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|
//"use strict";
// Various tools for parsing LLVM. Utilities of various sorts, that are
// specific to Emscripten (and hence not in utility.js).
// Does simple 'macro' substitution, using Django-like syntax,
// {{{ code }}} will be replaced with |eval(code)|.
function processMacros(text) {
return text.replace(/{{{[^}]+}}}/g, function(str) {
str = str.substr(3, str.length-6);
var ret = eval(str);
if (ret !== undefined) ret = ret.toString();
return ret;
});
}
// Simple #if/else/endif preprocessing for a file. Checks if the
// ident checked is true in our global.
function preprocess(text) {
var lines = text.split('\n');
var ret = '';
var showStack = [];
for (var i = 0; i < lines.length; i++) {
var line = lines[i];
if (line[line.length-1] == '\r') {
line = line.substr(0, line.length-1); // Windows will have '\r' left over from splitting over '\r\n'
}
if (!line[0] || line[0] != '#') {
if (showStack.indexOf(false) == -1) {
ret += line + '\n';
}
} else {
if (line[1] && line[1] == 'i') { // if
var parts = line.split(' ');
var ident = parts[1];
var op = parts[2];
var value = parts[3];
if (op) {
assert(op === '==')
showStack.push(ident in this && this[ident] == value);
} else {
showStack.push(ident in this && this[ident] > 0);
}
} else if (line[2] && line[2] == 'l') { // else
showStack.push(!showStack.pop());
} else if (line[2] && line[2] == 'n') { // endif
showStack.pop();
} else {
throw "Unclear preprocessor command: " + line;
}
}
}
assert(showStack.length == 0);
return ret;
}
function addPointing(type) { return type + '*' }
function removePointing(type, num) {
if (num === 0) return type;
assert(type.substr(type.length-(num ? num : 1)).replace(/\*/g, '') === ''); //, 'Error in removePointing with ' + [type, num, type.substr(type.length-(num ? num : 1))]);
return type.substr(0, type.length-(num ? num : 1));
}
function pointingLevels(type) {
if (!type) return 0;
var ret = 0;
var len1 = type.length - 1;
while (type[len1-ret] && type[len1-ret] === '*') {
ret ++;
}
return ret;
}
function removeAllPointing(type) {
return removePointing(type, pointingLevels(type));
}
function toNiceIdent(ident) {
assert(ident);
if (parseFloat(ident) == ident) return ident;
if (ident == 'null') return '0'; // see parseNumerical
return ident.replace('%', '$').replace(/["&\\ \.@:<>,\*\[\]\(\)-]/g, '_');
}
// Kind of a hack. In some cases we have strings that we do not want
// to |toNiceIdent|, as they are the output of previous processing. We
// should refactor everything into an object, with an explicit flag
// saying what has been |toNiceIdent|ed. Until then, this will detect
// simple idents that are in need of |toNiceIdent|ation. Or, we should
// ensure that processed strings never start with %,@, e.g. by always
// enclosing them in ().
function toNiceIdentCarefully(ident) {
if (ident[0] == '%' || ident[0] == '@') ident = toNiceIdent(ident);
return ident;
}
// Returns true if ident is a niceIdent (see toNiceIdent). If loose
// is true, then also allow () and spaces.
function isNiceIdent(ident, loose) {
if (loose) {
return /^\(?[$_]+[\w$_\d ]*\)?$/.test(ident);
} else {
return /^[$_]+[\w$_\d]*$/.test(ident);
}
}
function isStructPointerType(type) {
// This test is necessary for clang - in llvm-gcc, we
// could check for %struct. The downside is that %1 can
// be either a variable or a structure, and we guess it is
// a struct, which can lead to |call i32 %5()| having
// |%5()| as a function call (like |i32 (i8*)| etc.). So
// we must check later on, in call(), where we have more
// context, to differentiate such cases.
