/*! * shapefile Version 0.6.6(https://github.com/mbostock/shapefile) * Copyright 2017 Mike Bostock. * mbostock/shapefile is licensed under the BSD 3-clause "New" or "Revised" License */ (function (global, factory) { typeof exports === 'object' && typeof module !== 'undefined' ? factory(exports) : typeof define === 'function' && define.amd ? define(['exports'], factory) : (factory((global.shapefile = {}))); }(this, (function (exports) { 'use strict'; var array_cancel = function() { this._array = null; return Promise.resolve(); }; var array_read = function() { var array = this._array; this._array = null; return Promise.resolve(array ? {done: false, value: array} : {done: true, value: undefined}); }; function array(array) { return new ArraySource(array instanceof Uint8Array ? array : new Uint8Array(array)); } function ArraySource(array) { this._array = array; } ArraySource.prototype.read = array_read; ArraySource.prototype.cancel = array_cancel; var fetchPath = function(url) { return fetch(url).then(function(response) { return response.body && response.body.getReader ? response.body.getReader() : response.arrayBuffer().then(array); }); }; var requestPath = function(url) { return new Promise(function(resolve, reject) { var request = new XMLHttpRequest; request.responseType = "arraybuffer"; request.onload = function() { resolve(array(request.response)); }; request.onerror = reject; request.ontimeout = reject; request.open("GET", url, true); request.send(); }); }; function path(path) { return (typeof fetch === "function" ? fetchPath : requestPath)(path); } function stream(source) { return typeof source.read === "function" ? source : source.getReader(); } var empty = new Uint8Array(0); var slice_cancel = function() { return this._source.cancel(); }; function concat(a, b) { if (!a.length) return b; if (!b.length) return a; var c = new Uint8Array(a.length + b.length); c.set(a); c.set(b, a.length); return c; } var slice_read = function() { var that = this, array = that._array.subarray(that._index); return that._source.read().then(function(result) { that._array = empty; that._index = 0; return result.done ? (array.length > 0 ? {done: false, value: array} : {done: true, value: undefined}) : {done: false, value: concat(array, result.value)}; }); }; var slice_slice = function(length) { if ((length |= 0) < 0) throw new Error("invalid length"); var that = this, index = this._array.length - this._index; // If the request fits within the remaining buffer, resolve it immediately. if (this._index + length <= this._array.length) { return Promise.resolve(this._array.subarray(this._index, this._index += length)); } // Otherwise, read chunks repeatedly until the request is fulfilled. var array = new Uint8Array(length); array.set(this._array.subarray(this._index)); return (function read() { return that._source.read().then(function(result) { // When done, it鈥檚 possible the request wasn鈥檛 fully fullfilled! // If so, the pre-allocated array is too big and needs slicing. if (result.done) { that._array = empty; that._index = 0; return index > 0 ? array.subarray(0, index) : null; } // If this chunk fulfills the request, return the resulting array. if (index + result.value.length >= length) { that._array = result.value; that._index = length - index; array.set(result.value.subarray(0, length - index), index); return array; } // Otherwise copy this chunk into the array, then read the next chunk. array.set(result.value, index); index += result.value.length; return read(); }); })(); }; function slice(source) { return typeof source.slice === "function" ? source : new SliceSource(typeof source.read === "function" ? source : source.getReader()); } function SliceSource(source) { this._source = source; this._array = empty; this._index = 0; } SliceSource.prototype.read = slice_read; SliceSource.prototype.slice = slice_slice; SliceSource.prototype.cancel = slice_cancel; var dbf_cancel = function() { return this._source.cancel(); }; var readBoolean = function(value) { return /^[nf]$/i.test(value) ? false : /^[yt]$/i.test(value) ? true : null; }; var readDate = function(value) { return new Date(+value.substring(0, 4), value.substring(4, 6) - 1, +value.substring(6, 8)); }; var readNumber = function(value) { return !(value = value.trim()) || isNaN(value = +value) ? null : value; }; var readString = function(value) { return value.trim() || null; }; var types = { B: readNumber, C: readString, D: readDate, F: readNumber, L: readBoolean, M: readNumber, N: readNumber }; var dbf_read = function() { var that = this, i = 1; return that._source.slice(that._recordLength).then(function(value) { return value && (value[0] !