egm/webview_app.py

"""
EGM 输电线路绕击跳闸率计算程序 - Pywebview 界面
使用 Vue 3 + Quasar + TypeScript + Tailwind CSS 作为前端
"""

import os
import sys
import json
import math
from pathlib import Path
from typing import Dict, Any, List
from datetime import datetime
import webview
from loguru import logger

# 添加项目根目录到路径
project_root = Path(__file__).parent
sys.path.insert(0, str(project_root))

from core import (
    Parameter, para,
    func_ng, min_i, rs_fun, rc_fun, rg_fun,
    bd_area, thunder_density, arc_possibility,
    rg_line_function_factory, solve_circle_intersection,
    solve_circle_line_intersection, Draw
)
import numpy as np


class WebHandler:
    """Web日志处理器"""
    def __init__(self, callback=None):
        self.callback = callback
        self.logs: List[Dict[str, str]] = []

    def write(self, message):
        if message.strip():
            log_entry = {
                "level": "info",
                "time": datetime.now().strftime("%H:%M:%S"),
                "message": message.strip()
            }
            self.logs.append(log_entry)
            if self.callback:
                self.callback(log_entry)


class EGMWebApp:
    """EGM 计算程序的 Web 界面后端"""

    def __init__(self):
        self.window = None
        self.web_handler = None
        self.logs: List[Dict[str, str]] = []

    def add_log(self, level: str, message: str):
        """添加日志"""
        log_entry = {
            "level": level,
            "time": datetime.now().strftime("%H:%M:%S"),
            "message": message
        }
        self.logs.append(log_entry)

    def get_logs(self) -> List[Dict[str, str]]:
        """获取日志列表"""
        logs = self.logs.copy()
        self.logs = []
        return logs

    def calculate(self, params: Dict[str, Any]) -> Dict[str, Any]:
        """
        执行 EGM 计算

        Args:
            params: 包含 parameter, advance, optional 的字典

        Returns:
            计算结果字典
        """
        self.logs = []  # 清空日志
        self.add_log("info", "开始 EGM 计算...")

        try:
            # 解析参数
            parameter_data = params.get('parameter', {})
            advance_data = params.get('advance', {})
            optional_data = params.get('optional', {})

            # 更新全局参数对象
            para.h_g_sag = float(parameter_data.get('h_g_sag', 11.67))
            para.h_c_sag = float(parameter_data.get('h_c_sag', 14.43))
            para.td = int(parameter_data.get('td', 20))
            para.insulator_c_len = float(parameter_data.get('insulator_c_len', 7.02))
            para.string_c_len = float(parameter_data.get('string_c_len', 9.2))
            para.string_g_len = float(parameter_data.get('string_g_len', 0.5))
            para.gc_x = list(parameter_data.get('gc_x', [17.9, 17]))
            para.ground_angels = [
                angel / 180 * math.pi
                for angel in parameter_data.get('ground_angels', [0])
            ]
            para.h_arm = list(parameter_data.get('h_arm', [150, 130]))
            para.altitude = int(parameter_data.get('altitude', 1000))
            para.rated_voltage = float(parameter_data.get('rated_voltage', 750))

            para.ng = float(advance_data.get('ng', -1))
            para.Ip_a = float(advance_data.get('Ip_a', -1))
            para.Ip_b = float(advance_data.get('Ip_b', -1))

            para.voltage_n = int(optional_data.get('voltage_n', 3))
            para.max_i = float(optional_data.get('max_i', 200))

            self.add_log("info", f"参数: 额定电压={para.rated_voltage}kV, 雷暴日={para.td}d, 海拔={para.altitude}m")

            logger.info("开始执行 _do_calculate...")

            # 执行实际计算
            self.add_log("info", "EGM 计算中...")
            result = self._do_calculate()

            # 调试输出
            logger.info(f"_do_calculate 返回 keys: {list(result.keys())}")
            logger.info(f"日志列表: {self.logs}")

