klz-cables.com/scripts/pdf/model/build-datasheet-model.ts

import * as fs from 'fs';
import * as path from 'path';

import type { DatasheetModel, DatasheetVoltageTable, KeyValueItem, ProductData } from './types';
import type { ExcelMatch } from './excel-index';
import { findExcelForProduct } from './excel-index';
import { getLabels, getProductUrl, normalizeValue, stripHtml } from './utils';

type ExcelRow = Record<string, unknown>;
type VoltageTableModel = {
  voltageLabel: string;
  metaItems: KeyValueItem[];
  crossSections: string[];
  columns: Array<{ key: string; label: string; get: (rowIndex: number) => string }>;
};
type BuildExcelModelResult = { ok: boolean; technicalItems: KeyValueItem[]; voltageTables: VoltageTableModel[] };
type AssetMap = Record<string, string>;

const ASSET_MAP_FILE = path.join(process.cwd(), 'data/processed/asset-map.json');

function readAssetMap(): AssetMap {
  try {
    if (!fs.existsSync(ASSET_MAP_FILE)) return {};
    return JSON.parse(fs.readFileSync(ASSET_MAP_FILE, 'utf8')) as AssetMap;
  } catch {
    return {};
  }
}
const ASSET_MAP: AssetMap = readAssetMap();

function normalizeUnit(unitRaw: string): string {
  const u = normalizeValue(unitRaw);
  if (!u) return '';
  if (/^c$/i.test(u) || /^°c$/i.test(u)) return '°C';
  return u.replace(/Ω/gi, 'Ohm').replace(/[\u00B5\u03BC]/g, 'u');
}

function formatExcelHeaderLabel(key: string, unit?: string): string {
  const k = normalizeValue(key);
  if (!k) return '';
  const u = normalizeValue(unit || '');
  const compact = k.replace(/\s*\(approx\.?\)\s*/gi, ' (approx.) ').replace(/\s+/g, ' ').trim();
  if (!u) return compact;
  if (new RegExp(`\\(${u.replace(/[.*+?^${}()|[\\]\\]/g, '\\$&')}\\)`, 'i').test(compact)) return compact;
  return `${compact} (${u})`;
}

function normalizeVoltageLabel(raw: string): string {
  const v = normalizeValue(raw);
  if (!v) return '';
  const cleaned = v.replace(/\s+/g, ' ');
  if (/\bkv\b/i.test(cleaned)) return cleaned.replace(/\bkv\b/i, 'kV');
  const num = cleaned.match(/\d+(?:[.,]\d+)?(?:\s*\/\s*\d+(?:[.,]\d+)?)?/);
  if (!num) return cleaned;
  if (/[a-z]/i.test(cleaned)) return cleaned;
  return `${cleaned} kV`;
}

function parseVoltageSortKey(voltageLabel: string): number {
  const v = normalizeVoltageLabel(voltageLabel);
  const nums = v
    .replace(/,/g, '.')
    .match(/\d+(?:\.\d+)?/g)
    ?.map(n => Number(n))
    .filter(n => Number.isFinite(n));
  if (!nums || nums.length === 0) return Number.POSITIVE_INFINITY;
  return nums[nums.length - 1];
}

function compactNumericForLocale(value: string, locale: 'en' | 'de'): string {
  const v = normalizeValue(value);
  if (!v) return '';

  // Compact common bending-radius style: "15xD (Single core); 12xD (Multi core)" -> "15/12xD".
  // Keep semantics, reduce width. Never truncate with ellipses.
  if (/\d+xD/i.test(v)) {
    const nums = Array.from(v.matchAll(/(\d+)xD/gi)).map(m => m[1]).filter(Boolean);
    const unique: string[] = [];
    for (const n of nums) {
      if (!unique.includes(n)) unique.push(n);
    }
    if (unique.length) return `${unique.join('/') }xD`;
  }