== 0x1a) ? {done: false, value: that._fields.reduce(function(p, f) { p[f.name] = types[f.type](that._decode(value.subarray(i, i += f.length))); return p; }, {})} : {done: true, value: undefined}; }); }; var view = function(array) { return new DataView(array.buffer, array.byteOffset, array.byteLength); }; var dbf = function(source, decoder) { source = slice(source); return source.slice(32).then(function(array) { var head = view(array); return source.slice(head.getUint16(8, true) - 32).then(function(array) { return new Dbf(source, decoder, head, view(array)); }); }); }; function Dbf(source, decoder, head, body) { this._source = source; this._decode = decoder.decode.bind(decoder); this._recordLength = head.getUint16(10, true); this._fields = []; for (var n = 0; body.getUint8(n) !== 0x0d; n += 32) { for (var j = 0; j < 11; ++j) if (body.getUint8(n + j) === 0) break; this._fields.push({ name: this._decode(new Uint8Array(body.buffer, body.byteOffset + n, j)), type: String.fromCharCode(body.getUint8(n + 11)), length: body.getUint8(n + 16) }); } } var prototype = Dbf.prototype; prototype.read = dbf_read; prototype.cancel = dbf_cancel; function cancel() { return this._source.cancel(); } var parseMultiPoint = function(record) { var i = 40, j, n = record.getInt32(36, true), coordinates = new Array(n); for (j = 0; j < n; ++j, i += 16) coordinates[j] = [record.getFloat64(i, true), record.getFloat64(i + 8, true)]; return {type: "MultiPoint", coordinates: coordinates}; }; var parseNull = function() { return null; }; var parsePoint = function(record) { return {type: "Point", coordinates: [record.getFloat64(4, true), record.getFloat64(12, true)]}; }; var parsePolygon = function(record) { var i = 44, j, n = record.getInt32(36, true), m = record.getInt32(40, true), parts = new Array(n), points = new Array(m), polygons = [], holes = []; for (j = 0; j < n; ++j, i += 4) parts[j] = record.getInt32(i, true); for (j = 0; j < m; ++j, i += 16) points[j] = [record.getFloat64(i, true), record.getFloat64(i + 8, true)]; parts.forEach(function(i, j) { var ring = points.slice(i, parts[j + 1]); if (ringClockwise(ring)) polygons.push([ring]); else holes.push(ring); }); holes.forEach(function(hole) { polygons.some(function(polygon) { if (ringContainsSome(polygon[0], hole)) { polygon.push(hole); return true; } }) || polygons.push([hole]); }); return polygons.length === 1 ? {type: "Polygon", coordinates: polygons[0]} : {type: "MultiPolygon", coordinates: polygons}; }; function ringClockwise(ring) { if ((n = ring.length) < 4) return false; var i = 0, n, area = ring[n - 1][1] * ring[0][0] - ring[n - 1][0] * ring[0][1]; while (++i < n) area += ring[i - 1][1] * ring[i][0] - ring[i - 1][0] * ring[i][1]; return area >= 0; } function ringContainsSome(ring, hole) { var i = -1, n = hole.length, c; while (++i < n) { if (c = ringContains(ring, hole[i])) { return c > 0; } } return false; } function ringContains(ring, point) { var x = point[0], y = point[1], contains = -1; for (var i = 0, n = ring.length, j = n - 1; i < n; j = i++) { var pi = ring[i], xi = pi[0], yi = pi[1], pj = ring[j], xj = pj[0], yj = pj[1]; if (segmentContains(pi, pj, point)) { return 0; } if (((yi > y) !== (yj > y)) && ((x < (xj - xi) * (y - yi) / (yj - yi) + xi))) { contains = -contains; } } return contains; } function segmentContains(p0, p1, p2) { var x20 = p2[0] - p0[0], y20 = p2[1] - p0[1]; if (x20 === 0 && y20 === 0) return true; var x10 = p1[0] - p0[0], y10 = p1[1] - p0[1]; if (x10 === 0 && y10 === 0) return false; var t = (x20 * x10 + y20 * y10) / (x10 * x10 + y10 * y10); return t < 0 || t > 1 ? false : t === 0 || t === 1 ? true : t * x10 === x20 && t * y10 === y20; } var parsePolyLine = function(record) { var i = 44, j, n = record.getInt32(36, true), m = record.getInt32(40, true), parts = new Array(n), points = new Array(m); for (j = 0; j < n; ++j, i += 4) parts[j] = record.getInt32(i, true); for (j = 0; j < m; ++j, i += 16) points[j] = [record.getFloat64(i, true), record.getFloat64(i + 8, true)]; return n === 1 ? {type: "LineString", coordinates: points} : {type: "MultiLineString", coordinates: parts.map(function(i, j) { return points.slice(i, parts[j + 1]); })}; }; var concat$1 = function(a, b) { var ab = new Uint8Array(a.length + b.length); ab.set(a, 0); ab.set(b, a.length); return ab; }; var shp_read = function() { var that = this; ++that._index; return that._source.slice(12).then(function(array) { if (array == null) return {done: true, value: undefined}; var header = view(array); // If the record starts with an invalid shape type (see #36), scan ahead in // four-byte increments to find the next valid record, identified by the // expected index, a non-empty content length and a valid shape type. function skip() { return that._source.slice(4).then(function(chunk) { if (chunk == null) return {done: true, value: undefined}; header = view(array = concat$1(array.slice(4), chunk)); return header.getInt32(0, false) !