// Modified embenchen to direct to asm-wasm. // Flags: --validate-asm --allow-natives-syntax var EXPECTED_OUTPUT = '123456789\n' + '213456789\n' + '231456789\n' + '321456789\n' + '312456789\n' + '132456789\n' + '234156789\n' + '324156789\n' + '342156789\n' + '432156789\n' + '423156789\n' + '243156789\n' + '341256789\n' + '431256789\n' + '413256789\n' + '143256789\n' + '134256789\n' + '314256789\n' + '412356789\n' + '142356789\n' + '124356789\n' + '214356789\n' + '241356789\n' + '421356789\n' + '234516789\n' + '324516789\n' + '342516789\n' + '432516789\n' + '423516789\n' + '243516789\n' + 'Pfannkuchen(9) = 30.\n'; var Module = { arguments: [1], print: function(x) {Module.printBuffer += x + '\n';}, preRun: [function() {Module.printBuffer = ''}], postRun: [function() { assertEquals(EXPECTED_OUTPUT, Module.printBuffer); }], }; // The Module object: Our interface to the outside world. We import // and export values on it, and do the work to get that through // closure compiler if necessary. There are various ways Module can be used: // 1. Not defined. We create it here // 2. A function parameter, function(Module) { ..generated code.. } // 3. pre-run appended it, var Module = {}; ..generated code.. // 4. External script tag defines var Module. // We need to do an eval in order to handle the closure compiler // case, where this code here is minified but Module was defined // elsewhere (e.g. case 4 above). We also need to check if Module // already exists (e.g. case 3 above). // Note that if you want to run closure, and also to use Module // after the generated code, you will need to define var Module = {}; // before the code. Then that object will be used in the code, and you // can continue to use Module afterwards as well. var Module; if (!Module) Module = (typeof Module !== 'undefined' ? Module : null) || {}; // Sometimes an existing Module object exists with properties // meant to overwrite the default module functionality. Here // we collect those properties and reapply _after_ we configure // the current environment's defaults to avoid having to be so // defensive during initialization. var moduleOverrides = {}; for (var key in Module) { if (Module.hasOwnProperty(key)) { moduleOverrides[key] = Module[key]; } } // The environment setup code below is customized to use Module. // *** Environment setup code *** var ENVIRONMENT_IS_NODE = typeof process === 'object' && typeof require === 'function'; var ENVIRONMENT_IS_WEB = typeof window === 'object'; var ENVIRONMENT_IS_WORKER = typeof importScripts === 'function'; var ENVIRONMENT_IS_SHELL = !ENVIRONMENT_IS_WEB && !ENVIRONMENT_IS_NODE && !ENVIRONMENT_IS_WORKER; if (ENVIRONMENT_IS_NODE) { // Expose functionality in the same simple way that the shells work // Note that we pollute the global namespace here, otherwise we break in node if (!Module['print']) Module['print'] = function print(x) { process['stdout'].write(x + '\n'); }; if (!Module['printErr']) Module['printErr'] = function printErr(x) { process['stderr'].write(x + '\n'); }; var nodeFS = require('fs'); var nodePath = require('path'); Module['read'] = function read(filename, binary) { filename = nodePath['normalize'](filename); var ret = nodeFS['readFileSync'](filename); // The path is absolute if the normalized version is the same as the resolved. if (!ret && filename != nodePath['resolve'](filename)) { filename = path.join(__dirname, '..', 'src', filename); ret = nodeFS['readFileSync'](filename); } if (ret && !binary) ret = ret.toString(); return ret; }; Module['readBinary'] = function readBinary(filename) { return Module['read'](filename, true) }; Module['load'] = function load(f) { globalEval(read(f)); }; Module['arguments'] = process['argv'].slice(2); module['exports'] = Module; } else if (ENVIRONMENT_IS_SHELL) { if (!Module['print']) Module['print'] = print; if (typeof printErr != 'undefined') Module['printErr'] = printErr; // not present in v8 or older sm if (typeof read != 'undefined') { Module['read'] = read; } else { Module['read'] = function read() { throw 'no read() available (jsc?)' }; } Module['readBinary'] = function readBinary(f) { return read(f, 'binary'); }; if (typeof scriptArgs != 'undefined') { Module['arguments'] = scriptArgs; } else if (typeof arguments != 'undefined') { Module['arguments'] = arguments; } this['Module'] = Module; eval("if (typeof gc === 'function' && gc.toString().indexOf('[native code]') > 0) var gc = undefined"); // wipe out the SpiderMonkey shell 'gc' function, which can confuse closure (uses it as a minified name, and it is then initted to a non-falsey value unexpectedly) } else if (ENVIRONMENT_IS_WEB || ENVIRONMENT_IS_WORKER) { Module['read'] = function read(url) { var xhr = new XMLHttpRequest(); xhr.open('GET', url, false); xhr.send(null); return xhr.responseText; }; if (typeof arguments != 'undefined') { Module['arguments'] = arguments; } if (typeof console !== 'undefined') { if (!Module['print']) Module['print'] = function print(x) { console.log(x); }; if (!Module['printErr']) Module['printErr'] = function printErr(x) { console.log(x); }; } else { // Probably a worker, and without console.log. We can do very little here... var TRY_USE_DUMP = false; if (!Module['print']) Module['print'] = (TRY_USE_DUMP && (typeof(dump) !== "undefined") ? (function(x) { dump(x); }) : (function(x) { // self.postMessage(x); // enable this if you want stdout to be sent as messages })); } if (ENVIRONMENT_IS_WEB) { window['Module'] = Module; } else { Module['load'] = importScripts; } } else { // Unreachable because SHELL is dependant on the others throw 'Unknown runtime environment. Where are we?'; } function globalEval(x) { eval.call(null, x); } if (!Module['load'] == 'undefined' && Module['read']) { Module['load'] = function load(f) { globalEval(Module['read'](f)); }; } if (!Module['print']) { Module['print'] = function(){}; } if (!Module['printErr']) { Module['printErr'] = Module['print']; } if (!Module['arguments']) { Module['arguments'] = []; } // *** Environment setup code *** // Closure helpers Module.print = Module['print']; Module.printErr = Module['printErr']; // Callbacks Module['preRun'] = []; Module['postRun'] = []; // Merge back in the overrides for (var key in moduleOverrides) { if (moduleOverrides.hasOwnProperty(key)) { Module[key] = moduleOverrides[key]; } } // === Auto-generated preamble library stuff === //======================================== // Runtime code shared with compiler //======================================== var Runtime = { stackSave: function () { return STACKTOP; }, stackRestore: function (stackTop) { STACKTOP = stackTop; }, forceAlign: function (target, quantum) { quantum = quantum || 4; if (quantum == 1) return target; if (isNumber(target) && isNumber(quantum)) { return Math.ceil(target/quantum)*quantum; } else if (isNumber(quantum) && isPowerOfTwo(quantum)) { return '(((' +target + ')+' + (quantum-1) + ')&' + -quantum + ')'; } return 'Math.ceil((' + target + ')/' + quantum + ')*' + quantum; }, isNumberType: function (type) { return type in Runtime.INT_TYPES || type in Runtime.FLOAT_TYPES; }, isPointerType: function isPointerType(type) { return type[type.length-1] == '*'; }, isStructType: function isStructType(type) { if (isPointerType(type)) return false; if (isArrayType(type)) return true; if (/?/.test(type)) return true; // { i32, i8 } etc. - anonymous struct types // See comment in isStructPointerType() return type[0] == '%'; }, INT_TYPES: {"i1":0,"i8":0,"i16":0,"i32":0,"i64":0}, FLOAT_TYPES: {"float":0,"double":0}, or64: function (x, y) { var l = (x | 0) | (y | 0); var h = (Math.round(x / 4294967296) | Math.round(y / 4294967296)) * 4294967296; return l + h; }, and64: function (x, y) { var l = (x | 0) & (y | 0); var h = (Math.round(x / 4294967296) & Math.round(y / 4294967296)) * 4294967296; return l + h; }, xor64: function (x, y) { var l = (x | 0) ^ (y | 0); var h = (Math.round(x / 4294967296) ^ Math.round(y / 4294967296)) * 4294967296; return l + h; }, getNativeTypeSize: function (type) { switch (type) { case 'i1': case 'i8': return 1; case 'i16': return 2; case 'i32': return 4; case 'i64': return 8; case 'float': return 4; case 'double': return 8; default: { if (type[type.length-1] === '*') { return Runtime.QUANTUM_SIZE; // A pointer } else if (type[0] === 'i') { var bits = parseInt(type.substr(1)); assert(bits % 8 === 0); return bits/8; } else { return 0; } } } }, getNativeFieldSize: function (type) { return Math.max(Runtime.getNativeTypeSize(type), Runtime.QUANTUM_SIZE); }, dedup: function dedup(items, ident) { var seen = {}; if (ident) { return items.filter(function(item) { if (seen[item[ident]]) return false; seen[item[ident]] = true; return true; }); } else { return items.filter(function(item) { if (seen[item]) return false; seen[item] = true; return true; }); } }, set: function set() { var args = typeof arguments[0] === 'object' ? arguments[0] : arguments; var ret = {}; for (var i = 0; i < args.length; i++) { ret[args[i]] = 0; } return ret; }, STACK_ALIGN: 8, getAlignSize: function (type, size, vararg) { // we align i64s and doubles on 64-bit boundaries, unlike x86 if (!vararg && (type == 'i64' || type == 'double')) return 8; if (!type) return Math.min(size, 8); // align structures internally to 64 bits return Math.min(size || (type ? Runtime.getNativeFieldSize(type) : 0), Runtime.QUANTUM_SIZE); }, calculateStructAlignment: function calculateStructAlignment(type) { type.flatSize = 0; type.alignSize = 0; var diffs = []; var prev = -1; var index = 0; type.flatIndexes = type.fields.map(function(field) { index++; var size, alignSize; if (Runtime.isNumberType(field) || Runtime.isPointerType(field)) { size = Runtime.getNativeTypeSize(field); // pack char; char; in structs, also char[X]s. alignSize = Runtime.getAlignSize(field, size); } else if (Runtime.isStructType(field)) { if (field[1] === '0') { // this is [0 x something]. When inside another structure like here, it must be at the end, // and it adds no size // XXX this happens in java-nbody for example... assert(index === type.fields.length, 'zero-length in the middle!'); size = 0; if (Types.types[field]) { alignSize = Runtime.getAlignSize(null, Types.types[field].alignSize); } else { alignSize = type.alignSize || QUANTUM_SIZE; } } else { size = Types.types[field].flatSize; alignSize = Runtime.getAlignSize(null, Types.types[field].alignSize); } } else if (field[0] == 'b') { // bN, large number field, like a [N x i8] size = field.substr(1)|0; alignSize = 1; } else if (field[0] === '<') { // vector type size = alignSize = Types.types[field].flatSize; // fully aligned } else if (field[0] === 'i') { // illegal integer field, that could not be legalized because it is an internal structure field // it is ok to have such fields, if we just use them as markers of field size and nothing more complex size = alignSize = parseInt(field.substr(1))/8; assert(size % 1 === 0, 'cannot handle non-byte-size field ' + field); } else { assert(false, 'invalid type for calculateStructAlignment'); } if (type.packed) alignSize = 1; type.alignSize = Math.max(type.alignSize, alignSize); var curr = Runtime.alignMemory(type.flatSize, alignSize); // if necessary, place this on aligned memory type.flatSize = curr + size; if (prev >= 0) { diffs.push(curr-prev); } prev = curr; return curr; }); if (type.name_ && type.name_[0] === '[') { // arrays have 2 elements, so we get the proper difference. then we scale here. that way we avoid // allocating a potentially huge array for [999999 x i8] etc. type.flatSize = parseInt(type.name_.substr(1))*type.flatSize/2; } type.flatSize = Runtime.alignMemory(type.flatSize, type.alignSize); if (diffs.length == 0) { type.flatFactor = type.flatSize; } else if (Runtime.dedup(diffs).length == 1) { type.flatFactor = diffs[0]; } type.needsFlattening = (type.flatFactor != 1); return type.flatIndexes; }, generateStructInfo: function (struct, typeName, offset) { var type, alignment; if (typeName) { offset = offset || 0; type = (typeof Types === 'undefined' ? Runtime.typeInfo : Types.types)[typeName]; if (!type) return null; if (type.fields.length != struct.length) { printErr('Number of named fields must match the type for ' + typeName + ': possibly duplicate struct names. Cannot return structInfo'); return null; } alignment = type.flatIndexes; } else { var type = { fields: struct.map(function(item) { return item[0] }) }; alignment = Runtime.calculateStructAlignment(type); } var ret = { __size__: type.flatSize }; if (typeName) { struct.forEach(function(item, i) { if (typeof item === 'string') { ret[item] = alignment[i] + offset; } else { // embedded struct var key; for (var k in item) key = k; ret[key] = Runtime.generateStructInfo(item[key], type.fields[i], alignment[i]); } }); } else { struct.forEach(function(item, i) { ret[item[1]] = alignment[i]; }); } return ret; }, dynCall: function (sig, ptr, args) { if (args && args.length) { if (!args.splice) args = Array.prototype.slice.call(args); args.splice(0, 0, ptr); return Module['dynCall_' + sig].apply(null, args); } else { return Module['dynCall_' + sig].call(null, ptr); } }, functionPointers: [], addFunction: function (func) { for (var i = 0; i < Runtime.functionPointers.length; i++) { if (!Runtime.functionPointers[i]) { Runtime.functionPointers[i] = func; return 2*(1 + i); } } throw 'Finished up all reserved function pointers. Use a higher value for RESERVED_FUNCTION_POINTERS.'; }, removeFunction: function (index) { Runtime.functionPointers[(index-2)/2] = null; }, getAsmConst: function (code, numArgs) { // code is a constant string on the heap, so we can cache these if (!Runtime.asmConstCache) Runtime.asmConstCache = {}; var func = Runtime.asmConstCache[code]; if (func) return func; var args = []; for (var i = 0; i < numArgs; i++) { args.push(String.fromCharCode(36) + i); // $0, $1 etc } var source = Pointer_stringify(code); if (source[0] === '"') { // tolerate EM_ASM("..code..") even though EM_ASM(..code..) is correct if (source.indexOf('"', 1) === source.length-1) { source = source.substr(1, source.length-2); } else { // something invalid happened, e.g. EM_ASM("..code($0)..", input) abort('invalid EM_ASM input |' + source + '|. Please use EM_ASM(..code..) (no quotes) or EM_ASM({ ..code($0).. }, input) (to input values)'); } } try { var evalled = eval('(function(' + args.join(',') + '){ ' + source + ' })'); // new Function does not allow upvars in node } catch(e) { Module.printErr('error in executing inline EM_ASM code: ' + e + ' on: \n\n' + source + '\n\nwith args |' + args + '| (make sure to use the right one out of EM_ASM, EM_ASM_ARGS, etc.)'); throw e; } return Runtime.asmConstCache[code] = evalled; }, warnOnce: function (text) { if (!Runtime.warnOnce.shown) Runtime.warnOnce.shown = {}; if (!Runtime.warnOnce.shown[text]) { Runtime.warnOnce.shown[text] = 1; Module.printErr(text); } }, funcWrappers: {}, getFuncWrapper: function (func, sig) { assert(sig); if (!Runtime.funcWrappers[func]) { Runtime.funcWrappers[func] = function dynCall_wrapper() { return Runtime.dynCall(sig, func, arguments); }; } return Runtime.funcWrappers[func]; }, UTF8Processor: function () { var buffer = []; var needed = 0; this.processCChar = function (code) { code = code & 0xFF; if (buffer.length == 0) { if ((code & 0x80) == 0x00) { // 0xxxxxxx return String.fromCharCode(code); } buffer.push(code); if ((code & 0xE0) == 0xC0) { // 110xxxxx needed = 1; } else if ((code & 0xF0) == 0xE0) { // 1110xxxx needed = 2; } else { // 11110xxx needed = 3; } return ''; } if (needed) { buffer.push(code); needed--; if (needed > 0) return ''; } var c1 = buffer[0]; var c2 = buffer[1]; var c3 = buffer[2]; var c4 = buffer[3]; var ret; if (buffer.length == 2) { ret = String.fromCharCode(((c1 & 0x1F) << 6) | (c2 & 0x3F)); } else if (buffer.length == 3) { ret = String.fromCharCode(((c1 & 0x0F) << 12) | ((c2 & 0x3F) << 6) | (c3 & 0x3F)); } else { // http://mathiasbynens.be/notes/javascript-encoding#surrogate-formulae var codePoint = ((c1 & 0x07) << 18) | ((c2 & 0x3F) << 12) | ((c3 & 0x3F) << 6) | (c4 & 0x3F); ret = String.fromCharCode( Math.floor((codePoint - 0x10000) / 0x400) + 0xD800, (codePoint - 0x10000) % 0x400 + 0xDC00); } buffer.length = 0; return ret; } this.processJSString = function processJSString(string) { /* TODO: use TextEncoder when present, var encoder = new TextEncoder(); encoder['encoding'] = "utf-8"; var utf8Array = encoder['encode'](aMsg.data); */ string = unescape(encodeURIComponent(string)); var ret = []; for (var i = 0; i < string.length; i++) { ret.push(string.charCodeAt(i)); } return ret; } }, getCompilerSetting: function (name) { throw 'You must build with -s RETAIN_COMPILER_SETTINGS=1 for Runtime.getCompilerSetting or emscripten_get_compiler_setting to work'; }, stackAlloc: function (size) { var ret = STACKTOP;STACKTOP = (STACKTOP + size)|0;STACKTOP = (((STACKTOP)+7)&-8); return ret; }, staticAlloc: function (size) { var ret = STATICTOP;STATICTOP = (STATICTOP + size)|0;STATICTOP = (((STATICTOP)+7)&-8); return ret; }, dynamicAlloc: function (size) { var ret = DYNAMICTOP;DYNAMICTOP = (DYNAMICTOP + size)|0;DYNAMICTOP = (((DYNAMICTOP)+7)&-8); if (DYNAMICTOP >= TOTAL_MEMORY) enlargeMemory();; return ret; }, alignMemory: function (size,quantum) { var ret = size = Math.ceil((size)/(quantum ? quantum : 8))*(quantum ? quantum : 8); return ret; }, makeBigInt: function (low,high,unsigned) { var ret = (unsigned ? ((+((low>>>0)))+((+((high>>>0)))*(+4294967296))) : ((+((low>>>0)))+((+((high|0)))*(+4294967296)))); return ret; }, GLOBAL_BASE: 8, QUANTUM_SIZE: 4, __dummy__: 0 } Module['Runtime'] = Runtime; //======================================== // Runtime essentials //======================================== var __THREW__ = 0; // Used in checking for thrown exceptions. var ABORT = false; // whether we are quitting the application. no code should run after this. set in exit() and abort() var EXITSTATUS = 0; var undef = 0; // tempInt is used for 32-bit signed values or smaller. tempBigInt is used // for 32-bit unsigned values or more than 32 bits. TODO: audit all uses of tempInt var tempValue, tempInt, tempBigInt, tempInt2, tempBigInt2, tempPair, tempBigIntI, tempBigIntR, tempBigIntS, tempBigIntP, tempBigIntD, tempDouble, tempFloat; var tempI64, tempI64b; var tempRet0, tempRet1, tempRet2, tempRet3, tempRet4, tempRet5, tempRet6, tempRet7, tempRet8, tempRet9; function assert(condition, text) { if (!condition) { abort('Assertion failed: ' + text); } } var globalScope = this; // C calling interface. A convenient way to call C functions (in C files, or // defined with extern "C"). // // Note: LLVM optimizations can inline and remove functions, after which you will not be // able to call them. Closure can also do so. To avoid that, add your function to // the exports using something like // // -s EXPORTED_FUNCTIONS='["_main", "_myfunc"]' // // @param ident The name of the C function (note that C++ functions will be name-mangled - use extern "C") // @param returnType The return type of the function, one of the JS types 'number', 'string' or 'array' (use 'number' for any C pointer, and // 'array' for JavaScript arrays and typed arrays; note that arrays are 8-bit). // @param argTypes An array of the types of arguments for the function (if there are no arguments, this can be ommitted). Types are as in returnType, // except that 'array' is not possible (there is no way for us to know the length of the array) // @param args An array of the arguments to the function, as native JS values (as in returnType) // Note that string arguments will be stored on the stack (the JS string will become a C string on the stack). // @return The return value, as a native JS value (as in returnType) function ccall(ident, returnType, argTypes, args) { return ccallFunc(getCFunc(ident), returnType, argTypes, args); } Module["ccall"] = ccall; // Returns the C function with a specified identifier (for C++, you need to do manual name mangling) function getCFunc(ident) { try { var func = Module['_' + ident]; // closure exported function if (!func) func = eval('_' + ident); // explicit lookup } catch(e) { } assert(func, 'Cannot call unknown function ' + ident + ' (perhaps LLVM optimizations or closure removed it?)'); return func; } // Internal function that does a C call using a function, not an identifier function ccallFunc(func, returnType, argTypes, args) { var stack = 0; function toC(value, type) { if (type == 'string') { if (value === null || value === undefined || value === 0) return 0; // null string value = intArrayFromString(value); type = 'array'; } if (type == 'array') { if (!stack) stack = Runtime.stackSave(); var ret = Runtime.stackAlloc(value.length); writeArrayToMemory(value, ret); return ret; } return value; } function fromC(value, type) { if (type == 'string') { return Pointer_stringify(value); } assert(type != 'array'); return value; } var i = 0; var cArgs = args ? args.map(function(arg) { return toC(arg, argTypes[i++]); }) : []; var ret = fromC(func.apply(null, cArgs), returnType); if (stack) Runtime.stackRestore(stack); return ret; } // Returns a native JS wrapper for a C function. This is similar to ccall, but // returns a function you can call repeatedly in a normal way. For example: // // var my_function = cwrap('my_c_function', 'number', ['number', 'number']); // alert(my_function(5, 22)); // alert(my_function(99, 12)); // function cwrap(ident, returnType, argTypes) { var func = getCFunc(ident); return function() { return ccallFunc(func, returnType, argTypes, Array.prototype.slice.call(arguments)); } } Module["cwrap"] = cwrap; // Sets a value in memory in a dynamic way at run-time. Uses the // type data. This is the same as makeSetValue, except that // makeSetValue is done at compile-time and generates the needed // code then, whereas this function picks the right code at // run-time. // Note that setValue and getValue only do *aligned* writes and reads! // Note that ccall uses JS types as for defining types, while setValue and // getValue need LLVM types ('i8', 'i32') - this is a lower-level operation function setValue(ptr, value, type, noSafe) { type = type || 'i8'; if (type.charAt(type.length-1) === '*') type = 'i32'; // pointers are 32-bit switch(type) { case 'i1': HEAP8[(ptr)]=value; break; case 'i8': HEAP8[(ptr)]=value; break; case 'i16': HEAP16[((ptr)>>1)]=value; break; case 'i32': HEAP32[((ptr)>>2)]=value; break; case 'i64': (tempI64 = [value>>>0,(tempDouble=value,(+(Math_abs(tempDouble))) >= (+1) ? (tempDouble > (+0) ? ((Math_min((+(Math_floor((tempDouble)/(+4294967296)))), (+4294967295)))|0)>>>0 : (~~((+(Math_ceil((tempDouble - +(((~~(tempDouble)))>>>0))/(+4294967296))))))>>>0) : 0)],HEAP32[((ptr)>>2)]=tempI64[0],HEAP32[(((ptr)+(4))>>2)]=tempI64[1]); break; case 'float': HEAPF32[((ptr)>>2)]=value; break; case 'double': HEAPF64[((ptr)>>3)]=value; break; default: abort('invalid type for setValue: ' + type); } } Module['setValue'] = setValue; // Parallel to setValue. function getValue(ptr, type, noSafe) { type = type || 'i8'; if (type.charAt(type.length-1) === '*') type = 'i32'; // pointers are 32-bit switch(type) { case 'i1': return HEAP8[(ptr)]; case 'i8': return HEAP8[(ptr)]; case 'i16': return HEAP16[((ptr)>>1)]; case 'i32': return HEAP32[((ptr)>>2)]; case 'i64': return HEAP32[((ptr)>>2)]; case 'float': return HEAPF32[((ptr)>>2)]; case 'double': return HEAPF64[((ptr)>>3)]; default: abort('invalid type for setValue: ' + type); } return null; } Module['getValue'] = getValue; var ALLOC_NORMAL = 0; // Tries to use _malloc() var ALLOC_STACK = 1; // Lives for the duration of the current function call var ALLOC_STATIC = 2; // Cannot be freed var ALLOC_DYNAMIC = 3; // Cannot be freed except through sbrk var ALLOC_NONE = 4; // Do not allocate Module['ALLOC_NORMAL'] = ALLOC_NORMAL; Module['ALLOC_STACK'] = ALLOC_STACK; Module['ALLOC_STATIC'] = ALLOC_STATIC; Module['ALLOC_DYNAMIC'] = ALLOC_DYNAMIC; Module['ALLOC_NONE'] = ALLOC_NONE; // allocate(): This is for internal use. You can use it yourself as well, but the interface // is a little tricky (see docs right below). The reason is that it is optimized // for multiple syntaxes to save space in generated code. So you should // normally not use allocate(), and instead allocate memory using _malloc(), // initialize it with setValue(), and so forth. // @slab: An array of data, or a number. If a number, then the size of the block to allocate, // in *bytes* (note that this is sometimes confusing: the next parameter does not // affect this!) // @types: Either an array of types, one for each byte (or 0 if no type at that position), // or a single type which is used for the entire block. This only matters if there // is initial data - if @slab is a number, then this does not matter at all and is // ignored. // @allocator: How to allocate memory, see ALLOC_* function allocate(slab, types, allocator, ptr) { var zeroinit, size; if (typeof slab === 'number') { zeroinit = true; size = slab; } else { zeroinit = false; size = slab.length; } var singleType = typeof types === 'string' ? types : null; var ret; if (allocator == ALLOC_NONE) { ret = ptr; } else { ret = [_malloc, Runtime.stackAlloc, Runtime.staticAlloc, Runtime.dynamicAlloc][allocator === undefined ? ALLOC_STATIC : allocator](Math.max(size, singleType ? 1 : types.length)); } if (zeroinit) { var ptr = ret, stop; assert((ret & 3) == 0); stop = ret + (size & ~3); for (; ptr < stop; ptr += 4) { HEAP32[((ptr)>>2)]=0; } stop = ret + size; while (ptr < stop) { HEAP8[((ptr++)|0)]=0; } return ret; } if (singleType === 'i8') { if (slab.subarray || slab.slice) { HEAPU8.set(slab, ret); } else { HEAPU8.set(new Uint8Array(slab), ret); } return ret; } var i = 0, type, typeSize, previousType; while (i < size) { var curr = slab[i]; if (typeof curr === 'function') { curr = Runtime.getFunctionIndex(curr); } type = singleType || types[i]; if (type === 0) { i++; continue; } if (type == 'i64') type = 'i32'; // special case: we have one i32 here, and one i32 later setValue(ret+i, curr, type); // no need to look up size unless type changes, so cache it if (previousType !