#define CATCH_CONFIG_MAIN #include "catch.hpp" #include "JSON.h" TEST_CASE("array") { SECTION("Basics") { // construction with given type JSON j(JSON::value_type::array); CHECK(j.type() == JSON::value_type::array); // string representation of default value CHECK(j.toString() == "[]"); // check payload CHECK(*(j.data().array) == JSON::array_t()); // container members CHECK(j.size() == 0); CHECK(j.empty() == true); // implicit conversions CHECK_NOTHROW(JSON::array_t v = j); CHECK_THROWS_AS(JSON::object_t v = j, std::logic_error); CHECK_THROWS_AS(std::string v = j, std::logic_error); CHECK_THROWS_AS(bool v = j, std::logic_error); CHECK_THROWS_AS(int v = j, std::logic_error); CHECK_THROWS_AS(double v = j, std::logic_error); // explicit conversions CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); // transparent usage auto id = [](JSON::array_t v) { return v; }; CHECK(id(j) == j.get()); // copy constructor JSON k(j); CHECK(k == j); // copy assignment k = j; CHECK(k == j); // move constructor JSON l = std::move(k); CHECK(l == j); } SECTION("Create from value") { JSON::array_t v1 = {"string", 1, 1.0, false, nullptr}; JSON j1 = v1; CHECK(j1.get() == v1); JSON j2 = {"string", 1, 1.0, false, nullptr}; JSON::array_t v2 = j2; CHECK(j2.get() == v1); CHECK(j2.get() == v2); // special tests to make sure construction from initializer list works // case 1: there is an element that is not an array JSON j3 = { {"foo", "bar"}, 3 }; CHECK(j3.type() == JSON::value_type::array); // case 2: there is an element with more than two elements JSON j4 = { {"foo", "bar"}, {"one", "two", "three"} }; CHECK(j4.type() == JSON::value_type::array); // case 3: there is an element whose first element is not a string JSON j5 = { {"foo", "bar"}, {true, "baz"} }; CHECK(j5.type() == JSON::value_type::array); // check if nested arrays work and are recognized as arrays JSON j6 = { {{"foo", "bar"}} }; CHECK(j6.type() == JSON::value_type::array); CHECK(j6.size() == 1); CHECK(j6[0].type() == JSON::value_type::object); // move constructor JSON j7(std::move(v1)); CHECK(j7 == j1); } SECTION("Array operators") { JSON j = {0, 1, 2, 3, 4, 5, 6}; // read const int v1 = j[3]; CHECK(v1 == 3); // write j[4] = 9; int v2 = j[4]; CHECK(v2 == 9); // size CHECK (j.size() == 7); // push_back for different value types j.push_back(7); j.push_back("const char*"); j.push_back(42.23); std::string s = "std::string"; j.push_back(s); j.push_back(false); j.push_back(nullptr); j.push_back(j); CHECK (j.size() == 14); // operator+= for different value types j += 7; j += "const char*"; j += 42.23; j += s; j += false; j += nullptr; j += j; CHECK (j.size() == 21); // implicit transformation into an array JSON empty1, empty2; empty1 += "foo"; empty2.push_back("foo"); CHECK(empty1.type() == JSON::value_type::array); CHECK(empty2.type() == JSON::value_type::array); CHECK(empty1 == empty2); // exceptions JSON nonarray = 1; CHECK_THROWS_AS(const int i = nonarray[0], std::domain_error); CHECK_NOTHROW(j[21]); CHECK_THROWS_AS(const int i = j.at(21), std::out_of_range); CHECK_THROWS_AS(nonarray[0] = 10, std::domain_error); CHECK_NOTHROW(j[21] = 5); CHECK_THROWS_AS(j.at(21) = 5, std::out_of_range); CHECK_THROWS_AS(nonarray += 2, std::runtime_error); CHECK_THROWS_AS(nonarray.push_back(JSON(nullptr)), std::runtime_error); const JSON k = j; CHECK_NOTHROW(k[21]); CHECK_THROWS_AS(const int i = k.at(21), std::out_of_range); // add initializer list j.push_back({"a", "b", "c"}); CHECK (j.size() == 24); } SECTION("Iterators") { std::vector vec = {0, 1, 2, 3, 4, 5, 6}; JSON j1 = {0, 1, 2, 3, 4, 5, 6}; const JSON j2 = {0, 1, 2, 3, 4, 5, 6}; { // const_iterator