import { notNullish, isPrimitive } from './helpers.js'; const _DRIVE_LETTER_START_RE = /^[A-Za-z]:\//; function normalizeWindowsPath(input = "") { if (!input) { return input; } return input.replace(/\\/g, "/").replace(_DRIVE_LETTER_START_RE, (r) => r.toUpperCase()); } const _IS_ABSOLUTE_RE = /^[/\\](?![/\\])|^[/\\]{2}(?!\.)|^[A-Za-z]:[/\\]/; function cwd() { if (typeof process !== "undefined" && typeof process.cwd === "function") { return process.cwd().replace(/\\/g, "/"); } return "/"; } const resolve$2 = function(...arguments_) { arguments_ = arguments_.map((argument) => normalizeWindowsPath(argument)); let resolvedPath = ""; let resolvedAbsolute = false; for (let index = arguments_.length - 1; index >= -1 && !resolvedAbsolute; index--) { const path = index >= 0 ? arguments_[index] : cwd(); if (!path || path.length === 0) { continue; } resolvedPath = `${path}/${resolvedPath}`; resolvedAbsolute = isAbsolute(path); } resolvedPath = normalizeString(resolvedPath, !resolvedAbsolute); if (resolvedAbsolute && !isAbsolute(resolvedPath)) { return `/${resolvedPath}`; } return resolvedPath.length > 0 ? resolvedPath : "."; }; function normalizeString(path, allowAboveRoot) { let res = ""; let lastSegmentLength = 0; let lastSlash = -1; let dots = 0; let char = null; for (let index = 0; index <= path.length; ++index) { if (index < path.length) { char = path[index]; } else if (char === "/") { break; } else { char = "/"; } if (char === "/") { if (lastSlash === index - 1 || dots === 1) ; else if (dots === 2) { if (res.length < 2 || lastSegmentLength !== 2 || res[res.length - 1] !== "." || res[res.length - 2] !== ".") { if (res.length > 2) { const lastSlashIndex = res.lastIndexOf("/"); if (lastSlashIndex === -1) { res = ""; lastSegmentLength = 0; } else { res = res.slice(0, lastSlashIndex); lastSegmentLength = res.length - 1 - res.lastIndexOf("/"); } lastSlash = index; dots = 0; continue; } else if (res.length > 0) { res = ""; lastSegmentLength = 0; lastSlash = index; dots = 0; continue; } } if (allowAboveRoot) { res += res.length > 0 ? "/.." : ".."; lastSegmentLength = 2; } } else { if (res.length > 0) { res += `/${path.slice(lastSlash + 1, index)}`; } else { res = path.slice(lastSlash + 1, index); } lastSegmentLength = index - lastSlash - 1; } lastSlash = index; dots = 0; } else if (char === "." && dots !== -1) { ++dots; } else { dots = -1; } } return res; } const isAbsolute = function(p) { return _IS_ABSOLUTE_RE.test(p); }; const comma = ','.charCodeAt(0); const chars = 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/'; const intToChar = new Uint8Array(64); // 64 possible chars. const charToInt = new Uint8Array(128); // z is 122 in ASCII for (let i = 0; i < chars.length; i++) { const c = chars.charCodeAt(i); intToChar[i] = c; charToInt[c] = i; } function decodeInteger(reader, relative) { let value = 0; let shift = 0; let integer = 0; do { const c = reader.next(); integer = charToInt[c]; value |= (integer & 31) << shift; shift += 5; } while (integer & 32); const shouldNegate = value & 1; value >>>= 1; if (shouldNegate) { value = -0x80000000 | -value; } return relative + value; } function hasMoreVlq(reader, max) { if (reader.pos >= max) return false; return reader.peek() !== comma; } class StringReader { constructor(buffer) { this.pos = 0; this.buffer = buffer; } next() { return this.buffer.charCodeAt(this.pos++); } peek() { return this.buffer.charCodeAt(this.pos); } indexOf(char) { const { buffer, pos } = this; const idx = buffer.indexOf(char, pos); return idx === -1 ? buffer.length : idx; } } function decode(mappings) { const { length } = mappings; const reader = new StringReader(mappings); const decoded = []; let genColumn = 0; let sourcesIndex = 0; let sourceLine = 0; let sourceColumn = 0; let namesIndex = 0; do { const semi = reader.indexOf(';'); const line = []; let sorted = true; let lastCol = 0; genColumn = 0; while (reader.pos < semi) { let seg; genColumn = decodeInteger(reader, genColumn); if (genColumn < lastCol) sorted = false; lastCol = genColumn; if (hasMoreVlq(reader, semi)) { sourcesIndex = decodeInteger(reader, sourcesIndex); sourceLine = decodeInteger(reader, sourceLine); sourceColumn = decodeInteger(reader, sourceColumn); if (hasMoreVlq(reader, semi)) { namesIndex = decodeInteger(reader, namesIndex); seg = [genColumn, sourcesIndex, sourceLine, sourceColumn, namesIndex]; } else { seg = [genColumn, sourcesIndex, sourceLine, sourceColumn]; } } else { seg = [genColumn]; } line.push(seg); reader.pos++; } if (!sorted) sort(line); decoded.push(line); reader.pos = semi + 1; } while (reader.pos <= length); return decoded; } function sort(line) { line.sort(sortComparator$1); } function sortComparator$1(a, b) { return a[0] - b[0]; } // Matches the scheme of a URL, eg "http://" const schemeRegex = /^[\w+.-]+:\/\//; /** * Matches the parts of a URL: * 1. Scheme, including ":", guaranteed. * 2. User/password, including "@", optional. * 3. Host, guaranteed. * 4. Port, including ":", optional. * 5. Path, including "/", optional. * 6. Query, including "?", optional. * 7. Hash, including "#", optional. */ const urlRegex = /^([\w+.-]+:)\/\/([^@/#?]*@)?([^:/#?]*)(:\d+)?(\/[^#?]*)?(\?[^#]*)?(#.*)?/; /** * File URLs are weird. They dont' need the regular `//` in the scheme, they may or may not start * with a leading `/`, they can have a domain (but only if they don't start with a Windows drive). * * 1. Host, optional. * 2. Path, which may include "/", guaranteed. * 3. Query, including "?", optional. * 4. Hash, including "#", optional. */ const fileRegex = /^file:(?:\/\/((?![a-z]:)[^/#?]*)?)?(\/?[^#?]*)(\?[^#]*)?(#.*)?/i; var UrlType; (function (UrlType) { UrlType[UrlType["Empty"] = 1] = "Empty"; UrlType[UrlType["Hash"] = 2] = "Hash"; UrlType[UrlType["Query"] = 3] = "Query"; UrlType[UrlType["RelativePath"] = 4] = "RelativePath"; UrlType[UrlType["AbsolutePath"] = 5] = "AbsolutePath"; UrlType[UrlType["SchemeRelative"] = 6] = "SchemeRelative"; UrlType[UrlType["Absolute"] = 7] = "Absolute"; })(UrlType || (UrlType = {})); function isAbsoluteUrl(input) { return schemeRegex.test(input); } function isSchemeRelativeUrl(input) { return input.startsWith('//'); } function isAbsolutePath(input) { return input.startsWith('/'); } function isFileUrl(input) { return input.startsWith('file:'); } function isRelative(input) { return /^[.?#]/.test(input); } function parseAbsoluteUrl(input) { const match = urlRegex.exec(input); return makeUrl(match[1], match[2] || '', match[3], match[4] || '', match[5] || '/', match[6] || '', match[7] || ''); } function parseFileUrl(input) { const match = fileRegex.exec(input); const path = match[2]; return makeUrl('file:', '', match[1] || '', '', isAbsolutePath(path) ? path : '/' + path, match[3] || '', match[4] || ''); } function makeUrl(scheme, user, host, port, path, query, hash) { return { scheme, user, host, port, path, query, hash, type: UrlType.Absolute, }; } function parseUrl(input) { if (isSchemeRelativeUrl(input)) { const url = parseAbsoluteUrl('http:' + input); url.scheme = ''; url.type = UrlType.SchemeRelative; return url; } if (isAbsolutePath(input)) { const url = parseAbsoluteUrl('http://foo.com' + input); url.scheme = ''; url.host = ''; url.type = UrlType.AbsolutePath; return url; } if (isFileUrl(input)) return parseFileUrl(input); if (isAbsoluteUrl(input)) return parseAbsoluteUrl(input); const url = parseAbsoluteUrl('http://foo.com/' + input); url.scheme = ''; url.host = ''; url.type = input ? input.startsWith('?') ? UrlType.Query : input.startsWith('#') ? UrlType.Hash : UrlType.RelativePath : UrlType.Empty; return url; } function stripPathFilename(path) { // If a path ends with a parent directory "..", then it's a relative path with excess parent // paths. It's not a file, so we can't strip it. if (path.endsWith('/..')) return path; const index = path.lastIndexOf('/'); return path.slice(0, index + 1); } function mergePaths(url, base) { normalizePath(base, base.type); // If the path is just a "/", then it was an empty path to begin with (remember, we're a relative // path). if (url.path === '/') { url.path = base.path; } else { // Resolution happens relative to the base path's directory, not the