== type) { typeSize = Runtime.getNativeTypeSize(type); previousType = type; } i += typeSize; } return ret; } Module['allocate'] = allocate; function Pointer_stringify(ptr, /* optional */ length) { // TODO: use TextDecoder // Find the length, and check for UTF while doing so var hasUtf = false; var t; var i = 0; while (1) { t = HEAPU8[(((ptr)+(i))|0)]; if (t >= 128) hasUtf = true; else if (t == 0 && !length) break; i++; if (length && i == length) break; } if (!length) length = i; var ret = ''; if (!hasUtf) { var MAX_CHUNK = 1024; // split up into chunks, because .apply on a huge string can overflow the stack var curr; while (length > 0) { curr = String.fromCharCode.apply(String, HEAPU8.subarray(ptr, ptr + Math.min(length, MAX_CHUNK))); ret = ret ? ret + curr : curr; ptr += MAX_CHUNK; length -= MAX_CHUNK; } return ret; } var utf8 = new Runtime.UTF8Processor(); for (i = 0; i < length; i++) { t = HEAPU8[(((ptr)+(i))|0)]; ret += utf8.processCChar(t); } return ret; } Module['Pointer_stringify'] = Pointer_stringify; // Given a pointer 'ptr' to a null-terminated UTF16LE-encoded string in the emscripten HEAP, returns // a copy of that string as a Javascript String object. function UTF16ToString(ptr) { var i = 0; var str = ''; while (1) { var codeUnit = HEAP16[(((ptr)+(i*2))>>1)]; if (codeUnit == 0) return str; ++i; // fromCharCode constructs a character from a UTF-16 code unit, so we can pass the UTF16 string right through. str += String.fromCharCode(codeUnit); } } Module['UTF16ToString'] = UTF16ToString; // Copies the given Javascript String object 'str' to the emscripten HEAP at address 'outPtr', // null-terminated and encoded in UTF16LE form. The copy will require at most (str.length*2+1)*2 bytes of space in the HEAP. function stringToUTF16(str, outPtr) { for(var i = 0; i < str.length; ++i) { // charCodeAt returns a UTF-16 encoded code unit, so it can be directly written to the HEAP. var codeUnit = str.charCodeAt(i); // possibly a lead surrogate HEAP16[(((outPtr)+(i*2))>>1)]=codeUnit; } // Null-terminate the pointer to the HEAP. HEAP16[(((outPtr)+(str.length*2))>>1)]=0; } Module['stringToUTF16'] = stringToUTF16; // Given a pointer 'ptr' to a null-terminated UTF32LE-encoded string in the emscripten HEAP, returns // a copy of that string as a Javascript String object. function UTF32ToString(ptr) { var i = 0; var str = ''; while (1) { var utf32 = HEAP32[(((ptr)+(i*4))>>2)]; if (utf32 == 0) return str; ++i; // Gotcha: fromCharCode constructs a character from a UTF-16 encoded code (pair), not from a Unicode code point! So encode the code point to UTF-16 for constructing. if (utf32 >= 0x10000) { var ch = utf32 - 0x10000; str += String.fromCharCode(0xD800 | (ch >> 10), 0xDC00 | (ch & 0x3FF)); } else { str += String.fromCharCode(utf32); } } } Module['UTF32ToString'] = UTF32ToString; // Copies the given Javascript String object 'str' to the emscripten HEAP at address 'outPtr', // null-terminated and encoded in UTF32LE form. The copy will require at most (str.length+1)*4 bytes of space in the HEAP, // but can use less, since str.length does not return the number of characters in the string, but the number of UTF-16 code units in the string. function stringToUTF32(str, outPtr) { var iChar = 0; for(var iCodeUnit = 0; iCodeUnit < str.length; ++iCodeUnit) { // Gotcha: charCodeAt returns a 16-bit word that is a UTF-16 encoded code unit, not a Unicode code point of the character! We must decode the string to UTF-32 to the heap. var codeUnit = str.charCodeAt(iCodeUnit); // possibly a lead surrogate if (codeUnit >= 0xD800 && codeUnit <= 0xDFFF) { var trailSurrogate = str.charCodeAt(++iCodeUnit); codeUnit = 0x10000 + ((codeUnit & 0x3FF) << 10) | (trailSurrogate & 0x3FF); } HEAP32[(((outPtr)+(iChar*4))>>2)]=codeUnit; ++iChar; } // Null-terminate the pointer to the HEAP. HEAP32[(((outPtr)+(iChar*4))>>2)]=0; } Module['stringToUTF32'] = stringToUTF32; function demangle(func) { var i = 3; // params, etc. var basicTypes = { 'v': 'void', 'b': 'bool', 'c': 'char', 's': 'short', 'i': 'int', 'l': 'long', 'f': 'float', 'd': 'double', 'w': 'wchar_t', 'a': 'signed char', 'h': 'unsigned char', 't': 'unsigned short', 'j': 'unsigned int', 'm': 'unsigned long', 'x': 'long long', 'y': 'unsigned long long', 'z': '...' }; var subs = []; var first = true; function dump(x) { //return; if (x) Module.print(x); Module.print(func); var pre = ''; for (var a = 0; a < i; a++) pre += ' '; Module.print (pre + '^'); } function parseNested() { i++; if (func[i] === 'K') i++; // ignore const var parts = []; while (func[i] !== 'E') { if (func[i] === 'S') { // substitution i++; var next = func.indexOf('_', i); var num = func.substring(i, next) || 0; parts.push(subs[num] || '?'); i = next+1; continue; } if (func[i] === 'C') { // constructor parts.push(parts[parts.length-1]); i += 2; continue; } var size = parseInt(func.substr(i)); var pre = size.toString().length; if (!size || !pre) { i--; break; } // counter i++ below us var curr = func.substr(i + pre, size); parts.push(curr); subs.push(curr); i += pre + size; } i++; // skip E return parts; } function parse(rawList, limit, allowVoid) { // main parser limit = limit || Infinity; var ret = '', list = []; function flushList() { return '(' + list.join(', ') + ')'; } var name; if (func[i] === 'N') { // namespaced N-E name = parseNested().join('::'); limit--; if (limit === 0) return rawList ? [name] : name; } else { // not namespaced if (func[i] === 'K' || (first && func[i] === 'L')) i++; // ignore const and first 'L' var size = parseInt(func.substr(i)); if (size) { var pre = size.toString().length; name = func.substr(i + pre, size); i += pre + size; } } first = false; if (func[i] === 'I') { i++; var iList = parse(true); var iRet = parse(true, 1, true); ret += iRet[0] + ' ' + name + '<' + iList.join(', ') + '>'; } else { ret = name; } paramLoop: while (i < func.length && limit-- > 0) { //dump('paramLoop'); var c = func[i++]; if (c in basicTypes) { list.push(basicTypes[c]); } else { switch (c) { case 'P': list.push(parse(true, 1, true)[0] + '*'); break; // pointer case 'R': list.push(parse(true, 1, true)[0] + '&'); break; // reference case 'L': { // literal i++; // skip basic type var end = func.indexOf('E', i); var size = end - i; list.push(func.substr(i, size)); i += size + 2; // size + 'EE' break; } case 'A': { // array var size = parseInt(func.substr(i)); i += size.toString().length; if (func[i] !== '_') throw '?'; i++; // skip _ list.push(parse(true, 1, true)[0] + ' [' + size + ']'); break; } case 'E': break paramLoop; default: ret += '?' + c; break paramLoop; } } } if (!allowVoid && list.length === 1 && list[0] === 'void') list = []; // avoid (void) if (rawList) { if (ret) { list.push(ret + '?'); } return list; } else { return ret + flushList(); } } try { // Special-case the entry point, since its name differs from other name mangling. if (func == 'Object._main' || func == '_main') { return 'main()'; } if (typeof func === 'number') func = Pointer_stringify(func); if (func[0] !== '_') return func; if (func[1] !== '_') return func; // C function if (func[2] !== 'Z') return func; switch (func[3]) { case 'n': return 'operator new()'; case 'd': return 'operator delete()'; } return parse(); } catch(e) { return func; } } function demangleAll(text) { return text.replace(/__Z[\w\d_]+/g, function(x) { var y = demangle(x); return x === y ? x : (x + ' [' + y + ']') }); } function stackTrace() { var stack = new Error().stack; return stack ? demangleAll(stack) : '(no stack trace available)'; // Stack trace is not available at least on IE10 and Safari 6. } // Memory management var PAGE_SIZE = 4096; function alignMemoryPage(x) { return (x+4095)&-4096; } var HEAP; var HEAP8, HEAPU8, HEAP16, HEAPU16, HEAP32, HEAPU32, HEAPF32, HEAPF64; var STATIC_BASE = 0, STATICTOP = 0, staticSealed = false; // static area var STACK_BASE = 0, STACKTOP = 0, STACK_MAX = 0; // stack area var DYNAMIC_BASE = 0, DYNAMICTOP = 0; // dynamic area handled by sbrk function enlargeMemory() { abort('Cannot enlarge memory arrays. Either (1) compile with -s TOTAL_MEMORY=X with X higher than the current value ' + TOTAL_MEMORY + ', (2) compile with ALLOW_MEMORY_GROWTH which adjusts the size at runtime but prevents some optimizations, or (3) set Module.TOTAL_MEMORY before the program runs.'); } var TOTAL_STACK = Module['TOTAL_STACK'] || 5242880; var TOTAL_MEMORY = Module['TOTAL_MEMORY'] || 134217728; var FAST_MEMORY = Module['FAST_MEMORY'] || 2097152; var totalMemory = 4096; while (totalMemory < TOTAL_MEMORY || totalMemory < 2*TOTAL_STACK) { if (totalMemory < 16*1024*1024) { totalMemory *= 2; } else { totalMemory += 16*1024*1024 } } if (totalMemory !== TOTAL_MEMORY) { Module.printErr('increasing TOTAL_MEMORY to ' + totalMemory + ' to be more reasonable'); TOTAL_MEMORY = totalMemory; } // Initialize the runtime's memory // check for full engine support (use string 'subarray' to avoid closure compiler confusion) assert(typeof Int32Array !== 'undefined' && typeof Float64Array !== 'undefined' && !!(new Int32Array(1)['subarray']) && !!(new Int32Array(1)['set']), 'JS engine does not provide full typed array support'); var buffer = new ArrayBuffer(TOTAL_MEMORY); HEAP8 = new Int8Array(buffer); HEAP16 = new Int16Array(buffer); HEAP32 = new Int32Array(buffer); HEAPU8 = new Uint8Array(buffer); HEAPU16 = new Uint16Array(buffer); HEAPU32 = new Uint32Array(buffer); HEAPF32 = new Float32Array(buffer); HEAPF64 = new Float64Array(buffer); // Endianness check (note: assumes compiler arch was little-endian) HEAP32[0] = 255; assert(HEAPU8[0] === 255 && HEAPU8[3] === 0, 'Typed arrays 2 must be run on a little-endian system'); Module['HEAP'] = HEAP; Module['HEAP8'] = HEAP8; Module['HEAP16'] = HEAP16; Module['HEAP32'] = HEAP32; Module['HEAPU8'] = HEAPU8; Module['HEAPU16'] = HEAPU16; Module['HEAPU32'] = HEAPU32; Module['HEAPF32'] = HEAPF32; Module['HEAPF64'] = HEAPF64; function callRuntimeCallbacks(callbacks) { while(callbacks.length > 0) { var callback = callbacks.shift(); if (typeof callback == 'function') { callback(); continue; } var func = callback.func; if (typeof func === 'number') { if (callback.arg === undefined) { Runtime.dynCall('v', func); } else { Runtime.dynCall('vi', func, [callback.arg]); } } else { func(callback.arg === undefined ? null : callback.arg); } } } var __ATPRERUN__ = []; // functions called before the runtime is initialized var __ATINIT__ = []; // functions called during startup var __ATMAIN__ = []; // functions called when main() is to be run var __ATEXIT__ = []; // functions called during shutdown var __ATPOSTRUN__ = []; // functions called after the runtime has exited var runtimeInitialized = false; function preRun() { // compatibility - merge in anything from Module['preRun'] at this time if (Module['preRun']) { if (typeof Module['preRun'] == 'function') Module['preRun'] = [Module['preRun']]; while (Module['preRun'].length) { addOnPreRun(Module['preRun'].shift()); } } callRuntimeCallbacks(__ATPRERUN__); } function ensureInitRuntime() { if (runtimeInitialized) return; runtimeInitialized = true; callRuntimeCallbacks(__ATINIT__); } function preMain() { callRuntimeCallbacks(__ATMAIN__); } function exitRuntime() { callRuntimeCallbacks(__ATEXIT__); } function postRun() { // compatibility - merge in anything from Module['postRun'] at this time if (Module['postRun']) { if (typeof Module['postRun'] == 'function') Module['postRun'] = [Module['postRun']]; while (Module['postRun'].length) { addOnPostRun(Module['postRun'].shift()); } } callRuntimeCallbacks(__ATPOSTRUN__); } function addOnPreRun(cb) { __ATPRERUN__.unshift(cb); } Module['addOnPreRun'] = Module.addOnPreRun = addOnPreRun; function addOnInit(cb) { __ATINIT__.unshift(cb); } Module['addOnInit'] = Module.addOnInit = addOnInit; function addOnPreMain(cb) { __ATMAIN__.unshift(cb); } Module['addOnPreMain'] = Module.addOnPreMain = addOnPreMain; function addOnExit(cb) { __ATEXIT__.unshift(cb); } Module['addOnExit'] = Module.addOnExit = addOnExit; function addOnPostRun(cb) { __ATPOSTRUN__.unshift(cb); } Module['addOnPostRun'] = Module.addOnPostRun = addOnPostRun; // Tools // This processes a JS string into a C-line array of numbers, 0-terminated. // For LLVM-originating strings, see parser.js:parseLLVMString function function intArrayFromString(stringy, dontAddNull, length /* optional */) { var ret = (new Runtime.UTF8Processor()).processJSString(stringy); if (length) { ret.length = length; } if (!dontAddNull) { ret.push(0); } return ret; } Module['intArrayFromString'] = intArrayFromString; function intArrayToString(array) { var ret = []; for (var i = 0; i < array.length; i++) { var chr = array[i]; if (chr > 0xFF) { chr &= 0xFF; } ret.push(String.fromCharCode(chr)); } return ret.join(''); } Module['intArrayToString'] = intArrayToString; // Write a Javascript array to somewhere in the heap function writeStringToMemory(string, buffer, dontAddNull) { var array = intArrayFromString(string, dontAddNull); var i = 0; while (i < array.length) { var chr = array[i]; HEAP8[(((buffer)+(i))|0)]=chr; i = i + 1; } } Module['writeStringToMemory'] = writeStringToMemory; function writeArrayToMemory(array, buffer) { for (var i = 0; i < array.length; i++) { HEAP8[(((buffer)+(i))|0)]=array[i]; } } Module['writeArrayToMemory'] = writeArrayToMemory; function writeAsciiToMemory(str, buffer, dontAddNull) { for (var i = 0; i < str.length; i++) { HEAP8[(((buffer)+(i))|0)]=str.charCodeAt(i); } if (!dontAddNull) HEAP8[(((buffer)+(str.length))|0)]=0; } Module['writeAsciiToMemory'] = writeAsciiToMemory; function unSign(value, bits, ignore) { if (value >= 0) { return value; } return bits <= 32 ? 2*Math.abs(1 << (bits-1)) + value // Need some trickery, since if bits == 32, we are right at the limit of the bits JS uses in bitshifts : Math.pow(2, bits) + value; } function reSign(value, bits, ignore) { if (value <= 0) { return value; } var half = bits <= 32 ? Math.abs(1 << (bits-1)) // abs is needed if bits == 32 : Math.pow(2, bits-1); if (value >= half && (bits <= 32 || value > half)) { // for huge values, we can hit the precision limit and always get true here. so don't do that // but, in general there is no perfect solution here. With 64-bit ints, we get rounding and errors // TODO: In i64 mode 1, resign the two parts separately and safely value = -2*half + value; // Cannot bitshift half, as it may be at the limit of the bits JS uses in bitshifts } return value; } // check for imul support, and also for correctness ( https://bugs.webkit.org/show_bug.cgi?id=126345 ) if (!Math['imul'] || Math['imul'](0xffffffff, 5) !== -5) Math['imul'] = function imul(a, b) { var ah = a >>> 16; var al = a & 0xffff; var bh = b >>> 16; var bl = b & 0xffff; return (al*bl + ((ah*bl + al*bh) << 16))|0; }; Math.imul = Math['imul']; var Math_abs = Math.abs; var Math_cos = Math.cos; var Math_sin = Math.sin; var Math_tan = Math.tan; var Math_acos = Math.acos; var Math_asin = Math.asin; var Math_atan = Math.atan; var Math_atan2 = Math.atan2; var Math_exp = Math.exp; var Math_log = Math.log; var Math_sqrt = Math.sqrt; var Math_ceil = Math.ceil; var Math_floor = Math.floor; var Math_pow = Math.pow; var Math_imul = Math.imul; var Math_fround = Math.fround; var Math_min = Math.min; // A counter of dependencies for calling run(). If we need to // do asynchronous work before running, increment this and // decrement it. Incrementing must happen in a place like // PRE_RUN_ADDITIONS (used by emcc to add file preloading). // Note that you can add dependencies in preRun, even though // it happens right before run - run will be postponed until // the dependencies are met. var runDependencies = 0; var runDependencyWatcher = null; var dependenciesFulfilled = null; // overridden to take different actions when all run dependencies are fulfilled function addRunDependency(id) { runDependencies++; if (Module['monitorRunDependencies']) { Module['monitorRunDependencies'](runDependencies); } } Module['addRunDependency'] = addRunDependency; function removeRunDependency(id) { runDependencies--; if (Module['monitorRunDependencies']) { Module['monitorRunDependencies'](runDependencies); } if (runDependencies == 0) { if (runDependencyWatcher !== null) { clearInterval(runDependencyWatcher); runDependencyWatcher = null; } if (dependenciesFulfilled) { var callback = dependenciesFulfilled; dependenciesFulfilled = null; callback(); // can add another dependenciesFulfilled } } } Module['removeRunDependency'] = removeRunDependency; Module["preloadedImages"] = {}; // maps url to image data Module["preloadedAudios"] = {}; // maps url to audio data var memoryInitializer = null; // === Body === STATIC_BASE = 8; STATICTOP = STATIC_BASE + Runtime.alignMemory(547); /* global initializers */ __ATINIT__.push(); /* memory initializer */ allocate([101,114,114,111,114,58,32,37,100,10,0,0,0,0,0,0,80,102,97,110,110,107,117,99,104,101,110,40,37,100,41,32,61,32,37,100,46,10,0,0,37,100,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0], "i8", ALLOC_NONE, Runtime.GLOBAL_BASE); var tempDoublePtr = Runtime.alignMemory(allocate(12, "i8", ALLOC_STATIC), 8); assert(tempDoublePtr % 8 == 0); function copyTempFloat(ptr) { // functions, because inlining this code increases code size too much HEAP8[tempDoublePtr] = HEAP8[ptr]; HEAP8[tempDoublePtr+1] = HEAP8[ptr+1]; HEAP8[tempDoublePtr+2] = HEAP8[ptr+2]; HEAP8[tempDoublePtr+3] = HEAP8[ptr+3]; } function copyTempDouble(ptr) { HEAP8[tempDoublePtr] = HEAP8[ptr]; HEAP8[tempDoublePtr+1] = HEAP8[ptr+1]; HEAP8[tempDoublePtr+2] = HEAP8[ptr+2]; HEAP8[tempDoublePtr+3] = HEAP8[ptr+3]; HEAP8[tempDoublePtr+4] = HEAP8[ptr+4]; HEAP8[tempDoublePtr+5] = HEAP8[ptr+5]; HEAP8[tempDoublePtr+6] = HEAP8[ptr+6]; HEAP8[tempDoublePtr+7] = HEAP8[ptr+7]; } var ERRNO_CODES={EPERM:1,ENOENT:2,ESRCH:3,EINTR:4,EIO:5,ENXIO:6,E2BIG:7,ENOEXEC:8,EBADF:9,ECHILD:10,EAGAIN:11,EWOULDBLOCK:11,ENOMEM:12,EACCES:13,EFAULT:14,ENOTBLK:15,EBUSY:16,EEXIST:17,EXDEV:18,ENODEV:19,ENOTDIR:20,EISDIR:21,EINVAL:22,ENFILE:23,EMFILE:24,ENOTTY:25,ETXTBSY:26,EFBIG:27,ENOSPC:28,ESPIPE:29,EROFS:30,EMLINK:31,EPIPE:32,EDOM:33,ERANGE:34,ENOMSG:42,EIDRM:43,ECHRNG:44,EL2NSYNC:45,EL3HLT:46,EL3RST:47,ELNRNG:48,EUNATCH:49,ENOCSI:50,EL2HLT:51,EDEADLK:35,ENOLCK:37,EBADE:52,EBADR:53,EXFULL:54,ENOANO:55,EBADRQC:56,EBADSLT:57,EDEADLOCK:35,EBFONT:59,ENOSTR:60,ENODATA:61,ETIME:62,ENOSR:63,ENONET:64,ENOPKG:65,EREMOTE:66,ENOLINK:67,EADV:68,ESRMNT:69,ECOMM:70,EPROTO:71,EMULTIHOP:72,EDOTDOT:73,EBADMSG:74,ENOTUNIQ:76,EBADFD:77,EREMCHG:78,ELIBACC:79,ELIBBAD:80,ELIBSCN:81,ELIBMAX:82,ELIBEXEC:83,ENOSYS:38,ENOTEMPTY:39,ENAMETOOLONG:36,ELOOP:40,EOPNOTSUPP:95,EPFNOSUPPORT:96,ECONNRESET:104,ENOBUFS:105,EAFNOSUPPORT:97,EPROTOTYPE:91,ENOTSOCK:88,ENOPROTOOPT:92,ESHUTDOWN:108,ECONNREFUSED:111,EADDRINUSE:98,ECONNABORTED:103,ENETUNREACH:101,ENETDOWN:100,ETIMEDOUT:110,EHOSTDOWN:112,EHOSTUNREACH:113,EINPROGRESS:115,EALREADY:114,EDESTADDRREQ:89,EMSGSIZE:90,EPROTONOSUPPORT:93,ESOCKTNOSUPPORT:94,EADDRNOTAVAIL:99,ENETRESET:102,EISCONN:106,ENOTCONN:107,ETOOMANYREFS:109,EUSERS:87,EDQUOT:122,ESTALE:116,ENOTSUP:95,ENOMEDIUM:123,EILSEQ:84,EOVERFLOW:75,ECANCELED:125,ENOTRECOVERABLE:131,EOWNERDEAD:130,ESTRPIPE:86}; var ERRNO_MESSAGES={0:"Success",1:"Not super-user",2:"No such file or directory",3:"No such process",4:"Interrupted system call",5:"I/O error",6:"No such device or address",7:"Arg list too long",8:"Exec format error",9:"Bad file number",10:"No children",11:"No more processes",12:"Not enough core",13:"Permission denied",14:"Bad address",15:"Block device required",16:"Mount device busy",17:"File exists",18:"Cross-device link",19:"No such device",20:"Not a directory",21:"Is a directory",22:"Invalid argument",23:"Too many open files in system",24:"Too many open files",25:"Not a typewriter",26:"Text file busy",27:"File too large",28:"No space left on device",29:"Illegal seek",30:"Read only file system",31:"Too many links",32:"Broken pipe",33:"Math arg out of domain of func",34:"Math result not representable",35:"File locking deadlock error",36:"File or path name too long",37:"No record locks available",38:"Function not implemented",39:"Directory not empty",40:"Too many symbolic links",42:"No message of desired type",43:"Identifier removed",44:"Channel number out of range",45:"Level 2 not synchronized",46:"Level 3 halted",47:"Level 3 reset",48:"Link number out of range",49:"Protocol driver not attached",50:"No CSI structure available",51:"Level 2 halted",52:"Invalid exchange",53:"Invalid request descriptor",54:"Exchange full",55:"No anode",56:"Invalid request code",57:"Invalid slot",59:"Bad font file fmt",60:"Device not a stream",61:"No data (for no delay io)",62:"Timer expired",63:"Out of streams resources",64:"Machine is not on the network",65:"Package not installed",66:"The object is remote",67:"The link has been severed",68:"Advertise error",69:"Srmount error",70:"Communication error on send",71:"Protocol error",72:"Multihop attempted",73:"Cross mount point (not really error)",74:"Trying to read unreadable message",75:"Value too large for defined data type",76:"Given log. name not unique",77:"f.d. invalid for this operation",78:"Remote address changed",79:"Can access a needed shared lib",80:"Accessing a corrupted shared lib",81:".lib section in a.out corrupted",82:"Attempting to link in too many libs",83:"Attempting to exec a shared library",84:"Illegal byte sequence",86:"Streams pipe error",87:"Too many users",88:"Socket operation on non-socket",89:"Destination address required",90:"Message too long",91:"Protocol wrong type for socket",92:"Protocol not available",93:"Unknown protocol",94:"Socket type not supported",95:"Not supported",96:"Protocol family not supported",97:"Address family not supported by protocol family",98:"Address already in use",99:"Address not available",100:"Network interface is not configured",101:"Network is unreachable",102:"Connection reset by network",103:"Connection aborted",104:"Connection reset by peer",105:"No buffer space available",106:"Socket is already connected",107:"Socket is not connected",108:"Can't send after socket shutdown",109:"Too many references",110:"Connection timed out",111:"Connection refused",112:"Host is down",113:"Host is unreachable",114:"Socket already connected",115:"Connection already in progress",116:"Stale file handle",122:"Quota exceeded",123:"No medium (in tape drive)",125:"Operation canceled",130:"Previous owner died",131:"State not recoverable"}; var ___errno_state=0;function ___setErrNo(value) { // For convenient setting and returning of errno. HEAP32[((___errno_state)>>2)]=value; return value; } var PATH={splitPath:function (filename) { var splitPathRe = /^(\/?|)([\s\S]*?)((?:\.{1,2}|[^\/]+?|)(\.[^.\/]*|))(?:[\/]*)$/; return splitPathRe.exec(filename).slice(1); },normalizeArray:function (parts, allowAboveRoot) { // if the path tries to go above the root, `up` ends up > 0 var up = 0; for (var i = parts.length - 1; i >= 0; i--) { var last = parts[i]; if (last === '.') { parts.splice(i, 1); } else if (last === '..') { parts.splice(i, 1); up++; } else if (up) { parts.splice(i, 1); up--; } } // if the path is allowed to go above the root, restore leading ..s if (allowAboveRoot) { for (; up--; up) { parts.unshift('..'); } } return parts; },normalize:function (path) { var isAbsolute = path.charAt(0) === '/', trailingSlash = path.substr(-1) === '/'; // Normalize the path path = PATH.normalizeArray(path.split('/').filter(function(p) { return !!p; }), !isAbsolute).join('/'); if (!path && !isAbsolute) { path = '.'; } if (path && trailingSlash) { path += '/'; } return (isAbsolute ? '/' : '') + path; },dirname:function (path) { var result = PATH.splitPath(path), root = result[0], dir = result[1]; if (!root && !dir) { // No dirname whatsoever return '.'; } if (dir) { // It has a dirname, strip trailing slash dir = dir.substr(0, dir.length - 1); } return root + dir; },basename:function (path) { // EMSCRIPTEN return '/'' for '/', not an empty string if (path === '/') return '/'; var lastSlash = path.lastIndexOf('/'); if (lastSlash === -1) return path; return path.substr(lastSlash+1); },extname:function (path) { return PATH.splitPath(path)[3]; },join:function () { var paths = Array.prototype.slice.call(arguments, 0); return PATH.normalize(paths.join('/')); },join2:function (l, r) { return PATH.normalize(l + '/' + r); },resolve:function () { var resolvedPath = '', resolvedAbsolute = false; for (var i = arguments.length - 1; i >= -1 && !resolvedAbsolute; i--) { var path = (i >= 0) ? arguments[i] : FS.cwd(); // Skip empty and invalid entries if (typeof path !== 'string') { throw new TypeError('Arguments to path.resolve must be strings'); } else if (!path) { continue; } resolvedPath = path + '/' + resolvedPath; resolvedAbsolute = path.charAt(0) === '/'; } // At this point the path should be resolved to a full absolute path, but // handle relative paths to be safe (might happen when process.cwd() fails) resolvedPath = PATH.normalizeArray(resolvedPath.split('/').filter(function(p) { return !!p; }), !resolvedAbsolute).join('/'); return ((resolvedAbsolute ? '/' : '') + resolvedPath) || '.'; },relative:function (from, to) { from = PATH.resolve(from).substr(1); to = PATH.resolve(to).substr(1); function trim(arr) { var start = 0; for (; start < arr.length; start++) { if (arr[start] !== '') break; } var end = arr.length - 1; for (; end >= 0; end--) { if (arr[end] !== '') break; } if (start > end) return []; return arr.slice(start, end - start + 1); } var fromParts = trim(from.split('/')); var toParts = trim(to.split('/')); var length = Math.min(fromParts.length, toParts.length); var samePartsLength = length; for (var i = 0; i < length; i++) { if (fromParts[i] !== toParts[i]) { samePartsLength = i; break; } } var outputParts = []; for (var i = samePartsLength; i < fromParts.length; i++) { outputParts.push('..'); } outputParts = outputParts.concat(toParts.slice(samePartsLength)); return outputParts.join('/'); }}; var TTY={ttys:[],init:function () { // https://github.com/kripken/emscripten/pull/1555 // if (ENVIRONMENT_IS_NODE) { // // currently, FS.init does not distinguish if process.stdin is a file or TTY // // device, it always assumes it's a TTY device. because of this, we're forcing // // process.stdin to UTF8 encoding to at least make stdin reading compatible // // with text files until FS.init can be refactored. // process['stdin']['setEncoding']('utf8'); // } },shutdown:function () { // https://github.com/kripken/emscripten/pull/1555 // if (ENVIRONMENT_IS_NODE) { // // inolen: any idea as to why node -e 'process.stdin.read()' wouldn't exit immediately (with process.stdin being a tty)? // // isaacs: because now it's reading from the stream, you've expressed interest in it, so that read() kicks off a _read() which creates a ReadReq operation // // inolen: I thought read() in that case was a synchronous operation that just grabbed some amount of buffered data if it exists? // // isaacs: it is. but it also triggers a _read() call, which calls readStart() on the handle // // isaacs: do process.stdin.pause() and i'd think it'd probably close the pending call // process['stdin']['pause'](); // } },register:function (dev, ops) { TTY.ttys[dev] = { input: [], output: [], ops: ops }; FS.registerDevice(dev, TTY.stream_ops); },stream_ops:{open:function (stream) { var tty = TTY.ttys[stream.node.rdev]; if (!tty) { throw new FS.ErrnoError(ERRNO_CODES.ENODEV); } stream.tty = tty; stream.seekable = false; },close:function (stream) { // flush any pending line data if (stream.tty.output.length) { stream.tty.ops.put_char(stream.tty, 10); } },read:function (stream, buffer, offset, length, pos /* ignored */) { if (!stream.tty || !stream.tty.ops.get_char) { throw new FS.ErrnoError(ERRNO_CODES.ENXIO); } var bytesRead = 0; for (var i = 0; i < length; i++) { var result; try { result = stream.tty.ops.get_char(stream.tty); } catch (e) { throw new FS.ErrnoError(ERRNO_CODES.EIO); } if (result === undefined && bytesRead === 0) { throw new FS.ErrnoError(ERRNO_CODES.EAGAIN); } if (result === null || result === undefined) break; bytesRead++; buffer[offset+i] = result; } if (bytesRead) { stream.node.timestamp = Date.now(); } return bytesRead; },write:function (stream, buffer, offset, length, pos) { if (!stream.tty || !stream.tty.ops.put_char) { throw new FS.ErrnoError(ERRNO_CODES.ENXIO); } for (var i = 0; i < length; i++) { try { stream.tty.ops.put_char(stream.tty, buffer[offset+i]); } catch (e) { throw new FS.ErrnoError(ERRNO_CODES.EIO); } } if (length) { stream.node.timestamp = Date.now(); } return i; }},default_tty_ops:{get_char:function (tty) { if (!tty.input.length) { var result = null; if (ENVIRONMENT_IS_NODE) { result = process['stdin']['read'](); if (!result) { if (process['stdin']['_readableState'] && process['stdin']['_readableState']['ended']) { return null; // EOF } return undefined; // no data available } } else if (typeof window != 'undefined' && typeof window.prompt == 'function') { // Browser. result = window.prompt('Input: '); // returns null on cancel if (result !== null) { result += '\n'; } } else if (typeof readline == 'function') { // Command line. result = readline(); if (result !