// Copyright 2017 The Abseil Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "absl/types/span.h"
#include <array>
#include <initializer_list>
#include <numeric>
#include <stdexcept>
#include <string>
#include <type_traits>
#include <vector>
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include "absl/base/attributes.h"
#include "absl/base/config.h"
#include "absl/base/internal/exception_testing.h"
#include "absl/base/options.h"
#include "absl/container/fixed_array.h"
#include "absl/container/inlined_vector.h"
#include "absl/hash/hash_testing.h"
#include "absl/strings/str_cat.h"
namespace {
MATCHER_P(DataIs, data,
absl::StrCat("data() ", negation ? "isn't " : "is ",
testing::PrintToString(data))) {
return arg.data() == data;
}
template <typename T>
auto SpanIs(T data, size_t size)
-> decltype(testing::AllOf(DataIs(data), testing::SizeIs(size))) {
return testing::AllOf(DataIs(data), testing::SizeIs(size));
}
template <typename Container>
auto SpanIs(const Container& c) -> decltype(SpanIs(c.data(), c.size())) {
return SpanIs(c.data(), c.size());
}
std::vector<int> MakeRamp(int len, int offset = 0) {
std::vector<int> v(len);
std::iota(v.begin(), v.end(), offset);
return v;
}
TEST(IntSpan, EmptyCtors) {
absl::Span<int> s;
EXPECT_THAT(s, SpanIs(nullptr, 0));
}
TEST(IntSpan, PtrLenCtor) {
int a[] = {1, 2, 3};
absl::Span<int> s(&a[0], 2);
EXPECT_THAT(s, SpanIs(a, 2));
}
TEST(IntSpan, ArrayCtor) {
int a[] = {1, 2, 3};
absl::Span<int> s(a);
EXPECT_THAT(s, SpanIs(a, 3));
EXPECT_TRUE((std::is_constructible<absl::Span<const int>, int[3]>::value));
EXPECT_TRUE(
(std::is_constructible<absl::Span<const int>, const int[3]>::value));
EXPECT_FALSE((std::is_constructible<absl::Span<int>, const int[3]>::value));
EXPECT_TRUE((std::is_convertible<int[3], absl::Span<const int>>::value));
EXPECT_TRUE(
(std::is_convertible<const int[3], absl::Span<const int>>::value));
}
template <typename T>
void TakesGenericSpan(absl::Span<T>) {}
TEST(IntSpan, ContainerCtor) {
std::vector<int> empty;
absl::Span<int> s_empty(empty);
EXPECT_THAT(s_empty, SpanIs(empty));
std::vector<int> filled{1, 2, 3};
absl::Span<int> s_filled(filled);
EXPECT_THAT(s_filled, SpanIs(filled));
absl::Span<int> s_from_span(filled);
EXPECT_THAT(s_from_span, SpanIs(s_filled));
absl::Span<const int> const_filled = filled;
EXPECT_THAT(const_filled, SpanIs(filled));
absl::Span<const int> const_from_span = s_filled;
EXPECT_THAT(const_from_span, SpanIs(s_filled));
EXPECT_TRUE(
(std::is_convertible<std::vector<int>&, absl::Span<const int>>::value));
EXPECT_TRUE(
(std::is_convertible<absl::Span<int>&, absl::Span<const int>>::value));
TakesGenericSpan(absl::Span<int>(filled));
}
// A struct supplying shallow data() const.
struct ContainerWithShallowConstData {
std::vector<int> storage;
int* data() const { return const_cast<int*>(storage.data()); }
int size() const { return storage.size(); }
};
TEST(IntSpan, ShallowConstness) {
const ContainerWithShallowConstData c{MakeRamp(20)};
absl::Span<int> s(
c); // We should be able to do this even though data() is const.