            # 将日志添加到结果中（在返回之前添加最后一条日志）
            self.add_log("info", "EGM 计算完成")

            # 创建一个新的返回值，确保 logs 字段被包含
            final_result = {
                "success": result.get("success", True),
                "message": result.get("message", "计算完成"),
                "data": result.get("data", {}),
                "logs": self.logs,
                "DEBUG_VERSION": "v2"  # 标记版本
            }

            logger.info(f"最终返回结果 keys: {list(final_result.keys())}")
            logger.info(f"日志数量: {len(self.logs)}")
            logger.info(f"DEBUG: self.logs = {self.logs}")

            return final_result

        except Exception as e:
            self.add_log("error", f"计算失败: {str(e)}")
            import traceback
            traceback.print_exc()
            return {
                "success": False,
                "message": f"计算失败: {str(e)}",
                "error": str(e),
                "logs": self.logs
            }

    def _do_calculate(self) -> Dict[str, Any]:
        """执行实际的EGM计算"""
        try:
            h_whole = para.h_arm[0]
        except Exception as e:
            self.add_log("error", f"获取参数失败: {str(e)}")
            raise
        string_g_len = para.string_g_len
        string_c_len = para.string_c_len
        h_g_sag = para.h_g_sag
        h_c_sag = para.h_c_sag
        gc_x = para.gc_x.copy()
        h_arm = para.h_arm

        gc_y = [
            h_whole - string_g_len - h_g_sag * 2 / 3,
        ]
        if len(h_arm) > 1:
            for hoo in h_arm[1:]:
                gc_y.append(hoo - string_c_len - h_c_sag * 2 / 3)

        if len(gc_y) > 2:
            phase_n = 3
        else:
            phase_n = 1

        td = para.td
        ng = func_ng(td)
        avr_n_sf = 0
        ground_angels = para.ground_angels
        voltage_n = para.voltage_n
        n_sf_phases = np.zeros((phase_n, voltage_n))

        results = []

        for ground_angel in ground_angels:
            self.add_log("info", f"地面倾角 {ground_angel / math.pi * 180:.3f}°")
            rg_type = None
            rg_x = None
            rg_y = None

            for phase_conductor_foo in range(phase_n):
                rs_x = gc_x[phase_conductor_foo]
                rs_y = gc_y[phase_conductor_foo]
                rc_x = gc_x[phase_conductor_foo + 1]
                rc_y = gc_y[phase_conductor_foo + 1]

                if phase_n == 1:
                    rg_type = "g"
                if phase_n > 1:
                    if phase_conductor_foo < 2:
                        rg_type = "c"
                        rg_x = gc_x[phase_conductor_foo + 2]
                        rg_y = gc_y[phase_conductor_foo + 2]
                    else:
                        rg_type = "g"

                rated_voltage = para.rated_voltage

                for u_bar in range(voltage_n):
                    u_ph = rated_voltage / 1.732

                    insulator_c_len = para.insulator_c_len
                    i_min = min_i(insulator_c_len, u_ph)
                    _min_i = i_min
                    _max_i = para.max_i

                    i_max = _min_i

                    for i_bar in np.linspace(_min_i, _max_i, int((_max_i - _min_i) / 1)):
                        rs = rs_fun(i_bar)
                        rc = rc_fun(i_bar, u_ph)
                        rg = rg_fun(i_bar, rc_y, u_ph, typ=rg_type)

                        rg_line_func = None
                        if rg_type == "g":
                            rg_line_func = rg_line_function_factory(rg, ground_angel)

                        rs_rc_circle_intersection = solve_circle_intersection(
                            rs, rc, rs_x, rs_y, rc_x, rc_y
                        )
                        i_max = i_bar

                        if not rs_rc_circle_intersection:
                            continue

                        circle_rc_or_rg_line_intersection = None
                        if rg_type == "g":
                            circle_rc_or_rg_line_intersection = solve_circle_line_intersection(
                                rc, rc_x, rc_y, rg_line_func
                            )
                        elif rg_type == "c":
                            circle_rc_or_rg_line_intersection = solve_circle_intersection(
                                rg, rc, rg_x, rg_y, rc_x, rc_y
                            )

                        if not circle_rc_or_rg_line_intersection:
                            if rg_type == "g":
                                if rg_line_func(rc_x) > rc_y:
                                    i_min = i_bar
                                continue
                            else:
                                continue

                        min_distance_intersection = (
                            np.sum(
                                (
                                    np.array(rs_rc_circle_intersection)
                                    - np.array(circle_rc_or_rg_line_intersection)
                                )
                                ** 2
                            )
                            ** 0.5
                        )

