lixinran
/
MindMap
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
MindMap/frontend/node_modules/pdfjs-dist/image_decoders/pdf.image_decoders.mjs

7718 lines
240 KiB
JavaScript
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/**
* @licstart The following is the entire license notice for the
* JavaScript code in this page
*
* Copyright 2024 Mozilla Foundation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* @licend The above is the entire license notice for the
* JavaScript code in this page
*/
/**
* pdfjsVersion = 5.4.149
* pdfjsBuild = 9e2e9e209
*/
/******/ // The require scope
/******/ var __webpack_require__ = {};
/******/
/************************************************************************/
/******/ /* webpack/runtime/define property getters */
/******/ (() => {
/******/ // define getter functions for harmony exports
/******/ __webpack_require__.d = (exports, definition) => {
/******/ for(var key in definition) {
/******/ if(__webpack_require__.o(definition, key) && !__webpack_require__.o(exports, key)) {
/******/ Object.defineProperty(exports, key, { enumerable: true, get: definition[key] });
/******/ }
/******/ }
/******/ };
/******/ })();
/******/
/******/ /* webpack/runtime/hasOwnProperty shorthand */
/******/ (() => {
/******/ __webpack_require__.o = (obj, prop) => (Object.prototype.hasOwnProperty.call(obj, prop))
/******/ })();
/******/
/************************************************************************/
var __webpack_exports__ = {};
;// ./src/shared/util.js
const isNodeJS = typeof process === "object" && process + "" === "[object process]" && !process.versions.nw && !(process.versions.electron && process.type && process.type !== "browser");
const FONT_IDENTITY_MATRIX = (/* unused pure expression or super */ null && ([0.001, 0, 0, 0.001, 0, 0]));
const LINE_FACTOR = 1.35;
const LINE_DESCENT_FACTOR = 0.35;
const BASELINE_FACTOR = LINE_DESCENT_FACTOR / LINE_FACTOR;
const RenderingIntentFlag = {
ANY: 0x01,
DISPLAY: 0x02,
PRINT: 0x04,
SAVE: 0x08,
ANNOTATIONS_FORMS: 0x10,
ANNOTATIONS_STORAGE: 0x20,
ANNOTATIONS_DISABLE: 0x40,
IS_EDITING: 0x80,
OPLIST: 0x100
};
const AnnotationMode = {
DISABLE: 0,
ENABLE: 1,
ENABLE_FORMS: 2,
ENABLE_STORAGE: 3
};
const util_AnnotationEditorPrefix = "pdfjs_internal_editor_";
const AnnotationEditorType = {
DISABLE: -1,
NONE: 0,
FREETEXT: 3,
HIGHLIGHT: 9,
STAMP: 13,
INK: 15,
POPUP: 16,
SIGNATURE: 101,
COMMENT: 102
};
const AnnotationEditorParamsType = {
RESIZE: 1,
CREATE: 2,
FREETEXT_SIZE: 11,
FREETEXT_COLOR: 12,
FREETEXT_OPACITY: 13,
INK_COLOR: 21,
INK_THICKNESS: 22,
INK_OPACITY: 23,
HIGHLIGHT_COLOR: 31,
HIGHLIGHT_THICKNESS: 32,
HIGHLIGHT_FREE: 33,
HIGHLIGHT_SHOW_ALL: 34,
DRAW_STEP: 41
};
const PermissionFlag = {
PRINT: 0x04,
MODIFY_CONTENTS: 0x08,
COPY: 0x10,
MODIFY_ANNOTATIONS: 0x20,
FILL_INTERACTIVE_FORMS: 0x100,
COPY_FOR_ACCESSIBILITY: 0x200,
ASSEMBLE: 0x400,
PRINT_HIGH_QUALITY: 0x800
};
const TextRenderingMode = {
FILL: 0,
STROKE: 1,
FILL_STROKE: 2,
INVISIBLE: 3,
FILL_ADD_TO_PATH: 4,
STROKE_ADD_TO_PATH: 5,
FILL_STROKE_ADD_TO_PATH: 6,
ADD_TO_PATH: 7,
FILL_STROKE_MASK: 3,
ADD_TO_PATH_FLAG: 4
};
const util_ImageKind = {
GRAYSCALE_1BPP: 1,
RGB_24BPP: 2,
RGBA_32BPP: 3
};
const AnnotationType = {
TEXT: 1,
LINK: 2,
FREETEXT: 3,
LINE: 4,
SQUARE: 5,
CIRCLE: 6,
POLYGON: 7,
POLYLINE: 8,
HIGHLIGHT: 9,
UNDERLINE: 10,
SQUIGGLY: 11,
STRIKEOUT: 12,
STAMP: 13,
CARET: 14,
INK: 15,
POPUP: 16,
FILEATTACHMENT: 17,
SOUND: 18,
MOVIE: 19,
WIDGET: 20,
SCREEN: 21,
PRINTERMARK: 22,
TRAPNET: 23,
WATERMARK: 24,
THREED: 25,
REDACT: 26
};
const AnnotationReplyType = {
GROUP: "Group",
REPLY: "R"
};
const AnnotationFlag = {
INVISIBLE: 0x01,
HIDDEN: 0x02,
PRINT: 0x04,
NOZOOM: 0x08,
NOROTATE: 0x10,
NOVIEW: 0x20,
READONLY: 0x40,
LOCKED: 0x80,
TOGGLENOVIEW: 0x100,
LOCKEDCONTENTS: 0x200
};
const AnnotationFieldFlag = {
READONLY: 0x0000001,
REQUIRED: 0x0000002,
NOEXPORT: 0x0000004,
MULTILINE: 0x0001000,
PASSWORD: 0x0002000,
NOTOGGLETOOFF: 0x0004000,
RADIO: 0x0008000,
PUSHBUTTON: 0x0010000,
COMBO: 0x0020000,
EDIT: 0x0040000,
SORT: 0x0080000,
FILESELECT: 0x0100000,
MULTISELECT: 0x0200000,
DONOTSPELLCHECK: 0x0400000,
DONOTSCROLL: 0x0800000,
COMB: 0x1000000,
RICHTEXT: 0x2000000,
RADIOSINUNISON: 0x2000000,
COMMITONSELCHANGE: 0x4000000
};
const AnnotationBorderStyleType = {
SOLID: 1,
DASHED: 2,
BEVELED: 3,
INSET: 4,
UNDERLINE: 5
};
const AnnotationActionEventType = {
E: "Mouse Enter",
X: "Mouse Exit",
D: "Mouse Down",
U: "Mouse Up",
Fo: "Focus",
Bl: "Blur",
PO: "PageOpen",
PC: "PageClose",
PV: "PageVisible",
PI: "PageInvisible",
K: "Keystroke",
F: "Format",
V: "Validate",
C: "Calculate"
};
const DocumentActionEventType = {
WC: "WillClose",
WS: "WillSave",
DS: "DidSave",
WP: "WillPrint",
DP: "DidPrint"
};
const PageActionEventType = {
O: "PageOpen",
C: "PageClose"
};
const VerbosityLevel = {
ERRORS: 0,
WARNINGS: 1,
INFOS: 5
};
const OPS = {
dependency: 1,
setLineWidth: 2,
setLineCap: 3,
setLineJoin: 4,
setMiterLimit: 5,
setDash: 6,
setRenderingIntent: 7,
setFlatness: 8,
setGState: 9,
save: 10,
restore: 11,
transform: 12,
moveTo: 13,
lineTo: 14,
curveTo: 15,
curveTo2: 16,
curveTo3: 17,
closePath: 18,
rectangle: 19,
stroke: 20,
closeStroke: 21,
fill: 22,
eoFill: 23,
fillStroke: 24,
eoFillStroke: 25,
closeFillStroke: 26,
closeEOFillStroke: 27,
endPath: 28,
clip: 29,
eoClip: 30,
beginText: 31,
endText: 32,
setCharSpacing: 33,
setWordSpacing: 34,
setHScale: 35,
setLeading: 36,
setFont: 37,
setTextRenderingMode: 38,
setTextRise: 39,
moveText: 40,
setLeadingMoveText: 41,
setTextMatrix: 42,
nextLine: 43,
showText: 44,
showSpacedText: 45,
nextLineShowText: 46,
nextLineSetSpacingShowText: 47,
setCharWidth: 48,
setCharWidthAndBounds: 49,
setStrokeColorSpace: 50,
setFillColorSpace: 51,
setStrokeColor: 52,
setStrokeColorN: 53,
setFillColor: 54,
setFillColorN: 55,
setStrokeGray: 56,
setFillGray: 57,
setStrokeRGBColor: 58,
setFillRGBColor: 59,
setStrokeCMYKColor: 60,
setFillCMYKColor: 61,
shadingFill: 62,
beginInlineImage: 63,
beginImageData: 64,
endInlineImage: 65,
paintXObject: 66,
markPoint: 67,
markPointProps: 68,
beginMarkedContent: 69,
beginMarkedContentProps: 70,
endMarkedContent: 71,
beginCompat: 72,
endCompat: 73,
paintFormXObjectBegin: 74,
paintFormXObjectEnd: 75,
beginGroup: 76,
endGroup: 77,
beginAnnotation: 80,
endAnnotation: 81,
paintImageMaskXObject: 83,
paintImageMaskXObjectGroup: 84,
paintImageXObject: 85,
paintInlineImageXObject: 86,
paintInlineImageXObjectGroup: 87,
paintImageXObjectRepeat: 88,
paintImageMaskXObjectRepeat: 89,
paintSolidColorImageMask: 90,
constructPath: 91,
setStrokeTransparent: 92,
setFillTransparent: 93,
rawFillPath: 94
};
const DrawOPS = {
moveTo: 0,
lineTo: 1,
curveTo: 2,
closePath: 3
};
const PasswordResponses = {
NEED_PASSWORD: 1,
INCORRECT_PASSWORD: 2
};
let verbosity = VerbosityLevel.WARNINGS;
function setVerbosityLevel(level) {
if (Number.isInteger(level)) {
verbosity = level;
}
}
function getVerbosityLevel() {
return verbosity;
}
function info(msg) {
if (verbosity >= VerbosityLevel.INFOS) {
console.log(`Info: ${msg}`);
}
}
function util_warn(msg) {
if (verbosity >= VerbosityLevel.WARNINGS) {
console.log(`Warning: ${msg}`);
}
}
function unreachable(msg) {
throw new Error(msg);
}
function util_assert(cond, msg) {
if (!cond) {
unreachable(msg);
}
}
function _isValidProtocol(url) {
switch (url?.protocol) {
case "http:":
case "https:":
case "ftp:":
case "mailto:":
case "tel:":
return true;
default:
return false;
}
}
function createValidAbsoluteUrl(url, baseUrl = null, options = null) {
if (!url) {
return null;
}
if (options && typeof url === "string") {
if (options.addDefaultProtocol && url.startsWith("www.")) {
const dots = url.match(/\./g);
if (dots?.length >= 2) {
url = `http://${url}`;
}
}
if (options.tryConvertEncoding) {
try {
url = stringToUTF8String(url);
} catch {}
}
}
const absoluteUrl = baseUrl ? URL.parse(url, baseUrl) : URL.parse(url);
return _isValidProtocol(absoluteUrl) ? absoluteUrl : null;
}
function updateUrlHash(url, hash, allowRel = false) {
const res = URL.parse(url);
if (res) {
res.hash = hash;
return res.href;
}
if (allowRel && createValidAbsoluteUrl(url, "http://example.com")) {
return url.split("#", 1)[0] + `${hash ? `#${hash}` : ""}`;
}
return "";
}
function shadow(obj, prop, value, nonSerializable = false) {
Object.defineProperty(obj, prop, {
value,
enumerable: !nonSerializable,
configurable: true,
writable: false
});
return value;
}
const BaseException = function BaseExceptionClosure() {
function BaseException(message, name) {
this.message = message;
this.name = name;
}
BaseException.prototype = new Error();
BaseException.constructor = BaseException;
return BaseException;
}();
class PasswordException extends BaseException {
constructor(msg, code) {
super(msg, "PasswordException");
this.code = code;
}
}
class UnknownErrorException extends BaseException {
constructor(msg, details) {
super(msg, "UnknownErrorException");
this.details = details;
}
}
class InvalidPDFException extends BaseException {
constructor(msg) {
super(msg, "InvalidPDFException");
}
}
class ResponseException extends BaseException {
constructor(msg, status, missing) {
super(msg, "ResponseException");
this.status = status;
this.missing = missing;
}
}
class FormatError extends BaseException {
constructor(msg) {
super(msg, "FormatError");
}
}
class AbortException extends BaseException {
constructor(msg) {
super(msg, "AbortException");
}
}
function bytesToString(bytes) {
if (typeof bytes !== "object" || bytes?.length === undefined) {
unreachable("Invalid argument for bytesToString");
}
const length = bytes.length;
const MAX_ARGUMENT_COUNT = 8192;
if (length < MAX_ARGUMENT_COUNT) {
return String.fromCharCode.apply(null, bytes);
}
const strBuf = [];
for (let i = 0; i < length; i += MAX_ARGUMENT_COUNT) {
const chunkEnd = Math.min(i + MAX_ARGUMENT_COUNT, length);
const chunk = bytes.subarray(i, chunkEnd);
strBuf.push(String.fromCharCode.apply(null, chunk));
}
return strBuf.join("");
}
function stringToBytes(str) {
if (typeof str !== "string") {
unreachable("Invalid argument for stringToBytes");
}
const length = str.length;
const bytes = new Uint8Array(length);
for (let i = 0; i < length; ++i) {
bytes[i] = str.charCodeAt(i) & 0xff;
}
return bytes;
}
function string32(value) {
return String.fromCharCode(value >> 24 & 0xff, value >> 16 & 0xff, value >> 8 & 0xff, value & 0xff);
}
function util_objectSize(obj) {
return Object.keys(obj).length;
}
function isLittleEndian() {
const buffer8 = new Uint8Array(4);
buffer8[0] = 1;
const view32 = new Uint32Array(buffer8.buffer, 0, 1);
return view32[0] === 1;
}
function isEvalSupported() {
try {
new Function("");
return true;
} catch {
return false;
}
}
class util_FeatureTest {
static get isLittleEndian() {
return shadow(this, "isLittleEndian", isLittleEndian());
}
static get isEvalSupported() {
return shadow(this, "isEvalSupported", isEvalSupported());
}
static get isOffscreenCanvasSupported() {
return shadow(this, "isOffscreenCanvasSupported", typeof OffscreenCanvas !== "undefined");
}
static get isImageDecoderSupported() {
return shadow(this, "isImageDecoderSupported", typeof ImageDecoder !== "undefined");
}
static get platform() {
const {
platform,
userAgent
} = navigator;
return shadow(this, "platform", {
isAndroid: userAgent.includes("Android"),
isLinux: platform.includes("Linux"),
isMac: platform.includes("Mac"),
isWindows: platform.includes("Win"),
isFirefox: userAgent.includes("Firefox")
});
}
static get isCSSRoundSupported() {
return shadow(this, "isCSSRoundSupported", globalThis.CSS?.supports?.("width: round(1.5px, 1px)"));
}
}
const util_hexNumbers = Array.from(Array(256).keys(), n => n.toString(16).padStart(2, "0"));
class util_Util {
static makeHexColor(r, g, b) {
return `#${util_hexNumbers[r]}${util_hexNumbers[g]}${util_hexNumbers[b]}`;
}
static domMatrixToTransform(dm) {
return [dm.a, dm.b, dm.c, dm.d, dm.e, dm.f];
}
static scaleMinMax(transform, minMax) {
let temp;
if (transform[0]) {
if (transform[0] < 0) {
temp = minMax[0];
minMax[0] = minMax[2];
minMax[2] = temp;
}
minMax[0] *= transform[0];
minMax[2] *= transform[0];
if (transform[3] < 0) {
temp = minMax[1];
minMax[1] = minMax[3];
minMax[3] = temp;
}
minMax[1] *= transform[3];
minMax[3] *= transform[3];
} else {
temp = minMax[0];
minMax[0] = minMax[1];
minMax[1] = temp;
temp = minMax[2];
minMax[2] = minMax[3];
minMax[3] = temp;
if (transform[1] < 0) {
temp = minMax[1];
minMax[1] = minMax[3];
minMax[3] = temp;
}
minMax[1] *= transform[1];
minMax[3] *= transform[1];
if (transform[2] < 0) {
temp = minMax[0];
minMax[0] = minMax[2];
minMax[2] = temp;
}
minMax[0] *= transform[2];
minMax[2] *= transform[2];
}
minMax[0] += transform[4];
minMax[1] += transform[5];
minMax[2] += transform[4];
minMax[3] += transform[5];
}
static transform(m1, m2) {
return [m1[0] * m2[0] + m1[2] * m2[1], m1[1] * m2[0] + m1[3] * m2[1], m1[0] * m2[2] + m1[2] * m2[3], m1[1] * m2[2] + m1[3] * m2[3], m1[0] * m2[4] + m1[2] * m2[5] + m1[4], m1[1] * m2[4] + m1[3] * m2[5] + m1[5]];
}
static multiplyByDOMMatrix(m, md) {
return [m[0] * md.a + m[2] * md.b, m[1] * md.a + m[3] * md.b, m[0] * md.c + m[2] * md.d, m[1] * md.c + m[3] * md.d, m[0] * md.e + m[2] * md.f + m[4], m[1] * md.e + m[3] * md.f + m[5]];
}
static applyTransform(p, m, pos = 0) {
const p0 = p[pos];
const p1 = p[pos + 1];
p[pos] = p0 * m[0] + p1 * m[2] + m[4];
p[pos + 1] = p0 * m[1] + p1 * m[3] + m[5];
}
static applyTransformToBezier(p, transform, pos = 0) {
const m0 = transform[0];
const m1 = transform[1];
const m2 = transform[2];
const m3 = transform[3];
const m4 = transform[4];
const m5 = transform[5];
for (let i = 0; i < 6; i += 2) {
const pI = p[pos + i];
const pI1 = p[pos + i + 1];
p[pos + i] = pI * m0 + pI1 * m2 + m4;
p[pos + i + 1] = pI * m1 + pI1 * m3 + m5;
}
}
static applyInverseTransform(p, m) {
const p0 = p[0];
const p1 = p[1];
const d = m[0] * m[3] - m[1] * m[2];
p[0] = (p0 * m[3] - p1 * m[2] + m[2] * m[5] - m[4] * m[3]) / d;
p[1] = (-p0 * m[1] + p1 * m[0] + m[4] * m[1] - m[5] * m[0]) / d;
}
static axialAlignedBoundingBox(rect, transform, output) {
const m0 = transform[0];
const m1 = transform[1];
const m2 = transform[2];
const m3 = transform[3];
const m4 = transform[4];
const m5 = transform[5];
const r0 = rect[0];
const r1 = rect[1];
const r2 = rect[2];
const r3 = rect[3];
let a0 = m0 * r0 + m4;
let a2 = a0;
let a1 = m0 * r2 + m4;
let a3 = a1;
let b0 = m3 * r1 + m5;
let b2 = b0;
let b1 = m3 * r3 + m5;
let b3 = b1;
if (m1 !== 0 || m2 !== 0) {
const m1r0 = m1 * r0;
const m1r2 = m1 * r2;
const m2r1 = m2 * r1;
const m2r3 = m2 * r3;
a0 += m2r1;
a3 += m2r1;
a1 += m2r3;
a2 += m2r3;
b0 += m1r0;
b3 += m1r0;
b1 += m1r2;
b2 += m1r2;
}
output[0] = Math.min(output[0], a0, a1, a2, a3);
output[1] = Math.min(output[1], b0, b1, b2, b3);
output[2] = Math.max(output[2], a0, a1, a2, a3);
output[3] = Math.max(output[3], b0, b1, b2, b3);
}
static inverseTransform(m) {
const d = m[0] * m[3] - m[1] * m[2];
return [m[3] / d, -m[1] / d, -m[2] / d, m[0] / d, (m[2] * m[5] - m[4] * m[3]) / d, (m[4] * m[1] - m[5] * m[0]) / d];
}
static singularValueDecompose2dScale(matrix, output) {
const m0 = matrix[0];
const m1 = matrix[1];
const m2 = matrix[2];
const m3 = matrix[3];
const a = m0 ** 2 + m1 ** 2;
const b = m0 * m2 + m1 * m3;
const c = m2 ** 2 + m3 ** 2;
const first = (a + c) / 2;
const second = Math.sqrt(first ** 2 - (a * c - b ** 2));
output[0] = Math.sqrt(first + second || 1);
output[1] = Math.sqrt(first - second || 1);
}
static normalizeRect(rect) {
const r = rect.slice(0);
if (rect[0] > rect[2]) {
r[0] = rect[2];
r[2] = rect[0];
}
if (rect[1] > rect[3]) {
r[1] = rect[3];
r[3] = rect[1];
}
return r;
}
static intersect(rect1, rect2) {
const xLow = Math.max(Math.min(rect1[0], rect1[2]), Math.min(rect2[0], rect2[2]));
const xHigh = Math.min(Math.max(rect1[0], rect1[2]), Math.max(rect2[0], rect2[2]));
if (xLow > xHigh) {
return null;
}
const yLow = Math.max(Math.min(rect1[1], rect1[3]), Math.min(rect2[1], rect2[3]));
const yHigh = Math.min(Math.max(rect1[1], rect1[3]), Math.max(rect2[1], rect2[3]));
if (yLow > yHigh) {
return null;
}
return [xLow, yLow, xHigh, yHigh];
}
static pointBoundingBox(x, y, minMax) {
minMax[0] = Math.min(minMax[0], x);
minMax[1] = Math.min(minMax[1], y);
minMax[2] = Math.max(minMax[2], x);
minMax[3] = Math.max(minMax[3], y);
}
static rectBoundingBox(x0, y0, x1, y1, minMax) {
minMax[0] = Math.min(minMax[0], x0, x1);
minMax[1] = Math.min(minMax[1], y0, y1);
minMax[2] = Math.max(minMax[2], x0, x1);
minMax[3] = Math.max(minMax[3], y0, y1);
}
static #getExtremumOnCurve(x0, x1, x2, x3, y0, y1, y2, y3, t, minMax) {
if (t <= 0 || t >= 1) {
return;
}
const mt = 1 - t;
const tt = t * t;
const ttt = tt * t;
const x = mt * (mt * (mt * x0 + 3 * t * x1) + 3 * tt * x2) + ttt * x3;
const y = mt * (mt * (mt * y0 + 3 * t * y1) + 3 * tt * y2) + ttt * y3;
minMax[0] = Math.min(minMax[0], x);
minMax[1] = Math.min(minMax[1], y);
minMax[2] = Math.max(minMax[2], x);
minMax[3] = Math.max(minMax[3], y);
}
static #getExtremum(x0, x1, x2, x3, y0, y1, y2, y3, a, b, c, minMax) {
if (Math.abs(a) < 1e-12) {
if (Math.abs(b) >= 1e-12) {
this.#getExtremumOnCurve(x0, x1, x2, x3, y0, y1, y2, y3, -c / b, minMax);
}
return;
}
const delta = b ** 2 - 4 * c * a;
if (delta < 0) {
return;
}
const sqrtDelta = Math.sqrt(delta);
const a2 = 2 * a;
this.#getExtremumOnCurve(x0, x1, x2, x3, y0, y1, y2, y3, (-b + sqrtDelta) / a2, minMax);
this.#getExtremumOnCurve(x0, x1, x2, x3, y0, y1, y2, y3, (-b - sqrtDelta) / a2, minMax);
}
static bezierBoundingBox(x0, y0, x1, y1, x2, y2, x3, y3, minMax) {
minMax[0] = Math.min(minMax[0], x0, x3);
minMax[1] = Math.min(minMax[1], y0, y3);
minMax[2] = Math.max(minMax[2], x0, x3);
minMax[3] = Math.max(minMax[3], y0, y3);
this.#getExtremum(x0, x1, x2, x3, y0, y1, y2, y3, 3 * (-x0 + 3 * (x1 - x2) + x3), 6 * (x0 - 2 * x1 + x2), 3 * (x1 - x0), minMax);
this.#getExtremum(x0, x1, x2, x3, y0, y1, y2, y3, 3 * (-y0 + 3 * (y1 - y2) + y3), 6 * (y0 - 2 * y1 + y2), 3 * (y1 - y0), minMax);
}
}
const PDFStringTranslateTable = (/* unused pure expression or super */ null && ([0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2d8, 0x2c7, 0x2c6, 0x2d9, 0x2dd, 0x2db, 0x2da, 0x2dc, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2022, 0x2020, 0x2021, 0x2026, 0x2014, 0x2013, 0x192, 0x2044, 0x2039, 0x203a, 0x2212, 0x2030, 0x201e, 0x201c, 0x201d, 0x2018, 0x2019, 0x201a, 0x2122, 0xfb01, 0xfb02, 0x141, 0x152, 0x160, 0x178, 0x17d, 0x131, 0x142, 0x153, 0x161, 0x17e, 0, 0x20ac]));
function util_stringToPDFString(str, keepEscapeSequence = false) {
if (str[0] >= "\xEF") {
let encoding;
if (str[0] === "\xFE" && str[1] === "\xFF") {
encoding = "utf-16be";
if (str.length % 2 === 1) {
str = str.slice(0, -1);
}
} else if (str[0] === "\xFF" && str[1] === "\xFE") {
encoding = "utf-16le";
if (str.length % 2 === 1) {
str = str.slice(0, -1);
}
} else if (str[0] === "\xEF" && str[1] === "\xBB" && str[2] === "\xBF") {
encoding = "utf-8";
}
if (encoding) {
try {
const decoder = new TextDecoder(encoding, {
fatal: true
});
const buffer = stringToBytes(str);
const decoded = decoder.decode(buffer);
if (keepEscapeSequence || !decoded.includes("\x1b")) {
return decoded;
}
return decoded.replaceAll(/\x1b[^\x1b]*(?:\x1b|$)/g, "");
} catch (ex) {
util_warn(`stringToPDFString: "${ex}".`);
}
}
}
const strBuf = [];
for (let i = 0, ii = str.length; i < ii; i++) {
const charCode = str.charCodeAt(i);
if (!keepEscapeSequence && charCode === 0x1b) {
while (++i < ii && str.charCodeAt(i) !== 0x1b) {}
continue;
}
const code = PDFStringTranslateTable[charCode];
strBuf.push(code ? String.fromCharCode(code) : str.charAt(i));
}
return strBuf.join("");
}
function stringToUTF8String(str) {
return decodeURIComponent(escape(str));
}
function utf8StringToString(str) {
return unescape(encodeURIComponent(str));
}
function isArrayEqual(arr1, arr2) {
if (arr1.length !== arr2.length) {
return false;
}
for (let i = 0, ii = arr1.length; i < ii; i++) {
if (arr1[i] !== arr2[i]) {
return false;
}
}
return true;
}
function getModificationDate(date = new Date()) {
if (!(date instanceof Date)) {
date = new Date(date);
}
const buffer = [date.getUTCFullYear().toString(), (date.getUTCMonth() + 1).toString().padStart(2, "0"), date.getUTCDate().toString().padStart(2, "0"), date.getUTCHours().toString().padStart(2, "0"), date.getUTCMinutes().toString().padStart(2, "0"), date.getUTCSeconds().toString().padStart(2, "0")];
return buffer.join("");
}
let NormalizeRegex = null;
let NormalizationMap = null;
function normalizeUnicode(str) {
if (!NormalizeRegex) {
NormalizeRegex = /([\u00a0\u00b5\u037e\u0eb3\u2000-\u200a\u202f\u2126\ufb00-\ufb04\ufb06\ufb20-\ufb36\ufb38-\ufb3c\ufb3e\ufb40-\ufb41\ufb43-\ufb44\ufb46-\ufba1\ufba4-\ufba9\ufbae-\ufbb1\ufbd3-\ufbdc\ufbde-\ufbe7\ufbea-\ufbf8\ufbfc-\ufbfd\ufc00-\ufc5d\ufc64-\ufcf1\ufcf5-\ufd3d\ufd88\ufdf4\ufdfa-\ufdfb\ufe71\ufe77\ufe79\ufe7b\ufe7d]+)|(\ufb05+)/gu;
NormalizationMap = new Map([["ſt", "ſt"]]);
}
return str.replaceAll(NormalizeRegex, (_, p1, p2) => p1 ? p1.normalize("NFKC") : NormalizationMap.get(p2));
}
function getUuid() {
if (typeof crypto.randomUUID === "function") {
return crypto.randomUUID();
}
const buf = new Uint8Array(32);
crypto.getRandomValues(buf);
return bytesToString(buf);
}
const AnnotationPrefix = "pdfjs_internal_id_";
function _isValidExplicitDest(validRef, validName, dest) {
if (!Array.isArray(dest) || dest.length < 2) {
return false;
}
const [page, zoom, ...args] = dest;
if (!validRef(page) && !Number.isInteger(page)) {
return false;
}
if (!validName(zoom)) {
return false;
}
const argsLen = args.length;
let allowNull = true;
switch (zoom.name) {
case "XYZ":
if (argsLen < 2 || argsLen > 3) {
return false;
}
break;
case "Fit":
case "FitB":
return argsLen === 0;
case "FitH":
case "FitBH":
case "FitV":
case "FitBV":
if (argsLen > 1) {
return false;
}
break;
case "FitR":
if (argsLen !== 4) {
return false;
}
allowNull = false;
break;
default:
return false;
}
for (const arg of args) {
if (typeof arg === "number" || allowNull && arg === null) {
continue;
}
return false;
}
return true;
}
function MathClamp(v, min, max) {
return Math.min(Math.max(v, min), max);
}
function toHexUtil(arr) {
if (Uint8Array.prototype.toHex) {
return arr.toHex();
}
return Array.from(arr, num => util_hexNumbers[num]).join("");
}
function toBase64Util(arr) {
if (Uint8Array.prototype.toBase64) {
return arr.toBase64();
}
return btoa(bytesToString(arr));
}
function fromBase64Util(str) {
if (Uint8Array.fromBase64) {
return Uint8Array.fromBase64(str);
}
return stringToBytes(atob(str));
}
if (typeof Promise.try !== "function") {
Promise.try = function (fn, ...args) {
return new Promise(resolve => {
resolve(fn(...args));
});
};
}
if (typeof Math.sumPrecise !== "function") {
Math.sumPrecise = function (numbers) {
return numbers.reduce((a, b) => a + b, 0);
};
}
;// ./src/core/primitives.js
const CIRCULAR_REF = Symbol("CIRCULAR_REF");
const EOF = Symbol("EOF");
let CmdCache = Object.create(null);
let NameCache = Object.create(null);
let RefCache = Object.create(null);
function clearPrimitiveCaches() {
CmdCache = Object.create(null);
NameCache = Object.create(null);
RefCache = Object.create(null);
}
class Name {
constructor(name) {
this.name = name;
}
static get(name) {
return NameCache[name] ||= new Name(name);
}
}
class Cmd {
constructor(cmd) {
this.cmd = cmd;
}
static get(cmd) {
return CmdCache[cmd] ||= new Cmd(cmd);
}
}
const nonSerializable = function nonSerializableClosure() {
return nonSerializable;
};
class primitives_Dict {
constructor(xref = null) {
this._map = new Map();
this.xref = xref;
this.objId = null;
this.suppressEncryption = false;
this.__nonSerializable__ = nonSerializable;
}
assignXref(newXref) {
this.xref = newXref;
}
get size() {
return this._map.size;
}
get(key1, key2, key3) {
let value = this._map.get(key1);
if (value === undefined && key2 !== undefined) {
value = this._map.get(key2);
if (value === undefined && key3 !== undefined) {
value = this._map.get(key3);
}
}
if (value instanceof primitives_Ref && this.xref) {
return this.xref.fetch(value, this.suppressEncryption);
}
return value;
}
async getAsync(key1, key2, key3) {
let value = this._map.get(key1);
if (value === undefined && key2 !== undefined) {
value = this._map.get(key2);
if (value === undefined && key3 !== undefined) {
value = this._map.get(key3);
}
}
if (value instanceof primitives_Ref && this.xref) {
return this.xref.fetchAsync(value, this.suppressEncryption);
}
return value;
}
getArray(key1, key2, key3) {
let value = this._map.get(key1);
if (value === undefined && key2 !== undefined) {
value = this._map.get(key2);
if (value === undefined && key3 !== undefined) {
value = this._map.get(key3);
}
}
if (value instanceof primitives_Ref && this.xref) {
value = this.xref.fetch(value, this.suppressEncryption);
}
if (Array.isArray(value)) {
value = value.slice();
for (let i = 0, ii = value.length; i < ii; i++) {
if (value[i] instanceof primitives_Ref && this.xref) {
value[i] = this.xref.fetch(value[i], this.suppressEncryption);
}
}
}
return value;
}
getRaw(key) {
return this._map.get(key);
}
getKeys() {
return [...this._map.keys()];
}
getRawValues() {
return [...this._map.values()];
}
set(key, value) {
this._map.set(key, value);
}
setIfNotExists(key, value) {
if (!this.has(key)) {
this.set(key, value);
}
}
setIfNumber(key, value) {
if (typeof value === "number") {
this.set(key, value);
}
}
setIfArray(key, value) {
if (Array.isArray(value) || ArrayBuffer.isView(value)) {
this.set(key, value);
}
}
setIfDefined(key, value) {
if (value !== undefined && value !== null) {
this.set(key, value);
}
}
setIfName(key, value) {
if (typeof value === "string") {