s[0] = -1;
EXPECT_EQ(c.storage[0], -1);
}
TEST(CharSpan, StringCtor) {
std::string empty = "";
absl::Span<char> s_empty(empty);
EXPECT_THAT(s_empty, SpanIs(empty));
std::string abc = "abc";
absl::Span<char> s_abc(abc);
EXPECT_THAT(s_abc, SpanIs(abc));
absl::Span<const char> s_const_abc = abc;
EXPECT_THAT(s_const_abc, SpanIs(abc));
EXPECT_FALSE((std::is_constructible<absl::Span<int>, std::string>::value));
EXPECT_FALSE(
(std::is_constructible<absl::Span<const int>, std::string>::value));
EXPECT_TRUE(
(std::is_convertible<std::string, absl::Span<const char>>::value));
}
TEST(IntSpan, FromConstPointer) {
EXPECT_TRUE((std::is_constructible<absl::Span<const int* const>,
std::vector<int*>>::value));
EXPECT_TRUE((std::is_constructible<absl::Span<const int* const>,
std::vector<const int*>>::value));
EXPECT_FALSE((
std::is_constructible<absl::Span<const int*>, std::vector<int*>>::value));
EXPECT_FALSE((
std::is_constructible<absl::Span<int*>, std::vector<const int*>>::value));
}
struct TypeWithMisleadingData {
int& data() { return i; }
int size() { return 1; }
int i;
};
struct TypeWithMisleadingSize {
int* data() { return &i; }
const char* size() { return "1"; }
int i;
};
TEST(IntSpan, EvilTypes) {
EXPECT_FALSE(
(std::is_constructible<absl::Span<int>, TypeWithMisleadingData&>::value));
EXPECT_FALSE(
(std::is_constructible<absl::Span<int>, TypeWithMisleadingSize&>::value));
}
struct Base {
int* data() { return &i; }
int size() { return 1; }
int i;
};
struct Derived : Base {};
TEST(IntSpan, SpanOfDerived) {
EXPECT_TRUE((std::is_constructible<absl::Span<int>, Base&>::value));
EXPECT_TRUE((std::is_constructible<absl::Span<int>, Derived&>::value));
EXPECT_FALSE(
(std::is_constructible<absl::Span<Base>, std::vector<Derived>>::value));
}
void TestInitializerList(absl::Span<const int> s, const std::vector<int>& v) {
EXPECT_TRUE(absl::equal(s.begin(), s.end(), v.begin(), v.end()));
}
TEST(ConstIntSpan, InitializerListConversion) {
TestInitializerList({}, {});
TestInitializerList({1}, {1});
TestInitializerList({1, 2, 3}, {1, 2, 3});
EXPECT_FALSE((std::is_constructible<absl::Span<int>,
std::initializer_list<int>>::value));
EXPECT_FALSE((
std::is_convertible<absl::Span<int>, std::initializer_list<int>>::value));
}
TEST(IntSpan, Data) {
int i;
absl::Span<int> s(&i, 1);
EXPECT_EQ(&i, s.data());
}
TEST(IntSpan, SizeLengthEmpty) {
absl::Span<int> empty;
EXPECT_EQ(empty.size(), 0);
EXPECT_TRUE(empty.empty());
EXPECT_EQ(empty.size(), empty.length());
auto v = MakeRamp(10);
absl::Span<int> s(v);
EXPECT_EQ(s.size(), 10);
EXPECT_FALSE(s.empty());
EXPECT_EQ(s.size(), s.length());
}
TEST(IntSpan, ElementAccess) {
auto v = MakeRamp(10);
absl::Span<int> s(v);
for (int i = 0; i < s.size(); ++i) {
EXPECT_EQ(s[i], s.at(i));
}
EXPECT_EQ(s.front(), s[0]);
EXPECT_EQ(s.back(), s[9]);
#if !defined(NDEBUG) || ABSL_OPTION_HARDENED
EXPECT_DEATH_IF_SUPPORTED(s[-1], "");
EXPECT_DEATH_IF_SUPPORTED(s[10], "");
#endif
}
TEST(IntSpan, AtThrows) {
auto v = MakeRamp(10);
absl::Span<int> s(v);
EXPECT_EQ(s.at(9), 9);
ABSL_BASE_INTERNAL_EXPECT_FAIL(s.at(10), std::out_of_range,
"failed bounds check");
}
TEST(IntSpan, RemovePrefixAndSuffix) {
auto v = MakeRamp(20, 1);
absl::Span<int> s(v);
EXPECT_EQ(s.size(), 20);
s.remove_suffix(0);
s.remove_prefix(0);
EXPECT_EQ(s.size(), 20);
s.remove_prefix(1);
EXPECT_EQ(s.size(), 19);
EXPECT_EQ(s[0], 2);
s.remove_suffix(1);
