/////////////////////////////////////////////////////////////////////////////// // // Copyright (c) 2015 Microsoft Corporation. All rights reserved. // // This code is licensed under the MIT License (MIT). // // 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. // /////////////////////////////////////////////////////////////////////////////// // Adapted from // https://github.com/Microsoft/GSL/blob/3819df6e378ffccf0e29465afe99c3b324c2aa70/tests/Span_tests.cpp #include "gtest/gtest.h" #include "mozilla/Span.h" #include "nsString.h" #include "nsTArray.h" #include "mozilla/Range.h" #include #define SPAN_TEST(name) TEST(SpanTest, name) #define CHECK_THROW(a, b) using namespace mozilla; static_assert(std::is_convertible_v, Span>, "Range should convert into const"); static_assert(std::is_convertible_v, Span>, "const Range should convert into const"); static_assert(!std::is_convertible_v, Span>, "Range should not drop const in conversion"); static_assert(std::is_convertible_v, Range>, "Span should convert into const"); static_assert(std::is_convertible_v, Range>, "const Span should convert into const"); static_assert(!std::is_convertible_v, Range>, "Span should not drop const in conversion"); static_assert(std::is_convertible_v, Span>, "const Span should convert into const"); static_assert(std::is_convertible_v, Span>, "Span should convert into const"); static_assert(!std::is_convertible_v, Span>, "Span should not drop const in conversion"); static_assert(std::is_convertible_v, Span>, "const nsTArray should convert into const"); static_assert(std::is_convertible_v, Span>, "nsTArray should convert into const"); static_assert(!std::is_convertible_v, Span>, "nsTArray should not drop const in conversion"); static_assert(std::is_convertible_v, Span>, "nsTArray should convert into const"); static_assert(!std::is_convertible_v, Span>, "nsTArray should not drop const in conversion"); static_assert(std::is_convertible_v, Span>, "const std::vector should convert into const"); static_assert(std::is_convertible_v, Span>, "std::vector should convert into const"); static_assert(!std::is_convertible_v, Span>, "std::vector should not drop const in conversion"); /** * Rust slice-compatible nullptr replacement value. */ #define SLICE_CONST_INT_PTR reinterpret_cast(alignof(const int)) /** * Rust slice-compatible nullptr replacement value. */ #define SLICE_INT_PTR reinterpret_cast(alignof(int)) /** * Rust slice-compatible nullptr replacement value. */ #define SLICE_CONST_INT_PTR_PTR \ reinterpret_cast(alignof(const int*)) /** * Rust slice-compatible nullptr replacement value. */ #define SLICE_INT_PTR_PTR reinterpret_cast(alignof(int*)) namespace { struct BaseClass {}; struct DerivedClass : BaseClass {}; } // namespace void AssertSpanOfThreeInts(Span s) { ASSERT_EQ(s.size(), 3U); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[1], 2); ASSERT_EQ(s[2], 3); } void AssertSpanOfThreeChars(Span s) { ASSERT_EQ(s.size(), 3U); ASSERT_EQ(s[0], 'a'); ASSERT_EQ(s[1], 'b'); ASSERT_EQ(s[2], 'c'); } void AssertSpanOfThreeChar16s(Span s) { ASSERT_EQ(s.size(), 3U); ASSERT_EQ(s[0], 'a'); ASSERT_EQ(s[1], 'b'); ASSERT_EQ(s[2], 'c'); } void AssertSpanOfThreeCharsViaString(const nsACString& aStr) { AssertSpanOfThreeChars(aStr); } void AssertSpanOfThreeChar16sViaString(const nsAString& aStr) { AssertSpanOfThreeChar16s(aStr); } SPAN_TEST(default_constructor) { { Span s; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } { Span s; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } { #ifdef CONFIRM_COMPILATION_ERRORS Span s; ASSERT_EQ(s.Length(), 1U); ASSERT_EQ(s.data(), SLICE_INT_PTR); // explains why it can't compile #endif } { Span s{}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs{}; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } } SPAN_TEST(size_optimization) { { Span s; ASSERT_EQ(sizeof(s), sizeof(int*) + sizeof(size_t)); } { Span s; ASSERT_EQ(sizeof(s), sizeof(int*)); } } SPAN_TEST(from_nullptr_constructor) { { Span s = nullptr; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs = nullptr; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } { Span s = nullptr; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs = nullptr; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } { #ifdef CONFIRM_COMPILATION_ERRORS Span s = nullptr; ASSERT_EQ(s.Length(), 1U); ASSERT_EQ(s.data(), SLICE_INT_PTR); // explains why it can't compile #endif } { Span s{nullptr}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs{nullptr}; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } { Span s{nullptr}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR_PTR); Span cs{nullptr}; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR_PTR); } } SPAN_TEST(from_nullptr_length_constructor) { { Span s{nullptr, static_cast::index_type>(0)}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs{nullptr, static_cast::index_type>(0)}; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } { Span s{nullptr, static_cast::index_type>(0)}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); Span cs{nullptr, static_cast::index_type>(0)}; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR); } #if 0 { auto workaround_macro = []() { Span s{ nullptr, static_cast::index_type>(0) }; }; CHECK_THROW(workaround_macro(), fail_fast); } { auto workaround_macro = []() { Span s{nullptr, 1}; }; CHECK_THROW(workaround_macro(), fail_fast); auto const_workaround_macro = []() { Span cs{nullptr, 1}; }; CHECK_THROW(const_workaround_macro(), fail_fast); } { auto workaround_macro = []() { Span