== null) { result += '\n'; } } if (!result) { return null; } tty.input = intArrayFromString(result, true); } return tty.input.shift(); },put_char:function (tty, val) { if (val === null || val === 10) { Module['print'](tty.output.join('')); tty.output = []; } else { tty.output.push(TTY.utf8.processCChar(val)); } }},default_tty1_ops:{put_char:function (tty, val) { if (val === null || val === 10) { Module['printErr'](tty.output.join('')); tty.output = []; } else { tty.output.push(TTY.utf8.processCChar(val)); } }}}; var MEMFS={ops_table:null,CONTENT_OWNING:1,CONTENT_FLEXIBLE:2,CONTENT_FIXED:3,mount:function (mount) { return MEMFS.createNode(null, '/', 16384 | 511 /* 0777 */, 0); },createNode:function (parent, name, mode, dev) { if (FS.isBlkdev(mode) || FS.isFIFO(mode)) { // no supported throw new FS.ErrnoError(ERRNO_CODES.EPERM); } if (!MEMFS.ops_table) { MEMFS.ops_table = { dir: { node: { getattr: MEMFS.node_ops.getattr, setattr: MEMFS.node_ops.setattr, lookup: MEMFS.node_ops.lookup, mknod: MEMFS.node_ops.mknod, rename: MEMFS.node_ops.rename, unlink: MEMFS.node_ops.unlink, rmdir: MEMFS.node_ops.rmdir, readdir: MEMFS.node_ops.readdir, symlink: MEMFS.node_ops.symlink }, stream: { llseek: MEMFS.stream_ops.llseek } }, file: { node: { getattr: MEMFS.node_ops.getattr, setattr: MEMFS.node_ops.setattr }, stream: { llseek: MEMFS.stream_ops.llseek, read: MEMFS.stream_ops.read, write: MEMFS.stream_ops.write, allocate: MEMFS.stream_ops.allocate, mmap: MEMFS.stream_ops.mmap } }, link: { node: { getattr: MEMFS.node_ops.getattr, setattr: MEMFS.node_ops.setattr, readlink: MEMFS.node_ops.readlink }, stream: {} }, chrdev: { node: { getattr: MEMFS.node_ops.getattr, setattr: MEMFS.node_ops.setattr }, stream: FS.chrdev_stream_ops }, }; } var node = FS.createNode(parent, name, mode, dev); if (FS.isDir(node.mode)) { node.node_ops = MEMFS.ops_table.dir.node; node.stream_ops = MEMFS.ops_table.dir.stream; node.contents = {}; } else if (FS.isFile(node.mode)) { node.node_ops = MEMFS.ops_table.file.node; node.stream_ops = MEMFS.ops_table.file.stream; node.contents = []; node.contentMode = MEMFS.CONTENT_FLEXIBLE; } else if (FS.isLink(node.mode)) { node.node_ops = MEMFS.ops_table.link.node; node.stream_ops = MEMFS.ops_table.link.stream; } else if (FS.isChrdev(node.mode)) { node.node_ops = MEMFS.ops_table.chrdev.node; node.stream_ops = MEMFS.ops_table.chrdev.stream; } node.timestamp = Date.now(); // add the new node to the parent if (parent) { parent.contents[name] = node; } return node; },ensureFlexible:function (node) { if (node.contentMode !== MEMFS.CONTENT_FLEXIBLE) { var contents = node.contents; node.contents = Array.prototype.slice.call(contents); node.contentMode = MEMFS.CONTENT_FLEXIBLE; } },node_ops:{getattr:function (node) { var attr = {}; // device numbers reuse inode numbers. attr.dev = FS.isChrdev(node.mode) ? node.id : 1; attr.ino = node.id; attr.mode = node.mode; attr.nlink = 1; attr.uid = 0; attr.gid = 0; attr.rdev = node.rdev; if (FS.isDir(node.mode)) { attr.size = 4096; } else if (FS.isFile(node.mode)) { attr.size = node.contents.length; } else if (FS.isLink(node.mode)) { attr.size = node.link.length; } else { attr.size = 0; } attr.atime = new Date(node.timestamp); attr.mtime = new Date(node.timestamp); attr.ctime = new Date(node.timestamp); // NOTE: In our implementation, st_blocks = Math.ceil(st_size/st_blksize), // but this is not required by the standard. attr.blksize = 4096; attr.blocks = Math.ceil(attr.size / attr.blksize); return attr; },setattr:function (node, attr) { if (attr.mode !== undefined) { node.mode = attr.mode; } if (attr.timestamp !== undefined) { node.timestamp = attr.timestamp; } if (attr.size !== undefined) { MEMFS.ensureFlexible(node); var contents = node.contents; if (attr.size < contents.length) contents.length = attr.size; else while (attr.size > contents.length) contents.push(0); } },lookup:function (parent, name) { throw FS.genericErrors[ERRNO_CODES.ENOENT]; },mknod:function (parent, name, mode, dev) { return MEMFS.createNode(parent, name, mode, dev); },rename:function (old_node, new_dir, new_name) { // if we're overwriting a directory at new_name, make sure it's empty. if (FS.isDir(old_node.mode)) { var new_node; try { new_node = FS.lookupNode(new_dir, new_name); } catch (e) { } if (new_node) { for (var i in new_node.contents) { throw new FS.ErrnoError(ERRNO_CODES.ENOTEMPTY); } } } // do the internal rewiring delete old_node.parent.contents[old_node.name]; old_node.name = new_name; new_dir.contents[new_name] = old_node; old_node.parent = new_dir; },unlink:function (parent, name) { delete parent.contents[name]; },rmdir:function (parent, name) { var node = FS.lookupNode(parent, name); for (var i in node.contents) { throw new FS.ErrnoError(ERRNO_CODES.ENOTEMPTY); } delete parent.contents[name]; },readdir:function (node) { var entries = ['.', '..'] for (var key in node.contents) { if (!node.contents.hasOwnProperty(key)) { continue; } entries.push(key); } return entries; },symlink:function (parent, newname, oldpath) { var node = MEMFS.createNode(parent, newname, 511 /* 0777 */ | 40960, 0); node.link = oldpath; return node; },readlink:function (node) { if (!FS.isLink(node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } return node.link; }},stream_ops:{read:function (stream, buffer, offset, length, position) { var contents = stream.node.contents; if (position >= contents.length) return 0; var size = Math.min(contents.length - position, length); assert(size >= 0); if (size > 8 && contents.subarray) { // non-trivial, and typed array buffer.set(contents.subarray(position, position + size), offset); } else { for (var i = 0; i < size; i++) { buffer[offset + i] = contents[position + i]; } } return size; },write:function (stream, buffer, offset, length, position, canOwn) { var node = stream.node; node.timestamp = Date.now(); var contents = node.contents; if (length && contents.length === 0 && position === 0 && buffer.subarray) { // just replace it with the new data if (canOwn && offset === 0) { node.contents = buffer; // this could be a subarray of Emscripten HEAP, or allocated from some other source. node.contentMode = (buffer.buffer === HEAP8.buffer) ? MEMFS.CONTENT_OWNING : MEMFS.CONTENT_FIXED; } else { node.contents = new Uint8Array(buffer.subarray(offset, offset+length)); node.contentMode = MEMFS.CONTENT_FIXED; } return length; } MEMFS.ensureFlexible(node); var contents = node.contents; while (contents.length < position) contents.push(0); for (var i = 0; i < length; i++) { contents[position + i] = buffer[offset + i]; } return length; },llseek:function (stream, offset, whence) { var position = offset; if (whence === 1) { // SEEK_CUR. position += stream.position; } else if (whence === 2) { // SEEK_END. if (FS.isFile(stream.node.mode)) { position += stream.node.contents.length; } } if (position < 0) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } stream.ungotten = []; stream.position = position; return position; },allocate:function (stream, offset, length) { MEMFS.ensureFlexible(stream.node); var contents = stream.node.contents; var limit = offset + length; while (limit > contents.length) contents.push(0); },mmap:function (stream, buffer, offset, length, position, prot, flags) { if (!FS.isFile(stream.node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.ENODEV); } var ptr; var allocated; var contents = stream.node.contents; // Only make a new copy when MAP_PRIVATE is specified. if ( !(flags & 2) && (contents.buffer === buffer || contents.buffer === buffer.buffer) ) { // We can't emulate MAP_SHARED when the file is not backed by the buffer // we're mapping to (e.g. the HEAP buffer). allocated = false; ptr = contents.byteOffset; } else { // Try to avoid unnecessary slices. if (position > 0 || position + length < contents.length) { if (contents.subarray) { contents = contents.subarray(position, position + length); } else { contents = Array.prototype.slice.call(contents, position, position + length); } } allocated = true; ptr = _malloc(length); if (!ptr) { throw new FS.ErrnoError(ERRNO_CODES.ENOMEM); } buffer.set(contents, ptr); } return { ptr: ptr, allocated: allocated }; }}}; var IDBFS={dbs:{},indexedDB:function () { return window.indexedDB || window.mozIndexedDB || window.webkitIndexedDB || window.msIndexedDB; },DB_VERSION:21,DB_STORE_NAME:"FILE_DATA",mount:function (mount) { // reuse all of the core MEMFS functionality return MEMFS.mount.apply(null, arguments); },syncfs:function (mount, populate, callback) { IDBFS.getLocalSet(mount, function(err, local) { if (err) return callback(err); IDBFS.getRemoteSet(mount, function(err, remote) { if (err) return callback(err); var src = populate ? remote : local; var dst = populate ? local : remote; IDBFS.reconcile(src, dst, callback); }); }); },getDB:function (name, callback) { // check the cache first var db = IDBFS.dbs[name]; if (db) { return callback(null, db); } var req; try { req = IDBFS.indexedDB().open(name, IDBFS.DB_VERSION); } catch (e) { return callback(e); } req.onupgradeneeded = function(e) { var db = e.target.result; var transaction = e.target.transaction; var fileStore; if (db.objectStoreNames.contains(IDBFS.DB_STORE_NAME)) { fileStore = transaction.objectStore(IDBFS.DB_STORE_NAME); } else { fileStore = db.createObjectStore(IDBFS.DB_STORE_NAME); } fileStore.createIndex('timestamp', 'timestamp', { unique: false }); }; req.onsuccess = function() { db = req.result; // add to the cache IDBFS.dbs[name] = db; callback(null, db); }; req.onerror = function() { callback(this.error); }; },getLocalSet:function (mount, callback) { var entries = {}; function isRealDir(p) { return p !== '.' && p !== '..'; }; function toAbsolute(root) { return function(p) { return PATH.join2(root, p); } }; var check = FS.readdir(mount.mountpoint).filter(isRealDir).map(toAbsolute(mount.mountpoint)); while (check.length) { var path = check.pop(); var stat; try { stat = FS.stat(path); } catch (e) { return callback(e); } if (FS.isDir(stat.mode)) { check.push.apply(check, FS.readdir(path).filter(isRealDir).map(toAbsolute(path))); } entries[path] = { timestamp: stat.mtime }; } return callback(null, { type: 'local', entries: entries }); },getRemoteSet:function (mount, callback) { var entries = {}; IDBFS.getDB(mount.mountpoint, function(err, db) { if (err) return callback(err); var transaction = db.transaction([IDBFS.DB_STORE_NAME], 'readonly'); transaction.onerror = function() { callback(this.error); }; var store = transaction.objectStore(IDBFS.DB_STORE_NAME); var index = store.index('timestamp'); index.openKeyCursor().onsuccess = function(event) { var cursor = event.target.result; if (!cursor) { return callback(null, { type: 'remote', db: db, entries: entries }); } entries[cursor.primaryKey] = { timestamp: cursor.key }; cursor.continue(); }; }); },loadLocalEntry:function (path, callback) { var stat, node; try { var lookup = FS.lookupPath(path); node = lookup.node; stat = FS.stat(path); } catch (e) { return callback(e); } if (FS.isDir(stat.mode)) { return callback(null, { timestamp: stat.mtime, mode: stat.mode }); } else if (FS.isFile(stat.mode)) { return callback(null, { timestamp: stat.mtime, mode: stat.mode, contents: node.contents }); } else { return callback(new Error('node type not supported')); } },storeLocalEntry:function (path, entry, callback) { try { if (FS.isDir(entry.mode)) { FS.mkdir(path, entry.mode); } else if (FS.isFile(entry.mode)) { FS.writeFile(path, entry.contents, { encoding: 'binary', canOwn: true }); } else { return callback(new Error('node type not supported')); } FS.utime(path, entry.timestamp, entry.timestamp); } catch (e) { return callback(e); } callback(null); },removeLocalEntry:function (path, callback) { try { var lookup = FS.lookupPath(path); var stat = FS.stat(path); if (FS.isDir(stat.mode)) { FS.rmdir(path); } else if (FS.isFile(stat.mode)) { FS.unlink(path); } } catch (e) { return callback(e); } callback(null); },loadRemoteEntry:function (store, path, callback) { var req = store.get(path); req.onsuccess = function(event) { callback(null, event.target.result); }; req.onerror = function() { callback(this.error); }; },storeRemoteEntry:function (store, path, entry, callback) { var req = store.put(entry, path); req.onsuccess = function() { callback(null); }; req.onerror = function() { callback(this.error); }; },removeRemoteEntry:function (store, path, callback) { var req = store.delete(path); req.onsuccess = function() { callback(null); }; req.onerror = function() { callback(this.error); }; },reconcile:function (src, dst, callback) { var total = 0; var create = []; Object.keys(src.entries).forEach(function (key) { var e = src.entries[key]; var e2 = dst.entries[key]; if (!e2 || e.timestamp > e2.timestamp) { create.push(key); total++; } }); var remove = []; Object.keys(dst.entries).forEach(function (key) { var e = dst.entries[key]; var e2 = src.entries[key]; if (!e2) { remove.push(key); total++; } }); if (!total) { return callback(null); } var errored = false; var completed = 0; var db = src.type === 'remote' ? src.db : dst.db; var transaction = db.transaction([IDBFS.DB_STORE_NAME], 'readwrite'); var store = transaction.objectStore(IDBFS.DB_STORE_NAME); function done(err) { if (err) { if (!done.errored) { done.errored = true; return callback(err); } return; } if (++completed >= total) { return callback(null); } }; transaction.onerror = function() { done(this.error); }; // sort paths in ascending order so directory entries are created // before the files inside them create.sort().forEach(function (path) { if (dst.type === 'local') { IDBFS.loadRemoteEntry(store, path, function (err, entry) { if (err) return done(err); IDBFS.storeLocalEntry(path, entry, done); }); } else { IDBFS.loadLocalEntry(path, function (err, entry) { if (err) return done(err); IDBFS.storeRemoteEntry(store, path, entry, done); }); } }); // sort paths in descending order so files are deleted before their // parent directories remove.sort().reverse().forEach(function(path) { if (dst.type === 'local') { IDBFS.removeLocalEntry(path, done); } else { IDBFS.removeRemoteEntry(store, path, done); } }); }}; var NODEFS={isWindows:false,staticInit:function () { NODEFS.isWindows = !!process.platform.match(/^win/); },mount:function (mount) { assert(ENVIRONMENT_IS_NODE); return NODEFS.createNode(null, '/', NODEFS.getMode(mount.opts.root), 0); },createNode:function (parent, name, mode, dev) { if (!FS.isDir(mode) && !FS.isFile(mode) && !FS.isLink(mode)) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } var node = FS.createNode(parent, name, mode); node.node_ops = NODEFS.node_ops; node.stream_ops = NODEFS.stream_ops; return node; },getMode:function (path) { var stat; try { stat = fs.lstatSync(path); if (NODEFS.isWindows) { // On Windows, directories return permission bits 'rw-rw-rw-', even though they have 'rwxrwxrwx', so // propagate write bits to execute bits. stat.mode = stat.mode | ((stat.mode & 146) >> 1); } } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } return stat.mode; },realPath:function (node) { var parts = []; while (node.parent !== node) { parts.push(node.name); node = node.parent; } parts.push(node.mount.opts.root); parts.reverse(); return PATH.join.apply(null, parts); },flagsToPermissionStringMap:{0:"r",1:"r+",2:"r+",64:"r",65:"r+",66:"r+",129:"rx+",193:"rx+",514:"w+",577:"w",578:"w+",705:"wx",706:"wx+",1024:"a",1025:"a",1026:"a+",1089:"a",1090:"a+",1153:"ax",1154:"ax+",1217:"ax",1218:"ax+",4096:"rs",4098:"rs+"},flagsToPermissionString:function (flags) { if (flags in NODEFS.flagsToPermissionStringMap) { return NODEFS.flagsToPermissionStringMap[flags]; } else { return flags; } },node_ops:{getattr:function (node) { var path = NODEFS.realPath(node); var stat; try { stat = fs.lstatSync(path); } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } // node.js v0.10.20 doesn't report blksize and blocks on Windows. Fake them with default blksize of 4096. // See http://support.microsoft.com/kb/140365 if (NODEFS.isWindows && !stat.blksize) { stat.blksize = 4096; } if (NODEFS.isWindows && !stat.blocks) { stat.blocks = (stat.size+stat.blksize-1)/stat.blksize|0; } return { dev: stat.dev, ino: stat.ino, mode: stat.mode, nlink: stat.nlink, uid: stat.uid, gid: stat.gid, rdev: stat.rdev, size: stat.size, atime: stat.atime, mtime: stat.mtime, ctime: stat.ctime, blksize: stat.blksize, blocks: stat.blocks }; },setattr:function (node, attr) { var path = NODEFS.realPath(node); try { if (attr.mode !== undefined) { fs.chmodSync(path, attr.mode); // update the common node structure mode as well node.mode = attr.mode; } if (attr.timestamp !== undefined) { var date = new Date(attr.timestamp); fs.utimesSync(path, date, date); } if (attr.size !== undefined) { fs.truncateSync(path, attr.size); } } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },lookup:function (parent, name) { var path = PATH.join2(NODEFS.realPath(parent), name); var mode = NODEFS.getMode(path); return NODEFS.createNode(parent, name, mode); },mknod:function (parent, name, mode, dev) { var node = NODEFS.createNode(parent, name, mode, dev); // create the backing node for this in the fs root as well var path = NODEFS.realPath(node); try { if (FS.isDir(node.mode)) { fs.mkdirSync(path, node.mode); } else { fs.writeFileSync(path, '', { mode: node.mode }); } } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } return node; },rename:function (oldNode, newDir, newName) { var oldPath = NODEFS.realPath(oldNode); var newPath = PATH.join2(NODEFS.realPath(newDir), newName); try { fs.renameSync(oldPath, newPath); } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },unlink:function (parent, name) { var path = PATH.join2(NODEFS.realPath(parent), name); try { fs.unlinkSync(path); } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },rmdir:function (parent, name) { var path = PATH.join2(NODEFS.realPath(parent), name); try { fs.rmdirSync(path); } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },readdir:function (node) { var path = NODEFS.realPath(node); try { return fs.readdirSync(path); } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },symlink:function (parent, newName, oldPath) { var newPath = PATH.join2(NODEFS.realPath(parent), newName); try { fs.symlinkSync(oldPath, newPath); } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },readlink:function (node) { var path = NODEFS.realPath(node); try { return fs.readlinkSync(path); } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } }},stream_ops:{open:function (stream) { var path = NODEFS.realPath(stream.node); try { if (FS.isFile(stream.node.mode)) { stream.nfd = fs.openSync(path, NODEFS.flagsToPermissionString(stream.flags)); } } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },close:function (stream) { try { if (FS.isFile(stream.node.mode) && stream.nfd) { fs.closeSync(stream.nfd); } } catch (e) { if (!e.code) throw e; throw new FS.ErrnoError(ERRNO_CODES[e.code]); } },read:function (stream, buffer, offset, length, position) { // FIXME this is terrible. var nbuffer = new Buffer(length); var res; try { res = fs.readSync(stream.nfd, nbuffer, 0, length, position); } catch (e) { throw new FS.ErrnoError(ERRNO_CODES[e.code]); } if (res > 0) { for (var i = 0; i < res; i++) { buffer[offset + i] = nbuffer[i]; } } return res; },write:function (stream, buffer, offset, length, position) { // FIXME this is terrible. var nbuffer = new Buffer(buffer.subarray(offset, offset + length)); var res; try { res = fs.writeSync(stream.nfd, nbuffer, 0, length, position); } catch (e) { throw new FS.ErrnoError(ERRNO_CODES[e.code]); } return res; },llseek:function (stream, offset, whence) { var position = offset; if (whence === 1) { // SEEK_CUR. position += stream.position; } else if (whence === 2) { // SEEK_END. if (FS.isFile(stream.node.mode)) { try { var stat = fs.fstatSync(stream.nfd); position += stat.size; } catch (e) { throw new FS.ErrnoError(ERRNO_CODES[e.code]); } } } if (position < 0) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } stream.position = position; return position; }}}; var _stdin=allocate(1, "i32*", ALLOC_STATIC); var _stdout=allocate(1, "i32*", ALLOC_STATIC); var _stderr=allocate(1, "i32*", ALLOC_STATIC); function _fflush(stream) { // int fflush(FILE *stream); // http://pubs.opengroup.org/onlinepubs/000095399/functions/fflush.html // we don't currently perform any user-space buffering of data }var FS={root:null,mounts:[],devices:[null],streams:[],nextInode:1,nameTable:null,currentPath:"/",initialized:false,ignorePermissions:true,ErrnoError:null,genericErrors:{},handleFSError:function (e) { if (!(e instanceof FS.ErrnoError)) throw e + ' : ' + stackTrace(); return ___setErrNo(e.errno); },lookupPath:function (path, opts) { path = PATH.resolve(FS.cwd(), path); opts = opts || {}; var defaults = { follow_mount: true, recurse_count: 0 }; for (var key in defaults) { if (opts[key] === undefined) { opts[key] = defaults[key]; } } if (opts.recurse_count > 8) { // max recursive lookup of 8 throw new FS.ErrnoError(ERRNO_CODES.ELOOP); } // split the path var parts = PATH.normalizeArray(path.split('/').filter(function(p) { return !!p; }), false); // start at the root var current = FS.root; var current_path = '/'; for (var i = 0; i < parts.length; i++) { var islast = (i === parts.length-1); if (islast && opts.parent) { // stop resolving break; } current = FS.lookupNode(current, parts[i]); current_path = PATH.join2(current_path, parts[i]); // jump to the mount's root node if this is a mountpoint if (FS.isMountpoint(current)) { if (!islast || (islast && opts.follow_mount)) { current = current.mounted.root; } } // by default, lookupPath will not follow a symlink if it is the final path component. // setting opts.follow = true will override this behavior. if (!islast || opts.follow) { var count = 0; while (FS.isLink(current.mode)) { var link = FS.readlink(current_path); current_path = PATH.resolve(PATH.dirname(current_path), link); var lookup = FS.lookupPath(current_path, { recurse_count: opts.recurse_count }); current = lookup.node; if (count++ > 40) { // limit max consecutive symlinks to 40 (SYMLOOP_MAX). throw new FS.ErrnoError(ERRNO_CODES.ELOOP); } } } } return { path: current_path, node: current }; },getPath:function (node) { var path; while (true) { if (FS.isRoot(node)) { var mount = node.mount.mountpoint; if (!path) return mount; return mount[mount.length-1] !== '/' ? mount + '/' + path : mount + path; } path = path ? node.name + '/' + path : node.name; node = node.parent; } },hashName:function (parentid, name) { var hash = 0; for (var i = 0; i < name.length; i++) { hash = ((hash << 5) - hash + name.charCodeAt(i)) | 0; } return ((parentid + hash) >>> 0) % FS.nameTable.length; },hashAddNode:function (node) { var hash = FS.hashName(node.parent.id, node.name); node.name_next = FS.nameTable[hash]; FS.nameTable[hash] = node; },hashRemoveNode:function (node) { var hash = FS.hashName(node.parent.id, node.name); if (FS.nameTable[hash] === node) { FS.nameTable[hash] = node.name_next; } else { var current = FS.nameTable[hash]; while (current) { if (current.name_next === node) { current.name_next = node.name_next; break; } current = current.name_next; } } },lookupNode:function (parent, name) { var err = FS.mayLookup(parent); if (err) { throw new FS.ErrnoError(err); } var hash = FS.hashName(parent.id, name); for (var node = FS.nameTable[hash]; node; node = node.name_next) { var nodeName = node.name; if (node.parent.id === parent.id && nodeName === name) { return node; } } // if we failed to find it in the cache, call into the VFS return FS.lookup(parent, name); },createNode:function (parent, name, mode, rdev) { if (!FS.FSNode) { FS.FSNode = function(parent, name, mode, rdev) { if (!parent) { parent = this; // root node sets parent to itself } this.parent = parent; this.mount = parent.mount; this.mounted = null; this.id = FS.nextInode++; this.name = name; this.mode = mode; this.node_ops = {}; this.stream_ops = {}; this.rdev = rdev; }; FS.FSNode.prototype = {}; // compatibility var readMode = 292 | 73; var writeMode = 146; // NOTE we must use Object.defineProperties instead of individual calls to // Object.defineProperty in order to make closure compiler happy Object.defineProperties(FS.FSNode.prototype, { read: { get: function() { return (this.mode & readMode) === readMode; }, set: function(val) { val ? this.mode |= readMode : this.mode &= ~readMode; } }, write: { get: function() { return (this.mode & writeMode) === writeMode; }, set: function(val) { val ? this.mode |= writeMode : this.mode &= ~writeMode; } }, isFolder: { get: function() { return FS.isDir(this.mode); }, }, isDevice: { get: function() { return FS.isChrdev(this.mode); }, }, }); } var node = new FS.FSNode(parent, name, mode, rdev); FS.hashAddNode(node); return node; },destroyNode:function (node) { FS.hashRemoveNode(node); },isRoot:function (node) { return node === node.parent; },isMountpoint:function (node) { return !!node.mounted; },isFile:function (mode) { return (mode & 61440) === 32768; },isDir:function (mode) { return (mode & 61440) === 16384; },isLink:function (mode) { return (mode & 61440) === 40960; },isChrdev:function (mode) { return (mode & 61440) === 8192; },isBlkdev:function (mode) { return (mode & 61440) === 24576; },isFIFO:function (mode) { return (mode & 61440) === 4096; },isSocket:function (mode) { return (mode & 49152) === 49152; },flagModes:{"r":0,"rs":1052672,"r+":2,"w":577,"wx":705,"xw":705,"w+":578,"wx+":706,"xw+":706,"a":1089,"ax":1217,"xa":1217,"a+":1090,"ax+":1218,"xa+":1218},modeStringToFlags:function (str) { var flags = FS.flagModes[str]; if (typeof flags === 'undefined') { throw new Error('Unknown file open mode: ' + str); } return flags; },flagsToPermissionString:function (flag) { var accmode = flag & 2097155; var perms = ['r', 'w', 'rw'][accmode]; if ((flag & 512)) { perms += 'w'; } return perms; },nodePermissions:function (node, perms) { if (FS.ignorePermissions) { return 0; } // return 0 if any user, group or owner bits are set. if (perms.indexOf('r') !== -1 && !(node.mode & 292)) { return ERRNO_CODES.EACCES; } else if (perms.indexOf('w') !== -1 && !(node.mode & 146)) { return ERRNO_CODES.EACCES; } else if (perms.indexOf('x') !== -1 && !(node.mode & 73)) { return ERRNO_CODES.EACCES; } return 0; },mayLookup:function (dir) { return FS.nodePermissions(dir, 'x'); },mayCreate:function (dir, name) { try { var node = FS.lookupNode(dir, name); return ERRNO_CODES.EEXIST; } catch (e) { } return FS.nodePermissions(dir, 'wx'); },mayDelete:function (dir, name, isdir) { var node; try { node = FS.lookupNode(dir, name); } catch (e) { return e.errno; } var err = FS.nodePermissions(dir, 'wx'); if (err) { return err; } if (isdir) { if (!FS.isDir(node.mode)) { return ERRNO_CODES.ENOTDIR; } if (FS.isRoot(node) || FS.getPath(node) === FS.cwd()) { return ERRNO_CODES.EBUSY; } } else { if (FS.isDir(node.mode)) { return ERRNO_CODES.EISDIR; } } return 0; },mayOpen:function (node, flags) { if (!node) { return ERRNO_CODES.ENOENT; } if (FS.isLink(node.mode)) { return ERRNO_CODES.ELOOP; } else if (FS.isDir(node.mode)) { if ((flags & 2097155) !== 0 || // opening for write (flags & 512)) { return ERRNO_CODES.EISDIR; } } return FS.nodePermissions(node, FS.flagsToPermissionString(flags)); },MAX_OPEN_FDS:4096,nextfd:function (fd_start, fd_end) { fd_start = fd_start || 0; fd_end = fd_end || FS.MAX_OPEN_FDS; for (var fd = fd_start; fd <= fd_end; fd++) { if (!FS.streams[fd]) { return fd; } } throw new FS.ErrnoError(ERRNO_CODES.EMFILE); },getStream:function (fd) { return FS.streams[fd]; },createStream:function (stream, fd_start, fd_end) { if (!FS.FSStream) { FS.FSStream = function(){}; FS.FSStream.prototype = {}; // compatibility Object.defineProperties(FS.FSStream.prototype, { object: { get: function() { return this.node; }, set: function(val) { this.node = val; } }, isRead: { get: function() { return (this.flags & 2097155) !== 1; } }, isWrite: { get: function() { return (this.flags & 2097155) !== 0; } }, isAppend: { get: function() { return (this.flags & 1024); } } }); } if (0) { // reuse the object stream.