EXPECT_EQ(s.size(), 18);
EXPECT_EQ(s.back(), 19);
s.remove_prefix(7);
EXPECT_EQ(s.size(), 11);
EXPECT_EQ(s[0], 9);
s.remove_suffix(11);
EXPECT_EQ(s.size(), 0);
EXPECT_EQ(v, MakeRamp(20, 1));
#if !defined(NDEBUG) || ABSL_OPTION_HARDENED
absl::Span<int> prefix_death(v);
EXPECT_DEATH_IF_SUPPORTED(prefix_death.remove_prefix(21), "");
absl::Span<int> suffix_death(v);
EXPECT_DEATH_IF_SUPPORTED(suffix_death.remove_suffix(21), "");
#endif
}
TEST(IntSpan, Subspan) {
std::vector<int> empty;
EXPECT_EQ(absl::MakeSpan(empty).subspan(), empty);
EXPECT_THAT(absl::MakeSpan(empty).subspan(0, 0), SpanIs(empty));
EXPECT_THAT(absl::MakeSpan(empty).subspan(0, absl::Span<const int>::npos),
SpanIs(empty));
auto ramp = MakeRamp(10);
EXPECT_THAT(absl::MakeSpan(ramp).subspan(), SpanIs(ramp));
EXPECT_THAT(absl::MakeSpan(ramp).subspan(0, 10), SpanIs(ramp));
EXPECT_THAT(absl::MakeSpan(ramp).subspan(0, absl::Span<const int>::npos),
SpanIs(ramp));
EXPECT_THAT(absl::MakeSpan(ramp).subspan(0, 3), SpanIs(ramp.data(), 3));
EXPECT_THAT(absl::MakeSpan(ramp).subspan(5, absl::Span<const int>::npos),
SpanIs(ramp.data() + 5, 5));
EXPECT_THAT(absl::MakeSpan(ramp).subspan(3, 3), SpanIs(ramp.data() + 3, 3));
EXPECT_THAT(absl::MakeSpan(ramp).subspan(10, 5), SpanIs(ramp.data() + 10, 0));
#ifdef ABSL_HAVE_EXCEPTIONS
EXPECT_THROW(absl::MakeSpan(ramp).subspan(11, 5), std::out_of_range);
#else
EXPECT_DEATH_IF_SUPPORTED(absl::MakeSpan(ramp).subspan(11, 5), "");
#endif
}
TEST(IntSpan, First) {
std::vector<int> empty;
EXPECT_THAT(absl::MakeSpan(empty).first(0), SpanIs(empty));
auto ramp = MakeRamp(10);
EXPECT_THAT(absl::MakeSpan(ramp).first(0), SpanIs(ramp.data(), 0));
EXPECT_THAT(absl::MakeSpan(ramp).first(10), SpanIs(ramp));
EXPECT_THAT(absl::MakeSpan(ramp).first(3), SpanIs(ramp.data(), 3));
#ifdef ABSL_HAVE_EXCEPTIONS
EXPECT_THROW(absl::MakeSpan(ramp).first(11), std::out_of_range);
#else
EXPECT_DEATH_IF_SUPPORTED(absl::MakeSpan(ramp).first(11), "");
#endif
}
TEST(IntSpan, Last) {
std::vector<int> empty;
EXPECT_THAT(absl::MakeSpan(empty).last(0), SpanIs(empty));
auto ramp = MakeRamp(10);
EXPECT_THAT(absl::MakeSpan(ramp).last(0), SpanIs(ramp.data() + 10, 0));
EXPECT_THAT(absl::MakeSpan(ramp).last(10), SpanIs(ramp));
EXPECT_THAT(absl::MakeSpan(ramp).last(3), SpanIs(ramp.data() + 7, 3));
#ifdef ABSL_HAVE_EXCEPTIONS
EXPECT_THROW(absl::MakeSpan(ramp).last(11), std::out_of_range);
#else
EXPECT_DEATH_IF_SUPPORTED(absl::MakeSpan(ramp).last(11), "");
#endif
}
TEST(IntSpan, MakeSpanPtrLength) {
std::vector<int> empty;
auto s_empty = absl::MakeSpan(empty.data(), empty.size());
EXPECT_THAT(s_empty, SpanIs(empty));
std::array<int, 3> a{{1, 2, 3}};
auto s = absl::MakeSpan(a.data(), a.size());
EXPECT_THAT(s, SpanIs(a));
EXPECT_THAT(absl::MakeConstSpan(empty.data(), empty.size()), SpanIs(s_empty));
EXPECT_THAT(absl::MakeConstSpan(a.data(), a.size()), SpanIs(s));
}
TEST(IntSpan, MakeSpanTwoPtrs) {
std::vector<int> empty;
auto s_empty = absl::MakeSpan(empty.data(), empty.data());
EXPECT_THAT(s_empty, SpanIs(empty));
std::vector<int> v{1, 2, 3};
auto s = absl::MakeSpan(v.data(), v.data() + 1);
EXPECT_THAT(s, SpanIs(v.data(), 1));
EXPECT_THAT(absl::MakeConstSpan(empty.data(), empty.data()), SpanIs(s_empty));
EXPECT_THAT(absl::MakeConstSpan(v.data(), v.data() + 1), SpanIs(s));
}
TEST(IntSpan, MakeSpanContainer) {
std::vector<int> empty;
auto s_empty = absl::MakeSpan(empty);