this.set(key, Name.get(value));
} else if (value instanceof Name) {
this.set(key, value);
}
}
has(key) {
return this._map.has(key);
}
*[Symbol.iterator]() {
for (const [key, value] of this._map) {
yield [key, value instanceof primitives_Ref && this.xref ? this.xref.fetch(value, this.suppressEncryption) : value];
}
}
static get empty() {
const emptyDict = new primitives_Dict(null);
emptyDict.set = (key, value) => {
unreachable("Should not call `set` on the empty dictionary.");
};
return shadow(this, "empty", emptyDict);
}
static merge({
xref,
dictArray,
mergeSubDicts = false
}) {
const mergedDict = new primitives_Dict(xref),
properties = new Map();
for (const dict of dictArray) {
if (!(dict instanceof primitives_Dict)) {
continue;
}
for (const [key, value] of dict._map) {
let property = properties.get(key);
if (property === undefined) {
property = [];
properties.set(key, property);
} else if (!mergeSubDicts || !(value instanceof primitives_Dict)) {
continue;
}
property.push(value);
}
}
for (const [name, values] of properties) {
if (values.length === 1 || !(values[0] instanceof primitives_Dict)) {
mergedDict._map.set(name, values[0]);
continue;
}
const subDict = new primitives_Dict(xref);
for (const dict of values) {
for (const [key, value] of dict._map) {
if (!subDict._map.has(key)) {
subDict._map.set(key, value);
}
}
}
if (subDict.size > 0) {
mergedDict._map.set(name, subDict);
}
}
properties.clear();
return mergedDict.size > 0 ? mergedDict : primitives_Dict.empty;
}
clone() {
const dict = new primitives_Dict(this.xref);
for (const key of this.getKeys()) {
dict.set(key, this.getRaw(key));
}
return dict;
}
delete(key) {
delete this._map[key];
}
}
class primitives_Ref {
constructor(num, gen) {
this.num = num;
this.gen = gen;
}
toString() {
if (this.gen === 0) {
return `${this.num}R`;
}
return `${this.num}R${this.gen}`;
}
static fromString(str) {
const ref = RefCache[str];
if (ref) {
return ref;
}
const m = /^(\d+)R(\d*)$/.exec(str);
if (!m || m[1] === "0") {
return null;
}
return RefCache[str] = new primitives_Ref(parseInt(m[1]), !m[2] ? 0 : parseInt(m[2]));
}
static get(num, gen) {
const key = gen === 0 ? `${num}R` : `${num}R${gen}`;
return RefCache[key] ||= new primitives_Ref(num, gen);
}
}
class primitives_RefSet {
constructor(parent = null) {
this._set = new Set(parent?._set);
}
has(ref) {
return this._set.has(ref.toString());
}
put(ref) {
this._set.add(ref.toString());
}
remove(ref) {
this._set.delete(ref.toString());
}
[Symbol.iterator]() {
return this._set.values();
}
clear() {
this._set.clear();
}
}
class RefSetCache {
constructor() {
this._map = new Map();
}
get size() {
return this._map.size;
}
get(ref) {
return this._map.get(ref.toString());
}
has(ref) {
return this._map.has(ref.toString());
}
put(ref, obj) {
this._map.set(ref.toString(), obj);
}
putAlias(ref, aliasRef) {
this._map.set(ref.toString(), this.get(aliasRef));
}
[Symbol.iterator]() {
return this._map.values();
}
clear() {
this._map.clear();
}
*values() {
yield* this._map.values();
}
*items() {
for (const [ref, value] of this._map) {
yield [primitives_Ref.fromString(ref), value];
}
}
}
function primitives_isName(v, name) {
return v instanceof Name && (name === undefined || v.name === name);
}
function isCmd(v, cmd) {
return v instanceof Cmd && (cmd === undefined || v.cmd === cmd);
}
function isDict(v, type) {
return v instanceof primitives_Dict && (type === undefined || primitives_isName(v.get("Type"), type));
}
function isRefsEqual(v1, v2) {
return v1.num === v2.num && v1.gen === v2.gen;
}
;// ./src/core/base_stream.js
class base_stream_BaseStream {
get length() {
unreachable("Abstract getter `length` accessed");
}
get isEmpty() {
unreachable("Abstract getter `isEmpty` accessed");
}
get isDataLoaded() {
return shadow(this, "isDataLoaded", true);
}
getByte() {
unreachable("Abstract method `getByte` called");
}
getBytes(length) {
unreachable("Abstract method `getBytes` called");
}
async getImageData(length, decoderOptions) {
return this.getBytes(length, decoderOptions);
}
async asyncGetBytes() {
unreachable("Abstract method `asyncGetBytes` called");
}
get isAsync() {
return false;
}
get isAsyncDecoder() {
return false;
}
get canAsyncDecodeImageFromBuffer() {
return false;
}
async getTransferableImage() {
return null;
}
peekByte() {
const peekedByte = this.getByte();
if (peekedByte !== -1) {
this.pos--;
}
return peekedByte;
}
peekBytes(length) {
const bytes = this.getBytes(length);
this.pos -= bytes.length;
return bytes;
}
getUint16() {
const b0 = this.getByte();
const b1 = this.getByte();
if (b0 === -1 || b1 === -1) {
return -1;
}
return (b0 << 8) + b1;
}
getInt32() {
const b0 = this.getByte();
const b1 = this.getByte();
const b2 = this.getByte();
const b3 = this.getByte();
return (b0 << 24) + (b1 << 16) + (b2 << 8) + b3;
}
getByteRange(begin, end) {
unreachable("Abstract method `getByteRange` called");
}
getString(length) {
return bytesToString(this.getBytes(length));
}
skip(n) {
this.pos += n || 1;
}
reset() {
unreachable("Abstract method `reset` called");
}
moveStart() {
unreachable("Abstract method `moveStart` called");
}
makeSubStream(start, length, dict = null) {
unreachable("Abstract method `makeSubStream` called");
}
getBaseStreams() {
return null;
}
}
;// ./src/core/core_utils.js
const PDF_VERSION_REGEXP = /^[1-9]\.\d$/;
const MAX_INT_32 = 2 ** 31 - 1;
const MIN_INT_32 = -(2 ** 31);
const IDENTITY_MATRIX = (/* unused pure expression or super */ null && ([1, 0, 0, 1, 0, 0]));
const RESOURCES_KEYS_OPERATOR_LIST = (/* unused pure expression or super */ null && (["ColorSpace", "ExtGState", "Font", "Pattern", "Properties", "Shading", "XObject"]));
const RESOURCES_KEYS_TEXT_CONTENT = (/* unused pure expression or super */ null && (["ExtGState", "Font", "Properties", "XObject"]));
function getLookupTableFactory(initializer) {
let lookup;
return function () {
if (initializer) {
lookup = Object.create(null);
initializer(lookup);
initializer = null;
}
return lookup;
};
}
class MissingDataException extends BaseException {
constructor(begin, end) {
super(`Missing data [${begin}, ${end})`, "MissingDataException");
this.begin = begin;
this.end = end;
}
}
class ParserEOFException extends BaseException {
constructor(msg) {
super(msg, "ParserEOFException");
}
}
class XRefEntryException extends BaseException {
constructor(msg) {
super(msg, "XRefEntryException");
}
}
class XRefParseException extends BaseException {
constructor(msg) {
super(msg, "XRefParseException");
}
}
function arrayBuffersToBytes(arr) {
const length = arr.length;
if (length === 0) {
return new Uint8Array(0);
}
if (length === 1) {
return new Uint8Array(arr[0]);
}
let dataLength = 0;
for (let i = 0; i < length; i++) {
dataLength += arr[i].byteLength;
}
const data = new Uint8Array(dataLength);
let pos = 0;
for (let i = 0; i < length; i++) {
const item = new Uint8Array(arr[i]);
data.set(item, pos);
pos += item.byteLength;
}
return data;
}
async function fetchBinaryData(url) {
const response = await fetch(url);
if (!response.ok) {
throw new Error(`Failed to fetch file "${url}" with "${response.statusText}".`);
}
return new Uint8Array(await response.arrayBuffer());
}
function getInheritableProperty({
dict,
key,
getArray = false,
stopWhenFound = true
}) {
let values;
const visited = new RefSet();
while (dict instanceof Dict && !(dict.objId && visited.has(dict.objId))) {
if (dict.objId) {
visited.put(dict.objId);
}
const value = getArray ? dict.getArray(key) : dict.get(key);
if (value !== undefined) {
if (stopWhenFound) {
return value;
}
(values ||= []).push(value);
}
dict = dict.get("Parent");
}
return values;
}
function getParentToUpdate(dict, ref, xref) {
const visited = new RefSet();
const firstDict = dict;
const result = {
dict: null,
ref: null
};
while (dict instanceof Dict && !visited.has(ref)) {
visited.put(ref);
if (dict.has("T")) {
break;
}
ref = dict.getRaw("Parent");
if (!(ref instanceof Ref)) {
return result;
}
dict = xref.fetch(ref);
}
if (dict instanceof Dict && dict !== firstDict) {
result.dict = dict;
result.ref = ref;
}
return result;
}
const ROMAN_NUMBER_MAP = (/* unused pure expression or super */ null && (["", "C", "CC", "CCC", "CD", "D", "DC", "DCC", "DCCC", "CM", "", "X", "XX", "XXX", "XL", "L", "LX", "LXX", "LXXX", "XC", "", "I", "II", "III", "IV", "V", "VI", "VII", "VIII", "IX"]));
function toRomanNumerals(number, lowerCase = false) {
assert(Number.isInteger(number) && number > 0, "The number should be a positive integer.");
const roman = "M".repeat(number / 1000 | 0) + ROMAN_NUMBER_MAP[number % 1000 / 100 | 0] + ROMAN_NUMBER_MAP[10 + (number % 100 / 10 | 0)] + ROMAN_NUMBER_MAP[20 + number % 10];
return lowerCase ? roman.toLowerCase() : roman;
}
function log2(x) {
return x > 0 ? Math.ceil(Math.log2(x)) : 0;
}
function readInt8(data, offset) {
return data[offset] << 24 >> 24;
}
function readInt16(data, offset) {
return (data[offset] << 24 | data[offset + 1] << 16) >> 16;
}
function readUint16(data, offset) {
return data[offset] << 8 | data[offset + 1];
}
function readUint32(data, offset) {
return (data[offset] << 24 | data[offset + 1] << 16 | data[offset + 2] << 8 | data[offset + 3]) >>> 0;
}
function isWhiteSpace(ch) {
return ch === 0x20 || ch === 0x09 || ch === 0x0d || ch === 0x0a;
}
function isBooleanArray(arr, len) {
return Array.isArray(arr) && (len === null || arr.length === len) && arr.every(x => typeof x === "boolean");
}
function isNumberArray(arr, len) {
if (Array.isArray(arr)) {
return (len === null || arr.length === len) && arr.every(x => typeof x === "number");
}
return ArrayBuffer.isView(arr) && !(arr instanceof BigInt64Array || arr instanceof BigUint64Array) && (len === null || arr.length === len);
}
function lookupMatrix(arr, fallback) {
return isNumberArray(arr, 6) ? arr : fallback;
}
function lookupRect(arr, fallback) {
return isNumberArray(arr, 4) ? arr : fallback;
}
function lookupNormalRect(arr, fallback) {
return isNumberArray(arr, 4) ? Util.normalizeRect(arr) : fallback;
}
function parseXFAPath(path) {
const positionPattern = /(.+)\[(\d+)\]$/;
return path.split(".").map(component => {
const m = component.match(positionPattern);
if (m) {
return {
name: m[1],
pos: parseInt(m[2], 10)
};
}
return {
name: component,
pos: 0
};
});
}
function escapePDFName(str) {
const buffer = [];
let start = 0;
for (let i = 0, ii = str.length; i < ii; i++) {
const char = str.charCodeAt(i);
if (char < 0x21 || char > 0x7e || char === 0x23 || char === 0x28 || char === 0x29 || char === 0x3c || char === 0x3e || char === 0x5b || char === 0x5d || char === 0x7b || char === 0x7d || char === 0x2f || char === 0x25) {
if (start < i) {
buffer.push(str.substring(start, i));
}
buffer.push(`#${char.toString(16)}`);
start = i + 1;
}
}
if (buffer.length === 0) {
return str;
}
if (start < str.length) {
buffer.push(str.substring(start, str.length));
}
return buffer.join("");
}
function escapeString(str) {
return str.replaceAll(/([()\\\n\r])/g, match => {
if (match === "\n") {
return "\\n";
} else if (match === "\r") {
return "\\r";
}
return `\\${match}`;
});
}
function _collectJS(entry, xref, list, parents) {
if (!entry) {
return;
}
let parent = null;
if (entry instanceof Ref) {
if (parents.has(entry)) {
return;
}
parent = entry;
parents.put(parent);
entry = xref.fetch(entry);
}
if (Array.isArray(entry)) {
for (const element of entry) {
_collectJS(element, xref, list, parents);
}
} else if (entry instanceof Dict) {
if (isName(entry.get("S"), "JavaScript")) {
const js = entry.get("JS");
let code;
if (js instanceof BaseStream) {
code = js.getString();
} else if (typeof js === "string") {
code = js;
}
code &&= stringToPDFString(code, true).replaceAll("\x00", "");
if (code) {
list.push(code.trim());
}
}
_collectJS(entry.getRaw("Next"), xref, list, parents);
}
if (parent) {
parents.remove(parent);
}
}
function collectActions(xref, dict, eventType) {
const actions = Object.create(null);
const additionalActionsDicts = getInheritableProperty({
dict,
key: "AA",
stopWhenFound: false
});
if (additionalActionsDicts) {
for (let i = additionalActionsDicts.length - 1; i >= 0; i--) {
const additionalActions = additionalActionsDicts[i];
if (!(additionalActions instanceof Dict)) {
continue;
}
for (const key of additionalActions.getKeys()) {
const action = eventType[key];
if (!action) {
continue;
}
const actionDict = additionalActions.getRaw(key);
const parents = new RefSet();
const list = [];
_collectJS(actionDict, xref, list, parents);
if (list.length > 0) {
actions[action] = list;
}
}
}
}
if (dict.has("A")) {
const actionDict = dict.get("A");
const parents = new RefSet();
const list = [];
_collectJS(actionDict, xref, list, parents);
if (list.length > 0) {
actions.Action = list;
}
}
return objectSize(actions) > 0 ? actions : null;
}
const XMLEntities = {
0x3c: "&lt;",
0x3e: "&gt;",
0x26: "&amp;",
0x22: "&quot;",
0x27: "&apos;"
};
function* codePointIter(str) {
for (let i = 0, ii = str.length; i < ii; i++) {
const char = str.codePointAt(i);
if (char > 0xd7ff && (char < 0xe000 || char > 0xfffd)) {
i++;
}
yield char;
}
}
function encodeToXmlString(str) {
const buffer = [];
let start = 0;
for (let i = 0, ii = str.length; i < ii; i++) {
const char = str.codePointAt(i);
if (0x20 <= char && char <= 0x7e) {
const entity = XMLEntities[char];
if (entity) {
if (start < i) {
buffer.push(str.substring(start, i));
}
buffer.push(entity);
start = i + 1;
}
} else {
if (start < i) {
buffer.push(str.substring(start, i));
}
buffer.push(`&#x${char.toString(16).toUpperCase()};`);
if (char > 0xd7ff && (char < 0xe000 || char > 0xfffd)) {
i++;
}
start = i + 1;
}
}
if (buffer.length === 0) {
return str;
}
if (start < str.length) {
buffer.push(str.substring(start, str.length));
}
return buffer.join("");
}
function validateFontName(fontFamily, mustWarn = false) {
const m = /^("|').*("|')$/.exec(fontFamily);
if (m && m[1] === m[2]) {
const re = new RegExp(`[^\\\\]${m[1]}`);
if (re.test(fontFamily.slice(1, -1))) {
if (mustWarn) {
warn(`FontFamily contains unescaped ${m[1]}: ${fontFamily}.`);
}
return false;
}
} else {
for (const ident of fontFamily.split(/[ \t]+/)) {
if (/^(\d|(-(\d|-)))/.test(ident) || !/^[\w-\\]+$/.test(ident)) {
if (mustWarn) {
warn(`FontFamily contains invalid <custom-ident>: ${fontFamily}.`);
}
return false;
}
}
}
return true;
}
function validateCSSFont(cssFontInfo) {
const DEFAULT_CSS_FONT_OBLIQUE = "14";
const DEFAULT_CSS_FONT_WEIGHT = "400";
const CSS_FONT_WEIGHT_VALUES = new Set(["100", "200", "300", "400", "500", "600", "700", "800", "900", "1000", "normal", "bold", "bolder", "lighter"]);
const {
fontFamily,
fontWeight,
italicAngle
} = cssFontInfo;
if (!validateFontName(fontFamily, true)) {
return false;
}
const weight = fontWeight ? fontWeight.toString() : "";
cssFontInfo.fontWeight = CSS_FONT_WEIGHT_VALUES.has(weight) ? weight : DEFAULT_CSS_FONT_WEIGHT;
const angle = parseFloat(italicAngle);
cssFontInfo.italicAngle = isNaN(angle) || angle < -90 || angle > 90 ? DEFAULT_CSS_FONT_OBLIQUE : italicAngle.toString();
return true;
}
function recoverJsURL(str) {
const URL_OPEN_METHODS = ["app.launchURL", "window.open", "xfa.host.gotoURL"];
const regex = new RegExp("^\\s*(" + URL_OPEN_METHODS.join("|").replaceAll(".", "\\.") + ")\\((?:'|\")([^'\"]*)(?:'|\")(?:,\\s*(\\w+)\\)|\\))", "i");
const jsUrl = regex.exec(str);
if (jsUrl?.[2]) {
return {
url: jsUrl[2],
newWindow: jsUrl[1] === "app.launchURL" && jsUrl[3] === "true"
};
}
return null;
}
function numberToString(value) {
if (Number.isInteger(value)) {
return value.toString();
}
const roundedValue = Math.round(value * 100);
if (roundedValue % 100 === 0) {
return (roundedValue / 100).toString();
}
if (roundedValue % 10 === 0) {
return value.toFixed(1);
}
return value.toFixed(2);
}
function getNewAnnotationsMap(annotationStorage) {
if (!annotationStorage) {
return null;
}
const newAnnotationsByPage = new Map();
for (const [key, value] of annotationStorage) {
if (!key.startsWith(AnnotationEditorPrefix)) {
continue;
}
let annotations = newAnnotationsByPage.get(value.pageIndex);
if (!annotations) {
annotations = [];
newAnnotationsByPage.set(value.pageIndex, annotations);
}
annotations.push(value);
}
return newAnnotationsByPage.size > 0 ? newAnnotationsByPage : null;
}
function stringToAsciiOrUTF16BE(str) {
if (str === null || str === undefined) {
return str;
}
return isAscii(str) ? str : stringToUTF16String(str, true);
}
function isAscii(str) {
if (typeof str !== "string") {
return false;
}
return !str || /^[\x00-\x7F]*$/.test(str);
}
function stringToUTF16HexString(str) {
const buf = [];
for (let i = 0, ii = str.length; i < ii; i++) {
const char = str.charCodeAt(i);
buf.push(hexNumbers[char >> 8 & 0xff], hexNumbers[char & 0xff]);
}
return buf.join("");
}
function stringToUTF16String(str, bigEndian = false) {
const buf = [];
if (bigEndian) {
buf.push("\xFE\xFF");
}
for (let i = 0, ii = str.length; i < ii; i++) {
const char = str.charCodeAt(i);
buf.push(String.fromCharCode(char >> 8 & 0xff), String.fromCharCode(char & 0xff));
}
return buf.join("");
}
function getRotationMatrix(rotation, width, height) {
switch (rotation) {
case 90:
return [0, 1, -1, 0, width, 0];
case 180:
return [-1, 0, 0, -1, width, height];
case 270:
return [0, -1, 1, 0, 0, height];
default:
throw new Error("Invalid rotation");
}
}
function getSizeInBytes(x) {
return Math.ceil(Math.ceil(Math.log2(1 + x)) / 8);
}
;// ./src/core/arithmetic_decoder.js
const QeTable = [{
qe: 0x5601,
nmps: 1,
nlps: 1,
switchFlag: 1
}, {
qe: 0x3401,
nmps: 2,
nlps: 6,
switchFlag: 0
}, {
qe: 0x1801,
nmps: 3,
nlps: 9,
switchFlag: 0
}, {
qe: 0x0ac1,
nmps: 4,
nlps: 12,
switchFlag: 0
}, {
qe: 0x0521,
nmps: 5,
nlps: 29,
switchFlag: 0
}, {
qe: 0x0221,
nmps: 38,
nlps: 33,
switchFlag: 0
}, {
qe: 0x5601,
nmps: 7,
nlps: 6,
switchFlag: 1
}, {
qe: 0x5401,
nmps: 8,
nlps: 14,
switchFlag: 0
}, {
qe: 0x4801,
nmps: 9,
nlps: 14,
switchFlag: 0
}, {
qe: 0x3801,
nmps: 10,
nlps: 14,
switchFlag: 0
}, {
qe: 0x3001,
nmps: 11,
nlps: 17,
switchFlag: 0
}, {
qe: 0x2401,
nmps: 12,
nlps: 18,
switchFlag: 0
}, {
qe: 0x1c01,
nmps: 13,
nlps: 20,
switchFlag: 0
}, {
qe: 0x1601,
nmps: 29,
nlps: 21,
switchFlag: 0
}, {
qe: 0x5601,
nmps: 15,
nlps: 14,
switchFlag: 1
}, {
qe: 0x5401,
nmps: 16,
nlps: 14,
switchFlag: 0
}, {
qe: 0x5101,
nmps: 17,
nlps: 15,
switchFlag: 0
}, {
qe: 0x4801,
nmps: 18,
nlps: 16,
switchFlag: 0
}, {
qe: 0x3801,
nmps: 19,
nlps: 17,
switchFlag: 0
}, {
qe: 0x3401,
nmps: 20,
nlps: 18,
switchFlag: 0
}, {
qe: 0x3001,
nmps: 21,
nlps: 19,
switchFlag: 0
}, {
qe: 0x2801,
nmps: 22,
nlps: 19,
switchFlag: 0
}, {
qe: 0x2401,
nmps: 23,
nlps: 20,
switchFlag: 0
}, {
qe: 0x2201,
nmps: 24,
nlps: 21,
switchFlag: 0
}, {
qe: 0x1c01,
nmps: 25,
nlps: 22,
switchFlag: 0
}, {
qe: 0x1801,
nmps: 26,
nlps: 23,
switchFlag: 0
}, {
qe: 0x1601,
nmps: 27,
nlps: 24,
switchFlag: 0
}, {
qe: 0x1401,
nmps: 28,
nlps: 25,
switchFlag: 0
}, {
qe: 0x1201,
nmps: 29,
nlps: 26,
switchFlag: 0
}, {
qe: 0x1101,
nmps: 30,
nlps: 27,
switchFlag: 0
}, {
qe: 0x0ac1,
nmps: 31,
nlps: 28,
switchFlag: 0
}, {
qe: 0x09c1,
nmps: 32,
nlps: 29,
switchFlag: 0
}, {
qe: 0x08a1,
nmps: 33,
nlps: 30,
switchFlag: 0
}, {
qe: 0x0521,
nmps: 34,
nlps: 31,
switchFlag: 0
}, {
qe: 0x0441,
nmps: 35,
nlps: 32,
switchFlag: 0
}, {
qe: 0x02a1,
nmps: 36,
nlps: 33,
switchFlag: 0
}, {
qe: 0x0221,
nmps: 37,
nlps: 34,
switchFlag: 0
}, {
qe: 0x0141,
nmps: 38,
nlps: 35,
switchFlag: 0
}, {
qe: 0x0111,
nmps: 39,
nlps: 36,
switchFlag: 0
}, {
qe: 0x0085,
nmps: 40,
nlps: 37,
switchFlag: 0
}, {
qe: 0x0049,
nmps: 41,
nlps: 38,
switchFlag: 0
}, {
qe: 0x0025,
nmps: 42,
nlps: 39,
switchFlag: 0
}, {
qe: 0x0015,
nmps: 43,
nlps: 40,
switchFlag: 0
}, {
qe: 0x0009,
nmps: 44,
nlps: 41,
switchFlag: 0
}, {
qe: 0x0005,
nmps: 45,
nlps: 42,
switchFlag: 0
}, {
qe: 0x0001,
nmps: 45,
nlps: 43,
switchFlag: 0
}, {
qe: 0x5601,
nmps: 46,
nlps: 46,
switchFlag: 0
}];
class ArithmeticDecoder {
constructor(data, start, end) {
this.data = data;
this.bp = start;
this.dataEnd = end;
this.chigh = data[start];
this.clow = 0;
this.byteIn();
this.chigh = this.chigh << 7 & 0xffff | this.clow >> 9 & 0x7f;
this.clow = this.clow << 7 & 0xffff;
this.ct -= 7;
this.a = 0x8000;
}
byteIn() {
const data = this.data;
let bp = this.bp;
if (data[bp] === 0xff) {
if (data[bp + 1] > 0x8f) {
this.clow += 0xff00;
this.ct = 8;
} else {
bp++;
this.clow += data[bp] << 9;
this.ct = 7;
this.bp = bp;
}
} else {
bp++;
this.clow += bp < this.dataEnd ? data[bp] << 8 : 0xff00;
this.ct = 8;
this.bp = bp;
}
if (this.clow > 0xffff) {
this.chigh += this.clow >> 16;
this.clow &= 0xffff;
}
}
readBit(contexts, pos) {
let cx_index = contexts[pos] >> 1,
cx_mps = contexts[pos] & 1;
const qeTableIcx = QeTable[cx_index];
const qeIcx = qeTableIcx.qe;
let d;
let a = this.a - qeIcx;
if (this.chigh < qeIcx) {
if (a < qeIcx) {
a = qeIcx;
d = cx_mps;
cx_index = qeTableIcx.nmps;
} else {
a = qeIcx;
d = 1 ^ cx_mps;
if (qeTableIcx.switchFlag === 1) {
cx_mps = d;
}
cx_index = qeTableIcx.nlps;
}
} else {
this.chigh -= qeIcx;
if ((a & 0x8000) !== 0) {
this.a = a;
return cx_mps;
}
if (a < qeIcx) {
d = 1 ^ cx_mps;
if (qeTableIcx.switchFlag === 1) {
cx_mps = d;
}
cx_index = qeTableIcx.nlps;
} else {
d = cx_mps;
cx_index = qeTableIcx.nmps;
}
}
do {
if (this.ct === 0) {
this.byteIn();
}
a <<= 1;
this.chigh = this.chigh << 1 & 0xffff | this.clow >> 15 & 1;
this.clow = this.clow << 1 & 0xffff;
this.ct--;
} while ((a & 0x8000) === 0);
this.a = a;
contexts[pos] = cx_index << 1 | cx_mps;
return d;
}
}
;// ./src/core/ccitt.js
const ccittEOL = -2;
const ccittEOF = -1;
const twoDimPass = 0;
const twoDimHoriz = 1;
const twoDimVert0 = 2;
const twoDimVertR1 = 3;
const twoDimVertL1 = 4;
const twoDimVertR2 = 5;
const twoDimVertL2 = 6;
const twoDimVertR3 = 7;
const twoDimVertL3 = 8;
const twoDimTable = [[-1, -1], [-1, -1], [7, twoDimVertL3], [7, twoDimVertR3], [6, twoDimVertL2], [6, twoDimVertL2], [6, twoDimVertR2], [6, twoDimVertR2], [4, twoDimPass], [4, twoDimPass], [4, twoDimPass], [4, twoDimPass], [4, twoDimPass], [4, twoDimPass], [4, twoDimPass], [4, twoDimPass], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimHoriz], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertL1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [3, twoDimVertR1], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0], [1, twoDimVert0]];
const whiteTable1 = [[-1, -1], [12, ccittEOL], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [11, 1792], [11, 1792], [12, 1984], [12, 2048], [12, 2112], [12, 2176], [12, 2240], [12, 2304], [11, 1856], [11, 1856], [11, 1920], [11, 1920], [12, 2368], [12, 2432], [12, 2496], [12, 2560]];
const whiteTable2 = [[-1, -1], [-1, -1], [-1, -1], [-1, -1], [8, 29], [8, 29], [8, 30], [8, 30], [8, 45], [8, 45], [8, 46], [8, 46], [7, 22], [7, 22], [7, 22], [7, 22], [7, 23], [7, 23], [7, 23], [7, 23], [8, 47], [8, 47], [8, 48], [8, 48], [6, 13], [6, 13], [6, 13], [6, 13], [6, 13], [6, 13], [6, 13], [6, 13], [7, 20], [7, 20], [7, 20], [7, 20], [8, 33], [8, 33], [8, 34], [8, 34], [8, 35], [8, 35], [8, 36], [8, 36], [8, 37], [8, 37], [8, 38], [8, 38], [7, 19], [7, 19], [7, 19], [7, 19], [8, 31], [8, 31], [8, 32], [8, 32], [6, 1], [6, 1], [6, 1], [6, 1], [6, 1], [6, 1], [6, 1], [6, 1], [6, 12], [6, 12], [6, 12], [6, 12], [6, 12], [6, 12], [6, 12], [6, 12], [8, 53], [8, 53], [8, 54], [8, 54], [7, 26], [7, 26], [7, 26], [7, 26], [8, 39], [8, 39], [8, 40], [8, 40], [8, 41], [8, 41], [8, 42], [8, 42], [8, 43], [8, 43], [8, 44], [8, 44], [7, 21], [7, 21], [7, 21], [7, 21], [7, 28], [7, 28], [7, 28], [7, 28], [8, 61], [8, 61], [8, 62], [8, 62], [8, 63], [8, 63], [8, 0], [8, 0], [8, 320], [8, 320], [8, 384], [8, 384], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 10], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [5, 11], [7, 27], [7, 27], [7, 27], [7, 27], [8, 59], [8, 59], [8, 60], [8, 60], [9, 1472], [9, 1536], [9, 1600], [9, 1728], [7, 18], [7, 18], [7, 18], [7, 18], [7, 24], [7, 24], [7, 24], [7, 24], [8, 49], [8, 49], [8, 50], [8, 50], [8, 51], [8, 51], [8, 52], [8, 52], [7, 25], [7, 25], [7, 25], [7, 25], [8, 55], [8, 55], [8, 56], [8, 56], [8, 57], [8, 57], [8, 58], [8, 58], [6, 192], [6, 192], [6, 192], [6, 192], [6, 192], [6, 192], [6, 192], [6, 192], [6, 1664], [6, 1664], [6, 1664], [6, 1664], [6, 1664], [6, 1664], [6, 1664], [6, 1664], [8, 448], [8, 448], [8, 512], [8, 512], [9, 704], [9, 768], [8, 640], [8, 640], [8, 576], [8, 576], [9, 832], [9, 896], [9, 960], [9, 1024], [9, 1088], [9, 1152], [9, 1216], [9, 1280], [9, 1344], [9, 1408], [7, 256], [7, 256], [7, 256], [7, 256], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 2], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [4, 3], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 128], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 8], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [5, 9], [6, 16], [6, 16], [6, 16], [6, 16], [6, 16], [6, 16], [6, 16], [6, 16], [6, 17], [6, 17], [6, 17], [6, 17], [6, 17], [6, 17], [6, 17], [6, 17], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 4], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [4, 5], [6, 14], [6, 14], [6, 14], [6, 14], [6, 14], [6, 14], [6, 14], [6, 14], [6, 15], [6, 15], [6, 15], [6, 15], [6, 15], [6, 15], [6, 15], [6, 15], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [5, 64], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 6], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7], [4, 7]];