s{nullptr, 1}; }; CHECK_THROW(workaround_macro(), fail_fast); auto const_workaround_macro = []() { Span s{nullptr, 1}; }; CHECK_THROW(const_workaround_macro(), fail_fast); } #endif { Span s{nullptr, static_cast::index_type>(0)}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR_PTR); Span cs{nullptr, static_cast::index_type>(0)}; ASSERT_EQ(cs.Length(), 0U); ASSERT_EQ(cs.data(), SLICE_CONST_INT_PTR_PTR); } } SPAN_TEST(from_pointer_length_constructor) { int arr[4] = {1, 2, 3, 4}; { Span s{&arr[0], 2}; ASSERT_EQ(s.Length(), 2U); ASSERT_EQ(s.data(), &arr[0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[1], 2); } { Span s{&arr[0], 2}; ASSERT_EQ(s.Length(), 2U); ASSERT_EQ(s.data(), &arr[0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[1], 2); } { int* p = nullptr; Span s{p, static_cast::index_type>(0)}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); } #if 0 { int* p = nullptr; auto workaround_macro = [=]() { Span s{p, 2}; }; CHECK_THROW(workaround_macro(), fail_fast); } #endif { auto s = Span(&arr[0], 2); ASSERT_EQ(s.Length(), 2U); ASSERT_EQ(s.data(), &arr[0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[1], 2); } { int* p = nullptr; auto s = Span(p, static_cast::index_type>(0)); ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); } #if 0 { int* p = nullptr; auto workaround_macro = [=]() { Span(p, 2); }; CHECK_THROW(workaround_macro(), fail_fast); } #endif } SPAN_TEST(from_pointer_pointer_constructor) { int arr[4] = {1, 2, 3, 4}; { Span s{&arr[0], &arr[2]}; ASSERT_EQ(s.Length(), 2U); ASSERT_EQ(s.data(), &arr[0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[1], 2); } { Span s{&arr[0], &arr[2]}; ASSERT_EQ(s.Length(), 2U); ASSERT_EQ(s.data(), &arr[0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[1], 2); } { Span s{&arr[0], &arr[0]}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), &arr[0]); } { Span s{&arr[0], &arr[0]}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), &arr[0]); } // this will fail the std::distance() precondition, which asserts on MSVC // debug builds //{ // auto workaround_macro = [&]() { Span s{&arr[1], &arr[0]}; }; // CHECK_THROW(workaround_macro(), fail_fast); //} // this will fail the std::distance() precondition, which asserts on MSVC // debug builds //{ // int* p = nullptr; // auto workaround_macro = [&]() { Span s{&arr[0], p}; }; // CHECK_THROW(workaround_macro(), fail_fast); //} { int* p = nullptr; Span s{p, p}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); } { int* p = nullptr; Span s{p, p}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); } // this will fail the std::distance() precondition, which asserts on MSVC // debug builds //{ // int* p = nullptr; // auto workaround_macro = [&]() { Span s{&arr[0], p}; }; // CHECK_THROW(workaround_macro(), fail_fast); //} { auto s = Span(&arr[0], &arr[2]); ASSERT_EQ(s.Length(), 2U); ASSERT_EQ(s.data(), &arr[0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[1], 2); } { auto s = Span(&arr[0], &arr[0]); ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), &arr[0]); } { int* p = nullptr; auto s = Span(p, p); ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), SLICE_INT_PTR); } } SPAN_TEST(from_array_constructor) { int arr[5] = {1, 2, 3, 4, 5}; { Span s{arr}; ASSERT_EQ(s.Length(), 5U); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr}; ASSERT_EQ(s.Length(), 5U); ASSERT_EQ(s.data(), &arr[0]); } int arr2d[2][3] = {{1, 2, 3}, {4, 5, 6}}; #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr}; } { Span s{arr}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr2d}; ASSERT_EQ(s.Length(), 6U); ASSERT_EQ(s.data(), &arr2d[0][0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[5], 6); } { Span s{arr2d}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), &arr2d[0][0]); } { Span s{arr2d}; } #endif { Span s{&(arr2d[0]), 1}; ASSERT_EQ(s.Length(), 1U); ASSERT_EQ(s.data(), &arr2d[0]); } int arr3d[2][3][2] = {{{1, 2}, {3, 4}, {5, 6}}, {{7, 8}, {9, 10}, {11, 12}}}; #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr3d}; ASSERT_EQ(s.Length(), 12U); ASSERT_EQ(s.data(), &arr3d[0][0][0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[11], 12); } { Span s{arr3d}; ASSERT_EQ(s.Length(), 0U); ASSERT_EQ(s.data(), &arr3d[0][0][0]); } { Span s{arr3d}; } { Span s{arr3d}; ASSERT_EQ(s.Length(), 12U); ASSERT_EQ(s.data(), &arr3d[0][0][0]); ASSERT_EQ(s[0], 1); ASSERT_EQ(s[5], 6); } #endif { Span s{&arr3d[0], 1}; ASSERT_EQ(s.Length(), 1U); ASSERT_EQ(s.data(), &arr3d[0]); } { auto s = Span(arr); ASSERT_EQ(s.Length(), 5U); ASSERT_EQ(s.data(), &arr[0]); } { auto s = Span(&(arr2d[0]), 1); ASSERT_EQ(s.Length(), 1U); ASSERT_EQ(s.data(), &arr2d[0]); } { auto s = Span(&arr3d[0], 1); ASSERT_EQ(s.Length(), 1U); ASSERT_EQ(s.data(), &arr3d[0]); } } SPAN_TEST(from_dynamic_array_constructor) { double(*arr)[3][4] = new double[100][3][4]; { Span s(&arr[0][0][0], 10); ASSERT_EQ(s.Length(), 10U); ASSERT_EQ(s.data(), &arr[0][0][0]); } { auto s = Span(&arr[0][0][0], 10); ASSERT_EQ(s.Length(), 10U); ASSERT_EQ(s.data(), &arr[0][0][0]); } delete[] arr; } SPAN_TEST(from_std_array_constructor) { std::array arr = {{1, 2, 3, 4}}; { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); Span cs{arr}; ASSERT_EQ(cs.size(), narrow_cast(arr.size())); ASSERT_EQ(cs.data(), arr.data()); } { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); Span cs{arr}; ASSERT_EQ(cs.size(), narrow_cast(arr.size())); ASSERT_EQ(cs.data(), arr.data()); } #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr}; ASSERT_EQ(s.size(), 2U); ASSERT_EQ(s.data(), arr.data()); Span