                        if min_distance_intersection < 0.1:
                            break

                    self.add_log("info", f"最大电流为 {i_max:.2f}, 最小电流为 {i_min:.2f}")

                    curt_fineness = 0.1
                    if i_min > i_max or abs(i_min - i_max) < curt_fineness:
                        self.add_log("info", "最大电流小于等于最小电流，没有暴露弧。")
                        continue

                    curt_segment_n = int((i_max - i_min) / curt_fineness)
                    i_curt_samples, d_curt = np.linspace(
                        i_min, i_max, curt_segment_n + 1, retstep=True
                    )

                    bd_area_vec = np.vectorize(bd_area)
                    ip_a = para.Ip_a
                    ip_b = para.Ip_b

                    bd_area_vec_result = bd_area_vec(
                        i_curt_samples,
                        u_ph,
                        rc_x,
                        rc_y,
                        rs_x,
                        rs_y,
                        rg_x,
                        rg_y,
                        ground_angel,
                        rg_type,
                    )
                    thunder_density_result = thunder_density(
                        i_curt_samples, td, ip_a, ip_b
                    )
                    cal_bd_np = bd_area_vec_result * thunder_density_result
                    calculus = np.sum(cal_bd_np[:-1] + cal_bd_np[1:]) / 2 * d_curt

                    n_sf = (
                        2
                        * ng
                        / 10
                        * calculus
                        * arc_possibility(rated_voltage, insulator_c_len)
                    )
                    avr_n_sf += n_sf / voltage_n
                    n_sf_phases[phase_conductor_foo][u_bar] = n_sf

                    self.add_log("info", f"相{phase_conductor_foo + 1}, 跳闸率: {n_sf:.16f} 次/(100km·a)")

            result = {
                "ground_angle": f"{ground_angel / math.pi * 180:.3f}°",
                "tripping_rate": avr_n_sf,
                "phases": np.mean(n_sf_phases, axis=1).tolist()
            }
            results.append(result)

        return {
            "success": True,
            "message": "计算完成",
            "data": {
                "tripping_rate": f"{avr_n_sf:.16f} 次/(100km·a)",
                "results": results,
                "parameters": {
                    "rated_voltage": para.rated_voltage,
                    "td": para.td,
                    "altitude": para.altitude,
                    "ground_angels": [a / math.pi * 180 for a in para.ground_angels],
                    "max_i": para.max_i
                }
            }
        }

    def export_config(self, params: Dict[str, Any]) -> str:
        """
        导出配置为 JSON 字符串

        Args:
            params: 参数字典

        Returns:
            JSON 字符串
        """
        return json.dumps(params, indent=2, ensure_ascii=False)

    def get_default_config(self) -> Dict[str, Any]:
        """
        获取默认配置

        Returns:
            默认配置字典
        """
        return {
            "parameter": {
                "rated_voltage": 750,
                "h_c_sag": 14.43,
                "h_g_sag": 11.67,
                "insulator_c_len": 7.02,
                "string_c_len": 9.2,
                "string_g_len": 0.5,
                "h_arm": [150, 130],
                "gc_x": [17.9, 17],
                "ground_angels": [0],
                "altitude": 1000,
                "td": 20
            },
            "advance": {
                "ng": -1,
                "Ip_a": -1,
                "Ip_b": -1
            },
            "optional": {
                "voltage_n": 3,
                "max_i": 200
            }
        }


def start_webview():
    """启动 pywebview 界面"""

    # 确定前端 URL
    # 在开发环境中使用 Vite 开发服务器
    # 在生产环境中使用构建后的文件
    dev_mode = os.getenv('EGM_DEV_MODE', 'true').lower() == 'true'

    if dev_mode:
        # 开发模式：使用 Vite 开发服务器
        url = 'http://localhost:5173'
        logger.info(f"开发模式：使用 Vite 开发服务器 {url}")
        logger.info("请先在 webui 目录中运行: npm install && npm run dev")
    else:
        # 生产模式：使用构建后的文件
        dist_path = project_root / 'webui' / 'dist'
        if not dist_path.exists():
            logger.error(f"构建目录不存在: {dist_path}")
            logger.error("请先运行: cd webui && npm run build")
            sys.exit(1)
        url = f'file://{dist_path / "index.html"}'
        logger.info(f"生产模式：使用构建文件 {url}")

    # 创建 API 实例
    api = EGMWebApp()

    # 创建窗口
    window = webview.create_window(
        title='EGM 输电线路绕击跳闸率计算',
        url=url,
        js_api=api,
        width=1200,
        height=900,
        resizable=True,
        min_size=(800, 600)
    )

    # 启动
    logger.info("启动 EGM Web 界面...")
    webview.start(debug=dev_mode)


if __name__ == '__main__':
    # 配置日志
    logger.remove()
    logger.add(sys.stderr, level="INFO")
    logger.add("egm_webui.log", rotation="10 MB", retention="7 days")

    # 启动界面
    start_webview()