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	// Copyright © 2023-2024 Apple Inc.

	#include "doctest/doctest.h"

	#include <cmath>

	#include "mlx/mlx.h"
	#include "mlx/ops.h"

	using namespace mlx::core;
	using namespace mlx::core::linalg;

	TEST_CASE("[mlx.core.linalg.norm] no ord") {
	// Zero dimensions
	array x(2.0);
	CHECK_EQ(norm(x).item<float>(), 2.0f);
	CHECK_THROWS(norm(x, 0));

	x = array({1, 2, 3});
	float expected = std::sqrt(1 + 4 + 9);
	CHECK_EQ(norm(x).item<float>(), doctest::Approx(expected));
	CHECK_EQ(norm(x, 0, false).item<float>(), doctest::Approx(expected));
	CHECK_EQ(norm(x, -1, false).item<float>(), doctest::Approx(expected));
	CHECK_EQ(norm(x, -1, true).ndim(), 1);
	CHECK_THROWS(norm(x, 1));

	x = reshape(arange(9), {3, 3});
	expected =
	std::sqrt(0 + 1 + 2 * 2 + 3 * 3 + 4 * 4 + 5 * 5 + 6 * 6 + 7 * 7 + 8 * 8);

	CHECK_EQ(norm(x).item<float>(), doctest::Approx(expected));
	CHECK_EQ(
	norm(x, std::vector<int>{0, 1}).item<float>(), doctest::Approx(expected));
	CHECK(allclose(
	norm(x, 0, false),
	array(
	{std::sqrt(0 + 3 * 3 + 6 * 6),
	std::sqrt(1 + 4 * 4 + 7 * 7),
	std::sqrt(2 * 2 + 5 * 5 + 8 * 8)}))
	.item<bool>());
	CHECK(allclose(
	norm(x, 1, false),
	array(
	{std::sqrt(0 + 1 + 2 * 2),
	std::sqrt(3 * 3 + 4 * 4 + 5 * 5),
	std::sqrt(6 * 6 + 7 * 7 + 8 * 8)}))
	.item<bool>());

	x = reshape(arange(18), {2, 3, 3});
	CHECK(allclose(
	norm(x, 2, false),
	array(
	{
	std::sqrt(0 + 1 + 2 * 2),
	std::sqrt(3 * 3 + 4 * 4 + 5 * 5),
	std::sqrt(6 * 6 + 7 * 7 + 8 * 8),
	std::sqrt(9 * 9 + 10 * 10 + 11 * 11),
	std::sqrt(12 * 12 + 13 * 13 + 14 * 14),
	std::sqrt(15 * 15 + 16 * 16 + 17 * 17),
	},
	{2, 3}))
	.item<bool>());
	CHECK(allclose(
	norm(x, std::vector<int>{1, 2}, false),
	array(
	{std::sqrt(
	0 + 1 + 2 * 2 + 3 * 3 + 4 * 4 + 5 * 5 + 6 * 6 + 7 * 7 +
	8 * 8),
	std::sqrt(
	9 * 9 + 10 * 10 + 11 * 11 + 12 * 12 + 13 * 13 + 14 * 14 +
	15 * 15 + 16 * 16 + 17 * 17)},
	{2}))
	.item<bool>());
	CHECK_THROWS(norm(x, std::vector<int>{0, 1, 2}));
	}

	TEST_CASE("[mlx.core.linalg.norm] double ord") {
	CHECK_THROWS(norm(array(0), 2.0));

	array x({1, 2, 3});

	float expected = std::sqrt(1 + 4 + 9);
	CHECK_EQ(norm(x, 2.0).item<float>(), doctest::Approx(expected));
	CHECK_EQ(norm(x, 2.0, 0).item<float>(), doctest::Approx(expected));
	CHECK_THROWS(norm(x, 2.0, 1));

	expected = 1 + 2 + 3;
	CHECK_EQ(norm(x, 1.0).item<float>(), doctest::Approx(expected));

	expected = 3;
	CHECK_EQ(norm(x, 0.0).item<float>(), doctest::Approx(expected));

	expected = 3;
	CHECK_EQ(
	norm(x, std::numeric_limits<double>::infinity()).item<float>(),
	doctest::Approx(expected));

	expected = 1;
	CHECK_EQ(
	norm(x, -std::numeric_limits<double>::infinity()).item<float>(),
	doctest::Approx(expected));

	x = reshape(arange(9, float32), {3, 3});

