GSL/tests/strided_span_tests.cpp

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///////////////////////////////////////////////////////////////////////////////
//
// 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.
//
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///////////////////////////////////////////////////////////////////////////////
#include <catch/catch.hpp> // for AssertionHandler, StringRef, CHECK, CHECK...
#include <gsl/gsl_byte> // for byte
#include <gsl/gsl_util> // for narrow_cast
#include <gsl/multi_span> // for strided_span, index, multi_span, strided_...
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#include <iostream> // for size_t
#include <iterator> // for begin, end
#include <numeric> // for iota
#include <type_traits> // for integral_constant<>::value, is_convertible
#include <vector> // for vector
namespace gsl {
struct fail_fast;
} // namespace gsl
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using namespace std;
using namespace gsl;
namespace
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{
struct BaseClass
{
};
struct DerivedClass : BaseClass
{
};
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}
TEST_CASE("span_section_test")
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{
int a[30][4][5];
const auto av = as_multi_span(a);
const auto sub = av.section({15, 0, 0}, gsl::index<3>{2, 2, 2});
const auto subsub = sub.section({1, 0, 0}, gsl::index<3>{1, 1, 1});
(void) subsub;
}
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TEST_CASE("span_section")
{
std::vector<int> data(5 * 10);
std::iota(begin(data), end(data), 0);
const multi_span<int, 5, 10> av = as_multi_span(multi_span<int>{data}, dim<5>(), dim<10>());
const strided_span<int, 2> av_section_1 = av.section({1, 2}, {3, 4});
CHECK((av_section_1[{0, 0}] == 12));
CHECK((av_section_1[{0, 1}] == 13));
CHECK((av_section_1[{1, 0}] == 22));
CHECK((av_section_1[{2, 3}] == 35));
const strided_span<int, 2> av_section_2 = av_section_1.section({1, 2}, {2, 2});
CHECK((av_section_2[{0, 0}] == 24));
CHECK((av_section_2[{0, 1}] == 25));
CHECK((av_section_2[{1, 0}] == 34));
}
TEST_CASE("strided_span_constructors")
{
// Check stride constructor
{
int arr[] = {1, 2, 3, 4, 5, 6, 7, 8, 9};
const int carr[] = {1, 2, 3, 4, 5, 6, 7, 8, 9};
strided_span<int, 1> sav1{arr, {{9}, {1}}}; // T -> T
CHECK(sav1.bounds().index_bounds() == index<1>{9});
CHECK(sav1.bounds().stride() == 1);
CHECK((sav1[0] == 1 && sav1[8] == 9));
strided_span<const int, 1> sav2{carr, {{4}, {2}}}; // const T -> const T
CHECK(sav2.bounds().index_bounds() == index<1>{4});
CHECK(sav2.bounds().strides() == index<1>{2});
CHECK((sav2[0] == 1 && sav2[3] == 7));
strided_span<int, 2> sav3{arr, {{2, 2}, {6, 2}}}; // T -> const T
CHECK((sav3.bounds().index_bounds() == index<2>{2, 2}));
CHECK((sav3.bounds().strides() == index<2>{6, 2}));
CHECK((sav3[{0, 0}] == 1 && sav3[{0, 1}] == 3 && sav3[{1, 0}] == 7));
}
// Check multi_span constructor
{
int arr[] = {1, 2};
// From non-cv-qualified source
{
const multi_span<int> src = arr;
strided_span<int, 1> sav{src, {2, 1}};
CHECK(sav.bounds().index_bounds() == index<1>{2});
CHECK(sav.bounds().strides() == index<1>{1});
CHECK(sav[1] == 2);
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#if _MSC_VER > 1800
// strided_span<const int, 1> sav_c{ {src}, {2, 1} };