// A similar thing happns in isStructType()
return !Runtime.isNumberType(type) && type[0] == '%';
}
function isPointerType(type) {
return type[type.length-1] == '*';
}
function isStructType(type) {
if (isPointerType(type)) return false;
if (/^\[\d+\ x\ (.*)\]/.test(type)) return true; // [15 x ?] blocks. Like structs
if (/<?{ ?[^}]* ?}>?/.test(type)) return true; // { i32, i8 } etc. - anonymous struct types
// See comment in isStructPointerType()
return type[0] == '%';
}
function isStructuralType(type) {
return /^{ ?[^}]* ?}$/.test(type); // { i32, i8 } etc. - anonymous struct types
}
function getStructuralTypeParts(type) { // split { i32, i8 } etc. into parts
return type.replace(/[ {}]/g, '').split(',');
}
function getStructureTypeParts(type) {
if (isStructuralType(type)) {
return type.replace(/[ {}]/g, '').split(',');
} else {
var typeData = Types.types[type];
assert(typeData, type);
return typeData.fields;
}
}
function getStructuralTypePartBits(part) {
return Math.ceil((getBits(part) || 32)/32)*32; // simple 32-bit alignment. || 32 is for pointers
}
function isIntImplemented(type) {
return type[0] == 'i' || isPointerType(type);
}
// Note: works for iX types and structure types, not pointers (even though they are implemented as ints)
function getBits(type) {
if (!type) return 0;
if (type[0] == 'i') {
var left = type.substr(1);
if (!isNumber(left)) return 0;
return parseInt(left);
}
if (isStructuralType(type)) {
return sum(getStructuralTypeParts(type).map(getStructuralTypePartBits));
}
if (isStructType(type)) {
var typeData = Types.types[type];
return typeData.flatSize*8;
}
return 0;
}
function isIllegalType(type) {
var bits = getBits(type);
return bits > 0 && (bits >= 64 || !isPowerOfTwo(bits));
}
function isVoidType(type) {
return type == 'void';
}
// Detects a function definition, ([...|type,[type,...]])
function isFunctionDef(token, out) {
var text = token.text;
var nonPointing = removeAllPointing(text);
if (nonPointing[0] != '(' || nonPointing.substr(-1) != ')')
return false;
if (nonPointing === '()') return true;
if (!token.item) return false;
var fail = false;
var segments = splitTokenList(token.item.tokens);
segments.forEach(function(segment) {
var subtext = segment[0].text;
fail = fail || segment.length > 1 || !(isType(subtext) || subtext == '...');
});
if (out) {
out.segments = segments;
out.numArgs = segments.length;
}
return !fail;
}
function isPossiblyFunctionType(type) {
// A quick but unreliable way to see if something is a function type. Yes is just 'maybe', no is definite.
var len = type.length;
return type[len-2] == ')' && type[len-1] == '*';
}
function isFunctionType(type, out) {
if (!isPossiblyFunctionType(type)) return false;
type = type.replace(/"[^"]+"/g, '".."');
var parts;
// hackish, but quick splitting of function def parts. this must be fast as it happens a lot
if (type[0] != '[') {
parts = type.split(' ');
} else {
var index = type.search(']');
index += type.substr(index).search(' ');
parts = [type.substr(0, index), type.substr(index+1)];
}
if (pointingLevels(type) !== 1) return false;
var text = removeAllPointing(parts.slice(1).join(' '));
if (!text) return false;
if (out) out.returnType = parts[0];
return isType(parts[0]) && isFunctionDef({ text: text, item: tokenize(text.substr(1, text.length-2), true) }, out);
}
var isTypeCache = {}; // quite hot, optimize as much as possible
function isType(type) {
if (type in isTypeCache) return isTypeCache[type];
var ret = isPointerType(type) || isVoidType(type) || Runtime.isNumberType(type) || isStructType(type) || isFunctionType(type);
isTypeCache[type] = ret;
return ret;
}
function isVarArgsFunctionType(type) {
// assumes this is known to be a function type already
var varArgsSuffix = '...)*';
return type.substr(-varArgsSuffix.length) == varArgsSuffix;
}
function countNormalArgs(type) {
var out = {};
if (!isFunctionType(type, out)) return -1;
if (isVarArgsFunctionType(type)) out.numArgs--;
return out.numArgs;
}
function addIdent(token) {
token.ident = token.text;
return token;
}
function combineTokens(tokens) {
var ret = {
lineNum: tokens[0].lineNum,
text: '',
tokens: []
};
tokens.forEach(function(token) {
ret.text += token.text;
ret.tokens.push(token);
});
return ret;
}
function compareTokens(a, b) {
var aId = a.__uid__;
var bId = b.__uid__;
a.__uid__ = 0;
b.__uid__ = 0;
var ret = JSON.stringify(a) == JSON.stringify(b);
a.__uid__ = aId;
b.__uid__ = bId;
return ret;
}
function getTokenIndexByText(tokens, text) {
var i = 0;
while (tokens[i] && tokens[i].text != text) i++;
return i;
}
function findTokenText(item, text) {
return findTokenTextAfter(item, text, 0);
}
function findTokenTextAfter(item, text, startAt) {
for (var i = startAt; i < item.tokens.length; i++) {
if (item.tokens[i].text == text) return i;
}
return -1;
}
var SPLIT_TOKEN_LIST_SPLITTERS = set(',', 'to'); // 'to' can separate parameters as well...