__proto__ = FS.FSStream.prototype; } else { var newStream = new FS.FSStream(); for (var p in stream) { newStream[p] = stream[p]; } stream = newStream; } var fd = FS.nextfd(fd_start, fd_end); stream.fd = fd; FS.streams[fd] = stream; return stream; },closeStream:function (fd) { FS.streams[fd] = null; },getStreamFromPtr:function (ptr) { return FS.streams[ptr - 1]; },getPtrForStream:function (stream) { return stream ? stream.fd + 1 : 0; },chrdev_stream_ops:{open:function (stream) { var device = FS.getDevice(stream.node.rdev); // override node's stream ops with the device's stream.stream_ops = device.stream_ops; // forward the open call if (stream.stream_ops.open) { stream.stream_ops.open(stream); } },llseek:function () { throw new FS.ErrnoError(ERRNO_CODES.ESPIPE); }},major:function (dev) { return ((dev) >> 8); },minor:function (dev) { return ((dev) & 0xff); },makedev:function (ma, mi) { return ((ma) << 8 | (mi)); },registerDevice:function (dev, ops) { FS.devices[dev] = { stream_ops: ops }; },getDevice:function (dev) { return FS.devices[dev]; },getMounts:function (mount) { var mounts = []; var check = [mount]; while (check.length) { var m = check.pop(); mounts.push(m); check.push.apply(check, m.mounts); } return mounts; },syncfs:function (populate, callback) { if (typeof(populate) === 'function') { callback = populate; populate = false; } var mounts = FS.getMounts(FS.root.mount); var completed = 0; function done(err) { if (err) { if (!done.errored) { done.errored = true; return callback(err); } return; } if (++completed >= mounts.length) { callback(null); } }; // sync all mounts mounts.forEach(function (mount) { if (!mount.type.syncfs) { return done(null); } mount.type.syncfs(mount, populate, done); }); },mount:function (type, opts, mountpoint) { var root = mountpoint === '/'; var pseudo = !mountpoint; var node; if (root && FS.root) { throw new FS.ErrnoError(ERRNO_CODES.EBUSY); } else if (!root && !pseudo) { var lookup = FS.lookupPath(mountpoint, { follow_mount: false }); mountpoint = lookup.path; // use the absolute path node = lookup.node; if (FS.isMountpoint(node)) { throw new FS.ErrnoError(ERRNO_CODES.EBUSY); } if (!FS.isDir(node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.ENOTDIR); } } var mount = { type: type, opts: opts, mountpoint: mountpoint, mounts: [] }; // create a root node for the fs var mountRoot = type.mount(mount); mountRoot.mount = mount; mount.root = mountRoot; if (root) { FS.root = mountRoot; } else if (node) { // set as a mountpoint node.mounted = mount; // add the new mount to the current mount's children if (node.mount) { node.mount.mounts.push(mount); } } return mountRoot; },unmount:function (mountpoint) { var lookup = FS.lookupPath(mountpoint, { follow_mount: false }); if (!FS.isMountpoint(lookup.node)) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } // destroy the nodes for this mount, and all its child mounts var node = lookup.node; var mount = node.mounted; var mounts = FS.getMounts(mount); Object.keys(FS.nameTable).forEach(function (hash) { var current = FS.nameTable[hash]; while (current) { var next = current.name_next; if (mounts.indexOf(current.mount) !== -1) { FS.destroyNode(current); } current = next; } }); // no longer a mountpoint node.mounted = null; // remove this mount from the child mounts var idx = node.mount.mounts.indexOf(mount); assert(idx !== -1); node.mount.mounts.splice(idx, 1); },lookup:function (parent, name) { return parent.node_ops.lookup(parent, name); },mknod:function (path, mode, dev) { var lookup = FS.lookupPath(path, { parent: true }); var parent = lookup.node; var name = PATH.basename(path); var err = FS.mayCreate(parent, name); if (err) { throw new FS.ErrnoError(err); } if (!parent.node_ops.mknod) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } return parent.node_ops.mknod(parent, name, mode, dev); },create:function (path, mode) { mode = mode !== undefined ? mode : 438 /* 0666 */; mode &= 4095; mode |= 32768; return FS.mknod(path, mode, 0); },mkdir:function (path, mode) { mode = mode !== undefined ? mode : 511 /* 0777 */; mode &= 511 | 512; mode |= 16384; return FS.mknod(path, mode, 0); },mkdev:function (path, mode, dev) { if (typeof(dev) === 'undefined') { dev = mode; mode = 438 /* 0666 */; } mode |= 8192; return FS.mknod(path, mode, dev); },symlink:function (oldpath, newpath) { var lookup = FS.lookupPath(newpath, { parent: true }); var parent = lookup.node; var newname = PATH.basename(newpath); var err = FS.mayCreate(parent, newname); if (err) { throw new FS.ErrnoError(err); } if (!parent.node_ops.symlink) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } return parent.node_ops.symlink(parent, newname, oldpath); },rename:function (old_path, new_path) { var old_dirname = PATH.dirname(old_path); var new_dirname = PATH.dirname(new_path); var old_name = PATH.basename(old_path); var new_name = PATH.basename(new_path); // parents must exist var lookup, old_dir, new_dir; try { lookup = FS.lookupPath(old_path, { parent: true }); old_dir = lookup.node; lookup = FS.lookupPath(new_path, { parent: true }); new_dir = lookup.node; } catch (e) { throw new FS.ErrnoError(ERRNO_CODES.EBUSY); } // need to be part of the same mount if (old_dir.mount !== new_dir.mount) { throw new FS.ErrnoError(ERRNO_CODES.EXDEV); } // source must exist var old_node = FS.lookupNode(old_dir, old_name); // old path should not be an ancestor of the new path var relative = PATH.relative(old_path, new_dirname); if (relative.charAt(0) !== '.') { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } // new path should not be an ancestor of the old path relative = PATH.relative(new_path, old_dirname); if (relative.charAt(0) !== '.') { throw new FS.ErrnoError(ERRNO_CODES.ENOTEMPTY); } // see if the new path already exists var new_node; try { new_node = FS.lookupNode(new_dir, new_name); } catch (e) { // not fatal } // early out if nothing needs to change if (old_node === new_node) { return; } // we'll need to delete the old entry var isdir = FS.isDir(old_node.mode); var err = FS.mayDelete(old_dir, old_name, isdir); if (err) { throw new FS.ErrnoError(err); } // need delete permissions if we'll be overwriting. // need create permissions if new doesn't already exist. err = new_node ? FS.mayDelete(new_dir, new_name, isdir) : FS.mayCreate(new_dir, new_name); if (err) { throw new FS.ErrnoError(err); } if (!old_dir.node_ops.rename) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } if (FS.isMountpoint(old_node) || (new_node && FS.isMountpoint(new_node))) { throw new FS.ErrnoError(ERRNO_CODES.EBUSY); } // if we are going to change the parent, check write permissions if (new_dir !== old_dir) { err = FS.nodePermissions(old_dir, 'w'); if (err) { throw new FS.ErrnoError(err); } } // remove the node from the lookup hash FS.hashRemoveNode(old_node); // do the underlying fs rename try { old_dir.node_ops.rename(old_node, new_dir, new_name); } catch (e) { throw e; } finally { // add the node back to the hash (in case node_ops.rename // changed its name) FS.hashAddNode(old_node); } },rmdir:function (path) { var lookup = FS.lookupPath(path, { parent: true }); var parent = lookup.node; var name = PATH.basename(path); var node = FS.lookupNode(parent, name); var err = FS.mayDelete(parent, name, true); if (err) { throw new FS.ErrnoError(err); } if (!parent.node_ops.rmdir) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } if (FS.isMountpoint(node)) { throw new FS.ErrnoError(ERRNO_CODES.EBUSY); } parent.node_ops.rmdir(parent, name); FS.destroyNode(node); },readdir:function (path) { var lookup = FS.lookupPath(path, { follow: true }); var node = lookup.node; if (!node.node_ops.readdir) { throw new FS.ErrnoError(ERRNO_CODES.ENOTDIR); } return node.node_ops.readdir(node); },unlink:function (path) { var lookup = FS.lookupPath(path, { parent: true }); var parent = lookup.node; var name = PATH.basename(path); var node = FS.lookupNode(parent, name); var err = FS.mayDelete(parent, name, false); if (err) { // POSIX says unlink should set EPERM, not EISDIR if (err === ERRNO_CODES.EISDIR) err = ERRNO_CODES.EPERM; throw new FS.ErrnoError(err); } if (!parent.node_ops.unlink) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } if (FS.isMountpoint(node)) { throw new FS.ErrnoError(ERRNO_CODES.EBUSY); } parent.node_ops.unlink(parent, name); FS.destroyNode(node); },readlink:function (path) { var lookup = FS.lookupPath(path); var link = lookup.node; if (!link.node_ops.readlink) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } return link.node_ops.readlink(link); },stat:function (path, dontFollow) { var lookup = FS.lookupPath(path, { follow: !dontFollow }); var node = lookup.node; if (!node.node_ops.getattr) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } return node.node_ops.getattr(node); },lstat:function (path) { return FS.stat(path, true); },chmod:function (path, mode, dontFollow) { var node; if (typeof path === 'string') { var lookup = FS.lookupPath(path, { follow: !dontFollow }); node = lookup.node; } else { node = path; } if (!node.node_ops.setattr) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } node.node_ops.setattr(node, { mode: (mode & 4095) | (node.mode & ~4095), timestamp: Date.now() }); },lchmod:function (path, mode) { FS.chmod(path, mode, true); },fchmod:function (fd, mode) { var stream = FS.getStream(fd); if (!stream) { throw new FS.ErrnoError(ERRNO_CODES.EBADF); } FS.chmod(stream.node, mode); },chown:function (path, uid, gid, dontFollow) { var node; if (typeof path === 'string') { var lookup = FS.lookupPath(path, { follow: !dontFollow }); node = lookup.node; } else { node = path; } if (!node.node_ops.setattr) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } node.node_ops.setattr(node, { timestamp: Date.now() // we ignore the uid / gid for now }); },lchown:function (path, uid, gid) { FS.chown(path, uid, gid, true); },fchown:function (fd, uid, gid) { var stream = FS.getStream(fd); if (!stream) { throw new FS.ErrnoError(ERRNO_CODES.EBADF); } FS.chown(stream.node, uid, gid); },truncate:function (path, len) { if (len < 0) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } var node; if (typeof path === 'string') { var lookup = FS.lookupPath(path, { follow: true }); node = lookup.node; } else { node = path; } if (!node.node_ops.setattr) { throw new FS.ErrnoError(ERRNO_CODES.EPERM); } if (FS.isDir(node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.EISDIR); } if (!FS.isFile(node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } var err = FS.nodePermissions(node, 'w'); if (err) { throw new FS.ErrnoError(err); } node.node_ops.setattr(node, { size: len, timestamp: Date.now() }); },ftruncate:function (fd, len) { var stream = FS.getStream(fd); if (!stream) { throw new FS.ErrnoError(ERRNO_CODES.EBADF); } if ((stream.flags & 2097155) === 0) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } FS.truncate(stream.node, len); },utime:function (path, atime, mtime) { var lookup = FS.lookupPath(path, { follow: true }); var node = lookup.node; node.node_ops.setattr(node, { timestamp: Math.max(atime, mtime) }); },open:function (path, flags, mode, fd_start, fd_end) { flags = typeof flags === 'string' ? FS.modeStringToFlags(flags) : flags; mode = typeof mode === 'undefined' ? 438 /* 0666 */ : mode; if ((flags & 64)) { mode = (mode & 4095) | 32768; } else { mode = 0; } var node; if (typeof path === 'object') { node = path; } else { path = PATH.normalize(path); try { var lookup = FS.lookupPath(path, { follow: !(flags & 131072) }); node = lookup.node; } catch (e) { // ignore } } // perhaps we need to create the node if ((flags & 64)) { if (node) { // if O_CREAT and O_EXCL are set, error out if the node already exists if ((flags & 128)) { throw new FS.ErrnoError(ERRNO_CODES.EEXIST); } } else { // node doesn't exist, try to create it node = FS.mknod(path, mode, 0); } } if (!node) { throw new FS.ErrnoError(ERRNO_CODES.ENOENT); } // can't truncate a device if (FS.isChrdev(node.mode)) { flags &= ~512; } // check permissions var err = FS.mayOpen(node, flags); if (err) { throw new FS.ErrnoError(err); } // do truncation if necessary if ((flags & 512)) { FS.truncate(node, 0); } // we've already handled these, don't pass down to the underlying vfs flags &= ~(128 | 512); // register the stream with the filesystem var stream = FS.createStream({ node: node, path: FS.getPath(node), // we want the absolute path to the node flags: flags, seekable: true, position: 0, stream_ops: node.stream_ops, // used by the file family libc calls (fopen, fwrite, ferror, etc.) ungotten: [], error: false }, fd_start, fd_end); // call the new stream's open function if (stream.stream_ops.open) { stream.stream_ops.open(stream); } if (Module['logReadFiles'] && !(flags & 1)) { if (!FS.readFiles) FS.readFiles = {}; if (!(path in FS.readFiles)) { FS.readFiles[path] = 1; Module['printErr']('read file: ' + path); } } return stream; },close:function (stream) { try { if (stream.stream_ops.close) { stream.stream_ops.close(stream); } } catch (e) { throw e; } finally { FS.closeStream(stream.fd); } },llseek:function (stream, offset, whence) { if (!stream.seekable || !stream.stream_ops.llseek) { throw new FS.ErrnoError(ERRNO_CODES.ESPIPE); } return stream.stream_ops.llseek(stream, offset, whence); },read:function (stream, buffer, offset, length, position) { if (length < 0 || position < 0) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } if ((stream.flags & 2097155) === 1) { throw new FS.ErrnoError(ERRNO_CODES.EBADF); } if (FS.isDir(stream.node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.EISDIR); } if (!stream.stream_ops.read) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } var seeking = true; if (typeof position === 'undefined') { position = stream.position; seeking = false; } else if (!stream.seekable) { throw new FS.ErrnoError(ERRNO_CODES.ESPIPE); } var bytesRead = stream.stream_ops.read(stream, buffer, offset, length, position); if (!seeking) stream.position += bytesRead; return bytesRead; },write:function (stream, buffer, offset, length, position, canOwn) { if (length < 0 || position < 0) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } if ((stream.flags & 2097155) === 0) { throw new FS.ErrnoError(ERRNO_CODES.EBADF); } if (FS.isDir(stream.node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.EISDIR); } if (!stream.stream_ops.write) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } var seeking = true; if (typeof position === 'undefined') { position = stream.position; seeking = false; } else if (!stream.seekable) { throw new FS.ErrnoError(ERRNO_CODES.ESPIPE); } if (stream.flags & 1024) { // seek to the end before writing in append mode FS.llseek(stream, 0, 2); } var bytesWritten = stream.stream_ops.write(stream, buffer, offset, length, position, canOwn); if (!seeking) stream.position += bytesWritten; return bytesWritten; },allocate:function (stream, offset, length) { if (offset < 0 || length <= 0) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } if ((stream.flags & 2097155) === 0) { throw new FS.ErrnoError(ERRNO_CODES.EBADF); } if (!FS.isFile(stream.node.mode) && !FS.isDir(node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.ENODEV); } if (!stream.stream_ops.allocate) { throw new FS.ErrnoError(ERRNO_CODES.EOPNOTSUPP); } stream.stream_ops.allocate(stream, offset, length); },mmap:function (stream, buffer, offset, length, position, prot, flags) { // TODO if PROT is PROT_WRITE, make sure we have write access if ((stream.flags & 2097155) === 1) { throw new FS.ErrnoError(ERRNO_CODES.EACCES); } if (!stream.stream_ops.mmap) { throw new FS.ErrnoError(ERRNO_CODES.ENODEV); } return stream.stream_ops.mmap(stream, buffer, offset, length, position, prot, flags); },ioctl:function (stream, cmd, arg) { if (!stream.stream_ops.ioctl) { throw new FS.ErrnoError(ERRNO_CODES.ENOTTY); } return stream.stream_ops.ioctl(stream, cmd, arg); },readFile:function (path, opts) { opts = opts || {}; opts.flags = opts.flags || 'r'; opts.encoding = opts.encoding || 'binary'; if (opts.encoding !== 'utf8' && opts.encoding !== 'binary') { throw new Error('Invalid encoding type "' + opts.encoding + '"'); } var ret; var stream = FS.open(path, opts.flags); var stat = FS.stat(path); var length = stat.size; var buf = new Uint8Array(length); FS.read(stream, buf, 0, length, 0); if (opts.encoding === 'utf8') { ret = ''; var utf8 = new Runtime.UTF8Processor(); for (var i = 0; i < length; i++) { ret += utf8.processCChar(buf[i]); } } else if (opts.encoding === 'binary') { ret = buf; } FS.close(stream); return ret; },writeFile:function (path, data, opts) { opts = opts || {}; opts.flags = opts.flags || 'w'; opts.encoding = opts.encoding || 'utf8'; if (opts.encoding !== 'utf8' && opts.encoding !== 'binary') { throw new Error('Invalid encoding type "' + opts.encoding + '"'); } var stream = FS.open(path, opts.flags, opts.mode); if (opts.encoding === 'utf8') { var utf8 = new Runtime.UTF8Processor(); var buf = new Uint8Array(utf8.processJSString(data)); FS.write(stream, buf, 0, buf.length, 0, opts.canOwn); } else if (opts.encoding === 'binary') { FS.write(stream, data, 0, data.length, 0, opts.canOwn); } FS.close(stream); },cwd:function () { return FS.currentPath; },chdir:function (path) { var lookup = FS.lookupPath(path, { follow: true }); if (!FS.isDir(lookup.node.mode)) { throw new FS.ErrnoError(ERRNO_CODES.ENOTDIR); } var err = FS.nodePermissions(lookup.node, 'x'); if (err) { throw new FS.ErrnoError(err); } FS.currentPath = lookup.path; },createDefaultDirectories:function () { FS.mkdir('/tmp'); },createDefaultDevices:function () { // create /dev FS.mkdir('/dev'); // setup /dev/null FS.registerDevice(FS.makedev(1, 3), { read: function() { return 0; }, write: function() { return 0; } }); FS.mkdev('/dev/null', FS.makedev(1, 3)); // setup /dev/tty and /dev/tty1 // stderr needs to print output using Module['printErr'] // so we register a second tty just for it. TTY.register(FS.makedev(5, 0), TTY.default_tty_ops); TTY.register(FS.makedev(6, 0), TTY.default_tty1_ops); FS.mkdev('/dev/tty', FS.makedev(5, 0)); FS.mkdev('/dev/tty1', FS.makedev(6, 0)); // we're not going to emulate the actual shm device, // just create the tmp dirs that reside in it commonly FS.mkdir('/dev/shm'); FS.mkdir('/dev/shm/tmp'); },createStandardStreams:function () { // TODO deprecate the old functionality of a single // input / output callback and that utilizes FS.createDevice // and instead require a unique set of stream ops // by default, we symlink the standard streams to the // default tty devices. however, if the standard streams // have been overwritten we create a unique device for // them instead. if (Module['stdin']) { FS.createDevice('/dev', 'stdin', Module['stdin']); } else { FS.symlink('/dev/tty', '/dev/stdin'); } if (Module['stdout']) { FS.createDevice('/dev', 'stdout', null, Module['stdout']); } else { FS.symlink('/dev/tty', '/dev/stdout'); } if (Module['stderr']) { FS.createDevice('/dev', 'stderr', null, Module['stderr']); } else { FS.symlink('/dev/tty1', '/dev/stderr'); } // open default streams for the stdin, stdout and stderr devices var stdin = FS.open('/dev/stdin', 'r'); HEAP32[((_stdin)>>2)]=FS.getPtrForStream(stdin); assert(stdin.fd === 0, 'invalid handle for stdin (' + stdin.fd + ')'); var stdout = FS.open('/dev/stdout', 'w'); HEAP32[((_stdout)>>2)]=FS.getPtrForStream(stdout); assert(stdout.fd === 1, 'invalid handle for stdout (' + stdout.fd + ')'); var stderr = FS.open('/dev/stderr', 'w'); HEAP32[((_stderr)>>2)]=FS.getPtrForStream(stderr); assert(stderr.fd === 2, 'invalid handle for stderr (' + stderr.fd + ')'); },ensureErrnoError:function () { if (FS.ErrnoError) return; FS.ErrnoError = function ErrnoError(errno) { this.errno = errno; for (var key in ERRNO_CODES) { if (ERRNO_CODES[key] === errno) { this.code = key; break; } } this.message = ERRNO_MESSAGES[errno]; }; FS.ErrnoError.prototype = new Error(); FS.ErrnoError.prototype.constructor = FS.ErrnoError; // Some errors may happen quite a bit, to avoid overhead we reuse them (and suffer a lack of stack info) [ERRNO_CODES.ENOENT].forEach(function(code) { FS.genericErrors[code] = new FS.ErrnoError(code); FS.genericErrors[code].stack = ''; }); },staticInit:function () { FS.ensureErrnoError(); FS.nameTable = new Array(4096); FS.mount(MEMFS, {}, '/'); FS.createDefaultDirectories(); FS.createDefaultDevices(); },init:function (input, output, error) { assert(!FS.init.initialized, 'FS.init was previously called. If you want to initialize later with custom parameters, remove any earlier calls (note that one is automatically added to the generated code)'); FS.init.initialized = true; FS.ensureErrnoError(); // Allow Module.stdin etc. to provide defaults, if none explicitly passed to us here Module['stdin'] = input || Module['stdin']; Module['stdout'] = output || Module['stdout']; Module['stderr'] = error || Module['stderr']; FS.createStandardStreams(); },quit:function () { FS.init.initialized = false; for (var i = 0; i < FS.streams.length; i++) { var stream = FS.streams[i]; if (!stream) { continue; } FS.close(stream); } },getMode:function (canRead, canWrite) { var mode = 0; if (canRead) mode |= 292 | 73; if (canWrite) mode |= 146; return mode; },joinPath:function (parts, forceRelative) { var path = PATH.join.apply(null, parts); if (forceRelative && path[0] == '/') path = path.substr(1); return path; },absolutePath:function (relative, base) { return PATH.resolve(base, relative); },standardizePath:function (path) { return PATH.normalize(path); },findObject:function (path, dontResolveLastLink) { var ret = FS.analyzePath(path, dontResolveLastLink); if (ret.exists) { return ret.object; } else { ___setErrNo(ret.error); return null; } },analyzePath:function (path, dontResolveLastLink) { // operate from within the context of the symlink's target try { var lookup = FS.lookupPath(path, { follow: !dontResolveLastLink }); path = lookup.path; } catch (e) { } var ret = { isRoot: false, exists: false, error: 0, name: null, path: null, object: null, parentExists: false, parentPath: null, parentObject: null }; try { var lookup = FS.lookupPath(path, { parent: true }); ret.parentExists = true; ret.parentPath = lookup.path; ret.parentObject = lookup.node; ret.name = PATH.basename(path); lookup = FS.lookupPath(path, { follow: !dontResolveLastLink }); ret.exists = true; ret.path = lookup.path; ret.object = lookup.node; ret.name = lookup.node.name; ret.isRoot = lookup.path === '/'; } catch (e) { ret.error = e.errno; }; return ret; },createFolder:function (parent, name, canRead, canWrite) { var path = PATH.join2(typeof parent === 'string' ? parent : FS.getPath(parent), name); var mode = FS.getMode(canRead, canWrite); return FS.mkdir(path, mode); },createPath:function (parent, path, canRead, canWrite) { parent = typeof parent === 'string' ? parent : FS.getPath(parent); var parts = path.split('/').reverse(); while (parts.length) { var part = parts.pop(); if (!part) continue; var current = PATH.join2(parent, part); try { FS.mkdir(current); } catch (e) { // ignore EEXIST } parent = current; } return current; },createFile:function (parent, name, properties, canRead, canWrite) { var path = PATH.join2(typeof parent === 'string' ? parent : FS.getPath(parent), name); var mode = FS.getMode(canRead, canWrite); return FS.create(path, mode); },createDataFile:function (parent, name, data, canRead, canWrite, canOwn) { var path = name ? PATH.join2(typeof parent === 'string' ? parent : FS.getPath(parent), name) : parent; var mode = FS.getMode(canRead, canWrite); var node = FS.create(path, mode); if (data) { if (typeof data === 'string') { var arr = new Array(data.length); for (var i = 0, len = data.length; i < len; ++i) arr[i] = data.charCodeAt(i); data = arr; } // make sure we can write to the file FS.chmod(node, mode | 146); var stream = FS.open(node, 'w'); FS.write(stream, data, 0, data.length, 0, canOwn); FS.close(stream); FS.chmod(node, mode); } return node; },createDevice:function (parent, name, input, output) { var path = PATH.join2(typeof parent === 'string' ? parent : FS.getPath(parent), name); var mode = FS.getMode(!!input, !!output); if (!FS.createDevice.major) FS.createDevice.major = 64; var dev = FS.makedev(FS.createDevice.major++, 0); // Create a fake device that a set of stream ops to emulate // the old behavior. FS.registerDevice(dev, { open: function(stream) { stream.seekable = false; }, close: function(stream) { // flush any pending line data if (output && output.buffer && output.buffer.length) { output(10); } }, read: function(stream, buffer, offset, length, pos /* ignored */) { var bytesRead = 0; for (var i = 0; i < length; i++) { var result; try { result = input(); } catch (e) { throw new FS.ErrnoError(ERRNO_CODES.EIO); } if (result === undefined && bytesRead === 0) { throw new FS.ErrnoError(ERRNO_CODES.EAGAIN); } if (result === null || result === undefined) break; bytesRead++; buffer[offset+i] = result; } if (bytesRead) { stream.node.timestamp = Date.now(); } return bytesRead; }, write: function(stream, buffer, offset, length, pos) { for (var i = 0; i < length; i++) { try { output(buffer[offset+i]); } catch (e) { throw new FS.ErrnoError(ERRNO_CODES.EIO); } } if (length) { stream.node.timestamp = Date.now(); } return i; } }); return FS.mkdev(path, mode, dev); },createLink:function (parent, name, target, canRead, canWrite) { var path = PATH.join2(typeof parent === 'string' ? parent : FS.getPath(parent), name); return FS.symlink(target, path); },forceLoadFile:function (obj) { if (obj.isDevice || obj.isFolder || obj.link || obj.contents) return true; var success = true; if (typeof XMLHttpRequest !== 'undefined') { throw new Error("Lazy loading should have been performed (contents set) in createLazyFile, but it was not. Lazy loading only works in web workers. Use --embed-file or --preload-file in emcc on the main thread."); } else if (Module['read']) { // Command-line. try { // WARNING: Can't read binary files in V8's d8 or tracemonkey's js, as // read() will try to parse UTF8. obj.contents = intArrayFromString(Module['read'](obj.url), true); } catch (e) { success = false; } } else { throw new Error('Cannot load without read() or XMLHttpRequest.'); } if (!success) ___setErrNo(ERRNO_CODES.EIO); return success; },createLazyFile:function (parent, name, url, canRead, canWrite) { // Lazy chunked Uint8Array (implements get and length from Uint8Array). Actual getting is abstracted away for eventual reuse. function LazyUint8Array() { this.lengthKnown = false; this.chunks = []; // Loaded chunks. Index is the chunk number } LazyUint8Array.prototype.get = function LazyUint8Array_get(idx) { if (idx > this.length-1 || idx < 0) { return undefined; } var chunkOffset = idx % this.chunkSize; var chunkNum = Math.floor(idx / this.chunkSize); return this.getter(chunkNum)[chunkOffset]; } LazyUint8Array.prototype.setDataGetter = function LazyUint8Array_setDataGetter(getter) { this.getter = getter; } LazyUint8Array.prototype.cacheLength = function LazyUint8Array_cacheLength() { // Find length var xhr = new XMLHttpRequest(); xhr.open('HEAD', url, false); xhr.send(null); if (!(xhr.status >= 200 && xhr.status < 300 || xhr.status === 304)) throw new Error("Couldn't load " + url + ". Status: " + xhr.status); var datalength = Number(xhr.getResponseHeader("Content-length")); var header; var hasByteServing = (header = xhr.getResponseHeader("Accept-Ranges")) && header === "bytes"; var chunkSize = 1024*1024; // Chunk size in bytes if (!hasByteServing) chunkSize = datalength; // Function to get a range from the remote URL. var doXHR = (function(from, to) { if (from > to) throw new Error("invalid range (" + from + ", " + to + ") or no bytes requested!"); if (to > datalength-1) throw new Error("only " + datalength + " bytes available! programmer error!"); // TODO: Use mozResponseArrayBuffer, responseStream, etc. if available. var xhr = new XMLHttpRequest(); xhr.open('GET', url, false); if (datalength !== chunkSize) xhr.setRequestHeader("Range", "bytes=" + from + "-" + to); // Some hints to the browser that we want binary data. if (typeof Uint8Array != 'undefined') xhr.responseType = 'arraybuffer'; if (xhr.overrideMimeType) { xhr.overrideMimeType('text/plain; charset=x-user-defined'); } xhr.send(null); if (!(xhr.status >= 200 && xhr.status < 300 || xhr.status === 304)) throw new Error("Couldn't load " + url + ". Status: " + xhr.status); if (xhr.response !== undefined) { return new Uint8Array(xhr.response || []); } else { return intArrayFromString(xhr.responseText || '', true); } }); var lazyArray = this; lazyArray.setDataGetter(function(chunkNum) { var start = chunkNum * chunkSize; var end = (chunkNum+1) * chunkSize - 1; // including this byte end = Math.min(end, datalength-1); // if datalength-1 is selected, this is the last block if (typeof(lazyArray.chunks[chunkNum]) === "undefined") { lazyArray.chunks[chunkNum] = doXHR(start, end); } if (typeof(lazyArray.chunks[chunkNum]) === "undefined") throw new Error("doXHR failed!"); return lazyArray.chunks[chunkNum]; }); this._length = datalength; this._chunkSize = chunkSize; this.lengthKnown = true; } if (typeof XMLHttpRequest !