#!/usr/bin/env python3
# coding: utf-8
# Copyright (c) 2025-2026 Huawei Technologies Co., Ltd.
# This program is free software, you can redistribute it and/or modify it under the terms and conditions of
# CANN Open Software License Agreement Version 2.0 (the "License").
# Please refer to the License for details. You may not use this file except in compliance with the License.
# THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, EITHER EXPRESS OR IMPLIED,
# INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, MERCHANTABILITY, OR FITNESS FOR A PARTICULAR PURPOSE.
# See LICENSE in the root of the software repository for the full text of the License.
# -----------------------------------------------------------------------------------------------------------
"""
Test Hypot operation on board
"""
import os
import math
import torch
import pypto
import pytest
from numpy.testing import assert_allclose
import torch_npu


def test_hypot_onboard():
    device_id = int(os.environ.get('TILE_FWK_DEVICE_ID', 0))
    torch.npu.set_device(device_id)
    shape = (72, 71)
    view_shape = (32, 32)
    tile_shape = (32, 32)

    pypto.runtime._device_init()

    input1 = pypto.tensor(shape, pypto.DT_FP32, "PTO_TENSOR_input1")
    input2 = pypto.tensor(shape, pypto.DT_FP32, "PTO_TENSOR_input2")
    output = pypto.tensor(shape, pypto.DT_FP32, "PTO_TENSOR_output")

    b_loop_num = math.ceil(shape[0] / view_shape[0])
    s_loop_num = math.ceil(shape[1] / view_shape[1])

    with pypto.function("MAIN", input1, input2, output):
        for b_idx in pypto.loop(b_loop_num, name="b0", idx_name="bidx"):
            for s_idx in pypto.loop(s_loop_num, name="s0", idx_name="sidx"):
                offset_x = b_idx * view_shape[0]
                offset_y = s_idx * view_shape[1]

                valid_shape_x = pypto.min(pypto.symbolic_scalar(shape[0]) - offset_x,
                                          pypto.symbolic_scalar(view_shape[0]))
                valid_shape_y = pypto.min(pypto.symbolic_scalar(shape[1]) - offset_y,
                                          pypto.symbolic_scalar(view_shape[1]))
                view_tensor_a = pypto.view(input1, view_shape,
                                           [offset_x, offset_y],
                                           valid_shape=[valid_shape_x, valid_shape_y])
                view_tensor_b = pypto.view(input2, view_shape,
                                           [offset_x, offset_y],
                                           valid_shape=[valid_shape_x, valid_shape_y])

                pypto.set_vec_tile_shapes(tile_shape[0], tile_shape[1])
                res = pypto.hypot(view_tensor_a, view_tensor_b)
                pypto.assemble(res, [offset_x, offset_y], output)

    assert isinstance(output, pypto.tensor)
    a_tensor = torch.randn(size=[shape[0], shape[1]], dtype=torch.float32)
    b_tensor = torch.randn(size=[shape[0], shape[1]], dtype=torch.float32)
    out_tensor = torch.zeros(shape[0], shape[1], dtype=torch.float32)

    pto_a_tensor = pypto.from_torch(a_tensor, "PTO_TENSOR_input1")
    pto_b_tensor = pypto.from_torch(b_tensor, "PTO_TENSOR_input2")
    pto_out_tensor = pypto.from_torch(out_tensor, "PTO_TENSOR_output")
    pypto.runtime._device_run_once_data_from_host(pto_a_tensor, pto_b_tensor, pto_out_tensor)

    golden = torch.hypot(a_tensor, b_tensor)

    assert_allclose(out_tensor.flatten(), golden.flatten(), rtol=1e-3, atol=1e-3)

    pypto.runtime._device_fini()