for (JSON::const_iterator cit = j1.begin(); cit != j1.end(); ++cit) { int v = *cit; CHECK(v == vec[static_cast(v)]); if (cit == j1.begin()) { CHECK(v == 0); } } } { // const_iterator with cbegin/cend for (JSON::const_iterator cit = j1.cbegin(); cit != j1.cend(); ++cit) { int v = *cit; CHECK(v == vec[static_cast(v)]); if (cit == j1.cbegin()) { CHECK(v == 0); } } } { // range based for for (auto el : j1) { int v = el; CHECK(v == vec[static_cast(v)]); } } { // iterator for (JSON::iterator cit = j1.begin(); cit != j1.end(); ++cit) { int v_old = *cit; *cit = cit->get() * 2; int v = *cit; CHECK(v == vec[static_cast(v_old)] * 2); if (cit == j1.begin()) { CHECK(v == 0); } } } { // const_iterator (on const object) for (JSON::const_iterator cit = j2.begin(); cit != j2.end(); ++cit) { int v = *cit; CHECK(v == vec[static_cast(v)]); if (cit == j2.begin()) { CHECK(v == 0); } } } { // const_iterator with cbegin/cend (on const object) for (JSON::const_iterator cit = j2.cbegin(); cit != j2.cend(); ++cit) { int v = *cit; CHECK(v == vec[static_cast(v)]); if (cit == j2.cbegin()) { CHECK(v == 0); } } } { // range based for (on const object) for (auto el : j2) { int v = el; CHECK(v == vec[static_cast(v)]); } } } } TEST_CASE("object") { SECTION("Basics") { // construction with given type JSON j(JSON::value_type::object); CHECK(j.type() == JSON::value_type::object); // string representation of default value CHECK(j.toString() == "{}"); // check payload CHECK(*(j.data().object) == JSON::object_t()); // container members CHECK(j.size() == 0); CHECK(j.empty() == true); // implicit conversions CHECK_THROWS_AS(JSON::array_t v = j, std::logic_error); CHECK_NOTHROW(JSON::object_t v = j); CHECK_THROWS_AS(std::string v = j, std::logic_error); CHECK_THROWS_AS(bool v = j, std::logic_error); CHECK_THROWS_AS(int v = j, std::logic_error); CHECK_THROWS_AS(double v = j, std::logic_error); // explicit conversions CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); // transparent usage auto id = [](JSON::object_t v) { return v; }; CHECK(id(j) == j.get()); // copy constructor JSON k(j); CHECK(k == j); // copy assignment k = j; CHECK(k == j); // move constructor JSON l = std::move(k); CHECK(l == j); } SECTION("Create from value") { JSON::object_t v1 = { {"v1", "string"}, {"v2", 1}, {"v3", 1.0}, {"v4", false} }; JSON j1 = v1; CHECK(j1.get() == v1); JSON j2 = { {"v1", "string"}, {"v2", 1}, {"v3", 1.0}, {"v4", false} }; JSON::object_t v2 = j2; CHECK(j2.get() == v1); CHECK(j2.get() == v2); // check if multiple keys are ignored JSON j3 = { {"key", "value"}, {"key", 1} }; CHECK(j3.size() == 1); // move constructor JSON j7(std::move(v1)); CHECK(j7 == j1); } SECTION("Object operators") { JSON j = {{"k0", "v0"}, {"k1", nullptr}, {"k2", 42}, {"k3", 3.141}, {"k4", true}}; const JSON k = j; // read const std::string v0 = j["k0"]; CHECK(v0 == "v0"); auto v1 = j["k1"]; CHECK(v1 == nullptr); int v2 = j["k2"]; CHECK(v2 == 42); double v3 = j["k3"]; CHECK(v3 == 3.141); bool v4 = j["k4"]; CHECK(v4 == true); // write (replace) j["k0"] = "new v0"; CHECK(j["k0"] == "new v0"); // write (add) j["k5"] = false; // size CHECK(j.size() == 6); // find CHECK(j.find("k0") != j.end()); CHECK(j.find("v0") == j.end()); JSON::const_iterator i1 = j.find("k0"); JSON::iterator i2 = j.find("k0"); // at CHECK_THROWS_AS(j.at("foo"), std::out_of_range); CHECK_THROWS_AS(k.at("foo"), std::out_of_range); // add pair j.push_back(JSON::object_t::value_type {"int_key", 42}); CHECK(j["int_key"].get() == 42); j += JSON::object_t::value_type {"int_key2", 23}; CHECK(j["int_key2"].get() == 23); { // make sure null objects are transformed JSON