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chromium / external / github.com / emscripten-core / emscripten / refs/heads/android.wasm / . / src / parseTools.js
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/**
* @license
* Copyright 2010 The Emscripten Authors
* SPDX-License-Identifier: MIT
*
* Helpers and tools for use at compile time by JavaScript library files.
*
* Tests live in test/other/test_parseTools.js.
*/
global.FOUR_GB = 4 * 1024 * 1024 * 1024;
const FLOAT_TYPES = new Set(['float', 'double']);
// Does simple 'macro' substitution, using Django-like syntax,
// {{{ code }}} will be replaced with |eval(code)|.
// NOTE: Be careful with that ret check. If ret is |0|, |ret ? ret.toString() : ''| would result in ''!
function processMacros(text) {
// The `?` here in makes the regex non-greedy so it matches with the closest
// set of closing braces.
// `[\s\S]` works like `.` but include newline.
return text.replace(/{{{([\s\S]+?)}}}/g, (_, str) => {
try {
const ret = eval(str);
return ret !== null ? ret.toString() : '';
} catch (ex) {
ex.stack = 'In the following macro:\n\n' + str + '\n\n' + ex.stack;
throw ex;
}
});
}
// Simple #if/else/endif preprocessing for a file. Checks if the
// ident checked is true in our global.
// Also handles #include x.js (similar to C #include <file>)
function preprocess(filename) {
let text = read(filename);
if (EXPORT_ES6 && USE_ES6_IMPORT_META) {
// `eval`, Terser and Closure don't support module syntax; to allow it,
// we need to temporarily replace `import.meta` and `await import` usages
// with placeholders during preprocess phase, and back after all the other ops.
// See also: `phase_final_emitting` in emcc.py.
text = text
.replace(/\bimport\.meta\b/g, 'EMSCRIPTEN$IMPORT$META')
.replace(/\bawait import\b/g, 'EMSCRIPTEN$AWAIT$IMPORT');
}
// Remove windows line endings, if any
text = text.replace(/\r\n/g, '\n');
const IGNORE = 0;
const SHOW = 1;
// This state is entered after we have shown one of the block of an if/elif/else sequence.
// Once we enter this state we dont show any blocks or evaluate any
// conditions until the sequence ends.
const IGNORE_ALL = 2;
const showStack = [];
const showCurrentLine = () => showStack.every((x) => x == SHOW);
const oldFilename = currentFile;
currentFile = filename;
const fileExt = filename.split('.').pop().toLowerCase();
const isHtml = (fileExt === 'html' || fileExt === 'htm') ? true : false;
let inStyle = false;
const lines = text.split('\n');
// text.split yields an extra empty element at the end if text itself ends with a newline.
if (!lines[lines.length - 1]) {
lines.pop();
}
let ret = '';
let emptyLine = false;
try {
for (let [i, line] of lines.entries()) {
if (isHtml) {
if (line.includes('<style') && !inStyle) {
inStyle = true;
}
if (line.includes('</style') && inStyle) {
inStyle = false;
}
if (inStyle) {
if (showCurrentLine()) {
ret += line + '\n';
}
continue;
}
}
const trimmed = line.trim();
if (trimmed.startsWith('#')) {
const first = trimmed.split(' ', 1)[0];
if (first == '#if' || first == '#ifdef' || first == '#elif') {
if (first == '#ifdef') {
warn('use of #ifdef in js library. Use #if instead.');
}
if (first == '#elif') {
const curr = showStack.pop();
if (curr == SHOW || curr == IGNORE_ALL) {
// If we showed to previous block we enter the IGNORE_ALL state
// and stay there until endif is seen
showStack.push(IGNORE_ALL);
continue;
}
}
const after = trimmed.substring(trimmed.indexOf(' '));
const truthy = !!vm.runInThisContext(after, { filename, lineOffset: i, columnOffset: line.indexOf(after) });
showStack.push(truthy ? SHOW : IGNORE);
} else if (first === '#include') {
if (showCurrentLine()) {
let filename = line.substr(line.indexOf(' ') + 1);
if (filename.startsWith('"')) {
filename = filename.substr(1, filename.length - 2);
}
const result = preprocess(filename);
if (result) {
ret += `// include: ${filename}\n`;
ret += result;
ret += `// end include: ${filename}\n`;
}
}
} else if (first === '#else') {
assert(showStack.length > 0);
const curr = showStack.pop();
if (curr == IGNORE) {
showStack.push(SHOW);
} else {
showStack.push(IGNORE);
}
} else if (first === '#endif') {
assert(showStack.length > 0);
showStack.pop();
} else if (first === '#warning') {
if (showCurrentLine()) {
printErr(`${filename}:${i + 1}: #warning ${trimmed.substring(trimmed.indexOf(' ')).trim()}`);
}
} else if (first === '#error') {
if (showCurrentLine()) {
error(`${filename}:${i + 1}: #error ${trimmed.substring(trimmed.indexOf(' ')).trim()}`);
}
} else {
error(`${filename}:${i + 1}: Unknown preprocessor directive ${first}`);
}
} else {
if (showCurrentLine()) {
// Never emit more than one empty line at a time.
