12 #include <Eigen/CXX11/Tensor> 19 template<
int DataLayout>
54 Evaluator2 eval2(mat1.contract(mat2, dims4),
DefaultDevice());
55 eval2.evalTo(mat5.
data());
69 Evaluator3 eval3(mat1.contract(mat3, dims6),
DefaultDevice());
70 eval3.evalTo(mat6.
data());
81 template<
int DataLayout>
94 for (
int i = 0;
i < 6; ++
i) {
95 expected +=
vec1(
i) * vec2(
i);
100 template<
int DataLayout>
120 VERIFY_IS_APPROX(mat3(0,0,0),
mat1(0,0,0)*mat2(0,0,0,0) +
mat1(0,1,0)*mat2(0,0,1,0) +
121 mat1(0,0,1)*mat2(0,0,0,1) +
mat1(0,1,1)*mat2(0,0,1,1));
122 VERIFY_IS_APPROX(mat3(0,0,1),
mat1(0,0,0)*mat2(0,1,0,0) +
mat1(0,1,0)*mat2(0,1,1,0) +
123 mat1(0,0,1)*mat2(0,1,0,1) +
mat1(0,1,1)*mat2(0,1,1,1));
124 VERIFY_IS_APPROX(mat3(0,1,0),
mat1(0,0,0)*mat2(1,0,0,0) +
mat1(0,1,0)*mat2(1,0,1,0) +
125 mat1(0,0,1)*mat2(1,0,0,1) +
mat1(0,1,1)*mat2(1,0,1,1));
126 VERIFY_IS_APPROX(mat3(0,1,1),
mat1(0,0,0)*mat2(1,1,0,0) +
mat1(0,1,0)*mat2(1,1,1,0) +
127 mat1(0,0,1)*mat2(1,1,0,1) +
mat1(0,1,1)*mat2(1,1,1,1));
128 VERIFY_IS_APPROX(mat3(1,0,0),
mat1(1,0,0)*mat2(0,0,0,0) +
mat1(1,1,0)*mat2(0,0,1,0) +
129 mat1(1,0,1)*mat2(0,0,0,1) +
mat1(1,1,1)*mat2(0,0,1,1));
130 VERIFY_IS_APPROX(mat3(1,0,1),
mat1(1,0,0)*mat2(0,1,0,0) +
mat1(1,1,0)*mat2(0,1,1,0) +
131 mat1(1,0,1)*mat2(0,1,0,1) +
mat1(1,1,1)*mat2(0,1,1,1));
132 VERIFY_IS_APPROX(mat3(1,1,0),
mat1(1,0,0)*mat2(1,0,0,0) +
mat1(1,1,0)*mat2(1,0,1,0) +
133 mat1(1,0,1)*mat2(1,0,0,1) +
mat1(1,1,1)*mat2(1,0,1,1));
134 VERIFY_IS_APPROX(mat3(1,1,1),
mat1(1,0,0)*mat2(1,1,0,0) +
mat1(1,1,0)*mat2(1,1,1,0) +
135 mat1(1,0,1)*mat2(1,1,0,1) +
mat1(1,1,1)*mat2(1,1,1,1));
147 Evaluator2 eval2(mat4.contract(mat5, dims2),
DefaultDevice());
148 eval2.evalTo(mat6.
data());
153 mat4(0,1)*mat5(1,0,0) + mat4(1,1)*mat5(1,1,0));
155 mat4(0,1)*mat5(1,0,1) + mat4(1,1)*mat5(1,1,1));
158 template<
int DataLayout>
173 for (
int i = 0;
i < 5; ++
i) {
174 for (
int j = 0;
j < 5; ++
j) {
175 for (
int k = 0; k < 5; ++k) {
176 for (
int l = 0;
l < 5; ++
l) {
177 for (
int m = 0;
m < 5; ++
m) {
179 t1(0,
i,
j, 0) * t2(0, k,
l,
m, 0) +
180 t1(1,
i,
j, 0) * t2(1, k,
l,
m, 0) +
181 t1(0,
i,
j, 1) * t2(0, k,
l,
m, 1) +
182 t1(1,
i,
j, 1) * t2(1, k,
l,
m, 1) +
183 t1(0,
i,
j, 2) * t2(0, k,
l,
m, 2) +
184 t1(1,
i,
j, 2) * t2(1, k,
l,
m, 2));
192 template<
int DataLayout>
204 + t1(0, 1) * t2(0, 1, 0) + t1(1, 1) * t2(1, 1, 0));
206 + t1(0, 1) * t2(0, 1, 1) + t1(1, 1) * t2(1, 1, 1));
210 result = t2.contract(t1, dims);
213 + t1(0, 1) * t2(0, 0, 1) + t1(1, 1) * t2(0, 1, 1));
215 + t1(0, 1) * t2(1, 0, 1) + t1(1, 1) * t2(1, 1, 1));
218 template<
int DataLayout>
231 auto contract1 = t1.contract(t2, dims);
232 auto diff = t3 - contract1;
233 auto contract2 = t1.contract(t4, dims);
251 template<
int DataLayout>
262 mat3 = mat1.contract(mat2, dims);
270 template<
int DataLayout>
282 mat3 = mat1.contract(mat2, dims);
285 mat1(0,0,0)*mat2(0,0,0) +
mat1(1,0,0)*mat2(0,0,1) +
286 mat1(0,0,1)*mat2(1,0,0) +
mat1(1,0,1)*mat2(1,0,1));
288 mat1(0,1,0)*mat2(0,0,0) +
mat1(1,1,0)*mat2(0,0,1) +
289 mat1(0,1,1)*mat2(1,0,0) +
mat1(1,1,1)*mat2(1,0,1));
291 mat1(0,0,0)*mat2(0,1,0) +
mat1(1,0,0)*mat2(0,1,1) +
292 mat1(0,0,1)*mat2(1,1,0) +
mat1(1,0,1)*mat2(1,1,1));
294 mat1(0,1,0)*mat2(0,1,0) +
mat1(1,1,0)*mat2(0,1,1) +
295 mat1(0,1,1)*mat2(1,1,0) +
mat1(1,1,1)*mat2(1,1,1));
298 mat3 = mat1.contract(mat2, dims2);
301 mat1(0,0,0)*mat2(0,0,0) +
mat1(1,0,0)*mat2(0,0,1) +
302 mat1(0,0,1)*mat2(1,0,0) +
mat1(1,0,1)*mat2(1,0,1));
304 mat1(0,1,0)*mat2(0,0,0) +
mat1(1,1,0)*mat2(0,0,1) +
305 mat1(0,1,1)*mat2(1,0,0) +
mat1(1,1,1)*mat2(1,0,1));
