412 lines
No EOL
20 KiB
C++
412 lines
No EOL
20 KiB
C++
/*
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Crafter® Build
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Copyright (C) 2026 Catcrafts®
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Catcrafts.net
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This library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License version 3.0 as published by the Free Software Foundation;
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This library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public
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License along with this library; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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*/
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#include <cmath>
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import Crafter.Math;
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import std;
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using namespace Crafter;
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// Helper function to compare floating point values with tolerance
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template <typename T>
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constexpr bool FloatEquals(T a, T b, T epsilon = 0.001f) {
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return std::abs(static_cast<float>(a) - static_cast<float>(b)) < static_cast<float>(epsilon);
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}
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template <std::uint8_t Len>
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consteval std::array<bool, Len> AlternateTrueFalse() {
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std::array<bool, Len> result = {};
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for (std::uint8_t i = 0; i < Len; ++i) {
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result[i] = (i % 2 == 0); // Set true for even indices, false for odd indices
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}
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return result;
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}
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template <typename T, template<std::uint32_t, std::uint32_t> class VectorType, std::uint32_t MaxSize, std::uint32_t Len = 1, std::uint32_t Packing = 1>
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std::string* TestAllCombinations() {
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if constexpr (Len > MaxSize) {
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return nullptr;
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} else if constexpr (Len * Packing > MaxSize) {
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return TestAllCombinations<T, VectorType, MaxSize, Len + 1, 1>();
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} else {
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T floats[VectorType<Len, Packing>::Alignment];
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T floats1[VectorType<Len, Packing>::Alignment];
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T floats2[VectorType<Len, Packing>::Alignment];
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for (std::uint32_t i = 0; i < VectorType<Len, Packing>::Alignment; i++) {
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floats[i] = static_cast<T>(i+1);
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}
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for (std::uint32_t i = 0; i < Packing*Len; i++) {
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floats1[i] = static_cast<T>(i+1);
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}
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for (std::uint32_t i = 0; i < Packing*Len; i++) {
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floats2[i] = static_cast<T>(i+1+Len);
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}
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for (std::uint32_t i = Len*Packing; i < VectorType<Len, Packing>::Alignment; i++) {
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floats1[i] = 0;
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floats2[i] = 0;
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}
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std::string* result = nullptr;
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constexpr auto total = Len * Packing;
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if constexpr(total > 0 && (total & (total - 1)) == 0) {
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{
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VectorType<Len, Packing> vec(floats);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], floats[i])) {
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return new std::string(std::format("Load/Store mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(floats[i]), (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec + vec;
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], floats[i] + floats[i])) {
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return new std::string(std::format("Add mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(floats[i] + floats[i]), (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec - vec;
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], T(0))) {
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return new std::string(std::format("Subtract mismatch at Len={} Packing={}, Expected: 0, Got: {}", Len, Packing, (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec * vec;
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], floats[i] * floats[i])) {
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return new std::string(std::format("Multiply mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(floats[i] * floats[i]), (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec / vec;
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], T(1))) {
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return new std::string(std::format("Divide mismatch at Len={} Packing={}, Expected: 1, Got: {}", Len, Packing, (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec + T(2);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], floats[i] + T(2))) {
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return new std::string(std::format("Scalar add mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(floats[i] + T(2)), (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec - T(2);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], floats[i] - T(2))) {
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return new std::string(std::format("Scalar add mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(floats[i] + T(2)), (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec * T(2);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], floats[i] * T(2))) {
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return new std::string(std::format("Scalar multiply mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(floats[i] * T(2)), (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = vec / T(2);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(stored.v[i], floats[i] / T(2))) {
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return new std::string(std::format("Scalar multiply mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(floats[i] * T(2)), (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vec1(floats);
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VectorType<Len, Packing> vec2(floats);
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if (!(vec1 == vec2)) {
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return new std::string(std::format("Equality 1 test failed at Len={} Packing={}", Len, Packing));
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}
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}
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{
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VectorType<Len, Packing> vec1(floats);
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VectorType<Len, Packing> vec2(floats);
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vec2 *= 2;
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if (vec1 == vec2) {
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return new std::string(std::format("Equality 2 test failed at Len={} Packing={}", Len, Packing));
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}
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}
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{
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VectorType<Len, Packing> vec1(floats);
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VectorType<Len, Packing> vec2(floats);