if (emptyLine && !line) {
continue;
}
ret += line + '\n';
if (!line) {
emptyLine = true;
} else {
emptyLine = false;
}
}
}
}
assert(showStack.length == 0, `preprocessing error in file ${filename}, \
no matching #endif found (${showStack.length$}' unmatched preprocessing directives on stack)`);
return ret;
} finally {
currentFile = oldFilename;
}
}
// Returns true if ident is a niceIdent (see toNiceIdent). Also allow () and spaces.
function isNiceIdent(ident, loose) {
return /^\(?[$_]+[\w$_\d ]*\)?$/.test(ident);
}
// Simple variables or numbers, or things already quoted, do not need to be quoted
function needsQuoting(ident) {
if (/^[-+]?[$_]?[\w$_\d]*$/.test(ident)) return false; // number or variable
if (ident[0] === '(' && ident[ident.length - 1] === ')' && ident.indexOf('(', 1) < 0) return false; // already fully quoted
return true;
}
global.POINTER_SIZE = MEMORY64 ? 8 : 4;
global.STACK_ALIGN = 16;
const POINTER_BITS = POINTER_SIZE * 8;
const POINTER_TYPE = 'u' + POINTER_BITS;
const POINTER_JS_TYPE = MEMORY64 ? "'bigint'" : "'number'";
const POINTER_SHIFT = MEMORY64 ? '3' : '2';
const POINTER_HEAP = MEMORY64 ? 'HEAP64' : 'HEAP32';
const SIZE_TYPE = POINTER_TYPE;
// Similar to POINTER_TYPE, but this is the actual wasm type that is
// used in practice, while POINTER_TYPE is the more refined internal
// type (that is unsigned, where as core wasm does not have unsigned
// types).
const POINTER_WASM_TYPE = 'i' + POINTER_BITS;
function isPointerType(type) {
return type[type.length - 1] == '*';
}
// Given an expression like (VALUE=VALUE*2,VALUE<10?VALUE:t+1) , this will
// replace VALUE with value. If value is not a simple identifier of a variable,
// value will be replaced with tempVar.
function makeInlineCalculation(expression, value, tempVar) {
if (!isNiceIdent(value)) {
expression = tempVar + '=' + value + ',' + expression;
value = tempVar;
}
return '(' + expression.replace(/VALUE/g, value) + ')';
}
// XXX Make all i64 parts signed
// Splits a number (an integer in a double, possibly > 32 bits) into an i64
// value, represented by a low and high i32 pair.
// Will suffer from rounding and truncation.
function splitI64(value) {
if (WASM_BIGINT) {
// Nothing to do: just make sure it is a BigInt (as it must be of that
// type, to be sent into wasm).
return `BigInt(${value})`;
}
// general idea:
//
// $1$0 = ~~$d >>> 0;
// $1$1 = Math.abs($d) >= 1 ? (
// $d > 0 ? Math.floor(($d)/ 4294967296.0) >>> 0
// : Math.ceil(Math.min(-4294967296.0, $d - $1$0)/ 4294967296.0)
// ) : 0;
//
// We need to min on positive values here, since our input might be a double,
// and large values are rounded, so they can be slightly higher than expected.
// And if we get 4294967296, that will turn into a 0 if put into a HEAP32 or
// |0'd, etc.