strided_span<const int, 1> sav_c{multi_span<const int>{src},
strided_bounds<1>{2, 1}};
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#else
strided_span<const int, 1> sav_c{multi_span<const int>{src},
strided_bounds<1>{2, 1}};
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#endif
CHECK(sav_c.bounds().index_bounds() == index<1>{2});
CHECK(sav_c.bounds().strides() == index<1>{1});
CHECK(sav_c[1] == 2);
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#if _MSC_VER > 1800
strided_span<volatile int, 1> sav_v{src, {2, 1}};
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#else
strided_span<volatile int, 1> sav_v{multi_span<volatile int>{src},
strided_bounds<1>{2, 1}};
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#endif
CHECK(sav_v.bounds().index_bounds() == index<1>{2});
CHECK(sav_v.bounds().strides() == index<1>{1});
CHECK(sav_v[1] == 2);
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#if _MSC_VER > 1800
strided_span<const volatile int, 1> sav_cv{src, {2, 1}};
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#else
strided_span<const volatile int, 1> sav_cv{multi_span<const volatile int>{src},
strided_bounds<1>{2, 1}};
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#endif
CHECK(sav_cv.bounds().index_bounds() == index<1>{2});
CHECK(sav_cv.bounds().strides() == index<1>{1});
CHECK(sav_cv[1] == 2);
}
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// From const-qualified source
{
const multi_span<const int> src{arr};
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strided_span<const int, 1> sav_c{src, {2, 1}};
CHECK(sav_c.bounds().index_bounds() == index<1>{2});
CHECK(sav_c.bounds().strides() == index<1>{1});
CHECK(sav_c[1] == 2);
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#if _MSC_VER > 1800
strided_span<const volatile int, 1> sav_cv{src, {2, 1}};
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#else
strided_span<const volatile int, 1> sav_cv{multi_span<const volatile int>{src},
strided_bounds<1>{2, 1}};
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#endif
CHECK(sav_cv.bounds().index_bounds() == index<1>{2});
CHECK(sav_cv.bounds().strides() == index<1>{1});
CHECK(sav_cv[1] == 2);
}
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// From volatile-qualified source
{
const multi_span<volatile int> src{arr};
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strided_span<volatile int, 1> sav_v{src, {2, 1}};
CHECK(sav_v.bounds().index_bounds() == index<1>{2});
CHECK(sav_v.bounds().strides() == index<1>{1});
CHECK(sav_v[1] == 2);
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#if _MSC_VER > 1800
strided_span<const volatile int, 1> sav_cv{src, {2, 1}};
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#else
strided_span<const volatile int, 1> sav_cv{multi_span<const volatile int>{src},
strided_bounds<1>{2, 1}};
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#endif
CHECK(sav_cv.bounds().index_bounds() == index<1>{2});
CHECK(sav_cv.bounds().strides() == index<1>{1});
CHECK(sav_cv[1] == 2);
}
// From cv-qualified source
{
const multi_span<const volatile int> src{arr};
strided_span<const volatile int, 1> sav_cv{src, {2, 1}};
CHECK(sav_cv.bounds().index_bounds() == index<1>{2});
CHECK(sav_cv.bounds().strides() == index<1>{1});
CHECK(sav_cv[1] == 2);
}
}
// Check const-casting constructor
{
int arr[2] = {4, 5};