== 'undefined') { if (!ENVIRONMENT_IS_WORKER) throw 'Cannot do synchronous binary XHRs outside webworkers in modern browsers. Use --embed-file or --preload-file in emcc'; var lazyArray = new LazyUint8Array(); Object.defineProperty(lazyArray, "length", { get: function() { if(!this.lengthKnown) { this.cacheLength(); } return this._length; } }); Object.defineProperty(lazyArray, "chunkSize", { get: function() { if(!this.lengthKnown) { this.cacheLength(); } return this._chunkSize; } }); var properties = { isDevice: false, contents: lazyArray }; } else { var properties = { isDevice: false, url: url }; } var node = FS.createFile(parent, name, properties, canRead, canWrite); // This is a total hack, but I want to get this lazy file code out of the // core of MEMFS. If we want to keep this lazy file concept I feel it should // be its own thin LAZYFS proxying calls to MEMFS. if (properties.contents) { node.contents = properties.contents; } else if (properties.url) { node.contents = null; node.url = properties.url; } // override each stream op with one that tries to force load the lazy file first var stream_ops = {}; var keys = Object.keys(node.stream_ops); keys.forEach(function(key) { var fn = node.stream_ops[key]; stream_ops[key] = function forceLoadLazyFile() { if (!FS.forceLoadFile(node)) { throw new FS.ErrnoError(ERRNO_CODES.EIO); } return fn.apply(null, arguments); }; }); // use a custom read function stream_ops.read = function stream_ops_read(stream, buffer, offset, length, position) { if (!FS.forceLoadFile(node)) { throw new FS.ErrnoError(ERRNO_CODES.EIO); } var contents = stream.node.contents; if (position >= contents.length) return 0; var size = Math.min(contents.length - position, length); assert(size >= 0); if (contents.slice) { // normal array for (var i = 0; i < size; i++) { buffer[offset + i] = contents[position + i]; } } else { for (var i = 0; i < size; i++) { // LazyUint8Array from sync binary XHR buffer[offset + i] = contents.get(position + i); } } return size; }; node.stream_ops = stream_ops; return node; },createPreloadedFile:function (parent, name, url, canRead, canWrite, onload, onerror, dontCreateFile, canOwn) { Browser.init(); // TODO we should allow people to just pass in a complete filename instead // of parent and name being that we just join them anyways var fullname = name ? PATH.resolve(PATH.join2(parent, name)) : parent; function processData(byteArray) { function finish(byteArray) { if (!dontCreateFile) { FS.createDataFile(parent, name, byteArray, canRead, canWrite, canOwn); } if (onload) onload(); removeRunDependency('cp ' + fullname); } var handled = false; Module['preloadPlugins'].forEach(function(plugin) { if (handled) return; if (plugin['canHandle'](fullname)) { plugin['handle'](byteArray, fullname, finish, function() { if (onerror) onerror(); removeRunDependency('cp ' + fullname); }); handled = true; } }); if (!handled) finish(byteArray); } addRunDependency('cp ' + fullname); if (typeof url == 'string') { Browser.asyncLoad(url, function(byteArray) { processData(byteArray); }, onerror); } else { processData(url); } },indexedDB:function () { return window.indexedDB || window.mozIndexedDB || window.webkitIndexedDB || window.msIndexedDB; },DB_NAME:function () { return 'EM_FS_' + window.location.pathname; },DB_VERSION:20,DB_STORE_NAME:"FILE_DATA",saveFilesToDB:function (paths, onload, onerror) { onload = onload || function(){}; onerror = onerror || function(){}; var indexedDB = FS.indexedDB(); try { var openRequest = indexedDB.open(FS.DB_NAME(), FS.DB_VERSION); } catch (e) { return onerror(e); } openRequest.onupgradeneeded = function openRequest_onupgradeneeded() { console.log('creating db'); var db = openRequest.result; db.createObjectStore(FS.DB_STORE_NAME); }; openRequest.onsuccess = function openRequest_onsuccess() { var db = openRequest.result; var transaction = db.transaction([FS.DB_STORE_NAME], 'readwrite'); var files = transaction.objectStore(FS.DB_STORE_NAME); var ok = 0, fail = 0, total = paths.length; function finish() { if (fail == 0) onload(); else onerror(); } paths.forEach(function(path) { var putRequest = files.put(FS.analyzePath(path).object.contents, path); putRequest.onsuccess = function putRequest_onsuccess() { ok++; if (ok + fail == total) finish() }; putRequest.onerror = function putRequest_onerror() { fail++; if (ok + fail == total) finish() }; }); transaction.onerror = onerror; }; openRequest.onerror = onerror; },loadFilesFromDB:function (paths, onload, onerror) { onload = onload || function(){}; onerror = onerror || function(){}; var indexedDB = FS.indexedDB(); try { var openRequest = indexedDB.open(FS.DB_NAME(), FS.DB_VERSION); } catch (e) { return onerror(e); } openRequest.onupgradeneeded = onerror; // no database to load from openRequest.onsuccess = function openRequest_onsuccess() { var db = openRequest.result; try { var transaction = db.transaction([FS.DB_STORE_NAME], 'readonly'); } catch(e) { onerror(e); return; } var files = transaction.objectStore(FS.DB_STORE_NAME); var ok = 0, fail = 0, total = paths.length; function finish() { if (fail == 0) onload(); else onerror(); } paths.forEach(function(path) { var getRequest = files.get(path); getRequest.onsuccess = function getRequest_onsuccess() { if (FS.analyzePath(path).exists) { FS.unlink(path); } FS.createDataFile(PATH.dirname(path), PATH.basename(path), getRequest.result, true, true, true); ok++; if (ok + fail == total) finish(); }; getRequest.onerror = function getRequest_onerror() { fail++; if (ok + fail == total) finish() }; }); transaction.onerror = onerror; }; openRequest.onerror = onerror; }}; function _mkport() { throw 'TODO' }var SOCKFS={mount:function (mount) { return FS.createNode(null, '/', 16384 | 511 /* 0777 */, 0); },createSocket:function (family, type, protocol) { var streaming = type == 1; if (protocol) { assert(streaming == (protocol == 6)); // if SOCK_STREAM, must be tcp } // create our internal socket structure var sock = { family: family, type: type, protocol: protocol, server: null, peers: {}, pending: [], recv_queue: [], sock_ops: SOCKFS.websocket_sock_ops }; // create the filesystem node to store the socket structure var name = SOCKFS.nextname(); var node = FS.createNode(SOCKFS.root, name, 49152, 0); node.sock = sock; // and the wrapping stream that enables library functions such // as read and write to indirectly interact with the socket var stream = FS.createStream({ path: name, node: node, flags: FS.modeStringToFlags('r+'), seekable: false, stream_ops: SOCKFS.stream_ops }); // map the new stream to the socket structure (sockets have a 1:1 // relationship with a stream) sock.stream = stream; return sock; },getSocket:function (fd) { var stream = FS.getStream(fd); if (!stream || !FS.isSocket(stream.node.mode)) { return null; } return stream.node.sock; },stream_ops:{poll:function (stream) { var sock = stream.node.sock; return sock.sock_ops.poll(sock); },ioctl:function (stream, request, varargs) { var sock = stream.node.sock; return sock.sock_ops.ioctl(sock, request, varargs); },read:function (stream, buffer, offset, length, position /* ignored */) { var sock = stream.node.sock; var msg = sock.sock_ops.recvmsg(sock, length); if (!msg) { // socket is closed return 0; } buffer.set(msg.buffer, offset); return msg.buffer.length; },write:function (stream, buffer, offset, length, position /* ignored */) { var sock = stream.node.sock; return sock.sock_ops.sendmsg(sock, buffer, offset, length); },close:function (stream) { var sock = stream.node.sock; sock.sock_ops.close(sock); }},nextname:function () { if (!SOCKFS.nextname.current) { SOCKFS.nextname.current = 0; } return 'socket[' + (SOCKFS.nextname.current++) + ']'; },websocket_sock_ops:{createPeer:function (sock, addr, port) { var ws; if (typeof addr === 'object') { ws = addr; addr = null; port = null; } if (ws) { // for sockets that've already connected (e.g. we're the server) // we can inspect the _socket property for the address if (ws._socket) { addr = ws._socket.remoteAddress; port = ws._socket.remotePort; } // if we're just now initializing a connection to the remote, // inspect the url property else { var result = /ws[s]?:\/\/([^:]+):(\d+)/.exec(ws.url); if (!result) { throw new Error('WebSocket URL must be in the format ws(s)://address:port'); } addr = result[1]; port = parseInt(result[2], 10); } } else { // create the actual websocket object and connect try { // runtimeConfig gets set to true if WebSocket runtime configuration is available. var runtimeConfig = (Module['websocket'] && ('object' === typeof Module['websocket'])); // The default value is 'ws://' the replace is needed because the compiler replaces "//" comments with '#' // comments without checking context, so we'd end up with ws:#, the replace swaps the "#" for "//" again. var url = 'ws:#'.replace('#', '//'); if (runtimeConfig) { if ('string' === typeof Module['websocket']['url']) { url = Module['websocket']['url']; // Fetch runtime WebSocket URL config. } } if (url === 'ws://' || url === 'wss://') { // Is the supplied URL config just a prefix, if so complete it. url = url + addr + ':' + port; } // Make the WebSocket subprotocol (Sec-WebSocket-Protocol) default to binary if no configuration is set. var subProtocols = 'binary'; // The default value is 'binary' if (runtimeConfig) { if ('string' === typeof Module['websocket']['subprotocol']) { subProtocols = Module['websocket']['subprotocol']; // Fetch runtime WebSocket subprotocol config. } } // The regex trims the string (removes spaces at the beginning and end, then splits the string by // , into an Array. Whitespace removal is important for Websockify and ws. subProtocols = subProtocols.replace(/^ +| +$/g,"").split(/ *, */); // The node ws library API for specifying optional subprotocol is slightly different than the browser's. var opts = ENVIRONMENT_IS_NODE ? {'protocol': subProtocols.toString()} : subProtocols; // If node we use the ws library. var WebSocket = ENVIRONMENT_IS_NODE ? require('ws') : window['WebSocket']; ws = new WebSocket(url, opts); ws.binaryType = 'arraybuffer'; } catch (e) { throw new FS.ErrnoError(ERRNO_CODES.EHOSTUNREACH); } } var peer = { addr: addr, port: port, socket: ws, dgram_send_queue: [] }; SOCKFS.websocket_sock_ops.addPeer(sock, peer); SOCKFS.websocket_sock_ops.handlePeerEvents(sock, peer); // if this is a bound dgram socket, send the port number first to allow // us to override the ephemeral port reported to us by remotePort on the // remote end. if (sock.type === 2 && typeof sock.sport !== 'undefined') { peer.dgram_send_queue.push(new Uint8Array([ 255, 255, 255, 255, 'p'.charCodeAt(0), 'o'.charCodeAt(0), 'r'.charCodeAt(0), 't'.charCodeAt(0), ((sock.sport & 0xff00) >> 8) , (sock.sport & 0xff) ])); } return peer; },getPeer:function (sock, addr, port) { return sock.peers[addr + ':' + port]; },addPeer:function (sock, peer) { sock.peers[peer.addr + ':' + peer.port] = peer; },removePeer:function (sock, peer) { delete sock.peers[peer.addr + ':' + peer.port]; },handlePeerEvents:function (sock, peer) { var first = true; var handleOpen = function () { try { var queued = peer.dgram_send_queue.shift(); while (queued) { peer.socket.send(queued); queued = peer.dgram_send_queue.shift(); } } catch (e) { // not much we can do here in the way of proper error handling as we've already // lied and said this data was sent. shut it down. peer.socket.close(); } }; function handleMessage(data) { assert(typeof data !== 'string' && data.byteLength !== undefined); // must receive an ArrayBuffer data = new Uint8Array(data); // make a typed array view on the array buffer // if this is the port message, override the peer's port with it var wasfirst = first; first = false; if (wasfirst && data.length === 10 && data[0] === 255 && data[1] === 255 && data[2] === 255 && data[3] === 255 && data[4] === 'p'.charCodeAt(0) && data[5] === 'o'.charCodeAt(0) && data[6] === 'r'.charCodeAt(0) && data[7] === 't'.charCodeAt(0)) { // update the peer's port and it's key in the peer map var newport = ((data[8] << 8) | data[9]); SOCKFS.websocket_sock_ops.removePeer(sock, peer); peer.port = newport; SOCKFS.websocket_sock_ops.addPeer(sock, peer); return; } sock.recv_queue.push({ addr: peer.addr, port: peer.port, data: data }); }; if (ENVIRONMENT_IS_NODE) { peer.socket.on('open', handleOpen); peer.socket.on('message', function(data, flags) { if (!flags.binary) { return; } handleMessage((new Uint8Array(data)).buffer); // copy from node Buffer -> ArrayBuffer }); peer.socket.on('error', function() { // don't throw }); } else { peer.socket.onopen = handleOpen; peer.socket.onmessage = function peer_socket_onmessage(event) { handleMessage(event.data); }; } },poll:function (sock) { if (sock.type === 1 && sock.server) { // listen sockets should only say they're available for reading // if there are pending clients. return sock.pending.length ? (64 | 1) : 0; } var mask = 0; var dest = sock.type === 1 ? // we only care about the socket state for connection-based sockets SOCKFS.websocket_sock_ops.getPeer(sock, sock.daddr, sock.dport) : null; if (sock.recv_queue.length || !dest || // connection-less sockets are always ready to read (dest && dest.socket.readyState === dest.socket.CLOSING) || (dest && dest.socket.readyState === dest.socket.CLOSED)) { // let recv return 0 once closed mask |= (64 | 1); } if (!dest || // connection-less sockets are always ready to write (dest && dest.socket.readyState === dest.socket.OPEN)) { mask |= 4; } if ((dest && dest.socket.readyState === dest.socket.CLOSING) || (dest && dest.socket.readyState === dest.socket.CLOSED)) { mask |= 16; } return mask; },ioctl:function (sock, request, arg) { switch (request) { case 21531: var bytes = 0; if (sock.recv_queue.length) { bytes = sock.recv_queue[0].data.length; } HEAP32[((arg)>>2)]=bytes; return 0; default: return ERRNO_CODES.EINVAL; } },close:function (sock) { // if we've spawned a listen server, close it if (sock.server) { try { sock.server.close(); } catch (e) { } sock.server = null; } // close any peer connections var peers = Object.keys(sock.peers); for (var i = 0; i < peers.length; i++) { var peer = sock.peers[peers[i]]; try { peer.socket.close(); } catch (e) { } SOCKFS.websocket_sock_ops.removePeer(sock, peer); } return 0; },bind:function (sock, addr, port) { if (typeof sock.saddr !== 'undefined' || typeof sock.sport !== 'undefined') { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); // already bound } sock.saddr = addr; sock.sport = port || _mkport(); // in order to emulate dgram sockets, we need to launch a listen server when // binding on a connection-less socket // note: this is only required on the server side if (sock.type === 2) { // close the existing server if it exists if (sock.server) { sock.server.close(); sock.server = null; } // swallow error operation not supported error that occurs when binding in the // browser where this isn't supported try { sock.sock_ops.listen(sock, 0); } catch (e) { if (!(e instanceof FS.ErrnoError)) throw e; if (e.errno !== ERRNO_CODES.EOPNOTSUPP) throw e; } } },connect:function (sock, addr, port) { if (sock.server) { throw new FS.ErrnoError(ERRNO_CODS.EOPNOTSUPP); } // TODO autobind // if (!sock.addr && sock.type == 2) { // } // early out if we're already connected / in the middle of connecting if (typeof sock.daddr !== 'undefined' && typeof sock.dport !== 'undefined') { var dest = SOCKFS.websocket_sock_ops.getPeer(sock, sock.daddr, sock.dport); if (dest) { if (dest.socket.readyState === dest.socket.CONNECTING) { throw new FS.ErrnoError(ERRNO_CODES.EALREADY); } else { throw new FS.ErrnoError(ERRNO_CODES.EISCONN); } } } // add the socket to our peer list and set our // destination address / port to match var peer = SOCKFS.websocket_sock_ops.createPeer(sock, addr, port); sock.daddr = peer.addr; sock.dport = peer.port; // always "fail" in non-blocking mode throw new FS.ErrnoError(ERRNO_CODES.EINPROGRESS); },listen:function (sock, backlog) { if (!ENVIRONMENT_IS_NODE) { throw new FS.ErrnoError(ERRNO_CODES.EOPNOTSUPP); } if (sock.server) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); // already listening } var WebSocketServer = require('ws').Server; var host = sock.saddr; sock.server = new WebSocketServer({ host: host, port: sock.sport // TODO support backlog }); sock.server.on('connection', function(ws) { if (sock.type === 1) { var newsock = SOCKFS.createSocket(sock.family, sock.type, sock.protocol); // create a peer on the new socket var peer = SOCKFS.websocket_sock_ops.createPeer(newsock, ws); newsock.daddr = peer.addr; newsock.dport = peer.port; // push to queue for accept to pick up sock.pending.push(newsock); } else { // create a peer on the listen socket so calling sendto // with the listen socket and an address will resolve // to the correct client SOCKFS.websocket_sock_ops.createPeer(sock, ws); } }); sock.server.on('closed', function() { sock.server = null; }); sock.server.on('error', function() { // don't throw }); },accept:function (listensock) { if (!listensock.server) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } var newsock = listensock.pending.shift(); newsock.stream.flags = listensock.stream.flags; return newsock; },getname:function (sock, peer) { var addr, port; if (peer) { if (sock.daddr === undefined || sock.dport === undefined) { throw new FS.ErrnoError(ERRNO_CODES.ENOTCONN); } addr = sock.daddr; port = sock.dport; } else { // TODO saddr and sport will be set for bind()'d UDP sockets, but what // should we be returning for TCP sockets that've been connect()'d? addr = sock.saddr || 0; port = sock.sport || 0; } return { addr: addr, port: port }; },sendmsg:function (sock, buffer, offset, length, addr, port) { if (sock.type === 2) { // connection-less sockets will honor the message address, // and otherwise fall back to the bound destination address if (addr === undefined || port === undefined) { addr = sock.daddr; port = sock.dport; } // if there was no address to fall back to, error out if (addr === undefined || port === undefined) { throw new FS.ErrnoError(ERRNO_CODES.EDESTADDRREQ); } } else { // connection-based sockets will only use the bound addr = sock.daddr; port = sock.dport; } // find the peer for the destination address var dest = SOCKFS.websocket_sock_ops.getPeer(sock, addr, port); // early out if not connected with a connection-based socket if (sock.type === 1) { if (!dest || dest.socket.readyState === dest.socket.CLOSING || dest.socket.readyState === dest.socket.CLOSED) { throw new FS.ErrnoError(ERRNO_CODES.ENOTCONN); } else if (dest.socket.readyState === dest.socket.CONNECTING) { throw new FS.ErrnoError(ERRNO_CODES.EAGAIN); } } // create a copy of the incoming data to send, as the WebSocket API // doesn't work entirely with an ArrayBufferView, it'll just send // the entire underlying buffer var data; if (buffer instanceof Array || buffer instanceof ArrayBuffer) { data = buffer.slice(offset, offset + length); } else { // ArrayBufferView data = buffer.buffer.slice(buffer.byteOffset + offset, buffer.byteOffset + offset + length); } // if we're emulating a connection-less dgram socket and don't have // a cached connection, queue the buffer to send upon connect and // lie, saying the data was sent now. if (sock.type === 2) { if (!dest || dest.socket.readyState !== dest.socket.OPEN) { // if we're not connected, open a new connection if (!dest || dest.socket.readyState === dest.socket.CLOSING || dest.socket.readyState === dest.socket.CLOSED) { dest = SOCKFS.websocket_sock_ops.createPeer(sock, addr, port); } dest.dgram_send_queue.push(data); return length; } } try { // send the actual data dest.socket.send(data); return length; } catch (e) { throw new FS.ErrnoError(ERRNO_CODES.EINVAL); } },recvmsg:function (sock, length) { // http://pubs.opengroup.org/onlinepubs/7908799/xns/recvmsg.html if (sock.type === 1 && sock.server) { // tcp servers should not be recv()'ing on the listen socket throw new FS.ErrnoError(ERRNO_CODES.ENOTCONN); } var queued = sock.recv_queue.shift(); if (!queued) { if (sock.type === 1) { var dest = SOCKFS.websocket_sock_ops.getPeer(sock, sock.daddr, sock.dport); if (!dest) { // if we have a destination address but are not connected, error out throw new FS.ErrnoError(ERRNO_CODES.ENOTCONN); } else if (dest.socket.readyState === dest.socket.CLOSING || dest.socket.readyState === dest.socket.CLOSED) { // return null if the socket has closed return null; } else { // else, our socket is in a valid state but truly has nothing available throw new FS.ErrnoError(ERRNO_CODES.EAGAIN); } } else { throw new FS.ErrnoError(ERRNO_CODES.EAGAIN); } } // queued.data will be an ArrayBuffer if it's unadulterated, but if it's // requeued TCP data it'll be an ArrayBufferView var queuedLength = queued.data.byteLength || queued.data.length; var queuedOffset = queued.data.byteOffset || 0; var queuedBuffer = queued.data.buffer || queued.data; var bytesRead = Math.min(length, queuedLength); var res = { buffer: new Uint8Array(queuedBuffer, queuedOffset, bytesRead), addr: queued.addr, port: queued.port }; // push back any unread data for TCP connections if (sock.type === 1 && bytesRead < queuedLength) { var bytesRemaining = queuedLength - bytesRead; queued.data = new Uint8Array(queuedBuffer, queuedOffset + bytesRead, bytesRemaining); sock.recv_queue.unshift(queued); } return res; }}};function _send(fd, buf, len, flags) { var sock = SOCKFS.getSocket(fd); if (!sock) { ___setErrNo(ERRNO_CODES.EBADF); return -1; } // TODO honor flags return _write(fd, buf, len); } function _pwrite(fildes, buf, nbyte, offset) { // ssize_t pwrite(int fildes, const void *buf, size_t nbyte, off_t offset); // http://pubs.opengroup.org/onlinepubs/000095399/functions/write.html var stream = FS.getStream(fildes); if (!stream) { ___setErrNo(ERRNO_CODES.EBADF); return -1; } try { var slab = HEAP8; return FS.write(stream, slab, buf, nbyte, offset); } catch (e) { FS.handleFSError(e); return -1; } }function _write(fildes, buf, nbyte) { // ssize_t write(int fildes, const void *buf, size_t nbyte); // http://pubs.opengroup.org/onlinepubs/000095399/functions/write.html var stream = FS.getStream(fildes); if (!stream) { ___setErrNo(ERRNO_CODES.EBADF); return -1; } try { var slab = HEAP8; return FS.write(stream, slab, buf, nbyte); } catch (e) { FS.handleFSError(e); return -1; } } function _fileno(stream) { // int fileno(FILE *stream); // http://pubs.opengroup.org/onlinepubs/000095399/functions/fileno.html stream = FS.getStreamFromPtr(stream); if (!stream) return -1; return stream.fd; }function _fwrite(ptr, size, nitems, stream) { // size_t fwrite(const void *restrict ptr, size_t size, size_t nitems, FILE *restrict stream); // http://pubs.opengroup.org/onlinepubs/000095399/functions/fwrite.html var bytesToWrite = nitems * size; if (bytesToWrite == 0) return 0; var fd = _fileno(stream); var bytesWritten = _write(fd, ptr, bytesToWrite); if (bytesWritten == -1) { var streamObj = FS.getStreamFromPtr(stream); if (streamObj) streamObj.error = true; return 0; } else { return Math.floor(bytesWritten / size); } } Module["_strlen"] = _strlen; function __reallyNegative(x) { return x < 0 || (x === 0 && (1/x) === -Infinity); }function __formatString(format, varargs) { var textIndex = format; var argIndex = 0; function getNextArg(type) { // NOTE: Explicitly ignoring type safety. Otherwise this fails: // int x = 4; printf("%c\n", (char)x); var ret; if (type === 'double') { ret = HEAPF64[(((varargs)+(argIndex))>>3)]; } else if (type == 'i64') { ret = [HEAP32[(((varargs)+(argIndex))>>2)], HEAP32[(((varargs)+(argIndex+4))>>2)]]; } else { type = 'i32'; // varargs are always i32, i64, or double ret = HEAP32[(((varargs)+(argIndex))>>2)]; } argIndex += Runtime.getNativeFieldSize(type); return ret; } var ret = []; var curr, next, currArg; while(1) { var startTextIndex = textIndex; curr = HEAP8[(textIndex)]; if (curr === 0) break; next = HEAP8[((textIndex+1)|0)]; if (curr == 37) { // Handle flags. var flagAlwaysSigned = false; var flagLeftAlign = false; var flagAlternative = false; var flagZeroPad = false; var flagPadSign = false; flagsLoop: while (1) { switch (next) { case 43: flagAlwaysSigned = true; break; case 45: flagLeftAlign = true; break; case 35: flagAlternative = true; break; case 48: if (flagZeroPad) { break flagsLoop; } else { flagZeroPad = true; break; } case 32: flagPadSign = true; break; default: break flagsLoop; } textIndex++; next = HEAP8[((textIndex+1)|0)]; } // Handle width. var width = 0; if (next == 42) { width = getNextArg('i32'); textIndex++; next = HEAP8[((textIndex+1)|0)]; } else { while (next >= 48 && next <= 57) { width = width * 10 + (next - 48); textIndex++; next = HEAP8[((textIndex+1)|0)]; } } // Handle precision. var precisionSet = false, precision = -1; if (next == 46) { precision = 0; precisionSet = true; textIndex++; next = HEAP8[((textIndex+1)|0)]; if (next == 42) { precision = getNextArg('i32'); textIndex++; } else { while(1) { var precisionChr = HEAP8[((textIndex+1)|0)]; if (precisionChr < 48 || precisionChr > 57) break; precision = precision * 10 + (precisionChr - 48); textIndex++; } } next = HEAP8[((textIndex+1)|0)]; } if (precision < 0) { precision = 6; // Standard default. precisionSet = false; } // Handle integer sizes. WARNING: These assume a 32-bit architecture! var argSize; switch (String.fromCharCode(next)) { case 'h': var nextNext = HEAP8[((textIndex+2)|0)]; if (nextNext == 104) { textIndex++; argSize = 1; // char (actually i32 in varargs) } else { argSize = 2; // short (actually i32 in varargs) } break; case 'l': var nextNext = HEAP8[((textIndex+2)|0)]; if (nextNext == 108) { textIndex++; argSize = 8; // long long } else { argSize = 4; // long } break; case 'L': // long long case 'q': // int64_t case 'j': // intmax_t argSize = 8; break; case 'z': // size_t case 't': // ptrdiff_t case 'I': // signed ptrdiff_t or unsigned size_t argSize = 4; break; default: argSize = null; } if (argSize) textIndex++; next = HEAP8[((textIndex+1)|0)]; // Handle type specifier. switch (String.fromCharCode(next)) { case 'd': case 'i': case 'u': case 'o': case 'x': case 'X': case 'p': { // Integer. var signed = next == 100 || next == 105; argSize = argSize || 4; var currArg = getNextArg('i' + (argSize * 8)); var argText; // Flatten i64-1 [low, high] into a (slightly rounded) double if (argSize == 8) { currArg = Runtime.makeBigInt(currArg[0], currArg[1], next == 117); } // Truncate to requested size. if (argSize <= 4) { var limit = Math.pow(256, argSize) - 1; currArg = (signed ? reSign : unSign)(currArg & limit, argSize * 8); } // Format the number. var currAbsArg = Math.abs(currArg); var prefix = ''; if (next == 100 || next == 105) { argText = reSign(currArg, 8 * argSize, 1).toString(10); } else if (next == 117) { argText = unSign(currArg, 8 * argSize, 1).toString(10); currArg = Math.abs(currArg); } else if (next == 111) { argText = (flagAlternative ? '0' : '') + currAbsArg.toString(8); } else if (next == 120 || next == 88) { prefix = (flagAlternative && currArg != 0) ? '0x' : ''; if (currArg < 0) { // Represent negative numbers in hex as 2's complement. currArg = -currArg; argText = (currAbsArg - 1).toString(16); var buffer = []; for (var i = 0; i < argText.length; i++) { buffer.push((0xF - parseInt(argText[i], 16)).toString(16)); } argText = buffer.join(''); while (argText.length < argSize * 2) argText = 'f' + argText; } else { argText = currAbsArg.toString(16); } if (next == 88) { prefix = prefix.toUpperCase(); argText = argText.toUpperCase(); } } else if (next == 112) { if (currAbsArg === 0) { argText = '(nil)'; } else { prefix = '0x'; argText = currAbsArg.toString(16); } } if (precisionSet) { while (argText.length < precision) { argText = '0' + argText; } } // Add sign if needed if (currArg >= 0) { if (flagAlwaysSigned) { prefix = '+' + prefix; } else if (flagPadSign) { prefix = ' ' + prefix; } } // Move sign to prefix so we zero-pad after the sign if (argText.charAt(0) == '-') { prefix = '-' + prefix; argText = argText.substr(1); } // Add padding. while (prefix.length + argText.length < width) { if (flagLeftAlign) { argText += ' '; } else { if (flagZeroPad) { argText = '0' + argText; } else { prefix = ' ' + prefix; } } } // Insert the result into the buffer. argText = prefix + argText; argText.split('').forEach(function(chr) { ret.push(chr.charCodeAt(0)); }); break; } case 'f': case 'F': case 'e': case 'E': case 'g': case 'G': { // Float. var currArg = getNextArg('double'); var argText; if (isNaN(currArg)) { argText = 'nan'; flagZeroPad = false; } else if (!isFinite(currArg)) { argText = (currArg < 0 ? '-' : '') + 'inf'; flagZeroPad = false; } else { var isGeneral = false; var effectivePrecision = Math.min(precision, 20); // Convert g/G to f/F or e/E, as per: // http://pubs.opengroup.org/onlinepubs/9699919799/functions/printf.html if (next == 103 || next == 71) { isGeneral = true; precision = precision || 1; var exponent = parseInt(currArg.toExponential(effectivePrecision).split('e')[1], 10); if (precision > exponent && exponent >= -4) { next = ((next == 103) ? 