const blackTable1 = [[-1, -1], [-1, -1], [12, ccittEOL], [12, ccittEOL], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [-1, -1], [11, 1792], [11, 1792], [11, 1792], [11, 1792], [12, 1984], [12, 1984], [12, 2048], [12, 2048], [12, 2112], [12, 2112], [12, 2176], [12, 2176], [12, 2240], [12, 2240], [12, 2304], [12, 2304], [11, 1856], [11, 1856], [11, 1856], [11, 1856], [11, 1920], [11, 1920], [11, 1920], [11, 1920], [12, 2368], [12, 2368], [12, 2432], [12, 2432], [12, 2496], [12, 2496], [12, 2560], [12, 2560], [10, 18], [10, 18], [10, 18], [10, 18], [10, 18], [10, 18], [10, 18], [10, 18], [12, 52], [12, 52], [13, 640], [13, 704], [13, 768], [13, 832], [12, 55], [12, 55], [12, 56], [12, 56], [13, 1280], [13, 1344], [13, 1408], [13, 1472], [12, 59], [12, 59], [12, 60], [12, 60], [13, 1536], [13, 1600], [11, 24], [11, 24], [11, 24], [11, 24], [11, 25], [11, 25], [11, 25], [11, 25], [13, 1664], [13, 1728], [12, 320], [12, 320], [12, 384], [12, 384], [12, 448], [12, 448], [13, 512], [13, 576], [12, 53], [12, 53], [12, 54], [12, 54], [13, 896], [13, 960], [13, 1024], [13, 1088], [13, 1152], [13, 1216], [10, 64], [10, 64], [10, 64], [10, 64], [10, 64], [10, 64], [10, 64], [10, 64]];
const blackTable2 = [[8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [8, 13], [11, 23], [11, 23], [12, 50], [12, 51], [12, 44], [12, 45], [12, 46], [12, 47], [12, 57], [12, 58], [12, 61], [12, 256], [10, 16], [10, 16], [10, 16], [10, 16], [10, 17], [10, 17], [10, 17], [10, 17], [12, 48], [12, 49], [12, 62], [12, 63], [12, 30], [12, 31], [12, 32], [12, 33], [12, 40], [12, 41], [11, 22], [11, 22], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [8, 14], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 10], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [7, 11], [9, 15], [9, 15], [9, 15], [9, 15], [9, 15], [9, 15], [9, 15], [9, 15], [12, 128], [12, 192], [12, 26], [12, 27], [12, 28], [12, 29], [11, 19], [11, 19], [11, 20], [11, 20], [12, 34], [12, 35], [12, 36], [12, 37], [12, 38], [12, 39], [11, 21], [11, 21], [12, 42], [12, 43], [10, 0], [10, 0], [10, 0], [10, 0], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12], [7, 12]];
const blackTable3 = [[-1, -1], [-1, -1], [-1, -1], [-1, -1], [6, 9], [6, 8], [5, 7], [5, 7], [4, 6], [4, 6], [4, 6], [4, 6], [4, 5], [4, 5], [4, 5], [4, 5], [3, 1], [3, 1], [3, 1], [3, 1], [3, 1], [3, 1], [3, 1], [3, 1], [3, 4], [3, 4], [3, 4], [3, 4], [3, 4], [3, 4], [3, 4], [3, 4], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 3], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2], [2, 2]];
class CCITTFaxDecoder {
constructor(source, options = {}) {
if (typeof source?.next !== "function") {
throw new Error('CCITTFaxDecoder - invalid "source" parameter.');
}
this.source = source;
this.eof = false;
this.encoding = options.K || 0;
this.eoline = options.EndOfLine || false;
this.byteAlign = options.EncodedByteAlign || false;
this.columns = options.Columns || 1728;
this.rows = options.Rows || 0;
this.eoblock = options.EndOfBlock ?? true;
this.black = options.BlackIs1 || false;
this.codingLine = new Uint32Array(this.columns + 1);
this.refLine = new Uint32Array(this.columns + 2);
this.codingLine[0] = this.columns;
this.codingPos = 0;
this.row = 0;
this.nextLine2D = this.encoding < 0;
this.inputBits = 0;
this.inputBuf = 0;
this.outputBits = 0;
this.rowsDone = false;
let code1;
while ((code1 = this._lookBits(12)) === 0) {
this._eatBits(1);
}
if (code1 === 1) {
this._eatBits(12);
}
if (this.encoding > 0) {
this.nextLine2D = !this._lookBits(1);
this._eatBits(1);
}
}
readNextChar() {
if (this.eof) {
return -1;
}
const refLine = this.refLine;
const codingLine = this.codingLine;
const columns = this.columns;
let refPos, blackPixels, bits, i;
if (this.outputBits === 0) {
if (this.rowsDone) {
this.eof = true;
}
if (this.eof) {
return -1;
}
this.err = false;
let code1, code2, code3;
if (this.nextLine2D) {
for (i = 0; codingLine[i] < columns; ++i) {
refLine[i] = codingLine[i];
}
refLine[i++] = columns;
refLine[i] = columns;
codingLine[0] = 0;
this.codingPos = 0;
refPos = 0;
blackPixels = 0;
while (codingLine[this.codingPos] < columns) {
code1 = this._getTwoDimCode();
switch (code1) {
case twoDimPass:
this._addPixels(refLine[refPos + 1], blackPixels);
if (refLine[refPos + 1] < columns) {
refPos += 2;
}
break;
case twoDimHoriz:
code1 = code2 = 0;
if (blackPixels) {
do {
code1 += code3 = this._getBlackCode();
} while (code3 >= 64);
do {
code2 += code3 = this._getWhiteCode();
} while (code3 >= 64);
} else {
do {
code1 += code3 = this._getWhiteCode();
} while (code3 >= 64);
do {
code2 += code3 = this._getBlackCode();
} while (code3 >= 64);
}
this._addPixels(codingLine[this.codingPos] + code1, blackPixels);
if (codingLine[this.codingPos] < columns) {
this._addPixels(codingLine[this.codingPos] + code2, blackPixels ^ 1);
}
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
break;
case twoDimVertR3:
this._addPixels(refLine[refPos] + 3, blackPixels);
blackPixels ^= 1;
if (codingLine[this.codingPos] < columns) {
++refPos;
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
}
break;
case twoDimVertR2:
this._addPixels(refLine[refPos] + 2, blackPixels);
blackPixels ^= 1;
if (codingLine[this.codingPos] < columns) {
++refPos;
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
}
break;
case twoDimVertR1:
this._addPixels(refLine[refPos] + 1, blackPixels);
blackPixels ^= 1;
if (codingLine[this.codingPos] < columns) {
++refPos;
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
}
break;
case twoDimVert0:
this._addPixels(refLine[refPos], blackPixels);
blackPixels ^= 1;
if (codingLine[this.codingPos] < columns) {
++refPos;
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
}
break;
case twoDimVertL3:
this._addPixelsNeg(refLine[refPos] - 3, blackPixels);
blackPixels ^= 1;
if (codingLine[this.codingPos] < columns) {
if (refPos > 0) {
--refPos;
} else {
++refPos;
}
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
}
break;
case twoDimVertL2:
this._addPixelsNeg(refLine[refPos] - 2, blackPixels);
blackPixels ^= 1;
if (codingLine[this.codingPos] < columns) {
if (refPos > 0) {
--refPos;
} else {
++refPos;
}
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
}
break;
case twoDimVertL1:
this._addPixelsNeg(refLine[refPos] - 1, blackPixels);
blackPixels ^= 1;
if (codingLine[this.codingPos] < columns) {
if (refPos > 0) {
--refPos;
} else {
++refPos;
}
while (refLine[refPos] <= codingLine[this.codingPos] && refLine[refPos] < columns) {
refPos += 2;
}
}
break;
case ccittEOF:
this._addPixels(columns, 0);
this.eof = true;
break;
default:
info("bad 2d code");
this._addPixels(columns, 0);
this.err = true;
}
}
} else {
codingLine[0] = 0;
this.codingPos = 0;
blackPixels = 0;
while (codingLine[this.codingPos] < columns) {
code1 = 0;
if (blackPixels) {
do {
code1 += code3 = this._getBlackCode();
} while (code3 >= 64);
} else {
do {
code1 += code3 = this._getWhiteCode();
} while (code3 >= 64);
}
this._addPixels(codingLine[this.codingPos] + code1, blackPixels);
blackPixels ^= 1;
}
}
let gotEOL = false;
if (this.byteAlign) {
this.inputBits &= ~7;
}
if (!this.eoblock && this.row === this.rows - 1) {
this.rowsDone = true;
} else {
code1 = this._lookBits(12);
if (this.eoline) {
while (code1 !== ccittEOF && code1 !== 1) {
this._eatBits(1);
code1 = this._lookBits(12);
}
} else {
while (code1 === 0) {
this._eatBits(1);
code1 = this._lookBits(12);
}
}
if (code1 === 1) {
this._eatBits(12);
gotEOL = true;
} else if (code1 === ccittEOF) {
this.eof = true;
}
}
if (!this.eof && this.encoding > 0 && !this.rowsDone) {
this.nextLine2D = !this._lookBits(1);
this._eatBits(1);
}
if (this.eoblock && gotEOL && this.byteAlign) {
code1 = this._lookBits(12);
if (code1 === 1) {
this._eatBits(12);
if (this.encoding > 0) {
this._lookBits(1);
this._eatBits(1);
}
if (this.encoding >= 0) {
for (i = 0; i < 4; ++i) {
code1 = this._lookBits(12);
if (code1 !== 1) {
info("bad rtc code: " + code1);
}
this._eatBits(12);
if (this.encoding > 0) {
this._lookBits(1);
this._eatBits(1);
}
}
}
this.eof = true;
}
} else if (this.err && this.eoline) {
while (true) {
code1 = this._lookBits(13);
if (code1 === ccittEOF) {
this.eof = true;
return -1;
}
if (code1 >> 1 === 1) {
break;
}
this._eatBits(1);
}
this._eatBits(12);
if (this.encoding > 0) {
this._eatBits(1);
this.nextLine2D = !(code1 & 1);
}
}
this.outputBits = codingLine[0] > 0 ? codingLine[this.codingPos = 0] : codingLine[this.codingPos = 1];
this.row++;
}
let c;
if (this.outputBits >= 8) {
c = this.codingPos & 1 ? 0 : 0xff;
this.outputBits -= 8;
if (this.outputBits === 0 && codingLine[this.codingPos] < columns) {
this.codingPos++;
this.outputBits = codingLine[this.codingPos] - codingLine[this.codingPos - 1];
}
} else {
bits = 8;
c = 0;
do {
if (typeof this.outputBits !== "number") {
throw new FormatError('Invalid /CCITTFaxDecode data, "outputBits" must be a number.');
}
if (this.outputBits > bits) {
c <<= bits;
if (!(this.codingPos & 1)) {
c |= 0xff >> 8 - bits;
}
this.outputBits -= bits;
bits = 0;
} else {
c <<= this.outputBits;
if (!(this.codingPos & 1)) {
c |= 0xff >> 8 - this.outputBits;
}
bits -= this.outputBits;
this.outputBits = 0;
if (codingLine[this.codingPos] < columns) {
this.codingPos++;
this.outputBits = codingLine[this.codingPos] - codingLine[this.codingPos - 1];
} else if (bits > 0) {
c <<= bits;
bits = 0;
}
}
} while (bits);
}
if (this.black) {
c ^= 0xff;
}
return c;
}
_addPixels(a1, blackPixels) {
const codingLine = this.codingLine;
let codingPos = this.codingPos;
if (a1 > codingLine[codingPos]) {
if (a1 > this.columns) {
info("row is wrong length");
this.err = true;
a1 = this.columns;
}
if (codingPos & 1 ^ blackPixels) {
++codingPos;
}
codingLine[codingPos] = a1;
}
this.codingPos = codingPos;
}
_addPixelsNeg(a1, blackPixels) {
const codingLine = this.codingLine;
let codingPos = this.codingPos;
if (a1 > codingLine[codingPos]) {
if (a1 > this.columns) {
info("row is wrong length");
this.err = true;
a1 = this.columns;
}
if (codingPos & 1 ^ blackPixels) {
++codingPos;
}
codingLine[codingPos] = a1;
} else if (a1 < codingLine[codingPos]) {
if (a1 < 0) {
info("invalid code");
this.err = true;
a1 = 0;
}
while (codingPos > 0 && a1 < codingLine[codingPos - 1]) {
--codingPos;
}
codingLine[codingPos] = a1;
}
this.codingPos = codingPos;
}
_findTableCode(start, end, table, limit) {
const limitValue = limit || 0;
for (let i = start; i <= end; ++i) {
let code = this._lookBits(i);
if (code === ccittEOF) {
return [true, 1, false];
}
if (i < end) {
code <<= end - i;
}
if (!limitValue || code >= limitValue) {
const p = table[code - limitValue];
if (p[0] === i) {
this._eatBits(i);
return [true, p[1], true];
}
}
}
return [false, 0, false];
}
_getTwoDimCode() {
let code = 0;
let p;
if (this.eoblock) {
code = this._lookBits(7);
p = twoDimTable[code];
if (p?.[0] > 0) {
this._eatBits(p[0]);
return p[1];
}
} else {
const result = this._findTableCode(1, 7, twoDimTable);
if (result[0] && result[2]) {
return result[1];
}
}
info("Bad two dim code");
return ccittEOF;
}
_getWhiteCode() {
let code = 0;
let p;
if (this.eoblock) {
code = this._lookBits(12);
if (code === ccittEOF) {
return 1;
}
p = code >> 5 === 0 ? whiteTable1[code] : whiteTable2[code >> 3];
if (p[0] > 0) {
this._eatBits(p[0]);
return p[1];
}
} else {
let result = this._findTableCode(1, 9, whiteTable2);
if (result[0]) {
return result[1];
}
result = this._findTableCode(11, 12, whiteTable1);
if (result[0]) {
return result[1];
}
}
info("bad white code");
this._eatBits(1);
return 1;
}
_getBlackCode() {
let code, p;
if (this.eoblock) {
code = this._lookBits(13);
if (code === ccittEOF) {
return 1;
}
if (code >> 7 === 0) {
p = blackTable1[code];
} else if (code >> 9 === 0 && code >> 7 !== 0) {
p = blackTable2[(code >> 1) - 64];
} else {
p = blackTable3[code >> 7];
}
if (p[0] > 0) {
this._eatBits(p[0]);
return p[1];
}
} else {
let result = this._findTableCode(2, 6, blackTable3);
if (result[0]) {
return result[1];
}
result = this._findTableCode(7, 12, blackTable2, 64);
if (result[0]) {
return result[1];
}
result = this._findTableCode(10, 13, blackTable1);
if (result[0]) {
return result[1];
}
}
info("bad black code");
this._eatBits(1);
return 1;
}
_lookBits(n) {
let c;
while (this.inputBits < n) {
if ((c = this.source.next()) === -1) {
if (this.inputBits === 0) {
return ccittEOF;
}
return this.inputBuf << n - this.inputBits & 0xffff >> 16 - n;
}
this.inputBuf = this.inputBuf << 8 | c;
this.inputBits += 8;
}
return this.inputBuf >> this.inputBits - n & 0xffff >> 16 - n;
}
_eatBits(n) {
if ((this.inputBits -= n) < 0) {
this.inputBits = 0;
}
}
}
;// ./src/core/jbig2.js
class Jbig2Error extends BaseException {
constructor(msg) {
super(msg, "Jbig2Error");
}
}
class ContextCache {
getContexts(id) {
if (id in this) {
return this[id];
}
return this[id] = new Int8Array(1 << 16);
}
}
class DecodingContext {
constructor(data, start, end) {
this.data = data;
this.start = start;
this.end = end;
}
get decoder() {
const decoder = new ArithmeticDecoder(this.data, this.start, this.end);
return shadow(this, "decoder", decoder);
}
get contextCache() {
const cache = new ContextCache();
return shadow(this, "contextCache", cache);
}
}
function decodeInteger(contextCache, procedure, decoder) {
const contexts = contextCache.getContexts(procedure);
let prev = 1;
function readBits(length) {
let v = 0;
for (let i = 0; i < length; i++) {
const bit = decoder.readBit(contexts, prev);
prev = prev < 256 ? prev << 1 | bit : (prev << 1 | bit) & 511 | 256;
v = v << 1 | bit;
}
return v >>> 0;
}
const sign = readBits(1);
const value = readBits(1) ? readBits(1) ? readBits(1) ? readBits(1) ? readBits(1) ? readBits(32) + 4436 : readBits(12) + 340 : readBits(8) + 84 : readBits(6) + 20 : readBits(4) + 4 : readBits(2);
let signedValue;
if (sign === 0) {
signedValue = value;
} else if (value > 0) {
signedValue = -value;
}
if (signedValue >= MIN_INT_32 && signedValue <= MAX_INT_32) {
return signedValue;
}
return null;
}
function decodeIAID(contextCache, decoder, codeLength) {
const contexts = contextCache.getContexts("IAID");
let prev = 1;
for (let i = 0; i < codeLength; i++) {
const bit = decoder.readBit(contexts, prev);
prev = prev << 1 | bit;
}
if (codeLength < 31) {
return prev & (1 << codeLength) - 1;
}
return prev & 0x7fffffff;
}
const SegmentTypes = ["SymbolDictionary", null, null, null, "IntermediateTextRegion", null, "ImmediateTextRegion", "ImmediateLosslessTextRegion", null, null, null, null, null, null, null, null, "PatternDictionary", null, null, null, "IntermediateHalftoneRegion", null, "ImmediateHalftoneRegion", "ImmediateLosslessHalftoneRegion", null, null, null, null, null, null, null, null, null, null, null, null, "IntermediateGenericRegion", null, "ImmediateGenericRegion", "ImmediateLosslessGenericRegion", "IntermediateGenericRefinementRegion", null, "ImmediateGenericRefinementRegion", "ImmediateLosslessGenericRefinementRegion", null, null, null, null, "PageInformation", "EndOfPage", "EndOfStripe", "EndOfFile", "Profiles", "Tables", null, null, null, null, null, null, null, null, "Extension"];
const CodingTemplates = [[{
x: -1,
y: -2
}, {
x: 0,
y: -2
}, {
x: 1,
y: -2
}, {
x: -2,
y: -1
}, {
x: -1,
y: -1
}, {
x: 0,
y: -1
}, {
x: 1,
y: -1
}, {
x: 2,
y: -1
}, {
x: -4,
y: 0
}, {
x: -3,
y: 0
}, {
x: -2,
y: 0
}, {
x: -1,
y: 0
}], [{
x: -1,
y: -2
}, {
x: 0,
y: -2
}, {
x: 1,
y: -2
}, {
x: 2,
y: -2
}, {
x: -2,
y: -1
}, {
x: -1,
y: -1
}, {
x: 0,
y: -1
}, {
x: 1,
y: -1
}, {
x: 2,
y: -1
}, {
x: -3,
y: 0
}, {
x: -2,
y: 0
}, {
x: -1,
y: 0
}], [{
x: -1,
y: -2
}, {
x: 0,
y: -2
}, {
x: 1,
y: -2
}, {
x: -2,
y: -1
}, {
x: -1,
y: -1
}, {
x: 0,
y: -1
}, {
x: 1,
y: -1
}, {
x: -2,
y: 0
}, {
x: -1,
y: 0
}], [{
x: -3,
y: -1
}, {
x: -2,
y: -1
}, {
x: -1,
y: -1
}, {
x: 0,
y: -1
}, {
x: 1,
y: -1
}, {
x: -4,
y: 0
}, {
x: -3,
y: 0
}, {
x: -2,
y: 0
}, {
x: -1,
y: 0
}]];
const RefinementTemplates = [{
coding: [{
x: 0,
y: -1
}, {
x: 1,
y: -1
}, {
x: -1,
y: 0
}],
reference: [{
x: 0,
y: -1
}, {
x: 1,
y: -1
}, {
x: -1,
y: 0
}, {
x: 0,
y: 0
}, {
x: 1,
y: 0
}, {
x: -1,
y: 1
}, {
x: 0,
y: 1
}, {
x: 1,
y: 1
}]
}, {
coding: [{
x: -1,
y: -1
}, {
x: 0,
y: -1
}, {
x: 1,
y: -1
}, {
x: -1,
y: 0
}],
reference: [{
x: 0,
y: -1
}, {
x: -1,
y: 0
}, {
x: 0,
y: 0
}, {
x: 1,
y: 0
}, {
x: 0,
y: 1
}, {
x: 1,
y: 1
}]
}];
const ReusedContexts = [0x9b25, 0x0795, 0x00e5, 0x0195];
const RefinementReusedContexts = [0x0020, 0x0008];
function decodeBitmapTemplate0(width, height, decodingContext) {
const decoder = decodingContext.decoder;
const contexts = decodingContext.contextCache.getContexts("GB");
const bitmap = [];
let contextLabel, i, j, pixel, row, row1, row2;
const OLD_PIXEL_MASK = 0x7bf7;
for (i = 0; i < height; i++) {
row = bitmap[i] = new Uint8Array(width);
row1 = i < 1 ? row : bitmap[i - 1];
row2 = i < 2 ? row : bitmap[i - 2];
contextLabel = row2[0] << 13 | row2[1] << 12 | row2[2] << 11 | row1[0] << 7 | row1[1] << 6 | row1[2] << 5 | row1[3] << 4;
for (j = 0; j < width; j++) {
row[j] = pixel = decoder.readBit(contexts, contextLabel);
contextLabel = (contextLabel & OLD_PIXEL_MASK) << 1 | (j + 3 < width ? row2[j + 3] << 11 : 0) | (j + 4 < width ? row1[j + 4] << 4 : 0) | pixel;
}
}
return bitmap;
}
function decodeBitmap(mmr, width, height, templateIndex, prediction, skip, at, decodingContext) {
if (mmr) {
const input = new Reader(decodingContext.data, decodingContext.start, decodingContext.end);
return decodeMMRBitmap(input, width, height, false);
}
if (templateIndex === 0 && !skip && !prediction && at.length === 4 && at[0].x === 3 && at[0].y === -1 && at[1].x === -3 && at[1].y === -1 && at[2].x === 2 && at[2].y === -2 && at[3].x === -2 && at[3].y === -2) {
return decodeBitmapTemplate0(width, height, decodingContext);
}
const useskip = !!skip;
const template = CodingTemplates[templateIndex].concat(at);
template.sort((a, b) => a.y - b.y || a.x - b.x);
const templateLength = template.length;
const templateX = new Int8Array(templateLength);
const templateY = new Int8Array(templateLength);
const changingTemplateEntries = [];
let reuseMask = 0,
minX = 0,
maxX = 0,
minY = 0;
let c, k;
for (k = 0; k < templateLength; k++) {
templateX[k] = template[k].x;
templateY[k] = template[k].y;
minX = Math.min(minX, template[k].x);
maxX = Math.max(maxX, template[k].x);
minY = Math.min(minY, template[k].y);
if (k < templateLength - 1 && template[k].y === template[k + 1].y && template[k].x === template[k + 1].x - 1) {
reuseMask |= 1 << templateLength - 1 - k;
} else {
changingTemplateEntries.push(k);
}
}
const changingEntriesLength = changingTemplateEntries.length;
const changingTemplateX = new Int8Array(changingEntriesLength);
const changingTemplateY = new Int8Array(changingEntriesLength);
const changingTemplateBit = new Uint16Array(changingEntriesLength);
for (c = 0; c < changingEntriesLength; c++) {
k = changingTemplateEntries[c];
changingTemplateX[c] = template[k].x;
changingTemplateY[c] = template[k].y;
changingTemplateBit[c] = 1 << templateLength - 1 - k;
}
const sbb_left = -minX;
const sbb_top = -minY;
const sbb_right = width - maxX;
const pseudoPixelContext = ReusedContexts[templateIndex];
let row = new Uint8Array(width);
const bitmap = [];
const decoder = decodingContext.decoder;
const contexts = decodingContext.contextCache.getContexts("GB");
let ltp = 0,
j,
i0,
j0,
contextLabel = 0,
bit,
shift;
for (let i = 0; i < height; i++) {
if (prediction) {
const sltp = decoder.readBit(contexts, pseudoPixelContext);
ltp ^= sltp;
if (ltp) {
bitmap.push(row);
continue;
}
}
row = new Uint8Array(row);
bitmap.push(row);
for (j = 0; j < width; j++) {
if (useskip && skip[i][j]) {
row[j] = 0;
continue;
}
if (j >= sbb_left && j < sbb_right && i >= sbb_top) {
contextLabel = contextLabel << 1 & reuseMask;
for (k = 0; k < changingEntriesLength; k++) {
i0 = i + changingTemplateY[k];
j0 = j + changingTemplateX[k];
bit = bitmap[i0][j0];
if (bit) {
bit = changingTemplateBit[k];
contextLabel |= bit;
}
}
} else {
contextLabel = 0;
shift = templateLength - 1;
for (k = 0; k < templateLength; k++, shift--) {
j0 = j + templateX[k];
if (j0 >= 0 && j0 < width) {
i0 = i + templateY[k];
if (i0 >= 0) {
bit = bitmap[i0][j0];
if (bit) {
contextLabel |= bit << shift;
}
}
}
}
}
const pixel = decoder.readBit(contexts, contextLabel);
row[j] = pixel;
}
}
return bitmap;
}
function decodeRefinement(width, height, templateIndex, referenceBitmap, offsetX, offsetY, prediction, at, decodingContext) {
let codingTemplate = RefinementTemplates[templateIndex].coding;
if (templateIndex === 0) {
codingTemplate = codingTemplate.concat([at[0]]);
}
const codingTemplateLength = codingTemplate.length;
const codingTemplateX = new Int32Array(codingTemplateLength);
const codingTemplateY = new Int32Array(codingTemplateLength);
let k;
for (k = 0; k < codingTemplateLength; k++) {
codingTemplateX[k] = codingTemplate[k].x;
codingTemplateY[k] = codingTemplate[k].y;
}
let referenceTemplate = RefinementTemplates[templateIndex].reference;
if (templateIndex === 0) {
referenceTemplate = referenceTemplate.concat([at[1]]);
}
const referenceTemplateLength = referenceTemplate.length;
const referenceTemplateX = new Int32Array(referenceTemplateLength);
const referenceTemplateY = new Int32Array(referenceTemplateLength);
for (k = 0; k < referenceTemplateLength; k++) {
referenceTemplateX[k] = referenceTemplate[k].x;
referenceTemplateY[k] = referenceTemplate[k].y;
}
const referenceWidth = referenceBitmap[0].length;
const referenceHeight = referenceBitmap.length;
const pseudoPixelContext = RefinementReusedContexts[templateIndex];
const bitmap = [];
const decoder = decodingContext.decoder;
const contexts = decodingContext.contextCache.getContexts("GR");
let ltp = 0;
for (let i = 0; i < height; i++) {
if (prediction) {
const sltp = decoder.readBit(contexts, pseudoPixelContext);
ltp ^= sltp;
if (ltp) {
throw new Jbig2Error("prediction is not supported");
}
}
const row = new Uint8Array(width);
bitmap.push(row);
for (let j = 0; j < width; j++) {
let i0, j0;
let contextLabel = 0;
for (k = 0; k < codingTemplateLength; k++) {
i0 = i + codingTemplateY[k];
j0 = j + codingTemplateX[k];
if (i0 < 0 || j0 < 0 || j0 >= width) {
contextLabel <<= 1;
} else {
contextLabel = contextLabel << 1 | bitmap[i0][j0];
}
}
for (k = 0; k < referenceTemplateLength; k++) {
i0 = i + referenceTemplateY[k] - offsetY;
j0 = j + referenceTemplateX[k] - offsetX;
if (i0 < 0 || i0 >= referenceHeight || j0 < 0 || j0 >= referenceWidth) {
contextLabel <<= 1;
} else {
contextLabel = contextLabel << 1 | referenceBitmap[i0][j0];
}
}
const pixel = decoder.readBit(contexts, contextLabel);
row[j] = pixel;
}
}
return bitmap;
}
function decodeSymbolDictionary(huffman, refinement, symbols, numberOfNewSymbols, numberOfExportedSymbols, huffmanTables, templateIndex, at, refinementTemplateIndex, refinementAt, decodingContext, huffmanInput) {
if (huffman && refinement) {
throw new Jbig2Error("symbol refinement with Huffman is not supported");
}
const newSymbols = [];
let currentHeight = 0;
let symbolCodeLength = log2(symbols.length + numberOfNewSymbols);
const decoder = decodingContext.decoder;
const contextCache = decodingContext.contextCache;
let tableB1, symbolWidths;
if (huffman) {
tableB1 = getStandardTable(1);
symbolWidths = [];
symbolCodeLength = Math.max(symbolCodeLength, 1);
}
while (newSymbols.length < numberOfNewSymbols) {
const deltaHeight = huffman ? huffmanTables.tableDeltaHeight.decode(huffmanInput) : decodeInteger(contextCache, "IADH", decoder);
currentHeight += deltaHeight;
let currentWidth = 0,
totalWidth = 0;
const firstSymbol = huffman ? symbolWidths.length : 0;
while (true) {
const deltaWidth = huffman ? huffmanTables.tableDeltaWidth.decode(huffmanInput) : decodeInteger(contextCache, "IADW", decoder);
if (deltaWidth === null) {
break;
}
currentWidth += deltaWidth;
totalWidth += currentWidth;
let bitmap;
if (refinement) {
const numberOfInstances = decodeInteger(contextCache, "IAAI", decoder);
if (numberOfInstances > 1) {
bitmap = decodeTextRegion(huffman, refinement, currentWidth, currentHeight, 0, numberOfInstances, 1, symbols.concat(newSymbols), symbolCodeLength, 0, 0, 1, 0, huffmanTables, refinementTemplateIndex, refinementAt, decodingContext, 0, huffmanInput);
} else {
const symbolId = decodeIAID(contextCache, decoder, symbolCodeLength);
const rdx = decodeInteger(contextCache, "IARDX", decoder);
const rdy = decodeInteger(contextCache, "IARDY", decoder);
const symbol = symbolId < symbols.length ? symbols[symbolId] : newSymbols[symbolId - symbols.length];
bitmap = decodeRefinement(currentWidth, currentHeight, refinementTemplateIndex, symbol, rdx, rdy, false, refinementAt, decodingContext);
}
newSymbols.push(bitmap);
} else if (huffman) {
symbolWidths.push(currentWidth);
} else {
bitmap = decodeBitmap(false, currentWidth, currentHeight, templateIndex, false, null, at, decodingContext);
newSymbols.push(bitmap);
}
}
if (huffman && !refinement) {
const bitmapSize = huffmanTables.tableBitmapSize.decode(huffmanInput);
huffmanInput.byteAlign();
let collectiveBitmap;
if (bitmapSize === 0) {
collectiveBitmap = readUncompressedBitmap(huffmanInput, totalWidth, currentHeight);
} else {
const originalEnd = huffmanInput.end;
const bitmapEnd = huffmanInput.position + bitmapSize;
huffmanInput.end = bitmapEnd;
collectiveBitmap = decodeMMRBitmap(huffmanInput, totalWidth, currentHeight, false);
huffmanInput.end = originalEnd;
huffmanInput.position = bitmapEnd;
}
const numberOfSymbolsDecoded = symbolWidths.length;
if (firstSymbol === numberOfSymbolsDecoded - 1) {
newSymbols.push(collectiveBitmap);
} else {
let i,
y,
xMin = 0,
xMax,
bitmapWidth,
symbolBitmap;
for (i = firstSymbol; i < numberOfSymbolsDecoded; i++) {
bitmapWidth = symbolWidths[i];
xMax = xMin + bitmapWidth;
symbolBitmap = [];
for (y = 0; y < currentHeight; y++) {
symbolBitmap.push(collectiveBitmap[y].subarray(xMin, xMax));
}
newSymbols.push(symbolBitmap);
xMin = xMax;