file. url.path = stripPathFilename(base.path) + url.path; } } /** * The path can have empty directories "//", unneeded parents "foo/..", or current directory * "foo/.". We need to normalize to a standard representation. */ function normalizePath(url, type) { const rel = type <= UrlType.RelativePath; const pieces = url.path.split('/'); // We need to preserve the first piece always, so that we output a leading slash. The item at // pieces[0] is an empty string. let pointer = 1; // Positive is the number of real directories we've output, used for popping a parent directory. // Eg, "foo/bar/.." will have a positive 2, and we can decrement to be left with just "foo". let positive = 0; // We need to keep a trailing slash if we encounter an empty directory (eg, splitting "foo/" will // generate `["foo", ""]` pieces). And, if we pop a parent directory. But once we encounter a // real directory, we won't need to append, unless the other conditions happen again. let addTrailingSlash = false; for (let i = 1; i < pieces.length; i++) { const piece = pieces[i]; // An empty directory, could be a trailing slash, or just a double "//" in the path. if (!piece) { addTrailingSlash = true; continue; } // If we encounter a real directory, then we don't need to append anymore. addTrailingSlash = false; // A current directory, which we can always drop. if (piece === '.') continue; // A parent directory, we need to see if there are any real directories we can pop. Else, we // have an excess of parents, and we'll need to keep the "..". if (piece === '..') { if (positive) { addTrailingSlash = true; positive--; pointer--; } else if (rel) { // If we're in a relativePath, then we need to keep the excess parents. Else, in an absolute // URL, protocol relative URL, or an absolute path, we don't need to keep excess. pieces[pointer++] = piece; } continue; } // We've encountered a real directory. Move it to the next insertion pointer, which accounts for // any popped or dropped directories. pieces[pointer++] = piece; positive++; } let path = ''; for (let i = 1; i < pointer; i++) { path += '/' + pieces[i]; } if (!path || (addTrailingSlash && !path.endsWith('/..'))) { path += '/'; } url.path = path; } /** * Attempts to resolve `input` URL/path relative to `base`. */ function resolve$1(input, base) { if (!input && !base) return ''; const url = parseUrl(input); let inputType = url.type; if (base && inputType !== UrlType.Absolute) { const baseUrl = parseUrl(base); const baseType = baseUrl.type; switch (inputType) { case UrlType.Empty: url.hash = baseUrl.hash; // fall through case UrlType.Hash: url.query = baseUrl.query; // fall through case UrlType.Query: case UrlType.RelativePath: mergePaths(url, baseUrl); // fall through case UrlType.AbsolutePath: // The host, user, and port are joined, you can't copy one without the others. url.user = baseUrl.user; url.host = baseUrl.host; url.port = baseUrl.port; // fall through case UrlType.SchemeRelative: // The input doesn't have a schema at least, so we need to copy at least that over. url.scheme = baseUrl.scheme; } if (baseType > inputType) inputType = baseType; } normalizePath(url, inputType); const queryHash = url.query + url.hash; switch (inputType) { // This is impossible, because of the empty checks at the start of the function. // case UrlType.Empty: case UrlType.Hash: case UrlType.Query: return queryHash; case UrlType.RelativePath: { // The first char is always a "/", and we need it to be relative. const path = url.path.slice(1); if (!path) return queryHash || '.'; if (isRelative(base || input) && !isRelative(path)) { // If base started with a leading ".", or there is no base and input started with a ".", // then we need to ensure that the relative path starts with a ".". We don't know if // relative starts with a "..", though, so check before prepending. return './' + path + queryHash; } return path + queryHash; } case UrlType.AbsolutePath: return url.path + queryHash; default: return url.scheme + '//' + url.user + url.host + url.port + url.path + queryHash; } } function resolve(input, base) { // The