EXPECT_THAT(s_empty, SpanIs(empty));
std::vector<int> v{1, 2, 3};
auto s = absl::MakeSpan(v);
EXPECT_THAT(s, SpanIs(v));
EXPECT_THAT(absl::MakeConstSpan(empty), SpanIs(s_empty));
EXPECT_THAT(absl::MakeConstSpan(v), SpanIs(s));
EXPECT_THAT(absl::MakeSpan(s), SpanIs(s));
EXPECT_THAT(absl::MakeConstSpan(s), SpanIs(s));
}
TEST(CharSpan, MakeSpanString) {
std::string empty = "";
auto s_empty = absl::MakeSpan(empty);
EXPECT_THAT(s_empty, SpanIs(empty));
std::string str = "abc";
auto s_str = absl::MakeSpan(str);
EXPECT_THAT(s_str, SpanIs(str));
EXPECT_THAT(absl::MakeConstSpan(empty), SpanIs(s_empty));
EXPECT_THAT(absl::MakeConstSpan(str), SpanIs(s_str));
}
TEST(IntSpan, MakeSpanArray) {
int a[] = {1, 2, 3};
auto s = absl::MakeSpan(a);
EXPECT_THAT(s, SpanIs(a, 3));
const int ca[] = {1, 2, 3};
auto s_ca = absl::MakeSpan(ca);
EXPECT_THAT(s_ca, SpanIs(ca, 3));
EXPECT_THAT(absl::MakeConstSpan(a), SpanIs(s));
EXPECT_THAT(absl::MakeConstSpan(ca), SpanIs(s_ca));
}
// Compile-asserts that the argument has the expected decayed type.
template <typename Expected, typename T>
void CheckType(const T& /* value */) {
testing::StaticAssertTypeEq<Expected, T>();
}
TEST(IntSpan, MakeSpanTypes) {
std::vector<int> vec;
const std::vector<int> cvec;
int a[1];
const int ca[] = {1};
int* ip = a;
const int* cip = ca;
std::string s = "";
const std::string cs = "";
CheckType<absl::Span<int>>(absl::MakeSpan(vec));
CheckType<absl::Span<const int>>(absl::MakeSpan(cvec));
CheckType<absl::Span<int>>(absl::MakeSpan(ip, ip + 1));
CheckType<absl::Span<int>>(absl::MakeSpan(ip, 1));
CheckType<absl::Span<const int>>(absl::MakeSpan(cip, cip + 1));
CheckType<absl::Span<const int>>(absl::MakeSpan(cip, 1));
CheckType<absl::Span<int>>(absl::MakeSpan(a));
CheckType<absl::Span<int>>(absl::MakeSpan(a, a + 1));
CheckType<absl::Span<int>>(absl::MakeSpan(a, 1));
CheckType<absl::Span<const int>>(absl::MakeSpan(ca));
CheckType<absl::Span<const int>>(absl::MakeSpan(ca, ca + 1));
CheckType<absl::Span<const int>>(absl::MakeSpan(ca, 1));
CheckType<absl::Span<char>>(absl::MakeSpan(s));
CheckType<absl::Span<const char>>(absl::MakeSpan(cs));
}
TEST(ConstIntSpan, MakeConstSpanTypes) {
std::vector<int> vec;
const std::vector<int> cvec;
int array[1];
const int carray[] = {0};
int* ptr = array;
const int* cptr = carray;
std::string s = "";
std::string cs = "";
CheckType<absl::Span<const int>>(absl::MakeConstSpan(vec));
CheckType<absl::Span<const int>>(absl::MakeConstSpan(cvec));
CheckType<absl::Span<const int>>(absl::MakeConstSpan(ptr, ptr + 1));
CheckType<absl::Span<const int>>(absl::MakeConstSpan(ptr, 1));
CheckType<absl::Span<const int>>(absl::MakeConstSpan(cptr, cptr + 1));
CheckType<absl::Span<const int>>(absl::MakeConstSpan(cptr, 1));
CheckType<absl::Span<const int>>(absl::MakeConstSpan(array));
CheckType<absl::Span<const int>>(absl::MakeConstSpan(carray));
CheckType<absl::Span<const char>>(absl::MakeConstSpan(s));
CheckType<absl::Span<const char>>(absl::MakeConstSpan(cs));
}
TEST(IntSpan, Equality) {
const int arr1[] = {1, 2, 3, 4, 5};
int arr2[] = {1, 2, 3, 4, 5};
std::vector<int> vec1(std::begin(arr1), std::end(arr1));
std::vector<int> vec2 = vec1;
std::vector<int> other_vec = {2, 4, 6, 8, 10};
// These two slices are from different vectors, but have the same size and
// have the same elements (right now). They should compare equal. Test both
// == and !=.