	CHECK(allclose(
	norm(x, 2.0, 0, false),
	array(
	{std::sqrt(0 + 3 * 3 + 6 * 6),
	std::sqrt(1 + 4 * 4 + 7 * 7),
	std::sqrt(2 * 2 + 5 * 5 + 8 * 8)}))
	.item<bool>());
	CHECK(allclose(
	norm(x, 2.0, 1, false),
	array(
	{sqrt(0 + 1 + 2 * 2),
	sqrt(3 * 3 + 4 * 4 + 5 * 5),
	sqrt(6 * 6 + 7 * 7 + 8 * 8)}))
	.item<bool>());

	CHECK_EQ(
	norm(x, 1.0, std::vector<int>{0, 1}).item<float>(),
	doctest::Approx(15.0));
	CHECK_EQ(
	norm(x, 1.0, std::vector<int>{1, 0}).item<float>(),
	doctest::Approx(21.0));
	CHECK_EQ(
	norm(x, -1.0, std::vector<int>{0, 1}).item<float>(),
	doctest::Approx(9.0));
	CHECK_EQ(
	norm(x, -1.0, std::vector<int>{1, 0}).item<float>(),
	doctest::Approx(3.0));
	CHECK_EQ(
	norm(x, 2.0, std::vector<int>{0, 1}, false, Device::cpu).item<float>(),
	doctest::Approx(14.226707));
	CHECK_EQ(
	norm(x, 2.0, std::vector<int>{1, 0}, false, Device::cpu).item<float>(),
	doctest::Approx(14.226707));
	CHECK_EQ(
	norm(x, -2.0, std::vector<int>{0, 1}, false, Device::cpu).item<float>(),
	doctest::Approx(0.0));
	CHECK_EQ(
	norm(x, -2.0, std::vector<int>{1, 0}, false, Device::cpu).item<float>(),
	doctest::Approx(0.0));
	CHECK_EQ(norm(x, 1.0, std::vector<int>{0, 1}, true).shape(), Shape{1, 1});
	CHECK_EQ(norm(x, 1.0, std::vector<int>{1, 0}, true).shape(), Shape{1, 1});
	CHECK_EQ(norm(x, -1.0, std::vector<int>{0, 1}, true).shape(), Shape{1, 1});
	CHECK_EQ(norm(x, -1.0, std::vector<int>{1, 0}, true).shape(), Shape{1, 1});
	CHECK_EQ(
	norm(x, 2.0, std::vector<int>{0, 1}, true, Device::cpu).shape(),
	Shape{1, 1});
	CHECK_EQ(
	norm(x, 2.0, std::vector<int>{1, 0}, true, Device::cpu).shape(),
	Shape{1, 1});
	CHECK_EQ(
	norm(x, -2.0, std::vector<int>{0, 1}, true, Device::cpu).shape(),
	Shape{1, 1});
	CHECK_EQ(
	norm(x, -2.0, std::vector<int>{1, 0}, true, Device::cpu).shape(),
	Shape{1, 1});