const multi_span<int, 2> av(arr, 2);
multi_span<const int, 2> av2{av};
CHECK(av2[1] == 5);
static_assert(
std::is_convertible<const multi_span<int, 2>, multi_span<const int, 2>>::value,
"ctor is not implicit!");
const strided_span<int, 1> src{arr, {2, 1}};
strided_span<const int, 1> sav{src};
CHECK(sav.bounds().index_bounds() == index<1>{2});
CHECK(sav.bounds().stride() == 1);
CHECK(sav[1] == 5);
static_assert(
std::is_convertible<const strided_span<int, 1>, strided_span<const int, 1>>::value,
"ctor is not implicit!");
}
// Check copy constructor
{
int arr1[2] = {3, 4};
const strided_span<int, 1> src1{arr1, {2, 1}};
strided_span<int, 1> sav1{src1};
CHECK(sav1.bounds().index_bounds() == index<1>{2});
CHECK(sav1.bounds().stride() == 1);
CHECK(sav1[0] == 3);
int arr2[6] = {1, 2, 3, 4, 5, 6};
const strided_span<const int, 2> src2{arr2, {{3, 2}, {2, 1}}};
strided_span<const int, 2> sav2{src2};
CHECK((sav2.bounds().index_bounds() == index<2>{3, 2}));
CHECK((sav2.bounds().strides() == index<2>{2, 1}));
CHECK((sav2[{0, 0}] == 1 && sav2[{2, 0}] == 5));
}
// Check const-casting assignment operator
{
int arr1[2] = {1, 2};
int arr2[6] = {3, 4, 5, 6, 7, 8};
const strided_span<int, 1> src{arr1, {{2}, {1}}};
strided_span<const int, 1> sav{arr2, {{3}, {2}}};
strided_span<const int, 1>& sav_ref = (sav = src);
CHECK(sav.bounds().index_bounds() == index<1>{2});
CHECK(sav.bounds().strides() == index<1>{1});
CHECK(sav[0] == 1);
CHECK(&sav_ref == &sav);
}
// Check copy assignment operator
{
int arr1[2] = {3, 4};
int arr1b[1] = {0};
const strided_span<int, 1> src1{arr1, {2, 1}};
strided_span<int, 1> sav1{arr1b, {1, 1}};
strided_span<int, 1>& sav1_ref = (sav1 = src1);
CHECK(sav1.bounds().index_bounds() == index<1>{2});
CHECK(sav1.bounds().strides() == index<1>{1});
CHECK(sav1[0] == 3);
CHECK(&sav1_ref == &sav1);
const int arr2[6] = {1, 2, 3, 4, 5, 6};
const int arr2b[1] = {0};
const strided_span<const int, 2> src2{arr2, {{3, 2}, {2, 1}}};
strided_span<const int, 2> sav2{arr2b, {{1, 1}, {1, 1}}};
strided_span<const int, 2>& sav2_ref = (sav2 = src2);
CHECK((sav2.bounds().index_bounds() == index<2>{3, 2}));
CHECK((sav2.bounds().strides() == index<2>{2, 1}));
CHECK((sav2[{0, 0}] == 1 && sav2[{2, 0}] == 5));
CHECK(&sav2_ref == &sav2);
}
}
TEST_CASE("strided_span_slice")
{
std::vector<int> data(5 * 10);
std::iota(begin(data), end(data), 0);
const multi_span<int, 5, 10> src =
as_multi_span(multi_span<int>{data}, dim<5>(), dim<10>());
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const strided_span<int, 2> sav{src, {{5, 10}, {10, 1}}};
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#ifdef CONFIRM_COMPILATION_ERRORS
const strided_span<const int, 2> csav{{src}, {{5, 10}, {10, 1}}};
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#endif
const strided_span<const int, 2> csav{multi_span<const int, 5, 10>{src},
{{5, 10}, {10, 1}}};
strided_span<int, 1> sav_sl = sav[2];
CHECK(sav_sl[0] == 20);
CHECK(sav_sl[9] == 29);
strided_span<const int, 1> csav_sl = sav[3];
CHECK(csav_sl[0] == 30);
CHECK(csav_sl[9] == 39);
CHECK(sav[4][0] == 40);
CHECK(sav[4][9] == 49);
}
TEST_CASE("strided_span_column_major")
{
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// strided_span may be used to accommodate more peculiar
// use cases, such as column-major multidimensional array
// (aka. "FORTRAN" layout).
