// This file is part of Eigen, a lightweight C++ template library
// for linear algebra.
//
// Copyright (C) 2006-2008 Benoit Jacob <jacob.benoit.1@gmail.com>
//
// This Source Code Form is subject to the terms of the Mozilla
// Public License v. 2.0. If a copy of the MPL was not distributed
// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

#include "main.h"

template <bool IsInteger>
struct adjoint_specific;

template <>
struct adjoint_specific<true> {
  template <typename Vec, typename Mat, typename Scalar>
  static void run(const Vec& v1, const Vec& v2, Vec& v3, const Mat& square, Scalar s1, Scalar s2) {
    VERIFY(test_isApproxWithRef((s1 * v1 + s2 * v2).dot(v3),
                                numext::conj(s1) * v1.dot(v3) + numext::conj(s2) * v2.dot(v3), 0));
    VERIFY(test_isApproxWithRef(v3.dot(s1 * v1 + s2 * v2), s1 * v3.dot(v1) + s2 * v3.dot(v2), 0));

    // check compatibility of dot and adjoint
    VERIFY(test_isApproxWithRef(v1.dot(square * v2), (square.adjoint() * v1).dot(v2), 0));
  }
};

template <>
struct adjoint_specific<false> {
  template <typename Vec, typename Mat, typename Scalar>
  static void run(const Vec& v1, const Vec& v2, Vec& v3, const Mat& square, Scalar s1, Scalar s2) {
    typedef typename NumTraits<Scalar>::Real RealScalar;
    using std::abs;

    RealScalar ref = NumTraits<Scalar>::IsInteger ? RealScalar(0) : (std::max)((s1 * v1 + s2 * v2).norm(), v3.norm());
    VERIFY(test_isApproxWithRef((s1 * v1 + s2 * v2).dot(v3),
                                numext::conj(s1) * v1.dot(v3) + numext::conj(s2) * v2.dot(v3), ref));
    VERIFY(test_isApproxWithRef(v3.dot(s1 * v1 + s2 * v2), s1 * v3.dot(v1) + s2 * v3.dot(v2), ref));

    VERIFY_IS_APPROX(v1.squaredNorm(), v1.norm() * v1.norm());
    // check normalized() and normalize()
    VERIFY_IS_APPROX(v1, v1.norm() * v1.normalized());
    v3 = v1;
    v3.normalize();
    VERIFY_IS_APPROX(v1, v1.norm() * v3);
    VERIFY_IS_APPROX(v3, v1.normalized());
    VERIFY_IS_APPROX(v3.norm(), RealScalar(1));

    // check null inputs
    VERIFY_IS_APPROX((v1 * 0).normalized(), (v1 * 0));
#if (!EIGEN_ARCH_i386) || defined(EIGEN_VECTORIZE)
    RealScalar very_small = (std::numeric_limits<RealScalar>::min)();
    VERIFY(numext::is_exactly_zero((v1 * very_small).norm()));
    VERIFY_IS_APPROX((v1 * very_small).normalized(), (v1 * very_small));
    v3 = v1 * very_small;
    v3.normalize();
    VERIFY_IS_APPROX(v3, (v1 * very_small));
#endif

    // check compatibility of dot and adjoint
    ref = NumTraits<Scalar>::IsInteger ? 0
                                       : (std::max)((std::max)(v1.norm(), v2.norm()),
                                                    (std::max)((square * v2).norm(), (square.adjoint() * v1).norm()));
    VERIFY(internal::isMuchSmallerThan(abs(v1.dot(square * v2) - (square.adjoint() * v1).dot(v2)), ref,
                                       test_precision<Scalar>()));

    // check that Random().normalized() works: tricky as the random xpr must be evaluated by
    // normalized() in order to produce a consistent result.
    VERIFY_IS_APPROX(Vec::Random(v1.size()).normalized().norm(), RealScalar(1));
  }
};

template <typename MatrixType, typename Scalar = typename MatrixType::Scalar>
MatrixType RandomMatrix(Index rows, Index cols, Scalar min, Scalar max) {
  MatrixType M = MatrixType(rows, cols);
  for (Index i = 0; i < rows; ++i) {
    for (Index j = 0; j < cols; ++j) {
      M(i, j) = Eigen::internal::random<Scalar>(min, max);
    }
  }
  return M;
}

template <typename MatrixType>
void adjoint(const MatrixType& m) {
  /* this test covers the following files:
     Transpose.h Conjugate.h Dot.h
  */
  using std::abs;
  typedef typename MatrixType::Scalar Scalar;
  typedef typename NumTraits<Scalar>::Real RealScalar;
  typedef Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> VectorType;
  typedef Matrix<Scalar, MatrixType::RowsAtCompileTime, MatrixType::RowsAtCompileTime> SquareMatrixType;
  const Index PacketSize = internal::packet_traits<Scalar>::size;