	CHECK_EQ(
	norm(x, -1.0, std::vector<int>{-2, -1}, false).item<float>(),
	doctest::Approx(9.0));
	CHECK_EQ(
	norm(x, 1.0, std::vector<int>{-2, -1}, false).item<float>(),
	doctest::Approx(15.0));
	CHECK_EQ(
	norm(x, -2.0, std::vector<int>{-2, -1}, false, Device::cpu).item<float>(),
	doctest::Approx(0.0));
	CHECK_EQ(
	norm(x, 2.0, std::vector<int>{-2, -1}, false, Device::cpu).item<float>(),
	doctest::Approx(14.226707));

	x = reshape(arange(18, float32), {2, 3, 3});
	CHECK_THROWS(norm(x, 2.0, std::vector{0, 1, 2}));
	CHECK(allclose(
	norm(x, 3.0, 0),
	array(
	{9.,
	10.00333222,
	11.02199456,
	12.06217728,
	13.12502645,
	14.2094363,
	15.31340617,
	16.43469751,
	17.57113899},
	{3, 3}))
	.item<bool>());
	CHECK(allclose(
	norm(x, 3.0, 2),
	array(
	{2.08008382,
	6.,
	10.23127655,
	14.5180117,
	18.82291607,
	23.13593104},
	{2, 3}))
	.item<bool>());
	CHECK(
	allclose(
	norm(x, 0.0, 0), array({1., 2., 2., 2., 2., 2., 2., 2., 2.}, {3, 3}))
	.item<bool>());
	CHECK(allclose(norm(x, 0.0, 1), array({2., 3., 3., 3., 3., 3.}, {2, 3}))
	.item<bool>());
	CHECK(allclose(norm(x, 0.0, 2), array({2., 3., 3., 3., 3., 3.}, {2, 3}))
	.item<bool>());
	CHECK(allclose(
	norm(x, 1.0, 0),
	array({9., 11., 13., 15., 17., 19., 21., 23., 25.}, {3, 3}))
	.item<bool>());
	CHECK(allclose(norm(x, 1.0, 1), array({9., 12., 15., 36., 39., 42.}, {2, 3}))
	.item<bool>());
	CHECK(allclose(norm(x, 1.0, 2), array({3., 12., 21., 30., 39., 48.}, {2, 3}))
	.item<bool>());

	CHECK(allclose(norm(x, 1.0, std::vector<int>{0, 1}), array({21., 23., 25.}))
	.item<bool>());
	CHECK(allclose(norm(x, 1.0, std::vector<int>{1, 2}), array({15., 42.}))
	.item<bool>());
	CHECK(allclose(norm(x, -1.0, std::vector<int>{0, 1}), array({9., 11., 13.}))
	.item<bool>());
	CHECK(allclose(norm(x, -1.0, std::vector<int>{1, 2}), array({9., 36.}))
	.item<bool>());
	CHECK(allclose(norm(x, -1.0, std::vector<int>{1, 0}), array({9., 12., 15.}))
	.item<bool>());
	CHECK(allclose(norm(x, -1.0, std::vector<int>{2, 1}), array({3, 30}))
	.item<bool>());
	CHECK(allclose(norm(x, -1.0, std::vector<int>{1, 2}), array({9, 36}))
	.item<bool>());
	CHECK(allclose(
	norm(x, 2.0, std::vector<int>{0, 1}, false, Device::cpu),
	array({22.045408, 24.155825, 26.318918}))
	.item<bool>());
	CHECK(allclose(
	norm(x, 2.0, std::vector<int>{1, 2}, false, Device::cpu),
	array({14.226707, 39.759212}))
	.item<bool>());
	CHECK(allclose(
	norm(x, -2.0, std::vector<int>{0, 1}, false, Device::cpu),
	array({3, 2.7378995, 2.5128777}))
	.item<bool>());
	CHECK(allclose(
	norm(x, -2.0, std::vector<int>{1, 2}, false, Device::cpu),
	array({4.979028e-16, 7.009628e-16}),
	/* rtol = */ 1e-5,
	/* atol = */ 1e-6)
	.item<bool>());
	}

	TEST_CASE("[mlx.core.linalg.norm] string ord") {
	array x({1, 2, 3});
	CHECK_THROWS(norm(x, "fro"));

	x = reshape(arange(9, float32), {3, 3});
	CHECK_THROWS(norm(x, "bad ord"));