// Splits a list of tokens separated by commas. For example, a list of arguments in a function call
function splitTokenList(tokens) {
if (tokens.length == 0) return [];
if (!tokens.slice) tokens = tokens.tokens;
if (tokens.slice(-1)[0].text != ',') tokens.push({text:','});
var ret = [];
var seg = [];
for (var i = 0; i < tokens.length; i++) {
var token = tokens[i];
if (token.text in SPLIT_TOKEN_LIST_SPLITTERS) {
ret.push(seg);
seg = [];
} else if (token.text == ';') {
ret.push(seg);
break;
} else {
seg.push(token);
}
}
return ret;
}
function parseParamTokens(params) {
if (params.length === 0) return [];
var ret = [];
if (params[params.length-1].text != ',') {
params.push({ text: ',' });
}
var anonymousIndex = 0;
while (params.length > 0) {
var i = 0;
while (params[i].text != ',') i++;
var segment = params.slice(0, i);
params = params.slice(i+1);
segment = cleanSegment(segment);
var byVal = 0;
if (segment[1] && segment[1].text === 'byval') {
// handle 'byval' and 'byval align X'. We store the alignment in 'byVal'
byVal = QUANTUM_SIZE;
segment.splice(1, 1);
if (segment[1] && segment[1].text === 'align') {
assert(isNumber(segment[2].text));
byVal = parseInt(segment[2].text);
segment.splice(1, 2);
}
}
if (segment.length == 1) {
if (segment[0].text == '...') {
ret.push({
intertype: 'varargs',
type: 'i8*',
ident: 'varrp' // the conventional name we have for this
});
} else {
// Clang sometimes has a parameter with just a type,
// no name... the name is implied to be %{the index}
ret.push({
intertype: 'value',
type: segment[0].text,
ident: toNiceIdent('%') + anonymousIndex
});
Types.needAnalysis[ret[ret.length-1].type] = 0;
anonymousIndex ++;
}
} else if (segment[1].text in PARSABLE_LLVM_FUNCTIONS) {
ret.push(parseLLVMFunctionCall(segment));
} else if (segment[1].text === 'blockaddress') {
ret.push(parseBlockAddress(segment));
} else {
if (segment[2] && segment[2].text == 'to') { // part of bitcast params
segment = segment.slice(0, 2);
}
while (segment.length > 2) {
segment[0].text += segment[1].text;
segment.splice(1, 1); // TODO: merge tokens nicely
}
ret.push({
intertype: 'value',
type: segment[0].text,
ident: toNiceIdent(parseNumerical(segment[1].text, segment[0].text))
});
Types.needAnalysis[removeAllPointing(ret[ret.length-1].type)] = 0;
}
ret[ret.length-1].byVal = byVal;
}
return ret;
}
function hasVarArgs(params) {
for (var i = 0; i < params.length; i++) {
if (params[i].intertype == 'varargs') {
return true;
}
}
return false;
}
var UNINDEXABLE_GLOBALS = set(
'_llvm_global_ctors' // special-cased
);
function isIndexableGlobal(ident) {
if (!(ident in Variables.globals)) return false;
if (ident in UNINDEXABLE_GLOBALS) {
Variables.globals[ident].unIndexable = true;
return false;
}
var data = Variables.globals[ident];
// in asm.js, externals are just globals
return !data.alias && (ASM_JS || !data.external);
}
function makeGlobalDef(ident) {