}
}
}
}
const exportedSymbols = [],
flags = [];
let currentFlag = false,
i,
ii;
const totalSymbolsLength = symbols.length + numberOfNewSymbols;
while (flags.length < totalSymbolsLength) {
let runLength = huffman ? tableB1.decode(huffmanInput) : decodeInteger(contextCache, "IAEX", decoder);
while (runLength--) {
flags.push(currentFlag);
}
currentFlag = !currentFlag;
}
for (i = 0, ii = symbols.length; i < ii; i++) {
if (flags[i]) {
exportedSymbols.push(symbols[i]);
}
}
for (let j = 0; j < numberOfNewSymbols; i++, j++) {
if (flags[i]) {
exportedSymbols.push(newSymbols[j]);
}
}
return exportedSymbols;
}
function decodeTextRegion(huffman, refinement, width, height, defaultPixelValue, numberOfSymbolInstances, stripSize, inputSymbols, symbolCodeLength, transposed, dsOffset, referenceCorner, combinationOperator, huffmanTables, refinementTemplateIndex, refinementAt, decodingContext, logStripSize, huffmanInput) {
if (huffman && refinement) {
throw new Jbig2Error("refinement with Huffman is not supported");
}
const bitmap = [];
let i, row;
for (i = 0; i < height; i++) {
row = new Uint8Array(width);
if (defaultPixelValue) {
row.fill(defaultPixelValue);
}
bitmap.push(row);
}
const decoder = decodingContext.decoder;
const contextCache = decodingContext.contextCache;
let stripT = huffman ? -huffmanTables.tableDeltaT.decode(huffmanInput) : -decodeInteger(contextCache, "IADT", decoder);
let firstS = 0;
i = 0;
while (i < numberOfSymbolInstances) {
const deltaT = huffman ? huffmanTables.tableDeltaT.decode(huffmanInput) : decodeInteger(contextCache, "IADT", decoder);
stripT += deltaT;
const deltaFirstS = huffman ? huffmanTables.tableFirstS.decode(huffmanInput) : decodeInteger(contextCache, "IAFS", decoder);
firstS += deltaFirstS;
let currentS = firstS;
do {
let currentT = 0;
if (stripSize > 1) {
currentT = huffman ? huffmanInput.readBits(logStripSize) : decodeInteger(contextCache, "IAIT", decoder);
}
const t = stripSize * stripT + currentT;
const symbolId = huffman ? huffmanTables.symbolIDTable.decode(huffmanInput) : decodeIAID(contextCache, decoder, symbolCodeLength);
const applyRefinement = refinement && (huffman ? huffmanInput.readBit() : decodeInteger(contextCache, "IARI", decoder));
let symbolBitmap = inputSymbols[symbolId];
let symbolWidth = symbolBitmap[0].length;
let symbolHeight = symbolBitmap.length;
if (applyRefinement) {
const rdw = decodeInteger(contextCache, "IARDW", decoder);
const rdh = decodeInteger(contextCache, "IARDH", decoder);
const rdx = decodeInteger(contextCache, "IARDX", decoder);
const rdy = decodeInteger(contextCache, "IARDY", decoder);
symbolWidth += rdw;
symbolHeight += rdh;
symbolBitmap = decodeRefinement(symbolWidth, symbolHeight, refinementTemplateIndex, symbolBitmap, (rdw >> 1) + rdx, (rdh >> 1) + rdy, false, refinementAt, decodingContext);
}
let increment = 0;
if (!transposed) {
if (referenceCorner > 1) {
currentS += symbolWidth - 1;
} else {
increment = symbolWidth - 1;
}
} else if (!(referenceCorner & 1)) {
currentS += symbolHeight - 1;
} else {
increment = symbolHeight - 1;
}
const offsetT = t - (referenceCorner & 1 ? 0 : symbolHeight - 1);
const offsetS = currentS - (referenceCorner & 2 ? symbolWidth - 1 : 0);
let s2, t2, symbolRow;
if (transposed) {
for (s2 = 0; s2 < symbolHeight; s2++) {
row = bitmap[offsetS + s2];
if (!row) {
continue;
}
symbolRow = symbolBitmap[s2];
const maxWidth = Math.min(width - offsetT, symbolWidth);
switch (combinationOperator) {
case 0:
for (t2 = 0; t2 < maxWidth; t2++) {
row[offsetT + t2] |= symbolRow[t2];
}
break;
case 2:
for (t2 = 0; t2 < maxWidth; t2++) {
row[offsetT + t2] ^= symbolRow[t2];
}
break;
default:
throw new Jbig2Error(`operator ${combinationOperator} is not supported`);
}
}
} else {
for (t2 = 0; t2 < symbolHeight; t2++) {
row = bitmap[offsetT + t2];
if (!row) {
continue;
}
symbolRow = symbolBitmap[t2];
switch (combinationOperator) {
case 0:
for (s2 = 0; s2 < symbolWidth; s2++) {
row[offsetS + s2] |= symbolRow[s2];
}
break;
case 2:
for (s2 = 0; s2 < symbolWidth; s2++) {
row[offsetS + s2] ^= symbolRow[s2];
}
break;
default:
throw new Jbig2Error(`operator ${combinationOperator} is not supported`);
}
}
}
i++;
const deltaS = huffman ? huffmanTables.tableDeltaS.decode(huffmanInput) : decodeInteger(contextCache, "IADS", decoder);
if (deltaS === null) {
break;
}
currentS += increment + deltaS + dsOffset;
} while (true);
}
return bitmap;
}
function decodePatternDictionary(mmr, patternWidth, patternHeight, maxPatternIndex, template, decodingContext) {
const at = [];
if (!mmr) {
at.push({
x: -patternWidth,
y: 0
});
if (template === 0) {
at.push({
x: -3,
y: -1
}, {
x: 2,
y: -2
}, {
x: -2,
y: -2
});
}
}
const collectiveWidth = (maxPatternIndex + 1) * patternWidth;
const collectiveBitmap = decodeBitmap(mmr, collectiveWidth, patternHeight, template, false, null, at, decodingContext);
const patterns = [];
for (let i = 0; i <= maxPatternIndex; i++) {
const patternBitmap = [];
const xMin = patternWidth * i;
const xMax = xMin + patternWidth;
for (let y = 0; y < patternHeight; y++) {
patternBitmap.push(collectiveBitmap[y].subarray(xMin, xMax));
}
patterns.push(patternBitmap);
}
return patterns;
}
function decodeHalftoneRegion(mmr, patterns, template, regionWidth, regionHeight, defaultPixelValue, enableSkip, combinationOperator, gridWidth, gridHeight, gridOffsetX, gridOffsetY, gridVectorX, gridVectorY, decodingContext) {
const skip = null;
if (enableSkip) {
throw new Jbig2Error("skip is not supported");
}
if (combinationOperator !== 0) {
throw new Jbig2Error(`operator "${combinationOperator}" is not supported in halftone region`);
}
const regionBitmap = [];
let i, j, row;
for (i = 0; i < regionHeight; i++) {
row = new Uint8Array(regionWidth);
if (defaultPixelValue) {
row.fill(defaultPixelValue);
}
regionBitmap.push(row);
}
const numberOfPatterns = patterns.length;
const pattern0 = patterns[0];
const patternWidth = pattern0[0].length,
patternHeight = pattern0.length;
const bitsPerValue = log2(numberOfPatterns);
const at = [];
if (!mmr) {
at.push({
x: template <= 1 ? 3 : 2,
y: -1
});
if (template === 0) {
at.push({
x: -3,
y: -1
}, {
x: 2,
y: -2
}, {
x: -2,
y: -2
});
}
}
const grayScaleBitPlanes = [];
let mmrInput, bitmap;
if (mmr) {
mmrInput = new Reader(decodingContext.data, decodingContext.start, decodingContext.end);
}
for (i = bitsPerValue - 1; i >= 0; i--) {
if (mmr) {
bitmap = decodeMMRBitmap(mmrInput, gridWidth, gridHeight, true);
} else {
bitmap = decodeBitmap(false, gridWidth, gridHeight, template, false, skip, at, decodingContext);
}
grayScaleBitPlanes[i] = bitmap;
}
let mg, ng, bit, patternIndex, patternBitmap, x, y, patternRow, regionRow;
for (mg = 0; mg < gridHeight; mg++) {
for (ng = 0; ng < gridWidth; ng++) {
bit = 0;
patternIndex = 0;
for (j = bitsPerValue - 1; j >= 0; j--) {
bit ^= grayScaleBitPlanes[j][mg][ng];
patternIndex |= bit << j;
}
patternBitmap = patterns[patternIndex];
x = gridOffsetX + mg * gridVectorY + ng * gridVectorX >> 8;
y = gridOffsetY + mg * gridVectorX - ng * gridVectorY >> 8;
if (x >= 0 && x + patternWidth <= regionWidth && y >= 0 && y + patternHeight <= regionHeight) {
for (i = 0; i < patternHeight; i++) {
regionRow = regionBitmap[y + i];
patternRow = patternBitmap[i];
for (j = 0; j < patternWidth; j++) {
regionRow[x + j] |= patternRow[j];
}
}
} else {
let regionX, regionY;
for (i = 0; i < patternHeight; i++) {
regionY = y + i;
if (regionY < 0 || regionY >= regionHeight) {
continue;
}
regionRow = regionBitmap[regionY];
patternRow = patternBitmap[i];
for (j = 0; j < patternWidth; j++) {
regionX = x + j;
if (regionX >= 0 && regionX < regionWidth) {
regionRow[regionX] |= patternRow[j];
}
}
}
}
}
}
return regionBitmap;
}
function readSegmentHeader(data, start) {
const segmentHeader = {};
segmentHeader.number = readUint32(data, start);
const flags = data[start + 4];
const segmentType = flags & 0x3f;
if (!SegmentTypes[segmentType]) {
throw new Jbig2Error("invalid segment type: " + segmentType);
}
segmentHeader.type = segmentType;
segmentHeader.typeName = SegmentTypes[segmentType];
segmentHeader.deferredNonRetain = !!(flags & 0x80);
const pageAssociationFieldSize = !!(flags & 0x40);
const referredFlags = data[start + 5];
let referredToCount = referredFlags >> 5 & 7;
const retainBits = [referredFlags & 31];
let position = start + 6;
if (referredFlags === 7) {
referredToCount = readUint32(data, position - 1) & 0x1fffffff;
position += 3;
let bytes = referredToCount + 7 >> 3;
retainBits[0] = data[position++];
while (--bytes > 0) {
retainBits.push(data[position++]);
}
} else if (referredFlags === 5 || referredFlags === 6) {
throw new Jbig2Error("invalid referred-to flags");
}
segmentHeader.retainBits = retainBits;
let referredToSegmentNumberSize = 4;
if (segmentHeader.number <= 256) {
referredToSegmentNumberSize = 1;
} else if (segmentHeader.number <= 65536) {
referredToSegmentNumberSize = 2;
}
const referredTo = [];
let i, ii;
for (i = 0; i < referredToCount; i++) {
let number;
if (referredToSegmentNumberSize === 1) {
number = data[position];
} else if (referredToSegmentNumberSize === 2) {
number = readUint16(data, position);
} else {
number = readUint32(data, position);
}
referredTo.push(number);
position += referredToSegmentNumberSize;
}
segmentHeader.referredTo = referredTo;
if (!pageAssociationFieldSize) {
segmentHeader.pageAssociation = data[position++];
} else {
segmentHeader.pageAssociation = readUint32(data, position);
position += 4;
}
segmentHeader.length = readUint32(data, position);
position += 4;
if (segmentHeader.length === 0xffffffff) {
if (segmentType === 38) {
const genericRegionInfo = readRegionSegmentInformation(data, position);
const genericRegionSegmentFlags = data[position + RegionSegmentInformationFieldLength];
const genericRegionMmr = !!(genericRegionSegmentFlags & 1);
const searchPatternLength = 6;
const searchPattern = new Uint8Array(searchPatternLength);
if (!genericRegionMmr) {
searchPattern[0] = 0xff;
searchPattern[1] = 0xac;
}
searchPattern[2] = genericRegionInfo.height >>> 24 & 0xff;
searchPattern[3] = genericRegionInfo.height >> 16 & 0xff;
searchPattern[4] = genericRegionInfo.height >> 8 & 0xff;
searchPattern[5] = genericRegionInfo.height & 0xff;
for (i = position, ii = data.length; i < ii; i++) {
let j = 0;
while (j < searchPatternLength && searchPattern[j] === data[i + j]) {
j++;
}
if (j === searchPatternLength) {
segmentHeader.length = i + searchPatternLength;
break;
}
}
if (segmentHeader.length === 0xffffffff) {
throw new Jbig2Error("segment end was not found");
}
} else {
throw new Jbig2Error("invalid unknown segment length");
}
}
segmentHeader.headerEnd = position;
return segmentHeader;
}
function readSegments(header, data, start, end) {
const segments = [];
let position = start;
while (position < end) {
const segmentHeader = readSegmentHeader(data, position);
position = segmentHeader.headerEnd;
const segment = {
header: segmentHeader,
data
};
if (!header.randomAccess) {
segment.start = position;
position += segmentHeader.length;
segment.end = position;
}
segments.push(segment);
if (segmentHeader.type === 51) {
break;
}
}
if (header.randomAccess) {
for (let i = 0, ii = segments.length; i < ii; i++) {
segments[i].start = position;
position += segments[i].header.length;
segments[i].end = position;
}
}
return segments;
}
function readRegionSegmentInformation(data, start) {
return {
width: readUint32(data, start),
height: readUint32(data, start + 4),
x: readUint32(data, start + 8),
y: readUint32(data, start + 12),
combinationOperator: data[start + 16] & 7
};
}
const RegionSegmentInformationFieldLength = 17;
function processSegment(segment, visitor) {
const header = segment.header;
const data = segment.data,
end = segment.end;
let position = segment.start;
let args, at, i, atLength;
switch (header.type) {
case 0:
const dictionary = {};
const dictionaryFlags = readUint16(data, position);
dictionary.huffman = !!(dictionaryFlags & 1);
dictionary.refinement = !!(dictionaryFlags & 2);
dictionary.huffmanDHSelector = dictionaryFlags >> 2 & 3;
dictionary.huffmanDWSelector = dictionaryFlags >> 4 & 3;
dictionary.bitmapSizeSelector = dictionaryFlags >> 6 & 1;
dictionary.aggregationInstancesSelector = dictionaryFlags >> 7 & 1;
dictionary.bitmapCodingContextUsed = !!(dictionaryFlags & 256);
dictionary.bitmapCodingContextRetained = !!(dictionaryFlags & 512);
dictionary.template = dictionaryFlags >> 10 & 3;
dictionary.refinementTemplate = dictionaryFlags >> 12 & 1;
position += 2;
if (!dictionary.huffman) {
atLength = dictionary.template === 0 ? 4 : 1;
at = [];
for (i = 0; i < atLength; i++) {
at.push({
x: readInt8(data, position),
y: readInt8(data, position + 1)
});
position += 2;
}
dictionary.at = at;
}
if (dictionary.refinement && !dictionary.refinementTemplate) {
at = [];
for (i = 0; i < 2; i++) {
at.push({
x: readInt8(data, position),
y: readInt8(data, position + 1)
});
position += 2;
}
dictionary.refinementAt = at;
}
dictionary.numberOfExportedSymbols = readUint32(data, position);
position += 4;
dictionary.numberOfNewSymbols = readUint32(data, position);
position += 4;
args = [dictionary, header.number, header.referredTo, data, position, end];
break;
case 6:
case 7:
const textRegion = {};
textRegion.info = readRegionSegmentInformation(data, position);
position += RegionSegmentInformationFieldLength;
const textRegionSegmentFlags = readUint16(data, position);
position += 2;
textRegion.huffman = !!(textRegionSegmentFlags & 1);
textRegion.refinement = !!(textRegionSegmentFlags & 2);
textRegion.logStripSize = textRegionSegmentFlags >> 2 & 3;
textRegion.stripSize = 1 << textRegion.logStripSize;
textRegion.referenceCorner = textRegionSegmentFlags >> 4 & 3;
textRegion.transposed = !!(textRegionSegmentFlags & 64);
textRegion.combinationOperator = textRegionSegmentFlags >> 7 & 3;
textRegion.defaultPixelValue = textRegionSegmentFlags >> 9 & 1;
textRegion.dsOffset = textRegionSegmentFlags << 17 >> 27;
textRegion.refinementTemplate = textRegionSegmentFlags >> 15 & 1;
if (textRegion.huffman) {
const textRegionHuffmanFlags = readUint16(data, position);
position += 2;
textRegion.huffmanFS = textRegionHuffmanFlags & 3;
textRegion.huffmanDS = textRegionHuffmanFlags >> 2 & 3;
textRegion.huffmanDT = textRegionHuffmanFlags >> 4 & 3;
textRegion.huffmanRefinementDW = textRegionHuffmanFlags >> 6 & 3;
textRegion.huffmanRefinementDH = textRegionHuffmanFlags >> 8 & 3;
textRegion.huffmanRefinementDX = textRegionHuffmanFlags >> 10 & 3;
textRegion.huffmanRefinementDY = textRegionHuffmanFlags >> 12 & 3;
textRegion.huffmanRefinementSizeSelector = !!(textRegionHuffmanFlags & 0x4000);
}
if (textRegion.refinement && !textRegion.refinementTemplate) {
at = [];
for (i = 0; i < 2; i++) {
at.push({
x: readInt8(data, position),
y: readInt8(data, position + 1)
});
position += 2;
}
textRegion.refinementAt = at;
}
textRegion.numberOfSymbolInstances = readUint32(data, position);
position += 4;
args = [textRegion, header.referredTo, data, position, end];
break;
case 16:
const patternDictionary = {};
const patternDictionaryFlags = data[position++];
patternDictionary.mmr = !!(patternDictionaryFlags & 1);
patternDictionary.template = patternDictionaryFlags >> 1 & 3;
patternDictionary.patternWidth = data[position++];
patternDictionary.patternHeight = data[position++];
patternDictionary.maxPatternIndex = readUint32(data, position);
position += 4;
args = [patternDictionary, header.number, data, position, end];
break;
case 22:
case 23:
const halftoneRegion = {};
halftoneRegion.info = readRegionSegmentInformation(data, position);
position += RegionSegmentInformationFieldLength;
const halftoneRegionFlags = data[position++];
halftoneRegion.mmr = !!(halftoneRegionFlags & 1);
halftoneRegion.template = halftoneRegionFlags >> 1 & 3;
halftoneRegion.enableSkip = !!(halftoneRegionFlags & 8);
halftoneRegion.combinationOperator = halftoneRegionFlags >> 4 & 7;
halftoneRegion.defaultPixelValue = halftoneRegionFlags >> 7 & 1;
halftoneRegion.gridWidth = readUint32(data, position);
position += 4;
halftoneRegion.gridHeight = readUint32(data, position);
position += 4;
halftoneRegion.gridOffsetX = readUint32(data, position) & 0xffffffff;
position += 4;
halftoneRegion.gridOffsetY = readUint32(data, position) & 0xffffffff;
position += 4;
halftoneRegion.gridVectorX = readUint16(data, position);
position += 2;
halftoneRegion.gridVectorY = readUint16(data, position);
position += 2;
args = [halftoneRegion, header.referredTo, data, position, end];
break;
case 38:
case 39:
const genericRegion = {};
genericRegion.info = readRegionSegmentInformation(data, position);
position += RegionSegmentInformationFieldLength;
const genericRegionSegmentFlags = data[position++];
genericRegion.mmr = !!(genericRegionSegmentFlags & 1);
genericRegion.template = genericRegionSegmentFlags >> 1 & 3;
genericRegion.prediction = !!(genericRegionSegmentFlags & 8);
if (!genericRegion.mmr) {
atLength = genericRegion.template === 0 ? 4 : 1;
at = [];
for (i = 0; i < atLength; i++) {
at.push({
x: readInt8(data, position),
y: readInt8(data, position + 1)
});
position += 2;
}
genericRegion.at = at;
}
args = [genericRegion, data, position, end];
break;
case 48:
const pageInfo = {
width: readUint32(data, position),
height: readUint32(data, position + 4),
resolutionX: readUint32(data, position + 8),
resolutionY: readUint32(data, position + 12)
};
if (pageInfo.height === 0xffffffff) {
delete pageInfo.height;
}
const pageSegmentFlags = data[position + 16];
readUint16(data, position + 17);
pageInfo.lossless = !!(pageSegmentFlags & 1);
pageInfo.refinement = !!(pageSegmentFlags & 2);
pageInfo.defaultPixelValue = pageSegmentFlags >> 2 & 1;
pageInfo.combinationOperator = pageSegmentFlags >> 3 & 3;
pageInfo.requiresBuffer = !!(pageSegmentFlags & 32);
pageInfo.combinationOperatorOverride = !!(pageSegmentFlags & 64);
args = [pageInfo];
break;
case 49:
break;
case 50:
break;
case 51:
break;
case 53:
args = [header.number, data, position, end];
break;
case 62:
break;
default:
throw new Jbig2Error(`segment type ${header.typeName}(${header.type}) is not implemented`);
}
const callbackName = "on" + header.typeName;
if (callbackName in visitor) {
visitor[callbackName].apply(visitor, args);
}
}
function processSegments(segments, visitor) {
for (let i = 0, ii = segments.length; i < ii; i++) {
processSegment(segments[i], visitor);
}
}
function parseJbig2Chunks(chunks) {
const visitor = new SimpleSegmentVisitor();
for (let i = 0, ii = chunks.length; i < ii; i++) {
const chunk = chunks[i];
const segments = readSegments({}, chunk.data, chunk.start, chunk.end);
processSegments(segments, visitor);
}
return visitor.buffer;
}
function parseJbig2(data) {
const end = data.length;
let position = 0;
if (data[position] !== 0x97 || data[position + 1] !== 0x4a || data[position + 2] !== 0x42 || data[position + 3] !== 0x32 || data[position + 4] !== 0x0d || data[position + 5] !== 0x0a || data[position + 6] !== 0x1a || data[position + 7] !== 0x0a) {
throw new Jbig2Error("parseJbig2 - invalid header.");
}
const header = Object.create(null);
position += 8;
const flags = data[position++];
header.randomAccess = !(flags & 1);
if (!(flags & 2)) {
header.numberOfPages = readUint32(data, position);
position += 4;
}
const segments = readSegments(header, data, position, end);
const visitor = new SimpleSegmentVisitor();
processSegments(segments, visitor);
const {
width,
height
} = visitor.currentPageInfo;
const bitPacked = visitor.buffer;
const imgData = new Uint8ClampedArray(width * height);
let q = 0,
k = 0;
for (let i = 0; i < height; i++) {
let mask = 0,
buffer;
for (let j = 0; j < width; j++) {
if (!mask) {
mask = 128;
buffer = bitPacked[k++];
}
imgData[q++] = buffer & mask ? 0 : 255;
mask >>= 1;
}
}
return {
imgData,
width,
height
};
}
class SimpleSegmentVisitor {
onPageInformation(info) {
this.currentPageInfo = info;
const rowSize = info.width + 7 >> 3;
const buffer = new Uint8ClampedArray(rowSize * info.height);
if (info.defaultPixelValue) {
buffer.fill(0xff);
}
this.buffer = buffer;
}
drawBitmap(regionInfo, bitmap) {
const pageInfo = this.currentPageInfo;
const width = regionInfo.width,
height = regionInfo.height;
const rowSize = pageInfo.width + 7 >> 3;
const combinationOperator = pageInfo.combinationOperatorOverride ? regionInfo.combinationOperator : pageInfo.combinationOperator;
const buffer = this.buffer;
const mask0 = 128 >> (regionInfo.x & 7);
let offset0 = regionInfo.y * rowSize + (regionInfo.x >> 3);
let i, j, mask, offset;
switch (combinationOperator) {
case 0:
for (i = 0; i < height; i++) {
mask = mask0;
offset = offset0;
for (j = 0; j < width; j++) {
if (bitmap[i][j]) {
buffer[offset] |= mask;
}
mask >>= 1;
if (!mask) {
mask = 128;
offset++;
}
}
offset0 += rowSize;
}
break;
case 2:
for (i = 0; i < height; i++) {
mask = mask0;
offset = offset0;
for (j = 0; j < width; j++) {
if (bitmap[i][j]) {
buffer[offset] ^= mask;
}
mask >>= 1;
if (!mask) {
mask = 128;
offset++;
}
}
offset0 += rowSize;
}
break;
default:
throw new Jbig2Error(`operator ${combinationOperator} is not supported`);
}
}
onImmediateGenericRegion(region, data, start, end) {
const regionInfo = region.info;
const decodingContext = new DecodingContext(data, start, end);
const bitmap = decodeBitmap(region.mmr, regionInfo.width, regionInfo.height, region.template, region.prediction, null, region.at, decodingContext);
this.drawBitmap(regionInfo, bitmap);
}
onImmediateLosslessGenericRegion() {
this.onImmediateGenericRegion(...arguments);
}
onSymbolDictionary(dictionary, currentSegment, referredSegments, data, start, end) {
let huffmanTables, huffmanInput;
if (dictionary.huffman) {
huffmanTables = getSymbolDictionaryHuffmanTables(dictionary, referredSegments, this.customTables);
huffmanInput = new Reader(data, start, end);
}
let symbols = this.symbols;
if (!symbols) {
this.symbols = symbols = {};
}
const inputSymbols = [];
for (const referredSegment of referredSegments) {
const referredSymbols = symbols[referredSegment];
if (referredSymbols) {
inputSymbols.push(...referredSymbols);
}
}
const decodingContext = new DecodingContext(data, start, end);
symbols[currentSegment] = decodeSymbolDictionary(dictionary.huffman, dictionary.refinement, inputSymbols, dictionary.numberOfNewSymbols, dictionary.numberOfExportedSymbols, huffmanTables, dictionary.template, dictionary.at, dictionary.refinementTemplate, dictionary.refinementAt, decodingContext, huffmanInput);
}
onImmediateTextRegion(region, referredSegments, data, start, end) {
const regionInfo = region.info;
let huffmanTables, huffmanInput;
const symbols = this.symbols;
const inputSymbols = [];
for (const referredSegment of referredSegments) {
const referredSymbols = symbols[referredSegment];
if (referredSymbols) {
inputSymbols.push(...referredSymbols);
}
}
const symbolCodeLength = log2(inputSymbols.length);
if (region.huffman) {
huffmanInput = new Reader(data, start, end);
huffmanTables = getTextRegionHuffmanTables(region, referredSegments, this.customTables, inputSymbols.length, huffmanInput);
}
const decodingContext = new DecodingContext(data, start, end);
const bitmap = decodeTextRegion(region.huffman, region.refinement, regionInfo.width, regionInfo.height, region.defaultPixelValue, region.numberOfSymbolInstances, region.stripSize, inputSymbols, symbolCodeLength, region.transposed, region.dsOffset, region.referenceCorner, region.combinationOperator, huffmanTables, region.refinementTemplate, region.refinementAt, decodingContext, region.logStripSize, huffmanInput);
this.drawBitmap(regionInfo, bitmap);
}
onImmediateLosslessTextRegion() {
this.onImmediateTextRegion(...arguments);
}
onPatternDictionary(dictionary, currentSegment, data, start, end) {
let patterns = this.patterns;
if (!patterns) {
this.patterns = patterns = {};
}
const decodingContext = new DecodingContext(data, start, end);
patterns[currentSegment] = decodePatternDictionary(dictionary.mmr, dictionary.patternWidth, dictionary.patternHeight, dictionary.maxPatternIndex, dictionary.template, decodingContext);
}
onImmediateHalftoneRegion(region, referredSegments, data, start, end) {
const patterns = this.patterns[referredSegments[0]];
const regionInfo = region.info;
const decodingContext = new DecodingContext(data, start, end);
const bitmap = decodeHalftoneRegion(region.mmr, patterns, region.template, regionInfo.width, regionInfo.height, region.defaultPixelValue, region.enableSkip, region.combinationOperator, region.gridWidth, region.gridHeight, region.gridOffsetX, region.gridOffsetY, region.gridVectorX, region.gridVectorY, decodingContext);
this.drawBitmap(regionInfo, bitmap);
}
onImmediateLosslessHalftoneRegion() {
this.onImmediateHalftoneRegion(...arguments);
}
onTables(currentSegment, data, start, end) {
let customTables = this.customTables;
if (!customTables) {
this.customTables = customTables = {};
}
customTables[currentSegment] = decodeTablesSegment(data, start, end);
}
}
class HuffmanLine {
constructor(lineData) {
if (lineData.length === 2) {
this.isOOB = true;
this.rangeLow = 0;
this.prefixLength = lineData[0];
this.rangeLength = 0;
this.prefixCode = lineData[1];
this.isLowerRange = false;
} else {
this.isOOB = false;
this.rangeLow = lineData[0];
this.prefixLength = lineData[1];
this.rangeLength = lineData[2];
this.prefixCode = lineData[3];
this.isLowerRange = lineData[4] === "lower";
}
}
}
class HuffmanTreeNode {
constructor(line) {
this.children = [];
if (line) {
this.isLeaf = true;
this.rangeLength = line.rangeLength;
this.rangeLow = line.rangeLow;
this.isLowerRange = line.isLowerRange;
this.isOOB = line.isOOB;
} else {
this.isLeaf = false;
}
}
buildTree(line, shift) {