	CHECK_EQ(
	norm(x, "f", std::vector<int>{0, 1}).item<float>(),
	doctest::Approx(14.2828568570857));
	CHECK_EQ(
	norm(x, "fro", std::vector<int>{0, 1}).item<float>(),
	doctest::Approx(14.2828568570857));
	CHECK_EQ(
	norm(x, "nuc", std::vector<int>{0, 1}, false, Device::cpu).item<float>(),
	doctest::Approx(15.491934));

	x = reshape(arange(18, float32), {2, 3, 3});
	CHECK(allclose(
	norm(x, "fro", std::vector<int>{0, 1}),
	array({22.24859546, 24.31049156, 26.43860813}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "fro", std::vector<int>{1, 2}),
	array({14.28285686, 39.7617907}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "f", std::vector<int>{0, 1}),
	array({22.24859546, 24.31049156, 26.43860813}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "f", std::vector<int>{1, 0}),
	array({22.24859546, 24.31049156, 26.43860813}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "f", std::vector<int>{1, 2}),
	array({14.28285686, 39.7617907}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "f", std::vector<int>{2, 1}),
	array({14.28285686, 39.7617907}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "nuc", std::vector<int>{0, 1}, false, Device::cpu),
	array({25.045408, 26.893724, 28.831797}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "nuc", std::vector<int>{1, 2}, false, Device::cpu),
	array({15.491934, 40.211937}))
	.item<bool>());
	CHECK(allclose(
	norm(x, "nuc", std::vector<int>{-2, -1}, false, Device::cpu),
	array({15.491934, 40.211937}))
	.item<bool>());
	}

	TEST_CASE("test QR factorization") {
	// 0D and 1D throw
	CHECK_THROWS(linalg::qr(array(0.0)));
	CHECK_THROWS(linalg::qr(array({0.0, 1.0})));

	// Unsupported types throw
	CHECK_THROWS(linalg::qr(array({0, 1}, {1, 2})));

	array A = array({2., 3., 1., 2.}, {2, 2});
	auto [Q, R] = linalg::qr(A, Device::cpu);
	auto out = matmul(Q, R);
	CHECK(allclose(out, A).item<bool>());
	out = matmul(Q, Q);
	CHECK(allclose(out, eye(2), 1e-5, 1e-7).item<bool>());
	CHECK(allclose(tril(R, -1), zeros_like(R)).item<bool>());
	CHECK_EQ(Q.dtype(), float32);
	CHECK_EQ(R.dtype(), float32);
	}

	TEST_CASE("test SVD factorization") {
	// 0D and 1D throw
	CHECK_THROWS(linalg::svd(array(0.0)));
	CHECK_THROWS(linalg::svd(array({0.0, 1.0})));

	// Unsupported types throw
	CHECK_THROWS(linalg::svd(array({0, 1}, {1, 2})));

	const auto prng_key = random::key(42);
	const auto A = mlx::core::random::normal({5, 4}, prng_key);
	const auto outs = linalg::svd(A, true, Device::cpu);
	CHECK_EQ(outs.size(), 3);

	const auto& U = outs[0];
	const auto& S = outs[1];
	const auto& Vt = outs[2];

	CHECK_EQ(U.shape(), Shape{5, 5});
	CHECK_EQ(S.shape(), Shape{4});
	CHECK_EQ(Vt.shape(), Shape{4, 4});

	const auto U_slice = slice(U, {0, 0}, {U.shape(0), S.shape(0)});

	const auto A_again = matmul(matmul(U_slice, diag(S)), Vt);

	CHECK(
	allclose(A_again, A, /* rtol = / 1e-4, / atol = */ 1e-4).item<bool>());
	CHECK_EQ(U.dtype(), float32);
	CHECK_EQ(S.dtype(), float32);
	CHECK_EQ(Vt.dtype(), float32);

	// Test singular values
	const auto& outs_sv = linalg::svd(A, false, Device::cpu);
	const auto SV = outs_sv[0];

	CHECK_EQ(SV.shape(), Shape{4});
	CHECK_EQ(SV.dtype(), float32);