cs{arr}; ASSERT_EQ(cs.size(), 2U); ASSERT_EQ(cs.data(), arr.data()); } { Span s{arr}; ASSERT_EQ(s.size(), 0U); ASSERT_EQ(s.data(), arr.data()); Span cs{arr}; ASSERT_EQ(cs.size(), 0U); ASSERT_EQ(cs.data(), arr.data()); } { Span s{arr}; } { auto get_an_array = []() -> std::array { return {1, 2, 3, 4}; }; auto take_a_Span = [](Span s) { static_cast(s); }; // try to take a temporary std::array take_a_Span(get_an_array()); } #endif { auto get_an_array = []() -> std::array { return {{1, 2, 3, 4}}; }; auto take_a_Span = [](Span s) { static_cast(s); }; // try to take a temporary std::array take_a_Span(get_an_array()); } { auto s = Span(arr); ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); } } SPAN_TEST(from_const_std_array_constructor) { const std::array arr = {{1, 2, 3, 4}}; { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); } { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); } #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr}; ASSERT_EQ(s.size(), 2U); ASSERT_EQ(s.data(), arr.data()); } { Span s{arr}; ASSERT_EQ(s.size(), 0U); ASSERT_EQ(s.data(), arr.data()); } { Span s{arr}; } #endif { auto get_an_array = []() -> const std::array { return {{1, 2, 3, 4}}; }; auto take_a_Span = [](Span s) { static_cast(s); }; // try to take a temporary std::array take_a_Span(get_an_array()); } { auto s = Span(arr); ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); } } SPAN_TEST(from_std_array_const_constructor) { std::array arr = {{1, 2, 3, 4}}; { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); } { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); } #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr}; ASSERT_EQ(s.size(), 2U); ASSERT_EQ(s.data(), arr.data()); } { Span s{arr}; ASSERT_EQ(s.size(), 0U); ASSERT_EQ(s.data(), arr.data()); } { Span s{arr}; } { Span s{arr}; } #endif { auto s = Span(arr); ASSERT_EQ(s.size(), narrow_cast(arr.size())); ASSERT_EQ(s.data(), arr.data()); } } SPAN_TEST(from_mozilla_array_constructor) { mozilla::Array arr(1, 2, 3, 4); { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); Span cs{arr}; ASSERT_EQ(cs.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(cs.data(), &arr[0]); } { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); Span cs{arr}; ASSERT_EQ(cs.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(cs.data(), &arr[0]); } #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr}; ASSERT_EQ(s.size(), 2U); ASSERT_EQ(s.data(), &arr[0]); Span cs{arr}; ASSERT_EQ(cs.size(), 2U); ASSERT_EQ(cs.data(), &arr[0]); } { Span s{arr}; ASSERT_EQ(s.size(), 0U); ASSERT_EQ(s.data(), &arr[0]); Span cs{arr}; ASSERT_EQ(cs.size(), 0U); ASSERT_EQ(cs.data(), &arr[0]); } { Span s{arr}; } { auto get_an_array = []() -> mozilla::Array { return {1, 2, 3, 4}; }; auto take_a_Span = [](Span s) { static_cast(s); }; // try to take a temporary mozilla::Array take_a_Span(get_an_array()); } #endif { auto get_an_array = []() -> mozilla::Array { return {1, 2, 3, 4}; }; auto take_a_Span = [](Span s) { static_cast(s); }; // try to take a temporary mozilla::Array take_a_Span(get_an_array()); } { auto s = Span(arr); ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); } } SPAN_TEST(from_const_mozilla_array_constructor) { const mozilla::Array arr(1, 2, 3, 4); { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); } #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr}; ASSERT_EQ(s.size(), 2U); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr}; ASSERT_EQ(s.size(), 0U); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr}; } #endif #if 0 { auto get_an_array = []() -> const mozilla::Array { return { 1, 2, 3, 4 }; }; auto take_a_Span = [](Span s) { static_cast(s); }; // try to take a temporary mozilla::Array take_a_Span(get_an_array()); } #endif { auto s = Span(arr); ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); } } SPAN_TEST(from_mozilla_array_const_constructor) { mozilla::Array arr(1, 2, 3, 4); { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr}; ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); } #ifdef CONFIRM_COMPILATION_ERRORS { Span s{arr}; ASSERT_EQ(s.size(), 2U); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr}; ASSERT_EQ(s.size(), 0U); ASSERT_EQ(s.data(), &arr[0]); } { Span s{arr}; } { Span s{arr}; } #endif { auto s = Span(arr); ASSERT_EQ(s.size(), narrow_cast(arr.cend() - arr.cbegin())); ASSERT_EQ(s.data(), &arr[0]); } } SPAN_TEST(from_container_constructor) { std::vector v = {1, 2, 3}; const std::vector cv = v; { AssertSpanOfThreeInts(v); Span s{v}; ASSERT_EQ(s.size(), narrow_cast(v.size())); ASSERT_EQ(s.data(), v.data()); Span cs{v}; ASSERT_EQ(cs.size(), narrow_cast(v.size())); ASSERT_EQ(cs.data(), v.data()); } std::string str = "hello"; const std::string cstr = "hello"; { #ifdef CONFIRM_COMPILATION_ERRORS Span s{str}; ASSERT_EQ(s.size(), narrow_cast(str.size())); ASSERT_EQ(s.data(), str.data()); #endif Span cs{str}; ASSERT_EQ(cs.size(), narrow_cast(str.size())); ASSERT_EQ(cs.data(), str.data()); } { #ifdef CONFIRM_COMPILATION_ERRORS Span s{cstr}; #endif Span cs{cstr}; ASSERT_EQ(cs.size(), narrow_cast(cstr.size())); ASSERT_EQ(cs.data(), cstr.data()); } { #ifdef CONFIRM_COMPILATION_ERRORS auto get_temp_vector = []() -> std::vector { return {}; }; auto use_Span = [](Span s) { static_cast(s); }; use_Span(get_temp_vector()); #endif } { auto get_temp_vector = []() -> std::vector { return {}; }; auto use_Span = [](Span s) { static_cast(s); }; use_Span(get_temp_vector()); } { #ifdef CONFIRM_COMPILATION_ERRORS auto get_temp_string = []() -> std::string { return {}; }; auto use_Span = [](Span s) { static_cast(s); }; use_Span(get_temp_string()); #endif } { auto get_temp_string = []() -> std::string { return {}; }; auto use_Span = [](Span s) { static_cast(s); }; use_Span(get_temp_string()); } { #ifdef CONFIRM_COMPILATION_ERRORS auto get_temp_vector = []() -> const std::vector { return {}; }; auto use_Span = [](Span s) { static_cast(s); }; use_Span(get_temp_vector()); #endif } { auto get_temp_string = []() -> const std::string { return {}; }; auto use_Span = [](Span s) { static_cast(s); }; use_Span(get_temp_string()); } { #ifdef CONFIRM_COMPILATION_ERRORS std::map m; Span s{m}; #endif } { auto s = Span(v); ASSERT_EQ(s.size(), narrow_cast(v.size())); ASSERT_EQ(s.data(), v.data()); auto cs = Span(cv); ASSERT_EQ(cs.size(), narrow_cast(cv.size())); ASSERT_EQ(cs.data(), cv.data()); } } SPAN_TEST(from_xpcom_collections) { { nsTArray v; v.AppendElement(1); v.AppendElement(2); v.AppendElement(3); AssertSpanOfThreeInts(v); Span s{v}; ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); Span cs{v}; ASSERT_EQ(cs.size(), narrow_cast(v.Length())); ASSERT_EQ(cs.data(), v.Elements()); ASSERT_EQ(cs[2], 3); } { nsTArray v; v.AppendElement(1); v.AppendElement(2); v.AppendElement(3); AssertSpanOfThreeInts(v); auto s = Span(v); ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); } { AutoTArray v; v.AppendElement(1); v.AppendElement(2); v.AppendElement(3); AssertSpanOfThreeInts(v); Span s{v}; ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); Span cs{v}; ASSERT_EQ(cs.size(), narrow_cast(v.Length())); ASSERT_EQ(cs.data(), v.Elements()); ASSERT_EQ(cs[2], 3); } { AutoTArray v; v.AppendElement(1); v.AppendElement(2); v.AppendElement(3); AssertSpanOfThreeInts(v); auto s = Span(v); ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); } { FallibleTArray v; *(v.AppendElement(fallible)) = 1; *(v.AppendElement(fallible)) = 2; *(v.AppendElement(fallible)) = 3; AssertSpanOfThreeInts(v); Span s{v}; ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); Span cs{v}; ASSERT_EQ(cs.size(), narrow_cast(v.Length())); ASSERT_EQ(cs.data(), v.Elements()); ASSERT_EQ(cs[2], 3); } { FallibleTArray v; *(v.AppendElement(fallible)) = 1; *(v.AppendElement(fallible)) = 2; *(v.AppendElement(fallible)) = 3; AssertSpanOfThreeInts(v); auto s = Span(v); ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); } { nsAutoString str; str.AssignLiteral(u"abc"); AssertSpanOfThreeChar16s(str); AssertSpanOfThreeChar16sViaString(str); Span s{str.GetMutableData()}; ASSERT_EQ(s.size(), narrow_cast(str.Length())); ASSERT_EQ(s.data(), str.BeginWriting()); ASSERT_EQ(s[2], 'c'); Span cs{str}; ASSERT_EQ(cs.size(), narrow_cast(str.Length())); ASSERT_EQ(cs.data(), str.BeginReading()); ASSERT_EQ(cs[2], 'c'); } { nsAutoString str; str.AssignLiteral(u"abc"); AssertSpanOfThreeChar16s(str); AssertSpanOfThreeChar16sViaString(str); auto s = Span(str); ASSERT_EQ(s.size(), narrow_cast(str.Length())); ASSERT_EQ(s.data(), str.BeginReading()); ASSERT_EQ(s[2], 'c'); } { nsAutoCString str; str.AssignLiteral("abc"); AssertSpanOfThreeChars(str); AssertSpanOfThreeCharsViaString(str); Span cs{str}; ASSERT_EQ(cs.size(), narrow_cast(str.Length())); ASSERT_EQ(cs.data(), reinterpret_cast(str.BeginReading())); ASSERT_EQ(cs[2], 'c'); } { nsAutoCString str; str.AssignLiteral("abc"); AssertSpanOfThreeChars(str); AssertSpanOfThreeCharsViaString(str); auto s = Span(str); ASSERT_EQ(s.size(), narrow_cast(str.Length())); ASSERT_EQ(s.data(), str.BeginReading()); ASSERT_EQ(s[2], 'c'); } { nsTArray v; v.AppendElement(1); v.AppendElement(2); v.AppendElement(3); Range r(v.Elements(), v.Length()); AssertSpanOfThreeInts(r); Span s{r}; ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); Span cs{r}; ASSERT_EQ(cs.size(), narrow_cast(v.Length())); ASSERT_EQ(cs.data(), v.Elements()); ASSERT_EQ(cs[2], 3); } { nsTArray v; v.AppendElement(1); v.AppendElement(2); v.AppendElement(3); Range r(v.Elements(), v.Length()); AssertSpanOfThreeInts(r); auto s = Span(r); ASSERT_EQ(s.size(), narrow_cast(v.Length())); ASSERT_EQ(s.data(), v.Elements()); ASSERT_EQ(s[2], 3); } } SPAN_TEST(from_cstring) { { const char* str = nullptr; auto cs = MakeStringSpan(str); ASSERT_EQ(cs.size(), 0U); } { const char* str = "abc"; auto cs = MakeStringSpan(str); ASSERT_EQ(cs.size(), 3U); ASSERT_EQ(cs.data(), str); ASSERT_EQ(cs[2], 'c'); static_assert(MakeStringSpan("abc").size() == 3U); static_assert(MakeStringSpan("abc")[2] == 'c'); #ifdef CONFIRM_COMPILATION_ERRORS Span scccl("literal"); // error Span sccel; sccel = "literal"; // error cs = Span("literal"); // error #endif } { char arr[4] = {'a', 'b', 'c', 0}; auto cs = MakeStringSpan(arr); ASSERT_EQ(cs.size(), 3U); ASSERT_EQ(cs.data(), arr); ASSERT_EQ(cs[2], 'c'); cs = Span(arr); ASSERT_EQ(cs.size(), 4U); // zero terminator is part of the array span. ASSERT_EQ(cs.data(), arr); ASSERT_EQ(cs[2], 'c'); ASSERT_EQ(cs[3], '\0'); // zero terminator is part of the array span. #ifdef CONFIRM_COMPILATION_ERRORS Span scca(arr); // error Span sccca(arr); // error Span scccea; scccea = arr; // error #endif } { const char16_t* str = nullptr; auto cs = MakeStringSpan(str); ASSERT_EQ(cs.size(), 0U); } { char16_t arr[4] = {'a', 'b', 'c', 0}; const char16_t* str = arr; auto cs = MakeStringSpan(str); ASSERT_EQ(cs.size(), 3U); ASSERT_EQ(cs.data(), str); ASSERT_EQ(cs[2], 'c'); static_assert(MakeStringSpan(u"abc").size() == 3U); static_assert(MakeStringSpan(u"abc")[2] == u'c'); cs = MakeStringSpan(arr); ASSERT_EQ(cs.size(), 3U); ASSERT_EQ(cs.data(), str); ASSERT_EQ(cs[2], 