watermanagement-backend-prod/node_modules/@jridgewell/trace-mapping/dist/trace-mapping.umd.js

(function (global, factory) {
    typeof exports === 'object' && typeof module !== 'undefined' ? factory(exports, require('@jridgewell/sourcemap-codec'), require('@jridgewell/resolve-uri')) :
    typeof define === 'function' && define.amd ? define(['exports', '@jridgewell/sourcemap-codec', '@jridgewell/resolve-uri'], factory) :
    (global = typeof globalThis !== 'undefined' ? globalThis : global || self, factory(global.traceMapping = {}, global.sourcemapCodec, global.resolveURI));
})(this, (function (exports, sourcemapCodec, resolveUri) { 'use strict';

    function _interopDefaultLegacy (e) { return e && typeof e === 'object' && 'default' in e ? e : { 'default': e }; }

    var resolveUri__default = /*#__PURE__*/_interopDefaultLegacy(resolveUri);

    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 resolveUri__default["default"](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.
                const index = upperBound(originalLine, sourceColumn, memoizedBinarySearch(originalLine, sourceColumn, memo, sourceLine));
                insert(originalLine, (memo.lastIndex = index + 1), [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 AnyMap = function (map, mapUrl) {
        const parsed = typeof map === 'string' ? JSON.parse(map) : map;
        if (!('sections' in parsed))
            return new TraceMap(parsed, mapUrl);
        const mappings = [];
        const sources = [];
        const sourcesContent = [];
        const names = [];
        recurse(parsed, mapUrl, mappings, sources, sourcesContent, names, 0, 0, Infinity, Infinity);
        const joined = {
            version: 3,
            file: parsed.file,
            names,
            sources,
            sourcesContent,
            mappings,
        };
        return exports.presortedDecodedMap(joined);
    };
    function recurse(input, mapUrl, mappings, sources, sourcesContent, names, lineOffset, columnOffset, stopLine, stopColumn) {
        const { sections } = input;
        for (let i = 0; i < sections.length; i++) {
            const { map, offset } = sections[i];
            let sl = stopLine;
            let sc = stopColumn;
            if (i + 1 < sections.length) {
                const nextOffset = sections[i + 1].offset;
                sl = Math.min(stopLine, lineOffset + nextOffset.line);
                if (sl === stopLine) {
                    sc = Math.min(stopColumn, columnOffset + nextOffset.column);
                }
                else if (sl < stopLine) {
                    sc = columnOffset + nextOffset.column;
                }
            }
            addSection(map, mapUrl, mappings, sources, sourcesContent, names, lineOffset + offset.line, columnOffset + offset.column, sl, sc);
        }
    }
    function addSection(input, mapUrl, mappings, sources, sourcesContent, names, lineOffset, columnOffset, stopLine, stopColumn) {
        if ('sections' in input)
            return recurse(...arguments);
        const map = new TraceMap(input, mapUrl);
        const sourcesOffset = sources.length;
        const namesOffset = names.length;
        const decoded = exports.decodedMappings(map);
        const { resolvedSources, sourcesContent: contents } = map;
        append(sources, resolvedSources);
        append(names, map.names);
        if (contents)
            append(sourcesContent, contents);
        else
            for (let i = 0; i < resolvedSources.length; i++)
                sourcesContent.push(null);
        for (let i = 0; i < decoded.length; i++) {
            const lineI = lineOffset + i;
            // We can only add so many lines before we step into the range that the next section's map
            // controls. When we get to the last line, then we'll start checking the segments to see if
            // they've crossed into the column range. But it may not have any columns that overstep, so we
            // still need to check that we don't overstep lines, too.
            if (lineI > stopLine)
                return;
            // The out line may already exist in mappings (if we're continuing the line started by a
            // previous section). Or, we may have jumped ahead several lines to start this section.
            const out = getLine(mappings, lineI);
            // On the 0th loop, the section's column offset shifts us forward. On all other lines (since the
            // map can be multiple lines), it doesn't.
            const cOffset = i === 0 ? columnOffset : 0;
            const line = decoded[i];
            for (let j = 0; j < line.length; j++) {
                const seg = line[j];
                const column = cOffset + seg[COLUMN];
                // If this segment steps into the column range that the next section's map controls, we need
                // to stop early.
                if (lineI === stopLine && column >= stopColumn)
                    return;
                if (seg.length === 1) {
                    out.push([column]);
                    continue;
                }
                const sourcesIndex = sourcesOffset + seg[SOURCES_INDEX];
                const sourceLine = seg[SOURCE_LINE];
                const sourceColumn = seg[SOURCE_COLUMN];
                out.push(seg.length === 4
                    ? [column, sourcesIndex, sourceLine, sourceColumn]
                    : [column, sourcesIndex, sourceLine, sourceColumn, namesOffset + seg[NAMES_INDEX]]);
            }
        }
    }
    function append(arr, other) {
        for (let i = 0; i < other.length; i++)
            arr.push(other[i]);
    }
    function getLine(arr, index) {
        for (let i = arr.length; i <= index; i++)
            arr[i] = [];
        return arr[index];
    }