//
// For negatives, we need to ensure a -1 if the value is overall negative,
// even if not significant negative component
const low = value + '>>>0';
const high = makeInlineCalculation(
asmCoercion('Math.abs(VALUE)', 'double') + ' >= ' + asmEnsureFloat('1', 'double') + ' ? ' +
'(VALUE > ' + asmEnsureFloat('0', 'double') + ' ? ' +
asmCoercion('Math.floor((VALUE)/' +
asmEnsureFloat(4294967296, 'double') + ')', 'double') + '>>>0' +
' : ' +
asmFloatToInt(asmCoercion('Math.ceil((VALUE - +((' + asmFloatToInt('VALUE') + ')>>>0))/' +
asmEnsureFloat(4294967296, 'double') + ')', 'double')) + '>>>0' +
')' +
' : 0',
value,
'tempDouble',
);
return [low, high];
}
// Misc
function indentify(text, indent) {
// Don't try to indentify huge strings - we may run out of memory
if (text.length > 1024 * 1024) return text;
if (typeof indent == 'number') {
const len = indent;
indent = '';
for (let i = 0; i < len; i++) {
indent += ' ';
}
}
return text.replace(/\n/g, '\n' + indent);
}
// Correction tools
function getNativeTypeSize(type) {
switch (type) {
case 'i1': case 'i8': case 'u8': return 1;
case 'i16': case 'u16': return 2;
case 'i32': case 'u32': return 4;
case 'i64': case 'u64': return 8;
case 'float': return 4;
case 'double': return 8;
default: {
if (type[type.length - 1] === '*') {
return POINTER_SIZE;
}
if (type[0] === 'i') {
const bits = Number(type.substr(1));
assert(bits % 8 === 0, 'getNativeTypeSize invalid bits ' + bits + ', type ' + type);
return bits / 8;
}
return 0;
}
}
}
function getHeapOffset(offset, type) {
const sz = getNativeTypeSize(type);
const shifts = Math.log(sz) / Math.LN2;
if (MEMORY64 == 1) {
return `((${offset})/${2 ** shifts})`;
} else if (CAN_ADDRESS_2GB) {
return `((${offset})>>>${shifts})`;
} else {
return `((${offset})>>${shifts})`;
}
}
function ensureDot(value) {
value = value.toString();
// if already dotted, or Infinity or NaN, nothing to do here
// if smaller than 1 and running js opts, we always need to force a coercion
// (0.001 will turn into 1e-3, which has no .)
if ((value.includes('.') || /[IN]/.test(value))) return value;
const e = value.indexOf('e');
if (e < 0) return value + '.0';
return value.substr(0, e) + '.0' + value.substr(e);
}
// ensures that a float type has either 5.5 (clearly a float) or +5 (float due to asm coercion)
function asmEnsureFloat(value, type) {
if (!isNumber(value)) return value;
if (type === 'float') {
// normally ok to just emit Math.fround(0), but if the constant is large we
// may need a .0 (if it can't fit in an int)
if (value == 0) return 'Math.fround(0)';
value = ensureDot(value);
return 'Math.fround(' + value + ')';
}
if (FLOAT_TYPES.has(type)) {
return ensureDot(value);
}
return value;
}
function asmCoercion(value, type) {
assert(arguments.length == 2, 'asmCoercion takes exactly two arguments');
if (type == 'void') {
return value;
}
if (FLOAT_TYPES.has(type)) {
if (isNumber(value)) {
return asmEnsureFloat(value, type);
}
if (type === 'float') {
return 'Math.fround(' + value + ')';
}
return '(+(' + value + '))';
}
return '((' + value + ')|0)';
}
function asmFloatToInt(x) {
return '(~~(' + x + '))';
}
// See makeSetValue
function makeGetValue(ptr, pos, type, noNeedFirst, unsigned, ignore, align) {
assert(typeof align === 'undefined', 'makeGetValue no longer supports align parameter');
assert(typeof noNeedFirst === 'undefined', 'makeGetValue no longer supports noNeedFirst parameter');
if (typeof unsigned !== 'undefined') {
// TODO(sbc): make this into an error at some point.
printErr('makeGetValue: Please use u8/u16/u32/u64 unsigned types in favor of additional argument');
if (unsigned && type.startsWith('i')) {
type = 'u' + type.slice(1);
}
} else if (type.startsWith('u')) {
// Set `unsigned` based on the type name.
unsigned = true;
}
const offset = calcFastOffset(ptr, pos);
if (type === 'i53' || type === 'u53') {
return 'readI53From' + (unsigned ? 'U' : 'I') + '64(' + offset + ')';
}
const slab = getHeapForType(type);
let ret = slab + '[' + getHeapOffset(offset, type) + ']';
if (MEMORY64 && isPointerType(type)) {
ret = `Number(${ret})`;
}
return ret;
}
/**
* @param {number} ptr The pointer. Used to find both the slab and the offset in that slab. If the pointer
* is just an integer, then this is almost redundant, but in general the pointer type
* may in the future include information about which slab as well. So, for now it is
* possible to put |0| here, but if a pointer is available, that is more future-proof.