'c'); cs = Span(arr); ASSERT_EQ(cs.size(), 4U); // zero terminator is part of the array span. ASSERT_EQ(cs.data(), str); ASSERT_EQ(cs[2], 'c'); ASSERT_EQ(cs[3], '\0'); // zero terminator is part of the array span. #ifdef CONFIRM_COMPILATION_ERRORS Span scca(arr); // error Span scccea; scccea = arr; // error Span scccl(u"literal"); // error Span* sccel; *sccel = u"literal"; // error cs = Span(u"literal"); // error #endif } } SPAN_TEST(from_convertible_Span_constructor){{Span avd; Span avcd = avd; static_cast(avcd); } { #ifdef CONFIRM_COMPILATION_ERRORS Span avd; Span avb = avd; static_cast(avb); #endif } #ifdef CONFIRM_COMPILATION_ERRORS { Span s; Span s2 = s; static_cast(s2); } { Span s; Span s2 = s; static_cast(s2); } { Span s; Span s2 = s; static_cast(s2); } #endif } SPAN_TEST(copy_move_and_assignment) { Span s1; ASSERT_TRUE(s1.empty()); int arr[] = {3, 4, 5}; Span s2 = arr; ASSERT_EQ(s2.Length(), 3U); ASSERT_EQ(s2.data(), &arr[0]); s2 = s1; ASSERT_TRUE(s2.empty()); auto get_temp_Span = [&]() -> Span { return {&arr[1], 2}; }; auto use_Span = [&](Span s) { ASSERT_EQ(s.Length(), 2U); ASSERT_EQ(s.data(), &arr[1]); }; use_Span(get_temp_Span()); s1 = get_temp_Span(); ASSERT_EQ(s1.Length(), 2U); ASSERT_EQ(s1.data(), &arr[1]); } SPAN_TEST(first) { int arr[5] = {1, 2, 3, 4, 5}; { Span av = arr; ASSERT_EQ(av.First<2>().Length(), 2U); ASSERT_EQ(av.First(2).Length(), 2U); } { Span av = arr; ASSERT_EQ(av.First<0>().Length(), 0U); ASSERT_EQ(av.First(0).Length(), 0U); } { Span av = arr; ASSERT_EQ(av.First<5>().Length(), 5U); ASSERT_EQ(av.First(5).Length(), 5U); } #if 0 { Span av = arr; # ifdef CONFIRM_COMPILATION_ERRORS ASSERT_EQ(av.First<6>().Length() , 6U); ASSERT_EQ(av.First<-1>().Length() , -1); # endif CHECK_THROW(av.First(6).Length(), fail_fast); } #endif { Span av; ASSERT_EQ(av.First<0>().Length(), 0U); ASSERT_EQ(av.First(0).Length(), 0U); } } SPAN_TEST(last) { int arr[5] = {1, 2, 3, 4, 5}; { Span av = arr; ASSERT_EQ(av.Last<2>().Length(), 2U); ASSERT_EQ(av.Last(2).Length(), 2U); } { Span av = arr; ASSERT_EQ(av.Last<0>().Length(), 0U); ASSERT_EQ(av.Last(0).Length(), 0U); } { Span av = arr; ASSERT_EQ(av.Last<5>().Length(), 5U); ASSERT_EQ(av.Last(5).Length(), 5U); } #if 0 { Span av = arr; # ifdef CONFIRM_COMPILATION_ERRORS ASSERT_EQ(av.Last<6>().Length() , 6U); # endif CHECK_THROW(av.Last(6).Length(), fail_fast); } #endif { Span av; ASSERT_EQ(av.Last<0>().Length(), 0U); ASSERT_EQ(av.Last(0).Length(), 0U); } } SPAN_TEST(from_to) { int arr[5] = {1, 2, 3, 4, 5}; { Span av = arr; ASSERT_EQ(av.From(3).Length(), 2U); ASSERT_EQ(av.From(2)[1], 4); } { Span av = arr; ASSERT_EQ(av.From(5).Length(), 0U); } { Span av = arr; ASSERT_EQ(av.From(0).Length(), 5U); } { Span av = arr; ASSERT_EQ(av.To(3).Length(), 3U); ASSERT_EQ(av.To(3)[1], 2); } { Span av = arr; ASSERT_EQ(av.To(0).Length(), 0U); } { Span av = arr; ASSERT_EQ(av.To(5).Length(), 5U); } { Span av = arr; ASSERT_EQ(av.FromTo(1, 4).Length(), 3U); ASSERT_EQ(av.FromTo(1, 4)[1], 3); } { Span av = arr; ASSERT_EQ(av.FromTo(2, 2).Length(), 0U); } { Span av = arr; ASSERT_EQ(av.FromTo(0, 5).Length(), 5U); } } SPAN_TEST(Subspan) { int arr[5] = {1, 2, 3, 4, 5}; { Span av = arr; ASSERT_EQ((av.Subspan<2, 2>().Length()), 2U); ASSERT_EQ(av.Subspan(2, 2).Length(), 2U); ASSERT_EQ(av.Subspan(2, 3).Length(), 3U); } { Span av = arr; ASSERT_EQ((av.Subspan<0, 0>().Length()), 0U); ASSERT_EQ(av.Subspan(0, 0).Length(), 0U); } { Span av = arr; ASSERT_EQ((av.Subspan<0, 5>().Length()), 5U); ASSERT_EQ(av.Subspan(0, 5).Length(), 5U); CHECK_THROW(av.Subspan(0, 6).Length(), fail_fast); CHECK_THROW(av.Subspan(1, 5).Length(), fail_fast); } { Span av = arr; ASSERT_EQ((av.Subspan<4, 0>().Length()), 0U); ASSERT_EQ(av.Subspan(4, 0).Length(), 0U); ASSERT_EQ(av.Subspan(5, 0).Length(), 0U); CHECK_THROW(av.Subspan(6, 0).Length(), fail_fast); } { Span av; ASSERT_EQ((av.Subspan<0, 0>().Length()), 0U); ASSERT_EQ(av.Subspan(0, 0).Length(), 0U); CHECK_THROW((av.Subspan<1, 0>().Length()), fail_fast); } { Span av; ASSERT_EQ(av.Subspan(0).Length(), 0U); CHECK_THROW(av.Subspan(1).Length(), fail_fast); } { Span av = arr; ASSERT_EQ(av.Subspan(0).Length(), 5U); ASSERT_EQ(av.Subspan(1).Length(), 4U); ASSERT_EQ(av.Subspan(4).Length(), 1U); ASSERT_EQ(av.Subspan(5).Length(), 0U); CHECK_THROW(av.Subspan(6).Length(), fail_fast); auto av2 = av.Subspan(1); for (int i = 0; i < 4; ++i) ASSERT_EQ(av2[i], i + 2); } { Span av = arr; ASSERT_EQ(av.Subspan(0).Length(), 5U); ASSERT_EQ(av.Subspan(1).Length(), 4U); ASSERT_EQ(av.Subspan(4).Length(), 1U); ASSERT_EQ(av.Subspan(5).Length(), 0U); CHECK_THROW(av.Subspan(6).Length(), fail_fast); auto av2 = av.Subspan(1); for (int i = 0; i < 4; ++i) ASSERT_EQ(av2[i], i + 2); } } SPAN_TEST(at_call) { int arr[4] = {1, 2, 3, 4}; { Span s = arr; ASSERT_EQ(s.at(0), 1); CHECK_THROW(s.at(5), fail_fast); } { int arr2d[2] = {1, 6}; Span s = arr2d; ASSERT_EQ(s.at(0), 1); ASSERT_EQ(s.at(1), 6); CHECK_THROW(s.at(2), fail_fast); } } SPAN_TEST(operator_function_call) { int arr[4] = {1, 2, 3, 4}; { Span s = arr; ASSERT_EQ(s(0), 1); CHECK_THROW(s(5), fail_fast); } { int arr2d[2] = {1, 6}; Span s = arr2d; ASSERT_EQ(s(0), 1); ASSERT_EQ(s(1), 6); CHECK_THROW(s(2), fail_fast); } } SPAN_TEST(iterator_default_init) { Span::iterator it1; Span::iterator it2; ASSERT_EQ(it1, it2); } SPAN_TEST(const_iterator_default_init) { Span::const_iterator it1; Span::const_iterator it2; ASSERT_EQ(it1, it2); } SPAN_TEST(iterator_conversions) { Span::iterator badIt; Span::const_iterator badConstIt; ASSERT_EQ(badIt, badConstIt); int a[] = {1, 2, 3, 4}; Span s = a; auto