if (!NAMED_GLOBALS && isIndexableGlobal(ident)) return '';
return 'var ' + ident + ';';
}
function makeGlobalUse(ident) {
if (!NAMED_GLOBALS && isIndexableGlobal(ident)) {
var index = Variables.indexedGlobals[ident];
if (index === undefined) {
// we are accessing this before we index globals, likely from the library. mark as unindexable
UNINDEXABLE_GLOBALS[ident] = 1;
return ident;
}
// We know and assert on TOTAL_STACK being equal to GLOBAL_BASE
return (TOTAL_STACK + index).toString();
}
return ident;
}
function sortGlobals(globals) {
var ks = keys(globals);
ks.sort();
var inv = invertArray(ks);
return values(globals).sort(function(a, b) {
return inv[b.ident] - inv[a.ident];
});
}
function finalizeParam(param) {
if (param.intertype in PARSABLE_LLVM_FUNCTIONS) {
return finalizeLLVMFunctionCall(param);
} else if (param.intertype === 'blockaddress') {
return finalizeBlockAddress(param);
} else if (param.intertype === 'jsvalue') {
return param.ident;
} else {
if (param.type == 'i64' && USE_TYPED_ARRAYS == 2) {
return parseI64Constant(param.ident);
}
var ret = toNiceIdent(param.ident);
if (ret in Variables.globals) {
ret = makeGlobalUse(ret);
}
return ret;
}
}
// Segment ==> Parameter
function parseLLVMSegment(segment) {
var type;
if (segment.length == 1) {
if (isType(segment[0].text)) {
Types.needAnalysis[segment[0].text] = 0;
return {
intertype: 'type',
ident: toNiceIdent(segment[0].text),
type: segment[0].text
};
} else {
return {
intertype: 'value',
ident: toNiceIdent(segment[0].text),
type: 'i32'
};
}
} else if (segment[1].type && segment[1].type == '{') {
type = segment[0].text;
Types.needAnalysis[type] = 0;
return {
intertype: 'structvalue',
params: splitTokenList(segment[1].tokens).map(parseLLVMSegment),
type: type
};
} else if (segment[0].text in PARSABLE_LLVM_FUNCTIONS) {
return parseLLVMFunctionCall([{text: '?'}].concat(segment));
} else if (segment[1].text in PARSABLE_LLVM_FUNCTIONS) {
return parseLLVMFunctionCall(segment);
} else if (segment[1].text === 'blockaddress') {
return parseBlockAddress(segment);
} else {
type = segment[0].text;
Types.needAnalysis[type] = 0;
return {
intertype: 'value',
ident: toNiceIdent(segment[1].text),
type: type
};
}
}
function cleanSegment(segment) {
while (segment.length >= 2 && ['noalias', 'sret', 'nocapture', 'nest', 'zeroext', 'signext'].indexOf(segment[1].text) != -1) {
segment.splice(1, 1);
}
return segment;
}
var MATHOPS = set(['add', 'sub', 'sdiv', 'udiv', 'mul', 'icmp', 'zext', 'urem', 'srem', 'fadd', 'fsub', 'fmul', 'fdiv', 'fcmp', 'frem', 'uitofp', 'sitofp', 'fpext', 'fptrunc', 'fptoui', 'fptosi', 'trunc', 'sext', 'select', 'shl', 'shr', 'ashl', 'ashr', 'lshr', 'lshl', 'xor', 'or', 'and', 'ptrtoint', 'inttoptr']);
var PARSABLE_LLVM_FUNCTIONS = set('getelementptr', 'bitcast');
mergeInto(PARSABLE_LLVM_FUNCTIONS, MATHOPS);
// Parses a function call of form
// TYPE functionname MODIFIERS (...)
// e.g.
// i32* getelementptr inbounds (...)