base is always treated as a directory, if it's not empty. // https://github.com/mozilla/source-map/blob/8cb3ee57/lib/util.js#L327 // https://github.com/chromium/chromium/blob/da4adbb3/third_party/blink/renderer/devtools/front_end/sdk/SourceMap.js#L400-L401 if (base && !base.endsWith('/')) base += '/'; return resolve$1(input, base); } /** * Removes everything after the last "/", but leaves the slash. */ function stripFilename(path) { if (!path) return ''; const index = path.lastIndexOf('/'); return path.slice(0, index + 1); } const COLUMN = 0; const SOURCES_INDEX = 1; const SOURCE_LINE = 2; const SOURCE_COLUMN = 3; const NAMES_INDEX = 4; const REV_GENERATED_LINE = 1; const REV_GENERATED_COLUMN = 2; function maybeSort(mappings, owned) { const unsortedIndex = nextUnsortedSegmentLine(mappings, 0); if (unsortedIndex === mappings.length) return mappings; // If we own the array (meaning we parsed it from JSON), then we're free to directly mutate it. If // not, we do not want to modify the consumer's input array. if (!owned) mappings = mappings.slice(); for (let i = unsortedIndex; i < mappings.length; i = nextUnsortedSegmentLine(mappings, i + 1)) { mappings[i] = sortSegments(mappings[i], owned); } return mappings; } function nextUnsortedSegmentLine(mappings, start) { for (let i = start; i < mappings.length; i++) { if (!isSorted(mappings[i])) return i; } return mappings.length; } function isSorted(line) { for (let j = 1; j < line.length; j++) { if (line[j][COLUMN] < line[j - 1][COLUMN]) { return false; } } return true; } function sortSegments(line, owned) { if (!owned) line = line.slice(); return line.sort(sortComparator); } function sortComparator(a, b) { return a[COLUMN] - b[COLUMN]; } let found = false; /** * A binary search implementation that returns the index if a match is found. * If no match is found, then the left-index (the index associated with the item that comes just * before the desired index) is returned. To maintain proper sort order, a splice would happen at * the next index: * * ```js * const array = [1, 3]; * const needle = 2; * const index = binarySearch(array, needle, (item, needle) => item - needle); * * assert.equal(index, 0); * array.splice(index + 1, 0, needle); * assert.deepEqual(array, [1, 2, 3]); * ``` */ function binarySearch(haystack, needle, low, high) { while (low <= high) { const mid = low + ((high - low) >> 1); const cmp = haystack[mid][COLUMN] - needle; if (cmp === 0) { found = true; return mid; } if (cmp < 0) { low = mid + 1; } else { high = mid - 1; } } found = false; return low - 1; } function upperBound(haystack, needle, index) { for (let i = index + 1; i < haystack.length; index = i++) { if (haystack[i][COLUMN] !== needle) break; } return index; } function lowerBound(haystack, needle, index) { for (let i = index - 1; i >= 0; index = i--) { if (haystack[i][COLUMN] !== needle) break; } return index; } function memoizedState() { return { lastKey: -1, lastNeedle: -1, lastIndex: -1, }; } /** * This overly complicated beast is just to record the last tested line/column and the resulting * index, allowing us to skip a few tests if mappings are monotonically increasing. */ function memoizedBinarySearch(haystack, needle, state, key) { const { lastKey, lastNeedle, lastIndex } = state; let low = 0; let high = haystack.length - 1; if (key === lastKey) { if (needle === lastNeedle) { found = lastIndex !== -1 && haystack[lastIndex][COLUMN] === needle; return lastIndex; } if (needle >= lastNeedle) { // lastIndex may be -1 if the previous needle was not found. low = lastIndex === -1 ? 