== that._index ? skip() : read(); }); } // All records should have at least four bytes (for the record shape type), // so an invalid content length indicates corruption. function read() { var length = header.getInt32(4, false) * 2 - 4, type = header.getInt32(8, true); return length < 0 || (type && type !== that._type) ? skip() : that._source.slice(length).then(function(chunk) { return {done: false, value: type ? that._parse(view(concat$1(array.slice(8), chunk))) : null}; }); } return read(); }); }; var parsers = { 0: parseNull, 1: parsePoint, 3: parsePolyLine, 5: parsePolygon, 8: parseMultiPoint, 11: parsePoint, // PointZ 13: parsePolyLine, // PolyLineZ 15: parsePolygon, // PolygonZ 18: parseMultiPoint, // MultiPointZ 21: parsePoint, // PointM 23: parsePolyLine, // PolyLineM 25: parsePolygon, // PolygonM 28: parseMultiPoint // MultiPointM }; var shp = function(source) { source = slice(source); return source.slice(100).then(function(array) { return new Shp(source, view(array)); }); }; function Shp(source, header) { var type = header.getInt32(32, true); if (!(type in parsers)) throw new Error("unsupported shape type: " + type); this._source = source; this._type = type; this._index = 0; this._parse = parsers[type]; this.bbox = [header.getFloat64(36, true), header.getFloat64(44, true), header.getFloat64(52, true), header.getFloat64(60, true)]; } var prototype$2 = Shp.prototype; prototype$2.read = shp_read; prototype$2.cancel = cancel; function noop() {} var shapefile_cancel = function() { return Promise.all([ this._dbf && this._dbf.cancel(), this._shp.cancel() ]).then(noop); }; var shapefile_read = function() { var that = this; return Promise.all([ that._dbf ? that._dbf.read() : {value: {}}, that._shp.read() ]).then(function(results) { var dbf = results[0], shp = results[1]; return shp.done ? shp : { done: false, value: { type: "Feature", properties: dbf.value, geometry: shp.value } }; }); }; var shapefile = function(shpSource, dbfSource, decoder) { return Promise.all([ shp(shpSource), dbfSource && dbf(dbfSource, decoder) ]).then(function(sources) { return new Shapefile(sources[0], sources[1]); }); }; function Shapefile(shp$$1, dbf$$1) { this._shp = shp$$1; this._dbf = dbf$$1; this.bbox = shp$$1.bbox; } var prototype$1 = Shapefile.prototype; prototype$1.read = shapefile_read; prototype$1.cancel = shapefile_cancel; function open(shp$$1, dbf$$1, options) { if (typeof dbf$$1 === "string") { if (!/\.dbf$/.test(dbf$$1)) dbf$$1 += ".dbf"; dbf$$1 = path(dbf$$1, options); } else if (dbf$$1 instanceof ArrayBuffer || dbf$$1 instanceof Uint8Array) { dbf$$1 = array(dbf$$1); } else if (dbf$$1 != null) { dbf$$1 = stream(dbf$$1); } if (typeof shp$$1 === "string") { if (!/\.shp$/.test(shp$$1)) shp$$1 += ".shp"; if (dbf$$1 === undefined) dbf$$1 = path(shp$$1.substring(0, shp$$1.length - 4) + ".dbf", options).catch(function() {}); shp$$1 = path(shp$$1, options); } else if (shp$$1 instanceof ArrayBuffer || shp$$1 instanceof Uint8Array) { shp$$1 = array(shp$$1); } else { shp$$1 = stream(shp$$1); } return Promise.all([shp$$1, dbf$$1]).then(function(sources) { var shp$$1 = sources[0], dbf$$1 = sources[1], encoding = "windows-1252"; if (options && options.encoding != null) encoding = options.encoding; return shapefile(shp$$1, dbf$$1, dbf$$1 && new TextDecoder(encoding)); }); } function openShp(source, options) { if (typeof source === "string") { if (!/\.shp$/.test(source)) source += ".shp"; source = path(source, options); } else if (source instanceof ArrayBuffer || source instanceof Uint8Array) { source = array(source); } else { source = stream(source); } return Promise.resolve(source).then(shp); } function openDbf(source, options) { var encoding = "windows-1252"; if (options && options.encoding != null) encoding = options.encoding; encoding = new TextDecoder(encoding); if (typeof source === "string") { if (!/\.dbf$/.test(source)) source += ".dbf"; source = path(source, options); } else if (source instanceof ArrayBuffer || source instanceof Uint8Array) { source = array(source); } else { source = stream(source); } return Promise.resolve(source).then(function(source) { return dbf(source, encoding); }); } function read(shp$$1, dbf$$1, options) { return open(shp$$1, dbf$$1, options).then(function(source) { var features = [], collection = {type: "FeatureCollection", features: features, bbox: source.bbox}; return source.read().then(function read(result) { if (result.done) return collection; features.push(result.value); return source.read().then(read); }); }); } exports.open = open; exports.openShp = openShp; exports.openDbf = openDbf; exports.read = read; Object.defineProperty(exports, '__esModule', { value: true }); })));