const absl::Span<const int> from1 = vec1;
const absl::Span<const int> from2 = vec2;
EXPECT_EQ(from1, from1);
EXPECT_FALSE(from1 != from1);
EXPECT_EQ(from1, from2);
EXPECT_FALSE(from1 != from2);
// These two slices have different underlying vector values. They should be
// considered not equal. Test both == and !=.
const absl::Span<const int> from_other = other_vec;
EXPECT_NE(from1, from_other);
EXPECT_FALSE(from1 == from_other);
// Comparison between a vector and its slice should be equal. And vice-versa.
// This ensures implicit conversion to Span works on both sides of ==.
EXPECT_EQ(vec1, from1);
EXPECT_FALSE(vec1 != from1);
EXPECT_EQ(from1, vec1);
EXPECT_FALSE(from1 != vec1);
// This verifies that absl::Span<T> can be compared freely with
// absl::Span<const T>.
const absl::Span<int> mutable_from1(vec1);
const absl::Span<int> mutable_from2(vec2);
EXPECT_EQ(from1, mutable_from1);
EXPECT_EQ(mutable_from1, from1);
EXPECT_EQ(mutable_from1, mutable_from2);
EXPECT_EQ(mutable_from2, mutable_from1);
// Comparison between a vector and its slice should be equal for mutable
// Spans as well.
EXPECT_EQ(vec1, mutable_from1);
EXPECT_FALSE(vec1 != mutable_from1);
EXPECT_EQ(mutable_from1, vec1);
EXPECT_FALSE(mutable_from1 != vec1);
// Comparison between convertible-to-Span-of-const and Span-of-mutable. Arrays
// are used because they're the only value type which converts to a
// Span-of-mutable. EXPECT_TRUE is used instead of EXPECT_EQ to avoid
// array-to-pointer decay.
EXPECT_TRUE(arr1 == mutable_from1);
EXPECT_FALSE(arr1 != mutable_from1);
EXPECT_TRUE(mutable_from1 == arr1);
EXPECT_FALSE(mutable_from1 != arr1);
// Comparison between convertible-to-Span-of-mutable and Span-of-const
EXPECT_TRUE(arr2 == from1);
EXPECT_FALSE(arr2 != from1);
EXPECT_TRUE(from1 == arr2);
EXPECT_FALSE(from1 != arr2);
// With a different size, the array slices should not be equal.
EXPECT_NE(from1, absl::Span<const int>(from1).subspan(0, from1.size() - 1));
// With different contents, the array slices should not be equal.