  const hasDigit = /\d/.test(v);
  if (!hasDigit) return v;
  const trimmed = v.replace(/\s+/g, ' ').trim();
  const parts = trimmed.split(/(–|-)/);
  const out = parts.map(p => {
    if (p === '–' || p === '-') return p;
    const s = p.trim();
    if (!/^-?\d+(?:[.,]\d+)?$/.test(s)) return p;
    const n = s.replace(/,/g, '.');
    const compact = n
      .replace(/\.0+$/, '')
      .replace(/(\.\d*?)0+$/, '$1')
      .replace(/\.$/, '');
    const hadPlus = /^\+/.test(s);
    const withPlus = hadPlus && !/^\+/.test(compact) ? `+${compact}` : compact;
    return locale === 'de' ? withPlus.replace(/\./g, ',') : withPlus;
  });
  return out.join('');
}

function compactCellForDenseTable(value: string, unit: string | undefined, locale: 'en' | 'de'): string {
  let v = normalizeValue(value);
  if (!v) return '';
  const u = normalizeValue(unit || '');
  if (u) {
    const esc = u.replace(/[.*+?^${}()|[\]\\]/g, '\\$&');
    v = v.replace(new RegExp(`\\s*${esc}\\b`, 'ig'), '').trim();
    v = v
      .replace(/\bkg\s*\/\s*km\b/gi, '')
      .replace(/\bohm\s*\/\s*km\b/gi, '')
      .replace(/\bΩ\s*\/\s*km\b/gi, '')
      .replace(/\bu\s*f\s*\/\s*km\b/gi, '')
      .replace(/\bmh\s*\/\s*km\b/gi, '')
      .replace(/\bkA\b/gi, '')
      .replace(/\bmm\b/gi, '')
      .replace(/\bkv\b/gi, '')
      .replace(/\b°?c\b/gi, '')
      .replace(/\s+/g, ' ')
      .trim();
  }
  v = v.replace(/\s*–\s*/g, '-').replace(/\s*-\s*/g, '-').replace(/\s*\/\s*/g, '/').replace(/\s+/g, ' ').trim();
  return compactNumericForLocale(v, locale);
}

function resolveMediaToLocalPath(urlOrPath: string | null | undefined): string | null {
  if (!urlOrPath) return null;
  if (urlOrPath.startsWith('/')) return urlOrPath;
  if (/^media\//i.test(urlOrPath)) return `/${urlOrPath}`;
  const mapped = ASSET_MAP[urlOrPath];
  if (mapped) {
    if (mapped.startsWith('/')) return mapped;
    if (/^public\//i.test(mapped)) return `/${mapped.replace(/^public\//i, '')}`;
    if (/^media\//i.test(mapped)) return `/${mapped}`;
    return mapped;
  }
  return urlOrPath;
}

function guessColumnKey(row: ExcelRow, patterns: RegExp[]): string | null {
  const keys = Object.keys(row || {});
  for (const re of patterns) {
    const k = keys.find(x => {
      const key = String(x);
      if (re.test('conductor') && /ross section conductor/i.test(key)) return false;
      if (re.test('insulation thickness') && /Diameter over insulation/i.test(key)) return false;
      if (re.test('conductor') && !/^conductor$/i.test(key)) return false;
      if (re.test('insulation') && !/^insulation$/i.test(key)) return false;
      if (re.test('sheath') && !/^sheath$/i.test(key)) return false;
      if (re.test('norm') && !/^norm$/i.test(key)) return false;
      return re.test(key);
    });
    if (k) return k;
  }
  return null;
}

function technicalFullLabel(args: { key: string; excelKey: string; locale: 'en' | 'de' }): string {
  if (args.locale === 'en') return normalizeValue(args.excelKey);
  const raw = normalizeValue(args.excelKey);
  if (!raw) return '';
  return raw
    .replace(/\(approx\.?\)/gi, '(ca.)')
    .replace(/\bcapacitance\b/gi, 'Kapazität')
    .replace(/\binductance\b/gi, 'Induktivität')
    .replace(/\breactance\b/gi, 'Reaktanz')
    .replace(/\btest voltage\b/gi, 'Prüfspannung')
    .replace(/\brated voltage\b/gi, 'Nennspannung')
    .replace(/\boperating temperature range\b/gi, 'Temperaturbereich')
    .replace(/\bminimum sheath thickness\b/gi, 'Manteldicke (min.)')
    .replace(/\bsheath thickness\b/gi, 'Manteldicke')
    .replace(/\bnominal insulation thickness\b/gi, 'Isolationsdicke (nom.)')
    .replace(/\binsulation thickness\b/gi, 'Isolationsdicke')
    .replace(/\bdc resistance at 20\s*°?c\b/gi, 'DC-Leiterwiderstand (20 °C)')
    .replace(/\bouter diameter(?: of cable)?\b/gi, 'Außen-Ø')
    .replace(/\bbending radius\b/gi, 'Biegeradius')
    .replace(/\bpackaging\b/gi, 'Verpackung')
    .replace(/\bce\s*-?conformity\b/gi, 'CE-Konformität');
}