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if ((vec1 != vec2)) {
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return new std::string(std::format("Inequality 1 test failed at Len={} Packing={}", Len, Packing));
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}
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}
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{
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VectorType<Len, Packing> vec1(floats);
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VectorType<Len, Packing> vec2(floats);
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vec2 *= 2;
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if (!(vec1 != vec2)) {
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return new std::string(std::format("Inequality 2 test failed at Len={} Packing={}", Len, Packing));
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec = -vec;
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> result = vec.Store();
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for (std::uint32_t i = 0; i < Len * Packing; i++) {
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if (!FloatEquals(result.v[i], -floats[i])) {
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return new std::string(std::format("Negate mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)(-floats[i]), (float)result.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vecA(floats1);
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VectorType<Len, Packing> vecB(floats2);
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VectorType<Len, Packing> result = VectorType<Len, Packing>::template Blend<AlternateTrueFalse<Len>()>(vecA, vecB);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = result.Store();
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for (std::uint32_t i = 0; i < Len; i++) {
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bool useB = (i % 2 == 0);
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T expected = useB ? floats2[i]: floats1[i];
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if (!FloatEquals(stored.v[i], expected)) {
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return new std::string(std::format("Blend mismatch at Len={} Packing={}, Index={}, Expected: {}, Got: {}", Len, Packing, i, (float)expected, (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vecA(floats);
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VectorType<Len, Packing> vecB(floats);
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VectorType<Len, Packing> vecAdd(floats);
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VectorType<Len, Packing> result = VectorType<Len, Packing>::MulitplyAdd(vecA, vecB, vecAdd);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = result.Store();
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for (std::uint32_t i = 0; i < Len; i++) {
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T expected = floats[i] * floats[i] + floats[i];
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if (!FloatEquals(stored.v[i], expected)) {
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return new std::string(std::format("MulitplyAdd mismatch at Len={} Packing={}, Index={}, Expected: {}, Got: {}", Len, Packing, i, (float)expected, (float)stored.v[i]));
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}
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}
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}
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{
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VectorType<Len, Packing> vecA(floats);
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VectorType<Len, Packing> vecB(floats);
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VectorType<Len, Packing> vecSub(floats);
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VectorType<Len, Packing> result = VectorType<Len, Packing>::MulitplySub(vecA, vecB, vecSub);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = result.Store();
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for (std::uint32_t i = 0; i < Len; i++) {
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T expected = floats[i] * floats[i] - floats[i];
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if (!FloatEquals(stored.v[i], expected)) {
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return new std::string(std::format("MulitplySub mismatch at Len={} Packing={}, Index={}, Expected: {}, Got: {}", Len, Packing, i, (float)expected, (float)stored.v[i]));
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}
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}
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}
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}
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if constexpr(Packing == 1) {
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T expectedLengthSq = T(0);
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for (std::uint32_t i = 0; i < VectorType<Len, Packing>::Alignment; i++) {
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expectedLengthSq += floats[i] * floats[i];
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}
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{
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VectorType<Len, Packing> vec(floats);
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T dot = VectorType<Len, Packing>::Dot(vec, vec);
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if (!FloatEquals(dot, expectedLengthSq)) {
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return new std::string(std::format("Dot product mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)expectedLengthSq, (float)dot));
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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T lengthSq = vec.LengthSq();
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if (!FloatEquals(lengthSq, expectedLengthSq)) {
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return new std::string(std::format("LengthSq mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (float)expectedLengthSq, (float)lengthSq));
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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T length = vec.Length();
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if (!FloatEquals(length, static_cast<T>(std::sqrtf(static_cast<float>(expectedLengthSq))))) {
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return new std::string(std::format("Length mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, (std::sqrtf(static_cast<float>(expectedLengthSq))), (float)length));
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}
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}
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{
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VectorType<Len, Packing> vec(floats);
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vec.Normalize();
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T length = vec.Length();
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if (!FloatEquals(length, static_cast<T>(1))) {
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return new std::string(std::format("Normalize mismatch at Len={} Packing={}, Expected: {}, Got: {}", Len, Packing, 1, (float)length));
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}
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}
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}
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if constexpr(Len == 3) {
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{
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VectorType<Len, Packing> vec1(floats1);
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VectorType<Len, Packing> vec2(floats2);
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VectorType<Len, Packing> result = VectorType<Len, Packing>::Cross(vec1, vec2);
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Vector<T, Len*Packing, VectorType<Len, Packing>::Alignment> stored = result.Store();
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if (!FloatEquals(stored.v[0], T(-3)) || !FloatEquals(stored.v[1], T(6)) || !FloatEquals(stored.v[2], T(-3))) {
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return new std::string(std::format("Cross mismatch at Len={} Packing={}, Expected: -3,6,-3, Got: {},{},{}", Len, Packing, (float)stored.v[0], (float)stored.v[1], (float)stored.v[2]));
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}
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}
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if constexpr(4 * Packing < VectorType<1, 1>::MaxSize) {
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T qData[4];
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qData[0] = T(1);
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qData[1] = T(0);