* @param {number} pos The position in that slab - the offset. Added to any offset in the pointer itself.
* @param {number} value The value to set.
* @param {string} type A string defining the type. Used to find the slab (HEAPU8, HEAP16, HEAPU32, etc.).
* which means we should write to all slabs, ignore type differences if any on reads, etc.
* @return {string} JS code for performing the memory set operation
*/
function makeSetValue(ptr, pos, value, type) {
var rtn = makeSetValueImpl(ptr, pos, value, type);
if (ASSERTIONS == 2 && (type.startsWith('i') || type.startsWith('u'))) {
const width = getBitWidth(type);
const assertion = `checkInt${width}(${value})`;
rtn += ';' + assertion
}
return rtn;
}
function makeSetValueImpl(ptr, pos, value, type) {
if (type == 'i64' && !WASM_BIGINT) {
// If we lack BigInt support we must fall back to an reading a pair of I32
// values.
return '(tempI64 = [' + splitI64(value) + '], ' +
makeSetValueImpl(ptr, pos, 'tempI64[0]', 'i32') + ',' +
makeSetValueImpl(ptr, getFastValue(pos, '+', getNativeTypeSize('i32')), 'tempI64[1]', 'i32') + ')';
}
const offset = calcFastOffset(ptr, pos);
if (type === 'i53') {
return `writeI53ToI64(${offset}, ${value})`;
}
const slab = getHeapForType(type);
if (slab == 'HEAPU64' || slab == 'HEAP64') {
value = `BigInt(${value})`;
}
return slab + '[' + getHeapOffset(offset, type) + '] = ' + value;
}
function makeHEAPView(which, start, end) {
const size = parseInt(which.replace('U', '').replace('F', '')) / 8;
const shift = Math.log2(size);
const mod = size == 1 ? '' : CAN_ADDRESS_2GB ? ('>>>' + shift) : ('>>' + shift);
return `HEAP${which}.subarray((${start})${mod}, (${end})${mod})`;
}
// Given two values and an operation, returns the result of that operation.
// Tries to do as much as possible at compile time.
function getFastValue(a, op, b) {
// In the past we supported many operations, but today we only use addition.
assert(op == '+');
// Convert 'true' and 'false' to '1' and '0'.
a = a === 'true' ? '1' : (a === 'false' ? '0' : a);
b = b === 'true' ? '1' : (b === 'false' ? '0' : b);
let aNumber = null;
let bNumber = null;
if (typeof a == 'number') {
aNumber = a;
a = a.toString();
} else if (isNumber(a)) {
aNumber = parseFloat(a);
}
if (typeof b == 'number') {
bNumber = b;
b = b.toString();
} else if (isNumber(b)) {
bNumber = parseFloat(b);
}
// First check if we can do the addition at compile time
if (aNumber !== null && bNumber !== null) {
return (aNumber + bNumber).toString();
}
// If one of them is a number, keep it last
if (aNumber !== null) {
const c = b;
b = a;
a = c;
const cNumber = bNumber;
bNumber = aNumber;
aNumber = cNumber;
}
if (aNumber === 0) {
return b;
} else if (bNumber === 0) {
return a;
}
if (b[0] === '-') {
op = '-'
b = b.substr(1);
}
return `(${a})${op}(${b})`;
}
function calcFastOffset(ptr, pos) {
return getFastValue(ptr, '+', pos);
}
function getBitWidth(type) {
if (type == 'i53' || type == 'u53')
return 53;
return getNativeTypeSize(type) * 8;
}
function getHeapForType(type) {
assert(type);
if (isPointerType(type)) {
type = POINTER_TYPE;
}
if (WASM_BIGINT) {
switch (type) {
case 'i64': return 'HEAP64';
case 'u64': return 'HEAPU64';
}
}
switch (type) {
case 'i1': // fallthrough
case 'i8': return 'HEAP8';
case 'u8': return 'HEAPU8';
case 'i16': return 'HEAP16';
case 'u16': return 'HEAPU16';
case 'i32': return 'HEAP32';
case 'u32': return 'HEAPU32';
case 'double': return 'HEAPF64';
case 'float': return 'HEAPF32';
case 'i64': // fallthrough
case 'u64': error('use i53/u53, or avoid i64/u64 without WASM_BIGINT');
}
assert(false, 'bad heap type: ' + type);