  Index rows = m.rows();
  Index cols = m.cols();

  // Avoid integer overflow by limiting input values.
  RealScalar rmin = static_cast<RealScalar>(NumTraits<Scalar>::IsInteger ? NumTraits<Scalar>::IsSigned ? -100 : 0 : -1);
  RealScalar rmax = static_cast<RealScalar>(NumTraits<Scalar>::IsInteger ? 100 : 1);

  MatrixType m1 = RandomMatrix<MatrixType>(rows, cols, rmin, rmax),
             m2 = RandomMatrix<MatrixType>(rows, cols, rmin, rmax), m3(rows, cols),
             square = RandomMatrix<SquareMatrixType>(rows, rows, rmin, rmax);
  VectorType v1 = RandomMatrix<VectorType>(rows, 1, rmin, rmax), v2 = RandomMatrix<VectorType>(rows, 1, rmin, rmax),
             v3 = RandomMatrix<VectorType>(rows, 1, rmin, rmax), vzero = VectorType::Zero(rows);

  Scalar s1 = internal::random<Scalar>(rmin, rmax), s2 = internal::random<Scalar>(rmin, rmax);

  // check basic compatibility of adjoint, transpose, conjugate
  VERIFY_IS_APPROX(m1.transpose().conjugate().adjoint(), m1);
  VERIFY_IS_APPROX(m1.adjoint().conjugate().transpose(), m1);

  // check multiplicative behavior
  VERIFY_IS_APPROX((m1.adjoint() * m2).adjoint(), m2.adjoint() * m1);
  VERIFY_IS_APPROX((s1 * m1).adjoint(), numext::conj(s1) * m1.adjoint());

  // check basic properties of dot, squaredNorm
  VERIFY_IS_APPROX(numext::conj(v1.dot(v2)), v2.dot(v1));
  VERIFY_IS_APPROX(numext::real(v1.dot(v1)), v1.squaredNorm());

  adjoint_specific<NumTraits<Scalar>::IsInteger>::run(v1, v2, v3, square, s1, s2);

  VERIFY_IS_MUCH_SMALLER_THAN(abs(vzero.dot(v1)), static_cast<RealScalar>(1));

  // like in testBasicStuff, test operator() to check const-qualification
  Index r = internal::random<Index>(0, rows - 1), c = internal::random<Index>(0, cols - 1);
  VERIFY_IS_APPROX(m1.conjugate()(r, c), numext::conj(m1(r, c)));
  VERIFY_IS_APPROX(m1.adjoint()(c, r), numext::conj(m1(r, c)));

  // check inplace transpose
  m3 = m1;
  m3.transposeInPlace();
  VERIFY_IS_APPROX(m3, m1.transpose());
  m3.transposeInPlace();
  VERIFY_IS_APPROX(m3, m1);

  if (PacketSize < m3.rows() && PacketSize < m3.cols()) {
    m3 = m1;
    Index i = internal::random<Index>(0, m3.rows() - PacketSize);
    Index j = internal::random<Index>(0, m3.cols() - PacketSize);
    m3.template block<PacketSize, PacketSize>(i, j).transposeInPlace();
    VERIFY_IS_APPROX((m3.template block<PacketSize, PacketSize>(i, j)),
                     (m1.template block<PacketSize, PacketSize>(i, j).transpose()));
    m3.template block<PacketSize, PacketSize>(i, j).transposeInPlace();
    VERIFY_IS_APPROX(m3, m1);
  }

  // check inplace adjoint
  m3 = m1;
  m3.adjointInPlace();
  VERIFY_IS_APPROX(m3, m1.adjoint());
  m3.transposeInPlace();
  VERIFY_IS_APPROX(m3, m1.conjugate());