'f' : 'F').charCodeAt(0); precision -= exponent + 1; } else { next = ((next == 103) ? 'e' : 'E').charCodeAt(0); precision--; } effectivePrecision = Math.min(precision, 20); } if (next == 101 || next == 69) { argText = currArg.toExponential(effectivePrecision); // Make sure the exponent has at least 2 digits. if (/[eE][-+]\d$/.test(argText)) { argText = argText.slice(0, -1) + '0' + argText.slice(-1); } } else if (next == 102 || next == 70) { argText = currArg.toFixed(effectivePrecision); if (currArg === 0 && __reallyNegative(currArg)) { argText = '-' + argText; } } var parts = argText.split('e'); if (isGeneral && !flagAlternative) { // Discard trailing zeros and periods. while (parts[0].length > 1 && parts[0].indexOf('.') != -1 && (parts[0].slice(-1) == '0' || parts[0].slice(-1) == '.')) { parts[0] = parts[0].slice(0, -1); } } else { // Make sure we have a period in alternative mode. if (flagAlternative && argText.indexOf('.') == -1) parts[0] += '.'; // Zero pad until required precision. while (precision > effectivePrecision++) parts[0] += '0'; } argText = parts[0] + (parts.length > 1 ? 'e' + parts[1] : ''); // Capitalize 'E' if needed. if (next == 69) argText = argText.toUpperCase(); // Add sign. if (currArg >= 0) { if (flagAlwaysSigned) { argText = '+' + argText; } else if (flagPadSign) { argText = ' ' + argText; } } } // Add padding. while (argText.length < width) { if (flagLeftAlign) { argText += ' '; } else { if (flagZeroPad && (argText[0] == '-' || argText[0] == '+')) { argText = argText[0] + '0' + argText.slice(1); } else { argText = (flagZeroPad ? '0' : ' ') + argText; } } } // Adjust case. if (next < 97) argText = argText.toUpperCase(); // Insert the result into the buffer. argText.split('').forEach(function(chr) { ret.push(chr.charCodeAt(0)); }); break; } case 's': { // String. var arg = getNextArg('i8*'); var argLength = arg ? _strlen(arg) : '(null)'.length; if (precisionSet) argLength = Math.min(argLength, precision); if (!flagLeftAlign) { while (argLength < width--) { ret.push(32); } } if (arg) { for (var i = 0; i < argLength; i++) { ret.push(HEAPU8[((arg++)|0)]); } } else { ret = ret.concat(intArrayFromString('(null)'.substr(0, argLength), true)); } if (flagLeftAlign) { while (argLength < width--) { ret.push(32); } } break; } case 'c': { // Character. if (flagLeftAlign) ret.push(getNextArg('i8')); while (--width > 0) { ret.push(32); } if (!flagLeftAlign) ret.push(getNextArg('i8')); break; } case 'n': { // Write the length written so far to the next parameter. var ptr = getNextArg('i32*'); HEAP32[((ptr)>>2)]=ret.length; break; } case '%': { // Literal percent sign. ret.push(curr); break; } default: { // Unknown specifiers remain untouched. for (var i = startTextIndex; i < textIndex + 2; i++) { ret.push(HEAP8[(i)]); } } } textIndex += 2; // TODO: Support a/A (hex float) and m (last error) specifiers. // TODO: Support %1${specifier} for arg selection. } else { ret.push(curr); textIndex += 1; } } return ret; }function _fprintf(stream, format, varargs) { // int fprintf(FILE *restrict stream, const char *restrict format, ...); // http://pubs.opengroup.org/onlinepubs/000095399/functions/printf.html var result = __formatString(format, varargs); var stack = Runtime.stackSave(); var ret = _fwrite(allocate(result, 'i8', ALLOC_STACK), 1, result.length, stream); Runtime.stackRestore(stack); return ret; }function _printf(format, varargs) { // int printf(const char *restrict format, ...); // http://pubs.opengroup.org/onlinepubs/000095399/functions/printf.html var stdout = HEAP32[((_stdout)>>2)]; return _fprintf(stdout, format, varargs); } function _fputc(c, stream) { // int fputc(int c, FILE *stream); // http://pubs.opengroup.org/onlinepubs/000095399/functions/fputc.html var chr = unSign(c & 0xFF); HEAP8[((_fputc.ret)|0)]=chr; var fd = _fileno(stream); var ret = _write(fd, _fputc.ret, 1); if (ret == -1) { var streamObj = FS.getStreamFromPtr(stream); if (streamObj) streamObj.error = true; return -1; } else { return chr; } }function _putchar(c) { // int putchar(int c); // http://pubs.opengroup.org/onlinepubs/000095399/functions/putchar.html return _fputc(c, HEAP32[((_stdout)>>2)]); } function _sbrk(bytes) { // Implement a Linux-like 'memory area' for our 'process'. // Changes the size of the memory area by |bytes|; returns the // address of the previous top ('break') of the memory area // We control the "dynamic" memory - DYNAMIC_BASE to DYNAMICTOP var self = _sbrk; if (!self.called) { DYNAMICTOP = alignMemoryPage(DYNAMICTOP); // make sure we start out aligned self.called = true; assert(Runtime.dynamicAlloc); self.alloc = Runtime.dynamicAlloc; Runtime.dynamicAlloc = function() { abort('cannot dynamically allocate, sbrk now has control') }; } var ret = DYNAMICTOP; if (bytes != 0) self.alloc(bytes); return ret; // Previous break location. } function _sysconf(name) { // long sysconf(int name); // http://pubs.opengroup.org/onlinepubs/009695399/functions/sysconf.html switch(name) { case 30: return PAGE_SIZE; case 132: case 133: case 12: case 137: case 138: case 15: case 235: case 16: case 17: case 18: case 19: case 20: case 149: case 13: case 10: case 236: case 153: case 9: case 21: case 22: case 159: case 154: case 14: case 77: case 78: case 139: case 80: case 81: case 79: case 82: case 68: case 67: case 164: case 11: case 29: case 47: case 48: case 95: case 52: case 51: case 46: return 200809; case 27: case 246: case 127: case 128: case 23: case 24: case 160: case 161: case 181: case 182: case 242: case 183: case 184: case 243: case 244: case 245: case 165: case 178: case 179: case 49: case 50: case 168: case 169: case 175: case 170: case 171: case 172: case 97: case 76: case 32: case 173: case 35: return -1; case 176: case 177: case 7: case 155: case 8: case 157: case 125: case 126: case 92: case 93: case 129: case 130: case 131: case 94: case 91: return 1; case 74: case 60: case 69: case 70: case 4: return 1024; case 31: case 42: case 72: return 32; case 87: case 26: case 33: return 2147483647; case 34: case 1: return 47839; case 38: case 36: return 99; case 43: case 37: return 2048; case 0: return 2097152; case 3: return 65536; case 28: return 32768; case 44: return 32767; case 75: return 16384; case 39: return 1000; case 89: return 700; case 71: return 256; case 40: return 255; case 2: return 100; case 180: return 64; case 25: return 20; case 5: return 16; case 6: return 6; case 73: return 4; case 84: return 1; } ___setErrNo(ERRNO_CODES.EINVAL); return -1; } Module["_memset"] = _memset; function ___errno_location() { return ___errno_state; } function _abort() { Module['abort'](); } var Browser={mainLoop:{scheduler:null,method:"",shouldPause:false,paused:false,queue:[],pause:function () { Browser.mainLoop.shouldPause = true; },resume:function () { if (Browser.mainLoop.paused) { Browser.mainLoop.paused = false; Browser.mainLoop.scheduler(); } Browser.mainLoop.shouldPause = false; },updateStatus:function () { if (Module['setStatus']) { var message = Module['statusMessage'] || 'Please wait...'; var remaining = Browser.mainLoop.remainingBlockers; var expected = Browser.mainLoop.expectedBlockers; if (remaining) { if (remaining < expected) { Module['setStatus'](message + ' (' + (expected - remaining) + '/' + expected + ')'); } else { Module['setStatus'](message); } } else { Module['setStatus'](''); } } }},isFullScreen:false,pointerLock:false,moduleContextCreatedCallbacks:[],workers:[],init:function () { if (!Module["preloadPlugins"]) Module["preloadPlugins"] = []; // needs to exist even in workers if (Browser.initted || ENVIRONMENT_IS_WORKER) return; Browser.initted = true; try { new Blob(); Browser.hasBlobConstructor = true; } catch(e) { Browser.hasBlobConstructor = false; console.log("warning: no blob constructor, cannot create blobs with mimetypes"); } Browser.BlobBuilder = typeof MozBlobBuilder != "undefined" ? MozBlobBuilder : (typeof WebKitBlobBuilder != "undefined" ? WebKitBlobBuilder : (!Browser.hasBlobConstructor ? console.log("warning: no BlobBuilder") : null)); Browser.URLObject = typeof window != "undefined" ? (window.URL ? window.URL : window.webkitURL) : undefined; if (!Module.noImageDecoding && typeof Browser.URLObject === 'undefined') { console.log("warning: Browser does not support creating object URLs. Built-in browser image decoding will not be available."); Module.noImageDecoding = true; } // Support for plugins that can process preloaded files. You can add more of these to // your app by creating and appending to Module.preloadPlugins. // // Each plugin is asked if it can handle a file based on the file's name. If it can, // it is given the file's raw data. When it is done, it calls a callback with the file's // (possibly modified) data. For example, a plugin might decompress a file, or it // might create some side data structure for use later (like an Image element, etc.). var imagePlugin = {}; imagePlugin['canHandle'] = function imagePlugin_canHandle(name) { return !Module.noImageDecoding && /\.(jpg|jpeg|png|bmp)$/i.test(name); }; imagePlugin['handle'] = function imagePlugin_handle(byteArray, name, onload, onerror) { var b = null; if (Browser.hasBlobConstructor) { try { b = new Blob([byteArray], { type: Browser.getMimetype(name) }); if (b.size !== byteArray.length) { // Safari bug #118630 // Safari's Blob can only take an ArrayBuffer b = new Blob([(new Uint8Array(byteArray)).buffer], { type: Browser.getMimetype(name) }); } } catch(e) { Runtime.warnOnce('Blob constructor present but fails: ' + e + '; falling back to blob builder'); } } if (!b) { var bb = new Browser.BlobBuilder(); bb.append((new Uint8Array(byteArray)).buffer); // we need to pass a buffer, and must copy the array to get the right data range b = bb.getBlob(); } var url = Browser.URLObject.createObjectURL(b); var img = new Image(); img.onload = function img_onload() { assert(img.complete, 'Image ' + name + ' could not be decoded'); var canvas = document.createElement('canvas'); canvas.width = img.width; canvas.height = img.height; var ctx = canvas.getContext('2d'); ctx.drawImage(img, 0, 0); Module["preloadedImages"][name] = canvas; Browser.URLObject.revokeObjectURL(url); if (onload) onload(byteArray); }; img.onerror = function img_onerror(event) { console.log('Image ' + url + ' could not be decoded'); if (onerror) onerror(); }; img.src = url; }; Module['preloadPlugins'].push(imagePlugin); var audioPlugin = {}; audioPlugin['canHandle'] = function audioPlugin_canHandle(name) { return !Module.noAudioDecoding && name.substr(-4) in { '.ogg': 1, '.wav': 1, '.mp3': 1 }; }; audioPlugin['handle'] = function audioPlugin_handle(byteArray, name, onload, onerror) { var done = false; function finish(audio) { if (done) return; done = true; Module["preloadedAudios"][name] = audio; if (onload) onload(byteArray); } function fail() { if (done) return; done = true; Module["preloadedAudios"][name] = new Audio(); // empty shim if (onerror) onerror(); } if (Browser.hasBlobConstructor) { try { var b = new Blob([byteArray], { type: Browser.getMimetype(name) }); } catch(e) { return fail(); } var url = Browser.URLObject.createObjectURL(b); // XXX we never revoke this! var audio = new Audio(); audio.addEventListener('canplaythrough', function() { finish(audio) }, false); // use addEventListener due to chromium bug 124926 audio.onerror = function audio_onerror(event) { if (done) return; console.log('warning: browser could not fully decode audio ' + name + ', trying slower base64 approach'); function encode64(data) { var BASE = 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/'; var PAD = '='; var ret = ''; var leftchar = 0; var leftbits = 0; for (var i = 0; i < data.length; i++) { leftchar = (leftchar << 8) | data[i]; leftbits += 8; while (leftbits >= 6) { var curr = (leftchar >> (leftbits-6)) & 0x3f; leftbits -= 6; ret += BASE[curr]; } } if (leftbits == 2) { ret += BASE[(leftchar&3) << 4]; ret += PAD + PAD; } else if (leftbits == 4) { ret += BASE[(leftchar&0xf) << 2]; ret += PAD; } return ret; } audio.src = 'data:audio/x-' + name.substr(-3) + ';base64,' + encode64(byteArray); finish(audio); // we don't wait for confirmation this worked - but it's worth trying }; audio.src = url; // workaround for chrome bug 124926 - we do not always get oncanplaythrough or onerror Browser.safeSetTimeout(function() { finish(audio); // try to use it even though it is not necessarily ready to play }, 10000); } else { return fail(); } }; Module['preloadPlugins'].push(audioPlugin); // Canvas event setup var canvas = Module['canvas']; // forced aspect ratio can be enabled by defining 'forcedAspectRatio' on Module // Module['forcedAspectRatio'] = 4 / 3; canvas.requestPointerLock = canvas['requestPointerLock'] || canvas['mozRequestPointerLock'] || canvas['webkitRequestPointerLock'] || canvas['msRequestPointerLock'] || function(){}; canvas.exitPointerLock = document['exitPointerLock'] || document['mozExitPointerLock'] || document['webkitExitPointerLock'] || document['msExitPointerLock'] || function(){}; // no-op if function does not exist canvas.exitPointerLock = canvas.exitPointerLock.bind(document); function pointerLockChange() { Browser.pointerLock = document['pointerLockElement'] === canvas || document['mozPointerLockElement'] === canvas || document['webkitPointerLockElement'] === canvas || document['msPointerLockElement'] === canvas; } document.addEventListener('pointerlockchange', pointerLockChange, false); document.addEventListener('mozpointerlockchange', pointerLockChange, false); document.addEventListener('webkitpointerlockchange', pointerLockChange, false); document.addEventListener('mspointerlockchange', pointerLockChange, false); if (Module['elementPointerLock']) { canvas.addEventListener("click", function(ev) { if (!Browser.pointerLock && canvas.requestPointerLock) { canvas.requestPointerLock(); ev.preventDefault(); } }, false); } },createContext:function (canvas, useWebGL, setInModule, webGLContextAttributes) { var ctx; var errorInfo = '?'; function onContextCreationError(event) { errorInfo = event.statusMessage || errorInfo; } try { if (useWebGL) { var contextAttributes = { antialias: false, alpha: false }; if (webGLContextAttributes) { for (var attribute in webGLContextAttributes) { contextAttributes[attribute] = webGLContextAttributes[attribute]; } } canvas.addEventListener('webglcontextcreationerror', onContextCreationError, false); try { ['experimental-webgl', 'webgl'].some(function(webglId) { return ctx = canvas.getContext(webglId, contextAttributes); }); } finally { canvas.removeEventListener('webglcontextcreationerror', onContextCreationError, false); } } else { ctx = canvas.getContext('2d'); } if (!ctx) throw ':('; } catch (e) { Module.print('Could not create canvas: ' + [errorInfo, e]); return null; } if (useWebGL) { // Set the background of the WebGL canvas to black canvas.style.backgroundColor = "black"; // Warn on context loss canvas.addEventListener('webglcontextlost', function(event) { alert('WebGL context lost. You will need to reload the page.'); }, false); } if (setInModule) { GLctx = Module.ctx = ctx; Module.useWebGL = useWebGL; Browser.moduleContextCreatedCallbacks.forEach(function(callback) { callback() }); Browser.init(); } return ctx; },destroyContext:function (canvas, useWebGL, setInModule) {},fullScreenHandlersInstalled:false,lockPointer:undefined,resizeCanvas:undefined,requestFullScreen:function (lockPointer, resizeCanvas) { Browser.lockPointer = lockPointer; Browser.resizeCanvas = resizeCanvas; if (typeof Browser.lockPointer === 'undefined') Browser.lockPointer = true; if (typeof Browser.resizeCanvas === 'undefined') Browser.resizeCanvas = false; var canvas = Module['canvas']; function fullScreenChange() { Browser.isFullScreen = false; var canvasContainer = canvas.parentNode; if ((document['webkitFullScreenElement'] || document['webkitFullscreenElement'] || document['mozFullScreenElement'] || document['mozFullscreenElement'] || document['fullScreenElement'] || document['fullscreenElement'] || document['msFullScreenElement'] || document['msFullscreenElement'] || document['webkitCurrentFullScreenElement']) === canvasContainer) { canvas.cancelFullScreen = document['cancelFullScreen'] || document['mozCancelFullScreen'] || document['webkitCancelFullScreen'] || document['msExitFullscreen'] || document['exitFullscreen'] || function() {}; canvas.cancelFullScreen = canvas.cancelFullScreen.bind(document); if (Browser.lockPointer) canvas.requestPointerLock(); Browser.isFullScreen = true; if (Browser.resizeCanvas) Browser.setFullScreenCanvasSize(); } else { // remove the full screen specific parent of the canvas again to restore the HTML structure from before going full screen canvasContainer.parentNode.insertBefore(canvas, canvasContainer); canvasContainer.parentNode.removeChild(canvasContainer); if (Browser.resizeCanvas) Browser.setWindowedCanvasSize(); } if (Module['onFullScreen']) Module['onFullScreen'](Browser.isFullScreen); Browser.updateCanvasDimensions(canvas); } if (!Browser.fullScreenHandlersInstalled) { Browser.fullScreenHandlersInstalled = true; document.addEventListener('fullscreenchange', fullScreenChange, false); document.addEventListener('mozfullscreenchange', fullScreenChange, false); document.addEventListener('webkitfullscreenchange', fullScreenChange, false); document.addEventListener('MSFullscreenChange', fullScreenChange, false); } // create a new parent to ensure the canvas has no siblings. this allows browsers to optimize full screen performance when its parent is the full screen root var canvasContainer = document.createElement("div"); canvas.parentNode.insertBefore(canvasContainer, canvas); canvasContainer.appendChild(canvas); // use parent of canvas as full screen root to allow aspect ratio correction (Firefox stretches the root to screen size) canvasContainer.requestFullScreen = canvasContainer['requestFullScreen'] || canvasContainer['mozRequestFullScreen'] || canvasContainer['msRequestFullscreen'] || (canvasContainer['webkitRequestFullScreen'] ? function() { canvasContainer['webkitRequestFullScreen'](Element['ALLOW_KEYBOARD_INPUT']) } : null); canvasContainer.requestFullScreen(); },requestAnimationFrame:function requestAnimationFrame(func) { if (typeof window === 'undefined') { // Provide fallback to setTimeout if window is undefined (e.g. in Node.js) setTimeout(func, 1000/60); } else { if (!window.requestAnimationFrame) { window.requestAnimationFrame = window['requestAnimationFrame'] || window['mozRequestAnimationFrame'] || window['webkitRequestAnimationFrame'] || window['msRequestAnimationFrame'] || window['oRequestAnimationFrame'] || window['setTimeout']; } window.requestAnimationFrame(func); } },safeCallback:function (func) { return function() { if (!ABORT) return func.apply(null, arguments); }; },safeRequestAnimationFrame:function (func) { return Browser.requestAnimationFrame(function() { if (!ABORT) func(); }); },safeSetTimeout:function (func, timeout) { return setTimeout(function() { if (!ABORT) func(); }, timeout); },safeSetInterval:function (func, timeout) { return setInterval(function() { if (!ABORT) func(); }, timeout); },getMimetype:function (name) { return { 'jpg': 'image/jpeg', 'jpeg': 'image/jpeg', 'png': 'image/png', 'bmp': 'image/bmp', 'ogg': 'audio/ogg', 'wav': 'audio/wav', 'mp3': 'audio/mpeg' }[name.substr(name.lastIndexOf('.')+1)]; },getUserMedia:function (func) { if(!window.getUserMedia) { window.getUserMedia = navigator['getUserMedia'] || navigator['mozGetUserMedia']; } window.getUserMedia(func); },getMovementX:function (event) { return event['movementX'] || event['mozMovementX'] || event['webkitMovementX'] || 0; },getMovementY:function (event) { return event['movementY'] || event['mozMovementY'] || event['webkitMovementY'] || 0; },getMouseWheelDelta:function (event) { return Math.max(-1, Math.min(1, event.type === 'DOMMouseScroll' ? event.detail : -event.wheelDelta)); },mouseX:0,mouseY:0,mouseMovementX:0,mouseMovementY:0,calculateMouseEvent:function (event) { // event should be mousemove, mousedown or mouseup if (Browser.pointerLock) { // When the pointer is locked, calculate the coordinates // based on the movement of the mouse. // Workaround for Firefox bug 764498 if (event.type != 'mousemove' && ('mozMovementX' in event)) { Browser.mouseMovementX = Browser.mouseMovementY = 0; } else { Browser.mouseMovementX = Browser.getMovementX(event); Browser.mouseMovementY = Browser.getMovementY(event); } // check if SDL is available if (typeof SDL != "undefined") { Browser.mouseX = SDL.mouseX + Browser.mouseMovementX; Browser.mouseY = SDL.mouseY + Browser.mouseMovementY; } else { // just add the mouse delta to the current absolut mouse position // FIXME: ideally this should be clamped against the canvas size and zero Browser.mouseX += Browser.mouseMovementX; Browser.mouseY += Browser.mouseMovementY; } } else { // Otherwise, calculate the movement based on the changes // in the coordinates. var rect = Module["canvas"].getBoundingClientRect(); var x, y; // Neither .scrollX or .pageXOffset are defined in a spec, but // we prefer .scrollX because it is currently in a spec draft. // (see: http://www.w3.org/TR/2013/WD-cssom-view-20131217/) var scrollX = ((typeof window.scrollX !== 'undefined') ? window.scrollX : window.pageXOffset); var scrollY = ((typeof window.scrollY !== 'undefined') ? window.scrollY : window.pageYOffset); if (event.type == 'touchstart' || event.type == 'touchend' || event.type == 'touchmove') { var t = event.touches.item(0); if (t) { x = t.pageX - (scrollX + rect.left); y = t.pageY - (scrollY + rect.top); } else { return; } } else { x = event.pageX - (scrollX + rect.left); y = event.pageY - (scrollY + rect.top); } // the canvas might be CSS-scaled compared to its backbuffer; // SDL-using content will want mouse coordinates in terms // of backbuffer units. var cw = Module["canvas"].width; var ch = Module["canvas"].height; x = x * (cw / rect.width); y = y * (ch / rect.height); Browser.mouseMovementX = x - Browser.mouseX; Browser.mouseMovementY = y - Browser.mouseY; Browser.mouseX = x; Browser.mouseY = y; } },xhrLoad:function (url, onload, onerror) { var xhr = new XMLHttpRequest(); xhr.open('GET', url, true); xhr.responseType = 'arraybuffer'; xhr.onload = function xhr_onload() { if (xhr.status == 200 || (xhr.status == 0 && xhr.response)) { // file URLs can return 0 onload(xhr.response); } else { onerror(); } }; xhr.onerror = onerror; xhr.send(null); },asyncLoad:function (url, onload, onerror, noRunDep) { Browser.xhrLoad(url, function(arrayBuffer) { assert(arrayBuffer, 'Loading data file "' + url + '" failed (no arrayBuffer).'); onload(new Uint8Array(arrayBuffer)); if (!noRunDep) removeRunDependency('al ' + url); }, function(event) { if (onerror) { onerror(); } else { throw 'Loading data file "' + url + '" failed.'; } }); if (!noRunDep) addRunDependency('al ' + url); },resizeListeners:[],updateResizeListeners:function () { var canvas = Module['canvas']; Browser.resizeListeners.forEach(function(listener) { listener(canvas.width, canvas.height); }); },setCanvasSize:function (width, height, noUpdates) { var canvas = Module['canvas']; Browser.updateCanvasDimensions(canvas, width, height); if (!noUpdates) Browser.updateResizeListeners(); },windowedWidth:0,windowedHeight:0,setFullScreenCanvasSize:function () { // check if SDL is available if (typeof SDL != "undefined") { var flags = HEAPU32[((SDL.screen+Runtime.QUANTUM_SIZE*0)>>2)]; flags = flags | 0x00800000; // set SDL_FULLSCREEN flag HEAP32[((SDL.screen+Runtime.QUANTUM_SIZE*0)>>2)]=flags } Browser.updateResizeListeners(); },setWindowedCanvasSize:function () { // check if SDL is available if (typeof SDL != "undefined") { var flags = HEAPU32[((SDL.screen+Runtime.QUANTUM_SIZE*0)>>2)]; flags = flags & ~0x00800000; // clear SDL_FULLSCREEN flag HEAP32[((SDL.screen+Runtime.QUANTUM_SIZE*0)>>2)]=flags } Browser.updateResizeListeners(); },updateCanvasDimensions:function (canvas, wNative, hNative) { if (wNative && hNative) { canvas.widthNative = wNative; canvas.heightNative = hNative; } else { wNative = canvas.widthNative; hNative = canvas.heightNative; } var w = wNative; var h = hNative; if (Module['forcedAspectRatio'] && Module['forcedAspectRatio'] > 0) { if (w/h < Module['forcedAspectRatio']) { w = Math.round(h * Module['forcedAspectRatio']); } else { h = Math.round(w / Module['forcedAspectRatio']); } } if (((document['webkitFullScreenElement'] || document['webkitFullscreenElement'] || document['mozFullScreenElement'] || document['mozFullscreenElement'] || document['fullScreenElement'] || document['fullscreenElement'] || document['msFullScreenElement'] || document['msFullscreenElement'] || document['webkitCurrentFullScreenElement']) === canvas.parentNode) && (typeof screen != 'undefined')) { var factor = Math.min(screen.width / w, screen.height / h); w = Math.round(w * factor); h = Math.round(h * factor); } if (Browser.resizeCanvas) { if (canvas.width != w) canvas.width = w; if (canvas.height != h) canvas.height = h; if (typeof canvas.style != 'undefined') { canvas.style.removeProperty( "width"); canvas.style.removeProperty("height"); } } else { if (canvas.width != wNative) canvas.width = wNative; if (canvas.height != hNative) canvas.height = hNative; if (typeof canvas.style != 'undefined') { if (w != wNative || h != hNative) { canvas.style.setProperty( "width", w + "px", "important"); canvas.style.setProperty("height", h + "px", "important"); } else { canvas.style.removeProperty( "width"); canvas.style.removeProperty("height"); } } } }}; function _time(ptr) { var ret = Math.floor(Date.now()/1000); if (ptr) { HEAP32[((ptr)>>2)]=ret; } return ret; } function _emscripten_memcpy_big(dest, src, num) { HEAPU8.set(HEAPU8.subarray(src, src+num), dest); return dest; } Module["_memcpy"] = _memcpy; FS.staticInit();__ATINIT__.unshift({ func: function() { if (!Module["noFSInit"] && !FS.init.initialized) FS.init() } });__ATMAIN__.push({ func: function() { FS.ignorePermissions = false } });__ATEXIT__.push({ func: function() { FS.quit() } });Module["FS_createFolder"] = FS.createFolder;Module["FS_createPath"] = FS.createPath;Module["FS_createDataFile"] = FS.createDataFile;Module["FS_createPreloadedFile"] = FS.createPreloadedFile;Module["FS_createLazyFile"] = FS.createLazyFile;Module["FS_createLink"] = FS.createLink;Module["FS_createDevice"] = FS.createDevice; ___errno_state = Runtime.staticAlloc(4); HEAP32[((___errno_state)>>2)]=0; __ATINIT__.unshift({ func: function() { TTY.init() } });__ATEXIT__.push({ func: function() { TTY.shutdown() } });TTY.utf8 = new Runtime.UTF8Processor(); if (ENVIRONMENT_IS_NODE) { var fs = require("fs"); NODEFS.staticInit(); } __ATINIT__.push({ func: function() { SOCKFS.root = FS.mount(SOCKFS, {}, null); } }); _fputc.ret = allocate([0], "i8", ALLOC_STATIC); Module["requestFullScreen"] = function Module_requestFullScreen(lockPointer, resizeCanvas) { Browser.requestFullScreen(lockPointer, resizeCanvas) }; Module["requestAnimationFrame"] = function Module_requestAnimationFrame(func) { Browser.requestAnimationFrame(func) }; Module["setCanvasSize"] = function Module_setCanvasSize(width, height, noUpdates) { Browser.setCanvasSize(width, height, noUpdates) }; Module["pauseMainLoop"] = function Module_pauseMainLoop() { Browser.mainLoop.pause() }; Module["resumeMainLoop"] = function Module_resumeMainLoop() { Browser.mainLoop.resume() }; Module["getUserMedia"] = function Module_getUserMedia() { Browser.getUserMedia() } STACK_BASE = STACKTOP = Runtime.alignMemory(STATICTOP); staticSealed = true; // seal the static portion of memory STACK_MAX = STACK_BASE + 5242880; DYNAMIC_BASE = DYNAMICTOP = Runtime.alignMemory(STACK_MAX); assert(DYNAMIC_BASE < TOTAL_MEMORY, "TOTAL_MEMORY not big enough for stack"); var Math_min = Math.min; function asmPrintInt(x, y) { Module.print('int ' + x + ',' + y);// + ' ' + new Error().stack); } function asmPrintFloat(x, y) { Module.print('float ' + x + ',' + y);// + ' ' + new Error().stack); } // EMSCRIPTEN_START_ASM var ModuleFunc; var asm = (ModuleFunc = function(global, env, buffer) { 'use asm'; var HEAP8 = new global.Int8Array(buffer); var HEAP16 = new global.Int16Array(buffer); var HEAP32 = new global.Int32Array(buffer); var HEAPU8 = new global.Uint8Array(buffer); var HEAPU16 = new global.Uint16Array(buffer); var HEAPU32 = new global.Uint32Array(buffer); var HEAPF32 = new global.Float32Array(buffer); var HEAPF64 = new global.Float64Array(buffer); var STACKTOP=env.STACKTOP|0; var STACK_MAX=env.STACK_MAX|0; var tempDoublePtr=env.tempDoublePtr|0; var ABORT=env.ABORT|0; var __THREW__ = 0; var threwValue = 0; var setjmpId = 0; var undef = 0; var nan = +env.NaN, inf = +env.Infinity; var tempInt = 0, tempBigInt = 0, tempBigIntP = 0, tempBigIntS = 0, tempBigIntR = 0.0, tempBigIntI = 0, tempBigIntD = 0, tempValue = 0, tempDouble = 0.0; var tempRet0 = 0; var tempRet1 = 0; var tempRet2 = 0; var tempRet3 = 0; var tempRet4 = 0; var tempRet5 = 0; var tempRet6 = 0; var tempRet7 = 0; var tempRet8 = 0; var tempRet9 = 0; var Math_floor=global.Math.floor; var Math_abs=global.Math.abs; var Math_sqrt=global.Math.sqrt; var Math_pow=global.Math.pow; var Math_cos=global.Math.cos; var Math_sin=global.Math.sin; var Math_tan=global.Math.tan; var Math_acos=global.Math.acos; var Math_asin=global.Math.asin; var Math_atan=global.Math.atan; var Math_atan2=global.Math.atan2; var Math_exp=global.Math.exp; var Math_log=global.Math.log; var Math_ceil=global.Math.ceil; var Math_imul=global.Math.imul; var abort=env.abort; var assert=env.assert; var asmPrintInt=env.asmPrintInt; var asmPrintFloat=env.asmPrintFloat; var Math_min=env.min; var _fflush=env._fflush; var _emscripten_memcpy_big=env._emscripten_memcpy_big; var _putchar=env._putchar; var _fputc=env._fputc; var _send=env._send; var _pwrite=env._pwrite; var _abort=env._abort; var __reallyNegative=env.