function metaFullLabel(args: { key: string; excelKey: string; locale: 'en' | 'de' }): string {
  const key = normalizeValue(args.key);
  if (args.locale === 'de') {
    switch (key) {
      case 'test_volt':
        return 'Prüfspannung';
      case 'temp_range':
        return 'Temperaturbereich';
      case 'max_op_temp':
        return 'Leitertemperatur (max.)';
      case 'max_sc_temp':
        return 'Kurzschlusstemperatur (max.)';
      case 'min_lay_temp':
        return 'Minimale Verlegetemperatur';
      case 'min_store_temp':
        return 'Minimale Lagertemperatur';
      case 'cpr':
        return 'CPR-Klasse';
      case 'flame':
        return 'Flammhemmend';
      default:
        return formatExcelHeaderLabel(args.excelKey);
    }
  }

  switch (key) {
    case 'test_volt':
      return 'Test voltage';
    case 'temp_range':
      return 'Operating temperature range';
    case 'max_op_temp':
      return 'Conductor temperature (max.)';
    case 'max_sc_temp':
      return 'Short-circuit temperature (max.)';
    case 'min_lay_temp':
      return 'Minimum laying temperature';
    case 'min_store_temp':
      return 'Minimum storage temperature';
    case 'cpr':
      return 'CPR class';
    case 'flame':
      return 'Flame retardant';
    default:
      return formatExcelHeaderLabel(args.excelKey);
  }
}

function denseAbbrevLabel(args: { key: string; locale: 'en' | 'de'; unit?: string }): string {
  const u = normalizeUnit(args.unit || '');
  const unitSafe = u.replace(/Ω/gi, 'Ohm').replace(/[\u00B5\u03BC]/g, 'u');
  const suffix = unitSafe ? ` [${unitSafe}]` : '';

  switch (args.key) {
    case 'DI':
    case 'RI':
    case 'Wi':
    case 'Ibl':
    case 'Ibe':
    case 'Wm':
    case 'Rbv':
    case 'Fzv':
    case 'G':
      return `${args.key}${suffix}`;
    case 'Ik_cond':
      return `Ik${suffix}`;
    case 'Ik_screen':
      return `Ik_s${suffix}`;
    case 'Ø':
      return `Ø${suffix}`;
    case 'Cond':
      return args.locale === 'de' ? 'Leiter' : 'Cond.';
    case 'shape':
      return args.locale === 'de' ? 'Form' : 'Shape';
    // Electrical
    case 'cap':
      // Capacitance. Use a clear label; lowercase "cap" looks like an internal key.
      return `Cap${suffix}`;
    case 'X':
      return `X${suffix}`;
    case 'test_volt':
      return `U_test${suffix}`;
    case 'rated_volt':
      return `U0/U${suffix}`;
    case 'temp_range':
      return `T${suffix}`;
    case 'max_op_temp':
      return `T_op${suffix}`;
    case 'max_sc_temp':
      return `T_sc${suffix}`;
    case 'min_store_temp':
      return `T_st${suffix}`;
    case 'min_lay_temp':
      return `T_lay${suffix}`;
    case 'cpr':
      return `CPR${suffix}`;
    case 'flame':
      return `FR${suffix}`;
    default:
      return args.key || '';
  }
}

function summarizeOptions(options: string[] | undefined): string {
  const vals = (options || []).map(normalizeValue).filter(Boolean);
  if (vals.length === 0) return '';
  const uniq = Array.from(new Set(vals));
  if (uniq.length === 1) return uniq[0];
  // Never use ellipsis truncation in datasheets. Prefer full value list.
  // (Long values should be handled by layout; if needed we can later add wrapping rules.)
  return uniq.join(' / ');
}

