blob: d799675a9bc7574058651cc9541e8a2431f5314c [file] [log] [blame]
//===----------------------------------------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is dual licensed under the MIT and the University of Illinois Open
// Source Licenses. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
// UNSUPPORTED: c++98, c++03, c++11, c++14
// <experimental/simd>
//
// scalar access [simd.subscr]
// reference operator[](size_t);
// value_type operator[](size_t) const;
#include <experimental/simd>
#include <cassert>
#include <cstdint>
namespace ex = std::experimental::parallelism_v2;
template <typename SimdType>
void test_access() {
{
SimdType a(42), b(4);
static_assert(std::is_convertible<decltype(a[0]), int8_t>::value, "");
assert(a[0] == 42);
assert(!a[0] == !42);
assert(~a[0] == ~42);
assert(+a[0] == +42);
assert(-a[0] == -42);
assert(a[0] + b[0] == 42 + 4);
assert(a[0] - b[0] == 42 - 4);
assert(a[0] * b[0] == 42 * 4);
assert(a[0] / b[0] == 42 / 4);
assert(a[0] % b[0] == 42 % 4);
assert(a[0] << b[0] == (42 << 4));
assert(a[0] >> b[0] == (42 >> 4));
assert(a[0] < b[0] == false);
assert(a[0] <= b[0] == false);
assert(a[0] > b[0] == true);
assert(a[0] >= b[0] == true);
assert(a[0] == b[0] == false);
assert(a[0] != b[0] == true);
assert((a[0] & b[0]) == (42 & 4));
assert((a[0] | b[0]) == (42 | 4));
assert((a[0] ^ b[0]) == (42 ^ 4));
assert((a[0] && b[0]) == true);
assert((a[0] || b[0]) == true);
{
auto c = a;
++c[0];
assert(c[0] == 42 + 1);
assert(c[1] == 42);
}
{
auto c = a;
auto ret = c[0]++;
assert(ret == 42);
assert(c[0] == 42 + 1);
assert(c[1] == 42);
}
{
auto c = a;
--c[0];
assert(c[0] == 42 - 1);
assert(c[1] == 42);
}
{
auto c = a;
auto ret = c[0]--;
assert(ret == 42);
assert(c[0] == 42 - 1);
assert(c[1] == 42);
}
{
auto c = a;
c[0] += b[0];
assert(c[0] == 42 + 4);
assert(c[1] == 42);
}
{
auto c = a;
c[0] -= b[0];
assert(c[0] == 42 - 4);
assert(c[1] == 42);
}
{
auto c = a;
c[0] *= b[0];
assert(c[0] == 42 * 4);
assert(c[1] == 42);
}
{
auto c = a;
c[0] /= b[0];
assert(c[0] == 42 / 4);
assert(c[1] == 42);
}
{
auto c = a;
c[0] %= b[0];
assert(c[0] == 42 % 4);
assert(c[1] == 42);
}
{
auto c = a;
c[0] >>= b[0];
assert(c[0] == (42 >> 4));
assert(c[1] == 42);
}
{
auto c = a;
c[0] <<= b[0];
assert(c[0] == (42 << 4));
assert(c[1] == 42);
}
{
auto c = a;
c[0] &= b[0];
assert(c[0] == (42 & 4));
assert(c[1] == 42);
}
{
auto c = a;
c[0] |= b[0];
assert(c[0] == (42 | 4));
assert(c[1] == 42);
}
{
auto c = a;
c[0] ^= b[0];
assert(c[0] == (42 ^ 4));
assert(c[1] == 42);
}
{
auto c = a;
(void)(a[0] + (c[0] += a[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] -= a[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] *= a[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] /= a[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] %= a[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] >>= b[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] <<= b[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] &= a[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] |= a[0]));
}
{
auto c = a;
(void)(a[0] + (c[0] ^= a[0]));
}
}
{
const SimdType a(42);
const SimdType b(4);
static_assert(std::is_same<decltype(a[0]), int>::value, "");
assert(a[0] == 42);
assert(!a[0] == !42);
assert(~a[0] == ~42);
assert(+a[0] == +42);
assert(-a[0] == -42);
assert(a[0] + b[0] == 42 + 4);
assert(a[0] - b[0] == 42 - 4);
assert(a[0] * b[0] == 42 * 4);
assert(a[0] / b[0] == 42 / 4);
assert(a[0] % b[0] == 42 % 4);
assert(a[0] << b[0] == (42 << 4));
assert(a[0] >> b[0] == (42 >> 4));
assert(a[0] < b[0] == false);
assert(a[0] <= b[0] == false);
assert(a[0] > b[0] == true);
assert(a[0] >= b[0] == true);
assert(a[0] == b[0] == false);
assert(a[0] != b[0] == true);
assert((a[0] & b[0]) == (42 & 4));
assert((a[0] | b[0]) == (42 | 4));
assert((a[0] ^ b[0]) == (42 ^ 4));
assert((a[0] && b[0]) == true);
assert((a[0] || b[0]) == true);
}
}
int main() {
test_access<ex::native_simd<int>>();
test_access<ex::fixed_size_simd<int, 4>>();
}