function parseLLVMFunctionCall(segment) {
segment = segment.slice(0);
segment = cleanSegment(segment);
// Remove additional modifiers
var variant = null;
if (!segment[2] || !segment[2].item) {
variant = segment.splice(2, 1)[0];
if (variant && variant.text) variant = variant.text; // needed for mathops
}
assertTrue(['inreg', 'byval'].indexOf(segment[1].text) == -1);
assert(segment[1].text in PARSABLE_LLVM_FUNCTIONS);
while (!segment[2].item) {
segment.splice(2, 1); // Remove modifiers
if (!segment[2]) throw 'Invalid segment!';
}
var intertype = segment[1].text;
var type = segment[0].text;
if (type === '?') {
if (intertype === 'getelementptr') {
type = '*'; // a pointer, we can easily say, this is
} else if (segment[2].item.tokens.slice(-2)[0].text === 'to') {
type = segment[2].item.tokens.slice(-1)[0].text;
}
}
var ret = {
intertype: intertype,
variant: variant,
type: type,
params: parseParamTokens(segment[2].item.tokens)
};
Types.needAnalysis[ret.type] = 0;
ret.ident = toNiceIdent(ret.params[0].ident || 'NOIDENT');
return ret;
}
// Gets an array of tokens, we parse out the first
// 'ident' - either a simple ident of one token, or
// an LLVM internal function that generates an ident.
// We shift out of the array list the tokens that
// we ate.
function eatLLVMIdent(tokens) {
var ret;
if (tokens[0].text in PARSABLE_LLVM_FUNCTIONS) {
ret = parseLLVMFunctionCall([{text: 'i0'}].concat(tokens.slice(0,2))).ident; // TODO: Handle more cases, return a full object, process it later
tokens.shift();
tokens.shift();
} else {
ret = tokens[0].text;
tokens.shift();
}
return ret;
}
function cleanOutTokens(filterOut, tokens, indexes) {
if (typeof indexes !== 'object') indexes = [indexes];
for (var i = indexes.length-1; i >=0; i--) {
var index = indexes[i];
while (tokens[index].text in filterOut) {
tokens.splice(index, 1);
}
}
}
function _IntToHex(x) {
assert(x >= 0 && x <= 15);
if (x <= 9) {
return String.fromCharCode('0'.charCodeAt(0) + x);
} else {
return String.fromCharCode('A'.charCodeAt(0) + x - 10);
}
}
function IEEEUnHex(stringy) {
stringy = stringy.substr(2); // leading '0x';
if (stringy.replace(/0/g, '') === '') return 0;
while (stringy.length < 16) stringy = '0' + stringy;
if (FAKE_X86_FP80 && stringy.length > 16) {
stringy = stringy.substr(stringy.length-16, 16);
warnOnce('.ll contains floating-point values with more than 64 bits. Faking values for them. If they are used, this will almost certainly break horribly!');
}
assert(stringy.length === 16, 'Can only unhex 16-digit double numbers, nothing platform-specific'); // |long double| can cause x86_fp80 which causes this
var top = eval('0x' + stringy[0]);
var neg = !!(top & 8); // sign
if (neg) {
stringy = _IntToHex(top & ~8) + stringy.substr(1);
}
var a = eval('0x' + stringy.substr(0, 8)); // top half
var b = eval('0x' + stringy.substr(8)); // bottom half
var e = a >> ((52 - 32) & 0x7ff); // exponent
a = a & 0xfffff;
if (e === 0x7ff) {
if (a == 0 && b == 0) {
return neg ? '-Infinity' : 'Infinity';
} else {
return 'NaN';
}
}
e -= 1023; // offset
var absolute = ((((a | 0x100000) * 1.0) / Math.pow(2,52-32)) * Math.pow(2, e)) + (((b * 1.0) / Math.pow(2, 52)) * Math.pow(2, e));
return (absolute * (neg ? -1 : 1)).toString();
}
// 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, true)) {
expression = tempVar + '=' + value + ',' + expression;
value = tempVar;
}
return '(' + expression.replace(/VALUE/g, value) + ')';
}
// Makes a proper runtime value for a 64-bit value from low and high i32s. low and high are assumed to be unsigned.
function makeI64(low, high) {
high = high || '0';
if (USE_TYPED_ARRAYS == 2) {
return '[' + makeSignOp(low, 'i32', 'un', 1, 1) + ',' + makeSignOp(high, 'i32', 'un', 1, 1) + ']';
} else {
if (high) return RuntimeGenerator.makeBigInt(low, high);
return low;
}
}
// XXX Make all i64 parts signed
// Splits a number (an integer in a double, possibly > 32 bits) into an USE_TYPED_ARRAYS == 2 i64 value.