function parseNumericOption(value: string): number | null {
  const v = normalizeValue(value).replace(/,/g, '.');
  const m = v.match(/-?\d+(?:\.\d+)?/);
  if (!m) return null;
  const n = Number(m[0]);
  return Number.isFinite(n) ? n : null;
}

function summarizeNumericRange(options: string[] | undefined): { ok: boolean; text: string } {
  const vals = (options || []).map(parseNumericOption).filter((n): n is number => n !== null);
  if (vals.length < 3) return { ok: false, text: '' };
  const uniq = Array.from(new Set(vals));
  if (uniq.length < 4) return { ok: false, text: '' };
  uniq.sort((a, b) => a - b);
  const min = uniq[0];
  const max = uniq[uniq.length - 1];
  const fmt = (n: number) => (Number.isInteger(n) ? String(n) : String(n)).replace(/\.0+$/, '');
  return { ok: true, text: `${fmt(min)}–${fmt(max)}` };
}

function summarizeSmartOptions(_label: string, options: string[] | undefined): string {
  const range = summarizeNumericRange(options);
  if (range.ok) return range.text;
  return summarizeOptions(options);
}

function normalizeDesignation(value: string): string {
  return String(value || '')
    .toUpperCase()
    .replace(/-\d+$/g, '')
    .replace(/[^A-Z0-9]+/g, '');
}

function buildExcelModel(args: { product: ProductData; locale: 'en' | 'de' }): BuildExcelModelResult {
  const match = findExcelForProduct(args.product) as ExcelMatch | null;
  if (!match || match.rows.length === 0) return { ok: false, technicalItems: [], voltageTables: [] };

  const units = match.units || {};
  const rows = match.rows;
  let sample = rows.find(r => r && Object.keys(r).length > 0) || {};
  let maxColumns = Object.keys(sample).filter(k => k && k !== 'Part Number' && k !== 'Units').length;
  for (const r of rows) {
    const cols = Object.keys(r).filter(k => k && k !== 'Part Number' && k !== 'Units').length;
    if (cols > maxColumns) {
      sample = r;
      maxColumns = cols;
    }
  }

  const columnMapping: Record<string, { header: string; unit: string; key: string }> = {
    'number of cores and cross-section': { header: 'Cross-section', unit: '', key: 'cross_section' },
    'ross section conductor': { header: 'Cross-section', unit: '', key: 'cross_section' },

    'diameter over insulation': { header: 'DI', unit: 'mm', key: 'DI' },
    'diameter over insulation (approx.)': { header: 'DI', unit: 'mm', key: 'DI' },
    'dc resistance at 20 °C': { header: 'RI', unit: 'Ohm/km', key: 'RI' },
    'dc resistance at 20°C': { header: 'RI', unit: 'Ohm/km', key: 'RI' },
    'resistance conductor': { header: 'RI', unit: 'Ohm/km', key: 'RI' },
    'maximum resistance of conductor': { header: 'RI', unit: 'Ohm/km', key: 'RI' },
    'insulation thickness': { header: 'Wi', unit: 'mm', key: 'Wi' },
    'nominal insulation thickness': { header: 'Wi', unit: 'mm', key: 'Wi' },
    'current ratings in air, trefoil': { header: 'Ibl', unit: 'A', key: 'Ibl' },
    'current ratings in air, trefoil*': { header: 'Ibl', unit: 'A', key: 'Ibl' },
    'current ratings in ground, trefoil': { header: 'Ibe', unit: 'A', key: 'Ibe' },
    'current ratings in ground, trefoil*': { header: 'Ibe', unit: 'A', key: 'Ibe' },
    'conductor shortcircuit current': { header: 'Ik', unit: 'kA', key: 'Ik_cond' },
    'screen shortcircuit current': { header: 'Ik', unit: 'kA', key: 'Ik_screen' },
    'sheath thickness': { header: 'Wm', unit: 'mm', key: 'Wm' },
    'minimum sheath thickness': { header: 'Wm', unit: 'mm', key: 'Wm' },
    'nominal sheath thickness': { header: 'Wm', unit: 'mm', key: 'Wm' },
    'bending radius': { header: 'Rbv', unit: 'mm', key: 'Rbv' },
    'bending radius (min.)': { header: 'Rbv', unit: 'mm', key: 'Rbv' },
    'outer diameter': { header: 'Ø', unit: 'mm', key: 'Ø' },
    'outer diameter (approx.)': { header: 'Ø', unit: 'mm', key: 'Ø' },
    'outer diameter of cable': { header: 'Ø', unit: 'mm', key: 'Ø' },
    'pulling force': { header: 'Fzv', unit: 'N', key: 'Fzv' },
    'max. pulling force': { header: 'Fzv', unit: 'N', key: 'Fzv' },
    'conductor aluminum': { header: 'Cond.', unit: '', key: 'Cond' },
    'conductor copper': { header: 'Cond.', unit: '', key: 'Cond' },
    'weight': { header: 'G', unit: 'kg/km', key: 'G' },
    'weight (approx.)': { header: 'G', unit: 'kg/km', key: 'G' },
    'cable weight': { header: 'G', unit: 'kg/km', key: 'G' },