const bit = line.prefixCode >> shift & 1;
if (shift <= 0) {
this.children[bit] = new HuffmanTreeNode(line);
} else {
let node = this.children[bit];
if (!node) {
this.children[bit] = node = new HuffmanTreeNode(null);
}
node.buildTree(line, shift - 1);
}
}
decodeNode(reader) {
if (this.isLeaf) {
if (this.isOOB) {
return null;
}
const htOffset = reader.readBits(this.rangeLength);
return this.rangeLow + (this.isLowerRange ? -htOffset : htOffset);
}
const node = this.children[reader.readBit()];
if (!node) {
throw new Jbig2Error("invalid Huffman data");
}
return node.decodeNode(reader);
}
}
class HuffmanTable {
constructor(lines, prefixCodesDone) {
if (!prefixCodesDone) {
this.assignPrefixCodes(lines);
}
this.rootNode = new HuffmanTreeNode(null);
for (let i = 0, ii = lines.length; i < ii; i++) {
const line = lines[i];
if (line.prefixLength > 0) {
this.rootNode.buildTree(line, line.prefixLength - 1);
}
}
}
decode(reader) {
return this.rootNode.decodeNode(reader);
}
assignPrefixCodes(lines) {
const linesLength = lines.length;
let prefixLengthMax = 0;
for (let i = 0; i < linesLength; i++) {
prefixLengthMax = Math.max(prefixLengthMax, lines[i].prefixLength);
}
const histogram = new Uint32Array(prefixLengthMax + 1);
for (let i = 0; i < linesLength; i++) {
histogram[lines[i].prefixLength]++;
}
let currentLength = 1,
firstCode = 0,
currentCode,
currentTemp,
line;
histogram[0] = 0;
while (currentLength <= prefixLengthMax) {
firstCode = firstCode + histogram[currentLength - 1] << 1;
currentCode = firstCode;
currentTemp = 0;
while (currentTemp < linesLength) {
line = lines[currentTemp];
if (line.prefixLength === currentLength) {
line.prefixCode = currentCode;
currentCode++;
}
currentTemp++;
}
currentLength++;
}
}
}
function decodeTablesSegment(data, start, end) {
const flags = data[start];
const lowestValue = readUint32(data, start + 1) & 0xffffffff;
const highestValue = readUint32(data, start + 5) & 0xffffffff;
const reader = new Reader(data, start + 9, end);
const prefixSizeBits = (flags >> 1 & 7) + 1;
const rangeSizeBits = (flags >> 4 & 7) + 1;
const lines = [];
let prefixLength,
rangeLength,
currentRangeLow = lowestValue;
do {
prefixLength = reader.readBits(prefixSizeBits);
rangeLength = reader.readBits(rangeSizeBits);
lines.push(new HuffmanLine([currentRangeLow, prefixLength, rangeLength, 0]));
currentRangeLow += 1 << rangeLength;
} while (currentRangeLow < highestValue);
prefixLength = reader.readBits(prefixSizeBits);
lines.push(new HuffmanLine([lowestValue - 1, prefixLength, 32, 0, "lower"]));
prefixLength = reader.readBits(prefixSizeBits);
lines.push(new HuffmanLine([highestValue, prefixLength, 32, 0]));
if (flags & 1) {
prefixLength = reader.readBits(prefixSizeBits);
lines.push(new HuffmanLine([prefixLength, 0]));
}
return new HuffmanTable(lines, false);
}
const standardTablesCache = {};
function getStandardTable(number) {
let table = standardTablesCache[number];
if (table) {
return table;
}
let lines;
switch (number) {
case 1:
lines = [[0, 1, 4, 0x0], [16, 2, 8, 0x2], [272, 3, 16, 0x6], [65808, 3, 32, 0x7]];
break;
case 2:
lines = [[0, 1, 0, 0x0], [1, 2, 0, 0x2], [2, 3, 0, 0x6], [3, 4, 3, 0xe], [11, 5, 6, 0x1e], [75, 6, 32, 0x3e], [6, 0x3f]];
break;
case 3:
lines = [[-256, 8, 8, 0xfe], [0, 1, 0, 0x0], [1, 2, 0, 0x2], [2, 3, 0, 0x6], [3, 4, 3, 0xe], [11, 5, 6, 0x1e], [-257, 8, 32, 0xff, "lower"], [75, 7, 32, 0x7e], [6, 0x3e]];
break;
case 4:
lines = [[1, 1, 0, 0x0], [2, 2, 0, 0x2], [3, 3, 0, 0x6], [4, 4, 3, 0xe], [12, 5, 6, 0x1e], [76, 5, 32, 0x1f]];
break;
case 5:
lines = [[-255, 7, 8, 0x7e], [1, 1, 0, 0x0], [2, 2, 0, 0x2], [3, 3, 0, 0x6], [4, 4, 3, 0xe], [12, 5, 6, 0x1e], [-256, 7, 32, 0x7f, "lower"], [76, 6, 32, 0x3e]];
break;
case 6:
lines = [[-2048, 5, 10, 0x1c], [-1024, 4, 9, 0x8], [-512, 4, 8, 0x9], [-256, 4, 7, 0xa], [-128, 5, 6, 0x1d], [-64, 5, 5, 0x1e], [-32, 4, 5, 0xb], [0, 2, 7, 0x0], [128, 3, 7, 0x2], [256, 3, 8, 0x3], [512, 4, 9, 0xc], [1024, 4, 10, 0xd], [-2049, 6, 32, 0x3e, "lower"], [2048, 6, 32, 0x3f]];
break;
case 7:
lines = [[-1024, 4, 9, 0x8], [-512, 3, 8, 0x0], [-256, 4, 7, 0x9], [-128, 5, 6, 0x1a], [-64, 5, 5, 0x1b], [-32, 4, 5, 0xa], [0, 4, 5, 0xb], [32, 5, 5, 0x1c], [64, 5, 6, 0x1d], [128, 4, 7, 0xc], [256, 3, 8, 0x1], [512, 3, 9, 0x2], [1024, 3, 10, 0x3], [-1025, 5, 32, 0x1e, "lower"], [2048, 5, 32, 0x1f]];
break;
case 8:
lines = [[-15, 8, 3, 0xfc], [-7, 9, 1, 0x1fc], [-5, 8, 1, 0xfd], [-3, 9, 0, 0x1fd], [-2, 7, 0, 0x7c], [-1, 4, 0, 0xa], [0, 2, 1, 0x0], [2, 5, 0, 0x1a], [3, 6, 0, 0x3a], [4, 3, 4, 0x4], [20, 6, 1, 0x3b], [22, 4, 4, 0xb], [38, 4, 5, 0xc], [70, 5, 6, 0x1b], [134, 5, 7, 0x1c], [262, 6, 7, 0x3c], [390, 7, 8, 0x7d], [646, 6, 10, 0x3d], [-16, 9, 32, 0x1fe, "lower"], [1670, 9, 32, 0x1ff], [2, 0x1]];
break;
case 9:
lines = [[-31, 8, 4, 0xfc], [-15, 9, 2, 0x1fc], [-11, 8, 2, 0xfd], [-7, 9, 1, 0x1fd], [-5, 7, 1, 0x7c], [-3, 4, 1, 0xa], [-1, 3, 1, 0x2], [1, 3, 1, 0x3], [3, 5, 1, 0x1a], [5, 6, 1, 0x3a], [7, 3, 5, 0x4], [39, 6, 2, 0x3b], [43, 4, 5, 0xb], [75, 4, 6, 0xc], [139, 5, 7, 0x1b], [267, 5, 8, 0x1c], [523, 6, 8, 0x3c], [779, 7, 9, 0x7d], [1291, 6, 11, 0x3d], [-32, 9, 32, 0x1fe, "lower"], [3339, 9, 32, 0x1ff], [2, 0x0]];
break;
case 10:
lines = [[-21, 7, 4, 0x7a], [-5, 8, 0, 0xfc], [-4, 7, 0, 0x7b], [-3, 5, 0, 0x18], [-2, 2, 2, 0x0], [2, 5, 0, 0x19], [3, 6, 0, 0x36], [4, 7, 0, 0x7c], [5, 8, 0, 0xfd], [6, 2, 6, 0x1], [70, 5, 5, 0x1a], [102, 6, 5, 0x37], [134, 6, 6, 0x38], [198, 6, 7, 0x39], [326, 6, 8, 0x3a], [582, 6, 9, 0x3b], [1094, 6, 10, 0x3c], [2118, 7, 11, 0x7d], [-22, 8, 32, 0xfe, "lower"], [4166, 8, 32, 0xff], [2, 0x2]];
break;
case 11:
lines = [[1, 1, 0, 0x0], [2, 2, 1, 0x2], [4, 4, 0, 0xc], [5, 4, 1, 0xd], [7, 5, 1, 0x1c], [9, 5, 2, 0x1d], [13, 6, 2, 0x3c], [17, 7, 2, 0x7a], [21, 7, 3, 0x7b], [29, 7, 4, 0x7c], [45, 7, 5, 0x7d], [77, 7, 6, 0x7e], [141, 7, 32, 0x7f]];
break;
case 12:
lines = [[1, 1, 0, 0x0], [2, 2, 0, 0x2], [3, 3, 1, 0x6], [5, 5, 0, 0x1c], [6, 5, 1, 0x1d], [8, 6, 1, 0x3c], [10, 7, 0, 0x7a], [11, 7, 1, 0x7b], [13, 7, 2, 0x7c], [17, 7, 3, 0x7d], [25, 7, 4, 0x7e], [41, 8, 5, 0xfe], [73, 8, 32, 0xff]];
break;
case 13:
lines = [[1, 1, 0, 0x0], [2, 3, 0, 0x4], [3, 4, 0, 0xc], [4, 5, 0, 0x1c], [5, 4, 1, 0xd], [7, 3, 3, 0x5], [15, 6, 1, 0x3a], [17, 6, 2, 0x3b], [21, 6, 3, 0x3c], [29, 6, 4, 0x3d], [45, 6, 5, 0x3e], [77, 7, 6, 0x7e], [141, 7, 32, 0x7f]];
break;
case 14:
lines = [[-2, 3, 0, 0x4], [-1, 3, 0, 0x5], [0, 1, 0, 0x0], [1, 3, 0, 0x6], [2, 3, 0, 0x7]];
break;
case 15:
lines = [[-24, 7, 4, 0x7c], [-8, 6, 2, 0x3c], [-4, 5, 1, 0x1c], [-2, 4, 0, 0xc], [-1, 3, 0, 0x4], [0, 1, 0, 0x0], [1, 3, 0, 0x5], [2, 4, 0, 0xd], [3, 5, 1, 0x1d], [5, 6, 2, 0x3d], [9, 7, 4, 0x7d], [-25, 7, 32, 0x7e, "lower"], [25, 7, 32, 0x7f]];
break;
default:
throw new Jbig2Error(`standard table B.${number} does not exist`);
}
for (let i = 0, ii = lines.length; i < ii; i++) {
lines[i] = new HuffmanLine(lines[i]);
}
table = new HuffmanTable(lines, true);
standardTablesCache[number] = table;
return table;
}
class Reader {
constructor(data, start, end) {
this.data = data;
this.start = start;
this.end = end;
this.position = start;
this.shift = -1;
this.currentByte = 0;
}
readBit() {
if (this.shift < 0) {
if (this.position >= this.end) {
throw new Jbig2Error("end of data while reading bit");
}
this.currentByte = this.data[this.position++];
this.shift = 7;
}
const bit = this.currentByte >> this.shift & 1;
this.shift--;
return bit;
}
readBits(numBits) {
let result = 0,
i;
for (i = numBits - 1; i >= 0; i--) {
result |= this.readBit() << i;
}
return result;
}
byteAlign() {
this.shift = -1;
}
next() {
if (this.position >= this.end) {
return -1;
}
return this.data[this.position++];
}
}
function getCustomHuffmanTable(index, referredTo, customTables) {
let currentIndex = 0;
for (let i = 0, ii = referredTo.length; i < ii; i++) {
const table = customTables[referredTo[i]];
if (table) {
if (index === currentIndex) {
return table;
}
currentIndex++;
}
}
throw new Jbig2Error("can't find custom Huffman table");
}
function getTextRegionHuffmanTables(textRegion, referredTo, customTables, numberOfSymbols, reader) {
const codes = [];
for (let i = 0; i <= 34; i++) {
const codeLength = reader.readBits(4);
codes.push(new HuffmanLine([i, codeLength, 0, 0]));
}
const runCodesTable = new HuffmanTable(codes, false);
codes.length = 0;
for (let i = 0; i < numberOfSymbols;) {
const codeLength = runCodesTable.decode(reader);
if (codeLength >= 32) {
let repeatedLength, numberOfRepeats, j;
switch (codeLength) {
case 32:
if (i === 0) {
throw new Jbig2Error("no previous value in symbol ID table");
}
numberOfRepeats = reader.readBits(2) + 3;
repeatedLength = codes[i - 1].prefixLength;
break;
case 33:
numberOfRepeats = reader.readBits(3) + 3;
repeatedLength = 0;
break;
case 34:
numberOfRepeats = reader.readBits(7) + 11;
repeatedLength = 0;
break;
default:
throw new Jbig2Error("invalid code length in symbol ID table");
}
for (j = 0; j < numberOfRepeats; j++) {
codes.push(new HuffmanLine([i, repeatedLength, 0, 0]));
i++;
}
} else {
codes.push(new HuffmanLine([i, codeLength, 0, 0]));
i++;
}
}
reader.byteAlign();
const symbolIDTable = new HuffmanTable(codes, false);
let customIndex = 0,
tableFirstS,
tableDeltaS,
tableDeltaT;
switch (textRegion.huffmanFS) {
case 0:
case 1:
tableFirstS = getStandardTable(textRegion.huffmanFS + 6);
break;
case 3:
tableFirstS = getCustomHuffmanTable(customIndex, referredTo, customTables);
customIndex++;
break;
default:
throw new Jbig2Error("invalid Huffman FS selector");
}
switch (textRegion.huffmanDS) {
case 0:
case 1:
case 2:
tableDeltaS = getStandardTable(textRegion.huffmanDS + 8);
break;
case 3:
tableDeltaS = getCustomHuffmanTable(customIndex, referredTo, customTables);
customIndex++;
break;
default:
throw new Jbig2Error("invalid Huffman DS selector");
}
switch (textRegion.huffmanDT) {
case 0:
case 1:
case 2:
tableDeltaT = getStandardTable(textRegion.huffmanDT + 11);
break;
case 3:
tableDeltaT = getCustomHuffmanTable(customIndex, referredTo, customTables);
customIndex++;
break;
default:
throw new Jbig2Error("invalid Huffman DT selector");
}
if (textRegion.refinement) {
throw new Jbig2Error("refinement with Huffman is not supported");
}
return {
symbolIDTable,
tableFirstS,
tableDeltaS,
tableDeltaT
};
}
function getSymbolDictionaryHuffmanTables(dictionary, referredTo, customTables) {
let customIndex = 0,
tableDeltaHeight,
tableDeltaWidth;
switch (dictionary.huffmanDHSelector) {
case 0:
case 1:
tableDeltaHeight = getStandardTable(dictionary.huffmanDHSelector + 4);
break;
case 3:
tableDeltaHeight = getCustomHuffmanTable(customIndex, referredTo, customTables);
customIndex++;
break;
default:
throw new Jbig2Error("invalid Huffman DH selector");
}
switch (dictionary.huffmanDWSelector) {
case 0:
case 1:
tableDeltaWidth = getStandardTable(dictionary.huffmanDWSelector + 2);
break;
case 3:
tableDeltaWidth = getCustomHuffmanTable(customIndex, referredTo, customTables);
customIndex++;
break;
default:
throw new Jbig2Error("invalid Huffman DW selector");
}
let tableBitmapSize, tableAggregateInstances;
if (dictionary.bitmapSizeSelector) {
tableBitmapSize = getCustomHuffmanTable(customIndex, referredTo, customTables);
customIndex++;
} else {
tableBitmapSize = getStandardTable(1);
}
if (dictionary.aggregationInstancesSelector) {
tableAggregateInstances = getCustomHuffmanTable(customIndex, referredTo, customTables);
} else {
tableAggregateInstances = getStandardTable(1);
}
return {
tableDeltaHeight,
tableDeltaWidth,
tableBitmapSize,
tableAggregateInstances
};
}
function readUncompressedBitmap(reader, width, height) {
const bitmap = [];
for (let y = 0; y < height; y++) {
const row = new Uint8Array(width);
bitmap.push(row);
for (let x = 0; x < width; x++) {
row[x] = reader.readBit();
}
reader.byteAlign();
}
return bitmap;
}
function decodeMMRBitmap(input, width, height, endOfBlock) {
const params = {
K: -1,
Columns: width,
Rows: height,
BlackIs1: true,
EndOfBlock: endOfBlock
};
const decoder = new CCITTFaxDecoder(input, params);
const bitmap = [];
let currentByte,
eof = false;
for (let y = 0; y < height; y++) {
const row = new Uint8Array(width);
bitmap.push(row);
let shift = -1;
for (let x = 0; x < width; x++) {
if (shift < 0) {
currentByte = decoder.readNextChar();
if (currentByte === -1) {
currentByte = 0;
eof = true;
}
shift = 7;
}
row[x] = currentByte >> shift & 1;
shift--;
}
}
if (endOfBlock && !eof) {
const lookForEOFLimit = 5;
for (let i = 0; i < lookForEOFLimit; i++) {
if (decoder.readNextChar() === -1) {
break;
}
}
}
return bitmap;
}
class Jbig2Image {
parseChunks(chunks) {
return parseJbig2Chunks(chunks);
}
parse(data) {
const {
imgData,
width,
height
} = parseJbig2(data);
this.width = width;
this.height = height;
return imgData;
}
}
;// ./src/core/colorspace.js
function resizeRgbImage(src, dest, w1, h1, w2, h2, alpha01) {
const COMPONENTS = 3;
alpha01 = alpha01 !== 1 ? 0 : alpha01;
const xRatio = w1 / w2;
const yRatio = h1 / h2;
let newIndex = 0,
oldIndex;
const xScaled = new Uint16Array(w2);
const w1Scanline = w1 * COMPONENTS;
for (let i = 0; i < w2; i++) {
xScaled[i] = Math.floor(i * xRatio) * COMPONENTS;
}
for (let i = 0; i < h2; i++) {
const py = Math.floor(i * yRatio) * w1Scanline;
for (let j = 0; j < w2; j++) {
oldIndex = py + xScaled[j];
dest[newIndex++] = src[oldIndex++];
dest[newIndex++] = src[oldIndex++];
dest[newIndex++] = src[oldIndex++];
newIndex += alpha01;
}
}
}
function resizeRgbaImage(src, dest, w1, h1, w2, h2, alpha01) {
const xRatio = w1 / w2;
const yRatio = h1 / h2;
let newIndex = 0;
const xScaled = new Uint16Array(w2);
if (alpha01 === 1) {
for (let i = 0; i < w2; i++) {
xScaled[i] = Math.floor(i * xRatio);
}
const src32 = new Uint32Array(src.buffer);
const dest32 = new Uint32Array(dest.buffer);
const rgbMask = util_FeatureTest.isLittleEndian ? 0x00ffffff : 0xffffff00;
for (let i = 0; i < h2; i++) {
const buf = src32.subarray(Math.floor(i * yRatio) * w1);
for (let j = 0; j < w2; j++) {
dest32[newIndex++] |= buf[xScaled[j]] & rgbMask;
}
}
} else {
const COMPONENTS = 4;
const w1Scanline = w1 * COMPONENTS;
for (let i = 0; i < w2; i++) {
xScaled[i] = Math.floor(i * xRatio) * COMPONENTS;
}
for (let i = 0; i < h2; i++) {
const buf = src.subarray(Math.floor(i * yRatio) * w1Scanline);
for (let j = 0; j < w2; j++) {
const oldIndex = xScaled[j];
dest[newIndex++] = buf[oldIndex];
dest[newIndex++] = buf[oldIndex + 1];
dest[newIndex++] = buf[oldIndex + 2];
}
}
}
}
function copyRgbaImage(src, dest, alpha01) {
if (alpha01 === 1) {
const src32 = new Uint32Array(src.buffer);
const dest32 = new Uint32Array(dest.buffer);
const rgbMask = util_FeatureTest.isLittleEndian ? 0x00ffffff : 0xffffff00;
for (let i = 0, ii = src32.length; i < ii; i++) {
dest32[i] |= src32[i] & rgbMask;
}
} else {
let j = 0;
for (let i = 0, ii = src.length; i < ii; i += 4) {
dest[j++] = src[i];
dest[j++] = src[i + 1];
dest[j++] = src[i + 2];
}
}
}
class ColorSpace {
static #rgbBuf = new Uint8ClampedArray(3);
constructor(name, numComps) {
this.name = name;
this.numComps = numComps;
}
getRgb(src, srcOffset, output = new Uint8ClampedArray(3)) {
this.getRgbItem(src, srcOffset, output, 0);
return output;
}
getRgbHex(src, srcOffset) {
const buffer = this.getRgb(src, srcOffset, ColorSpace.#rgbBuf);
return util_Util.makeHexColor(buffer[0], buffer[1], buffer[2]);
}
getRgbItem(src, srcOffset, dest, destOffset) {
unreachable("Should not call ColorSpace.getRgbItem");
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
unreachable("Should not call ColorSpace.getRgbBuffer");
}
getOutputLength(inputLength, alpha01) {
unreachable("Should not call ColorSpace.getOutputLength");
}
isPassthrough(bits) {
return false;
}
isDefaultDecode(decodeMap, bpc) {
return ColorSpace.isDefaultDecode(decodeMap, this.numComps);
}
fillRgb(dest, originalWidth, originalHeight, width, height, actualHeight, bpc, comps, alpha01) {
const count = originalWidth * originalHeight;
let rgbBuf = null;
const numComponentColors = 1 << bpc;
const needsResizing = originalHeight !== height || originalWidth !== width;
if (this.isPassthrough(bpc)) {
rgbBuf = comps;
} else if (this.numComps === 1 && count > numComponentColors && this.name !== "DeviceGray" && this.name !== "DeviceRGB") {
const allColors = bpc <= 8 ? new Uint8Array(numComponentColors) : new Uint16Array(numComponentColors);
for (let i = 0; i < numComponentColors; i++) {
allColors[i] = i;
}
const colorMap = new Uint8ClampedArray(numComponentColors * 3);
this.getRgbBuffer(allColors, 0, numComponentColors, colorMap, 0, bpc, 0);
if (!needsResizing) {
let destPos = 0;
for (let i = 0; i < count; ++i) {
const key = comps[i] * 3;
dest[destPos++] = colorMap[key];
dest[destPos++] = colorMap[key + 1];
dest[destPos++] = colorMap[key + 2];
destPos += alpha01;
}
} else {
rgbBuf = new Uint8Array(count * 3);
let rgbPos = 0;
for (let i = 0; i < count; ++i) {
const key = comps[i] * 3;
rgbBuf[rgbPos++] = colorMap[key];
rgbBuf[rgbPos++] = colorMap[key + 1];
rgbBuf[rgbPos++] = colorMap[key + 2];
}
}
} else if (!needsResizing) {
this.getRgbBuffer(comps, 0, width * actualHeight, dest, 0, bpc, alpha01);
} else {
rgbBuf = new Uint8ClampedArray(count * 3);
this.getRgbBuffer(comps, 0, count, rgbBuf, 0, bpc, 0);
}
if (rgbBuf) {
if (needsResizing) {
resizeRgbImage(rgbBuf, dest, originalWidth, originalHeight, width, height, alpha01);
} else {
let destPos = 0,
rgbPos = 0;
for (let i = 0, ii = width * actualHeight; i < ii; i++) {
dest[destPos++] = rgbBuf[rgbPos++];
dest[destPos++] = rgbBuf[rgbPos++];
dest[destPos++] = rgbBuf[rgbPos++];
destPos += alpha01;
}
}
}
}
get usesZeroToOneRange() {
return shadow(this, "usesZeroToOneRange", true);
}
static isDefaultDecode(decode, numComps) {
if (!Array.isArray(decode)) {
return true;
}
if (numComps * 2 !== decode.length) {
util_warn("The decode map is not the correct length");
return true;
}
for (let i = 0, ii = decode.length; i < ii; i += 2) {
if (decode[i] !== 0 || decode[i + 1] !== 1) {
return false;
}
}
return true;
}
}
class AlternateCS extends ColorSpace {
constructor(numComps, base, tintFn) {
super("Alternate", numComps);
this.base = base;
this.tintFn = tintFn;
this.tmpBuf = new Float32Array(base.numComps);
}
getRgbItem(src, srcOffset, dest, destOffset) {
const tmpBuf = this.tmpBuf;
this.tintFn(src, srcOffset, tmpBuf, 0);
this.base.getRgbItem(tmpBuf, 0, dest, destOffset);
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
const tintFn = this.tintFn;
const base = this.base;
const scale = 1 / ((1 << bits) - 1);
const baseNumComps = base.numComps;
const usesZeroToOneRange = base.usesZeroToOneRange;
const isPassthrough = (base.isPassthrough(8) || !usesZeroToOneRange) && alpha01 === 0;
let pos = isPassthrough ? destOffset : 0;
const baseBuf = isPassthrough ? dest : new Uint8ClampedArray(baseNumComps * count);
const numComps = this.numComps;
const scaled = new Float32Array(numComps);
const tinted = new Float32Array(baseNumComps);
let i, j;
for (i = 0; i < count; i++) {
for (j = 0; j < numComps; j++) {
scaled[j] = src[srcOffset++] * scale;
}
tintFn(scaled, 0, tinted, 0);
if (usesZeroToOneRange) {
for (j = 0; j < baseNumComps; j++) {
baseBuf[pos++] = tinted[j] * 255;
}
} else {
base.getRgbItem(tinted, 0, baseBuf, pos);
pos += baseNumComps;
}
}
if (!isPassthrough) {
base.getRgbBuffer(baseBuf, 0, count, dest, destOffset, 8, alpha01);
}
}
getOutputLength(inputLength, alpha01) {
return this.base.getOutputLength(inputLength * this.base.numComps / this.numComps, alpha01);
}
}
class PatternCS extends ColorSpace {
constructor(baseCS) {
super("Pattern", null);
this.base = baseCS;
}
isDefaultDecode(decodeMap, bpc) {
unreachable("Should not call PatternCS.isDefaultDecode");
}
}
class IndexedCS extends ColorSpace {
constructor(base, highVal, lookup) {
super("Indexed", 1);
this.base = base;
this.highVal = highVal;
const length = base.numComps * (highVal + 1);
this.lookup = new Uint8Array(length);
if (lookup instanceof base_stream_BaseStream) {
const bytes = lookup.getBytes(length);
this.lookup.set(bytes);
} else if (typeof lookup === "string") {
for (let i = 0; i < length; ++i) {
this.lookup[i] = lookup.charCodeAt(i) & 0xff;
}
} else {
throw new FormatError(`IndexedCS - unrecognized lookup table: ${lookup}`);
}
}
getRgbItem(src, srcOffset, dest, destOffset) {
const {
base,
highVal,
lookup
} = this;
const start = MathClamp(Math.round(src[srcOffset]), 0, highVal) * base.numComps;
base.getRgbBuffer(lookup, start, 1, dest, destOffset, 8, 0);
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
const {
base,
highVal,
lookup
} = this;
const {
numComps
} = base;
const outputDelta = base.getOutputLength(numComps, alpha01);
for (let i = 0; i < count; ++i) {
const lookupPos = MathClamp(Math.round(src[srcOffset++]), 0, highVal) * numComps;
base.getRgbBuffer(lookup, lookupPos, 1, dest, destOffset, 8, alpha01);
destOffset += outputDelta;
}
}
getOutputLength(inputLength, alpha01) {
return this.base.getOutputLength(inputLength * this.base.numComps, alpha01);
}
isDefaultDecode(decodeMap, bpc) {
if (!Array.isArray(decodeMap)) {
return true;
}
if (decodeMap.length !== 2) {
util_warn("Decode map length is not correct");
return true;
}
if (!Number.isInteger(bpc) || bpc < 1) {
util_warn("Bits per component is not correct");
return true;
}
return decodeMap[0] === 0 && decodeMap[1] === (1 << bpc) - 1;
}
}
class DeviceGrayCS extends ColorSpace {
constructor() {
super("DeviceGray", 1);
}
getRgbItem(src, srcOffset, dest, destOffset) {
const c = src[srcOffset] * 255;
dest[destOffset] = dest[destOffset + 1] = dest[destOffset + 2] = c;
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
const scale = 255 / ((1 << bits) - 1);
let j = srcOffset,
q = destOffset;
for (let i = 0; i < count; ++i) {
const c = scale * src[j++];
dest[q++] = c;
dest[q++] = c;
dest[q++] = c;
q += alpha01;
}
}
getOutputLength(inputLength, alpha01) {
return inputLength * (3 + alpha01);
}
}
class DeviceRgbCS extends ColorSpace {
constructor() {
super("DeviceRGB", 3);
}
getRgbItem(src, srcOffset, dest, destOffset) {
dest[destOffset] = src[srcOffset] * 255;
dest[destOffset + 1] = src[srcOffset + 1] * 255;
dest[destOffset + 2] = src[srcOffset + 2] * 255;
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
if (bits === 8 && alpha01 === 0) {
dest.set(src.subarray(srcOffset, srcOffset + count * 3), destOffset);
return;
}
const scale = 255 / ((1 << bits) - 1);
let j = srcOffset,
q = destOffset;
for (let i = 0; i < count; ++i) {
dest[q++] = scale * src[j++];
dest[q++] = scale * src[j++];
dest[q++] = scale * src[j++];
q += alpha01;
}
}
getOutputLength(inputLength, alpha01) {
return inputLength * (3 + alpha01) / 3 | 0;
}
isPassthrough(bits) {
return bits === 8;
}
}
class DeviceRgbaCS extends ColorSpace {
constructor() {
super("DeviceRGBA", 4);
}
getOutputLength(inputLength, _alpha01) {
return inputLength * 4;
}
isPassthrough(bits) {
return bits === 8;
}
fillRgb(dest, originalWidth, originalHeight, width, height, actualHeight, bpc, comps, alpha01) {
if (originalHeight !== height || originalWidth !== width) {
resizeRgbaImage(comps, dest, originalWidth, originalHeight, width, height, alpha01);
} else {
copyRgbaImage(comps, dest, alpha01);
}
}
}
class DeviceCmykCS extends ColorSpace {
constructor() {
super("DeviceCMYK", 4);
}
#toRgb(src, srcOffset, srcScale, dest, destOffset) {
const c = src[srcOffset] * srcScale;
const m = src[srcOffset + 1] * srcScale;
const y = src[srcOffset + 2] * srcScale;
const k = src[srcOffset + 3] * srcScale;
dest[destOffset] = 255 + c * (-4.387332384609988 * c + 54.48615194189176 * m + 18.82290502165302 * y + 212.25662451639585 * k + -285.2331026137004) + m * (1.7149763477362134 * m - 5.6096736904047315 * y + -17.873870861415444 * k - 5.497006427196366) + y * (-2.5217340131683033 * y - 21.248923337353073 * k + 17.5119270841813) + k * (-21.86122147463605 * k - 189.48180835922747);
dest[destOffset + 1] = 255 + c * (8.841041422036149 * c + 60.118027045597366 * m + 6.871425592049007 * y + 31.159100130055922 * k + -79.2970844816548) + m * (-15.310361306967817 * m + 17.575251261109482 * y + 131.35250912493976 * k - 190.9453302588951) + y * (4.444339102852739 * y + 9.8632861493405 * k - 24.86741582555878) + k * (-20.737325471181034 * k - 187.80453709719578);
dest[destOffset + 2] = 255 + c * (0.8842522430003296 * c + 8.078677503112928 * m + 30.89978309703729 * y - 0.23883238689178934 * k + -14.183576799673286) + m * (10.49593273432072 * m + 63.02378494754052 * y + 50.606957656360734 * k - 112.23884253719248) + y * (0.03296041114873217 * y + 115.60384449646641 * k + -193.58209356861505) + k * (-22.33816807309886 * k - 180.12613974708367);
}
getRgbItem(src, srcOffset, dest, destOffset) {
this.#toRgb(src, srcOffset, 1, dest, destOffset);
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
const scale = 1 / ((1 << bits) - 1);
for (let i = 0; i < count; i++) {
this.#toRgb(src, srcOffset, scale, dest, destOffset);
srcOffset += 4;
destOffset += 3 + alpha01;
}
}
getOutputLength(inputLength, alpha01) {
return inputLength / 4 * (3 + alpha01) | 0;
}
}
class CalGrayCS extends ColorSpace {
constructor(whitePoint, blackPoint, gamma) {
super("CalGray", 1);
if (!whitePoint) {
throw new FormatError("WhitePoint missing - required for color space CalGray");
}
[this.XW, this.YW, this.ZW] = whitePoint;
[this.XB, this.YB, this.ZB] = blackPoint || [0, 0, 0];
this.G = gamma || 1;
if (this.XW < 0 || this.ZW < 0 || this.YW !== 1) {
throw new FormatError(`Invalid WhitePoint components for ${this.name}, no fallback available`);
}
if (this.XB < 0 || this.YB < 0 || this.ZB < 0) {
info(`Invalid BlackPoint for ${this.name}, falling back to default.`);
this.XB = this.YB = this.ZB = 0;
}
if (this.XB !== 0 || this.YB !== 0 || this.ZB !== 0) {