// Will suffer from rounding. mergeI64 does the opposite.
function splitI64(value) {
// We need to min 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.
if (legalizedI64s) {
return [value + '>>>0', 'Math.min(Math.floor((' + value + ')/4294967296), 4294967295)'];
} else {
return makeInlineCalculation(makeI64('VALUE>>>0', 'Math.min(Math.floor(VALUE/4294967296), 4294967295)'), value, 'tempBigIntP');
}
}
function mergeI64(value, unsigned) {
assert(USE_TYPED_ARRAYS == 2);
if (legalizedI64s) {
return RuntimeGenerator.makeBigInt(value + '$0', value + '$1', unsigned);
} else {
return makeInlineCalculation(RuntimeGenerator.makeBigInt('VALUE[0]', 'VALUE[1]', unsigned), value, 'tempI64');
}
}
// Takes an i64 value and changes it into the [low, high] form used in i64 mode 1. In that
// mode, this is a no-op
function ensureI64_1(value) {
if (USE_TYPED_ARRAYS == 2) return value;
return splitI64(value, 1);
}
function makeCopyI64(value) {
assert(USE_TYPED_ARRAYS == 2);
return value + '.slice(0)';
}
// Given a string representation of an integer of arbitrary size, return it
// split up into 32-bit chunks
function parseArbitraryInt(str, bits) {
// We parse the string into a vector of digits, base 10. This is convenient to work on.
assert(bits % 32 == 0 || ('i' + (bits % 32)) in Runtime.INT_TYPES, 'Arbitrary-sized ints must tails that are of legal size');
function str2vec(s) { // index 0 is the highest value
var ret = [];
for (var i = 0; i < s.length; i++) {
ret.push(s.charCodeAt(i) - '0'.charCodeAt(0));
}
return ret;
}
function divide2(v) { // v /= 2
for (var i = v.length-1; i >= 0; i--) {
var d = v[i];
var r = d % 2;
d = Math.floor(d/2);
v[i] = d;
if (r) {
assert(i+1 < v.length);
var d2 = v[i+1];
d2 += 5;
if (d2 >= 10) {
v[i] = d+1;
d2 -= 10;
}
v[i+1] = d2;
}
}
}
function mul2(v) { // v *= 2
for (var i = v.length-1; i >= 0; i--) {
var d = v[i]*2;
r = d >= 10;
v[i] = d%10;
var j = i-1;
if (r) {
if (j < 0) {
v.unshift(1);
break;
}
v[j] += 0.5; // will be multiplied
}
}
}
function subtract(v, w) { // v -= w. we assume v >= w
while (v.length > w.length) w.splice(0, 0, 0);
for (var i = 0; i < v.length; i++) {
v[i] -= w[i];
if (v[i] < 0) {
v[i] += 10;
// find something to take from
var j = i-1;
while (v[j] == 0) {
v[j] = 9;
j--;
assert(j >= 0);
}
v[j]--;
}
}
}
function isZero(v) {
for (var i = 0; i < v.length; i++) {
if (v[i] > 0) return false;
}
return true;
}
var v;
if (str[0] == '-') {
// twos-complement is needed
str = str.substr(1);
v = str2vec('1');
for (var i = 0; i < bits; i++) {
mul2(v);
}
subtract(v, str2vec(str));
} else {
v = str2vec(str);
}
var bitsv = [];
while (!isZero(v)) {
bitsv.push((v[v.length-1] % 2 != 0)+0);
v[v.length-1] = v[v.length-1] & 0xfe;
divide2(v);
}
var ret = zeros(Math.ceil(bits/32));
for (var i = 0; i < bitsv.length; i++) {
ret[Math.floor(i/32)] += bitsv[i]*Math.pow(2, i % 32);
}
return ret;
}
function parseI64Constant(str, legalized) {
if (!isNumber(str)) {
// This is a variable. Copy it, so we do not modify the original
return legalizedI64s ? str : makeCopyI64(str);
}
var parsed = parseArbitraryInt(str, 64);
if (legalizedI64s || legalized) return parsed;
return '[' + parsed[0] + ',' + parsed[1] + ']';
}
function parseNumerical(value, type) {
if ((!type || type == 'double' || type == 'float') && (value.substr && value.substr(0,2) == '0x')) {
// Hexadecimal double value, as the llvm docs say,
// "The one non-intuitive notation for constants is the hexadecimal form of floating point constants."