je; CHECK_NOTHROW(je.push_back(JSON::object_t::value_type {"int_key", 42})); CHECK(je["int_key"].get() == 42); } { // make sure null objects are transformed JSON je; CHECK_NOTHROW((je += JSON::object_t::value_type {"int_key", 42})); CHECK(je["int_key"].get() == 42); } // add initializer list (of pairs) { JSON je; je.push_back({ {"one", 1}, {"two", false}, {"three", {1, 2, 3}} }); CHECK(je["one"].get() == 1); CHECK(je["two"].get() == false); CHECK(je["three"].size() == 3); } { JSON je; je += { {"one", 1}, {"two", false}, {"three", {1, 2, 3}} }; CHECK(je["one"].get() == 1); CHECK(je["two"].get() == false); CHECK(je["three"].size() == 3); } // key/value for non-end iterator CHECK(i1.key() == "k0"); CHECK(i1.value() == j["k0"]); CHECK(i2.key() == "k0"); CHECK(i2.value() == j["k0"]); // key/value for uninitialzed iterator JSON::const_iterator i3; JSON::iterator i4; CHECK_THROWS_AS(i3.key(), std::out_of_range); CHECK_THROWS_AS(i3.value(), std::out_of_range); CHECK_THROWS_AS(i4.key(), std::out_of_range); CHECK_THROWS_AS(i4.value(), std::out_of_range); // key/value for end-iterator JSON::const_iterator i5 = j.find("v0"); JSON::iterator i6 = j.find("v0"); CHECK_THROWS_AS(i5.key(), std::out_of_range); CHECK_THROWS_AS(i5.value(), std::out_of_range); CHECK_THROWS_AS(i6.key(), std::out_of_range); CHECK_THROWS_AS(i6.value(), std::out_of_range); // implicit transformation into an object JSON empty; empty["foo"] = "bar"; CHECK(empty.type() == JSON::value_type::object); CHECK(empty["foo"] == "bar"); // exceptions JSON nonarray = 1; CHECK_THROWS_AS(const int i = nonarray["v1"], std::domain_error); CHECK_THROWS_AS(nonarray["v1"] = 10, std::domain_error); } SECTION("Iterators") { JSON j1 = {{"k0", 0}, {"k1", 1}, {"k2", 2}, {"k3", 3}}; const JSON j2 = {{"k0", 0}, {"k1", 1}, {"k2", 2}, {"k3", 3}}; // iterator for (JSON::iterator it = j1.begin(); it != j1.end(); ++it) { switch (static_cast(it.value())) { case (0): CHECK(it.key() == "k0"); break; case (1): CHECK(it.key() == "k1"); break; case (2): CHECK(it.key() == "k2"); break; case (3): CHECK(it.key() == "k3"); break; default: CHECK(false); } CHECK((*it).type() == JSON::value_type::number); CHECK(it->type() == JSON::value_type::number); } // range-based for for (auto& element : j1) { element = 2 * element.get(); } // const_iterator for (JSON::const_iterator it = j1.begin(); it != j1.end(); ++it) { switch (static_cast(it.value())) { case (0): CHECK(it.key() == "k0"); break; case (2): CHECK(it.key() == "k1"); break; case (4): CHECK(it.key() == "k2"); break; case (6): CHECK(it.key() == "k3"); break; default: CHECK(false); } CHECK((*it).type() == JSON::value_type::number); CHECK(it->type() == JSON::value_type::number); } // const_iterator using cbegin/cend for (JSON::const_iterator it = j1.cbegin(); it != j1.cend(); ++it) { switch (static_cast(it.value())) { case (0): CHECK(it.key() == "k0"); break; case (2): CHECK(it.key() == "k1"); break; case (4): CHECK(it.key() == "k2"); break; case (6): CHECK(it.key() == "k3"); break; default: CHECK(false); } CHECK((*it).type() == JSON::value_type::number); CHECK(it->type() == JSON::value_type::number); } // const_iterator (on const object) for (JSON::const_iterator it = j2.begin(); it != j2.end(); ++it) { switch (static_cast(it.value())) { case (0): CHECK(it.key() == "k0"); break; case (1): CHECK(it.key() == "k1"); break; case (2): CHECK(it.key() == "k2"); break; case (3): CHECK(it.key() == "k3"); break; default: CHECK(false); } CHECK((*it).type() == JSON::value_type::number); CHECK(it->type() == JSON::value_type::number); } // const_iterator using cbegin/cend (on const object) for (JSON::const_iterator