it = s.begin(); auto cit = s.cbegin(); ASSERT_EQ(it, cit); ASSERT_EQ(cit, it); Span::const_iterator cit2 = it; ASSERT_EQ(cit2, cit); Span::const_iterator cit3 = it + 4; ASSERT_EQ(cit3, s.cend()); } SPAN_TEST(iterator_comparisons) { int a[] = {1, 2, 3, 4}; { Span s = a; Span::iterator it = s.begin(); auto it2 = it + 1; Span::const_iterator cit = s.cbegin(); ASSERT_EQ(it, cit); ASSERT_EQ(cit, it); ASSERT_EQ(it, it); ASSERT_EQ(cit, cit); ASSERT_EQ(cit, s.begin()); ASSERT_EQ(s.begin(), cit); ASSERT_EQ(s.cbegin(), cit); ASSERT_EQ(it, s.begin()); ASSERT_EQ(s.begin(), it); ASSERT_NE(it, it2); ASSERT_NE(it2, it); ASSERT_NE(it, s.end()); ASSERT_NE(it2, s.end()); ASSERT_NE(s.end(), it); ASSERT_NE(it2, cit); ASSERT_NE(cit, it2); ASSERT_LT(it, it2); ASSERT_LE(it, it2); ASSERT_LE(it2, s.end()); ASSERT_LT(it, s.end()); ASSERT_LE(it, cit); ASSERT_LE(cit, it); ASSERT_LT(cit, it2); ASSERT_LE(cit, it2); ASSERT_LT(cit, s.end()); ASSERT_LE(cit, s.end()); ASSERT_GT(it2, it); ASSERT_GE(it2, it); ASSERT_GT(s.end(), it2); ASSERT_GE(s.end(), it2); ASSERT_GT(it2, cit); ASSERT_GE(it2, cit); } } SPAN_TEST(begin_end) { { int a[] = {1, 2, 3, 4}; Span s = a; Span::iterator it = s.begin(); Span::iterator it2 = std::begin(s); ASSERT_EQ(it, it2); it = s.end(); it2 = std::end(s); ASSERT_EQ(it, it2); } { int a[] = {1, 2, 3, 4}; Span s = a; auto it = s.begin(); auto first = it; ASSERT_EQ(it, first); ASSERT_EQ(*it, 1); auto beyond = s.end(); ASSERT_NE(it, beyond); CHECK_THROW(*beyond, fail_fast); ASSERT_EQ(beyond - first, 4U); ASSERT_EQ(first - first, 0U); ASSERT_EQ(beyond - beyond, 0U); ++it; ASSERT_EQ(it - first, 1U); ASSERT_EQ(*it, 2); *it = 22; ASSERT_EQ(*it, 22); ASSERT_EQ(beyond - it, 3U); it = first; ASSERT_EQ(it, first); while (it != s.end()) { *it = 5; ++it; } ASSERT_EQ(it, beyond); ASSERT_EQ(it - beyond, 0U); for (auto& n : s) { ASSERT_EQ(n, 5); } } } SPAN_TEST(cbegin_cend) { #if 0 { int a[] = { 1, 2, 3, 4 }; Span s = a; Span::const_iterator cit = s.cbegin(); Span::const_iterator cit2 = std::cbegin(s); ASSERT_EQ(cit , cit2); cit = s.cend(); cit2 = std::cend(s); ASSERT_EQ(cit , cit2); } #endif { int a[] = {1, 2, 3, 4}; Span s = a; auto it = s.cbegin(); auto first = it; ASSERT_EQ(it, first); ASSERT_EQ(*it, 1); auto beyond = s.cend(); ASSERT_NE(it, beyond); CHECK_THROW(*beyond, fail_fast); ASSERT_EQ(beyond - first, 4U); ASSERT_EQ(first - first, 0U); ASSERT_EQ(beyond - beyond, 0U); ++it; ASSERT_EQ(it - first, 1U); ASSERT_EQ(*it, 2); ASSERT_EQ(beyond - it, 3U); int last = 0; it = first; ASSERT_EQ(it, first); while (it != s.cend()) { ASSERT_EQ(*it, last + 1); last = *it; ++it; } ASSERT_EQ(it, beyond); ASSERT_EQ(it - beyond, 0U); } } SPAN_TEST(rbegin_rend) { { int a[] = {1, 2, 3, 4}; Span s = a; auto it = s.rbegin(); auto first = it; ASSERT_EQ(it, first); ASSERT_EQ(*it, 4); auto beyond = s.rend(); ASSERT_NE(it, beyond); CHECK_THROW(*beyond, fail_fast); ASSERT_EQ(beyond - first, 4U); ASSERT_EQ(first - first, 0U); ASSERT_EQ(beyond - beyond, 0U); ++it; ASSERT_EQ(it - first, 1U); ASSERT_EQ(*it, 3); *it = 22; ASSERT_EQ(*it, 22); ASSERT_EQ(beyond - it, 3U); it = first; ASSERT_EQ(it, first); while (it != s.rend()) { *it = 5; ++it; } ASSERT_EQ(it, beyond); ASSERT_EQ(it - beyond, 0U); for (auto& n : s) { ASSERT_EQ(n, 5); } } } SPAN_TEST(crbegin_crend) { { int a[] = {1, 2, 3, 4}; Span s = a; auto it = s.crbegin(); auto first = it; ASSERT_EQ(it, first); ASSERT_EQ(*it, 4); auto beyond = s.crend(); ASSERT_NE(it, beyond); CHECK_THROW(*beyond, fail_fast); ASSERT_EQ(beyond - first, 4U); ASSERT_EQ(first - first, 0U); ASSERT_EQ(beyond - beyond, 0U); ++it; ASSERT_EQ(it - first, 1U); ASSERT_EQ(*it, 3); ASSERT_EQ(beyond - it, 3U); it = first; ASSERT_EQ(it, first); int last = 5; while (it != s.crend()) { ASSERT_EQ(*it, last - 1); last = *it; ++it; } ASSERT_EQ(it, beyond); ASSERT_EQ(it - beyond, 0U); } } SPAN_TEST(comparison_operators) { { Span s1 = nullptr; Span s2 = nullptr; ASSERT_EQ(s1, s2); ASSERT_FALSE(s1 != s2); ASSERT_FALSE(s1 < s2); ASSERT_LE(s1, s2); ASSERT_FALSE(s1 > s2); ASSERT_GE(s1, s2); ASSERT_EQ(s2, s1); ASSERT_FALSE(s2 != s1); ASSERT_FALSE(s2 < s1); ASSERT_LE(s2, s1); ASSERT_FALSE(s2 > s1); ASSERT_GE(s2, s1); } { int arr[] = {2, 1}; Span s1 = arr; Span s2 = arr; ASSERT_EQ(s1, s2); ASSERT_FALSE(s1 != s2); ASSERT_FALSE(s1 < s2); ASSERT_LE(s1, s2); ASSERT_FALSE(s1 > s2); ASSERT_GE(s1, s2); ASSERT_EQ(s2, s1); ASSERT_FALSE(s2 != s1); ASSERT_FALSE(s2 < s1); ASSERT_LE(s2, s1); ASSERT_FALSE(s2 > s1); ASSERT_GE(s2, s1); } { int arr[] = {2, 1}; // bigger Span s1 = nullptr; Span s2 = arr; ASSERT_NE(s1, s2); ASSERT_NE(s2, s1); ASSERT_NE(s1, s2); ASSERT_NE(s2, s1); ASSERT_LT(s1, s2); ASSERT_FALSE(s2 < s1); ASSERT_LE(s1, s2); ASSERT_FALSE(s2 <= s1); ASSERT_GT(s2, s1); ASSERT_FALSE(s1 > s2); ASSERT_GE(s2, s1); ASSERT_FALSE(s1 >= s2); } { int arr1[] = {1, 2}; int arr2[] = {1, 2}; Span s1 = arr1; Span s2 = arr2; ASSERT_EQ(s1, s2); ASSERT_FALSE(s1 != s2); ASSERT_FALSE(s1 < s2); ASSERT_LE(s1, s2); ASSERT_FALSE(s1 > s2); ASSERT_GE(s1, s2); ASSERT_EQ(s2, s1); ASSERT_FALSE(s2 != s1); ASSERT_FALSE(s2 < s1); ASSERT_LE(s2, s1); ASSERT_FALSE(s2 > s1); ASSERT_GE(s2, s1); } { int arr[] = {1, 2, 3}; AssertSpanOfThreeInts(arr); Span s1 = {&arr[0], 2}; // shorter Span s2 = arr; // longer ASSERT_NE(s1, s2); ASSERT_NE(s2, s1); ASSERT_NE(s1, s2); ASSERT_NE(s2, s1); ASSERT_LT(s1, s2); ASSERT_FALSE(s2 < s1); ASSERT_LE(s1, s2); ASSERT_FALSE(s2 <= s1); ASSERT_GT(s2, s1); ASSERT_FALSE(s1 > s2); ASSERT_GE(s2, s1); ASSERT_FALSE(s1 >= s2); } { int arr1[] = {1, 2}; // smaller int arr2[] = {2, 1}; // bigger