::pEpLogger logger{ "TestStruct", log_enabled };
        Adapter::pEpLog::pEpLogger& m4gic_logger_n4me = logger;

        class Exception : public std::runtime_error {
        public:
            explicit Exception(const std::string& msg) : std::runtime_error(msg) {}
        };
    };


    bool TestStruct1::log_enabled{ true };
} // namespace pEp


int main()
{
    // c-types are always POD
    // we need to handle pointer types and value types differently
    // pointer types need to be memory-managed (heap)
    // value types are being copied around (stack)
    static_assert(std::is_pod<int>::value && !std::is_pointer<int>::value, "not an integral");
    static_assert(
        std::is_pod<Test_enum>::value && !std::is_pointer<Test_enum>::value,
        "not an integral");
    static_assert(
        std::is_pod<Test_struct1>::value && !std::is_pointer<Test_struct1>::value,
        "not an integral");

    //    pEp::Utils::readKey();
    pEp::Adapter::pEpLog::set_enabled(true);

    // POD
    if (0) {
        // VALID USAGE
        int init_val = 0;
        // new pEp::POD on int
        {
            pEpLogH1("new pEp::POD on int");
            int c_int = init_val;
            pEp::POD<int> pint(&c_int);
            test_getters(&c_int, pint, init_val);
            test_assign(&c_int, pint);
        }
        // equality operator
        {
            pEpLogH1("equality operator");
            int c_int1 = init_val;
            int c_int2 = init_val;
            pEp::POD<int> pint1(&c_int1);
            pEp::POD<int> pint2(&c_int2);
            assert(pint1 == pint2);

            c_int2 = 23;
            assert(pint1 != pint2);
        }
    }

    // String
    //            pEp::String::log_enabled = false;
    if (1) {
        //TODO: Test non-owning mode

        // INVALID USAGE
        //    char* c_str_u;           // uninitialized == INVALID
        //    undefined behaviour, most likely "pointer being freed was not allocated"
        //    {
        //        char* c_str;
        //        pEp::String pstr(c_str);
        //    }
        //    char* c_str_s = "fdsfs"; // statically initialized == INVALID
        //    {
        //        char ca[4] = { 'p', 'E', 'p'};
        //        char* c_str = ca;
        //        pEp::String pstr(c_str);
        //    }

        // VALID USAGE
        // new pEp::String on char* pointing to NULL
        {
            pEpLogH1("new pEp::String on char* pointing to NULL");
            char* c_str = NULL; // nullptr

            pEp::String pstr(true, &c_str);
            test_getters(&c_str, pstr, "");
            test_assign(&c_str, pstr);
        }

        std::string init_val{ "initialized c string" };
        // new pEp::String on already initalized char*
        {
            pEpLogH1("new pEp::String on already initalized char*");
            char* c_str = strdup(init_val.c_str());

            pEp::String pstr(true, &c_str);
            test_getters(&c_str, pstr, init_val);
            test_assign(&c_str, pstr);
        }

        // bind()
        {
            pEpLogH1("bind()");
            pEp::String pstr{};

            char* c_str = strdup(init_val.c_str());
            //TODO: PITYASSERT_THROWS
            pstr.bind(true, &c_str);
            test_getters(&c_str, pstr, init_val);
            test_assign(&c_str, pstr);
        }

        // equality operator
        {
            pEpLogH1("equality operator");
            pEp::String pstr1{};

            char* c_str1 = strdup(init_val.c_str());
            char* c_str2 = strdup(init_val.c_str());
            pstr1.bind(true, &c_str1);
            pEp::String pstr2{ true, &c_str2 };
            assert(pstr1 == pstr2);
            pstr2 = "huhu";
            assert(pstr1 != pstr2);
        }
    }

    if (0) {
        // create
        {
            pEp::TestStruct1 pstruct1(23, TWO, "pEp");
            pEpLog(pstruct1.c_int);
            pEpLog(pstruct1.c_enum);
            pEpLog(pstruct1.c_str);

            Test_struct1* c_struct1 = pstruct1;
            pEpLog(c_struct1->c_int);
            pEpLog(c_struct1->c_enum);
            pEpLog(c_struct1->c_str);
            pEpLog("DONE");
        }

        // wrap
        {
            Test_struct1* c_struct1 = new_test_struct(0, ONE, "pEp");
            pEpLog(c_struct1->c_int);
            pEpLog(c_struct1->c_enum);
            pEpLog(c_struct1->c_str);
            pEpLog("DONE");

            pEp::TestStruct1 pstruct1(true, &c_struct1);
            pEpLog(pstruct1.c_int);
            pEpLog(pstruct1.c_enum);
            pEpLog(pstruct1.c_str);
        }
    }

    //    if (0) {
    //        ::PEP_SESSION session;
    //        setenv("HOME", ".", 1);
    //        ::init(&session, nullptr, nullptr, nullptr);
    //
    //        //                create identity
    //        pEp::Identity id1{ "wrong@entry.lol", "wrong", "23", "INVA_FPR" };
    //
    //        pEpLog(id1);
    //        id1.username = "alice";
    //        id1.address = "alice@peptest.org";
    //
    //        pEpLog(id1.address);
    //        pEpLog(id1.username);
    //        ::myself(session, id1);
    //        pEpLog(id1);
    //
    //        pEp::Identity id2{ "bob" };
    //        ::update_identity(session, id2);
    //        pEpLog(id2);
    //    }
}

//---------------------------------------------------------------------------------------------
//
//// TOOD:
//// ctor not exception safe
//class Identity {
//public:
//    Identity(
//        const std::string& address = "",
//        const std::string& username = "",
//        const std::string& user_id = "",
//        const std::string& fpr = "")
//    {
//        pEpLogClass("called");
//        _wrappee = ::new_identity(nullptr, nullptr, nullptr, nullptr);
//
//        // set the pEp::String wrapper underlying c_str
//        this->address.bind(true, &_wrappee->address, address);
//        this->username.bind(true, &_wrappee->username, username);
//        this->user_id.bind(true, &_wrappee->user_id, user_id);
//        this->fpr.bind(true, &_wrappee->fpr, fpr);
//    }
//
//    ~Identity()
//    {
//        _free();
//    }
//
//
//    pEp::String address{};
//    pEp::String username{};
//    pEp::String user_id{};
//    pEp::String fpr{};
//
//    operator ::pEp_identity*()
//    {
//        return _wrappee;
//    }
//
//    static bool log_enabled;
//
//private:
//    void _free()
//    {
//        //            pEp::free(_wrappee);
//    }
//
//    ::pEp_identity* _wrappee{ nullptr };
//    Adapter::pEpLog::pEpLogger logger{ "IdentWrappySP", log_enabled };
//    Adapter::pEpLog::pEpLogger& m4gic_logger_n4me = logger;
//};
//
//bool Identity::log_enabled{ true };
//