it = j2.cbegin(); it != j2.cend(); ++it) { switch (static_cast(it.value())) { case (0): CHECK(it.key() == "k0"); break; case (1): CHECK(it.key() == "k1"); break; case (2): CHECK(it.key() == "k2"); break; case (3): CHECK(it.key() == "k3"); break; default: CHECK(false); } CHECK((*it).type() == JSON::value_type::number); CHECK(it->type() == JSON::value_type::number); } // range-based for (on const object) for (auto element : j1) { CHECK(element.get() >= 0); } } } TEST_CASE("null") { SECTION("Basics") { // construction with given type JSON j; CHECK(j.type() == JSON::value_type::null); // string representation of default value CHECK(j.toString() == "null"); // container members CHECK(j.size() == 0); CHECK(j.empty() == true); // implicit conversions CHECK_NOTHROW(JSON::array_t v = j); CHECK_THROWS_AS(JSON::object_t v = j, std::logic_error); CHECK_THROWS_AS(std::string v = j, std::logic_error); CHECK_THROWS_AS(bool v = j, std::logic_error); CHECK_THROWS_AS(int v = j, std::logic_error); CHECK_THROWS_AS(double v = j, std::logic_error); // explicit conversions CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); // copy constructor JSON k(j); CHECK(k == j); // copy assignment k = j; CHECK(k == j); // move constructor JSON l = std::move(k); CHECK(l == j); } SECTION("Create from value") { JSON j1 = nullptr; CHECK(j1.type() == JSON::value_type::null); } } TEST_CASE("string") { SECTION("Basics") { // construction with given type JSON j(JSON::value_type::string); CHECK(j.type() == JSON::value_type::string); // string representation of default value CHECK(j.toString() == "\"\""); // check payload CHECK(*(j.data().string) == JSON::string_t()); // container members CHECK(j.size() == 1); CHECK(j.empty() == false); // implicit conversions CHECK_NOTHROW(JSON::array_t v = j); CHECK_THROWS_AS(JSON::object_t v = j, std::logic_error); CHECK_NOTHROW(std::string v = j); CHECK_THROWS_AS(bool v = j, std::logic_error); CHECK_THROWS_AS(int v = j, std::logic_error); CHECK_THROWS_AS(double v = j, std::logic_error); // explicit conversions CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); // transparent usage auto id = [](std::string v) { return v; }; CHECK(id(j) == j.get()); // copy constructor JSON k(j); CHECK(k == j); // copy assignment k = j; CHECK(k == j); // move constructor JSON l = std::move(k); CHECK(l == j); } SECTION("Create from value") { JSON j1 = std::string("Hello, world"); std::string v1 = j1; CHECK(j1.get() == v1); JSON j2 = "Hello, world"; CHECK(j2.get() == "Hello, world"); std::string v3 = "Hello, world"; JSON j3 = std::move(v3); CHECK(j3.get() == "Hello, world"); } } TEST_CASE("boolean") { SECTION("Basics") { // construction with given type JSON j(JSON::value_type::boolean); CHECK(j.type() == JSON::value_type::boolean); // string representation of default value CHECK(j.toString() == "false"); // check payload CHECK(j.data().boolean == JSON::boolean_t()); // container members CHECK(j.size() == 1); CHECK(j.empty() == false); // implicit conversions CHECK_NOTHROW(JSON::array_t v = j); CHECK_THROWS_AS(JSON::object_t v = j, std::logic_error); CHECK_THROWS_AS(std::string v = j, std::logic_error); CHECK_NOTHROW(bool v = j); CHECK_THROWS_AS(int v = j, std::logic_error); CHECK_THROWS_AS(double v = j, std::logic_error); // explicit conversions CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); // transparent usage auto id = [](bool v) { return v; }; CHECK(id(j) == j.get()); // copy constructor JSON k(j); CHECK(k == j); // copy assignment k = j; CHECK(k == j); // move constructor JSON l = std::move(k); CHECK(l == j); } SECTION("Create from value") { JSON j1 = true; bool