value = IEEEUnHex(value);
} else if (USE_TYPED_ARRAYS == 2 && isIllegalType(type)) {
return value; // do not parseFloat etc., that can lead to loss of precision
} else if (value == 'null') {
// NULL *is* 0, in C/C++. No JS null! (null == 0 is false, etc.)
value = '0';
} else if (value === 'true') {
return '1';
} else if (value === 'false') {
return '0';
}
if (isNumber(value)) {
return parseFloat(value).toString(); // will change e.g. 5.000000e+01 to 50
} else {
return value;
}
}
// \0Dsometext is really '\r', then sometext
// This function returns an array of int values
function parseLLVMString(str) {
var ret = [];
var i = 0;
while (i < str.length) {
var chr = str[i];
if (chr != '\\') {
ret.push(chr.charCodeAt(0));
i++;
} else {
ret.push(eval('0x' + str[i+1]+str[i+2]));
i += 3;
}
}
return ret;
}
function getLabelIds(labels) {
return labels.map(function(label) { return label.ident });
}
function cleanLabel(label) {
if (label[0] == 'B') {
return label.substr(5);
} else {
return label;
}
}
function getOldLabel(label) {
var parts = label.split('|');
return parts[parts.length-1];
}
function calcAllocatedSize(type) {
if (pointingLevels(type) == 0 && isStructType(type)) {
return Types.types[type].flatSize; // makeEmptyStruct(item.allocatedType).length;
} else {
return Runtime.getNativeTypeSize(type); // We can really get away with '1', though, at least on the stack...
}
}
// Generates the type signature for a structure, for each byte, the type that is there.
// i32, 0, 0, 0 - for example, an int32 is here, then nothing to do for the 3 next bytes, naturally
function generateStructTypes(type) {
if (isArray(type)) return type; // already in the form of [type, type,...]
if (Runtime.isNumberType(type) || isPointerType(type)) {
if (USE_TYPED_ARRAYS == 2 && type == 'i64') {
return ['i64', 0, 0, 0, 'i32', 0, 0, 0];
}
return [type].concat(zeros(Runtime.getNativeFieldSize(type)-1));
}
// Avoid multiple concats by finding the size first. This is much faster
var typeData = Types.types[type];
var size = typeData.flatSize;
var ret = new Array(size);
var index = 0;
function add(typeData) {
var start = index;
for (var i = 0; i < typeData.fields.length; i++) {
var type = typeData.fields[i];
if (!SAFE_HEAP && isPointerType(type)) type = '*'; // do not include unneeded type names without safe heap
if (Runtime.isNumberType(type) || isPointerType(type)) {
if (USE_TYPED_ARRAYS == 2 && type == 'i64') {
ret[index++] = 'i64';
ret[index++] = 0;
ret[index++] = 0;
ret[index++] = 0;
ret[index++] = 'i32';
ret[index++] = 0;
ret[index++] = 0;
ret[index++] = 0;
continue;
}
ret[index++] = type;
} else {
add(Types.types[type]);
}
var more = (i+1 < typeData.fields.length ? typeData.flatIndexes[i+1] : typeData.flatSize) - (index - start);
for (var j = 0; j < more; j++) {
ret[index++] = 0;
}
}
}
add(typeData);
assert(index == size);
return ret;
}
// Flow blocks
function recurseBlock(block, func) {
var ret = [];
if (block.type == 'reloop') {
ret.push(func(block.inner));
} else if (block.type == 'multiple') {
block.entryLabels.forEach(function(entryLabel) { ret.push(func(entryLabel.block)) });
}
ret.push(func(block.next));
return ret;
}
function getActualLabelId(labelId) {
return labelId.split('|').slice(-1)[0];
}
// Misc
function indentify(text, indent) {
if (text.length > 1024*1024) return text; // Don't try to indentify huge strings - we may run out of memory
if (typeof indent === 'number') {
var len = indent;
indent = '';
for (var i = 0; i < len; i++) indent += ' ';
}
return text.replace(/\n/g, '\n' + indent);
}
// Correction tools
function correctSpecificSign() {
if (!Framework.currItem) return false;
if (Framework.currItem.funcData.ident.indexOf('emscripten_autodebug') >= 0) return 1; // always correct in the autodebugger code!