0 : lastIndex; } else { high = lastIndex; } } state.lastKey = key; state.lastNeedle = needle; return (state.lastIndex = binarySearch(haystack, needle, low, high)); } // Rebuilds the original source files, with mappings that are ordered by source line/column instead // of generated line/column. function buildBySources(decoded, memos) { const sources = memos.map(buildNullArray); for (let i = 0; i < decoded.length; i++) { const line = decoded[i]; for (let j = 0; j < line.length; j++) { const seg = line[j]; if (seg.length === 1) continue; const sourceIndex = seg[SOURCES_INDEX]; const sourceLine = seg[SOURCE_LINE]; const sourceColumn = seg[SOURCE_COLUMN]; const originalSource = sources[sourceIndex]; const originalLine = (originalSource[sourceLine] || (originalSource[sourceLine] = [])); const memo = memos[sourceIndex]; // The binary search either found a match, or it found the left-index just before where the // segment should go. Either way, we want to insert after that. And there may be multiple // generated segments associated with an original location, so there may need to move several // indexes before we find where we need to insert. let index = upperBound(originalLine, sourceColumn, memoizedBinarySearch(originalLine, sourceColumn, memo, sourceLine)); memo.lastIndex = ++index; insert(originalLine, index, [sourceColumn, i, seg[COLUMN]]); } } return sources; } function insert(array, index, value) { for (let i = array.length; i > index; i--) { array[i] = array[i - 1]; } array[index] = value; } // Null arrays allow us to use ordered index keys without actually allocating contiguous memory like // a real array. We use a null-prototype object to avoid prototype pollution and deoptimizations. // Numeric properties on objects are magically sorted in ascending order by the engine regardless of // the insertion order. So, by setting any numeric keys, even out of order, we'll get ascending // order when iterating with for-in. function buildNullArray() { return { __proto__: null }; } const LINE_GTR_ZERO = '`line` must be greater than 0 (lines start at line 1)'; const COL_GTR_EQ_ZERO = '`column` must be greater than or equal to 0 (columns start at column 0)'; const LEAST_UPPER_BOUND = -1; const GREATEST_LOWER_BOUND = 1; class TraceMap { constructor(map, mapUrl) { const isString = typeof map === 'string'; if (!isString && map._decodedMemo) return map; const parsed = (isString ? JSON.parse(map) : map); const { version, file, names, sourceRoot, sources, sourcesContent } = parsed; this.version = version; this.file = file; this.names = names || []; this.sourceRoot = sourceRoot; this.sources = sources; this.sourcesContent = sourcesContent; this.ignoreList = parsed.ignoreList || parsed.x_google_ignoreList || undefined; const from = resolve(sourceRoot || '', stripFilename(mapUrl)); this.resolvedSources = sources.map((s) => resolve(s || '', from)); const { mappings } = parsed; if (typeof mappings === 'string') { this._encoded = mappings; this._decoded = undefined; } else { this._encoded = undefined; this._decoded = maybeSort(mappings, isString); } this._decodedMemo = memoizedState(); this._bySources = undefined; this._bySourceMemos = undefined; } } /** * Typescript doesn't allow friend access to private fields, so this just casts the map into a type * with public access modifiers. */ function cast(map) { return map; } /** * Returns the decoded (array of lines of segments) form of the SourceMap's mappings field. */ function decodedMappings(map) { var _a; return ((_a = cast(map))._decoded || (_a._decoded = decode(cast(map)._encoded))); } /** * A higher-level API to find the source/line/column associated with a generated line/column * (think, from a stack trace). Line is 1-based, but column is 0-based, due to legacy behavior in * `source-map` library. */ function originalPositionFor(map, needle) { let { line, column, bias } = needle; line--; if (line < 0) throw new Error(LINE_GTR_ZERO); if (column < 0) throw new Error(COL_GTR_EQ_ZERO); const decoded = decodedMappings(map); // It's common for parent source maps to have pointers to lines that have no // mapping (like a "//# sourceMappingURL=") at the end of the child file. if (line >= decoded.length) return OMapping(null, null, null, null); const segments = decoded[line]; const index = traceSegmentInternal(segments, cast(map)._decodedMemo, line, column, bias || GREATEST_LOWER_BOUND); if (index === -1) return OMapping(null, null, null, null); const segment = segments[index]; if (segment.length === 1) return OMapping(null, null, null, null); const { names, resolvedSources } = map; return