int cm_array[3 * 5] = {1, 4, 7, 10, 13, 2, 5, 8, 11, 14, 3, 6, 9, 12, 15};
strided_span<int, 2> cm_sav{cm_array, {{5, 3}, {1, 5}}};
// Accessing elements
CHECK((cm_sav[{0, 0}] == 1));
CHECK((cm_sav[{0, 1}] == 2));
CHECK((cm_sav[{1, 0}] == 4));
CHECK((cm_sav[{4, 2}] == 15));
// Slice
strided_span<int, 1> cm_sl = cm_sav[3];
CHECK(cm_sl[0] == 10);
CHECK(cm_sl[1] == 11);
CHECK(cm_sl[2] == 12);
// Section
strided_span<int, 2> cm_sec = cm_sav.section({2, 1}, {3, 2});
CHECK((cm_sec.bounds().index_bounds() == index<2>{3, 2}));
CHECK((cm_sec[{0, 0}] == 8));
CHECK((cm_sec[{0, 1}] == 9));
CHECK((cm_sec[{1, 0}] == 11));
CHECK((cm_sec[{2, 1}] == 15));
}
TEST_CASE("strided_span_bounds")
{
int arr[] = {0, 1, 2, 3};
multi_span<int> av(arr);
{
// incorrect sections
CHECK_THROWS_AS(av.section(0, 0)[0], fail_fast);
CHECK_THROWS_AS(av.section(1, 0)[0], fail_fast);
CHECK_THROWS_AS(av.section(1, 1)[1], fail_fast);
CHECK_THROWS_AS(av.section(2, 5), fail_fast);
CHECK_THROWS_AS(av.section(5, 2), fail_fast);
CHECK_THROWS_AS(av.section(5, 0), fail_fast);
CHECK_THROWS_AS(av.section(0, 5), fail_fast);
CHECK_THROWS_AS(av.section(5, 5), fail_fast);
}
{
// zero stride
strided_span<int, 1> sav{av, {{4}, {}}};
CHECK(sav[0] == 0);
CHECK(sav[3] == 0);
CHECK_THROWS_AS(sav[4], fail_fast);
}
{
// zero extent
strided_span<int, 1> sav{av, {{}, {1}}};
CHECK_THROWS_AS(sav[0], fail_fast);
}
{
// zero extent and stride
strided_span<int, 1> sav{av, {{}, {}}};
CHECK_THROWS_AS(sav[0], fail_fast);
}
{
// strided array ctor with matching strided bounds
strided_span<int, 1> sav{arr, {4, 1}};
CHECK(sav.bounds().index_bounds() == index<1>{4});
CHECK(sav[3] == 3);
CHECK_THROWS_AS(sav[4], fail_fast);
}
{
// strided array ctor with smaller strided bounds
strided_span<int, 1> sav{arr, {2, 1}};
CHECK(sav.bounds().index_bounds() == index<1>{2});
CHECK(sav[1] == 1);
CHECK_THROWS_AS(sav[2], fail_fast);
}
{
// strided array ctor with fitting irregular bounds
strided_span<int, 1> sav{arr, {2, 3}};
CHECK(sav.bounds().index_bounds() == index<1>{2});
CHECK(sav[0] == 0);
CHECK(sav[1] == 3);
CHECK_THROWS_AS(sav[2], fail_fast);
}
{
// bounds cross data boundaries - from static arrays
CHECK_THROWS_AS((strided_span<int, 1>{arr, {3, 2}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{arr, {3, 3}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{arr, {4, 5}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{arr, {5, 1}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{arr, {5, 5}}), fail_fast);
}
{
// bounds cross data boundaries - from array view
CHECK_THROWS_AS((strided_span<int, 1>{av, {3, 2}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av, {3, 3}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av, {4, 5}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av, {5, 1}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av, {5, 5}}), fail_fast);
}
{
// bounds cross data boundaries - from dynamic arrays
CHECK_THROWS_AS((strided_span<int, 1>{av.data(), 4, {3, 2}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av.data(), 4, {3, 3}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av.data(), 4, {4, 5}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av.data(), 4, {5, 1}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av.data(), 4, {5, 5}}), fail_fast);
CHECK_THROWS_AS((strided_span<int, 1>{av.data(), 2, {2, 2}}), fail_fast);
}
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#ifdef CONFIRM_COMPILATION_ERRORS
{
strided_span<int, 1> sav0{av.data(), {3, 2}};
strided_span<int, 1> sav1{arr, {1}};
strided_span<int, 1> sav2{arr, {1, 1, 1}};
strided_span<int, 1> sav3{av, {1}};
strided_span<int, 1> sav4{av, {1, 1, 1}};
strided_span<int, 2> sav5{av.as_multi_span(dim<2>(), dim<2>()), {1}};
strided_span<int, 2> sav6{av.as_multi_span(dim<2>(), dim<2>()), {1, 1, 1}};