util_warn(`${this.name}, BlackPoint: XB: ${this.XB}, YB: ${this.YB}, ` + `ZB: ${this.ZB}, only default values are supported.`);
}
if (this.G < 1) {
info(`Invalid Gamma: ${this.G} for ${this.name}, falling back to default.`);
this.G = 1;
}
}
#toRgb(src, srcOffset, dest, destOffset, scale) {
const A = src[srcOffset] * scale;
const AG = A ** this.G;
const L = this.YW * AG;
const val = Math.max(295.8 * L ** 0.3333333333333333 - 40.8, 0);
dest[destOffset] = val;
dest[destOffset + 1] = val;
dest[destOffset + 2] = val;
}
getRgbItem(src, srcOffset, dest, destOffset) {
this.#toRgb(src, srcOffset, dest, destOffset, 1);
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
const scale = 1 / ((1 << bits) - 1);
for (let i = 0; i < count; ++i) {
this.#toRgb(src, srcOffset, dest, destOffset, scale);
srcOffset += 1;
destOffset += 3 + alpha01;
}
}
getOutputLength(inputLength, alpha01) {
return inputLength * (3 + alpha01);
}
}
class CalRGBCS extends ColorSpace {
static #BRADFORD_SCALE_MATRIX = new Float32Array([0.8951, 0.2664, -0.1614, -0.7502, 1.7135, 0.0367, 0.0389, -0.0685, 1.0296]);
static #BRADFORD_SCALE_INVERSE_MATRIX = new Float32Array([0.9869929, -0.1470543, 0.1599627, 0.4323053, 0.5183603, 0.0492912, -0.0085287, 0.0400428, 0.9684867]);
static #SRGB_D65_XYZ_TO_RGB_MATRIX = new Float32Array([3.2404542, -1.5371385, -0.4985314, -0.9692660, 1.8760108, 0.0415560, 0.0556434, -0.2040259, 1.0572252]);
static #FLAT_WHITEPOINT_MATRIX = new Float32Array([1, 1, 1]);
static #tempNormalizeMatrix = new Float32Array(3);
static #tempConvertMatrix1 = new Float32Array(3);
static #tempConvertMatrix2 = new Float32Array(3);
static #DECODE_L_CONSTANT = ((8 + 16) / 116) ** 3 / 8.0;
constructor(whitePoint, blackPoint, gamma, matrix) {
super("CalRGB", 3);
if (!whitePoint) {
throw new FormatError("WhitePoint missing - required for color space CalRGB");
}
const [XW, YW, ZW] = this.whitePoint = whitePoint;
const [XB, YB, ZB] = this.blackPoint = blackPoint || new Float32Array(3);
[this.GR, this.GG, this.GB] = gamma || new Float32Array([1, 1, 1]);
[this.MXA, this.MYA, this.MZA, this.MXB, this.MYB, this.MZB, this.MXC, this.MYC, this.MZC] = matrix || new Float32Array([1, 0, 0, 0, 1, 0, 0, 0, 1]);
if (XW < 0 || ZW < 0 || YW !== 1) {
throw new FormatError(`Invalid WhitePoint components for ${this.name}, no fallback available`);
}
if (XB < 0 || YB < 0 || ZB < 0) {
info(`Invalid BlackPoint for ${this.name} [${XB}, ${YB}, ${ZB}], ` + "falling back to default.");
this.blackPoint = new Float32Array(3);
}
if (this.GR < 0 || this.GG < 0 || this.GB < 0) {
info(`Invalid Gamma [${this.GR}, ${this.GG}, ${this.GB}] for ` + `${this.name}, falling back to default.`);
this.GR = this.GG = this.GB = 1;
}
}
#matrixProduct(a, b, result) {
result[0] = a[0] * b[0] + a[1] * b[1] + a[2] * b[2];
result[1] = a[3] * b[0] + a[4] * b[1] + a[5] * b[2];
result[2] = a[6] * b[0] + a[7] * b[1] + a[8] * b[2];
}
#toFlat(sourceWhitePoint, LMS, result) {
result[0] = LMS[0] * 1 / sourceWhitePoint[0];
result[1] = LMS[1] * 1 / sourceWhitePoint[1];
result[2] = LMS[2] * 1 / sourceWhitePoint[2];
}
#toD65(sourceWhitePoint, LMS, result) {
const D65X = 0.95047;
const D65Y = 1;
const D65Z = 1.08883;
result[0] = LMS[0] * D65X / sourceWhitePoint[0];
result[1] = LMS[1] * D65Y / sourceWhitePoint[1];
result[2] = LMS[2] * D65Z / sourceWhitePoint[2];
}
#sRGBTransferFunction(color) {
if (color <= 0.0031308) {
return MathClamp(12.92 * color, 0, 1);
}
if (color >= 0.99554525) {
return 1;
}
return MathClamp((1 + 0.055) * color ** (1 / 2.4) - 0.055, 0, 1);
}
#decodeL(L) {
if (L < 0) {
return -this.#decodeL(-L);
}
if (L > 8.0) {
return ((L + 16) / 116) ** 3;
}
return L * CalRGBCS.#DECODE_L_CONSTANT;
}
#compensateBlackPoint(sourceBlackPoint, XYZ_Flat, result) {
if (sourceBlackPoint[0] === 0 && sourceBlackPoint[1] === 0 && sourceBlackPoint[2] === 0) {
result[0] = XYZ_Flat[0];
result[1] = XYZ_Flat[1];
result[2] = XYZ_Flat[2];
return;
}
const zeroDecodeL = this.#decodeL(0);
const X_DST = zeroDecodeL;
const X_SRC = this.#decodeL(sourceBlackPoint[0]);
const Y_DST = zeroDecodeL;
const Y_SRC = this.#decodeL(sourceBlackPoint[1]);
const Z_DST = zeroDecodeL;
const Z_SRC = this.#decodeL(sourceBlackPoint[2]);
const X_Scale = (1 - X_DST) / (1 - X_SRC);
const X_Offset = 1 - X_Scale;
const Y_Scale = (1 - Y_DST) / (1 - Y_SRC);
const Y_Offset = 1 - Y_Scale;
const Z_Scale = (1 - Z_DST) / (1 - Z_SRC);
const Z_Offset = 1 - Z_Scale;
result[0] = XYZ_Flat[0] * X_Scale + X_Offset;
result[1] = XYZ_Flat[1] * Y_Scale + Y_Offset;
result[2] = XYZ_Flat[2] * Z_Scale + Z_Offset;
}
#normalizeWhitePointToFlat(sourceWhitePoint, XYZ_In, result) {
if (sourceWhitePoint[0] === 1 && sourceWhitePoint[2] === 1) {
result[0] = XYZ_In[0];
result[1] = XYZ_In[1];
result[2] = XYZ_In[2];
return;
}
const LMS = result;
this.#matrixProduct(CalRGBCS.#BRADFORD_SCALE_MATRIX, XYZ_In, LMS);
const LMS_Flat = CalRGBCS.#tempNormalizeMatrix;
this.#toFlat(sourceWhitePoint, LMS, LMS_Flat);
this.#matrixProduct(CalRGBCS.#BRADFORD_SCALE_INVERSE_MATRIX, LMS_Flat, result);
}
#normalizeWhitePointToD65(sourceWhitePoint, XYZ_In, result) {
const LMS = result;
this.#matrixProduct(CalRGBCS.#BRADFORD_SCALE_MATRIX, XYZ_In, LMS);
const LMS_D65 = CalRGBCS.#tempNormalizeMatrix;
this.#toD65(sourceWhitePoint, LMS, LMS_D65);
this.#matrixProduct(CalRGBCS.#BRADFORD_SCALE_INVERSE_MATRIX, LMS_D65, result);
}
#toRgb(src, srcOffset, dest, destOffset, scale) {
const A = MathClamp(src[srcOffset] * scale, 0, 1);
const B = MathClamp(src[srcOffset + 1] * scale, 0, 1);
const C = MathClamp(src[srcOffset + 2] * scale, 0, 1);
const AGR = A === 1 ? 1 : A ** this.GR;
const BGG = B === 1 ? 1 : B ** this.GG;
const CGB = C === 1 ? 1 : C ** this.GB;
const X = this.MXA * AGR + this.MXB * BGG + this.MXC * CGB;
const Y = this.MYA * AGR + this.MYB * BGG + this.MYC * CGB;
const Z = this.MZA * AGR + this.MZB * BGG + this.MZC * CGB;
const XYZ = CalRGBCS.#tempConvertMatrix1;
XYZ[0] = X;
XYZ[1] = Y;
XYZ[2] = Z;
const XYZ_Flat = CalRGBCS.#tempConvertMatrix2;
this.#normalizeWhitePointToFlat(this.whitePoint, XYZ, XYZ_Flat);
const XYZ_Black = CalRGBCS.#tempConvertMatrix1;
this.#compensateBlackPoint(this.blackPoint, XYZ_Flat, XYZ_Black);
const XYZ_D65 = CalRGBCS.#tempConvertMatrix2;
this.#normalizeWhitePointToD65(CalRGBCS.#FLAT_WHITEPOINT_MATRIX, XYZ_Black, XYZ_D65);
const SRGB = CalRGBCS.#tempConvertMatrix1;
this.#matrixProduct(CalRGBCS.#SRGB_D65_XYZ_TO_RGB_MATRIX, XYZ_D65, SRGB);
dest[destOffset] = this.#sRGBTransferFunction(SRGB[0]) * 255;
dest[destOffset + 1] = this.#sRGBTransferFunction(SRGB[1]) * 255;
dest[destOffset + 2] = this.#sRGBTransferFunction(SRGB[2]) * 255;
}
getRgbItem(src, srcOffset, dest, destOffset) {
this.#toRgb(src, srcOffset, dest, destOffset, 1);
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
const scale = 1 / ((1 << bits) - 1);
for (let i = 0; i < count; ++i) {
this.#toRgb(src, srcOffset, dest, destOffset, scale);
srcOffset += 3;
destOffset += 3 + alpha01;
}
}
getOutputLength(inputLength, alpha01) {
return inputLength * (3 + alpha01) / 3 | 0;
}
}
class LabCS extends ColorSpace {
constructor(whitePoint, blackPoint, range) {
super("Lab", 3);
if (!whitePoint) {
throw new FormatError("WhitePoint missing - required for color space Lab");
}
[this.XW, this.YW, this.ZW] = whitePoint;
[this.amin, this.amax, this.bmin, this.bmax] = range || [-100, 100, -100, 100];
[this.XB, this.YB, this.ZB] = blackPoint || [0, 0, 0];
if (this.XW < 0 || this.ZW < 0 || this.YW !== 1) {
throw new FormatError("Invalid WhitePoint components, no fallback available");
}
if (this.XB < 0 || this.YB < 0 || this.ZB < 0) {
info("Invalid BlackPoint, falling back to default");
this.XB = this.YB = this.ZB = 0;
}
if (this.amin > this.amax || this.bmin > this.bmax) {
info("Invalid Range, falling back to defaults");
this.amin = -100;
this.amax = 100;
this.bmin = -100;
this.bmax = 100;
}
}
#fn_g(x) {
return x >= 6 / 29 ? x ** 3 : 108 / 841 * (x - 4 / 29);
}
#decode(value, high1, low2, high2) {
return low2 + value * (high2 - low2) / high1;
}
#toRgb(src, srcOffset, maxVal, dest, destOffset) {
let Ls = src[srcOffset];
let as = src[srcOffset + 1];
let bs = src[srcOffset + 2];
if (maxVal !== false) {
Ls = this.#decode(Ls, maxVal, 0, 100);
as = this.#decode(as, maxVal, this.amin, this.amax);
bs = this.#decode(bs, maxVal, this.bmin, this.bmax);
}
if (as > this.amax) {
as = this.amax;
} else if (as < this.amin) {
as = this.amin;
}
if (bs > this.bmax) {
bs = this.bmax;
} else if (bs < this.bmin) {
bs = this.bmin;
}
const M = (Ls + 16) / 116;
const L = M + as / 500;
const N = M - bs / 200;
const X = this.XW * this.#fn_g(L);
const Y = this.YW * this.#fn_g(M);
const Z = this.ZW * this.#fn_g(N);
let r, g, b;
if (this.ZW < 1) {
r = X * 3.1339 + Y * -1.617 + Z * -0.4906;
g = X * -0.9785 + Y * 1.916 + Z * 0.0333;
b = X * 0.072 + Y * -0.229 + Z * 1.4057;
} else {
r = X * 3.2406 + Y * -1.5372 + Z * -0.4986;
g = X * -0.9689 + Y * 1.8758 + Z * 0.0415;
b = X * 0.0557 + Y * -0.204 + Z * 1.057;
}
dest[destOffset] = Math.sqrt(r) * 255;
dest[destOffset + 1] = Math.sqrt(g) * 255;
dest[destOffset + 2] = Math.sqrt(b) * 255;
}
getRgbItem(src, srcOffset, dest, destOffset) {
this.#toRgb(src, srcOffset, false, dest, destOffset);
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
const maxVal = (1 << bits) - 1;
for (let i = 0; i < count; i++) {
this.#toRgb(src, srcOffset, maxVal, dest, destOffset);
srcOffset += 3;
destOffset += 3 + alpha01;
}
}
getOutputLength(inputLength, alpha01) {
return inputLength * (3 + alpha01) / 3 | 0;
}
isDefaultDecode(decodeMap, bpc) {
return true;
}
get usesZeroToOneRange() {
return shadow(this, "usesZeroToOneRange", false);
}
}
;// ./external/qcms/qcms_utils.js
class QCMS {
static #memoryArray = null;
static _memory = null;
static _mustAddAlpha = false;
static _destBuffer = null;
static _destOffset = 0;
static _destLength = 0;
static _cssColor = "";
static _makeHexColor = null;
static get _memoryArray() {
const array = this.#memoryArray;
if (array?.byteLength) {
return array;
}
return this.#memoryArray = new Uint8Array(this._memory.buffer);
}
}
function copy_result(ptr, len) {
const {
_mustAddAlpha,
_destBuffer,
_destOffset,
_destLength,
_memoryArray
} = QCMS;
if (len === _destLength) {
_destBuffer.set(_memoryArray.subarray(ptr, ptr + len), _destOffset);
return;
}
if (_mustAddAlpha) {
for (let i = ptr, ii = ptr + len, j = _destOffset; i < ii; i += 3, j += 4) {
_destBuffer[j] = _memoryArray[i];
_destBuffer[j + 1] = _memoryArray[i + 1];
_destBuffer[j + 2] = _memoryArray[i + 2];
_destBuffer[j + 3] = 255;
}
} else {
for (let i = ptr, ii = ptr + len, j = _destOffset; i < ii; i += 3, j += 4) {
_destBuffer[j] = _memoryArray[i];
_destBuffer[j + 1] = _memoryArray[i + 1];
_destBuffer[j + 2] = _memoryArray[i + 2];
}
}
}
function copy_rgb(ptr) {
const {
_destBuffer,
_destOffset,
_memoryArray
} = QCMS;
_destBuffer[_destOffset] = _memoryArray[ptr];
_destBuffer[_destOffset + 1] = _memoryArray[ptr + 1];
_destBuffer[_destOffset + 2] = _memoryArray[ptr + 2];
}
function make_cssRGB(ptr) {
const {
_memoryArray
} = QCMS;
QCMS._cssColor = QCMS._makeHexColor(_memoryArray[ptr], _memoryArray[ptr + 1], _memoryArray[ptr + 2]);
}
;// ./external/qcms/qcms.js
let wasm;
const cachedTextDecoder = typeof TextDecoder !== 'undefined' ? new TextDecoder('utf-8', {
ignoreBOM: true,
fatal: true
}) : {
decode: () => {
throw Error('TextDecoder not available');
}
};
if (typeof TextDecoder !== 'undefined') {
cachedTextDecoder.decode();
}
;
let cachedUint8ArrayMemory0 = null;
function getUint8ArrayMemory0() {
if (cachedUint8ArrayMemory0 === null || cachedUint8ArrayMemory0.byteLength === 0) {
cachedUint8ArrayMemory0 = new Uint8Array(wasm.memory.buffer);
}
return cachedUint8ArrayMemory0;
}
function getStringFromWasm0(ptr, len) {
ptr = ptr >>> 0;
return cachedTextDecoder.decode(getUint8ArrayMemory0().subarray(ptr, ptr + len));
}
let WASM_VECTOR_LEN = 0;
function passArray8ToWasm0(arg, malloc) {
const ptr = malloc(arg.length * 1, 1) >>> 0;
getUint8ArrayMemory0().set(arg, ptr / 1);
WASM_VECTOR_LEN = arg.length;
return ptr;
}
function qcms_convert_array(transformer, src) {
const ptr0 = passArray8ToWasm0(src, wasm.__wbindgen_malloc);
const len0 = WASM_VECTOR_LEN;
wasm.qcms_convert_array(transformer, ptr0, len0);
}
function qcms_convert_one(transformer, src, css) {
wasm.qcms_convert_one(transformer, src, css);
}
function qcms_convert_three(transformer, src1, src2, src3, css) {
wasm.qcms_convert_three(transformer, src1, src2, src3, css);
}
function qcms_convert_four(transformer, src1, src2, src3, src4, css) {
wasm.qcms_convert_four(transformer, src1, src2, src3, src4, css);
}
function qcms_transformer_from_memory(mem, in_type, intent) {
const ptr0 = passArray8ToWasm0(mem, wasm.__wbindgen_malloc);
const len0 = WASM_VECTOR_LEN;
const ret = wasm.qcms_transformer_from_memory(ptr0, len0, in_type, intent);
return ret >>> 0;
}
function qcms_drop_transformer(transformer) {
wasm.qcms_drop_transformer(transformer);
}
const DataType = Object.freeze({
RGB8: 0,
"0": "RGB8",
RGBA8: 1,
"1": "RGBA8",
BGRA8: 2,
"2": "BGRA8",
Gray8: 3,
"3": "Gray8",
GrayA8: 4,
"4": "GrayA8",
CMYK: 5,
"5": "CMYK"
});
const Intent = Object.freeze({
Perceptual: 0,
"0": "Perceptual",
RelativeColorimetric: 1,
"1": "RelativeColorimetric",
Saturation: 2,
"2": "Saturation",
AbsoluteColorimetric: 3,
"3": "AbsoluteColorimetric"
});
async function __wbg_load(module, imports) {
if (typeof Response === 'function' && module instanceof Response) {
if (typeof WebAssembly.instantiateStreaming === 'function') {
try {
return await WebAssembly.instantiateStreaming(module, imports);
} catch (e) {
if (module.headers.get('Content-Type') != 'application/wasm') {
console.warn("`WebAssembly.instantiateStreaming` failed because your server does not serve Wasm with `application/wasm` MIME type. Falling back to `WebAssembly.instantiate` which is slower. Original error:\n", e);
} else {
throw e;
}
}
}
const bytes = await module.arrayBuffer();
return await WebAssembly.instantiate(bytes, imports);
} else {
const instance = await WebAssembly.instantiate(module, imports);
if (instance instanceof WebAssembly.Instance) {
return {
instance,
module
};
} else {
return instance;
}
}
}
function __wbg_get_imports() {
const imports = {};
imports.wbg = {};
imports.wbg.__wbg_copyresult_b08ee7d273f295dd = function (arg0, arg1) {
copy_result(arg0 >>> 0, arg1 >>> 0);
};
imports.wbg.__wbg_copyrgb_d60ce17bb05d9b67 = function (arg0) {
copy_rgb(arg0 >>> 0);
};
imports.wbg.__wbg_makecssRGB_893bf0cd9fdb302d = function (arg0) {
make_cssRGB(arg0 >>> 0);
};
imports.wbg.__wbindgen_init_externref_table = function () {
const table = wasm.__wbindgen_export_0;
const offset = table.grow(4);
table.set(0, undefined);
table.set(offset + 0, undefined);
table.set(offset + 1, null);
table.set(offset + 2, true);
table.set(offset + 3, false);
};
imports.wbg.__wbindgen_throw = function (arg0, arg1) {
throw new Error(getStringFromWasm0(arg0, arg1));
};
return imports;
}
function __wbg_init_memory(imports, memory) {}
function __wbg_finalize_init(instance, module) {
wasm = instance.exports;
__wbg_init.__wbindgen_wasm_module = module;
cachedUint8ArrayMemory0 = null;
wasm.__wbindgen_start();
return wasm;
}
function initSync(module) {
if (wasm !== undefined) return wasm;
if (typeof module !== 'undefined') {
if (Object.getPrototypeOf(module) === Object.prototype) {
({
module
} = module);
} else {
console.warn('using deprecated parameters for `initSync()`; pass a single object instead');
}
}
const imports = __wbg_get_imports();
__wbg_init_memory(imports);
if (!(module instanceof WebAssembly.Module)) {
module = new WebAssembly.Module(module);
}
const instance = new WebAssembly.Instance(module, imports);
return __wbg_finalize_init(instance, module);
}
async function __wbg_init(module_or_path) {
if (wasm !== undefined) return wasm;
if (typeof module_or_path !== 'undefined') {
if (Object.getPrototypeOf(module_or_path) === Object.prototype) {
({
module_or_path
} = module_or_path);
} else {
console.warn('using deprecated parameters for the initialization function; pass a single object instead');
}
}
const imports = __wbg_get_imports();
if (typeof module_or_path === 'string' || typeof Request === 'function' && module_or_path instanceof Request || typeof URL === 'function' && module_or_path instanceof URL) {
module_or_path = fetch(module_or_path);
}
__wbg_init_memory(imports);
const {
instance,
module
} = await __wbg_load(await module_or_path, imports);
return __wbg_finalize_init(instance, module);
}
/* harmony default export */ const qcms = ((/* unused pure expression or super */ null && (__wbg_init)));
;// ./src/core/icc_colorspace.js
function fetchSync(url) {
const xhr = new XMLHttpRequest();
xhr.open("GET", url, false);
xhr.responseType = "arraybuffer";
xhr.send(null);
return xhr.response;
}
class IccColorSpace extends ColorSpace {
#transformer;
#convertPixel;
static #useWasm = true;
static #wasmUrl = null;
static #finalizer = null;
constructor(iccProfile, name, numComps) {
if (!IccColorSpace.isUsable) {
throw new Error("No ICC color space support");
}
super(name, numComps);
let inType;
switch (numComps) {
case 1:
inType = DataType.Gray8;
this.#convertPixel = (src, srcOffset, css) => qcms_convert_one(this.#transformer, src[srcOffset] * 255, css);
break;
case 3:
inType = DataType.RGB8;
this.#convertPixel = (src, srcOffset, css) => qcms_convert_three(this.#transformer, src[srcOffset] * 255, src[srcOffset + 1] * 255, src[srcOffset + 2] * 255, css);
break;
case 4:
inType = DataType.CMYK;
this.#convertPixel = (src, srcOffset, css) => qcms_convert_four(this.#transformer, src[srcOffset] * 255, src[srcOffset + 1] * 255, src[srcOffset + 2] * 255, src[srcOffset + 3] * 255, css);
break;
default:
throw new Error(`Unsupported number of components: ${numComps}`);
}
this.#transformer = qcms_transformer_from_memory(iccProfile, inType, Intent.Perceptual);
if (!this.#transformer) {
throw new Error("Failed to create ICC color space");
}
IccColorSpace.#finalizer ||= new FinalizationRegistry(transformer => {
qcms_drop_transformer(transformer);
});
IccColorSpace.#finalizer.register(this, this.#transformer);
}
getRgbHex(src, srcOffset) {
this.#convertPixel(src, srcOffset, true);
return QCMS._cssColor;
}
getRgbItem(src, srcOffset, dest, destOffset) {
QCMS._destBuffer = dest;
QCMS._destOffset = destOffset;
QCMS._destLength = 3;
this.#convertPixel(src, srcOffset, false);
QCMS._destBuffer = null;
}
getRgbBuffer(src, srcOffset, count, dest, destOffset, bits, alpha01) {
src = src.subarray(srcOffset, srcOffset + count * this.numComps);
if (bits !== 8) {
const scale = 255 / ((1 << bits) - 1);
for (let i = 0, ii = src.length; i < ii; i++) {
src[i] *= scale;
}
}
QCMS._mustAddAlpha = alpha01 && dest.buffer === src.buffer;
QCMS._destBuffer = dest;
QCMS._destOffset = destOffset;
QCMS._destLength = count * (3 + alpha01);
qcms_convert_array(this.#transformer, src);
QCMS._mustAddAlpha = false;
QCMS._destBuffer = null;
}
getOutputLength(inputLength, alpha01) {
return inputLength / this.numComps * (3 + alpha01) | 0;
}
static setOptions({
useWasm,
useWorkerFetch,
wasmUrl
}) {
if (!useWorkerFetch) {
this.#useWasm = false;
return;
}
this.#useWasm = useWasm;
this.#wasmUrl = wasmUrl;
}
static get isUsable() {
let isUsable = false;
if (this.#useWasm) {
if (this.#wasmUrl) {
try {
this._module = initSync({
module: fetchSync(`${this.#wasmUrl}qcms_bg.wasm`)
});
isUsable = !!this._module;
QCMS._memory = this._module.memory;
QCMS._makeHexColor = util_Util.makeHexColor;
} catch (e) {
util_warn(`ICCBased color space: "${e}".`);
}
} else {
util_warn("No ICC color space support due to missing `wasmUrl` API option");
}
}
return shadow(this, "isUsable", isUsable);
}
}
class CmykICCBasedCS extends IccColorSpace {
static #iccUrl;
constructor() {
const iccProfile = new Uint8Array(fetchSync(`${CmykICCBasedCS.#iccUrl}CGATS001Compat-v2-micro.icc`));
super(iccProfile, "DeviceCMYK", 4);
}
static setOptions({
iccUrl
}) {
this.#iccUrl = iccUrl;
}
static get isUsable() {
let isUsable = false;
if (IccColorSpace.isUsable) {
if (this.#iccUrl) {
isUsable = true;
} else {
util_warn("No CMYK ICC profile support due to missing `iccUrl` API option");
}
}
return shadow(this, "isUsable", isUsable);
}
}
;// ./src/core/colorspace_utils.js
class ColorSpaceUtils {
static parse({
cs,
xref,
resources = null,
pdfFunctionFactory,
globalColorSpaceCache,
localColorSpaceCache,
asyncIfNotCached = false
}) {
const options = {
xref,
resources,
pdfFunctionFactory,
globalColorSpaceCache,
localColorSpaceCache
};
let csName, csRef, parsedCS;
if (cs instanceof primitives_Ref) {
csRef = cs;
const cachedCS = globalColorSpaceCache.getByRef(csRef) || localColorSpaceCache.getByRef(csRef);
if (cachedCS) {
return cachedCS;
}
cs = xref.fetch(cs);
}
if (cs instanceof Name) {
csName = cs.name;
const cachedCS = localColorSpaceCache.getByName(csName);
if (cachedCS) {
return cachedCS;
}
}
try {
parsedCS = this.#parse(cs, options);
} catch (ex) {
if (asyncIfNotCached && !(ex instanceof MissingDataException)) {
return Promise.reject(ex);
}
throw ex;
}
if (csName || csRef) {
localColorSpaceCache.set(csName, csRef, parsedCS);
if (csRef) {
globalColorSpaceCache.set(null, csRef, parsedCS);
}
}
return asyncIfNotCached ? Promise.resolve(parsedCS) : parsedCS;
}
static #subParse(cs, options) {
const {
globalColorSpaceCache
} = options;
let csRef;
if (cs instanceof primitives_Ref) {
csRef = cs;
const cachedCS = globalColorSpaceCache.getByRef(csRef);
if (cachedCS) {
return cachedCS;
}
}
const parsedCS = this.#parse(cs, options);
if (csRef) {
globalColorSpaceCache.set(null, csRef, parsedCS);
}
return parsedCS;
}
static #parse(cs, options) {
const {
xref,
resources,
pdfFunctionFactory,
globalColorSpaceCache
} = options;
cs = xref.fetchIfRef(cs);
if (cs instanceof Name) {
switch (cs.name) {
case "G":
case "DeviceGray":
return this.gray;
case "RGB":
case "DeviceRGB":
return this.rgb;
case "DeviceRGBA":
return this.rgba;
case "CMYK":
case "DeviceCMYK":
return this.cmyk;
case "Pattern":
return new PatternCS(null);
default:
if (resources instanceof primitives_Dict) {
const colorSpaces = resources.get("ColorSpace");
if (colorSpaces instanceof primitives_Dict) {
const resourcesCS = colorSpaces.get(cs.name);
if (resourcesCS) {
if (resourcesCS instanceof Name) {
return this.#parse(resourcesCS, options);
}
cs = resourcesCS;
break;
}
}
}
util_warn(`Unrecognized ColorSpace: ${cs.name}`);
return this.gray;
}
}
if (Array.isArray(cs)) {
const mode = xref.fetchIfRef(cs[0]).name;
let params, numComps, baseCS, whitePoint, blackPoint, gamma;
switch (mode) {
case "G":
case "DeviceGray":
return this.gray;
case "RGB":
case "DeviceRGB":
return this.rgb;
case "CMYK":
case "DeviceCMYK":
return this.cmyk;
case "CalGray":
params = xref.fetchIfRef(cs[1]);
whitePoint = params.getArray("WhitePoint");
blackPoint = params.getArray("BlackPoint");
gamma = params.get("Gamma");
return new CalGrayCS(whitePoint, blackPoint, gamma);
case "CalRGB":
params = xref.fetchIfRef(cs[1]);
whitePoint = params.getArray("WhitePoint");
blackPoint = params.getArray("BlackPoint");
gamma = params.getArray("Gamma");
const matrix = params.getArray("Matrix");
return new CalRGBCS(whitePoint, blackPoint, gamma, matrix);
case "ICCBased":
const isRef = cs[1] instanceof primitives_Ref;
if (isRef) {
const cachedCS = globalColorSpaceCache.getByRef(cs[1]);
if (cachedCS) {
return cachedCS;
}
}
const stream = xref.fetchIfRef(cs[1]);
const dict = stream.dict;
numComps = dict.get("N");
if (IccColorSpace.isUsable) {
try {
const iccCS = new IccColorSpace(stream.getBytes(), "ICCBased", numComps);
if (isRef) {
globalColorSpaceCache.set(null, cs[1], iccCS);
}
return iccCS;
} catch (ex) {
if (ex instanceof MissingDataException) {
throw ex;
}
util_warn(`ICCBased color space (${cs[1]}): "${ex}".`);
}
}
const altRaw = dict.getRaw("Alternate");
if (altRaw) {
const altCS = this.#subParse(altRaw, options);
if (altCS.numComps === numComps) {
return altCS;
}
util_warn("ICCBased color space: Ignoring incorrect /Alternate entry.");
}
if (numComps === 1) {
return this.gray;
} else if (numComps === 3) {
return this.rgb;
} else if (numComps === 4) {
return this.cmyk;
}
break;
case "Pattern":
baseCS = cs[1] || null;
if (baseCS) {
baseCS = this.#subParse(baseCS, options);
}
return new PatternCS(baseCS);
case "I":
case "Indexed":
baseCS = this.#subParse(cs[1], options);
const hiVal = MathClamp(xref.fetchIfRef(cs[2]), 0, 255);
const lookup = xref.fetchIfRef(cs[3]);
return new IndexedCS(baseCS, hiVal, lookup);
case "Separation":
case "DeviceN":
const name = xref.fetchIfRef(cs[1]);
numComps = Array.isArray(name) ? name.length : 1;
baseCS = this.#subParse(cs[2], options);
const tintFn = pdfFunctionFactory.create(cs[3]);
return new AlternateCS(numComps, baseCS, tintFn);
case "Lab":
params = xref.fetchIfRef(cs[1]);
whitePoint = params.getArray("WhitePoint");
blackPoint = params.getArray("BlackPoint");
const range = params.getArray("Range");
return new LabCS(whitePoint, blackPoint, range);
default:
util_warn(`Unimplemented ColorSpace object: ${mode}`);
return this.gray;
}
}
util_warn(`Unrecognized ColorSpace object: ${cs}`);
return this.gray;
}
static get gray() {
return shadow(this, "gray", new DeviceGrayCS());
}
static get rgb() {
return shadow(this, "rgb", new DeviceRgbCS());
}
static get rgba() {
return shadow(this, "rgba", new DeviceRgbaCS());
}
static get cmyk() {
if (CmykICCBasedCS.isUsable) {
try {
return shadow(this, "cmyk", new CmykICCBasedCS());
} catch {
util_warn("CMYK fallback: DeviceCMYK");
}
}
return shadow(this, "cmyk", new DeviceCmykCS());
}
}
;// ./src/shared/image_utils.js