OMapping(resolvedSources[segment[SOURCES_INDEX]], segment[SOURCE_LINE] + 1, segment[SOURCE_COLUMN], segment.length === 5 ? names[segment[NAMES_INDEX]] : null); } /** * Finds the generated line/column position of the provided source/line/column source position. */ function generatedPositionFor(map, needle) { const { source, line, column, bias } = needle; return generatedPosition(map, source, line, column, bias || GREATEST_LOWER_BOUND, false); } function OMapping(source, line, column, name) { return { source, line, column, name }; } function GMapping(line, column) { return { line, column }; } function traceSegmentInternal(segments, memo, line, column, bias) { let index = memoizedBinarySearch(segments, column, memo, line); if (found) { index = (bias === LEAST_UPPER_BOUND ? upperBound : lowerBound)(segments, column, index); } else if (bias === LEAST_UPPER_BOUND) index++; if (index === -1 || index === segments.length) return -1; return index; } function sliceGeneratedPositions(segments, memo, line, column, bias) { let min = traceSegmentInternal(segments, memo, line, column, GREATEST_LOWER_BOUND); // We ignored the bias when tracing the segment so that we're guarnateed to find the first (in // insertion order) segment that matched. Even if we did respect the bias when tracing, we would // still need to call `lowerBound()` to find the first segment, which is slower than just looking // for the GREATEST_LOWER_BOUND to begin with. The only difference that matters for us is when the // binary search didn't match, in which case GREATEST_LOWER_BOUND just needs to increment to // match LEAST_UPPER_BOUND. if (!found && bias === LEAST_UPPER_BOUND) min++; if (min === -1 || min === segments.length) return []; // We may have found the segment that started at an earlier column. If this is the case, then we // need to slice all generated segments that match _that_ column, because all such segments span // to our desired column. const matchedColumn = found ? column : segments[min][COLUMN]; // The binary search is not guaranteed to find the lower bound when a match wasn't found. if (!found) min = lowerBound(segments, matchedColumn, min); const max = upperBound(segments, matchedColumn, min); const result = []; for (; min <= max; min++) { const segment = segments[min]; result.push(GMapping(segment[REV_GENERATED_LINE] + 1, segment[REV_GENERATED_COLUMN])); } return result; } function generatedPosition(map, source, line, column, bias, all) { var _a; line--; if (line < 0) throw new Error(LINE_GTR_ZERO); if (column < 0) throw new Error(COL_GTR_EQ_ZERO); const { sources, resolvedSources } = map; let sourceIndex = sources.indexOf(source); if (sourceIndex === -1) sourceIndex = resolvedSources.indexOf(source); if (sourceIndex === -1) return all ? [] : GMapping(null, null); const generated = ((_a = cast(map))._bySources || (_a._bySources = buildBySources(decodedMappings(map), (cast(map)._bySourceMemos = sources.map(memoizedState))))); const segments = generated[sourceIndex][line]; if (segments == null) return all ? [] : GMapping(null, null); const memo = cast(map)._bySourceMemos[sourceIndex]; if (all) return sliceGeneratedPositions(segments, memo, line, column, bias); const index = traceSegmentInternal(segments, memo, line, column, bias); if (index === -1) return GMapping(null, null); const segment = segments[index]; return GMapping(segment[REV_GENERATED_LINE] + 1, segment[REV_GENERATED_COLUMN]); } const CHROME_IE_STACK_REGEXP = /^\s*at .*(?:\S:\d+|\(native\))/m; const SAFARI_NATIVE_CODE_REGEXP = /^(?:eval@)?(?:\[native code\])?$/; const stackIgnorePatterns = [ "node:internal", /\/packages\/\w+\/dist\//, /\/@vitest\/\w+\/dist\//, "/vitest/dist/", "/vitest/src/", "/vite-node/dist/", "/vite-node/src/", "/node_modules/chai/", "/node_modules/tinypool/", "/node_modules/tinyspy/", // browser related deps "/deps/chunk-", "/deps/@vitest", "/deps/loupe", "/deps/chai", /node:\w+/, /__vitest_test__/, /__vitest_browser__/, /\/deps\/vitest_/ ]; function extractLocation(urlLike) { if (!urlLike.includes(":")) { return [urlLike]; } const regExp = /(.+?)(?::(\d+))?(?::(\d+))?