	CHECK(allclose(norm(SV), norm(A, "fro")).item<bool>());
	}

	TEST_CASE("test matrix inversion") {
	// 0D and 1D throw
	CHECK_THROWS(linalg::inv(array(0.0), Device::cpu));
	CHECK_THROWS(linalg::inv(array({0.0, 1.0}), Device::cpu));

	// Unsupported types throw
	CHECK_THROWS(linalg::inv(array({0, 1}, {1, 2}), Device::cpu));

	// Non-square throws.
	CHECK_THROWS(linalg::inv(array({1, 2, 3, 4, 5, 6}, {2, 3}), Device::cpu));

	const auto prng_key = random::key(42);
	const auto A = random::normal({5, 5}, prng_key);
	const auto A_inv = linalg::inv(A, Device::cpu);
	const auto identity = eye(A.shape(0));

	CHECK(allclose(matmul(A, A_inv), identity, /* rtol = / 0, / atol = */ 1e-6)
	.item<bool>());
	CHECK(allclose(matmul(A_inv, A), identity, /* rtol = / 0, / atol = */ 1e-6)
	.item<bool>());
	}

	TEST_CASE("test matrix cholesky") {
	// 0D and 1D throw
	CHECK_THROWS(linalg::cholesky(array(0.0), /* upper = */ false, Device::cpu));
	CHECK_THROWS(
	linalg::cholesky(array({0.0, 1.0}), /* upper = */ false, Device::cpu));

	// Unsupported types throw
	CHECK_THROWS(linalg::cholesky(
	array({0, 1}, {1, 2}), /* upper = */ false, Device::cpu));

	// Non-square throws.
	CHECK_THROWS(linalg::cholesky(
	array({1, 2, 3, 4, 5, 6}, {2, 3}), /* upper = */ false, Device::cpu));

	const auto prng_key = random::key(220398);
	const auto sqrtA = random::normal({5, 5}, prng_key);
	const auto A = matmul(sqrtA, transpose(sqrtA));
	const auto L = linalg::cholesky(A, /* upper = */ false, Device::cpu);
	const auto U = linalg::cholesky(A, /* upper = */ true, Device::cpu);

	CHECK(allclose(matmul(L, transpose(L)), A, /* rtol = / 0, / atol = */ 1e-6)
	.item<bool>());
	CHECK(allclose(matmul(transpose(U), U), A, /* rtol = / 0, / atol = */ 1e-6)
	.item<bool>());
	}

	TEST_CASE("test matrix pseudo-inverse") {
	// 0D and 1D throw
	CHECK_THROWS(linalg::pinv(array(0.0), Device::cpu));
	CHECK_THROWS(linalg::pinv(array({0.0, 1.0}), Device::cpu));

	// Unsupported types throw
	CHECK_THROWS(linalg::pinv(array({0, 1}, {1, 2}), Device::cpu));

	{ // Square m == n
	const auto A = array({1.0, 2.0, 3.0, 4.0}, {2, 2});
	const auto A_pinv = linalg::pinv(A, Device::cpu);
	const auto A_again = matmul(matmul(A, A_pinv), A);
	CHECK(allclose(A_again, A).item<bool>());
	const auto A_pinv_again = matmul(matmul(A_pinv, A), A_pinv);
	CHECK(allclose(A_pinv_again, A_pinv).item<bool>());
	}
	{ // Rectangular matrix m < n
	const auto prng_key = random::key(42);
	const auto A = random::normal({4, 5}, prng_key);
	const auto A_pinv = linalg::pinv(A, Device::cpu);
	const auto zeros = zeros_like(A_pinv, Device::cpu);
	CHECK_FALSE(allclose(zeros, A_pinv, /* rtol = / 0, / atol = */ 1e-6)
	.item<bool>());
	const auto A_again = matmul(matmul(A, A_pinv), A);
	CHECK(allclose(A_again, A).item<bool>());
	const auto A_pinv_again = matmul(matmul(A_pinv, A), A_pinv);
	CHECK(allclose(A_pinv_again, A_pinv).item<bool>());
	}
	{ // Rectangular matrix m > n
	const auto prng_key = random::key(10);
	const auto A = random::normal({6, 5}, prng_key);
	const auto A_pinv = linalg::pinv(A, Device::cpu);
	const auto zeros2 = zeros_like(A_pinv, Device::cpu);
	CHECK_FALSE(allclose(zeros2, A_pinv, /* rtol = / 0, / atol = */ 1e-6)
	.item<bool>());
	const auto A_again = matmul(matmul(A, A_pinv), A);
	CHECK(allclose(A_again, A).item<bool>());
	const auto A_pinv_again = matmul(matmul(A_pinv, A), A_pinv);
	CHECK(allclose(A_pinv_again, A_pinv).item<bool>());
	}
	}