function convertToRGBA(params) {
switch (params.kind) {
case ImageKind.GRAYSCALE_1BPP:
return convertBlackAndWhiteToRGBA(params);
case ImageKind.RGB_24BPP:
return convertRGBToRGBA(params);
}
return null;
}
function convertBlackAndWhiteToRGBA({
src,
srcPos = 0,
dest,
width,
height,
nonBlackColor = 0xffffffff,
inverseDecode = false
}) {
const black = FeatureTest.isLittleEndian ? 0xff000000 : 0x000000ff;
const [zeroMapping, oneMapping] = inverseDecode ? [nonBlackColor, black] : [black, nonBlackColor];
const widthInSource = width >> 3;
const widthRemainder = width & 7;
const srcLength = src.length;
dest = new Uint32Array(dest.buffer);
let destPos = 0;
for (let i = 0; i < height; i++) {
for (const max = srcPos + widthInSource; srcPos < max; srcPos++) {
const elem = srcPos < srcLength ? src[srcPos] : 255;
dest[destPos++] = elem & 0b10000000 ? oneMapping : zeroMapping;
dest[destPos++] = elem & 0b1000000 ? oneMapping : zeroMapping;
dest[destPos++] = elem & 0b100000 ? oneMapping : zeroMapping;
dest[destPos++] = elem & 0b10000 ? oneMapping : zeroMapping;
dest[destPos++] = elem & 0b1000 ? oneMapping : zeroMapping;
dest[destPos++] = elem & 0b100 ? oneMapping : zeroMapping;
dest[destPos++] = elem & 0b10 ? oneMapping : zeroMapping;
dest[destPos++] = elem & 0b1 ? oneMapping : zeroMapping;
}
if (widthRemainder === 0) {
continue;
}
const elem = srcPos < srcLength ? src[srcPos++] : 255;
for (let j = 0; j < widthRemainder; j++) {
dest[destPos++] = elem & 1 << 7 - j ? oneMapping : zeroMapping;
}
}
return {
srcPos,
destPos
};
}
function convertRGBToRGBA({
src,
srcPos = 0,
dest,
destPos = 0,
width,
height
}) {
let i = 0;
const len = width * height * 3;
const len32 = len >> 2;
const src32 = new Uint32Array(src.buffer, srcPos, len32);
if (FeatureTest.isLittleEndian) {
for (; i < len32 - 2; i += 3, destPos += 4) {
const s1 = src32[i];
const s2 = src32[i + 1];
const s3 = src32[i + 2];
dest[destPos] = s1 | 0xff000000;
dest[destPos + 1] = s1 >>> 24 | s2 << 8 | 0xff000000;
dest[destPos + 2] = s2 >>> 16 | s3 << 16 | 0xff000000;
dest[destPos + 3] = s3 >>> 8 | 0xff000000;
}
for (let j = i * 4, jj = srcPos + len; j < jj; j += 3) {
dest[destPos++] = src[j] | src[j + 1] << 8 | src[j + 2] << 16 | 0xff000000;
}
} else {
for (; i < len32 - 2; i += 3, destPos += 4) {
const s1 = src32[i];
const s2 = src32[i + 1];
const s3 = src32[i + 2];
dest[destPos] = s1 | 0xff;
dest[destPos + 1] = s1 << 24 | s2 >>> 8 | 0xff;
dest[destPos + 2] = s2 << 16 | s3 >>> 16 | 0xff;
dest[destPos + 3] = s3 << 8 | 0xff;
}
for (let j = i * 4, jj = srcPos + len; j < jj; j += 3) {
dest[destPos++] = src[j] << 24 | src[j + 1] << 16 | src[j + 2] << 8 | 0xff;
}
}
return {
srcPos: srcPos + len,
destPos
};
}
function grayToRGBA(src, dest) {
if (util_FeatureTest.isLittleEndian) {
for (let i = 0, ii = src.length; i < ii; i++) {
dest[i] = src[i] * 0x10101 | 0xff000000;
}
} else {
for (let i = 0, ii = src.length; i < ii; i++) {
dest[i] = src[i] * 0x1010100 | 0x000000ff;
}
}
}
;// ./src/core/jpg.js
class JpegError extends BaseException {
constructor(msg) {
super(msg, "JpegError");
}
}
class DNLMarkerError extends BaseException {
constructor(message, scanLines) {
super(message, "DNLMarkerError");
this.scanLines = scanLines;
}
}
class EOIMarkerError extends BaseException {
constructor(msg) {
super(msg, "EOIMarkerError");
}
}
const dctZigZag = new Uint8Array([0, 1, 8, 16, 9, 2, 3, 10, 17, 24, 32, 25, 18, 11, 4, 5, 12, 19, 26, 33, 40, 48, 41, 34, 27, 20, 13, 6, 7, 14, 21, 28, 35, 42, 49, 56, 57, 50, 43, 36, 29, 22, 15, 23, 30, 37, 44, 51, 58, 59, 52, 45, 38, 31, 39, 46, 53, 60, 61, 54, 47, 55, 62, 63]);
const dctCos1 = 4017;
const dctSin1 = 799;
const dctCos3 = 3406;
const dctSin3 = 2276;
const dctCos6 = 1567;
const dctSin6 = 3784;
const dctSqrt2 = 5793;
const dctSqrt1d2 = 2896;
function buildHuffmanTable(codeLengths, values) {
let k = 0,
i,
j,
length = 16;
while (length > 0 && !codeLengths[length - 1]) {
length--;
}
const code = [{
children: [],
index: 0
}];
let p = code[0],
q;
for (i = 0; i < length; i++) {
for (j = 0; j < codeLengths[i]; j++) {
p = code.pop();
p.children[p.index] = values[k];
while (p.index > 0) {
p = code.pop();
}
p.index++;
code.push(p);
while (code.length <= i) {
code.push(q = {
children: [],
index: 0
});
p.children[p.index] = q.children;
p = q;
}
k++;
}
if (i + 1 < length) {
code.push(q = {
children: [],
index: 0
});
p.children[p.index] = q.children;
p = q;
}
}
return code[0].children;
}
function getBlockBufferOffset(component, row, col) {
return 64 * ((component.blocksPerLine + 1) * row + col);
}
function decodeScan(data, offset, frame, components, resetInterval, spectralStart, spectralEnd, successivePrev, successive, parseDNLMarker = false) {
const mcusPerLine = frame.mcusPerLine;
const progressive = frame.progressive;
const startOffset = offset;
let bitsData = 0,
bitsCount = 0;
function readBit() {
if (bitsCount > 0) {
bitsCount--;
return bitsData >> bitsCount & 1;
}
bitsData = data[offset++];
if (bitsData === 0xff) {
const nextByte = data[offset++];
if (nextByte) {
if (nextByte === 0xdc && parseDNLMarker) {
offset += 2;
const scanLines = readUint16(data, offset);
offset += 2;
if (scanLines > 0 && scanLines !== frame.scanLines) {
throw new DNLMarkerError("Found DNL marker (0xFFDC) while parsing scan data", scanLines);
}
} else if (nextByte === 0xd9) {
if (parseDNLMarker) {
const maybeScanLines = blockRow * (frame.precision === 8 ? 8 : 0);
if (maybeScanLines > 0 && Math.round(frame.scanLines / maybeScanLines) >= 5) {
throw new DNLMarkerError("Found EOI marker (0xFFD9) while parsing scan data, " + "possibly caused by incorrect `scanLines` parameter", maybeScanLines);
}
}
throw new EOIMarkerError("Found EOI marker (0xFFD9) while parsing scan data");
}
throw new JpegError(`unexpected marker ${(bitsData << 8 | nextByte).toString(16)}`);
}
}
bitsCount = 7;
return bitsData >>> 7;
}
function decodeHuffman(tree) {
let node = tree;
while (true) {
node = node[readBit()];
switch (typeof node) {
case "number":
return node;
case "object":
continue;
}
throw new JpegError("invalid huffman sequence");
}
}
function receive(length) {
let n = 0;
while (length > 0) {
n = n << 1 | readBit();
length--;
}
return n;
}
function receiveAndExtend(length) {
if (length === 1) {
return readBit() === 1 ? 1 : -1;
}
const n = receive(length);
if (n >= 1 << length - 1) {
return n;
}
return n + (-1 << length) + 1;
}
function decodeBaseline(component, blockOffset) {
const t = decodeHuffman(component.huffmanTableDC);
const diff = t === 0 ? 0 : receiveAndExtend(t);
component.blockData[blockOffset] = component.pred += diff;
let k = 1;
while (k < 64) {
const rs = decodeHuffman(component.huffmanTableAC);
const s = rs & 15,
r = rs >> 4;
if (s === 0) {
if (r < 15) {
break;
}
k += 16;
continue;
}
k += r;
const z = dctZigZag[k];
component.blockData[blockOffset + z] = receiveAndExtend(s);
k++;
}
}
function decodeDCFirst(component, blockOffset) {
const t = decodeHuffman(component.huffmanTableDC);
const diff = t === 0 ? 0 : receiveAndExtend(t) << successive;
component.blockData[blockOffset] = component.pred += diff;
}
function decodeDCSuccessive(component, blockOffset) {
component.blockData[blockOffset] |= readBit() << successive;
}
let eobrun = 0;
function decodeACFirst(component, blockOffset) {
if (eobrun > 0) {
eobrun--;
return;
}
let k = spectralStart;
const e = spectralEnd;
while (k <= e) {
const rs = decodeHuffman(component.huffmanTableAC);
const s = rs & 15,
r = rs >> 4;
if (s === 0) {
if (r < 15) {
eobrun = receive(r) + (1 << r) - 1;
break;
}
k += 16;
continue;
}
k += r;
const z = dctZigZag[k];
component.blockData[blockOffset + z] = receiveAndExtend(s) * (1 << successive);
k++;
}
}
let successiveACState = 0,
successiveACNextValue;
function decodeACSuccessive(component, blockOffset) {
let k = spectralStart;
const e = spectralEnd;
let r = 0;
let s;
let rs;
while (k <= e) {
const offsetZ = blockOffset + dctZigZag[k];
const sign = component.blockData[offsetZ] < 0 ? -1 : 1;
switch (successiveACState) {
case 0:
rs = decodeHuffman(component.huffmanTableAC);
s = rs & 15;
r = rs >> 4;
if (s === 0) {
if (r < 15) {
eobrun = receive(r) + (1 << r);
successiveACState = 4;
} else {
r = 16;
successiveACState = 1;
}
} else {
if (s !== 1) {
throw new JpegError("invalid ACn encoding");
}
successiveACNextValue = receiveAndExtend(s);
successiveACState = r ? 2 : 3;
}
continue;
case 1:
case 2:
if (component.blockData[offsetZ]) {
component.blockData[offsetZ] += sign * (readBit() << successive);
} else {
r--;
if (r === 0) {
successiveACState = successiveACState === 2 ? 3 : 0;
}
}
break;
case 3:
if (component.blockData[offsetZ]) {
component.blockData[offsetZ] += sign * (readBit() << successive);
} else {
component.blockData[offsetZ] = successiveACNextValue << successive;
successiveACState = 0;
}
break;
case 4:
if (component.blockData[offsetZ]) {
component.blockData[offsetZ] += sign * (readBit() << successive);
}
break;
}
k++;
}
if (successiveACState === 4) {
eobrun--;
if (eobrun === 0) {
successiveACState = 0;
}
}
}
let blockRow = 0;
function decodeMcu(component, decode, mcu, row, col) {
const mcuRow = mcu / mcusPerLine | 0;
const mcuCol = mcu % mcusPerLine;
blockRow = mcuRow * component.v + row;
const blockCol = mcuCol * component.h + col;
const blockOffset = getBlockBufferOffset(component, blockRow, blockCol);
decode(component, blockOffset);
}
function decodeBlock(component, decode, mcu) {
blockRow = mcu / component.blocksPerLine | 0;
const blockCol = mcu % component.blocksPerLine;
const blockOffset = getBlockBufferOffset(component, blockRow, blockCol);
decode(component, blockOffset);
}
const componentsLength = components.length;
let component, i, j, k, n;
let decodeFn;
if (progressive) {
if (spectralStart === 0) {
decodeFn = successivePrev === 0 ? decodeDCFirst : decodeDCSuccessive;
} else {
decodeFn = successivePrev === 0 ? decodeACFirst : decodeACSuccessive;
}
} else {
decodeFn = decodeBaseline;
}
let mcu = 0,
fileMarker;
const mcuExpected = componentsLength === 1 ? components[0].blocksPerLine * components[0].blocksPerColumn : mcusPerLine * frame.mcusPerColumn;
let h, v;
while (mcu <= mcuExpected) {
const mcuToRead = resetInterval ? Math.min(mcuExpected - mcu, resetInterval) : mcuExpected;
if (mcuToRead > 0) {
for (i = 0; i < componentsLength; i++) {
components[i].pred = 0;
}
eobrun = 0;
if (componentsLength === 1) {
component = components[0];
for (n = 0; n < mcuToRead; n++) {
decodeBlock(component, decodeFn, mcu);
mcu++;
}
} else {
for (n = 0; n < mcuToRead; n++) {
for (i = 0; i < componentsLength; i++) {
component = components[i];
h = component.h;
v = component.v;
for (j = 0; j < v; j++) {
for (k = 0; k < h; k++) {
decodeMcu(component, decodeFn, mcu, j, k);
}
}
}
mcu++;
}
}
}
bitsCount = 0;
fileMarker = findNextFileMarker(data, offset);
if (!fileMarker) {
break;
}
if (fileMarker.invalid) {
const partialMsg = mcuToRead > 0 ? "unexpected" : "excessive";
util_warn(`decodeScan - ${partialMsg} MCU data, current marker is: ${fileMarker.invalid}`);
offset = fileMarker.offset;
}
if (fileMarker.marker >= 0xffd0 && fileMarker.marker <= 0xffd7) {
offset += 2;
} else {
break;
}
}
return offset - startOffset;
}
function quantizeAndInverse(component, blockBufferOffset, p) {
const qt = component.quantizationTable,
blockData = component.blockData;
let v0, v1, v2, v3, v4, v5, v6, v7;
let p0, p1, p2, p3, p4, p5, p6, p7;
let t;
if (!qt) {
throw new JpegError("missing required Quantization Table.");
}
for (let row = 0; row < 64; row += 8) {
p0 = blockData[blockBufferOffset + row];
p1 = blockData[blockBufferOffset + row + 1];
p2 = blockData[blockBufferOffset + row + 2];
p3 = blockData[blockBufferOffset + row + 3];
p4 = blockData[blockBufferOffset + row + 4];
p5 = blockData[blockBufferOffset + row + 5];
p6 = blockData[blockBufferOffset + row + 6];
p7 = blockData[blockBufferOffset + row + 7];
p0 *= qt[row];
if ((p1 | p2 | p3 | p4 | p5 | p6 | p7) === 0) {
t = dctSqrt2 * p0 + 512 >> 10;
p[row] = t;
p[row + 1] = t;
p[row + 2] = t;
p[row + 3] = t;
p[row + 4] = t;
p[row + 5] = t;
p[row + 6] = t;
p[row + 7] = t;
continue;
}
p1 *= qt[row + 1];
p2 *= qt[row + 2];
p3 *= qt[row + 3];
p4 *= qt[row + 4];
p5 *= qt[row + 5];
p6 *= qt[row + 6];
p7 *= qt[row + 7];
v0 = dctSqrt2 * p0 + 128 >> 8;
v1 = dctSqrt2 * p4 + 128 >> 8;
v2 = p2;
v3 = p6;
v4 = dctSqrt1d2 * (p1 - p7) + 128 >> 8;
v7 = dctSqrt1d2 * (p1 + p7) + 128 >> 8;
v5 = p3 << 4;
v6 = p5 << 4;
v0 = v0 + v1 + 1 >> 1;
v1 = v0 - v1;
t = v2 * dctSin6 + v3 * dctCos6 + 128 >> 8;
v2 = v2 * dctCos6 - v3 * dctSin6 + 128 >> 8;
v3 = t;
v4 = v4 + v6 + 1 >> 1;
v6 = v4 - v6;
v7 = v7 + v5 + 1 >> 1;
v5 = v7 - v5;
v0 = v0 + v3 + 1 >> 1;
v3 = v0 - v3;
v1 = v1 + v2 + 1 >> 1;
v2 = v1 - v2;
t = v4 * dctSin3 + v7 * dctCos3 + 2048 >> 12;
v4 = v4 * dctCos3 - v7 * dctSin3 + 2048 >> 12;
v7 = t;
t = v5 * dctSin1 + v6 * dctCos1 + 2048 >> 12;
v5 = v5 * dctCos1 - v6 * dctSin1 + 2048 >> 12;
v6 = t;
p[row] = v0 + v7;
p[row + 7] = v0 - v7;
p[row + 1] = v1 + v6;
p[row + 6] = v1 - v6;
p[row + 2] = v2 + v5;
p[row + 5] = v2 - v5;
p[row + 3] = v3 + v4;
p[row + 4] = v3 - v4;
}
for (let col = 0; col < 8; ++col) {
p0 = p[col];
p1 = p[col + 8];
p2 = p[col + 16];
p3 = p[col + 24];
p4 = p[col + 32];
p5 = p[col + 40];
p6 = p[col + 48];
p7 = p[col + 56];
if ((p1 | p2 | p3 | p4 | p5 | p6 | p7) === 0) {
t = dctSqrt2 * p0 + 8192 >> 14;
if (t < -2040) {
t = 0;
} else if (t >= 2024) {
t = 255;
} else {
t = t + 2056 >> 4;
}
blockData[blockBufferOffset + col] = t;
blockData[blockBufferOffset + col + 8] = t;
blockData[blockBufferOffset + col + 16] = t;
blockData[blockBufferOffset + col + 24] = t;
blockData[blockBufferOffset + col + 32] = t;
blockData[blockBufferOffset + col + 40] = t;
blockData[blockBufferOffset + col + 48] = t;
blockData[blockBufferOffset + col + 56] = t;
continue;
}
v0 = dctSqrt2 * p0 + 2048 >> 12;
v1 = dctSqrt2 * p4 + 2048 >> 12;
v2 = p2;
v3 = p6;
v4 = dctSqrt1d2 * (p1 - p7) + 2048 >> 12;
v7 = dctSqrt1d2 * (p1 + p7) + 2048 >> 12;
v5 = p3;
v6 = p5;
v0 = (v0 + v1 + 1 >> 1) + 4112;
v1 = v0 - v1;
t = v2 * dctSin6 + v3 * dctCos6 + 2048 >> 12;
v2 = v2 * dctCos6 - v3 * dctSin6 + 2048 >> 12;
v3 = t;
v4 = v4 + v6 + 1 >> 1;
v6 = v4 - v6;
v7 = v7 + v5 + 1 >> 1;
v5 = v7 - v5;
v0 = v0 + v3 + 1 >> 1;
v3 = v0 - v3;
v1 = v1 + v2 + 1 >> 1;
v2 = v1 - v2;
t = v4 * dctSin3 + v7 * dctCos3 + 2048 >> 12;
v4 = v4 * dctCos3 - v7 * dctSin3 + 2048 >> 12;
v7 = t;
t = v5 * dctSin1 + v6 * dctCos1 + 2048 >> 12;
v5 = v5 * dctCos1 - v6 * dctSin1 + 2048 >> 12;
v6 = t;
p0 = v0 + v7;
p7 = v0 - v7;
p1 = v1 + v6;
p6 = v1 - v6;
p2 = v2 + v5;
p5 = v2 - v5;
p3 = v3 + v4;
p4 = v3 - v4;
if (p0 < 16) {
p0 = 0;
} else if (p0 >= 4080) {
p0 = 255;
} else {
p0 >>= 4;
}
if (p1 < 16) {
p1 = 0;
} else if (p1 >= 4080) {
p1 = 255;
} else {
p1 >>= 4;
}
if (p2 < 16) {
p2 = 0;
} else if (p2 >= 4080) {
p2 = 255;
} else {
p2 >>= 4;
}
if (p3 < 16) {
p3 = 0;
} else if (p3 >= 4080) {
p3 = 255;
} else {
p3 >>= 4;
}
if (p4 < 16) {
p4 = 0;
} else if (p4 >= 4080) {
p4 = 255;
} else {
p4 >>= 4;
}
if (p5 < 16) {
p5 = 0;
} else if (p5 >= 4080) {
p5 = 255;
} else {
p5 >>= 4;
}
if (p6 < 16) {
p6 = 0;
} else if (p6 >= 4080) {
p6 = 255;
} else {
p6 >>= 4;
}
if (p7 < 16) {
p7 = 0;
} else if (p7 >= 4080) {
p7 = 255;
} else {
p7 >>= 4;
}
blockData[blockBufferOffset + col] = p0;
blockData[blockBufferOffset + col + 8] = p1;
blockData[blockBufferOffset + col + 16] = p2;
blockData[blockBufferOffset + col + 24] = p3;
blockData[blockBufferOffset + col + 32] = p4;
blockData[blockBufferOffset + col + 40] = p5;
blockData[blockBufferOffset + col + 48] = p6;
blockData[blockBufferOffset + col + 56] = p7;
}
}
function buildComponentData(frame, component) {
const blocksPerLine = component.blocksPerLine;
const blocksPerColumn = component.blocksPerColumn;
const computationBuffer = new Int16Array(64);
for (let blockRow = 0; blockRow < blocksPerColumn; blockRow++) {
for (let blockCol = 0; blockCol < blocksPerLine; blockCol++) {
const offset = getBlockBufferOffset(component, blockRow, blockCol);
quantizeAndInverse(component, offset, computationBuffer);
}
}
return component.blockData;
}
function findNextFileMarker(data, currentPos, startPos = currentPos) {
const maxPos = data.length - 1;
let newPos = startPos < currentPos ? startPos : currentPos;
if (currentPos >= maxPos) {
return null;
}
const currentMarker = readUint16(data, currentPos);
if (currentMarker >= 0xffc0 && currentMarker <= 0xfffe) {
return {
invalid: null,
marker: currentMarker,
offset: currentPos
};
}
let newMarker = readUint16(data, newPos);
while (!(newMarker >= 0xffc0 && newMarker <= 0xfffe)) {
if (++newPos >= maxPos) {
return null;
}
newMarker = readUint16(data, newPos);
}
return {
invalid: currentMarker.toString(16),
marker: newMarker,
offset: newPos
};
}
function prepareComponents(frame) {
const mcusPerLine = Math.ceil(frame.samplesPerLine / 8 / frame.maxH);
const mcusPerColumn = Math.ceil(frame.scanLines / 8 / frame.maxV);
for (const component of frame.components) {
const blocksPerLine = Math.ceil(Math.ceil(frame.samplesPerLine / 8) * component.h / frame.maxH);
const blocksPerColumn = Math.ceil(Math.ceil(frame.scanLines / 8) * component.v / frame.maxV);
const blocksPerLineForMcu = mcusPerLine * component.h;
const blocksPerColumnForMcu = mcusPerColumn * component.v;
const blocksBufferSize = 64 * blocksPerColumnForMcu * (blocksPerLineForMcu + 1);
component.blockData = new Int16Array(blocksBufferSize);
component.blocksPerLine = blocksPerLine;
component.blocksPerColumn = blocksPerColumn;
}
frame.mcusPerLine = mcusPerLine;
frame.mcusPerColumn = mcusPerColumn;
}
function readDataBlock(data, offset) {
const length = readUint16(data, offset);
offset += 2;
let endOffset = offset + length - 2;
const fileMarker = findNextFileMarker(data, endOffset, offset);
if (fileMarker?.invalid) {
util_warn("readDataBlock - incorrect length, current marker is: " + fileMarker.invalid);
endOffset = fileMarker.offset;
}
const array = data.subarray(offset, endOffset);
return {
appData: array,
oldOffset: offset,
newOffset: offset + array.length
};
}
function skipData(data, offset) {
const length = readUint16(data, offset);
offset += 2;
const endOffset = offset + length - 2;
const fileMarker = findNextFileMarker(data, endOffset, offset);
if (fileMarker?.invalid) {
return fileMarker.offset;
}
return endOffset;
}
class JpegImage {
constructor({
decodeTransform = null,
colorTransform = -1
} = {}) {
this._decodeTransform = decodeTransform;
this._colorTransform = colorTransform;
}
static canUseImageDecoder(data, colorTransform = -1) {
let exifOffsets = null;
let offset = 0;
let numComponents = null;
let fileMarker = readUint16(data, offset);
offset += 2;
if (fileMarker !== 0xffd8) {
throw new JpegError("SOI not found");
}
fileMarker = readUint16(data, offset);
offset += 2;
markerLoop: while (fileMarker !== 0xffd9) {
switch (fileMarker) {
case 0xffe1:
const {
appData,
oldOffset,
newOffset
} = readDataBlock(data, offset);
offset = newOffset;
if (appData[0] === 0x45 && appData[1] === 0x78 && appData[2] === 0x69 && appData[3] === 0x66 && appData[4] === 0 && appData[5] === 0) {
if (exifOffsets) {
throw new JpegError("Duplicate EXIF-blocks found.");
}
exifOffsets = {
exifStart: oldOffset + 6,
exifEnd: newOffset
};
}
fileMarker = readUint16(data, offset);
offset += 2;
continue;
case 0xffc0:
case 0xffc1:
case 0xffc2:
numComponents = data[offset + (2 + 1 + 2 + 2)];
break markerLoop;
case 0xffff:
if (data[offset] !== 0xff) {
offset--;
}
break;
}
offset = skipData(data, offset);
fileMarker = readUint16(data, offset);
offset += 2;
}
if (numComponents === 4) {
return null;
}
if (numComponents === 3 && colorTransform === 0) {
return null;
}
return exifOffsets || {};
}
parse(data, {
dnlScanLines = null
} = {}) {
let offset = 0;
let jfif = null;
let adobe = null;
let frame, resetInterval;
let numSOSMarkers = 0;
const quantizationTables = [];
const huffmanTablesAC = [],
huffmanTablesDC = [];
let fileMarker = readUint16(data, offset);
offset += 2;
if (fileMarker !== 0xffd8) {
throw new JpegError("SOI not found");
}
fileMarker = readUint16(data, offset);
offset += 2;
markerLoop: while (fileMarker !== 0xffd9) {
let i, j, l;
switch (fileMarker) {
case 0xffe0:
case 0xffe1:
case 0xffe2:
case 0xffe3:
case 0xffe4:
case 0xffe5:
case 0xffe6:
case 0xffe7:
case 0xffe8:
case 0xffe9:
case 0xffea:
case 0xffeb:
case 0xffec:
case 0xffed:
case 0xffee:
case 0xffef:
case 0xfffe:
const {
appData,
newOffset
} = readDataBlock(data, offset);
offset = newOffset;
if (fileMarker === 0xffe0) {
if (appData[0] === 0x4a && appData[1] === 0x46 && appData[2] === 0x49 && appData[3] === 0x46 && appData[4] === 0) {
jfif = {
version: {
major: appData[5],
minor: appData[6]
},
densityUnits: appData[7],
xDensity: appData[8] << 8 | appData[9],
yDensity: appData[10] << 8 | appData[11],
thumbWidth: appData[12],
thumbHeight: appData[13],
thumbData: appData.subarray(14, 14 + 3 * appData[12] * appData[13])
};
}
}
if (fileMarker === 0xffee) {
if (appData[0] === 0x41 && appData[1] === 0x64 && appData[2] === 0x6f && appData[3] === 0x62 && appData[4] === 0x65) {
adobe = {
version: appData[5] << 8 | appData[6],
flags0: appData[7] << 8 | appData[8],
flags1: appData[9] << 8 | appData[10],
transformCode: appData[11]
};
}
}
break;
case 0xffdb:
const quantizationTablesLength = readUint16(data, offset);
offset += 2;
const quantizationTablesEnd = quantizationTablesLength + offset - 2;
let z;
while (offset < quantizationTablesEnd) {
const quantizationTableSpec = data[offset++];
const tableData = new Uint16Array(64);
if (quantizationTableSpec >> 4 === 0) {
for (j = 0; j < 64; j++) {
z = dctZigZag[j];
tableData[z] = data[offset++];
}
} else if (quantizationTableSpec >> 4 === 1) {
for (j = 0; j < 64; j++) {
z = dctZigZag[j];
tableData[z] = readUint16(data, offset);
offset += 2;
}
} else {
throw new JpegError("DQT - invalid table spec");
}
quantizationTables[quantizationTableSpec & 15] = tableData;
}
break;
case 0xffc0:
case 0xffc1:
case 0xffc2:
if (frame) {
throw new JpegError("Only single frame JPEGs supported");
}
offset += 2;
frame = {};
frame.extended = fileMarker === 0xffc1;
frame.progressive = fileMarker === 0xffc2;
frame.precision = data[offset++];
const sofScanLines = readUint16(data, offset);
offset += 2;
frame.scanLines = dnlScanLines || sofScanLines;
frame.samplesPerLine = readUint16(data, offset);
offset += 2;
frame.components = [];
frame.componentIds = {};
const componentsCount = data[offset++];
let maxH = 0,
maxV = 0;
for (i = 0; i < componentsCount; i++) {
const componentId = data[offset];
const h = data[offset + 1] >> 4;
const v = data[offset + 1] & 15;
if (maxH < h) {
maxH = h;
}
if (maxV < v) {
maxV = v;
}
const qId = data[offset + 2];
l = frame.components.push({
h,
v,
quantizationId: qId,
quantizationTable: null
});
frame.componentIds[componentId] = l - 1;
offset += 3;
}
frame.maxH = maxH;
frame.maxV = maxV;
prepareComponents(frame);
break;
case 0xffc4:
const huffmanLength = readUint16(data, offset);
offset += 2;
for (i = 2; i < huffmanLength;) {
const huffmanTableSpec = data[offset++];
const codeLengths = new Uint8Array(16);
let codeLengthSum = 0;
for (j = 0; j < 16; j++, offset++) {
codeLengthSum += codeLengths[j] = data[offset];
}
const huffmanValues = new Uint8Array(codeLengthSum);
for (j = 0; j < codeLengthSum; j++, offset++) {
huffmanValues[j] = data[offset];
}
i += 17 + codeLengthSum;
(huffmanTableSpec >> 4 === 0 ? huffmanTablesDC : huffmanTablesAC)[huffmanTableSpec & 15] = buildHuffmanTable(codeLengths, huffmanValues);
}
break;
case 0xffdd:
offset += 2;
resetInterval = readUint16(data, offset);
offset += 2;
break;
case 0xffda:
const parseDNLMarker = ++numSOSMarkers === 1 && !dnlScanLines;
offset += 2;
const selectorsCount = data[offset++],
components = [];
for (i = 0; i < selectorsCount; i++) {
const index = data[offset++];
const componentIndex = frame.componentIds[index];
const component = frame.components[componentIndex];
component.index = index;
const tableSpec = data[offset++];
component.huffmanTableDC = huffmanTablesDC[tableSpec >> 4];
component.huffmanTableAC = huffmanTablesAC[tableSpec & 15];
components.push(component);
}
const spectralStart = data[offset++],
spectralEnd = data[offset++],
successiveApproximation = data[offset++];
try {
const processed = decodeScan(data, offset, frame, components, resetInterval, spectralStart, spectralEnd, successiveApproximation >> 4, successiveApproximation & 15, parseDNLMarker);
offset += processed;
} catch (ex) {
if (ex instanceof DNLMarkerError) {
util_warn(`${ex.message} -- attempting to re-parse the JPEG image.`);
return this.parse(data, {
dnlScanLines: ex.scanLines
});
} else if (ex instanceof EOIMarkerError) {
util_warn(`${ex.message} -- ignoring the rest of the image data.`);
break markerLoop;
}
throw ex;
}
break;
case 0xffdc:
offset += 4;
break;
case 0xffff:
if (data[offset] !== 0xff) {
offset--;
}
break;
default:
const nextFileMarker = findNextFileMarker(data, offset - 2, offset - 3);
if (nextFileMarker?.invalid) {
util_warn("JpegImage.parse - unexpected data, current marker is: " + nextFileMarker.invalid);
offset = nextFileMarker.offset;
break;
}
if (!nextFileMarker || offset >= data.length - 1) {
util_warn("JpegImage.parse - reached the end of the image data " + "without finding an EOI marker (0xFFD9).");
break markerLoop;
}
throw new JpegError("JpegImage.parse - unknown marker: " + fileMarker.toString(16));
}
fileMarker = readUint16(data, offset);
offset += 2;
}
if (!frame) {
throw new JpegError("JpegImage.parse - no frame data found.");
}
this.width = frame.samplesPerLine;
this.height = frame.scanLines;
this.jfif = jfif;
this.adobe = adobe;
this.components = [];
for (const component of frame.components) {