}
function makeReturn64(value) {
if (WASM_BIGINT) {
return `BigInt(${value})`;
}
const pair = splitI64(value);
// `return (a, b, c)` in JavaScript will execute `a`, and `b` and return the final
// element `c`
return `(setTempRet0(${pair[1]}), ${pair[0]})`;
}
function makeThrow(excPtr) {
if (ASSERTIONS && DISABLE_EXCEPTION_CATCHING) {
var assertInfo = 'Exception thrown, but exception catching is not enabled. Compile with -sNO_DISABLE_EXCEPTION_CATCHING or -sEXCEPTION_CATCHING_ALLOWED=[..] to catch.';
if (MAIN_MODULE) {
assertInfo += ' (note: in dynamic linking, if a side module wants exceptions, the main module must be built with that support)';
}
return `assert(false, '${assertInfo}');`;
}
return `throw ${excPtr};`;
}
function storeException(varName, excPtr) {
var exceptionToStore = EXCEPTION_STACK_TRACES ? `new CppException(${excPtr})` : `${excPtr}`;
return `${varName} = ${exceptionToStore};`;
}
function charCode(char) {
return char.charCodeAt(0);
}
function makeDynCall(sig, funcPtr) {
assert(!sig.includes('j'), 'Cannot specify 64-bit signatures ("j" in signature string) with makeDynCall!');
let args = [];
for (let i = 1; i < sig.length; ++i) {
args.push(`a${i}`);
}
args = args.join(', ');
const needArgConversion = MEMORY64 && sig.includes('p');
let callArgs = args;
if (needArgConversion) {
callArgs = [];
for (let i = 1; i < sig.length; ++i) {
if (sig[i] == 'p') {
callArgs.push(`BigInt(a${i})`);
} else {
callArgs.push(`a${i}`);
}
}
callArgs = callArgs.join(', ');
}
// Normalize any 'p' characters to either 'j' (wasm64) or 'i' (wasm32)
if (sig.includes('p')) {
let normalizedSig = '';
for (let sigChr of sig) {
if (sigChr == 'p') {
sigChr = MEMORY64 ? 'j' : 'i';
}
normalizedSig += sigChr;
}
sig = normalizedSig;
}
if (funcPtr === undefined) {
warn(`
Legacy use of {{{ makeDynCall("${sig}") }}}(funcPtr, arg1, arg2, ...). \
Starting from Emscripten 2.0.2 (Aug 31st 2020), syntax for makeDynCall has changed. \
New syntax is {{{ makeDynCall("${sig}", "funcPtr") }}}(arg1, arg2, ...). \
Please update to new syntax.`);
if (DYNCALLS) {
if (!hasExportedSymbol(`dynCall_${sig}`)) {
if (ASSERTIONS) {
return `((${args}) => { throw 'Internal Error! Attempted to invoke wasm function pointer with signature "${sig}", but no such functions have gotten exported!' })`;
} else {
return `((${args}) => {} /* a dynamic function call to signature ${sig}, but there are no exported function pointers with that signature, so this path should never be taken. Build with ASSERTIONS enabled to validate. */)`;
}
}
return `((cb, ${args}) => getDynCaller("${sig}", cb)(${callArgs}))`;
} else {
return `((cb, ${args}) => getWasmTableEntry(cb)(${callArgs}))`;
}
}
if (DYNCALLS) {
if (!hasExportedSymbol(`dynCall_${sig}`)) {
if (ASSERTIONS) {
return `((${args}) => { throw 'Internal Error! Attempted to invoke wasm function pointer with signature "${sig}", but no such functions have gotten exported!' })`;
} else {
return `((${args}) => {} /* a dynamic function call to signature ${sig}, but there are no exported function pointers with that signature, so this path should never be taken. Build with ASSERTIONS enabled to validate. */)`;
}
}
const dyncall = `dynCall_${sig}`;
if (sig.length > 1) {
return `((${args}) => ${dyncall}.apply(null, [${funcPtr}, ${callArgs}]))`;
}
return `(() => ${dyncall}.call(null, ${funcPtr}))`;
}
if (needArgConversion) {
return `((${args}) => getWasmTableEntry(${funcPtr}).call(null, ${callArgs}))`;
}
return `getWasmTableEntry(${funcPtr})`;
}
function makeEval(code) {
if (DYNAMIC_EXECUTION == 0) {
// Treat eval as error.