__reallyNegative; var _fwrite=env._fwrite; var _sbrk=env._sbrk; var _mkport=env._mkport; var _fprintf=env._fprintf; var ___setErrNo=env.___setErrNo; var __formatString=env.__formatString; var _fileno=env._fileno; var _printf=env._printf; var _time=env._time; var _sysconf=env._sysconf; var _write=env._write; var ___errno_location=env.___errno_location; var tempFloat = 0.0; // EMSCRIPTEN_START_FUNCS function _malloc(i12) { i12 = i12 | 0; var i1 = 0, i2 = 0, i3 = 0, i4 = 0, i5 = 0, i6 = 0, i7 = 0, i8 = 0, i9 = 0, i10 = 0, i11 = 0, i13 = 0, i14 = 0, i15 = 0, i16 = 0, i17 = 0, i18 = 0, i19 = 0, i20 = 0, i21 = 0, i22 = 0, i23 = 0, i24 = 0, i25 = 0, i26 = 0, i27 = 0, i28 = 0, i29 = 0, i30 = 0, i31 = 0, i32 = 0; i1 = STACKTOP; do { if (i12 >>> 0 < 245) { if (i12 >>> 0 < 11) { i12 = 16; } else { i12 = i12 + 11 & -8; } i20 = i12 >>> 3; i18 = HEAP32[14] | 0; i21 = i18 >>> i20; if ((i21 & 3 | 0) != 0) { i6 = (i21 & 1 ^ 1) + i20 | 0; i5 = i6 << 1; i3 = 96 + (i5 << 2) | 0; i5 = 96 + (i5 + 2 << 2) | 0; i7 = HEAP32[i5 >> 2] | 0; i2 = i7 + 8 | 0; i4 = HEAP32[i2 >> 2] | 0; do { if ((i3 | 0) != (i4 | 0)) { if (i4 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i8 = i4 + 12 | 0; if ((HEAP32[i8 >> 2] | 0) == (i7 | 0)) { HEAP32[i8 >> 2] = i3; HEAP32[i5 >> 2] = i4; break; } else { _abort(); } } else { HEAP32[14] = i18 & ~(1 << i6); } } while (0); i32 = i6 << 3; HEAP32[i7 + 4 >> 2] = i32 | 3; i32 = i7 + (i32 | 4) | 0; HEAP32[i32 >> 2] = HEAP32[i32 >> 2] | 1; i32 = i2; STACKTOP = i1; return i32 | 0; } if (i12 >>> 0 > (HEAP32[64 >> 2] | 0) >>> 0) { if ((i21 | 0) != 0) { i7 = 2 << i20; i7 = i21 << i20 & (i7 | 0 - i7); i7 = (i7 & 0 - i7) + -1 | 0; i2 = i7 >>> 12 & 16; i7 = i7 >>> i2; i6 = i7 >>> 5 & 8; i7 = i7 >>> i6; i5 = i7 >>> 2 & 4; i7 = i7 >>> i5; i4 = i7 >>> 1 & 2; i7 = i7 >>> i4; i3 = i7 >>> 1 & 1; i3 = (i6 | i2 | i5 | i4 | i3) + (i7 >>> i3) | 0; i7 = i3 << 1; i4 = 96 + (i7 << 2) | 0; i7 = 96 + (i7 + 2 << 2) | 0; i5 = HEAP32[i7 >> 2] | 0; i2 = i5 + 8 | 0; i6 = HEAP32[i2 >> 2] | 0; do { if ((i4 | 0) != (i6 | 0)) { if (i6 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i8 = i6 + 12 | 0; if ((HEAP32[i8 >> 2] | 0) == (i5 | 0)) { HEAP32[i8 >> 2] = i4; HEAP32[i7 >> 2] = i6; break; } else { _abort(); } } else { HEAP32[14] = i18 & ~(1 << i3); } } while (0); i6 = i3 << 3; i4 = i6 - i12 | 0; HEAP32[i5 + 4 >> 2] = i12 | 3; i3 = i5 + i12 | 0; HEAP32[i5 + (i12 | 4) >> 2] = i4 | 1; HEAP32[i5 + i6 >> 2] = i4; i6 = HEAP32[64 >> 2] | 0; if ((i6 | 0) != 0) { i5 = HEAP32[76 >> 2] | 0; i8 = i6 >>> 3; i9 = i8 << 1; i6 = 96 + (i9 << 2) | 0; i7 = HEAP32[14] | 0; i8 = 1 << i8; if ((i7 & i8 | 0) != 0) { i7 = 96 + (i9 + 2 << 2) | 0; i8 = HEAP32[i7 >> 2] | 0; if (i8 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { i28 = i7; i27 = i8; } } else { HEAP32[14] = i7 | i8; i28 = 96 + (i9 + 2 << 2) | 0; i27 = i6; } HEAP32[i28 >> 2] = i5; HEAP32[i27 + 12 >> 2] = i5; HEAP32[i5 + 8 >> 2] = i27; HEAP32[i5 + 12 >> 2] = i6; } HEAP32[64 >> 2] = i4; HEAP32[76 >> 2] = i3; i32 = i2; STACKTOP = i1; return i32 | 0; } i18 = HEAP32[60 >> 2] | 0; if ((i18 | 0) != 0) { i2 = (i18 & 0 - i18) + -1 | 0; i31 = i2 >>> 12 & 16; i2 = i2 >>> i31; i30 = i2 >>> 5 & 8; i2 = i2 >>> i30; i32 = i2 >>> 2 & 4; i2 = i2 >>> i32; i6 = i2 >>> 1 & 2; i2 = i2 >>> i6; i3 = i2 >>> 1 & 1; i3 = HEAP32[360 + ((i30 | i31 | i32 | i6 | i3) + (i2 >>> i3) << 2) >> 2] | 0; i2 = (HEAP32[i3 + 4 >> 2] & -8) - i12 | 0; i6 = i3; while (1) { i5 = HEAP32[i6 + 16 >> 2] | 0; if ((i5 | 0) == 0) { i5 = HEAP32[i6 + 20 >> 2] | 0; if ((i5 | 0) == 0) { break; } } i6 = (HEAP32[i5 + 4 >> 2] & -8) - i12 | 0; i4 = i6 >>> 0 < i2 >>> 0; i2 = i4 ? i6 : i2; i6 = i5; i3 = i4 ? i5 : i3; } i6 = HEAP32[72 >> 2] | 0; if (i3 >>> 0 < i6 >>> 0) { _abort(); } i4 = i3 + i12 | 0; if (!(i3 >>> 0 < i4 >>> 0)) { _abort(); } i5 = HEAP32[i3 + 24 >> 2] | 0; i7 = HEAP32[i3 + 12 >> 2] | 0; do { if ((i7 | 0) == (i3 | 0)) { i8 = i3 + 20 | 0; i7 = HEAP32[i8 >> 2] | 0; if ((i7 | 0) == 0) { i8 = i3 + 16 | 0; i7 = HEAP32[i8 >> 2] | 0; if ((i7 | 0) == 0) { i26 = 0; break; } } while (1) { i10 = i7 + 20 | 0; i9 = HEAP32[i10 >> 2] | 0; if ((i9 | 0) != 0) { i7 = i9; i8 = i10; continue; } i10 = i7 + 16 | 0; i9 = HEAP32[i10 >> 2] | 0; if ((i9 | 0) == 0) { break; } else { i7 = i9; i8 = i10; } } if (i8 >>> 0 < i6 >>> 0) { _abort(); } else { HEAP32[i8 >> 2] = 0; i26 = i7; break; } } else { i8 = HEAP32[i3 + 8 >> 2] | 0; if (i8 >>> 0 < i6 >>> 0) { _abort(); } i6 = i8 + 12 | 0; if ((HEAP32[i6 >> 2] | 0) != (i3 | 0)) { _abort(); } i9 = i7 + 8 | 0; if ((HEAP32[i9 >> 2] | 0) == (i3 | 0)) { HEAP32[i6 >> 2] = i7; HEAP32[i9 >> 2] = i8; i26 = i7; break; } else { _abort(); } } } while (0); do { if ((i5 | 0) != 0) { i7 = HEAP32[i3 + 28 >> 2] | 0; i6 = 360 + (i7 << 2) | 0; if ((i3 | 0) == (HEAP32[i6 >> 2] | 0)) { HEAP32[i6 >> 2] = i26; if ((i26 | 0) == 0) { HEAP32[60 >> 2] = HEAP32[60 >> 2] & ~(1 << i7); break; } } else { if (i5 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i6 = i5 + 16 | 0; if ((HEAP32[i6 >> 2] | 0) == (i3 | 0)) { HEAP32[i6 >> 2] = i26; } else { HEAP32[i5 + 20 >> 2] = i26; } if ((i26 | 0) == 0) { break; } } if (i26 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } HEAP32[i26 + 24 >> 2] = i5; i5 = HEAP32[i3 + 16 >> 2] | 0; do { if ((i5 | 0) != 0) { if (i5 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i26 + 16 >> 2] = i5; HEAP32[i5 + 24 >> 2] = i26; break; } } } while (0); i5 = HEAP32[i3 + 20 >> 2] | 0; if ((i5 | 0) != 0) { if (i5 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i26 + 20 >> 2] = i5; HEAP32[i5 + 24 >> 2] = i26; break; } } } } while (0); if (i2 >>> 0 < 16) { i32 = i2 + i12 | 0; HEAP32[i3 + 4 >> 2] = i32 | 3; i32 = i3 + (i32 + 4) | 0; HEAP32[i32 >> 2] = HEAP32[i32 >> 2] | 1; } else { HEAP32[i3 + 4 >> 2] = i12 | 3; HEAP32[i3 + (i12 | 4) >> 2] = i2 | 1; HEAP32[i3 + (i2 + i12) >> 2] = i2; i6 = HEAP32[64 >> 2] | 0; if ((i6 | 0) != 0) { i5 = HEAP32[76 >> 2] | 0; i8 = i6 >>> 3; i9 = i8 << 1; i6 = 96 + (i9 << 2) | 0; i7 = HEAP32[14] | 0; i8 = 1 << i8; if ((i7 & i8 | 0) != 0) { i7 = 96 + (i9 + 2 << 2) | 0; i8 = HEAP32[i7 >> 2] | 0; if (i8 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { i25 = i7; i24 = i8; } } else { HEAP32[14] = i7 | i8; i25 = 96 + (i9 + 2 << 2) | 0; i24 = i6; } HEAP32[i25 >> 2] = i5; HEAP32[i24 + 12 >> 2] = i5; HEAP32[i5 + 8 >> 2] = i24; HEAP32[i5 + 12 >> 2] = i6; } HEAP32[64 >> 2] = i2; HEAP32[76 >> 2] = i4; } i32 = i3 + 8 | 0; STACKTOP = i1; return i32 | 0; } } } else { if (!(i12 >>> 0 > 4294967231)) { i24 = i12 + 11 | 0; i12 = i24 & -8; i26 = HEAP32[60 >> 2] | 0; if ((i26 | 0) != 0) { i25 = 0 - i12 | 0; i24 = i24 >>> 8; if ((i24 | 0) != 0) { if (i12 >>> 0 > 16777215) { i27 = 31; } else { i31 = (i24 + 1048320 | 0) >>> 16 & 8; i32 = i24 << i31; i30 = (i32 + 520192 | 0) >>> 16 & 4; i32 = i32 << i30; i27 = (i32 + 245760 | 0) >>> 16 & 2; i27 = 14 - (i30 | i31 | i27) + (i32 << i27 >>> 15) | 0; i27 = i12 >>> (i27 + 7 | 0) & 1 | i27 << 1; } } else { i27 = 0; } i30 = HEAP32[360 + (i27 << 2) >> 2] | 0; L126 : do { if ((i30 | 0) == 0) { i29 = 0; i24 = 0; } else { if ((i27 | 0) == 31) { i24 = 0; } else { i24 = 25 - (i27 >>> 1) | 0; } i29 = 0; i28 = i12 << i24; i24 = 0; while (1) { i32 = HEAP32[i30 + 4 >> 2] & -8; i31 = i32 - i12 | 0; if (i31 >>> 0 < i25 >>> 0) { if ((i32 | 0) == (i12 | 0)) { i25 = i31; i29 = i30; i24 = i30; break L126; } else { i25 = i31; i24 = i30; } } i31 = HEAP32[i30 + 20 >> 2] | 0; i30 = HEAP32[i30 + (i28 >>> 31 << 2) + 16 >> 2] | 0; i29 = (i31 | 0) == 0 | (i31 | 0) == (i30 | 0) ? i29 : i31; if ((i30 | 0) == 0) { break; } else { i28 = i28 << 1; } } } } while (0); if ((i29 | 0) == 0 & (i24 | 0) == 0) { i32 = 2 << i27; i26 = i26 & (i32 | 0 - i32); if ((i26 | 0) == 0) { break; } i32 = (i26 & 0 - i26) + -1 | 0; i28 = i32 >>> 12 & 16; i32 = i32 >>> i28; i27 = i32 >>> 5 & 8; i32 = i32 >>> i27; i30 = i32 >>> 2 & 4; i32 = i32 >>> i30; i31 = i32 >>> 1 & 2; i32 = i32 >>> i31; i29 = i32 >>> 1 & 1; i29 = HEAP32[360 + ((i27 | i28 | i30 | i31 | i29) + (i32 >>> i29) << 2) >> 2] | 0; } if ((i29 | 0) != 0) { while (1) { i27 = (HEAP32[i29 + 4 >> 2] & -8) - i12 | 0; i26 = i27 >>> 0 < i25 >>> 0; i25 = i26 ? i27 : i25; i24 = i26 ? i29 : i24; i26 = HEAP32[i29 + 16 >> 2] | 0; if ((i26 | 0) != 0) { i29 = i26; continue; } i29 = HEAP32[i29 + 20 >> 2] | 0; if ((i29 | 0) == 0) { break; } } } if ((i24 | 0) != 0 ? i25 >>> 0 < ((HEAP32[64 >> 2] | 0) - i12 | 0) >>> 0 : 0) { i4 = HEAP32[72 >> 2] | 0; if (i24 >>> 0 < i4 >>> 0) { _abort(); } i2 = i24 + i12 | 0; if (!(i24 >>> 0 < i2 >>> 0)) { _abort(); } i3 = HEAP32[i24 + 24 >> 2] | 0; i6 = HEAP32[i24 + 12 >> 2] | 0; do { if ((i6 | 0) == (i24 | 0)) { i6 = i24 + 20 | 0; i5 = HEAP32[i6 >> 2] | 0; if ((i5 | 0) == 0) { i6 = i24 + 16 | 0; i5 = HEAP32[i6 >> 2] | 0; if ((i5 | 0) == 0) { i22 = 0; break; } } while (1) { i8 = i5 + 20 | 0; i7 = HEAP32[i8 >> 2] | 0; if ((i7 | 0) != 0) { i5 = i7; i6 = i8; continue; } i7 = i5 + 16 | 0; i8 = HEAP32[i7 >> 2] | 0; if ((i8 | 0) == 0) { break; } else { i5 = i8; i6 = i7; } } if (i6 >>> 0 < i4 >>> 0) { _abort(); } else { HEAP32[i6 >> 2] = 0; i22 = i5; break; } } else { i5 = HEAP32[i24 + 8 >> 2] | 0; if (i5 >>> 0 < i4 >>> 0) { _abort(); } i7 = i5 + 12 | 0; if ((HEAP32[i7 >> 2] | 0) != (i24 | 0)) { _abort(); } i4 = i6 + 8 | 0; if ((HEAP32[i4 >> 2] | 0) == (i24 | 0)) { HEAP32[i7 >> 2] = i6; HEAP32[i4 >> 2] = i5; i22 = i6; break; } else { _abort(); } } } while (0); do { if ((i3 | 0) != 0) { i4 = HEAP32[i24 + 28 >> 2] | 0; i5 = 360 + (i4 << 2) | 0; if ((i24 | 0) == (HEAP32[i5 >> 2] | 0)) { HEAP32[i5 >> 2] = i22; if ((i22 | 0) == 0) { HEAP32[60 >> 2] = HEAP32[60 >> 2] & ~(1 << i4); break; } } else { if (i3 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i4 = i3 + 16 | 0; if ((HEAP32[i4 >> 2] | 0) == (i24 | 0)) { HEAP32[i4 >> 2] = i22; } else { HEAP32[i3 + 20 >> 2] = i22; } if ((i22 | 0) == 0) { break; } } if (i22 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } HEAP32[i22 + 24 >> 2] = i3; i3 = HEAP32[i24 + 16 >> 2] | 0; do { if ((i3 | 0) != 0) { if (i3 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i22 + 16 >> 2] = i3; HEAP32[i3 + 24 >> 2] = i22; break; } } } while (0); i3 = HEAP32[i24 + 20 >> 2] | 0; if ((i3 | 0) != 0) { if (i3 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i22 + 20 >> 2] = i3; HEAP32[i3 + 24 >> 2] = i22; break; } } } } while (0); L204 : do { if (!(i25 >>> 0 < 16)) { HEAP32[i24 + 4 >> 2] = i12 | 3; HEAP32[i24 + (i12 | 4) >> 2] = i25 | 1; HEAP32[i24 + (i25 + i12) >> 2] = i25; i4 = i25 >>> 3; if (i25 >>> 0 < 256) { i6 = i4 << 1; i3 = 96 + (i6 << 2) | 0; i5 = HEAP32[14] | 0; i4 = 1 << i4; if ((i5 & i4 | 0) != 0) { i5 = 96 + (i6 + 2 << 2) | 0; i4 = HEAP32[i5 >> 2] | 0; if (i4 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { i21 = i5; i20 = i4; } } else { HEAP32[14] = i5 | i4; i21 = 96 + (i6 + 2 << 2) | 0; i20 = i3; } HEAP32[i21 >> 2] = i2; HEAP32[i20 + 12 >> 2] = i2; HEAP32[i24 + (i12 + 8) >> 2] = i20; HEAP32[i24 + (i12 + 12) >> 2] = i3; break; } i3 = i25 >>> 8; if ((i3 | 0) != 0) { if (i25 >>> 0 > 16777215) { i3 = 31; } else { i31 = (i3 + 1048320 | 0) >>> 16 & 8; i32 = i3 << i31; i30 = (i32 + 520192 | 0) >>> 16 & 4; i32 = i32 << i30; i3 = (i32 + 245760 | 0) >>> 16 & 2; i3 = 14 - (i30 | i31 | i3) + (i32 << i3 >>> 15) | 0; i3 = i25 >>> (i3 + 7 | 0) & 1 | i3 << 1; } } else { i3 = 0; } i6 = 360 + (i3 << 2) | 0; HEAP32[i24 + (i12 + 28) >> 2] = i3; HEAP32[i24 + (i12 + 20) >> 2] = 0; HEAP32[i24 + (i12 + 16) >> 2] = 0; i4 = HEAP32[60 >> 2] | 0; i5 = 1 << i3; if ((i4 & i5 | 0) == 0) { HEAP32[60 >> 2] = i4 | i5; HEAP32[i6 >> 2] = i2; HEAP32[i24 + (i12 + 24) >> 2] = i6; HEAP32[i24 + (i12 + 12) >> 2] = i2; HEAP32[i24 + (i12 + 8) >> 2] = i2; break; } i4 = HEAP32[i6 >> 2] | 0; if ((i3 | 0) == 31) { i3 = 0; } else { i3 = 25 - (i3 >>> 1) | 0; } L225 : do { if ((HEAP32[i4 + 4 >> 2] & -8 | 0) != (i25 | 0)) { i3 = i25 << i3; while (1) { i6 = i4 + (i3 >>> 31 << 2) + 16 | 0; i5 = HEAP32[i6 >> 2] | 0; if ((i5 | 0) == 0) { break; } if ((HEAP32[i5 + 4 >> 2] & -8 | 0) == (i25 | 0)) { i18 = i5; break L225; } else { i3 = i3 << 1; i4 = i5; } } if (i6 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i6 >> 2] = i2; HEAP32[i24 + (i12 + 24) >> 2] = i4; HEAP32[i24 + (i12 + 12) >> 2] = i2; HEAP32[i24 + (i12 + 8) >> 2] = i2; break L204; } } else { i18 = i4; } } while (0); i4 = i18 + 8 | 0; i3 = HEAP32[i4 >> 2] | 0; i5 = HEAP32[72 >> 2] | 0; if (i18 >>> 0 < i5 >>> 0) { _abort(); } if (i3 >>> 0 < i5 >>> 0) { _abort(); } else { HEAP32[i3 + 12 >> 2] = i2; HEAP32[i4 >> 2] = i2; HEAP32[i24 + (i12 + 8) >> 2] = i3; HEAP32[i24 + (i12 + 12) >> 2] = i18; HEAP32[i24 + (i12 + 24) >> 2] = 0; break; } } else { i32 = i25 + i12 | 0; HEAP32[i24 + 4 >> 2] = i32 | 3; i32 = i24 + (i32 + 4) | 0; HEAP32[i32 >> 2] = HEAP32[i32 >> 2] | 1; } } while (0); i32 = i24 + 8 | 0; STACKTOP = i1; return i32 | 0; } } } else { i12 = -1; } } } while (0); i18 = HEAP32[64 >> 2] | 0; if (!(i12 >>> 0 > i18 >>> 0)) { i3 = i18 - i12 | 0; i2 = HEAP32[76 >> 2] | 0; if (i3 >>> 0 > 15) { HEAP32[76 >> 2] = i2 + i12; HEAP32[64 >> 2] = i3; HEAP32[i2 + (i12 + 4) >> 2] = i3 | 1; HEAP32[i2 + i18 >> 2] = i3; HEAP32[i2 + 4 >> 2] = i12 | 3; } else { HEAP32[64 >> 2] = 0; HEAP32[76 >> 2] = 0; HEAP32[i2 + 4 >> 2] = i18 | 3; i32 = i2 + (i18 + 4) | 0; HEAP32[i32 >> 2] = HEAP32[i32 >> 2] | 1; } i32 = i2 + 8 | 0; STACKTOP = i1; return i32 | 0; } i18 = HEAP32[68 >> 2] | 0; if (i12 >>> 0 < i18 >>> 0) { i31 = i18 - i12 | 0; HEAP32[68 >> 2] = i31; i32 = HEAP32[80 >> 2] | 0; HEAP32[80 >> 2] = i32 + i12; HEAP32[i32 + (i12 + 4) >> 2] = i31 | 1; HEAP32[i32 + 4 >> 2] = i12 | 3; i32 = i32 + 8 | 0; STACKTOP = i1; return i32 | 0; } do { if ((HEAP32[132] | 0) == 0) { i18 = _sysconf(30) | 0; if ((i18 + -1 & i18 | 0) == 0) { HEAP32[536 >> 2] = i18; HEAP32[532 >> 2] = i18; HEAP32[540 >> 2] = -1; HEAP32[544 >> 2] = -1; HEAP32[548 >> 2] = 0; HEAP32[500 >> 2] = 0; HEAP32[132] = (_time(0) | 0) & -16 ^ 1431655768; break; } else { _abort(); } } } while (0); i20 = i12 + 48 | 0; i25 = HEAP32[536 >> 2] | 0; i21 = i12 + 47 | 0; i22 = i25 + i21 | 0; i25 = 0 - i25 | 0; i18 = i22 & i25; if (!(i18 >>> 0 > i12 >>> 0)) { i32 = 0; STACKTOP = i1; return i32 | 0; } i24 = HEAP32[496 >> 2] | 0; if ((i24 | 0) != 0 ? (i31 = HEAP32[488 >> 2] | 0, i32 = i31 + i18 | 0, i32 >>> 0 <= i31 >>> 0 | i32 >>> 0 > i24 >>> 0) : 0) { i32 = 0; STACKTOP = i1; return i32 | 0; } L269 : do { if ((HEAP32[500 >> 2] & 4 | 0) == 0) { i26 = HEAP32[80 >> 2] | 0; L271 : do { if ((i26 | 0) != 0) { i24 = 504 | 0; while (1) { i27 = HEAP32[i24 >> 2] | 0; if (!(i27 >>> 0 > i26 >>> 0) ? (i23 = i24 + 4 | 0, (i27 + (HEAP32[i23 >> 2] | 0) | 0) >>> 0 > i26 >>> 0) : 0) { break; } i24 = HEAP32[i24 + 8 >> 2] | 0; if ((i24 | 0) == 0) { i13 = 182; break L271; } } if ((i24 | 0) != 0) { i25 = i22 - (HEAP32[68 >> 2] | 0) & i25; if (i25 >>> 0 < 2147483647) { i13 = _sbrk(i25 | 0) | 0; i26 = (i13 | 0) == ((HEAP32[i24 >> 2] | 0) + (HEAP32[i23 >> 2] | 0) | 0); i22 = i13; i24 = i25; i23 = i26 ? i13 : -1; i25 = i26 ? i25 : 0; i13 = 191; } else { i25 = 0; } } else { i13 = 182; } } else { i13 = 182; } } while (0); do { if ((i13 | 0) == 182) { i23 = _sbrk(0) | 0; if ((i23 | 0) != (-1 | 0)) { i24 = i23; i22 = HEAP32[532 >> 2] | 0; i25 = i22 + -1 | 0; if ((i25 & i24 | 0) == 0) { i25 = i18; } else { i25 = i18 - i24 + (i25 + i24 & 0 - i22) | 0; } i24 = HEAP32[488 >> 2] | 0; i26 = i24 + i25 | 0; if (i25 >>> 0 > i12 >>> 0 & i25 >>> 0 < 2147483647) { i22 = HEAP32[496 >> 2] | 0; if ((i22 | 0) != 0 ? i26 >>> 0 <= i24 >>> 0 | i26 >>> 0 > i22 >>> 0 : 0) { i25 = 0; break; } i22 = _sbrk(i25 | 0) | 0; i13 = (i22 | 0) == (i23 | 0); i24 = i25; i23 = i13 ? i23 : -1; i25 = i13 ? i25 : 0; i13 = 191; } else { i25 = 0; } } else { i25 = 0; } } } while (0); L291 : do { if ((i13 | 0) == 191) { i13 = 0 - i24 | 0; if ((i23 | 0) != (-1 | 0)) { i17 = i23; i14 = i25; i13 = 202; break L269; } do { if ((i22 | 0) != (-1 | 0) & i24 >>> 0 < 2147483647 & i24 >>> 0 < i20 >>> 0 ? (i19 = HEAP32[536 >> 2] | 0, i19 = i21 - i24 + i19 & 0 - i19, i19 >>> 0 < 2147483647) : 0) { if ((_sbrk(i19 | 0) | 0) == (-1 | 0)) { _sbrk(i13 | 0) | 0; break L291; } else { i24 = i19 + i24 | 0; break; } } } while (0); if ((i22 | 0) != (-1 | 0)) { i17 = i22; i14 = i24; i13 = 202; break L269; } } } while (0); HEAP32[500 >> 2] = HEAP32[500 >> 2] | 4; i13 = 199; } else { i25 = 0; i13 = 199; } } while (0); if ((((i13 | 0) == 199 ? i18 >>> 0 < 2147483647 : 0) ? (i17 = _sbrk(i18 | 0) | 0, i16 = _sbrk(0) | 0, (i16 | 0) != (-1 | 0) & (i17 | 0) != (-1 | 0) & i17 >>> 0 < i16 >>> 0) : 0) ? (i15 = i16 - i17 | 0, i14 = i15 >>> 0 > (i12 + 40 | 0) >>> 0, i14) : 0) { i14 = i14 ? i15 : i25; i13 = 202; } if ((i13 | 0) == 202) { i15 = (HEAP32[488 >> 2] | 0) + i14 | 0; HEAP32[488 >> 2] = i15; if (i15 >>> 0 > (HEAP32[492 >> 2] | 0) >>> 0) { HEAP32[492 >> 2] = i15; } i15 = HEAP32[80 >> 2] | 0; L311 : do { if ((i15 | 0) != 0) { i21 = 504 | 0; while (1) { i16 = HEAP32[i21 >> 2] | 0; i19 = i21 + 4 | 0; i20 = HEAP32[i19 >> 2] | 0; if ((i17 | 0) == (i16 + i20 | 0)) { i13 = 214; break; } i18 = HEAP32[i21 + 8 >> 2] | 0; if ((i18 | 0) == 0) { break; } else { i21 = i18; } } if (((i13 | 0) == 214 ? (HEAP32[i21 + 12 >> 2] & 8 | 0) == 0 : 0) ? i15 >>> 0 >= i16 >>> 0 & i15 >>> 0 < i17 >>> 0 : 0) { HEAP32[i19 >> 2] = i20 + i14; i2 = (HEAP32[68 >> 2] | 0) + i14 | 0; i3 = i15 + 8 | 0; if ((i3 & 7 | 0) == 0) { i3 = 0; } else { i3 = 0 - i3 & 7; } i32 = i2 - i3 | 0; HEAP32[80 >> 2] = i15 + i3; HEAP32[68 >> 2] = i32; HEAP32[i15 + (i3 + 4) >> 2] = i32 | 1; HEAP32[i15 + (i2 + 4) >> 2] = 40; HEAP32[84 >> 2] = HEAP32[544 >> 2]; break; } if (i17 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { HEAP32[72 >> 2] = i17; } i19 = i17 + i14 | 0; i16 = 504 | 0; while (1) { if ((HEAP32[i16 >> 2] | 0) == (i19 | 0)) { i13 = 224; break; } i18 = HEAP32[i16 + 8 >> 2] | 0; if ((i18 | 0) == 0) { break; } else { i16 = i18; } } if ((i13 | 0) == 224 ? (HEAP32[i16 + 12 >> 2] & 8 | 0) == 0 : 0) { HEAP32[i16 >> 2] = i17; i6 = i16 + 4 | 0; HEAP32[i6 >> 2] = (HEAP32[i6 >> 2] | 0) + i14; i6 = i17 + 8 | 0; if ((i6 & 7 | 0) == 0) { i6 = 0; } else { i6 = 0 - i6 & 7; } i7 = i17 + (i14 + 8) | 0; if ((i7 & 7 | 0) == 0) { i13 = 0; } else { i13 = 0 - i7 & 7; } i15 = i17 + (i13 + i14) | 0; i8 = i6 + i12 | 0; i7 = i17 + i8 | 0; i10 = i15 - (i17 + i6) - i12 | 0; HEAP32[i17 + (i6 + 4) >> 2] = i12 | 3; L348 : do { if ((i15 | 0) != (HEAP32[80 >> 2] | 0)) { if ((i15 | 0) == (HEAP32[76 >> 2] | 0)) { i32 = (HEAP32[64 >> 2] | 0) + i10 | 0; HEAP32[64 >> 2] = i32; HEAP32[76 >> 2] = i7; HEAP32[i17 + (i8 + 4) >> 2] = i32 | 1; HEAP32[i17 + (i32 + i8) >> 2] = i32; break; } i12 = i14 + 4 | 0; i18 = HEAP32[i17 + (i12 + i13) >> 2] | 0; if ((i18 & 3 | 0) == 1) { i11 = i18 & -8; i16 = i18 >>> 3; do { if (!(i18 >>> 0 < 256)) { i9 = HEAP32[i17 + ((i13 | 24) + i14) >> 2] | 0; i19 = HEAP32[i17 + (i14 + 12 + i13) >> 2] | 0; do { if ((i19 | 0) == (i15 | 0)) { i19 = i13 | 16; i18 = i17 + (i12 + i19) | 0; i16 = HEAP32[i18 >> 2] | 0; if ((i16 | 0) == 0) { i18 = i17 + (i19 + i14) | 0; i16 = HEAP32[i18 >> 2] | 0; if ((i16 | 0) == 0) { i5 = 0; break; } } while (1) { i20 = i16 + 20 | 0; i19 = HEAP32[i20 >> 2] | 0; if ((i19 | 0) != 0) { i16 = i19; i18 = i20; continue; } i19 = i16 + 16 | 0; i20 = HEAP32[i19 >> 2] | 0; if ((i20 | 0) == 0) { break; } else { i16 = i20; i18 = i19; } } if (i18 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i18 >> 2] = 0; i5 = i16; break; } } else { i18 = HEAP32[i17 + ((i13 | 8) + i14) >> 2] | 0; if (i18 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i16 = i18 + 12 | 0; if ((HEAP32[i16 >> 2] | 0) != (i15 | 0)) { _abort(); } i20 = i19 + 8 | 0; if ((HEAP32[i20 >> 2] | 0) == (i15 | 0)) { HEAP32[i16 >> 2] = i19; HEAP32[i20 >> 2] = i18; i5 = i19; break; } else { _abort(); } } } while (0); if ((i9 | 0) != 0) { i16 = HEAP32[i17 + (i14 + 28 + i13) >> 2] | 0; i18 = 360 + (i16 << 2) | 0; if ((i15 | 0) == (HEAP32[i18 >> 2] | 0)) { HEAP32[i18 >> 2] = i5; if ((i5 | 0) == 0) { HEAP32[60 >> 2] = HEAP32[60 >> 2] & ~(1 << i16); break; } } else { if (i9 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i16 = i9 + 16 | 0; if ((HEAP32[i16 >> 2] | 0) == (i15 | 0)) { HEAP32[i16 >> 2] = i5; } else { HEAP32[i9 + 20 >> 2] = i5; } if ((i5 | 0) == 0) { break; } } if (i5 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } HEAP32[i5 + 24 >> 2] = i9; i15 = i13 | 16; i9 = HEAP32[i17 + (i15 + i14) >> 2] | 0; do { if ((i9 | 0) != 0) { if (i9 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i5 + 16 >> 2] = i9; HEAP32[i9 + 24 >> 2] = i5; break; } } } while (0); i9 = HEAP32[i17 + (i12 + i15) >> 2] | 0; if ((i9 | 0) != 0) { if (i9 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i5 + 20 >> 2] = i9; HEAP32[i9 + 24 >> 2] = i5; break; } } } } else { i5 = HEAP32[i17 + ((i13 | 8) + i14) >> 2] | 0; i12 = HEAP32[i17 + (i14 + 12 + i13) >> 2] | 0; i18 = 96 + (i16 << 1 << 2) | 0; if ((i5 | 0) != (i18 | 0)) { if (i5 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } if ((HEAP32[i5 + 12 >> 2] | 0) != (i15 | 0)) { _abort(); } } if ((i12 | 0) == (i5 | 0)) { HEAP32[14] = HEAP32[14] & ~(1 << i16); break; } if ((i12 | 0) != (i18 | 0)) { if (i12 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i16 = i12 + 8 | 0; if ((HEAP32[i16 >> 2] | 0) == (i15 | 0)) { i9 = i16; } else { _abort(); } } else { i9 = i12 + 8 | 0; } HEAP32[i5 + 12 >> 2] = i12; HEAP32[i9 >> 2] = i5; } } while (0); i15 = i17 + ((i11 | i13) + i14) | 0; i10 = i11 + i10 | 0; } i5 = i15 + 4 | 0; HEAP32[i5 >> 2] = HEAP32[i5 >> 2] & -2; HEAP32[i17 + (i8 + 4) >> 2] = i10 | 1; HEAP32[i17 + (i10 + i8) >> 2] = i10; i5 = i10 >>> 3; if (i10 >>> 0 < 256) { i10 = i5 << 1; i2 = 96 + (i10 << 2) | 0; i9 = HEAP32[14] | 0; i5 = 1 << i5; if ((i9 & i5 | 0) != 0) { i9 = 96 + (i10 + 2 << 2) | 0; i5 = HEAP32[i9 >> 2] | 0; if (i5 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { i3 = i9; i4 = i5; } } else { HEAP32[14] = i9 | i5; i3 = 96 + (i10 + 2 << 2) | 0; i4 = i2; } HEAP32[i3 >> 2] = i7; HEAP32[i4 + 12 >> 2] = i7; HEAP32[i17 + (i8 + 8) >> 2] = i4; HEAP32[i17 + (i8 + 12) >> 2] = i2; break; } i3 = i10 >>> 8; if ((i3 | 0) != 0) { if (i10 >>> 0 > 16777215) { i3 = 31; } else { i31 = (i3 + 1048320 | 0) >>> 16 & 8; i32 = i3 << i31; i30 = (i32 + 520192 | 0) >>> 16 & 4; i32 = i32 << i30; i3 = (i32 + 245760 | 0) >>> 16 & 2; i3 = 14 - (i30 | i31 | i3) + (i32 << i3 >>> 15) | 0; i3 = i10 >>> (i3 + 7 | 0) & 1 | i3 << 1; } } else { i3 = 0; } i4 = 360 + (i3 << 2) | 0; HEAP32[i17 + (i8 + 28) >> 2] = i3; HEAP32[i17 + (i8 + 20) >> 2] = 0; HEAP32[i17 + (i8 + 16) >> 2] = 0; i9 = HEAP32[60 >> 2] | 0; i5 = 1 << i3; if ((i9 & i5 | 0) == 0) { HEAP32[60 >> 2] = i9 | i5; HEAP32[i4 >> 2] = i7; HEAP32[i17 + (i8 + 24) >> 2] = i4; HEAP32[i17 + (i8 + 12) >> 2] = i7; HEAP32[i17 + (i8 + 8) >> 2] = i7; break; } i4 = HEAP32[i4 >> 2] | 0; if ((i3 | 0) == 31) { i3 = 0; } else { i3 = 25 - (i3 >>> 1) | 0; } L444 : do { if ((HEAP32[i4 + 4 >> 2] & -8 | 0) != (i10 | 0)) { i3 = i10 << i3; while (1) { i5 = i4 + (i3 >>> 31 << 2) + 16 | 0; i9 = HEAP32[i5 >> 2] | 0; if ((i9 | 0) == 0) { break; } if ((HEAP32[i9 + 4 >> 2] & -8 | 0) == (i10 | 0)) { i2 = i9; break L444; } else { i3 = i3 << 1; i4 = i9; } } if (i5 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i5 >> 2] = i7; HEAP32[i17 + (i8 + 24) >> 2] = i4; HEAP32[i17 + (i8 + 12) >> 2] = i7; HEAP32[i17 + (i8 + 8) >> 2] = i7; break L348; } } else { i2 = i4; } } while (0); i4 = i2 + 8 | 0; i3 = HEAP32[i4 >> 2] | 0; i5 = HEAP32[72 >> 2] | 0; if (i2 >>> 0 < i5 >>> 0) { _abort(); } if (i3 >>> 0 < i5 >>> 0) { _abort(); } else { HEAP32[i3 + 12 >> 2] = i7; HEAP32[i4 >> 2] = i7; HEAP32[i17 + (i8 + 8) >> 2] = i3; HEAP32[i17 + (i8 + 12) >> 2] = i2; HEAP32[i17 + (i8 + 24) >> 2] = 0; break; } } else { i32 = (HEAP32[68 >> 2] | 0) + i10 | 0; HEAP32[68 >> 2] = i32; HEAP32[80 >> 2] = i7; HEAP32[i17 + (i8 + 4) >> 2] = i32 | 1; } } while (0); i32 = i17 + (i6 | 8) | 0; STACKTOP = i1; return i32 | 0; } i3 = 504 | 0; while (1) { i2 = HEAP32[i3 >> 2] | 0; if (!