    'shape of conductor': { header: 'Conductor shape', unit: '', key: 'shape' },
    'operating temperature range': { header: 'Operating temp range', unit: '°C', key: 'temp_range' },
    'maximal operating conductor temperature': { header: 'Max operating temp', unit: '°C', key: 'max_op_temp' },
    'maximal short-circuit temperature': { header: 'Max short-circuit temp', unit: '°C', key: 'max_sc_temp' },
    'minimal storage temperature': { header: 'Min storage temp', unit: '°C', key: 'min_store_temp' },
    'minimal temperature for laying': { header: 'Min laying temp', unit: '°C', key: 'min_lay_temp' },
    'test voltage': { header: 'Test voltage', unit: 'kV', key: 'test_volt' },
    'rated voltage': { header: 'Rated voltage', unit: 'kV', key: 'rated_volt' },
    'cpr class': { header: 'CPR class', unit: '', key: 'cpr' },
    'flame retardant': { header: 'Flame retardant', unit: '', key: 'flame' },
    'self-extinguishing of single cable': { header: 'Flame retardant', unit: '', key: 'flame' },

    // High-value electrical/screen columns
    'capacitance (approx.)': { header: 'Capacitance', unit: 'uF/km', key: 'cap' },
    'capacitance': { header: 'Capacitance', unit: 'uF/km', key: 'cap' },
    'reactance': { header: 'Reactance', unit: 'Ohm/km', key: 'X' },
    'diameter over screen': { header: 'Diameter over screen', unit: 'mm', key: 'D_screen' },
    'metallic screen mm2': { header: 'Metallic screen', unit: 'mm2', key: 'S_screen' },
    'metallic screen': { header: 'Metallic screen', unit: 'mm2', key: 'S_screen' },
  };

  const excelKeys = Object.keys(sample).filter(k => k && k !== 'Part Number' && k !== 'Units');
  const matchedColumns: Array<{ excelKey: string; mapping: { header: string; unit: string; key: string } }> = [];
  for (const excelKey of excelKeys) {
    const normalized = normalizeValue(excelKey).toLowerCase();
    for (const [pattern, mapping] of Object.entries(columnMapping)) {
      if (normalized === pattern.toLowerCase() || new RegExp(pattern, 'i').test(normalized)) {
        matchedColumns.push({ excelKey, mapping });
        break;
      }
    }
  }

  const seenKeys = new Set<string>();
  const deduplicated: typeof matchedColumns = [];
  for (const item of matchedColumns) {
    if (!seenKeys.has(item.mapping.key)) {
      seenKeys.add(item.mapping.key);
      deduplicated.push(item);
    }
  }

  const sampleKeys = Object.keys(sample).filter(k => k && k !== 'Part Number' && k !== 'Units').sort();
  const compatibleRows = rows.filter(r => {
    const rKeys = Object.keys(r).filter(k => k && k !== 'Part Number' && k !== 'Units').sort();
    return JSON.stringify(rKeys) === JSON.stringify(sampleKeys);
  });
  if (compatibleRows.length === 0) return { ok: false, technicalItems: [], voltageTables: [] };