++vec2.back();
EXPECT_NE(from1, from2);
}
class IntSpanOrderComparisonTest : public testing::Test {
public:
IntSpanOrderComparisonTest()
: arr_before_{1, 2, 3},
arr_after_{1, 2, 4},
carr_after_{1, 2, 4},
vec_before_(std::begin(arr_before_), std::end(arr_before_)),
vec_after_(std::begin(arr_after_), std::end(arr_after_)),
before_(vec_before_),
after_(vec_after_),
cbefore_(vec_before_),
cafter_(vec_after_) {}
protected:
int arr_before_[3], arr_after_[3];
const int carr_after_[3];
std::vector<int> vec_before_, vec_after_;
absl::Span<int> before_, after_;
absl::Span<const int> cbefore_, cafter_;
};
TEST_F(IntSpanOrderComparisonTest, CompareSpans) {
EXPECT_TRUE(cbefore_ < cafter_);
EXPECT_TRUE(cbefore_ <= cafter_);
EXPECT_TRUE(cafter_ > cbefore_);
EXPECT_TRUE(cafter_ >= cbefore_);
EXPECT_FALSE(cbefore_ > cafter_);
EXPECT_FALSE(cafter_ < cbefore_);
EXPECT_TRUE(before_ < after_);
EXPECT_TRUE(before_ <= after_);
EXPECT_TRUE(after_ > before_);
EXPECT_TRUE(after_ >= before_);
EXPECT_FALSE(before_ > after_);
EXPECT_FALSE(after_ < before_);
EXPECT_TRUE(cbefore_ < after_);
EXPECT_TRUE(cbefore_ <= after_);
EXPECT_TRUE(after_ > cbefore_);
EXPECT_TRUE(after_ >= cbefore_);
EXPECT_FALSE(cbefore_ > after_);
EXPECT_FALSE(after_ < cbefore_);
}
TEST_F(IntSpanOrderComparisonTest, SpanOfConstAndContainer) {
EXPECT_TRUE(cbefore_ < vec_after_);
EXPECT_TRUE(cbefore_ <= vec_after_);
EXPECT_TRUE(vec_after_ > cbefore_);
EXPECT_TRUE(vec_after_ >= cbefore_);
EXPECT_FALSE(cbefore_ > vec_after_);
EXPECT_FALSE(vec_after_ < cbefore_);
EXPECT_TRUE(arr_before_ < cafter_);
EXPECT_TRUE(arr_before_ <= cafter_);
EXPECT_TRUE(cafter_ > arr_before_);
EXPECT_TRUE(cafter_ >= arr_before_);
EXPECT_FALSE(arr_before_ > cafter_);
EXPECT_FALSE(cafter_ < arr_before_);
}
TEST_F(IntSpanOrderComparisonTest, SpanOfMutableAndContainer) {
EXPECT_TRUE(vec_before_ < after_);
EXPECT_TRUE(vec_before_ <= after_);
EXPECT_TRUE(after_ > vec_before_);
EXPECT_TRUE(after_ >= vec_before_);
EXPECT_FALSE(vec_before_ > after_);
EXPECT_FALSE(after_ < vec_before_);
EXPECT_TRUE(before_ < carr_after_);
EXPECT_TRUE(before_ <= carr_after_);
EXPECT_TRUE(carr_after_ > before_);
EXPECT_TRUE(carr_after_ >= before_);
EXPECT_FALSE(before_ > carr_after_);
EXPECT_FALSE(carr_after_ < before_);
}
TEST_F(IntSpanOrderComparisonTest, EqualSpans) {
EXPECT_FALSE(before_ < before_);
EXPECT_TRUE(before_ <= before_);
EXPECT_FALSE(before_ > before_);
EXPECT_TRUE(before_ >= before_);
}
TEST_F(IntSpanOrderComparisonTest, Subspans) {
auto subspan = before_.subspan(0, 1);
EXPECT_TRUE(subspan < before_);
EXPECT_TRUE(subspan <= before_);
EXPECT_TRUE(before_ > subspan);
EXPECT_TRUE(before_ >= subspan);
EXPECT_FALSE(subspan > before_);
EXPECT_FALSE(before_ < subspan);
}
TEST_F(IntSpanOrderComparisonTest, EmptySpans) {
absl::Span<int> empty;
EXPECT_FALSE(empty < empty);
EXPECT_TRUE(empty <= empty);
EXPECT_FALSE(empty > empty);
EXPECT_TRUE(empty >= empty);
EXPECT_TRUE(empty < before_);
EXPECT_TRUE(empty <= before_);
EXPECT_TRUE(before_ > empty);
EXPECT_TRUE(before_ >= empty);
EXPECT_FALSE(empty > before_);
EXPECT_FALSE(before_ < empty);
}
TEST(IntSpan, ExposesContainerTypesAndConsts) {
absl::Span<int> slice;
CheckType<absl::Span<int>::iterator>(slice.begin());
EXPECT_TRUE((std::is_convertible<decltype(slice.begin()),
absl::Span<int>::const_iterator>::value));