strided_span<int, 2> sav7{av.as_multi_span(dim<2>(), dim<2>()),
{{1, 1}, {1, 1}, {1, 1}}};
index<1> index{0, 1};
strided_span<int, 1> sav8{arr, {1, {1, 1}}};
strided_span<int, 1> sav9{arr, {{1, 1}, {1, 1}}};
strided_span<int, 1> sav10{av, {1, {1, 1}}};
strided_span<int, 1> sav11{av, {{1, 1}, {1, 1}}};
strided_span<int, 2> sav12{av.as_multi_span(dim<2>(), dim<2>()), {{1}, {1}}};
strided_span<int, 2> sav13{av.as_multi_span(dim<2>(), dim<2>()), {{1}, {1, 1, 1}}};
strided_span<int, 2> sav14{av.as_multi_span(dim<2>(), dim<2>()), {{1, 1, 1}, {1}}};
}
#endif
}
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TEST_CASE("strided_span_type_conversion")
{
int arr[] = {0, 1, 2, 3};
multi_span<int> av(arr);
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{
strided_span<int, 1> sav{av.data(), av.size(), {av.size() / 2, 2}};
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#ifdef CONFIRM_COMPILATION_ERRORS
strided_span<long, 1> lsav1 = sav.as_strided_span<long, 1>();
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#endif
}
{
strided_span<int, 1> sav{av, {av.size() / 2, 2}};
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#ifdef CONFIRM_COMPILATION_ERRORS
strided_span<long, 1> lsav1 = sav.as_strided_span<long, 1>();
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#endif
}
multi_span<const byte, dynamic_range> bytes = as_bytes(av);
// retype strided array with regular strides - from raw data
{
strided_bounds<2> bounds{{2, bytes.size() / 4}, {bytes.size() / 2, 1}};
strided_span<const byte, 2> sav2{bytes.data(), bytes.size(), bounds};
strided_span<const int, 2> sav3 = sav2.as_strided_span<const int>();
CHECK(sav3[0][0] == 0);
CHECK(sav3[1][0] == 2);
CHECK_THROWS_AS(sav3[1][1], fail_fast);
CHECK_THROWS_AS(sav3[0][1], fail_fast);
}
// retype strided array with regular strides - from multi_span
{
strided_bounds<2> bounds{{2, bytes.size() / 4}, {bytes.size() / 2, 1}};
multi_span<const byte, 2, dynamic_range> bytes2 =
as_multi_span(bytes, dim<2>(), dim(bytes.size() / 2));
strided_span<const byte, 2> sav2{bytes2, bounds};
strided_span<int, 2> sav3 = sav2.as_strided_span<int>();
CHECK(sav3[0][0] == 0);
CHECK(sav3[1][0] == 2);
CHECK_THROWS_AS(sav3[1][1], fail_fast);
CHECK_THROWS_AS(sav3[0][1], fail_fast);
}
// retype strided array with not enough elements - last dimension of the array is too small
{
strided_bounds<2> bounds{{4, 2}, {4, 1}};
multi_span<const byte, 2, dynamic_range> bytes2 =
as_multi_span(bytes, dim<2>(), dim(bytes.size() / 2));
strided_span<const byte, 2> sav2{bytes2, bounds};
CHECK_THROWS_AS(sav2.as_strided_span<int>(), fail_fast);
}
// retype strided array with not enough elements - strides are too small
{
strided_bounds<2> bounds{{4, 2}, {2, 1}};
multi_span<const byte, 2, dynamic_range> bytes2 =
as_multi_span(bytes, dim<2>(), dim(bytes.size() / 2));
strided_span<const byte, 2> sav2{bytes2, bounds};
CHECK_THROWS_AS(sav2.as_strided_span<int>(), fail_fast);
}
// retype strided array with not enough elements - last dimension does not divide by the new
// typesize
{
strided_bounds<2> bounds{{2, 6}, {4, 1}};
multi_span<const byte, 2, dynamic_range> bytes2 =
as_multi_span(bytes, dim<2>(), dim(bytes.size() / 2));
strided_span<const byte, 2> sav2{bytes2, bounds};
CHECK_THROWS_AS(sav2.as_strided_span<int>(), fail_fast);
}
// retype strided array with not enough elements - strides does not divide by the new
// typesize
{
strided_bounds<2> bounds{{2, 1}, {6, 1}};
multi_span<const byte, 2, dynamic_range> bytes2 =
as_multi_span(bytes, dim<2>(), dim(bytes.size() / 2));
strided_span<const byte, 2> sav2{bytes2, bounds};
CHECK_THROWS_AS(sav2.as_strided_span<int>(), fail_fast);
}
// retype strided array with irregular strides - from raw data
{
strided_bounds<1> bounds{bytes.size() / 2, 2};