	TEST_CASE("test cross product") {
	using namespace mlx::core::linalg;

	// Test for vectors of length 3
	array a = array({1.0, 2.0, 3.0});
	array b = array({4.0, 5.0, 6.0});

	array expected = array(
	{2.0 * 6.0 - 3.0 * 5.0, 3.0 * 4.0 - 1.0 * 6.0, 1.0 * 5.0 - 2.0 * 4.0});

	array result = cross(a, b);
	CHECK(allclose(result, expected).item<bool>());

	// Test for vectors of length 3 with negative values
	a = array({-1.0, -2.0, -3.0});
	b = array({4.0, -5.0, 6.0});

	expected = array(
	{-2.0 * 6.0 - (-3.0 * -5.0),
	-3.0 * 4.0 - (-1.0 * 6.0),
	-1.0 * -5.0 - (-2.0 * 4.0)});

	result = cross(a, b);
	CHECK(allclose(result, expected).item<bool>());

	// Test for incorrect vector size (should throw)
	b = array({1.0, 2.0});
	expected = array(
	{-2.0 * 0.0 - (-3.0 * 2.0),
	-3.0 * 1.0 - (-1.0 * 0.0),
	-1.0 * 2.0 - (-2.0 * 1.0)});

	result = cross(a, b);
	CHECK(allclose(result, expected).item<bool>());

	// Test for vectors of length 3 with integer values
	a = array({1, 2, 3});
	b = array({4, 5, 6});

	expected = array({2 * 6 - 3 * 5, 3 * 4 - 1 * 6, 1 * 5 - 2 * 4});

	result = cross(a, b);
	CHECK(allclose(result, expected).item<bool>());
	}

	TEST_CASE("test matrix eigh") {
	// 0D and 1D throw
	CHECK_THROWS(linalg::eigh(array(0.0)));
	CHECK_THROWS(linalg::eigh(array({0.0, 1.0})));
	CHECK_THROWS(linalg::eigvalsh(array(0.0)));
	CHECK_THROWS(linalg::eigvalsh(array({0.0, 1.0})));

	// Unsupported types throw
	CHECK_THROWS(linalg::eigh(array({0, 1}, {1, 2})));

	// Non-square throws
	CHECK_THROWS(linalg::eigh(array({1, 2, 3, 4, 5, 6}, {2, 3})));

	// Test a simple 2x2 symmetric matrix
	array A = array({1.0, 2.0, 2.0, 4.0}, {2, 2}, float32);
	auto [eigvals, eigvecs] = linalg::eigh(A, "L", Device::cpu);

	// Expected eigenvalues
	array expected_eigvals = array({0.0, 5.0});
	CHECK(allclose(
	eigvals,
	expected_eigvals,
	/* rtol = */ 1e-5,
	/* atol = */ 1e-5)
	.item<bool>());

	// Verify orthogonality of eigenvectors
	CHECK(allclose(
	matmul(eigvecs, transpose(eigvecs)),
	eye(2),
	/* rtol = */ 1e-5,
	/* atol = */ 1e-5)
	.item<bool>());

	// Verify eigendecomposition
	CHECK(allclose(matmul(A, eigvecs), eigvals * eigvecs).item<bool>());
	}