  // check mixed dot product
  typedef Matrix<RealScalar, MatrixType::RowsAtCompileTime, 1> RealVectorType;
  RealVectorType rv1 = RandomMatrix<RealVectorType>(rows, 1, rmin, rmax);

  VERIFY_IS_APPROX(v1.dot(rv1.template cast<Scalar>()), v1.dot(rv1));
  VERIFY_IS_APPROX(rv1.template cast<Scalar>().dot(v1), rv1.dot(v1));

  VERIFY(is_same_type(m1, m1.template conjugateIf<false>()));
  VERIFY(is_same_type(m1.conjugate(), m1.template conjugateIf<true>()));
}

template <int>
void adjoint_extra() {
  MatrixXcf a(10, 10), b(10, 10);
  VERIFY_RAISES_ASSERT(a = a.transpose());
  VERIFY_RAISES_ASSERT(a = a.transpose() + b);
  VERIFY_RAISES_ASSERT(a = b + a.transpose());
  VERIFY_RAISES_ASSERT(a = a.conjugate().transpose());
  VERIFY_RAISES_ASSERT(a = a.adjoint());
  VERIFY_RAISES_ASSERT(a = a.adjoint() + b);
  VERIFY_RAISES_ASSERT(a = b + a.adjoint());

  // no assertion should be triggered for these cases:
  a.transpose() = a.transpose();
  a.transpose() += a.transpose();
  a.transpose() += a.transpose() + b;
  a.transpose() = a.adjoint();
  a.transpose() += a.adjoint();
  a.transpose() += a.adjoint() + b;

  // regression tests for check_for_aliasing
  MatrixXd c(10, 10);
  c = 1.0 * MatrixXd::Ones(10, 10) + c;
  c = MatrixXd::Ones(10, 10) * 1.0 + c;
  c = c + MatrixXd::Ones(10, 10).cwiseProduct(MatrixXd::Zero(10, 10));
  c = MatrixXd::Ones(10, 10) * MatrixXd::Zero(10, 10);

  // regression for bug 1646
  for (int j = 0; j < 10; ++j) {
    c.col(j).head(j) = c.row(j).head(j);
  }

  for (int j = 0; j < 10; ++j) {
    c.col(j) = c.row(j);
  }

  a.conservativeResize(1, 1);
  a = a.transpose();

  a.conservativeResize(0, 0);
  a = a.transpose();
}

template <typename Scalar>
void inner_product_boundary_sizes() {
  const Index PS = internal::packet_traits<Scalar>::size;
  // Sizes that exercise every branch in the 4-way unrolled vectorized inner product:
  // scalar fallback (< PS), 1-3 packets, quad loop entry/exit, remainder packets, scalar cleanup
  const Index sizes[] = {0,
                         1,
                         PS - 1,
                         PS,
                         PS + 1,
                         2 * PS - 1,
                         2 * PS,
                         2 * PS + 1,
                         3 * PS - 1,
                         3 * PS,
                         3 * PS + 1,
                         4 * PS - 1,
                         4 * PS,
                         4 * PS + 1,
                         8 * PS,
                         8 * PS + 1,
                         8 * PS + PS,
                         8 * PS + 2 * PS,
                         8 * PS + 3 * PS,
                         8 * PS + 3 * PS + 1};
  for (int si = 0; si < 20; ++si) {
    const Index n = sizes[si];
    if (n <= 0) continue;
    typedef Matrix<Scalar, Dynamic, 1> Vec;
    Vec v1 = Vec::Random(n);
    Vec v2 = Vec::Random(n);
    // Reference: scalar loop
    Scalar expected(0);
    for (Index k = 0; k < n; ++k) expected += numext::conj(v1(k)) * v2(k);
    VERIFY_IS_APPROX(v1.dot(v2), expected);
    // Also test squaredNorm
    Scalar sq_expected(0);
    for (Index k = 0; k < n; ++k) sq_expected += numext::conj(v1(k)) * v1(k);
    VERIFY_IS_APPROX(v1.squaredNorm(), numext::real(sq_expected));
  }
}