strided_span<const byte, 1> sav2{bytes.data(), bytes.size(), bounds};
CHECK_THROWS_AS(sav2.as_strided_span<int>(), fail_fast);
}
// retype strided array with irregular strides - from multi_span
{
strided_bounds<1> bounds{bytes.size() / 2, 2};
strided_span<const byte, 1> sav2{bytes, bounds};
CHECK_THROWS_AS(sav2.as_strided_span<int>(), fail_fast);
}
}
TEST_CASE("empty_strided_spans")
{
{
multi_span<int, 0> empty_av(nullptr);
strided_span<int, 1> empty_sav{empty_av, {0, 1}};
CHECK(empty_sav.bounds().index_bounds() == index<1>{0});
CHECK_THROWS_AS(empty_sav[0], fail_fast);
CHECK_THROWS_AS(empty_sav.begin()[0], fail_fast);
CHECK_THROWS_AS(empty_sav.cbegin()[0], fail_fast);
for (const auto& v : empty_sav) {
(void) v;
CHECK(false);
}
}
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{
strided_span<int, 1> empty_sav{nullptr, 0, {0, 1}};
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CHECK(empty_sav.bounds().index_bounds() == index<1>{0});
CHECK_THROWS_AS(empty_sav[0], fail_fast);
CHECK_THROWS_AS(empty_sav.begin()[0], fail_fast);
CHECK_THROWS_AS(empty_sav.cbegin()[0], fail_fast);
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for (const auto& v : empty_sav) {
(void) v;
CHECK(false);
}
}
}
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void iterate_every_other_element(multi_span<int, dynamic_range> av)
{
// pick every other element
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auto length = av.size() / 2;
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#if _MSC_VER > 1800
auto bounds = strided_bounds<1>({length}, {2});
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#else
auto bounds = strided_bounds<1>(index<1>{length}, index<1>{2});
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#endif
strided_span<int, 1> strided(&av.data()[1], av.size() - 1, bounds);
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CHECK(strided.size() == length);
CHECK(strided.bounds().index_bounds()[0] == length);
for (auto i = 0; i < strided.size(); ++i) {
CHECK(strided[i] == av[2 * i + 1]);
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}
int idx = 0;
for (auto num : strided) {
CHECK(num == av[2 * idx + 1]);
idx++;
}
}
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TEST_CASE("strided_span_section_iteration")
{
int arr[8] = {4, 0, 5, 1, 6, 2, 7, 3};
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// static bounds
{
multi_span<int, 8> av(arr, 8);
iterate_every_other_element(av);
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}
// dynamic bounds
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{
multi_span<int, dynamic_range> av(arr, 8);
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iterate_every_other_element(av);
}
}
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TEST_CASE("dynamic_strided_span_section_iteration")
{
auto arr = new int[8];
for (int i = 0; i < 4; ++i) {
arr[2 * i] = 4 + i;
arr[2 * i + 1] = i;
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}
auto av = as_multi_span(arr, 8);
iterate_every_other_element(av);
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delete[] arr;
}
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void iterate_second_slice(multi_span<int, dynamic_range, dynamic_range, dynamic_range> av)
{
const int expected[6] = {2, 3, 10, 11, 18, 19};
auto section = av.section({0, 1, 0}, {3, 1, 2});
for (auto i = 0; i < section.extent<0>(); ++i) {
for (auto j = 0; j < section.extent<1>(); ++j)
for (auto k = 0; k < section.extent<2>(); ++k) {
auto idx = index<3>{i, j, k}; // avoid braces in the CHECK macro
CHECK(section[idx] == expected[2 * i + 2 * j + k]);
}
}
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for (auto i = 0; i < section.extent<0>(); ++i) {
for (auto j = 0; j < section.extent<1>(); ++j)