(i2 >>> 0 > i15 >>> 0) ? (i11 = HEAP32[i3 + 4 >> 2] | 0, i10 = i2 + i11 | 0, i10 >>> 0 > i15 >>> 0) : 0) { break; } i3 = HEAP32[i3 + 8 >> 2] | 0; } i3 = i2 + (i11 + -39) | 0; if ((i3 & 7 | 0) == 0) { i3 = 0; } else { i3 = 0 - i3 & 7; } i2 = i2 + (i11 + -47 + i3) | 0; i2 = i2 >>> 0 < (i15 + 16 | 0) >>> 0 ? i15 : i2; i3 = i2 + 8 | 0; i4 = i17 + 8 | 0; if ((i4 & 7 | 0) == 0) { i4 = 0; } else { i4 = 0 - i4 & 7; } i32 = i14 + -40 - i4 | 0; HEAP32[80 >> 2] = i17 + i4; HEAP32[68 >> 2] = i32; HEAP32[i17 + (i4 + 4) >> 2] = i32 | 1; HEAP32[i17 + (i14 + -36) >> 2] = 40; HEAP32[84 >> 2] = HEAP32[544 >> 2]; HEAP32[i2 + 4 >> 2] = 27; HEAP32[i3 + 0 >> 2] = HEAP32[504 >> 2]; HEAP32[i3 + 4 >> 2] = HEAP32[508 >> 2]; HEAP32[i3 + 8 >> 2] = HEAP32[512 >> 2]; HEAP32[i3 + 12 >> 2] = HEAP32[516 >> 2]; HEAP32[504 >> 2] = i17; HEAP32[508 >> 2] = i14; HEAP32[516 >> 2] = 0; HEAP32[512 >> 2] = i3; i4 = i2 + 28 | 0; HEAP32[i4 >> 2] = 7; if ((i2 + 32 | 0) >>> 0 < i10 >>> 0) { while (1) { i3 = i4 + 4 | 0; HEAP32[i3 >> 2] = 7; if ((i4 + 8 | 0) >>> 0 < i10 >>> 0) { i4 = i3; } else { break; } } } if ((i2 | 0) != (i15 | 0)) { i2 = i2 - i15 | 0; i3 = i15 + (i2 + 4) | 0; HEAP32[i3 >> 2] = HEAP32[i3 >> 2] & -2; HEAP32[i15 + 4 >> 2] = i2 | 1; HEAP32[i15 + i2 >> 2] = i2; i3 = i2 >>> 3; if (i2 >>> 0 < 256) { i4 = i3 << 1; i2 = 96 + (i4 << 2) | 0; i5 = HEAP32[14] | 0; i3 = 1 << i3; if ((i5 & i3 | 0) != 0) { i4 = 96 + (i4 + 2 << 2) | 0; i3 = HEAP32[i4 >> 2] | 0; if (i3 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { i7 = i4; i8 = i3; } } else { HEAP32[14] = i5 | i3; i7 = 96 + (i4 + 2 << 2) | 0; i8 = i2; } HEAP32[i7 >> 2] = i15; HEAP32[i8 + 12 >> 2] = i15; HEAP32[i15 + 8 >> 2] = i8; HEAP32[i15 + 12 >> 2] = i2; break; } i3 = i2 >>> 8; if ((i3 | 0) != 0) { if (i2 >>> 0 > 16777215) { i3 = 31; } else { i31 = (i3 + 1048320 | 0) >>> 16 & 8; i32 = i3 << i31; i30 = (i32 + 520192 | 0) >>> 16 & 4; i32 = i32 << i30; i3 = (i32 + 245760 | 0) >>> 16 & 2; i3 = 14 - (i30 | i31 | i3) + (i32 << i3 >>> 15) | 0; i3 = i2 >>> (i3 + 7 | 0) & 1 | i3 << 1; } } else { i3 = 0; } i7 = 360 + (i3 << 2) | 0; HEAP32[i15 + 28 >> 2] = i3; HEAP32[i15 + 20 >> 2] = 0; HEAP32[i15 + 16 >> 2] = 0; i4 = HEAP32[60 >> 2] | 0; i5 = 1 << i3; if ((i4 & i5 | 0) == 0) { HEAP32[60 >> 2] = i4 | i5; HEAP32[i7 >> 2] = i15; HEAP32[i15 + 24 >> 2] = i7; HEAP32[i15 + 12 >> 2] = i15; HEAP32[i15 + 8 >> 2] = i15; break; } i4 = HEAP32[i7 >> 2] | 0; if ((i3 | 0) == 31) { i3 = 0; } else { i3 = 25 - (i3 >>> 1) | 0; } L499 : do { if ((HEAP32[i4 + 4 >> 2] & -8 | 0) != (i2 | 0)) { i3 = i2 << i3; while (1) { i7 = i4 + (i3 >>> 31 << 2) + 16 | 0; i5 = HEAP32[i7 >> 2] | 0; if ((i5 | 0) == 0) { break; } if ((HEAP32[i5 + 4 >> 2] & -8 | 0) == (i2 | 0)) { i6 = i5; break L499; } else { i3 = i3 << 1; i4 = i5; } } if (i7 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i7 >> 2] = i15; HEAP32[i15 + 24 >> 2] = i4; HEAP32[i15 + 12 >> 2] = i15; HEAP32[i15 + 8 >> 2] = i15; break L311; } } else { i6 = i4; } } while (0); i4 = i6 + 8 | 0; i3 = HEAP32[i4 >> 2] | 0; i2 = HEAP32[72 >> 2] | 0; if (i6 >>> 0 < i2 >>> 0) { _abort(); } if (i3 >>> 0 < i2 >>> 0) { _abort(); } else { HEAP32[i3 + 12 >> 2] = i15; HEAP32[i4 >> 2] = i15; HEAP32[i15 + 8 >> 2] = i3; HEAP32[i15 + 12 >> 2] = i6; HEAP32[i15 + 24 >> 2] = 0; break; } } } else { i32 = HEAP32[72 >> 2] | 0; if ((i32 | 0) == 0 | i17 >>> 0 < i32 >>> 0) { HEAP32[72 >> 2] = i17; } HEAP32[504 >> 2] = i17; HEAP32[508 >> 2] = i14; HEAP32[516 >> 2] = 0; HEAP32[92 >> 2] = HEAP32[132]; HEAP32[88 >> 2] = -1; i2 = 0; do { i32 = i2 << 1; i31 = 96 + (i32 << 2) | 0; HEAP32[96 + (i32 + 3 << 2) >> 2] = i31; HEAP32[96 + (i32 + 2 << 2) >> 2] = i31; i2 = i2 + 1 | 0; } while ((i2 | 0) != 32); i2 = i17 + 8 | 0; if ((i2 & 7 | 0) == 0) { i2 = 0; } else { i2 = 0 - i2 & 7; } i32 = i14 + -40 - i2 | 0; HEAP32[80 >> 2] = i17 + i2; HEAP32[68 >> 2] = i32; HEAP32[i17 + (i2 + 4) >> 2] = i32 | 1; HEAP32[i17 + (i14 + -36) >> 2] = 40; HEAP32[84 >> 2] = HEAP32[544 >> 2]; } } while (0); i2 = HEAP32[68 >> 2] | 0; if (i2 >>> 0 > i12 >>> 0) { i31 = i2 - i12 | 0; HEAP32[68 >> 2] = i31; i32 = HEAP32[80 >> 2] | 0; HEAP32[80 >> 2] = i32 + i12; HEAP32[i32 + (i12 + 4) >> 2] = i31 | 1; HEAP32[i32 + 4 >> 2] = i12 | 3; i32 = i32 + 8 | 0; STACKTOP = i1; return i32 | 0; } } HEAP32[(___errno_location() | 0) >> 2] = 12; i32 = 0; STACKTOP = i1; return i32 | 0; } function _free(i7) { i7 = i7 | 0; var i1 = 0, i2 = 0, i3 = 0, i4 = 0, i5 = 0, i6 = 0, i8 = 0, i9 = 0, i10 = 0, i11 = 0, i12 = 0, i13 = 0, i14 = 0, i15 = 0, i16 = 0, i17 = 0, i18 = 0, i19 = 0, i20 = 0, i21 = 0; i1 = STACKTOP; if ((i7 | 0) == 0) { STACKTOP = i1; return; } i15 = i7 + -8 | 0; i16 = HEAP32[72 >> 2] | 0; if (i15 >>> 0 < i16 >>> 0) { _abort(); } i13 = HEAP32[i7 + -4 >> 2] | 0; i12 = i13 & 3; if ((i12 | 0) == 1) { _abort(); } i8 = i13 & -8; i6 = i7 + (i8 + -8) | 0; do { if ((i13 & 1 | 0) == 0) { i19 = HEAP32[i15 >> 2] | 0; if ((i12 | 0) == 0) { STACKTOP = i1; return; } i15 = -8 - i19 | 0; i13 = i7 + i15 | 0; i12 = i19 + i8 | 0; if (i13 >>> 0 < i16 >>> 0) { _abort(); } if ((i13 | 0) == (HEAP32[76 >> 2] | 0)) { i2 = i7 + (i8 + -4) | 0; if ((HEAP32[i2 >> 2] & 3 | 0) != 3) { i2 = i13; i11 = i12; break; } HEAP32[64 >> 2] = i12; HEAP32[i2 >> 2] = HEAP32[i2 >> 2] & -2; HEAP32[i7 + (i15 + 4) >> 2] = i12 | 1; HEAP32[i6 >> 2] = i12; STACKTOP = i1; return; } i18 = i19 >>> 3; if (i19 >>> 0 < 256) { i2 = HEAP32[i7 + (i15 + 8) >> 2] | 0; i11 = HEAP32[i7 + (i15 + 12) >> 2] | 0; i14 = 96 + (i18 << 1 << 2) | 0; if ((i2 | 0) != (i14 | 0)) { if (i2 >>> 0 < i16 >>> 0) { _abort(); } if ((HEAP32[i2 + 12 >> 2] | 0) != (i13 | 0)) { _abort(); } } if ((i11 | 0) == (i2 | 0)) { HEAP32[14] = HEAP32[14] & ~(1 << i18); i2 = i13; i11 = i12; break; } if ((i11 | 0) != (i14 | 0)) { if (i11 >>> 0 < i16 >>> 0) { _abort(); } i14 = i11 + 8 | 0; if ((HEAP32[i14 >> 2] | 0) == (i13 | 0)) { i17 = i14; } else { _abort(); } } else { i17 = i11 + 8 | 0; } HEAP32[i2 + 12 >> 2] = i11; HEAP32[i17 >> 2] = i2; i2 = i13; i11 = i12; break; } i17 = HEAP32[i7 + (i15 + 24) >> 2] | 0; i18 = HEAP32[i7 + (i15 + 12) >> 2] | 0; do { if ((i18 | 0) == (i13 | 0)) { i19 = i7 + (i15 + 20) | 0; i18 = HEAP32[i19 >> 2] | 0; if ((i18 | 0) == 0) { i19 = i7 + (i15 + 16) | 0; i18 = HEAP32[i19 >> 2] | 0; if ((i18 | 0) == 0) { i14 = 0; break; } } while (1) { i21 = i18 + 20 | 0; i20 = HEAP32[i21 >> 2] | 0; if ((i20 | 0) != 0) { i18 = i20; i19 = i21; continue; } i20 = i18 + 16 | 0; i21 = HEAP32[i20 >> 2] | 0; if ((i21 | 0) == 0) { break; } else { i18 = i21; i19 = i20; } } if (i19 >>> 0 < i16 >>> 0) { _abort(); } else { HEAP32[i19 >> 2] = 0; i14 = i18; break; } } else { i19 = HEAP32[i7 + (i15 + 8) >> 2] | 0; if (i19 >>> 0 < i16 >>> 0) { _abort(); } i16 = i19 + 12 | 0; if ((HEAP32[i16 >> 2] | 0) != (i13 | 0)) { _abort(); } i20 = i18 + 8 | 0; if ((HEAP32[i20 >> 2] | 0) == (i13 | 0)) { HEAP32[i16 >> 2] = i18; HEAP32[i20 >> 2] = i19; i14 = i18; break; } else { _abort(); } } } while (0); if ((i17 | 0) != 0) { i18 = HEAP32[i7 + (i15 + 28) >> 2] | 0; i16 = 360 + (i18 << 2) | 0; if ((i13 | 0) == (HEAP32[i16 >> 2] | 0)) { HEAP32[i16 >> 2] = i14; if ((i14 | 0) == 0) { HEAP32[60 >> 2] = HEAP32[60 >> 2] & ~(1 << i18); i2 = i13; i11 = i12; break; } } else { if (i17 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i16 = i17 + 16 | 0; if ((HEAP32[i16 >> 2] | 0) == (i13 | 0)) { HEAP32[i16 >> 2] = i14; } else { HEAP32[i17 + 20 >> 2] = i14; } if ((i14 | 0) == 0) { i2 = i13; i11 = i12; break; } } if (i14 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } HEAP32[i14 + 24 >> 2] = i17; i16 = HEAP32[i7 + (i15 + 16) >> 2] | 0; do { if ((i16 | 0) != 0) { if (i16 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i14 + 16 >> 2] = i16; HEAP32[i16 + 24 >> 2] = i14; break; } } } while (0); i15 = HEAP32[i7 + (i15 + 20) >> 2] | 0; if ((i15 | 0) != 0) { if (i15 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i14 + 20 >> 2] = i15; HEAP32[i15 + 24 >> 2] = i14; i2 = i13; i11 = i12; break; } } else { i2 = i13; i11 = i12; } } else { i2 = i13; i11 = i12; } } else { i2 = i15; i11 = i8; } } while (0); if (!(i2 >>> 0 < i6 >>> 0)) { _abort(); } i12 = i7 + (i8 + -4) | 0; i13 = HEAP32[i12 >> 2] | 0; if ((i13 & 1 | 0) == 0) { _abort(); } if ((i13 & 2 | 0) == 0) { if ((i6 | 0) == (HEAP32[80 >> 2] | 0)) { i21 = (HEAP32[68 >> 2] | 0) + i11 | 0; HEAP32[68 >> 2] = i21; HEAP32[80 >> 2] = i2; HEAP32[i2 + 4 >> 2] = i21 | 1; if ((i2 | 0) != (HEAP32[76 >> 2] | 0)) { STACKTOP = i1; return; } HEAP32[76 >> 2] = 0; HEAP32[64 >> 2] = 0; STACKTOP = i1; return; } if ((i6 | 0) == (HEAP32[76 >> 2] | 0)) { i21 = (HEAP32[64 >> 2] | 0) + i11 | 0; HEAP32[64 >> 2] = i21; HEAP32[76 >> 2] = i2; HEAP32[i2 + 4 >> 2] = i21 | 1; HEAP32[i2 + i21 >> 2] = i21; STACKTOP = i1; return; } i11 = (i13 & -8) + i11 | 0; i12 = i13 >>> 3; do { if (!(i13 >>> 0 < 256)) { i10 = HEAP32[i7 + (i8 + 16) >> 2] | 0; i15 = HEAP32[i7 + (i8 | 4) >> 2] | 0; do { if ((i15 | 0) == (i6 | 0)) { i13 = i7 + (i8 + 12) | 0; i12 = HEAP32[i13 >> 2] | 0; if ((i12 | 0) == 0) { i13 = i7 + (i8 + 8) | 0; i12 = HEAP32[i13 >> 2] | 0; if ((i12 | 0) == 0) { i9 = 0; break; } } while (1) { i14 = i12 + 20 | 0; i15 = HEAP32[i14 >> 2] | 0; if ((i15 | 0) != 0) { i12 = i15; i13 = i14; continue; } i14 = i12 + 16 | 0; i15 = HEAP32[i14 >> 2] | 0; if ((i15 | 0) == 0) { break; } else { i12 = i15; i13 = i14; } } if (i13 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i13 >> 2] = 0; i9 = i12; break; } } else { i13 = HEAP32[i7 + i8 >> 2] | 0; if (i13 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i14 = i13 + 12 | 0; if ((HEAP32[i14 >> 2] | 0) != (i6 | 0)) { _abort(); } i12 = i15 + 8 | 0; if ((HEAP32[i12 >> 2] | 0) == (i6 | 0)) { HEAP32[i14 >> 2] = i15; HEAP32[i12 >> 2] = i13; i9 = i15; break; } else { _abort(); } } } while (0); if ((i10 | 0) != 0) { i12 = HEAP32[i7 + (i8 + 20) >> 2] | 0; i13 = 360 + (i12 << 2) | 0; if ((i6 | 0) == (HEAP32[i13 >> 2] | 0)) { HEAP32[i13 >> 2] = i9; if ((i9 | 0) == 0) { HEAP32[60 >> 2] = HEAP32[60 >> 2] & ~(1 << i12); break; } } else { if (i10 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i12 = i10 + 16 | 0; if ((HEAP32[i12 >> 2] | 0) == (i6 | 0)) { HEAP32[i12 >> 2] = i9; } else { HEAP32[i10 + 20 >> 2] = i9; } if ((i9 | 0) == 0) { break; } } if (i9 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } HEAP32[i9 + 24 >> 2] = i10; i6 = HEAP32[i7 + (i8 + 8) >> 2] | 0; do { if ((i6 | 0) != 0) { if (i6 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i9 + 16 >> 2] = i6; HEAP32[i6 + 24 >> 2] = i9; break; } } } while (0); i6 = HEAP32[i7 + (i8 + 12) >> 2] | 0; if ((i6 | 0) != 0) { if (i6 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i9 + 20 >> 2] = i6; HEAP32[i6 + 24 >> 2] = i9; break; } } } } else { i9 = HEAP32[i7 + i8 >> 2] | 0; i7 = HEAP32[i7 + (i8 | 4) >> 2] | 0; i8 = 96 + (i12 << 1 << 2) | 0; if ((i9 | 0) != (i8 | 0)) { if (i9 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } if ((HEAP32[i9 + 12 >> 2] | 0) != (i6 | 0)) { _abort(); } } if ((i7 | 0) == (i9 | 0)) { HEAP32[14] = HEAP32[14] & ~(1 << i12); break; } if ((i7 | 0) != (i8 | 0)) { if (i7 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } i8 = i7 + 8 | 0; if ((HEAP32[i8 >> 2] | 0) == (i6 | 0)) { i10 = i8; } else { _abort(); } } else { i10 = i7 + 8 | 0; } HEAP32[i9 + 12 >> 2] = i7; HEAP32[i10 >> 2] = i9; } } while (0); HEAP32[i2 + 4 >> 2] = i11 | 1; HEAP32[i2 + i11 >> 2] = i11; if ((i2 | 0) == (HEAP32[76 >> 2] | 0)) { HEAP32[64 >> 2] = i11; STACKTOP = i1; return; } } else { HEAP32[i12 >> 2] = i13 & -2; HEAP32[i2 + 4 >> 2] = i11 | 1; HEAP32[i2 + i11 >> 2] = i11; } i6 = i11 >>> 3; if (i11 >>> 0 < 256) { i7 = i6 << 1; i3 = 96 + (i7 << 2) | 0; i8 = HEAP32[14] | 0; i6 = 1 << i6; if ((i8 & i6 | 0) != 0) { i6 = 96 + (i7 + 2 << 2) | 0; i7 = HEAP32[i6 >> 2] | 0; if (i7 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { i4 = i6; i5 = i7; } } else { HEAP32[14] = i8 | i6; i4 = 96 + (i7 + 2 << 2) | 0; i5 = i3; } HEAP32[i4 >> 2] = i2; HEAP32[i5 + 12 >> 2] = i2; HEAP32[i2 + 8 >> 2] = i5; HEAP32[i2 + 12 >> 2] = i3; STACKTOP = i1; return; } i4 = i11 >>> 8; if ((i4 | 0) != 0) { if (i11 >>> 0 > 16777215) { i4 = 31; } else { i20 = (i4 + 1048320 | 0) >>> 16 & 8; i21 = i4 << i20; i19 = (i21 + 520192 | 0) >>> 16 & 4; i21 = i21 << i19; i4 = (i21 + 245760 | 0) >>> 16 & 2; i4 = 14 - (i19 | i20 | i4) + (i21 << i4 >>> 15) | 0; i4 = i11 >>> (i4 + 7 | 0) & 1 | i4 << 1; } } else { i4 = 0; } i5 = 360 + (i4 << 2) | 0; HEAP32[i2 + 28 >> 2] = i4; HEAP32[i2 + 20 >> 2] = 0; HEAP32[i2 + 16 >> 2] = 0; i7 = HEAP32[60 >> 2] | 0; i6 = 1 << i4; L199 : do { if ((i7 & i6 | 0) != 0) { i5 = HEAP32[i5 >> 2] | 0; if ((i4 | 0) == 31) { i4 = 0; } else { i4 = 25 - (i4 >>> 1) | 0; } L205 : do { if ((HEAP32[i5 + 4 >> 2] & -8 | 0) != (i11 | 0)) { i4 = i11 << i4; i7 = i5; while (1) { i6 = i7 + (i4 >>> 31 << 2) + 16 | 0; i5 = HEAP32[i6 >> 2] | 0; if ((i5 | 0) == 0) { break; } if ((HEAP32[i5 + 4 >> 2] & -8 | 0) == (i11 | 0)) { i3 = i5; break L205; } else { i4 = i4 << 1; i7 = i5; } } if (i6 >>> 0 < (HEAP32[72 >> 2] | 0) >>> 0) { _abort(); } else { HEAP32[i6 >> 2] = i2; HEAP32[i2 + 24 >> 2] = i7; HEAP32[i2 + 12 >> 2] = i2; HEAP32[i2 + 8 >> 2] = i2; break L199; } } else { i3 = i5; } } while (0); i5 = i3 + 8 | 0; i4 = HEAP32[i5 >> 2] | 0; i6 = HEAP32[72 >> 2] | 0; if (i3 >>> 0 < i6 >>> 0) { _abort(); } if (i4 >>> 0 < i6 >>> 0) { _abort(); } else { HEAP32[i4 + 12 >> 2] = i2; HEAP32[i5 >> 2] = i2; HEAP32[i2 + 8 >> 2] = i4; HEAP32[i2 + 12 >> 2] = i3; HEAP32[i2 + 24 >> 2] = 0; break; } } else { HEAP32[60 >> 2] = i7 | i6; HEAP32[i5 >> 2] = i2; HEAP32[i2 + 24 >> 2] = i5; HEAP32[i2 + 12 >> 2] = i2; HEAP32[i2 + 8 >> 2] = i2; } } while (0); i21 = (HEAP32[88 >> 2] | 0) + -1 | 0; HEAP32[88 >> 2] = i21; if ((i21 | 0) == 0) { i2 = 512 | 0; } else { STACKTOP = i1; return; } while (1) { i2 = HEAP32[i2 >> 2] | 0; if ((i2 | 0) == 0) { break; } else { i2 = i2 + 8 | 0; } } HEAP32[88 >> 2] = -1; STACKTOP = i1; return; } function __Z15fannkuch_workerPv(i9) { i9 = i9 | 0; var i1 = 0, i2 = 0, i3 = 0, i4 = 0, i5 = 0, i6 = 0, i7 = 0, i8 = 0, i10 = 0, i11 = 0, i12 = 0, i13 = 0, i14 = 0, i15 = 0, i16 = 0, i17 = 0, i18 = 0, i19 = 0, i20 = 0; i3 = STACKTOP; i7 = HEAP32[i9 + 4 >> 2] | 0; i6 = i7 << 2; i5 = _malloc(i6) | 0; i2 = _malloc(i6) | 0; i6 = _malloc(i6) | 0; i10 = (i7 | 0) > 0; if (i10) { i8 = 0; do { HEAP32[i5 + (i8 << 2) >> 2] = i8; i8 = i8 + 1 | 0; } while ((i8 | 0) != (i7 | 0)); i8 = i7 + -1 | 0; i17 = HEAP32[i9 >> 2] | 0; HEAP32[i5 + (i17 << 2) >> 2] = i8; i9 = i5 + (i8 << 2) | 0; HEAP32[i9 >> 2] = i17; if (i10) { i10 = i7 << 2; i11 = 0; i12 = i7; L7 : while (1) { if ((i12 | 0) > 1) { while (1) { i13 = i12 + -1 | 0; HEAP32[i6 + (i13 << 2) >> 2] = i12; if ((i13 | 0) > 1) { i12 = i13; } else { i12 = 1; break; } } } i13 = HEAP32[i5 >> 2] | 0; if ((i13 | 0) != 0 ? (HEAP32[i9 >> 2] | 0) != (i8 | 0) : 0) { _memcpy(i2 | 0, i5 | 0, i10 | 0) | 0; i15 = 0; i14 = HEAP32[i2 >> 2] | 0; while (1) { i17 = i14 + -1 | 0; if ((i17 | 0) > 1) { i16 = 1; do { i20 = i2 + (i16 << 2) | 0; i19 = HEAP32[i20 >> 2] | 0; i18 = i2 + (i17 << 2) | 0; HEAP32[i20 >> 2] = HEAP32[i18 >> 2]; HEAP32[i18 >> 2] = i19; i16 = i16 + 1 | 0; i17 = i17 + -1 | 0; } while ((i16 | 0) < (i17 | 0)); } i15 = i15 + 1 | 0; i20 = i2 + (i14 << 2) | 0; i16 = HEAP32[i20 >> 2] | 0; HEAP32[i20 >> 2] = i14; if ((i16 | 0) == 0) { break; } else { i14 = i16; } } i11 = (i11 | 0) < (i15 | 0) ? i15 : i11; } if ((i12 | 0) >= (i8 | 0)) { i8 = 34; break; } while (1) { if ((i12 | 0) > 0) { i14 = 0; while (1) { i15 = i14 + 1 | 0; HEAP32[i5 + (i14 << 2) >> 2] = HEAP32[i5 + (i15 << 2) >> 2]; if ((i15 | 0) == (i12 | 0)) { i14 = i12; break; } else { i14 = i15; } } } else { i14 = 0; } HEAP32[i5 + (i14 << 2) >> 2] = i13; i14 = i6 + (i12 << 2) | 0; i20 = (HEAP32[i14 >> 2] | 0) + -1 | 0; HEAP32[i14 >> 2] = i20; i14 = i12 + 1 | 0; if ((i20 | 0) > 0) { continue L7; } if ((i14 | 0) >= (i8 | 0)) { i8 = 34; break L7; } i13 = HEAP32[i5 >> 2] | 0; i12 = i14; } } if ((i8 | 0) == 34) { _free(i5); _free(i2); _free(i6); STACKTOP = i3; return i11 | 0; } } else { i1 = i9; i4 = i8; } } else { i4 = i7 + -1 | 0; i20 = HEAP32[i9 >> 2] | 0; HEAP32[i5 + (i20 << 2) >> 2] = i4; i1 = i5 + (i4 << 2) | 0; HEAP32[i1 >> 2] = i20; } i11 = 0; L36 : while (1) { if ((i7 | 0) > 1) { while (1) { i8 = i7 + -1 | 0; HEAP32[i6 + (i8 << 2) >> 2] = i7; if ((i8 | 0) > 1) { i7 = i8; } else { i7 = 1; break; } } } i8 = HEAP32[i5 >> 2] | 0; if ((i8 | 0) != 0 ? (HEAP32[i1 >> 2] | 0) != (i4 | 0) : 0) { i10 = 0; i9 = HEAP32[i2 >> 2] | 0; while (1) { i13 = i9 + -1 | 0; if ((i13 | 0) > 1) { i12 = 1; do { i18 = i2 + (i12 << 2) | 0; i19 = HEAP32[i18 >> 2] | 0; i20 = i2 + (i13 << 2) | 0; HEAP32[i18 >> 2] = HEAP32[i20 >> 2]; HEAP32[i20 >> 2] = i19; i12 = i12 + 1 | 0; i13 = i13 + -1 | 0; } while ((i12 | 0) < (i13 | 0)); } i10 = i10 + 1 | 0; i20 = i2 + (i9 << 2) | 0; i12 = HEAP32[i20 >> 2] | 0; HEAP32[i20 >> 2] = i9; if ((i12 | 0) == 0) { break; } else { i9 = i12; } } i11 = (i11 | 0) < (i10 | 0) ? i10 : i11; } if ((i7 | 0) >= (i4 | 0)) { i8 = 34; break; } while (1) { if ((i7 | 0) > 0) { i9 = 0; while (1) { i10 = i9 + 1 | 0; HEAP32[i5 + (i9 << 2) >> 2] = HEAP32[i5 + (i10 << 2) >> 2]; if ((i10 | 0) == (i7 | 0)) { i9 = i7; break; } else { i9 = i10; } } } else { i9 = 0; } HEAP32[i5 + (i9 << 2) >> 2] = i8; i9 = i6 + (i7 << 2) | 0; i20 = (HEAP32[i9 >> 2] | 0) + -1 | 0; HEAP32[i9 >> 2] = i20; i9 = i7 + 1 | 0; if ((i20 | 0) > 0) { continue L36; } if ((i9 | 0) >= (i4 | 0)) { i8 = 34; break L36; } i8 = HEAP32[i5 >> 2] | 0; i7 = i9; } } if ((i8 | 0) == 34) { _free(i5); _free(i2); _free(i6); STACKTOP = i3; return i11 | 0; } return 0; } function _main(i3, i5) { i3 = i3 | 0; i5 = i5 | 0; var i1 = 0, i2 = 0, i4 = 0, i6 = 0, i7 = 0, i8 = 0, i9 = 0, i10 = 0, i11 = 0; i2 = STACKTOP; STACKTOP = STACKTOP + 16 | 0; i1 = i2; L1 : do { if ((i3 | 0) > 1) { i3 = HEAP8[HEAP32[i5 + 4 >> 2] | 0] | 0; switch (i3 | 0) { case 50: { i3 = 10; break L1; } case 51: { i4 = 4; break L1; } case 52: { i3 = 11; break L1; } case 53: { i3 = 12; break L1; } case 49: { i3 = 9; break L1; } case 48: { i11 = 0; STACKTOP = i2; return i11 | 0; } default: { HEAP32[i1 >> 2] = i3 + -48; _printf(8, i1 | 0) | 0; i11 = -1; STACKTOP = i2; return i11 | 0; } } } else { i4 = 4; } } while (0); if ((i4 | 0) == 4) { i3 = 11; } i5 = i3 + -1 | 0; i6 = 0; i7 = 0; while (1) { i4 = _malloc(12) | 0; HEAP32[i4 >> 2] = i7; HEAP32[i4 + 4 >> 2] = i3; HEAP32[i4 + 8 >> 2] = i6; i7 = i7 + 1 | 0; if ((i7 | 0) == (i5 | 0)) { break; } else { i6 = i4; } } i5 = i3 << 2; i6 = _malloc(i5) | 0; i5 = _malloc(i5) | 0; i7 = 0; do { HEAP32[i6 + (i7 << 2) >> 2] = i7; i7 = i7 + 1 | 0; } while ((i7 | 0) != (i3 | 0)); i8 = i3; i7 = 30; L19 : do { i9 = 0; do { HEAP32[i1 >> 2] = (HEAP32[i6 + (i9 << 2) >> 2] | 0) + 1; _printf(48, i1 | 0) | 0; i9 = i9 + 1 | 0; } while ((i9 | 0) != (i3 | 0)); _putchar(10) | 0; i7 = i7 + -1 | 0; if ((i8 | 0) <= 1) { if ((i8 | 0) == (i3 | 0)) { break; } } else { while (1) { i9 = i8 + -1 | 0; HEAP32[i5 + (i9 << 2) >> 2] = i8; if ((i9 | 0) > 1) { i8 = i9; } else { i8 = 1; break; } } } while (1) { i9 = HEAP32[i6 >> 2] | 0; if ((i8 | 0) > 0) { i11 = 0; while (1) { i10 = i11 + 1 | 0; HEAP32[i6 + (i11 << 2) >> 2] = HEAP32[i6 + (i10 << 2) >> 2]; if ((i10 | 0) == (i8 | 0)) { i10 = i8; break; } else { i11 = i10; } } } else { i10 = 0; } HEAP32[i6 + (i10 << 2) >> 2] = i9; i9 = i5 + (i8 << 2) | 0; i11 = (HEAP32[i9 >> 2] | 0) + -1 | 0; HEAP32[i9 >> 2] = i11; i9 = i8 + 1 | 0; if ((i11 | 0) > 0) { break; } if ((i9 | 0) == (i3 | 0)) { break L19; } else { i8 = i9; } } } while ((i7 | 0) != 0); _free(i6); _free(i5); if ((i4 | 0) == 0) { i5 = 0; } else { i5 = 0; while (1) { i6 = __Z15fannkuch_workerPv(i4) | 0; i5 = (i5 | 0) < (i6 | 0) ? i6 : i5; i6 = HEAP32[i4 + 8 >> 2] | 0; _free(i4); if ((i6 | 0) == 0) { break; } else { i4 = i6; } } } HEAP32[i1 >> 2] = i3; HEAP32[i1 + 4 >> 2] = i5; _printf(24, i1 | 0) | 0; i11 = 0; STACKTOP = i2; return i11 | 0; } function _memcpy(i3, i2, i1) { i3 = i3 | 0; i2 = i2 | 0; i1 = i1 | 0; var i4 = 0; if ((i1 | 0) >= 4096) return _emscripten_memcpy_big(i3 | 0, i2 | 0, i1 | 0) | 0; i4 = i3 | 0; if ((i3 & 3) == (i2 & 3)) { while (i3 & 3) { if ((i1 | 0) == 0) return i4 | 0; HEAP8[i3] = HEAP8[i2] | 0; i3 = i3 + 1 | 0; i2 = i2 + 1 | 0; i1 = i1 - 1 | 0; } while ((i1 | 0) >= 4) { HEAP32[i3 >> 2] = HEAP32[i2 >> 2]; i3 = i3 + 4 | 0; i2 = i2 + 4 | 0; i1 = i1 - 4 | 0; } } while ((i1 | 0) > 0) { HEAP8[i3] = HEAP8[i2] | 0; i3 = i3 + 1 | 0; i2 = i2 + 1 | 0; i1 = i1 - 1 | 0; } return i4 | 0; } function _memset(i1, i4, i3) { i1 = i1 | 0; i4 = i4 | 0; i3 = i3 | 0; var i2 = 0, i5 = 0, i6 = 0, i7 = 0; i2 = i1 + i3 | 0; if ((i3 | 0) >= 20) { i4 = i4 & 255; i7 = i1 & 3; i6 = i4 | i4 << 8 | i4 << 16 | i4 << 24; i5 = i2 & ~3; if (i7) { i7 = i1 + 4 - i7 | 0; while ((i1 | 0) < (i7 | 0)) { HEAP8[i1] = i4; i1 = i1 + 1 | 0; } } while ((i1 | 0) < (i5 | 0)) { HEAP32[i1 >> 2] = i6; i1 = i1 + 4 | 0; } } while ((i1 | 0) < (i2 | 0)) { HEAP8[i1] = i4; i1 = i1 + 1 | 0; } return i1 - i3 | 0; } function copyTempDouble(i1) { i1 = i1 | 0; HEAP8[tempDoublePtr] = HEAP8[i1]; HEAP8[tempDoublePtr + 1 | 0] = HEAP8[i1 + 1 | 0]; HEAP8[tempDoublePtr + 2 | 0] = HEAP8[i1 + 2 | 0]; HEAP8[tempDoublePtr + 3 | 0] = HEAP8[i1 + 3 | 0]; HEAP8[tempDoublePtr + 4 | 0] = HEAP8[i1 + 4 | 0]; HEAP8[tempDoublePtr + 5 | 0] = HEAP8[i1 + 5 | 0]; HEAP8[tempDoublePtr + 6 | 0] = HEAP8[i1 + 6 | 0]; HEAP8[tempDoublePtr + 7 | 0] = HEAP8[i1 + 7 | 0]; } function copyTempFloat(i1) { i1 = i1 | 0; HEAP8[tempDoublePtr] = HEAP8[i1]; HEAP8[tempDoublePtr + 1 | 0] = HEAP8[i1 + 1 | 0]; HEAP8[tempDoublePtr + 2 | 0] = HEAP8[i1 + 2 | 0]; HEAP8[tempDoublePtr + 3 | 0] = HEAP8[i1 + 3 | 0]; } function runPostSets() {} function _strlen(i1) { i1 = i1 | 0; var i2 = 0; i2 = i1; while (HEAP8[i2] | 0) { i2 = i2 + 1 | 0; } return i2 - i1 | 0; } function stackAlloc(i1) { i1 = i1 | 0; var i2 = 0; i2 = STACKTOP; STACKTOP = STACKTOP + i1 | 0; STACKTOP = STACKTOP + 7 & -8; return i2 | 0; } function setThrew(i1, i2) { i1 = i1 | 0; i2 = i2 | 0; if ((__THREW__ | 0) == 0) { __THREW__ = i1; threwValue = i2; } } function stackRestore(i1) { i1 = i1 | 0; STACKTOP = i1; } function setTempRet9(i1) { i1 = i1 | 0; tempRet9 = i1; } function setTempRet8(i1) { i1 = i1 | 0; tempRet8 = i1; } function setTempRet7(i1) { i1 = i1 | 0; tempRet7 = i1; } function setTempRet6(i1) { i1 = i1 | 0; tempRet6 = i1; } function setTempRet5(i1) { i1 = i1 | 0; tempRet5 = i1; } function setTempRet4(i1) { i1 = i1 | 0; tempRet4 = i1; } function setTempRet3(i1) { i1 = i1 | 0; tempRet3 = i1; } function setTempRet2(i1) { i1 = i1 | 0; tempRet2 = i1; } function setTempRet1(i1) { i1 = i1 | 0; tempRet1 = i1; } function setTempRet0(i1) { i1 = i1 | 0; tempRet0 = i1; } function stackSave() { return STACKTOP | 0; } // EMSCRIPTEN_END_FUNCS return { _strlen: _strlen, _free: _free, _main: _main, _memset: _memset, _malloc: _malloc, _memcpy: _memcpy, runPostSets: runPostSets, stackAlloc: stackAlloc, stackSave: stackSave, stackRestore: stackRestore, setThrew: setThrew, setTempRet0: setTempRet0, setTempRet1: setTempRet1, setTempRet2: setTempRet2, setTempRet3: setTempRet3, setTempRet4: setTempRet4, setTempRet5: setTempRet5, setTempRet6: setTempRet6, setTempRet7: setTempRet7, setTempRet8: setTempRet8, setTempRet9: setTempRet9 }; }) // EMSCRIPTEN_END_ASM ({ "Math": Math, "Int8Array": Int8Array, "Int16Array": Int16Array, "Int32Array": Int32Array, "Uint8Array": Uint8Array, "Uint16Array": Uint16Array, "Uint32Array": Uint32Array, "Float32Array": Float32Array, "Float64Array": Float64Array }, { "abort": abort, "assert": assert, "asmPrintInt": asmPrintInt, "asmPrintFloat": asmPrintFloat, "min": Math_min, "_fflush": _fflush, "_emscripten_memcpy_big": _emscripten_memcpy_big, "_putchar": _putchar, "_fputc": _fputc, "_send": _send, "_pwrite": _pwrite, "_abort": _abort, "__reallyNegative": __reallyNegative, "_fwrite": _fwrite, "_sbrk": _sbrk, "_mkport": _mkport, "_fprintf": _fprintf, "___setErrNo": ___setErrNo, "__formatString": __formatString, "_fileno": _fileno, "_printf": _printf, "_time": _time, "_sysconf": _sysconf, "_write": _write, "___errno_location": ___errno_location, "STACKTOP": STACKTOP, "STACK_MAX": STACK_MAX, "tempDoublePtr": tempDoublePtr, "ABORT": ABORT, "NaN": NaN, "Infinity": Infinity }, buffer); assertTrue(%IsAsmWasmCode(ModuleFunc)); var _strlen = Module["_strlen"] = asm["_strlen"]; var _free = Module["_free"] = asm["_free"]; var _main = Module["_main"] = asm["_main"]; var _memset = Module["_memset"] = asm["_memset"]; var _malloc = Module["_malloc"] = asm["_malloc"]; var _memcpy = Module["_memcpy"] = asm["_memcpy"]; var runPostSets = Module["runPostSets"] = asm["runPostSets"]; Runtime.stackAlloc = function(size) { return asm['stackAlloc'](size) }; Runtime.stackSave = function() { return asm['stackSave']() }; Runtime.stackRestore = function(top) { asm['stackRestore'](top) }; // Warning: printing of i64 values may be slightly rounded! No deep i64 math used, so precise i64 code not included var i64Math = null; // === Auto-generated postamble setup entry stuff === if (memoryInitializer) { if (ENVIRONMENT_IS_NODE || ENVIRONMENT_IS_SHELL) { var data = Module['readBinary'](memoryInitializer); HEAPU8.set(data, STATIC_BASE); } else { addRunDependency('memory initializer'); Browser.asyncLoad(memoryInitializer, function(data) { HEAPU8.set(data, STATIC_BASE); removeRunDependency('memory initializer'); }, function(data) { throw 'could not load memory initializer ' + memoryInitializer; }); } } function ExitStatus(status) { this.name = "ExitStatus"; this.message = "Program terminated with exit(" + status + ")"; this.status = status; }; ExitStatus.prototype = new Error(); ExitStatus.prototype.constructor = ExitStatus; var initialStackTop; var preloadStartTime = null; var calledMain = false; dependenciesFulfilled = function runCaller() { // If run has never been called, and we should call run (INVOKE_RUN is true, and Module.noInitialRun is not false) if (!Module['calledRun'] && shouldRunNow) run([].concat(Module["arguments"])); if (!Module['calledRun']) dependenciesFulfilled = runCaller; // try this again later, after new deps are fulfilled } Module['callMain'] = Module.callMain = function callMain(args) { assert(runDependencies == 0, 'cannot call main when async dependencies remain! (listen on __ATMAIN__)'); assert(__ATPRERUN__.length == 0, 'cannot call main when preRun functions remain to be called'); args = args || []; ensureInitRuntime(); var argc = args.length+1; function pad() { for (var i = 0; i < 4-1; i++) { argv.push(0); } } var argv = [allocate(intArrayFromString("/bin/this.program"), 'i8', ALLOC_NORMAL) ]; pad(); for (var i = 0; i < argc-1; i = i + 1) { argv.push(allocate(intArrayFromString(args[i]), 'i8', ALLOC_NORMAL)); pad(); } argv.push(0); argv = allocate(argv, 'i32', ALLOC_NORMAL); initialStackTop = STACKTOP; try { var ret = Module['_main'](argc, argv, 0); // if we're not running an evented main loop, it's time to exit if (!Module['noExitRuntime']) { exit(ret); } } catch(e) { if (e instanceof ExitStatus) { // exit() throws this once it's done to make sure execution // has been stopped completely return; } else if (e == 'SimulateInfiniteLoop') { // running an evented main loop, don't immediately exit Module['noExitRuntime'] = true; return; } else { if (e && typeof e === 'object' && e.stack) Module.printErr('exception thrown: ' + [e, e.stack]); throw e; } } finally { calledMain = true; } } function run(args) { args = args || Module['arguments']; if (preloadStartTime === null) preloadStartTime = Date.now(); if (runDependencies > 0) { Module.printErr('run() called, but dependencies remain, so not running'); return; } preRun(); if (runDependencies > 0) return; // a preRun added a dependency, run will be called later if (Module['calledRun']) return; // run may have just been called through dependencies being fulfilled just in this very frame function doRun() { if (Module['calledRun']) return; // run may have just been called while the async setStatus time below was happening Module['calledRun'] = true; ensureInitRuntime(); preMain(); if (ENVIRONMENT_IS_WEB && preloadStartTime !== null) { Module.printErr('pre-main prep time: ' + (Date.now() - preloadStartTime) + ' ms'); } if (Module['_main'] && shouldRunNow) { Module['callMain'](args); } postRun(); } if (Module['setStatus']) { Module['setStatus']('Running...'); setTimeout(function() { setTimeout(function() { Module['setStatus'](''); }, 1); if (!ABORT) doRun(); }, 1); } else { doRun(); } } Module['run'] = Module.run = run; function exit(status) { ABORT = true; EXITSTATUS = status; STACKTOP = initialStackTop; // exit the runtime exitRuntime(); // TODO We should handle this differently based on environment. // In the browser, the best we can do is throw an exception // to halt execution, but in node we could process.exit and // I'd imagine SM shell would have something equivalent. // This would let us set a proper exit status (which // would be great for checking test exit statuses). // https://github.com/kripken/emscripten/issues/1371 // throw an exception to halt the current execution throw new ExitStatus(status); } Module['exit'] = Module.exit = exit; function abort(text) { if (text) { Module.print(text); Module.printErr(text); } ABORT = true; EXITSTATUS = 1; var extra = '\nIf this abort() is unexpected, build with -s ASSERTIONS=1 which can give more information.'; throw 'abort() at ' + stackTrace() + extra; } Module['abort'] = Module.abort = abort; // {{PRE_RUN_ADDITIONS}} if (Module['preInit']) { if (typeof Module['preInit'] == 'function') Module['preInit'] = [Module['preInit']]; while (Module['preInit'].length > 0) { Module['preInit'].pop()(); } } // shouldRunNow refers to calling main(), not run(). var shouldRunNow = true; if (Module['noInitialRun']) { shouldRunNow = false; } run([].concat(Module["arguments"]));