307 mat1(0,0,0)*mat2(0,1,0) +
mat1(1,0,0)*mat2(0,1,1) +
308 mat1(0,0,1)*mat2(1,1,0) +
mat1(1,0,1)*mat2(1,1,1));
310 mat1(0,1,0)*mat2(0,1,0) +
mat1(1,1,0)*mat2(0,1,1) +
311 mat1(0,1,1)*mat2(1,1,0) +
mat1(1,1,1)*mat2(1,1,1));
315 template<
int DataLayout>
332 mat3 = mat1.contract(mat2, dims1);
333 mat4 = mat2.contract(mat1, dims2);
337 for (
size_t i = 0;
i < 5;
i++) {
338 for (
size_t j = 0;
j < 10;
j++) {
344 for (
size_t i = 0;
i < 5;
i++) {
345 for (
size_t j = 0;
j < 10;
j++) {
352 template<
int DataLayout>
363 t_left += t_left.constant(1.0
f);
364 t_right += t_right.constant(1.0
f);
367 MapXf m_left(t_left.
data(), 1500, 248);
368 MapXf m_right(t_right.
data(), 248, 1400);
375 t_result = t_left.contract(t_right, dims);
376 m_result = m_left * m_right;
384 template<
int DataLayout>
395 MapXf m_left(t_left.
data(), 30, 50);
396 MapXf m_right(t_right.
data(), 50, 1);
403 t_result = t_left.contract(t_right, dims);
404 m_result = m_left * m_right;
412 template<
int DataLayout>
426 MapXf m_left(t_left.
data(), 7, 13*17);
427 MapXf m_right(t_right.
data(), 1, 7);
436 template<
int DataLayout>
445 t_left += t_left.constant(1.0
f);
446 t_right += t_right.constant(1.0
f);
454 t_result = t_left.contract(t_right, dims);
466 template<
int DataLayout>
482 for (
int k = 0; k < result.
dimension(2); ++k) {
492 template<
int DataLayout>
505 mat3 =
mat1.contract(mat2, dims);
525 CALL_SUBTEST(test_contraction_of_contraction<ColMajor>());
526 CALL_SUBTEST(test_contraction_of_contraction<RowMajor>());
529 CALL_SUBTEST(test_out_of_order_contraction<ColMajor>());
530 CALL_SUBTEST(test_out_of_order_contraction<RowMajor>());
void setCpuCacheSizes(std::ptrdiff_t l1, std::ptrdiff_t l2, std::ptrdiff_t l3)
static void test_scalar()
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Index dimension(std::size_t n) const
void test_cxx11_tensor_contraction()
static void test_consistency()
static void test_large_contraction()
A matrix or vector expression mapping an existing array of data.
static void test_matrix_vector()
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Tensor< Scalar_, NumIndices_, Options_, IndexType_ > & setRandom()
static void test_small_blocking_factors()
A cost model used to limit the number of threads used for evaluating tensor expression.
static void test_tensor_product()
#define EIGEN_STATIC_ASSERT(CONDITION, MSG)
MatrixXd mat1(size, size)
#define VERIFY_IS_APPROX(a, b)
static const Line3 l(Rot3(), 1, 1)
#define VERIFY_IS_EQUAL(a, b)
A tensor expression mapping an existing array of data.
static void test_contraction_of_contraction()
Tensor< float, 1 >::DimensionPair DimPair
static void test_out_of_order_contraction()
Point2(* f)(const Point3 &, OptionalJacobian< 2, 3 >)
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE DenseIndex TotalSize() const
static void test_const_inputs()
static void test_multidims()
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar * data()
#define CALL_SUBTEST(FUNC)
static void test_tensor_vector()
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Dimensions & dimensions() const
internal::nested_eval< T, 1 >::type eval(const T &xpr)
The matrix class, also used for vectors and row-vectors.
EIGEN_DEVICE_FUNC bool isApprox(const Scalar &x, const Scalar &y, const typename NumTraits< Scalar >::Real &precision=NumTraits< Scalar >::dummy_precision())
mxArray * scalar(mxClassID classid)
static void test_full_redux()
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Tensor< Scalar_, NumIndices_, Options_, IndexType_ > & setZero()