return "abort('DYNAMIC_EXECUTION=0 was set, cannot eval');";
}
let ret = '';
if (DYNAMIC_EXECUTION == 2) {
// Warn on evals, but proceed.
ret += "err('Warning: DYNAMIC_EXECUTION=2 was set, but calling eval in the following location:');\n";
ret += 'err(stackTrace());\n';
}
ret += code;
return ret;
}
global.ATINITS = [];
function addAtInit(code) {
ATINITS.push(code);
}
global.ATEXITS = [];
function addAtExit(code) {
if (EXIT_RUNTIME) {
ATEXITS.push(code);
}
}
function makeRetainedCompilerSettings() {
const ignore = new Set();
if (STRICT) {
for (const setting of LEGACY_SETTINGS) {
ignore.add(setting);
}
}
const ret = {};
for (const x in global) {
if (!ignore.has(x) && x[0] !== '_' && x == x.toUpperCase()) {
const value = global[x];
if (typeof value == 'number' || typeof value == 'boolean' || typeof value == 'string' || Array.isArray(x)) {
ret[x] = value;
}
}
}
return ret;
}
// In wasm, the heap size must be a multiple of 64KiB.
const WASM_PAGE_SIZE = 65536;
// Receives a function as text, and a function that constructs a modified
// function, to which we pass the parsed-out arguments, body, and possible
// "async" prefix of the input function. Returns the output of that function.
function modifyJSFunction(text, func) {
// Match a function with a name.
let async_;
let args;
let rest;
let match = text.match(/^\s*(async\s+)?function\s+([^(]*)?\s*\(([^)]*)\)/);
if (match) {
async_ = match[1] || '';
args = match[3];
rest = text.substr(match[0].length);
} else {
// Match an arrow function
let match = text.match(/^\s*(var (\w+) = )?(async\s+)?\(([^)]*)\)\s+=>\s+/);
if (match) {
async_ = match[3] || '';
args = match[4];
rest = text.substr(match[0].length);
} else {
// Match a function without a name (we could probably use a single regex
// for both, but it would be more complex).
match = text.match(/^\s*(async\s+)?function\(([^)]*)\)/);
assert(match, `could not match function:\n${text}\n`);
async_ = match[1] || '';
args = match[2];
rest = text.substr(match[0].length);
}
}
let body = rest;
const bodyStart = rest.indexOf('{');
let oneliner = bodyStart < 0;
if (!oneliner) {
const bodyEnd = rest.lastIndexOf('}');
assert(bodyEnd > 0);
body = rest.substring(bodyStart + 1, bodyEnd);
}
return func(args, body, async_, oneliner);
}
function runIfMainThread(text) {
if (WASM_WORKERS && PTHREADS) {
return 'if (!ENVIRONMENT_IS_WASM_WORKER && !ENVIRONMENT_IS_PTHREAD) { ' + text + ' }';
} else if (WASM_WORKERS) {
return 'if (!ENVIRONMENT_IS_WASM_WORKER) { ' + text + ' }';
} else if (PTHREADS) {
return 'if (!ENVIRONMENT_IS_PTHREAD) { ' + text + ' }';
} else {
return text;
}
}
// Legacy name for runIfMainThread.
// TODO(remove).
const runOnMainThread = runIfMainThread;
function expectToReceiveOnModule(name) {
return INCOMING_MODULE_JS_API.has(name);
}
function makeRemovedModuleAPIAssert(moduleName, localName) {
if (!ASSERTIONS) return '';
if (!localName) localName = moduleName;
return `legacyModuleProp('${moduleName}', '${localName}');`;
}
function checkReceiving(name) {
// ALL_INCOMING_MODULE_JS_API contains all valid incoming module API symbols
// so calling makeModuleReceive* with a symbol not in this list is an error
assert(ALL_INCOMING_MODULE_JS_API.has(name), `${name} is not part of INCOMING_MODULE_JS_API`);
}
// Make code to receive a value on the incoming Module object.
function makeModuleReceive(localName, moduleName) {
if (!moduleName) moduleName = localName;
checkReceiving(moduleName);
let ret = '';
if (expectToReceiveOnModule(moduleName)) {
// Usually the local we use is the same as the Module property name,
// but sometimes they must differ.