  const csKey =
    guessColumnKey(sample, [/number of cores and cross-section/i, /cross.?section/i, /ross section conductor/i]) || null;
  const voltageKey = guessColumnKey(sample, [/rated voltage/i, /voltage rating/i, /nennspannung/i, /spannungs/i]) || null;
  if (!csKey) return { ok: false, technicalItems: [], voltageTables: [] };

  const byVoltage = new Map<string, number[]>();
  for (let i = 0; i < compatibleRows.length; i++) {
    const cs = normalizeValue(String(compatibleRows[i]?.[csKey] ?? ''));
    if (!cs) continue;
    const rawV = voltageKey ? normalizeValue(String(compatibleRows[i]?.[voltageKey] ?? '')) : '';
    const voltageLabel = normalizeVoltageLabel(rawV || '');
    const key = voltageLabel || (args.locale === 'de' ? 'Spannung unbekannt' : 'Voltage unknown');
    const arr = byVoltage.get(key) ?? [];
    arr.push(i);
    byVoltage.set(key, arr);
  }

  const voltageKeysSorted = Array.from(byVoltage.keys()).sort((a, b) => {
    const na = parseVoltageSortKey(a);
    const nb = parseVoltageSortKey(b);
    if (na !== nb) return na - nb;
    return a.localeCompare(b);
  });

  const technicalItems: KeyValueItem[] = [];
  const globalConstantColumns = new Set<string>();

  for (const { excelKey, mapping } of deduplicated) {
    const values = compatibleRows.map(r => normalizeValue(String(r?.[excelKey] ?? ''))).filter(Boolean);
    const unique = Array.from(new Set(values.map(v => v.toLowerCase())));
    if (unique.length === 1 && values.length > 0) {
      globalConstantColumns.add(excelKey);
      const unit = normalizeUnit(units[excelKey] || mapping.unit || '');
      const labelBase = technicalFullLabel({ key: mapping.key, excelKey, locale: args.locale });
      const label = formatExcelHeaderLabel(labelBase, unit);
      const value = compactCellForDenseTable(values[0], unit, args.locale);
      if (!technicalItems.find(t => t.label === label)) technicalItems.push({ label, value, unit });
    }
  }
  technicalItems.sort((a, b) => a.label.localeCompare(b.label));

  const voltageTables: VoltageTableModel[] = [];
  for (const vKey of voltageKeysSorted) {
    const indices = byVoltage.get(vKey) || [];
    if (!indices.length) continue;
    const crossSections = indices.map(idx => normalizeValue(String(compatibleRows[idx]?.[csKey] ?? '')));

    const metaItems: KeyValueItem[] = [];
    const metaCandidates = new Map<string, KeyValueItem>();

    if (voltageKey) {
      const rawV = normalizeValue(String(compatibleRows[indices[0]]?.[voltageKey] ?? ''));
      metaItems.push({
        label: args.locale === 'de' ? 'Spannung' : 'Voltage',
        value: normalizeVoltageLabel(rawV || ''),
      });
    }

    const metaKeyPriority = [
      'test_volt',
      'temp_range',
      'max_op_temp',
      'max_sc_temp',
      'min_lay_temp',
      'min_store_temp',
      'cpr',
      'flame',
    ];
    const metaKeyPrioritySet = new Set(metaKeyPriority);

    const denseTableKeyOrder = [
      'Cond',
      'shape',
      // Electrical properties (when present)
      'cap',
      'X',
      // Dimensions and ratings
      'DI',
      'RI',
      'Wi',
      'Ibl',
      'Ibe',
      'Ik_cond',
      'Wm',
      'Rbv',
      'Ø',
      // Screen data (when present)
      'D_screen',
      'S_screen',
      'Fzv',
      'G',
    ] as const;
    const denseTableKeys = new Set<string>(denseTableKeyOrder);

    const tableColumns: Array<{ excelKey: string; mapping: { header: string; unit: string; key: string } }> = [];
    for (const { excelKey, mapping } of deduplicated) {
      if (excelKey === csKey || excelKey === voltageKey) continue;
      const values = indices.map(idx => normalizeValue(String(compatibleRows[idx]?.[excelKey] ?? ''))).filter(Boolean);
      if (!values.length) continue;
      const unique = Array.from(new Set(values.map(v => v.toLowerCase())));
      const unit = normalizeUnit(units[excelKey] || mapping.unit || '');