v1 = j1; CHECK(j1.get() == v1); JSON j2 = false; bool v2 = j2; CHECK(j2.get() == v2); } } TEST_CASE("number (int)") { SECTION("Basics") { // construction with given type JSON j(JSON::value_type::number); CHECK(j.type() == JSON::value_type::number); // string representation of default value CHECK(j.toString() == "0"); // check payload CHECK(j.data().number == JSON::number_t()); // container members CHECK(j.size() == 1); CHECK(j.empty() == false); // implicit conversions CHECK_NOTHROW(JSON::array_t v = j); CHECK_THROWS_AS(JSON::object_t v = j, std::logic_error); CHECK_THROWS_AS(std::string v = j, std::logic_error); CHECK_THROWS_AS(bool v = j, std::logic_error); CHECK_NOTHROW(int v = j); CHECK_NOTHROW(double v = j); // explicit conversions CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_NOTHROW(auto v = j.get()); CHECK_NOTHROW(auto v = j.get()); // transparent usage auto id = [](int v) { return v; }; CHECK(id(j) == j.get()); // copy constructor JSON k(j); CHECK(k == j); // copy assignment k = j; CHECK(k == j); // move constructor JSON l = std::move(k); CHECK(l == j); } SECTION("Create from value") { JSON j1 = 23; int v1 = j1; CHECK(j1.get() == v1); JSON j2 = 42; int v2 = j2; CHECK(j2.get() == v2); } } TEST_CASE("number (float)") { SECTION("Basics") { // construction with given type JSON j(JSON::value_type::number_float); CHECK(j.type() == JSON::value_type::number_float); // string representation of default value CHECK(j.toString() == "0.000000"); // check payload CHECK(j.data().number_float == JSON::number_float_t()); // container members CHECK(j.size() == 1); CHECK(j.empty() == false); // implicit conversions CHECK_NOTHROW(JSON::array_t v = j); CHECK_THROWS_AS(JSON::object_t v = j, std::logic_error); CHECK_THROWS_AS(std::string v = j, std::logic_error); CHECK_THROWS_AS(bool v = j, std::logic_error); CHECK_NOTHROW(int v = j); CHECK_NOTHROW(double v = j); // explicit conversions CHECK_NOTHROW(auto v = j.get()); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_THROWS_AS(auto v = j.get(), std::logic_error); CHECK_NOTHROW(auto v = j.get()); CHECK_NOTHROW(auto v = j.get()); // transparent usage auto id = [](double v) { return v; }; CHECK(id(j) == j.get()); // copy constructor JSON k(j); CHECK(k == j); // copy assignment k = j; CHECK(k == j); // move constructor JSON l = std::move(k); CHECK(l == j); } SECTION("Create from value") { JSON j1 = 3.1415926; double v1 = j1; CHECK(j1.get() == v1); JSON j2 = 2.7182818; double v2 = j2; CHECK(j2.get() == v2); } } TEST_CASE("Parser") { SECTION("null") { // accept the exact values CHECK(JSON::parse("null") == JSON(nullptr)); // ignore whitespace CHECK(JSON::parse(" null ") == JSON(nullptr)); CHECK(JSON::parse("\tnull\n") == JSON(nullptr)); // respect capitalization CHECK_THROWS_AS(JSON::parse("Null"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("NULL"), std::invalid_argument); // do not accept prefixes CHECK_THROWS_AS(JSON::parse("n"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("nu"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("nul"), std::invalid_argument); } SECTION("string") { // accept some values CHECK(JSON::parse("\"\"") == JSON("")); CHECK(JSON::parse("\"foo\"") == JSON("foo")); // quotes must be closed CHECK_THROWS_AS(JSON::parse("\""), std::invalid_argument); } SECTION("boolean") { // accept the exact values CHECK(JSON::parse("true") == JSON(true)); CHECK(JSON::parse("false") == JSON(false)); // ignore whitespace CHECK(JSON::parse(" true ") == JSON(true)); CHECK(JSON::parse("\tfalse\n") == JSON(false)); // respect capitalization