const quantizationTable = quantizationTables[component.quantizationId];
if (quantizationTable) {
component.quantizationTable = quantizationTable;
}
this.components.push({
index: component.index,
output: buildComponentData(frame, component),
scaleX: component.h / frame.maxH,
scaleY: component.v / frame.maxV,
blocksPerLine: component.blocksPerLine,
blocksPerColumn: component.blocksPerColumn
});
}
this.numComponents = this.components.length;
return undefined;
}
_getLinearizedBlockData(width, height, isSourcePDF = false) {
const scaleX = this.width / width,
scaleY = this.height / height;
let component, componentScaleX, componentScaleY, blocksPerScanline;
let x, y, i, j, k;
let index;
let offset = 0;
let output;
const numComponents = this.components.length;
const dataLength = width * height * numComponents;
const data = new Uint8ClampedArray(dataLength);
const xScaleBlockOffset = new Uint32Array(width);
const mask3LSB = 0xfffffff8;
let lastComponentScaleX;
for (i = 0; i < numComponents; i++) {
component = this.components[i];
componentScaleX = component.scaleX * scaleX;
componentScaleY = component.scaleY * scaleY;
offset = i;
output = component.output;
blocksPerScanline = component.blocksPerLine + 1 << 3;
if (componentScaleX !== lastComponentScaleX) {
for (x = 0; x < width; x++) {
j = 0 | x * componentScaleX;
xScaleBlockOffset[x] = (j & mask3LSB) << 3 | j & 7;
}
lastComponentScaleX = componentScaleX;
}
for (y = 0; y < height; y++) {
j = 0 | y * componentScaleY;
index = blocksPerScanline * (j & mask3LSB) | (j & 7) << 3;
for (x = 0; x < width; x++) {
data[offset] = output[index + xScaleBlockOffset[x]];
offset += numComponents;
}
}
}
let transform = this._decodeTransform;
if (!isSourcePDF && numComponents === 4 && !transform) {
transform = new Int32Array([-256, 255, -256, 255, -256, 255, -256, 255]);
}
if (transform) {
for (i = 0; i < dataLength;) {
for (j = 0, k = 0; j < numComponents; j++, i++, k += 2) {
data[i] = (data[i] * transform[k] >> 8) + transform[k + 1];
}
}
}
return data;
}
get _isColorConversionNeeded() {
if (this.adobe) {
return !!this.adobe.transformCode;
}
if (this.numComponents === 3) {
if (this._colorTransform === 0) {
return false;
} else if (this.components[0].index === 0x52 && this.components[1].index === 0x47 && this.components[2].index === 0x42) {
return false;
}
return true;
}
if (this._colorTransform === 1) {
return true;
}
return false;
}
_convertYccToRgb(data) {
let Y, Cb, Cr;
for (let i = 0, length = data.length; i < length; i += 3) {
Y = data[i];
Cb = data[i + 1];
Cr = data[i + 2];
data[i] = Y - 179.456 + 1.402 * Cr;
data[i + 1] = Y + 135.459 - 0.344 * Cb - 0.714 * Cr;
data[i + 2] = Y - 226.816 + 1.772 * Cb;
}
return data;
}
_convertYccToRgba(data, out) {
for (let i = 0, j = 0, length = data.length; i < length; i += 3, j += 4) {
const Y = data[i];
const Cb = data[i + 1];
const Cr = data[i + 2];
out[j] = Y - 179.456 + 1.402 * Cr;
out[j + 1] = Y + 135.459 - 0.344 * Cb - 0.714 * Cr;
out[j + 2] = Y - 226.816 + 1.772 * Cb;
out[j + 3] = 255;
}
return out;
}
_convertYcckToRgb(data) {
this._convertYcckToCmyk(data);
return this._convertCmykToRgb(data);
}
_convertYcckToRgba(data) {
this._convertYcckToCmyk(data);
return this._convertCmykToRgba(data);
}
_convertYcckToCmyk(data) {
let Y, Cb, Cr;
for (let i = 0, length = data.length; i < length; i += 4) {
Y = data[i];
Cb = data[i + 1];
Cr = data[i + 2];
data[i] = 434.456 - Y - 1.402 * Cr;
data[i + 1] = 119.541 - Y + 0.344 * Cb + 0.714 * Cr;
data[i + 2] = 481.816 - Y - 1.772 * Cb;
}
return data;
}
_convertCmykToRgb(data) {
const count = data.length / 4;
ColorSpaceUtils.cmyk.getRgbBuffer(data, 0, count, data, 0, 8, 0);
return data.subarray(0, count * 3);
}
_convertCmykToRgba(data) {
ColorSpaceUtils.cmyk.getRgbBuffer(data, 0, data.length / 4, data, 0, 8, 1);
if (ColorSpaceUtils.cmyk instanceof DeviceCmykCS) {
for (let i = 3, ii = data.length; i < ii; i += 4) {
data[i] = 255;
}
}
return data;
}
getData({
width,
height,
forceRGBA = false,
forceRGB = false,
isSourcePDF = false
}) {
if (this.numComponents > 4) {
throw new JpegError("Unsupported color mode");
}
const data = this._getLinearizedBlockData(width, height, isSourcePDF);
if (this.numComponents === 1 && (forceRGBA || forceRGB)) {
const len = data.length * (forceRGBA ? 4 : 3);
const rgbaData = new Uint8ClampedArray(len);
let offset = 0;
if (forceRGBA) {
grayToRGBA(data, new Uint32Array(rgbaData.buffer));
} else {
for (const grayColor of data) {
rgbaData[offset++] = grayColor;
rgbaData[offset++] = grayColor;
rgbaData[offset++] = grayColor;
}
}
return rgbaData;
} else if (this.numComponents === 3 && this._isColorConversionNeeded) {
if (forceRGBA) {
const rgbaData = new Uint8ClampedArray(data.length / 3 * 4);
return this._convertYccToRgba(data, rgbaData);
}
return this._convertYccToRgb(data);
} else if (this.numComponents === 4) {
if (this._isColorConversionNeeded) {
if (forceRGBA) {
return this._convertYcckToRgba(data);
}
if (forceRGB) {
return this._convertYcckToRgb(data);
}
return this._convertYcckToCmyk(data);
} else if (forceRGBA) {
return this._convertCmykToRgba(data);
} else if (forceRGB) {
return this._convertCmykToRgb(data);
}
}
return data;
}
}
;// ./external/openjpeg/openjpeg.js
var OpenJPEG = (() => {
return async function (moduleArg = {}) {
var moduleRtn;
var Module = moduleArg;
var readyPromiseResolve, readyPromiseReject;
var readyPromise = new Promise((resolve, reject) => {
readyPromiseResolve = resolve;
readyPromiseReject = reject;
});
var ENVIRONMENT_IS_WEB = true;
var ENVIRONMENT_IS_WORKER = false;
var arguments_ = [];
var thisProgram = "./this.program";
var quit_ = (status, toThrow) => {
throw toThrow;
};
var _scriptName = import.meta.url;
var scriptDirectory = "";
var readAsync, readBinary;
if (ENVIRONMENT_IS_WEB || ENVIRONMENT_IS_WORKER) {
try {
scriptDirectory = new URL(".", _scriptName).href;
} catch {}
readAsync = async url => {
var response = await fetch(url, {
credentials: "same-origin"
});
if (response.ok) {
return response.arrayBuffer();
}
throw new Error(response.status + " : " + response.url);
};
} else {}
var out = console.log.bind(console);
var err = console.error.bind(console);
var wasmBinary;
var wasmMemory;
var ABORT = false;
var EXITSTATUS;
var HEAP8, HEAPU8, HEAP16, HEAPU16, HEAP32, HEAPU32, HEAPF32, HEAP64, HEAPU64, HEAPF64;
var runtimeInitialized = false;
function updateMemoryViews() {
var b = wasmMemory.buffer;
HEAP8 = new Int8Array(b);
HEAP16 = new Int16Array(b);
HEAPU8 = new Uint8Array(b);
HEAPU16 = new Uint16Array(b);
HEAP32 = new Int32Array(b);
HEAPU32 = new Uint32Array(b);
HEAPF32 = new Float32Array(b);
HEAPF64 = new Float64Array(b);
HEAP64 = new BigInt64Array(b);
HEAPU64 = new BigUint64Array(b);
}
function preRun() {
if (Module["preRun"]) {
if (typeof Module["preRun"] == "function") Module["preRun"] = [Module["preRun"]];
while (Module["preRun"].length) {
addOnPreRun(Module["preRun"].shift());
}
}
callRuntimeCallbacks(onPreRuns);
}
function initRuntime() {
runtimeInitialized = true;
wasmExports["t"]();
}
function postRun() {
if (Module["postRun"]) {
if (typeof Module["postRun"] == "function") Module["postRun"] = [Module["postRun"]];
while (Module["postRun"].length) {
addOnPostRun(Module["postRun"].shift());
}
}
callRuntimeCallbacks(onPostRuns);
}
var runDependencies = 0;
var dependenciesFulfilled = null;
function addRunDependency(id) {
runDependencies++;
Module["monitorRunDependencies"]?.(runDependencies);
}
function removeRunDependency(id) {
runDependencies--;
Module["monitorRunDependencies"]?.(runDependencies);
if (runDependencies == 0) {
if (dependenciesFulfilled) {
var callback = dependenciesFulfilled;
dependenciesFulfilled = null;
callback();
}
}
}
function abort(what) {
Module["onAbort"]?.(what);
what = "Aborted(" + what + ")";
err(what);
ABORT = true;
what += ". Build with -sASSERTIONS for more info.";
var e = new WebAssembly.RuntimeError(what);
readyPromiseReject(e);
throw e;
}
var wasmBinaryFile;
function getWasmImports() {
return {
a: wasmImports
};
}
async function createWasm() {
function receiveInstance(instance, module) {
wasmExports = instance.exports;
wasmMemory = wasmExports["s"];
updateMemoryViews();
removeRunDependency("wasm-instantiate");
return wasmExports;
}
addRunDependency("wasm-instantiate");
var info = getWasmImports();
return new Promise((resolve, reject) => {
Module["instantiateWasm"](info, (mod, inst) => {
resolve(receiveInstance(mod, inst));
});
});
}
class ExitStatus {
name = "ExitStatus";
constructor(status) {
this.message = `Program terminated with exit(${status})`;
this.status = status;
}
}
var callRuntimeCallbacks = callbacks => {
while (callbacks.length > 0) {
callbacks.shift()(Module);
}
};
var onPostRuns = [];
var addOnPostRun = cb => onPostRuns.push(cb);
var onPreRuns = [];
var addOnPreRun = cb => onPreRuns.push(cb);
var noExitRuntime = true;
var __abort_js = () => abort("");
var runtimeKeepaliveCounter = 0;
var __emscripten_runtime_keepalive_clear = () => {
noExitRuntime = false;
runtimeKeepaliveCounter = 0;
};
var timers = {};
var handleException = e => {
if (e instanceof ExitStatus || e == "unwind") {
return EXITSTATUS;
}
quit_(1, e);
};
var keepRuntimeAlive = () => noExitRuntime || runtimeKeepaliveCounter > 0;
var _proc_exit = code => {
EXITSTATUS = code;
if (!keepRuntimeAlive()) {
Module["onExit"]?.(code);
ABORT = true;
}
quit_(code, new ExitStatus(code));
};
var exitJS = (status, implicit) => {
EXITSTATUS = status;
_proc_exit(status);
};
var _exit = exitJS;
var maybeExit = () => {
if (!keepRuntimeAlive()) {
try {
_exit(EXITSTATUS);
} catch (e) {
handleException(e);
}
}
};
var callUserCallback = func => {
if (ABORT) {
return;
}
try {
func();
maybeExit();
} catch (e) {
handleException(e);
}
};
var _emscripten_get_now = () => performance.now();
var __setitimer_js = (which, timeout_ms) => {
if (timers[which]) {
clearTimeout(timers[which].id);
delete timers[which];
}
if (!timeout_ms) return 0;
var id = setTimeout(() => {
delete timers[which];
callUserCallback(() => __emscripten_timeout(which, _emscripten_get_now()));
}, timeout_ms);
timers[which] = {
id,
timeout_ms
};
return 0;
};
function _copy_pixels_1(compG_ptr, nb_pixels) {
compG_ptr >>= 2;
const imageData = Module.imageData = new Uint8ClampedArray(nb_pixels);
const compG = HEAP32.subarray(compG_ptr, compG_ptr + nb_pixels);
imageData.set(compG);
}
function _copy_pixels_3(compR_ptr, compG_ptr, compB_ptr, nb_pixels) {
compR_ptr >>= 2;
compG_ptr >>= 2;
compB_ptr >>= 2;
const imageData = Module.imageData = new Uint8ClampedArray(nb_pixels * 3);
const compR = HEAP32.subarray(compR_ptr, compR_ptr + nb_pixels);
const compG = HEAP32.subarray(compG_ptr, compG_ptr + nb_pixels);
const compB = HEAP32.subarray(compB_ptr, compB_ptr + nb_pixels);
for (let i = 0; i < nb_pixels; i++) {
imageData[3 * i] = compR[i];
imageData[3 * i + 1] = compG[i];
imageData[3 * i + 2] = compB[i];
}
}
function _copy_pixels_4(compR_ptr, compG_ptr, compB_ptr, compA_ptr, nb_pixels) {
compR_ptr >>= 2;
compG_ptr >>= 2;
compB_ptr >>= 2;
compA_ptr >>= 2;
const imageData = Module.imageData = new Uint8ClampedArray(nb_pixels * 4);
const compR = HEAP32.subarray(compR_ptr, compR_ptr + nb_pixels);
const compG = HEAP32.subarray(compG_ptr, compG_ptr + nb_pixels);
const compB = HEAP32.subarray(compB_ptr, compB_ptr + nb_pixels);
const compA = HEAP32.subarray(compA_ptr, compA_ptr + nb_pixels);
for (let i = 0; i < nb_pixels; i++) {
imageData[4 * i] = compR[i];
imageData[4 * i + 1] = compG[i];
imageData[4 * i + 2] = compB[i];
imageData[4 * i + 3] = compA[i];
}
}
var getHeapMax = () => 2147483648;
var alignMemory = (size, alignment) => Math.ceil(size / alignment) * alignment;
var growMemory = size => {
var b = wasmMemory.buffer;
var pages = (size - b.byteLength + 65535) / 65536 | 0;
try {
wasmMemory.grow(pages);
updateMemoryViews();
return 1;
} catch (e) {}
};
var _emscripten_resize_heap = requestedSize => {
var oldSize = HEAPU8.length;
requestedSize >>>= 0;
var maxHeapSize = getHeapMax();
if (requestedSize > maxHeapSize) {
return false;
}
for (var cutDown = 1; cutDown <= 4; cutDown *= 2) {
var overGrownHeapSize = oldSize * (1 + .2 / cutDown);
overGrownHeapSize = Math.min(overGrownHeapSize, requestedSize + 100663296);
var newSize = Math.min(maxHeapSize, alignMemory(Math.max(requestedSize, overGrownHeapSize), 65536));
var replacement = growMemory(newSize);
if (replacement) {
return true;
}
}
return false;
};
var ENV = {};
var getExecutableName = () => thisProgram || "./this.program";
var getEnvStrings = () => {
if (!getEnvStrings.strings) {
var lang = (typeof navigator == "object" && navigator.languages && navigator.languages[0] || "C").replace("-", "_") + ".UTF-8";
var env = {
USER: "web_user",
LOGNAME: "web_user",
PATH: "/",
PWD: "/",
HOME: "/home/web_user",
LANG: lang,
_: getExecutableName()
};
for (var x in ENV) {
if (ENV[x] === undefined) delete env[x];else env[x] = ENV[x];
}
var strings = [];
for (var x in env) {
strings.push(`${x}=${env[x]}`);
}
getEnvStrings.strings = strings;
}
return getEnvStrings.strings;
};
var stringToUTF8Array = (str, heap, outIdx, maxBytesToWrite) => {
if (!(maxBytesToWrite > 0)) return 0;
var startIdx = outIdx;
var endIdx = outIdx + maxBytesToWrite - 1;
for (var i = 0; i < str.length; ++i) {
var u = str.charCodeAt(i);
if (u >= 55296 && u <= 57343) {
var u1 = str.charCodeAt(++i);
u = 65536 + ((u & 1023) << 10) | u1 & 1023;
}
if (u <= 127) {
if (outIdx >= endIdx) break;
heap[outIdx++] = u;
} else if (u <= 2047) {
if (outIdx + 1 >= endIdx) break;
heap[outIdx++] = 192 | u >> 6;
heap[outIdx++] = 128 | u & 63;
} else if (u <= 65535) {
if (outIdx + 2 >= endIdx) break;
heap[outIdx++] = 224 | u >> 12;
heap[outIdx++] = 128 | u >> 6 & 63;
heap[outIdx++] = 128 | u & 63;
} else {
if (outIdx + 3 >= endIdx) break;
heap[outIdx++] = 240 | u >> 18;
heap[outIdx++] = 128 | u >> 12 & 63;
heap[outIdx++] = 128 | u >> 6 & 63;
heap[outIdx++] = 128 | u & 63;
}
}
heap[outIdx] = 0;
return outIdx - startIdx;
};
var stringToUTF8 = (str, outPtr, maxBytesToWrite) => stringToUTF8Array(str, HEAPU8, outPtr, maxBytesToWrite);
var _environ_get = (__environ, environ_buf) => {
var bufSize = 0;
var envp = 0;
for (var string of getEnvStrings()) {
var ptr = environ_buf + bufSize;
HEAPU32[__environ + envp >> 2] = ptr;
bufSize += stringToUTF8(string, ptr, Infinity) + 1;
envp += 4;
}
return 0;
};
var lengthBytesUTF8 = str => {
var len = 0;
for (var i = 0; i < str.length; ++i) {
var c = str.charCodeAt(i);
if (c <= 127) {
len++;
} else if (c <= 2047) {
len += 2;
} else if (c >= 55296 && c <= 57343) {
len += 4;
++i;
} else {
len += 3;
}
}
return len;
};
var _environ_sizes_get = (penviron_count, penviron_buf_size) => {
var strings = getEnvStrings();
HEAPU32[penviron_count >> 2] = strings.length;
var bufSize = 0;
for (var string of strings) {
bufSize += lengthBytesUTF8(string) + 1;
}
HEAPU32[penviron_buf_size >> 2] = bufSize;
return 0;
};
var _fd_close = fd => 52;
var INT53_MAX = 9007199254740992;
var INT53_MIN = -9007199254740992;
var bigintToI53Checked = num => num < INT53_MIN || num > INT53_MAX ? NaN : Number(num);
function _fd_seek(fd, offset, whence, newOffset) {
offset = bigintToI53Checked(offset);
return 70;
}
var printCharBuffers = [null, [], []];
var UTF8Decoder = typeof TextDecoder != "undefined" ? new TextDecoder() : undefined;
var UTF8ArrayToString = (heapOrArray, idx = 0, maxBytesToRead = NaN) => {
var endIdx = idx + maxBytesToRead;
var endPtr = idx;
while (heapOrArray[endPtr] && !(endPtr >= endIdx)) ++endPtr;
if (endPtr - idx > 16 && heapOrArray.buffer && UTF8Decoder) {
return UTF8Decoder.decode(heapOrArray.subarray(idx, endPtr));
}
var str = "";
while (idx < endPtr) {
var u0 = heapOrArray[idx++];
if (!(u0 & 128)) {
str += String.fromCharCode(u0);
continue;
}
var u1 = heapOrArray[idx++] & 63;
if ((u0 & 224) == 192) {
str += String.fromCharCode((u0 & 31) << 6 | u1);
continue;
}
var u2 = heapOrArray[idx++] & 63;
if ((u0 & 240) == 224) {
u0 = (u0 & 15) << 12 | u1 << 6 | u2;
} else {
u0 = (u0 & 7) << 18 | u1 << 12 | u2 << 6 | heapOrArray[idx++] & 63;
}
if (u0 < 65536) {
str += String.fromCharCode(u0);
} else {
var ch = u0 - 65536;
str += String.fromCharCode(55296 | ch >> 10, 56320 | ch & 1023);
}
}
return str;
};
var printChar = (stream, curr) => {
var buffer = printCharBuffers[stream];
if (curr === 0 || curr === 10) {
(stream === 1 ? out : err)(UTF8ArrayToString(buffer));
buffer.length = 0;
} else {
buffer.push(curr);
}
};
var UTF8ToString = (ptr, maxBytesToRead) => ptr ? UTF8ArrayToString(HEAPU8, ptr, maxBytesToRead) : "";
var _fd_write = (fd, iov, iovcnt, pnum) => {
var num = 0;
for (var i = 0; i < iovcnt; i++) {
var ptr = HEAPU32[iov >> 2];
var len = HEAPU32[iov + 4 >> 2];
iov += 8;
for (var j = 0; j < len; j++) {
printChar(fd, HEAPU8[ptr + j]);
}
num += len;
}
HEAPU32[pnum >> 2] = num;
return 0;
};
function _gray_to_rgba(compG_ptr, nb_pixels) {
compG_ptr >>= 2;
const imageData = Module.imageData = new Uint8ClampedArray(nb_pixels * 4);
const compG = HEAP32.subarray(compG_ptr, compG_ptr + nb_pixels);
for (let i = 0; i < nb_pixels; i++) {
imageData[4 * i] = imageData[4 * i + 1] = imageData[4 * i + 2] = compG[i];
imageData[4 * i + 3] = 255;
}
}
function _graya_to_rgba(compG_ptr, compA_ptr, nb_pixels) {
compG_ptr >>= 2;
compA_ptr >>= 2;
const imageData = Module.imageData = new Uint8ClampedArray(nb_pixels * 4);
const compG = HEAP32.subarray(compG_ptr, compG_ptr + nb_pixels);
const compA = HEAP32.subarray(compA_ptr, compA_ptr + nb_pixels);
for (let i = 0; i < nb_pixels; i++) {
imageData[4 * i] = imageData[4 * i + 1] = imageData[4 * i + 2] = compG[i];
imageData[4 * i + 3] = compA[i];
}
}
function _jsPrintWarning(message_ptr) {
const message = UTF8ToString(message_ptr);
(Module.warn || console.warn)(`OpenJPEG: ${message}`);
}
function _rgb_to_rgba(compR_ptr, compG_ptr, compB_ptr, nb_pixels) {
compR_ptr >>= 2;
compG_ptr >>= 2;
compB_ptr >>= 2;
const imageData = Module.imageData = new Uint8ClampedArray(nb_pixels * 4);
const compR = HEAP32.subarray(compR_ptr, compR_ptr + nb_pixels);
const compG = HEAP32.subarray(compG_ptr, compG_ptr + nb_pixels);
const compB = HEAP32.subarray(compB_ptr, compB_ptr + nb_pixels);
for (let i = 0; i < nb_pixels; i++) {
imageData[4 * i] = compR[i];
imageData[4 * i + 1] = compG[i];
imageData[4 * i + 2] = compB[i];
imageData[4 * i + 3] = 255;
}
}
function _storeErrorMessage(message_ptr) {
const message = UTF8ToString(message_ptr);
if (!Module.errorMessages) {
Module.errorMessages = message;
} else {
Module.errorMessages += "\n" + message;
}
}
var writeArrayToMemory = (array, buffer) => {
HEAP8.set(array, buffer);
};
if (Module["noExitRuntime"]) noExitRuntime = Module["noExitRuntime"];
if (Module["print"]) out = Module["print"];
if (Module["printErr"]) err = Module["printErr"];
if (Module["wasmBinary"]) wasmBinary = Module["wasmBinary"];
if (Module["arguments"]) arguments_ = Module["arguments"];
if (Module["thisProgram"]) thisProgram = Module["thisProgram"];
Module["writeArrayToMemory"] = writeArrayToMemory;
var wasmImports = {
l: __abort_js,
k: __emscripten_runtime_keepalive_clear,
m: __setitimer_js,
g: _copy_pixels_1,
f: _copy_pixels_3,
e: _copy_pixels_4,
n: _emscripten_resize_heap,
p: _environ_get,
q: _environ_sizes_get,
b: _fd_close,
o: _fd_seek,
c: _fd_write,
r: _gray_to_rgba,
i: _graya_to_rgba,
d: _jsPrintWarning,
j: _proc_exit,
h: _rgb_to_rgba,
a: _storeErrorMessage
};
var wasmExports = await createWasm();
var ___wasm_call_ctors = wasmExports["t"];
var _malloc = Module["_malloc"] = wasmExports["u"];
var _free = Module["_free"] = wasmExports["v"];
var _jp2_decode = Module["_jp2_decode"] = wasmExports["w"];
var __emscripten_timeout = wasmExports["x"];
function run() {
if (runDependencies > 0) {
dependenciesFulfilled = run;
return;
}
preRun();
if (runDependencies > 0) {
dependenciesFulfilled = run;
return;
}
function doRun() {
Module["calledRun"] = true;
if (ABORT) return;
initRuntime();
readyPromiseResolve(Module);
Module["onRuntimeInitialized"]?.();
postRun();
}
if (Module["setStatus"]) {
Module["setStatus"]("Running...");
setTimeout(() => {
setTimeout(() => Module["setStatus"](""), 1);
doRun();
}, 1);
} else {
doRun();
}
}
function preInit() {
if (Module["preInit"]) {
if (typeof Module["preInit"] == "function") Module["preInit"] = [Module["preInit"]];
while (Module["preInit"].length > 0) {
Module["preInit"].shift()();
}
}
}
preInit();
run();
moduleRtn = readyPromise;
return moduleRtn;
};
})();
/* harmony default export */ const openjpeg = (OpenJPEG);
;// ./src/core/stream.js
class Stream extends base_stream_BaseStream {
constructor(arrayBuffer, start, length, dict) {
super();
this.bytes = arrayBuffer instanceof Uint8Array ? arrayBuffer : new Uint8Array(arrayBuffer);
this.start = start || 0;
this.pos = this.start;
this.end = start + length || this.bytes.length;
this.dict = dict;
}
get length() {
return this.end - this.start;
}
get isEmpty() {
return this.length === 0;
}
getByte() {
if (this.pos >= this.end) {
return -1;
}
return this.bytes[this.pos++];
}
getBytes(length) {
const bytes = this.bytes;
const pos = this.pos;
const strEnd = this.end;
if (!length) {
return bytes.subarray(pos, strEnd);
}
let end = pos + length;
if (end > strEnd) {
end = strEnd;
}
this.pos = end;
return bytes.subarray(pos, end);
}
getByteRange(begin, end) {
if (begin < 0) {
begin = 0;
}
if (end > this.end) {
end = this.end;
}
return this.bytes.subarray(begin, end);
}
reset() {
this.pos = this.start;
}
moveStart() {
this.start = this.pos;
}
makeSubStream(start, length, dict = null) {
return new Stream(this.bytes.buffer, start, length, dict);
}
}
class StringStream extends Stream {
constructor(str) {
super(stringToBytes(str));
}
}
class NullStream extends Stream {
constructor() {
super(new Uint8Array(0));
}
}
;// ./src/core/jpx.js
class JpxError extends BaseException {
constructor(msg) {
super(msg, "JpxError");
}
}
class JpxImage {
static #buffer = null;
static #handler = null;
static #modulePromise = null;
static #useWasm = true;
static #useWorkerFetch = true;
static #wasmUrl = null;
static setOptions({
handler,
useWasm,
useWorkerFetch,
wasmUrl
}) {
this.#useWasm = useWasm;
this.#useWorkerFetch = useWorkerFetch;
this.#wasmUrl = wasmUrl;
if (!useWorkerFetch) {
this.#handler = handler;
}
}
static async #getJsModule(fallbackCallback) {
const path = `${this.#wasmUrl}openjpeg_nowasm_fallback.js`;
let instance = null;
try {
const mod = await import(
/*webpackIgnore: true*/
/*@vite-ignore*/
path);
instance = mod.default();
} catch (e) {
util_warn(`JpxImage#getJsModule: ${e}`);
}
fallbackCallback(instance);
}
static async #instantiateWasm(fallbackCallback, imports, successCallback) {
const filename = "openjpeg.wasm";
try {
if (!this.#buffer) {
if (this.#useWorkerFetch) {
this.#buffer = await fetchBinaryData(`${this.#wasmUrl}${filename}`);
} else {
this.#buffer = await this.#handler.sendWithPromise("FetchBinaryData", {
type: "wasmFactory",
filename
});
}
}
const results = await WebAssembly.instantiate(this.#buffer, imports);
return successCallback(results.instance);
} catch (reason) {
util_warn(`JpxImage#instantiateWasm: ${reason}`);
this.#getJsModule(fallbackCallback);
return null;
} finally {
this.#handler = null;
}
}
static async decode(bytes, {
numComponents = 4,
isIndexedColormap = false,
smaskInData = false,
reducePower = 0
} = {}) {
if (!this.#modulePromise) {
const {
promise,
resolve
} = Promise.withResolvers();
const promises = [promise];
if (!this.#useWasm) {
this.#getJsModule(resolve);
} else {
promises.push(openjpeg({
warn: util_warn,
instantiateWasm: this.#instantiateWasm.bind(this, resolve)
}));
}
this.#modulePromise = Promise.race(promises);
}
const module = await this.#modulePromise;
if (!module) {
throw new JpxError("OpenJPEG failed to initialize");
}
let ptr;
try {
const size = bytes.length;
ptr = module._malloc(size);
module.writeArrayToMemory(bytes, ptr);
const ret = module._jp2_decode(ptr, size, numComponents > 0 ? numComponents : 0, !!isIndexedColormap, !!smaskInData, reducePower);
if (ret) {
const {
errorMessages
} = module;
if (errorMessages) {
delete module.errorMessages;
throw new JpxError(errorMessages);
}
throw new JpxError("Unknown error");
}
const {
imageData
} = module;
module.imageData = null;
return imageData;
} finally {
if (ptr) {
module._free(ptr);
}
}
}
static cleanup() {
this.#modulePromise = null;
}
static parseImageProperties(stream) {
if (stream instanceof ArrayBuffer || ArrayBuffer.isView(stream)) {
stream = new Stream(stream);
} else {
throw new JpxError("Invalid data format, must be a TypedArray.");
}
let newByte = stream.getByte();
while (newByte >= 0) {
const oldByte = newByte;
newByte = stream.getByte();
const code = oldByte << 8 | newByte;
if (code === 0xff51) {
stream.skip(4);
const Xsiz = stream.getInt32() >>> 0;
const Ysiz = stream.getInt32() >>> 0;
const XOsiz = stream.getInt32() >>> 0;
const YOsiz = stream.getInt32() >>> 0;
stream.skip(16);
const Csiz = stream.getUint16();
return {
width: Xsiz - XOsiz,
height: Ysiz - YOsiz,
bitsPerComponent: 8,
componentsCount: Csiz
};
}
}
throw new JpxError("No size marker found in JPX stream");
}
}
;// ./src/pdf.image_decoders.js
globalThis.pdfjsImageDecoders = {
getVerbosityLevel: getVerbosityLevel,
Jbig2Error: Jbig2Error,
Jbig2Image: Jbig2Image,
JpegError: JpegError,
JpegImage: JpegImage,
JpxError: JpxError,
JpxImage: JpxImage,
setVerbosityLevel: setVerbosityLevel,
VerbosityLevel: VerbosityLevel
};
export { Jbig2Error, Jbig2Image, JpegError, JpegImage, JpxError, JpxImage, VerbosityLevel, getVerbosityLevel, setVerbosityLevel };
//# sourceMappingURL=pdf.image_decoders.mjs.map
Reference in New Issue View Git Blame Copy Permalink