CheckType<absl::Span<int>::const_iterator>(slice.cbegin());
EXPECT_TRUE((std::is_convertible<decltype(slice.end()),
absl::Span<int>::const_iterator>::value));
CheckType<absl::Span<int>::const_iterator>(slice.cend());
CheckType<absl::Span<int>::reverse_iterator>(slice.rend());
EXPECT_TRUE(
(std::is_convertible<decltype(slice.rend()),
absl::Span<int>::const_reverse_iterator>::value));
CheckType<absl::Span<int>::const_reverse_iterator>(slice.crend());
testing::StaticAssertTypeEq<int, absl::Span<int>::value_type>();
testing::StaticAssertTypeEq<int, absl::Span<const int>::value_type>();
testing::StaticAssertTypeEq<int*, absl::Span<int>::pointer>();
testing::StaticAssertTypeEq<const int*, absl::Span<const int>::pointer>();
testing::StaticAssertTypeEq<int&, absl::Span<int>::reference>();
testing::StaticAssertTypeEq<const int&, absl::Span<const int>::reference>();
testing::StaticAssertTypeEq<const int&, absl::Span<int>::const_reference>();
testing::StaticAssertTypeEq<const int&,
absl::Span<const int>::const_reference>();
EXPECT_EQ(static_cast<absl::Span<int>::size_type>(-1), absl::Span<int>::npos);
}
TEST(IntSpan, IteratorsAndReferences) {
auto accept_pointer = [](int*) {};
auto accept_reference = [](int&) {};
auto accept_iterator = [](absl::Span<int>::iterator) {};
auto accept_const_iterator = [](absl::Span<int>::const_iterator) {};
auto accept_reverse_iterator = [](absl::Span<int>::reverse_iterator) {};
auto accept_const_reverse_iterator =
[](absl::Span<int>::const_reverse_iterator) {};
int a[1];
absl::Span<int> s = a;
accept_pointer(s.data());
accept_iterator(s.begin());
accept_const_iterator(s.begin());
accept_const_iterator(s.cbegin());
accept_iterator(s.end());
accept_const_iterator(s.end());
accept_const_iterator(s.cend());
accept_reverse_iterator(s.rbegin());
accept_const_reverse_iterator(s.rbegin());
accept_const_reverse_iterator(s.crbegin());
accept_reverse_iterator(s.rend());
accept_const_reverse_iterator(s.rend());
accept_const_reverse_iterator(s.crend());
accept_reference(s[0]);
accept_reference(s.at(0));
accept_reference(s.front());
accept_reference(s.back());
}
TEST(IntSpan, IteratorsAndReferences_Const) {
auto accept_pointer = [](int*) {};
auto accept_reference = [](int&) {};
auto accept_iterator = [](absl::Span<int>::iterator) {};
auto accept_const_iterator = [](absl::Span<int>::const_iterator) {};
auto accept_reverse_iterator = [](absl::Span<int>::reverse_iterator) {};
auto accept_const_reverse_iterator =
[](absl::Span<int>::const_reverse_iterator) {};
int a[1];
const absl::Span<int> s = a;
accept_pointer(s.data());
accept_iterator(s.begin());
accept_const_iterator(s.begin());
accept_const_iterator(s.cbegin());
accept_iterator(s.end());
accept_const_iterator(s.end());
accept_const_iterator(s.cend());
accept_reverse_iterator(s.rbegin());
accept_const_reverse_iterator(s.rbegin());
accept_const_reverse_iterator(s.crbegin());
accept_reverse_iterator(s.rend());
accept_const_reverse_iterator(s.rend());
accept_const_reverse_iterator(s.crend());
accept_reference(s[0]);
accept_reference(s.at(0));
accept_reference(s.front());
accept_reference(s.back());
}
TEST(IntSpan, NoexceptTest) {
int a[] = {1, 2, 3};
std::vector<int> v;
EXPECT_TRUE(noexcept(absl::Span<const int>()));
EXPECT_TRUE(noexcept(absl::Span<const int>(a, 2)));
EXPECT_TRUE(noexcept(absl::Span<const int>(a)));
EXPECT_TRUE(noexcept(absl::Span<const int>(v)));