Span s1 = arr1; Span s2 = arr2; ASSERT_NE(s1, s2); ASSERT_NE(s2, s1); ASSERT_NE(s1, s2); ASSERT_NE(s2, s1); ASSERT_LT(s1, s2); ASSERT_FALSE(s2 < s1); ASSERT_LE(s1, s2); ASSERT_FALSE(s2 <= s1); ASSERT_GT(s2, s1); ASSERT_FALSE(s1 > s2); ASSERT_GE(s2, s1); ASSERT_FALSE(s1 >= s2); } } SPAN_TEST(as_bytes) { int a[] = {1, 2, 3, 4}; { Span s = a; ASSERT_EQ(s.Length(), 4U); Span bs = AsBytes(s); ASSERT_EQ(static_cast(bs.data()), static_cast(s.data())); ASSERT_EQ(bs.Length(), s.LengthBytes()); } { Span s; auto bs = AsBytes(s); ASSERT_EQ(bs.Length(), s.Length()); ASSERT_EQ(bs.Length(), 0U); ASSERT_EQ(bs.size_bytes(), 0U); ASSERT_EQ(static_cast(bs.data()), static_cast(s.data())); ASSERT_EQ(bs.data(), reinterpret_cast(SLICE_INT_PTR)); } { Span s = a; auto bs = AsBytes(s); ASSERT_EQ(static_cast(bs.data()), static_cast(s.data())); ASSERT_EQ(bs.Length(), s.LengthBytes()); } } SPAN_TEST(as_writable_bytes) { int a[] = {1, 2, 3, 4}; { #ifdef CONFIRM_COMPILATION_ERRORS // you should not be able to get writeable bytes for const objects Span s = a; ASSERT_EQ(s.Length(), 4U); Span bs = AsWritableBytes(s); ASSERT_EQ(static_cast(bs.data()), static_cast(s.data())); ASSERT_EQ(bs.Length(), s.LengthBytes()); #endif } { Span s; auto bs = AsWritableBytes(s); ASSERT_EQ(bs.Length(), s.Length()); ASSERT_EQ(bs.Length(), 0U); ASSERT_EQ(bs.size_bytes(), 0U); ASSERT_EQ(static_cast(bs.data()), static_cast(s.data())); ASSERT_EQ(bs.data(), reinterpret_cast(SLICE_INT_PTR)); } { Span s = a; auto bs = AsWritableBytes(s); ASSERT_EQ(static_cast(bs.data()), static_cast(s.data())); ASSERT_EQ(bs.Length(), s.LengthBytes()); } } SPAN_TEST(as_chars) { const uint8_t a[] = {1, 2, 3, 4}; Span u = Span(a); Span c = AsChars(u); ASSERT_EQ(static_cast(u.data()), static_cast(c.data())); ASSERT_EQ(u.size(), c.size()); } SPAN_TEST(as_writable_chars) { uint8_t a[] = {1, 2, 3, 4}; Span u = Span(a); Span c = AsWritableChars(u); ASSERT_EQ(static_cast(u.data()), static_cast(c.data())); ASSERT_EQ(u.size(), c.size()); } SPAN_TEST(fixed_size_conversions) { int arr[] = {1, 2, 3, 4}; // converting to an Span from an equal size array is ok Span s4 = arr; ASSERT_EQ(s4.Length(), 4U); // converting to dynamic_range is always ok { Span s = s4; ASSERT_EQ(s.Length(), s4.Length()); static_cast(s); } // initialization or assignment to static Span that REDUCES size is NOT ok #ifdef CONFIRM_COMPILATION_ERRORS { Span s = arr; } { Span s2 = s4; static_cast(s2); } #endif #if 0 // even when done dynamically { Span s = arr; auto f = [&]() { Span s2 = s; static_cast(s2); }; CHECK_THROW(f(), fail_fast); } #endif // but doing so explicitly is ok // you can convert statically { Span s2 = {arr, 2}; static_cast(s2); } { Span s1 = s4.First<1>(); static_cast(s1); } // ...or dynamically { // NB: implicit conversion to Span from Span Span s1 = s4.First(1); static_cast(s1); } #if 0 // initialization or assignment to static Span that requires size INCREASE is not ok. int arr2[2] = {1, 2}; #endif #ifdef CONFIRM_COMPILATION_ERRORS { Span s3 = arr2; } { Span s2 = arr2; Span s4a = s2; } #endif #if 0 { auto f = [&]() { Span _s4 = {arr2, 2}; static_cast(_s4); }; CHECK_THROW(f(), fail_fast); } // this should fail - we are trying to assign a small dynamic Span to a fixed_size larger one Span av = arr2; auto f = [&]() { Span _s4 = av; static_cast(_s4); }; CHECK_THROW(f(), fail_fast); #endif } #if 0 SPAN_TEST(interop_with_std_regex) { char lat[] = { '1', '2', '3', '4', '5', '6', 'E', 'F', 'G' }; Span s = lat; auto f_it = s.begin() + 7; std::match_results::iterator> match; std::regex_match(s.begin(), s.end(), match, std::regex(".*")); ASSERT_EQ(match.ready()); ASSERT_TRUE(!match.empty()); ASSERT_TRUE(match[0].matched); ASSERT_TRUE(match[0].first , s.begin()); ASSERT_EQ(match[0].second , s.end()); std::regex_search(s.begin(), s.end(), match, std::regex("F")); ASSERT_TRUE(match.ready()); ASSERT_TRUE(!match.empty()); ASSERT_TRUE(match[0].matched); ASSERT_EQ(match[0].first , f_it); ASSERT_EQ(match[0].second , (f_it + 1)); } SPAN_TEST(interop_with_gsl_at) { int arr[5] = { 1, 2, 3, 4, 5 }; Span s{ arr }; ASSERT_EQ(at(s, 0) , 1 ); ASSERT_EQ(at(s, 1) , 2U); } #endif SPAN_TEST(default_constructible) { ASSERT_TRUE((std::is_default_constructible>::value)); ASSERT_TRUE((std::is_default_constructible>::value)); ASSERT_TRUE((!std::is_default_constructible>::value)); } SPAN_TEST(type_inference) { static constexpr int arr[5] = {1, 2, 3, 4, 5}; constexpr auto s = Span{arr}; static_assert(std::is_same_v, decltype(s)>); static_assert(arr == s.Elements()); } SPAN_TEST(split_at_dynamic_with_dynamic_extent) { static constexpr int arr[5] = {1, 2, 3, 4, 5}; constexpr Span s = Span{arr}; { // Split at begin. constexpr auto splitAt0Result = s.SplitAt(0); static_assert( std::is_same_v, decltype(splitAt0Result.first)>); static_assert( std::is_same_v, decltype(splitAt0Result.second)>); ASSERT_EQ(s.Elements(), splitAt0Result.second.Elements()); ASSERT_EQ(0u, splitAt0Result.first.Length()); ASSERT_EQ(5u, splitAt0Result.second.Length()); } { // Split at end. constexpr auto splitAt5Result = s.SplitAt(s.Length()); static_assert( std::is_same_v, decltype(splitAt5Result.first)>); static_assert( std::is_same_v, decltype(splitAt5Result.second)>); ASSERT_EQ(s.Elements(), splitAt5Result.first.Elements()); ASSERT_EQ(5u, splitAt5Result.first.Length()); ASSERT_EQ(0u, splitAt5Result.second.Length()); } { // Split inside. constexpr auto splitAt3Result = s.SplitAt(3); static_assert( std::is_same_v, decltype(splitAt3Result.first)>); static_assert( std::is_same_v, decltype(splitAt3Result.second)>); ASSERT_EQ(s.Elements(), splitAt3Result.first.Elements()); ASSERT_EQ(s.Elements() + 