// Test transposeInPlace at vectorization boundary sizes.
// BlockedInPlaceTranspose uses PacketSize-blocked loops with a scalar remainder (line 273),
// exercising off-by-one-prone transitions.
template <typename Scalar>
void transposeInPlace_boundary() {
  const Index PS = internal::packet_traits<Scalar>::size;
  // Sizes around packet boundaries where the blocked path's remainder handling is exercised.
  const Index sizes[] = {1,      2,          3,      PS - 1,     PS,     PS + 1,    2 * PS - 1,
                         2 * PS, 2 * PS + 1, 3 * PS, 3 * PS + 1, 4 * PS, 4 * PS + 1};
  for (int si = 0; si < 13; ++si) {
    Index n = sizes[si];
    if (n <= 0) continue;
    typedef Matrix<Scalar, Dynamic, Dynamic> Mat;

    // Square transposeInPlace
    Mat m1 = Mat::Random(n, n);
    Mat m2 = m1;
    m2.transposeInPlace();
    VERIFY_IS_APPROX(m2, m1.transpose());
    // Double transpose should return to original
    m2.transposeInPlace();
    VERIFY_IS_APPROX(m2, m1);
  }

  // Non-square transposeInPlace (resizable dynamic matrices)
  const Index rect_sizes[][2] = {{2, 5}, {PS, 2 * PS + 1}, {3, 1}, {1, 7}, {2 * PS, PS + 1}};
  for (int si = 0; si < 5; ++si) {
    Index r = rect_sizes[si][0], c = rect_sizes[si][1];
    if (r <= 0 || c <= 0) continue;
    typedef Matrix<Scalar, Dynamic, Dynamic> Mat;
    Mat m1 = Mat::Random(r, c);
    Mat expected = m1.transpose();
    Mat m2 = m1;
    m2.transposeInPlace();
    VERIFY_IS_APPROX(m2, expected);
    VERIFY(m2.rows() == c && m2.cols() == r);
  }
}

EIGEN_DECLARE_TEST(adjoint) {
  for (int i = 0; i < g_repeat; i++) {
    CALL_SUBTEST_1(adjoint(Matrix<float, 1, 1>()));
    CALL_SUBTEST_2(adjoint(Matrix3d()));
    CALL_SUBTEST_3(adjoint(Matrix4f()));

    CALL_SUBTEST_4(adjoint(MatrixXcf(internal::random<int>(1, EIGEN_TEST_MAX_SIZE / 2),
                                     internal::random<int>(1, EIGEN_TEST_MAX_SIZE / 2))));
    CALL_SUBTEST_5(adjoint(
        MatrixXi(internal::random<int>(1, EIGEN_TEST_MAX_SIZE), internal::random<int>(1, EIGEN_TEST_MAX_SIZE))));
    CALL_SUBTEST_6(adjoint(
        MatrixXf(internal::random<int>(1, EIGEN_TEST_MAX_SIZE), internal::random<int>(1, EIGEN_TEST_MAX_SIZE))));

    // Complement for 128 bits vectorization:
    CALL_SUBTEST_8(adjoint(Matrix2d()));
    CALL_SUBTEST_9(adjoint(Matrix<int, 4, 4>()));

    // 256 bits vectorization:
    CALL_SUBTEST_10(adjoint(Matrix<float, 8, 8>()));
    CALL_SUBTEST_11(adjoint(Matrix<double, 4, 4>()));
    CALL_SUBTEST_12(adjoint(Matrix<int, 8, 8>()));
  }
  // test a large static matrix only once
  CALL_SUBTEST_7(adjoint(Matrix<float, 100, 100>()));

  CALL_SUBTEST_13(adjoint_extra<0>());

  // Inner product vectorization boundary tests (deterministic, outside g_repeat)
  CALL_SUBTEST_14(inner_product_boundary_sizes<float>());
  CALL_SUBTEST_15(inner_product_boundary_sizes<double>());
  CALL_SUBTEST_16(inner_product_boundary_sizes<std::complex<float>>());
  CALL_SUBTEST_17(inner_product_boundary_sizes<std::complex<double>>());

  // transposeInPlace at vectorization boundaries (deterministic, outside g_repeat).
  CALL_SUBTEST_18(transposeInPlace_boundary<float>());
  CALL_SUBTEST_18(transposeInPlace_boundary<double>());
  CALL_SUBTEST_18(transposeInPlace_boundary<std::complex<float>>());
}