CHECK_THROWS_AS(JSON::parse("True"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("False"), std::invalid_argument); // do not accept prefixes CHECK_THROWS_AS(JSON::parse("t"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("tr"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("tru"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("f"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("fa"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("fal"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("fals"), std::invalid_argument); } SECTION("number (int)") { // accept the exact values CHECK(JSON::parse("0") == JSON(0)); CHECK(JSON::parse("-0") == JSON(0)); CHECK(JSON::parse("1") == JSON(1)); CHECK(JSON::parse("-1") == JSON(-1)); CHECK(JSON::parse("12345678") == JSON(12345678)); CHECK(JSON::parse("-12345678") == JSON(-12345678)); CHECK(JSON::parse("0.0") == JSON(0)); CHECK(JSON::parse("-0.0") == JSON(0)); CHECK(JSON::parse("1.0") == JSON(1)); CHECK(JSON::parse("-1.0") == JSON(-1)); CHECK(JSON::parse("12345678.0") == JSON(12345678)); CHECK(JSON::parse("-12345678.0") == JSON(-12345678)); CHECK(JSON::parse("17e0") == JSON(17)); CHECK(JSON::parse("17e1") == JSON(170)); CHECK(JSON::parse("17e3") == JSON(17000)); CHECK(JSON::parse("17e+0") == JSON(17)); CHECK(JSON::parse("17e+1") == JSON(170)); CHECK(JSON::parse("17e+3") == JSON(17000)); CHECK(JSON::parse("17E0") == JSON(17)); CHECK(JSON::parse("17E1") == JSON(170)); CHECK(JSON::parse("17E3") == JSON(17000)); CHECK(JSON::parse("17E+0") == JSON(17)); CHECK(JSON::parse("17E+1") == JSON(170)); CHECK(JSON::parse("17E+3") == JSON(17000)); CHECK(JSON::parse("10000e-0") == JSON(10000)); CHECK(JSON::parse("10000e-1") == JSON(1000)); CHECK(JSON::parse("10000e-4") == JSON(1)); CHECK(JSON::parse("10000E-0") == JSON(10000)); CHECK(JSON::parse("10000E-1") == JSON(1000)); CHECK(JSON::parse("10000E-4") == JSON(1)); CHECK(JSON::parse("17.0e0") == JSON(17)); CHECK(JSON::parse("17.0e1") == JSON(170)); CHECK(JSON::parse("17.0e3") == JSON(17000)); CHECK(JSON::parse("17.0e+0") == JSON(17)); CHECK(JSON::parse("17.0e+1") == JSON(170)); CHECK(JSON::parse("17.0e+3") == JSON(17000)); CHECK(JSON::parse("17.0E0") == JSON(17)); CHECK(JSON::parse("17.0E1") == JSON(170)); CHECK(JSON::parse("17.0E3") == JSON(17000)); CHECK(JSON::parse("17.0E+0") == JSON(17)); CHECK(JSON::parse("17.0E+1") == JSON(170)); CHECK(JSON::parse("17.0E+3") == JSON(17000)); CHECK(JSON::parse("10000.0e-0") == JSON(10000)); CHECK(JSON::parse("10000.0e-1") == JSON(1000)); CHECK(JSON::parse("10000.0e-4") == JSON(1)); CHECK(JSON::parse("10000.0E-0") == JSON(10000)); CHECK(JSON::parse("10000.0E-1") == JSON(1000)); CHECK(JSON::parse("10000.0E-4") == JSON(1)); // trailing zero is not allowed //CHECK_THROWS_AS(JSON::parse("01"), std::invalid_argument); // whitespace inbetween is an error //CHECK_THROWS_AS(JSON::parse("1 0"), std::invalid_argument); // only one minus is allowd CHECK_THROWS_AS(JSON::parse("--1"), std::invalid_argument); // string representations are not allowed CHECK_THROWS_AS(JSON::parse("NAN"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("nan"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("INF"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("inf"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("INFINITY"), std::invalid_argument); CHECK_THROWS_AS(JSON::parse("infinity"), std::invalid_argument); } SECTION("parse from C++ string") { std::string s = "{ \"foo\": [1,2,true] }"; CHECK_NOTHROW(JSON::parse(s)); } SECTION("user-defined string literal operator") { auto j1 = "[1,2,3]"_json; JSON j2 = {1, 2, 3}; CHECK(j1 == j2); auto j3 = "{\"key\": \"value\"}"_json; CHECK(j3["key"] == "value"); } }