3, splitAt3Result.second.Elements()); ASSERT_EQ(3u, splitAt3Result.first.Length()); ASSERT_EQ(2u, splitAt3Result.second.Length()); } } SPAN_TEST(split_at_dynamic_with_static_extent) { static constexpr int arr[5] = {1, 2, 3, 4, 5}; constexpr auto s = Span{arr}; { // Split at begin. constexpr auto splitAt0Result = s.SplitAt(0); static_assert( std::is_same_v, decltype(splitAt0Result.first)>); static_assert( std::is_same_v, decltype(splitAt0Result.second)>); ASSERT_EQ(s.Elements(), splitAt0Result.second.Elements()); } { // Split at end. constexpr auto splitAt5Result = s.SplitAt(s.Length()); static_assert( std::is_same_v, decltype(splitAt5Result.first)>); static_assert( std::is_same_v, decltype(splitAt5Result.second)>); ASSERT_EQ(s.Elements(), splitAt5Result.first.Elements()); } { // Split inside. constexpr auto splitAt3Result = s.SplitAt(3); static_assert( std::is_same_v, decltype(splitAt3Result.first)>); static_assert( std::is_same_v, decltype(splitAt3Result.second)>); ASSERT_EQ(s.Elements(), splitAt3Result.first.Elements()); ASSERT_EQ(s.Elements() + 3, splitAt3Result.second.Elements()); } } SPAN_TEST(split_at_static) { static constexpr int arr[5] = {1, 2, 3, 4, 5}; constexpr auto s = Span{arr}; // Split at begin. constexpr auto splitAt0Result = s.SplitAt<0>(); static_assert( std::is_same_v, decltype(splitAt0Result.first)>); static_assert( std::is_same_v, decltype(splitAt0Result.second)>); static_assert(splitAt0Result.second.Elements() == s.Elements()); // Split at end. constexpr auto splitAt5Result = s.SplitAt(); static_assert(std::is_same_v, decltype(splitAt5Result.first)>); static_assert( std::is_same_v, decltype(splitAt5Result.second)>); static_assert(splitAt5Result.first.Elements() == s.Elements()); // Split inside. constexpr auto splitAt3Result = s.SplitAt<3>(); static_assert( std::is_same_v, decltype(splitAt3Result.first)>); static_assert( std::is_same_v, decltype(splitAt3Result.second)>); static_assert(splitAt3Result.first.Elements() == s.Elements()); static_assert(splitAt3Result.second.Elements() == s.Elements() + 3); } SPAN_TEST(as_const_dynamic) { static int arr[5] = {1, 2, 3, 4, 5}; auto span = Span{arr, 5}; auto constSpan = span.AsConst(); static_assert(std::is_same_v, decltype(constSpan)>); } SPAN_TEST(as_const_static) { { static constexpr int constArr[5] = {1, 2, 3, 4, 5}; constexpr auto span = Span{constArr}; // is already a Span constexpr auto constSpan = span.AsConst(); static_assert( std::is_same_v, decltype(constSpan)>); } { static int arr[5] = {1, 2, 3, 4, 5}; auto span = Span{arr}; auto constSpan = span.AsConst(); static_assert(std::is_same_v, decltype(constSpan)>); } } SPAN_TEST(construct_from_iterators_dynamic) { const int constArr[5] = {1, 2, 3, 4, 5}; auto constSpan = Span{constArr}; // const from const { const auto wholeSpan = Span{constSpan.cbegin(), constSpan.cend()}; static_assert(std::is_same_v>); ASSERT_TRUE(constSpan == wholeSpan); const auto emptyBeginSpan = Span{constSpan.cbegin(), constSpan.cbegin()}; ASSERT_TRUE(emptyBeginSpan.IsEmpty()); const auto emptyEndSpan = Span{constSpan.cend(), constSpan.cend()}; ASSERT_TRUE(emptyEndSpan.IsEmpty()); const auto subSpan = Span{constSpan.cbegin() + 1, constSpan.cend() - 1}; ASSERT_EQ(constSpan.Length() - 2, subSpan.Length()); ASSERT_EQ(constSpan.Elements() + 1, subSpan.Elements()); } int arr[5] = {1, 2, 3, 4, 5}; auto span = Span{arr}; // const from non-const { const auto wholeSpan = Span{span.cbegin(), span.cend()}; static_assert(std::is_same_v>); // XXX Can't use span == wholeSpan because of difference in constness. ASSERT_EQ(span.Elements(), wholeSpan.Elements()); ASSERT_EQ(span.Length(), wholeSpan.Length()); const auto emptyBeginSpan = Span{span.cbegin(), span.cbegin()}; ASSERT_TRUE(emptyBeginSpan.IsEmpty()); const auto emptyEndSpan = Span{span.cend(), span.cend()}; ASSERT_TRUE(emptyEndSpan.IsEmpty()); const auto subSpan = Span{span.cbegin() + 1, span.cend() - 1}; ASSERT_EQ(span.Length() - 2, subSpan.Length()); ASSERT_EQ(span.Elements() + 1, subSpan.Elements()); } // non-const from non-const { const auto wholeSpan = Span{span.begin(), span.end()}; static_assert(std::is_same_v>); ASSERT_TRUE(span == wholeSpan); const auto emptyBeginSpan = Span{span.begin(), span.begin()}; ASSERT_TRUE(emptyBeginSpan.IsEmpty()); const auto emptyEndSpan = Span{span.end(), span.end()}; ASSERT_TRUE(emptyEndSpan.IsEmpty()); const auto subSpan = Span{span.begin() + 1, span.end() - 1}; ASSERT_EQ(span.Length() - 2, subSpan.Length()); } } SPAN_TEST(construct_from_iterators_static) { static constexpr int arr[5] = {1, 2, 3, 4, 5}; constexpr auto constSpan = Span{arr}; // const { const auto wholeSpan = Span{constSpan.cbegin(), constSpan.cend()}; static_assert(std::is_same_v>); ASSERT_TRUE(constSpan == wholeSpan); const auto emptyBeginSpan = Span{constSpan.cbegin(), constSpan.cbegin()}; ASSERT_TRUE(emptyBeginSpan.IsEmpty()); const auto emptyEndSpan = Span{constSpan.cend(), constSpan.cend()}; ASSERT_TRUE(emptyEndSpan.IsEmpty()); const auto subSpan = Span{constSpan.cbegin() + 1, constSpan.cend() - 1}; ASSERT_EQ(constSpan.Length() - 2, subSpan.Length()); ASSERT_EQ(constSpan.Elements() + 1, subSpan.Elements()); } } SPAN_TEST(construct_from_container_with_type_deduction) { std::vector vec = {1, 2, 3, 4, 5}; // from const { const auto& constVecRef = vec; auto span = Span{constVecRef}; static_assert(std::is_same_v>); } // from non-const { auto span = Span{vec}; static_assert(std::is_same_v>); } }