ret = `\nif (Module['${moduleName}']) ${localName} = Module['${moduleName}'];`;
}
ret += makeRemovedModuleAPIAssert(moduleName, localName);
return ret;
}
function makeModuleReceiveExpr(name, defaultValue) {
checkReceiving(name);
if (expectToReceiveOnModule(name)) {
return `Module['${name}'] || ${defaultValue}`;
} else {
return `${defaultValue}`;
}
}
function makeModuleReceiveWithVar(localName, moduleName, defaultValue, noAssert) {
if (!moduleName) moduleName = localName;
checkReceiving(moduleName);
let ret = 'var ' + localName;
if (!expectToReceiveOnModule(moduleName)) {
if (defaultValue) {
ret += ' = ' + defaultValue;
}
ret += ';';
} else {
if (defaultValue) {
ret += ` = Module['${moduleName}'] || ${defaultValue};`;
} else {
ret += ';' + makeModuleReceive(localName, moduleName);
return ret;
}
}
if (!noAssert) {
ret += makeRemovedModuleAPIAssert(moduleName, localName);
}
return ret;
}
function makeRemovedFSAssert(fsName) {
assert(ASSERTIONS);
const lower = fsName.toLowerCase();
if (JS_LIBRARIES.includes('library_' + lower + '.js')) return '';
return `var ${fsName} = '${fsName} is no longer included by default; build with -l${lower}.js';`;
}
// Given an array of elements [elem1,elem2,elem3], returns a string "['elem1','elem2','elem3']"
function buildStringArray(array) {
if (array.length > 0) {
return "['" + array.join("','") + "']";
} else {
return '[]';
}
}
// Generates access to a JS imports scope variable in pthreads worker.js. In MODULARIZE mode these flow into the imports object for the Module.
// In non-MODULARIZE mode, we can directly access the variables in global scope.
function makeAsmImportsAccessInPthread(variable) {
if (!MINIMAL_RUNTIME) {
// Regular runtime uses the name "Module" for both imports and exports.
return `Module['${variable}']`;
}
if (MODULARIZE) {
// MINIMAL_RUNTIME uses 'imports' as the name for the imports object in MODULARIZE builds.
return `imports['${variable}']`;
}
// In non-MODULARIZE builds, can access the imports from global scope.
return `self.${variable}`;
}
function _asmjsDemangle(symbol) {
if (symbol in WASM_SYSTEM_EXPORTS) {
return symbol;
}
if (symbol.startsWith('dynCall_')) {
return symbol;
}
// Strip leading "_"
assert(symbol.startsWith('_'), 'expected mangled symbol: ' + symbol);
return symbol.substr(1);
}
// TODO(sbc): Remove this function along with _asmjsDemangle.
function hasExportedFunction(func) {
warnOnce('hasExportedFunction has been replaced with hasExportedSymbol, which takes and unmangled (no leading underscore) symbol name');
return WASM_EXPORTS.has(_asmjsDemangle(func));
}
function hasExportedSymbol(sym) {
return WASM_EXPORTS.has(sym);
}
// Called when global runtime symbols such as wasmMemory, wasmExports and
// wasmTable are set. In this case we maybe need to re-export them on the
// Module object.
function receivedSymbol(sym) {
if (EXPORTED_RUNTIME_METHODS.includes(sym)) {
return `Module['${sym}'] = ${sym};`
}
return '';
}
// JS API I64 param handling: if we have BigInt support, the ABI is simple,
// it is a BigInt. Otherwise, we legalize into pairs of i32s.
function defineI64Param(name) {
if (WASM_BIGINT) {
return name;
}
return `${name}_low, ${name}_high`;
}
function receiveI64ParamAsI53(name, onError, handleErrors = true) {
var errorHandler = handleErrors ? `if (isNaN(${name})) return ${onError}` : '';
if (WASM_BIGINT) {
// Just convert the bigint into a double.
return `${name} = bigintToI53Checked(${name});${errorHandler};`;
}
// Convert the high/low pair to a Number, checking for
// overflow of the I53 range and returning onError in that case.
return `var ${name} = convertI32PairToI53Checked(${name}_low, ${name}_high);${errorHandler};`;
}
function receiveI64ParamAsI53Unchecked(name) {
if (WASM_BIGINT) {
return `${name} = Number(${name});`;
}
return `var ${name} = convertI32PairToI53(${name}_low, ${name}_high);`;
}
// Any function called from wasm64 may have bigint args, this function takes
// a list of variable names to convert to number.
function from64(x) {
if (!MEMORY64) {
return '';
}
if (Array.isArray(x)) {
let ret = '';
for (e of x) ret += from64(e);
return ret;
}
return `${x} = Number(${x});`;
}
function to64(x) {
if (!MEMORY64) return x;
return `BigInt(${x})`;
}
// Add assertions to catch common errors when using the Promise object we
// create on Module.ready() and return from MODULARIZE Module() invocations.
function addReadyPromiseAssertions(promise) {
// Warn on someone doing
//
// var instance = Module();
// ...