for (auto k = 0; k < section.extent<2>(); ++k)
CHECK(section[i][j][k] == expected[2 * i + 2 * j + k]);
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}
int i = 0;
for (const auto num : section) {
CHECK(num == expected[i]);
i++;
}
}
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TEST_CASE("strided_span_section_iteration_3d")
{
int arr[3][4][2]{};
for (auto i = 0; i < 3; ++i) {
for (auto j = 0; j < 4; ++j)
for (auto k = 0; k < 2; ++k) arr[i][j][k] = 8 * i + 2 * j + k;
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}
{
multi_span<int, 3, 4, 2> av = arr;
iterate_second_slice(av);
}
}
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TEST_CASE("dynamic_strided_span_section_iteration_3d")
{
const auto height = 12, width = 2;
const auto size = height * width;
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auto arr = new int[static_cast<std::size_t>(size)];
for (auto i = 0; i < size; ++i) {
arr[i] = i;
}
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{
auto av = as_multi_span(as_multi_span(arr, 24), dim<3>(), dim<4>(), dim<2>());
iterate_second_slice(av);
}
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{
auto av = as_multi_span(as_multi_span(arr, 24), dim(3), dim<4>(), dim<2>());
iterate_second_slice(av);
}
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{
auto av = as_multi_span(as_multi_span(arr, 24), dim<3>(), dim(4), dim<2>());
iterate_second_slice(av);
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}
{
auto av = as_multi_span(as_multi_span(arr, 24), dim<3>(), dim<4>(), dim(2));
iterate_second_slice(av);
}
delete[] arr;
}
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TEST_CASE("strided_span_conversion")
{
// get an multi_span of 'c' values from the list of X's
struct X
{
int a;
int b;
int c;
};
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X arr[4] = {{0, 1, 2}, {3, 4, 5}, {6, 7, 8}, {9, 10, 11}};
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int s = sizeof(int) / sizeof(byte);
auto d2 = 3 * s;
auto d1 = narrow_cast<int>(sizeof(int)) * 12 / d2;
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// convert to 4x12 array of bytes
auto av = as_multi_span(as_bytes(as_multi_span(arr, 4)), dim(d1), dim(d2));
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CHECK(av.bounds().index_bounds()[0] == 4);
CHECK(av.bounds().index_bounds()[1] == 12);
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// get the last 4 columns
auto section = av.section({0, 2 * s}, {4, s}); // { { arr[0].c[0], arr[0].c[1], arr[0].c[2],
// arr[0].c[3] } , { arr[1].c[0], ... } , ...
// }
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// convert to array 4x1 array of integers
auto cs = section.as_strided_span<int>(); // { { arr[0].c }, {arr[1].c } , ... }
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CHECK(cs.bounds().index_bounds()[0] == 4);
CHECK(cs.bounds().index_bounds()[1] == 1);
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// transpose to 1x4 array
strided_bounds<2> reverse_bounds{
{cs.bounds().index_bounds()[1], cs.bounds().index_bounds()[0]},
{cs.bounds().strides()[1], cs.bounds().strides()[0]}};
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strided_span<int, 2> transposed{cs.data(), cs.bounds().total_size(), reverse_bounds};
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// slice to get a one-dimensional array of c's
strided_span<int, 1> result = transposed[0];
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CHECK(result.bounds().index_bounds()[0] == 4);
CHECK_THROWS_AS(result.bounds().index_bounds()[1], fail_fast);
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int i = 0;
for (auto& num : result) {
CHECK(num == arr[i].c);
i++;
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}
}