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qData[2] = T(0);
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qData[3] = T(0);
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VectorType<3, Packing> vecV(floats);
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VectorType<4, Packing> vecQ(qData);
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VectorType<3, Packing> result = VectorType<3, Packing>::Rotate(vecV, vecQ);
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Vector<T, 3*Packing, VectorType<3, Packing>::Alignment> stored = result.Store();
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for (std::uint32_t i = 0; i < 3; i++) {
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if (!FloatEquals(stored.v[i], floats[i])) {
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return new std::string(std::format("Rotate mismatch at Len={} Packing={}, Index={}, Expected: {}, Got: {}", Len, Packing, i, (float)floats[i], (float)stored.v[i]));
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}
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}
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}
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}
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// // Test QuanternionFromEuler() static method (Len == 4 only)
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// if constexpr(Len == 4) {
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// T eulerData[3] = {T(0), T(0), T(0)}; // Zero rotation
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// VectorType<3, 1> eulerVec(eulerData);
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// VectorType<4, 1> result = VectorType<4, 1>::QuanternionFromEuler(eulerVec);
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// Vector<T, 4, 8> stored = result.Store();
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// // Identity quaternion should be (1, 0, 0, 0)
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// if (!FloatEquals(stored.v[0], T(1)) || !FloatEquals(stored.v[1], T(0)) ||
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// !FloatEquals(stored.v[2], T(0)) || !FloatEquals(stored.v[3], T(0))) {
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// return new std::string(std::format("QuanternionFromEuler mismatch at Len={} Packing={}, Expected: 1,0,0,0, Got: {},{},{},{}", Len, Packing, (float)stored.v[0], (float)stored.v[1], (float)stored.v[2], (float)stored.v[3]));
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// }
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// }
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// // Test batch Normalize() for 2 vectors (Len == 2)
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// if constexpr(Len == 2) {
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// T aData[2] = {T(3), T(4)};
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// T eData[2] = {T(6), T(8)};
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// VectorType<2, 1> vecA(aData);
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// VectorType<2, 1> vecE(eData);
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// auto result = VectorType<2, 1>::Normalize(vecA, vecE);
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// Vector<T, 2, 8> storedA = std::get<0>(result).Store();
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// Vector<T, 2, 8> storedE = std::get<1>(result).Store();
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// // Normalize (3,4) -> (0.6, 0.8)
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// for (std::uint32_t i = 0; i < 2; i++) {
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// if (!FloatEquals(storedA.v[i], static_cast<T>(0.6f + i * 0.2f))) {
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// return new std::string(std::format("Normalize 2 vec test failed (A) at index {}, Expected: {}, Got: {}", i, (float)(0.6f + i * 0.2f), (float)storedA.v[i]));
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// }
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// }
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// // Normalize (6,8) -> (0.6, 0.8)
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// for (std::uint32_t i = 0; i < 2; i++) {
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// if (!FloatEquals(storedE.v[i], static_cast<T>(0.6f + i * 0.2f))) {
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// return new std::string(std::format("Normalize 2 vec test failed (E) at index {}, Expected: {}, Got: {}", i, (float)(0.6f + i * 0.2f), (float)storedE.v[i]));
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// }
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// }
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// }
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// // Test batch LengthSq() for 2 vectors (Len == 2)
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// if constexpr(Len == 2) {
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// T aData[2] = {T(3), T(4)};
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// T eData[2] = {T(5), T(12)};
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// VectorType<2, 1> vecA(aData);
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// VectorType<2, 1> vecE(eData);
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// VectorType<2, 1> result = VectorType<2, 1>::LengthSq(vecA, vecE);
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// Vector<T, 2, 8> stored = result.Store();
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// // LengthSq of (3,4) = 9+16 = 25
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// // LengthSq of (5,12) = 25+144 = 169
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// if (!FloatEquals(stored.v[0], T(25)) || !FloatEquals(stored.v[1], T(169))) {
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// return new std::string(std::format("LengthSq 2 vec test failed at Len={} Packing={}, Expected: 25,169, Got: {},{}", Len, Packing, (float)stored.v[0], (float)stored.v[1]));
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// }
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// }
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// // Test batch Dot() for 2 vectors (Len == 2)
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// if constexpr(Len == 2) {
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// T a0Data[2] = {T(1), T(2)};
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// T a1Data[2] = {T(3), T(4)};
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// T e0Data[2] = {T(5), T(6)};
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// T e1Data[2] = {T(7), T(8)};
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// VectorType<2, 1> vecA0(a0Data);
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// VectorType<2, 1> vecA1(a1Data);
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// VectorType<2, 1> vecE0(e0Data);
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// VectorType<2, 1> vecE1(e1Data);
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// VectorType<2, 1> result = VectorType<2, 1>::Dot(vecA0, vecA1, vecE0, vecE1);
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// Vector<T, 2, 8> stored = result.Store();
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// // Dot (1,2) with (3,4) = 3+8=11
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// // Dot (5,6) with (7,8) = 35+48=83
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// if (!FloatEquals(stored.v[0], T(11)) || !FloatEquals(stored.v[1], T(83))) {
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// return new std::string(std::format("Dot 2 vec test failed at Len={} Packing={}, Expected: 11,83, Got: {},{}", Len, Packing, (float)stored.v[0], (float)stored.v[1]));
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// }
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// }
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|
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return TestAllCombinations<T, VectorType, MaxSize, Len, Packing + 1>();
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}
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}
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|
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extern "C" {
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std::string* RunTest() {
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std::string* err = TestAllCombinations<_Float16, VectorF16, VectorF16<1, 1>::MaxSize>();
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|
if (err) {
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|
return err;
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|
}
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|
return nullptr;
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|
}
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|
} |