// instance._main();
const properties = Array.from(EXPORTED_FUNCTIONS.values());
// Also warn on onRuntimeInitialized which might be a common pattern with
// older MODULARIZE-using codebases.
properties.push('onRuntimeInitialized');
const warningEnding = ' on the Promise object, instead of the instance. Use .then() to get called back with the instance, see the MODULARIZE docs in src/settings.js';
const res = JSON.stringify(properties);
return res + `.forEach((prop) => {
if (!Object.getOwnPropertyDescriptor(${promise}, prop)) {
Object.defineProperty(${promise}, prop, {
get: () => abort('You are getting ' + prop + '${warningEnding}'),
set: () => abort('You are setting ' + prop + '${warningEnding}'),
});
}
});`;
}
function asyncIf(condition) {
return condition ? 'async' : '';
}
function awaitIf(condition) {
return condition ? 'await' : '';
}
// Adds a call to runtimeKeepalivePush, if needed by the current build
// configuration.
// We skip this completely in MINIMAL_RUNTIME and also in builds that
// don't ever need to exit the runtime.
function runtimeKeepalivePush() {
if (MINIMAL_RUNTIME || (EXIT_RUNTIME == 0 && PTHREADS == 0)) return '';
return 'runtimeKeepalivePush();';
}
// Adds a call to runtimeKeepalivePush, if needed by the current build
// configuration.
// We skip this completely in MINIMAL_RUNTIME and also in builds that
// don't ever need to exit the runtime.
function runtimeKeepalivePop() {
if (MINIMAL_RUNTIME || (EXIT_RUNTIME == 0 && PTHREADS == 0)) return '';
return 'runtimeKeepalivePop();';
}
// Some web functions like TextDecoder.decode() may not work with a view of a
// SharedArrayBuffer, see https://github.com/whatwg/encoding/issues/172
// To avoid that, this function allows obtaining an unshared copy of an
// ArrayBuffer.
function getUnsharedTextDecoderView(heap, start, end) {
const shared = `${heap}.slice(${start}, ${end})`;
const unshared = `${heap}.subarray(${start}, ${end})`;
// No need to worry about this in non-shared memory builds
if (!SHARED_MEMORY) return unshared;
// If asked to get an unshared view to what we know will be a shared view, or if in -Oz,
// then unconditionally do a .slice() for smallest code size.
if (SHRINK_LEVEL == 2 || heap == 'HEAPU8') return shared;
// Otherwise, generate a runtime type check: must do a .slice() if looking at a SAB,
// or can use .subarray() otherwise.
return `${heap}.buffer instanceof SharedArrayBuffer ? ${shared} : ${unshared}`;
}
function getEntryFunction() {
var entryFunction = 'main';
if (STANDALONE_WASM) {
if (EXPECT_MAIN) {
entryFunction = '_start';
} else {
entryFunction = '_initialize';
}
} else if (PROXY_TO_PTHREAD) {
// User requested the PROXY_TO_PTHREAD option, so call a stub main which pthread_create()s a new thread
// that will call the user's real main() for the application.
entryFunction = '_emscripten_proxy_main';
}
if (MAIN_MODULE) {
return `resolveGlobalSymbol('${entryFunction}').sym;`
}
return '_' + entryFunction;
}
function preJS() {
let result = '';
for (const fileName of PRE_JS_FILES) {
result += read(fileName);
}
return result;
}
function formattedMinNodeVersion() {
var major = MIN_NODE_VERSION / 10000
var minor = (MIN_NODE_VERSION / 100) % 100
var rev = MIN_NODE_VERSION % 100
return `v${major}.${minor}.${rev}`;
}
function getPerformanceNow() {
if (DETERMINISTIC) {
return 'deterministicNow';
} else {
return 'performance.now';
}
}