EXPECT_TRUE(noexcept(absl::Span<int>(v)));
EXPECT_TRUE(noexcept(absl::Span<const int>({1, 2, 3})));
EXPECT_TRUE(noexcept(absl::MakeSpan(v)));
EXPECT_TRUE(noexcept(absl::MakeSpan(a)));
EXPECT_TRUE(noexcept(absl::MakeSpan(a, 2)));
EXPECT_TRUE(noexcept(absl::MakeSpan(a, a + 1)));
EXPECT_TRUE(noexcept(absl::MakeConstSpan(v)));
EXPECT_TRUE(noexcept(absl::MakeConstSpan(a)));
EXPECT_TRUE(noexcept(absl::MakeConstSpan(a, 2)));
EXPECT_TRUE(noexcept(absl::MakeConstSpan(a, a + 1)));
absl::Span<int> s(v);
EXPECT_TRUE(noexcept(s.data()));
EXPECT_TRUE(noexcept(s.size()));
EXPECT_TRUE(noexcept(s.length()));
EXPECT_TRUE(noexcept(s.empty()));
EXPECT_TRUE(noexcept(s[0]));
EXPECT_TRUE(noexcept(s.front()));
EXPECT_TRUE(noexcept(s.back()));
EXPECT_TRUE(noexcept(s.begin()));
EXPECT_TRUE(noexcept(s.cbegin()));
EXPECT_TRUE(noexcept(s.end()));
EXPECT_TRUE(noexcept(s.cend()));
EXPECT_TRUE(noexcept(s.rbegin()));
EXPECT_TRUE(noexcept(s.crbegin()));
EXPECT_TRUE(noexcept(s.rend()));
EXPECT_TRUE(noexcept(s.crend()));
EXPECT_TRUE(noexcept(s.remove_prefix(0)));
EXPECT_TRUE(noexcept(s.remove_suffix(0)));
}
// ConstexprTester exercises expressions in a constexpr context. Simply placing
// the expression in a constexpr function is not enough, as some compilers will
// simply compile the constexpr function as runtime code. Using template
// parameters forces compile-time execution.
template <int i>
struct ConstexprTester {};
#define ABSL_TEST_CONSTEXPR(expr) \
do { \
ABSL_ATTRIBUTE_UNUSED ConstexprTester<(expr, 1)> t; \
} while (0)
struct ContainerWithConstexprMethods {
constexpr int size() const { return 1; }
constexpr const int* data() const { return &i; }
const int i;
};
TEST(ConstIntSpan, ConstexprTest) {
static constexpr int a[] = {1, 2, 3};
static constexpr int sized_arr[2] = {1, 2};
static constexpr ContainerWithConstexprMethods c{1};
ABSL_TEST_CONSTEXPR(absl::Span<const int>());
ABSL_TEST_CONSTEXPR(absl::Span<const int>(a, 2));
ABSL_TEST_CONSTEXPR(absl::Span<const int>(sized_arr));
ABSL_TEST_CONSTEXPR(absl::Span<const int>(c));
ABSL_TEST_CONSTEXPR(absl::MakeSpan(&a[0], 1));
ABSL_TEST_CONSTEXPR(absl::MakeSpan(c));
ABSL_TEST_CONSTEXPR(absl::MakeSpan(a));
ABSL_TEST_CONSTEXPR(absl::MakeConstSpan(&a[0], 1));
ABSL_TEST_CONSTEXPR(absl::MakeConstSpan(c));
ABSL_TEST_CONSTEXPR(absl::MakeConstSpan(a));
constexpr absl::Span<const int> span = c;
ABSL_TEST_CONSTEXPR(span.data());
ABSL_TEST_CONSTEXPR(span.size());
ABSL_TEST_CONSTEXPR(span.length());
ABSL_TEST_CONSTEXPR(span.empty());
ABSL_TEST_CONSTEXPR(span.begin());
ABSL_TEST_CONSTEXPR(span.cbegin());
ABSL_TEST_CONSTEXPR(span.subspan(0, 0));
ABSL_TEST_CONSTEXPR(span.first(1));
ABSL_TEST_CONSTEXPR(span.last(1));
ABSL_TEST_CONSTEXPR(span[0]);
}
struct BigStruct {
char bytes[10000];
};
TEST(Span, SpanSize) {
EXPECT_LE(sizeof(absl::Span<int>), 2 * sizeof(void*));
EXPECT_LE(sizeof(absl::Span<BigStruct>), 2 * sizeof(void*));
}
TEST(Span, Hash) {
int array[] = {1, 2, 3, 4};
int array2[] = {1, 2, 3};
using T = absl::Span<const int>;
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
{// Empties
T(), T(nullptr, 0), T(array, 0), T(array2, 0),
// Different array with same value
T(array, 3), T(array2), T({1, 2, 3}),
// Same array, but different length
T(array, 1), T(array, 2),
// Same length, but different array
T(array + 1, 2), T(array + 2, 2)}));
}
} // namespace