$/; const parts = regExp.exec(urlLike.replace(/^\(|\)$/g, "")); if (!parts) { return [urlLike]; } let url = parts[1]; if (url.startsWith("async ")) { url = url.slice(6); } if (url.startsWith("http:") || url.startsWith("https:")) { const urlObj = new URL(url); url = urlObj.pathname; } if (url.startsWith("/@fs/")) { const isWindows = /^\/@fs\/[a-zA-Z]:\//.test(url); url = url.slice(isWindows ? 5 : 4); } return [url, parts[2] || void 0, parts[3] || void 0]; } function parseSingleFFOrSafariStack(raw) { let line = raw.trim(); if (SAFARI_NATIVE_CODE_REGEXP.test(line)) { return null; } if (line.includes(" > eval")) { line = line.replace( / line (\d+)(?: > eval line \d+)* > eval:\d+:\d+/g, ":$1" ); } if (!line.includes("@") && !line.includes(":")) { return null; } const functionNameRegex = /((.*".+"[^@]*)?[^@]*)(@)/; const matches = line.match(functionNameRegex); const functionName = matches && matches[1] ? matches[1] : void 0; const [url, lineNumber, columnNumber] = extractLocation( line.replace(functionNameRegex, "") ); if (!url || !lineNumber || !columnNumber) { return null; } return { file: url, method: functionName || "", line: Number.parseInt(lineNumber), column: Number.parseInt(columnNumber) }; } function parseSingleStack(raw) { const line = raw.trim(); if (!CHROME_IE_STACK_REGEXP.test(line)) { return parseSingleFFOrSafariStack(line); } return parseSingleV8Stack(line); } function parseSingleV8Stack(raw) { let line = raw.trim(); if (!CHROME_IE_STACK_REGEXP.test(line)) { return null; } if (line.includes("(eval ")) { line = line.replace(/eval code/g, "eval").replace(/(\(eval at [^()]*)|(,.*$)/g, ""); } let sanitizedLine = line.replace(/^\s+/, "").replace(/\(eval code/g, "(").replace(/^.*?\s+/, ""); const location = sanitizedLine.match(/ (\(.+\)$)/); sanitizedLine = location ? sanitizedLine.replace(location[0], "") : sanitizedLine; const [url, lineNumber, columnNumber] = extractLocation( location ? location[1] : sanitizedLine ); let method = location && sanitizedLine || ""; let file = url && ["eval", ""].includes(url) ? void 0 : url; if (!file || !lineNumber || !columnNumber) { return null; } if (method.startsWith("async ")) { method = method.slice(6); } if (file.startsWith("file://")) { file = file.slice(7); } file = resolve$2(file); if (method) { method = method.replace(/__vite_ssr_import_\d+__\./g, ""); } return { method, file, line: Number.parseInt(lineNumber), column: Number.parseInt(columnNumber) }; } function parseStacktrace(stack, options = {}) { const { ignoreStackEntries = stackIgnorePatterns } = options; let stacks = !CHROME_IE_STACK_REGEXP.test(stack) ? parseFFOrSafariStackTrace(stack) : parseV8Stacktrace(stack); if (ignoreStackEntries.length) { stacks = stacks.filter( (stack2) => !ignoreStackEntries.some((p) => stack2.file.match(p)) ); } return stacks.map((stack2) => { var _a; if (options.getFileName) { stack2.file = options.getFileName(stack2.file); } const map = (_a = options.getSourceMap) == null ? void 0 : _a.call(options, stack2.file); if (!map || typeof map !== "object" || !map.version) { return stack2; } const traceMap = new TraceMap(map); const { line, column } = originalPositionFor(traceMap, stack2); if (line != null && column != null) { return { ...stack2, line, column }; } return stack2; }); } function parseFFOrSafariStackTrace(stack) { return stack.split("\n").map((line) => parseSingleFFOrSafariStack(line)).filter(notNullish); } function parseV8Stacktrace(stack) { return stack.split("\n").map((line) => parseSingleV8Stack(line)).filter(notNullish); } function parseErrorStacktrace(e, options = {}) { if (!e || isPrimitive(e)) { return []; } if (e.stacks) { return e.stacks; } const stackStr = e.stack || e.stackStr || ""; let stackFrames = parseStacktrace(stackStr, options); if (options.frameFilter) { stackFrames = stackFrames.filter( (f) => options.frameFilter(e, f) !== false ); } e.stacks = stackFrames; return stackFrames; } export { TraceMap, generatedPositionFor, originalPositionFor, parseErrorStacktrace, parseSingleFFOrSafariStack, parseSingleStack, parseSingleV8Stack, parseStacktrace };