    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;
    /**
     * Returns the encoded (VLQ string) form of the SourceMap's mappings field.
     */
    exports.encodedMappings = void 0;
    /**
     * Returns the decoded (array of lines of segments) form of the SourceMap's mappings field.
     */
    exports.decodedMappings = void 0;
    /**
     * A low-level API to find the segment associated with a generated line/column (think, from a
     * stack trace). Line and column here are 0-based, unlike `originalPositionFor`.
     */
    exports.traceSegment = void 0;
    /**
     * 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.
     */
    exports.originalPositionFor = void 0;
    /**
     * Finds the generated line/column position of the provided source/line/column source position.
     */
    exports.generatedPositionFor = void 0;
    /**
     * Finds all generated line/column positions of the provided source/line/column source position.
     */
    exports.allGeneratedPositionsFor = void 0;
    /**
     * Iterates each mapping in generated position order.
     */
    exports.eachMapping = void 0;
    /**
     * Retrieves the source content for a particular source, if its found. Returns null if not.
     */
    exports.sourceContentFor = void 0;
    /**
     * A helper that skips sorting of the input map's mappings array, which can be expensive for larger
     * maps.
     */
    exports.presortedDecodedMap = void 0;
    /**
     * Returns a sourcemap object (with decoded mappings) suitable for passing to a library that expects
     * a sourcemap, or to JSON.stringify.
     */
    exports.decodedMap = void 0;
    /**
     * Returns a sourcemap object (with encoded mappings) suitable for passing to a library that expects
     * a sourcemap, or to JSON.stringify.
     */
    exports.encodedMap = void 0;
    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;
            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;
        }
    }
    (() => {
        exports.encodedMappings = (map) => {
            var _a;
            return ((_a = map._encoded) !== null && _a !== void 0 ? _a : (map._encoded = sourcemapCodec.encode(map._decoded)));
        };
        exports.decodedMappings = (map) => {
            return (map._decoded || (map._decoded = sourcemapCodec.decode(map._encoded)));
        };
        exports.traceSegment = (map, line, column) => {
            const decoded = exports.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 null;
            const segments = decoded[line];
            const index = traceSegmentInternal(segments, map._decodedMemo, line, column, GREATEST_LOWER_BOUND);
            return index === -1 ? null : segments[index];
        };
        exports.originalPositionFor = (map, { line, column, bias }) => {
            line--;
            if (line < 0)
                throw new Error(LINE_GTR_ZERO);
            if (column < 0)
                throw new Error(COL_GTR_EQ_ZERO);
            const decoded = exports.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, 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);
        };
        exports.allGeneratedPositionsFor = (map, { source, line, column, bias }) => {
            // SourceMapConsumer uses LEAST_UPPER_BOUND for some reason, so we follow suit.
            return generatedPosition(map, source, line, column, bias || LEAST_UPPER_BOUND, true);
        };
        exports.generatedPositionFor = (map, { source, line, column, bias }) => {
            return generatedPosition(map, source, line, column, bias || GREATEST_LOWER_BOUND, false);
        };
        exports.eachMapping = (map, cb) => {
            const decoded = exports.decodedMappings(map);
            const { names, resolvedSources } = map;
            for (let i = 0; i < decoded.length; i++) {
                const line = decoded[i];
                for (let j = 0; j < line.length; j++) {
                    const seg = line[j];
                    const generatedLine = i + 1;
                    const generatedColumn = seg[0];
                    let source = null;
                    let originalLine = null;
                    let originalColumn = null;
                    let name = null;
                    if (seg.length !== 1) {
                        source = resolvedSources[seg[1]];
                        originalLine = seg[2] + 1;
                        originalColumn = seg[3];
                    }
                    if (seg.length === 5)
                        name = names[seg[4]];
                    cb({
                        generatedLine,
                        generatedColumn,
                        source,
                        originalLine,
                        originalColumn,
                        name,
                    });
                }
            }
        };
        exports.sourceContentFor = (map, source) => {
            const { sources, resolvedSources, sourcesContent } = map;
            if (sourcesContent == null)
                return null;
            let index = sources.indexOf(source);
            if (index === -1)
                index = resolvedSources.indexOf(source);
            return index === -1 ? null : sourcesContent[index];
        };
        exports.presortedDecodedMap = (map, mapUrl) => {
            const tracer = new TraceMap(clone(map, []), mapUrl);
            tracer._decoded = map.mappings;
            return tracer;
        };
        exports.decodedMap = (map) => {
            return clone(map, exports.decodedMappings(map));
        };
        exports.encodedMap = (map) => {
            return clone(map, exports.encodedMappings(map));
        };
        function generatedPosition(map, source, line, column, bias, all) {
            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 = (map._bySources || (map._bySources = buildBySources(exports.decodedMappings(map), (map._bySourceMemos = sources.map(memoizedState)))));
            const segments = generated[sourceIndex][line];
            if (segments == null)
                return all ? [] : GMapping(null, null);
            const memo = 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]);
        }
    })();
    function clone(map, mappings) {
        return {
            version: map.version,
            file: map.file,
            names: map.names,
            sourceRoot: map.sourceRoot,
            sources: map.sources,
            sourcesContent: map.sourcesContent,
            mappings,
        };
    }
    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;
    }

    exports.AnyMap = AnyMap;
    exports.GREATEST_LOWER_BOUND = GREATEST_LOWER_BOUND;
    exports.LEAST_UPPER_BOUND = LEAST_UPPER_BOUND;
    exports.TraceMap = TraceMap;

    Object.defineProperty(exports, '__esModule', { value: true });

}));
//# sourceMappingURL=trace-mapping.umd.js.map