      if (denseTableKeys.has(mapping.key)) {
        tableColumns.push({ excelKey, mapping });
        continue;
      }

      if (globalConstantColumns.has(excelKey) && !metaKeyPrioritySet.has(mapping.key)) {
        continue;
      }

      const value = unique.length === 1 ? compactCellForDenseTable(values[0], unit, args.locale) : summarizeSmartOptions(excelKey, values);
      const label = metaFullLabel({ key: mapping.key, excelKey, locale: args.locale });
      metaCandidates.set(mapping.key, { label, value, unit });
    }

    for (const k of metaKeyPriority) {
      const item = metaCandidates.get(k);
      if (item && item.label && item.value) metaItems.push(item);
    }

    const mappedByKey = new Map<string, { excelKey: string; mapping: { header: string; unit: string; key: string } }>();
    for (const c of tableColumns) {
      if (!mappedByKey.has(c.mapping.key)) mappedByKey.set(c.mapping.key, c);
    }

    // If conductor material is missing in Excel, derive it from designation.
    // NA... => Al, N... => Cu (common for this dataset).
    if (!mappedByKey.has('Cond')) {
      mappedByKey.set('Cond', {
        excelKey: '',
        mapping: { header: 'Cond.', unit: '', key: 'Cond' },
      });
    }

    const orderedTableColumns = denseTableKeyOrder
      .filter(k => mappedByKey.has(k))
      .map(k => mappedByKey.get(k)!)
      .map(({ excelKey, mapping }) => {
        const unit = normalizeUnit((excelKey ? units[excelKey] : '') || mapping.unit || '');
        return {
          key: mapping.key,
          label: denseAbbrevLabel({ key: mapping.key, locale: args.locale, unit }) || formatExcelHeaderLabel(excelKey, unit),
          get: (rowIndex: number) => {
            const srcRowIndex = indices[rowIndex];

            if (mapping.key === 'Cond' && !excelKey) {
              const pn = normalizeDesignation(args.product.name || args.product.slug || args.product.sku || '');
              if (/^NA/.test(pn)) return 'Al';
              if (/^N/.test(pn)) return 'Cu';
              return '';
            }

            const raw = excelKey ? normalizeValue(String(compatibleRows[srcRowIndex]?.[excelKey] ?? '')) : '';
            return compactCellForDenseTable(raw, unit, args.locale);
          },
        };
      });

    voltageTables.push({ voltageLabel: vKey, metaItems, crossSections, columns: orderedTableColumns });
  }

  return { ok: true, technicalItems, voltageTables };
}

export function buildDatasheetModel(args: { product: ProductData; locale: 'en' | 'de' }): DatasheetModel {
  const labels = getLabels(args.locale);
  const categoriesLine = (args.product.categories || []).map(c => stripHtml(c.name)).join(' • ');
  const descriptionText = stripHtml(args.product.shortDescriptionHtml || args.product.descriptionHtml || '');
  const heroSrc = resolveMediaToLocalPath(args.product.featuredImage || args.product.images?.[0] || null);
  const productUrl = getProductUrl(args.product);

  const excelModel = buildExcelModel({ product: args.product, locale: args.locale });
  const voltageTables: DatasheetVoltageTable[] = excelModel.ok
    ? excelModel.voltageTables.map(t => {
        const columns = t.columns.map(c => ({ key: c.key, label: c.label }));
        const rows = t.crossSections.map((configuration, rowIndex) => ({
          configuration,
          cells: t.columns.map(c => compactNumericForLocale(c.get(rowIndex), args.locale)),
        }));
        return {
          voltageLabel: t.voltageLabel,
          metaItems: t.metaItems,
          columns,
          rows,
        };
      })
    : [];

  return {
    locale: args.locale,
    product: {
      id: args.product.id,
      name: stripHtml(args.product.name),
      sku: args.product.sku,
      categoriesLine,
      descriptionText,
      heroSrc,
      productUrl,
    },
    labels,
    technicalItems: excelModel.ok ? excelModel.technicalItems : [],
    voltageTables,
  };
}