	TEST_CASE("test lu") {
	// Test 2x2 matrix
	array a = array({1., 2., 3., 4.}, {2, 2});
	auto out = linalg::lu(a, Device::cpu);
	auto L = take_along_axis(out[1], expand_dims(out[0], -1), -2);
	array expected = matmul(L, out[2]);
	CHECK(allclose(a, expected).item<bool>());

	// Test 3x3 matrix
	a = array({1., 2., 3., 4., 5., 6., 7., 8., 10.}, {3, 3});
	out = linalg::lu(a, Device::cpu);
	L = take_along_axis(out[1], expand_dims(out[0], -1), -2);
	expected = matmul(L, out[2]);
	CHECK(allclose(a, expected).item<bool>());

	// Test batch dimension
	a = broadcast_to(a, {3, 3, 3});
	out = linalg::lu(a, Device::cpu);
	L = take_along_axis(out[1], expand_dims(out[0], -1), -2);
	expected = matmul(L, out[2]);
	CHECK(allclose(a, expected).item<bool>());
	}

	TEST_CASE("test solve") {
	// 0D and 1D throw
	CHECK_THROWS(linalg::solve(array(0.), array(0.), Device::cpu));
	CHECK_THROWS(linalg::solve(array({0.}), array({0.}), Device::cpu));

	// Unsupported types throw
	CHECK_THROWS(
	linalg::solve(array({0, 1, 1, 2}, {2, 2}), array({1, 3}), Device::cpu));

	// Non-square throws
	array a = reshape(arange(6), {3, 2});
	array b = reshape(arange(3), {3, 1});
	CHECK_THROWS(linalg::solve(a, b, Device::cpu));

	// Test 2x2 matrix with 1D rhs
	a = array({2., 1., 1., 3.}, {2, 2});
	b = array({8., 13.}, {2});

	array result = linalg::solve(a, b, Device::cpu);
	CHECK(allclose(matmul(a, result), b).item<bool>());

	// Test 3x3 matrix
	a = array({1., 2., 3., 4., 5., 6., 7., 8., 10.}, {3, 3});
	b = array({6., 15., 25.}, {3, 1});

	result = linalg::solve(a, b, Device::cpu);
	CHECK(allclose(matmul(a, result), b).item<bool>());

	// Test batch dimension
	a = broadcast_to(a, {5, 3, 3});
	b = broadcast_to(b, {5, 3, 1});

	result = linalg::solve(a, b, Device::cpu);
	CHECK(allclose(matmul(a, result), b).item<bool>());

	// Test multi-column rhs
	a = array({2., 1., 1., 1., 3., 2., 1., 0., 0.}, {3, 3});
	b = array({4., 2., 5., 3., 6., 1.}, {3, 2});

	result = linalg::solve(a, b, Device::cpu);
	CHECK(allclose(matmul(a, result), b).item<bool>());

	// Test batch multi-column rhs
	a = broadcast_to(a, {5, 3, 3});
	b = broadcast_to(b, {5, 3, 2});

	result = linalg::solve(a, b, Device::cpu);
	CHECK(allclose(matmul(a, result), b).item<bool>());
	}

	TEST_CASE("test solve_triangluar") {
	// Test lower triangular matrix
	array a = array({2., 0., 0., 3., 1., 0., 1., -1., 1.}, {3, 3});
	array b = array({2., 5., 0.});

	array result =
	linalg::solve_triangular(a, b, /* upper = */ false, Device::cpu);
	array expected = array({1., 2., 1.});
	CHECK(allclose(expected, result).item<bool>());

	// Test upper triangular matrix
	a = array({2., 1., 3., 0., 4., 2., 0., 0., 1.}, {3, 3});
	b = array({5., 14., 3.});

	result = linalg::solve_triangular(a, b, /* upper = */ true, Device::cpu);
	expected = array({-3., 2., 3.});
	CHECK(allclose(expected, result).item<bool>());
	}