return (CORRECT_SIGNS === 2 && Debugging.getIdentifier() in CORRECT_SIGNS_LINES) ||
(CORRECT_SIGNS === 3 && !(Debugging.getIdentifier() in CORRECT_SIGNS_LINES));
}
function correctSigns() {
return CORRECT_SIGNS === 1 || correctSpecificSign();
}
function correctSpecificOverflow() {
if (!Framework.currItem) return false;
return (CORRECT_OVERFLOWS === 2 && Debugging.getIdentifier() in CORRECT_OVERFLOWS_LINES) ||
(CORRECT_OVERFLOWS === 3 && !(Debugging.getIdentifier() in CORRECT_OVERFLOWS_LINES));
}
function correctOverflows() {
return CORRECT_OVERFLOWS === 1 || correctSpecificOverflow();
}
function correctSpecificRounding() {
if (!Framework.currItem) return false;
return (CORRECT_ROUNDINGS === 2 && Debugging.getIdentifier() in CORRECT_ROUNDINGS_LINES) ||
(CORRECT_ROUNDINGS === 3 && !(Debugging.getIdentifier() in CORRECT_ROUNDINGS_LINES));
}
function correctRoundings() {
return CORRECT_ROUNDINGS === 1 || correctSpecificRounding();
}
function checkSpecificSafeHeap() {
if (!Framework.currItem) return false;
return (SAFE_HEAP === 2 && Debugging.getIdentifier() in SAFE_HEAP_LINES) ||
(SAFE_HEAP === 3 && !(Debugging.getIdentifier() in SAFE_HEAP_LINES));
}
function checkSafeHeap() {
return SAFE_HEAP === 1 || checkSpecificSafeHeap();
}
if (ASM_JS) {
var hexMemoryMask = '0x' + (TOTAL_MEMORY-1).toString(16);
var decMemoryMask = (TOTAL_MEMORY-1).toString();
var memoryMask = hexMemoryMask.length <= decMemoryMask.length ? hexMemoryMask : decMemoryMask;
}
function getHeapOffset(offset, type, forceAsm) {
if (USE_TYPED_ARRAYS !== 2) {
return offset;
} else {
if (Runtime.getNativeFieldSize(type) > 4) {
type = 'i32'; // XXX we emulate 64-bit values as 32
}
var shifts = Math.log(Runtime.getNativeTypeSize(type))/Math.LN2;
offset = '(' + offset + ')';
if (ASM_JS && (phase == 'funcs' || forceAsm)) offset = '(' + offset + '&' + memoryMask + ')';
if (shifts != 0) {
return '(' + offset + '>>' + shifts + ')';
} else {
return offset;
}
}
}
function makeVarDef(js) {
if (!ASM_JS) js = 'var ' + js;
return js;
}
function asmEnsureFloat(value, type) { // ensures that a float type has either 5.5 (clearly a float) or +5 (float due to asm coercion)
if (!ASM_JS) return value;
if (type in Runtime.FLOAT_TYPES && isNumber(value) && value.toString().indexOf('.') < 0) {
return '(+(' + value + '))';
} else {
return value;
}
}
function asmInitializer(type, impl) {
if (type in Runtime.FLOAT_TYPES) {
return '+0';
} else {
return '0';
}
}
function asmCoercion(value, type, signedness) {
if (!ASM_JS) return value;
if (type == 'void') {
return value;
} else if (type in Runtime.FLOAT_TYPES) {
if (isNumber(value)) {
return asmEnsureFloat(value, type);
} else {
if (signedness) {
if (signedness == 'u') {
value = '(' + value + ')>>>0';
} else {
value = '(' + value + ')|0';
}
}
return '(+(' + value + '))';
}
} else {
return '((' + value + ')|0)';
}
}
function asmMultiplyI32(a, b) {
// special-case: there is no integer multiply in asm, because there is no true integer
// multiply in JS. While we wait for Math.imul, do double multiply
if (USE_MATH_IMUL) {
return 'Math.imul(' + a + ',' + b + ')';
}
return '(~~(+((' + a + ')|0) * +((' + b + ')|0)))';
}
function makeGetTempDouble(i, type, forSet) { // get an aliased part of the tempDouble temporary storage
// Cannot use makeGetValue because it uses us
// this is a unique case where we *can* use HEAPF64
var slab = type == 'double' ? 'HEAPF64' : makeGetSlabs(null, type)[0];
var ptr = getFastValue('tempDoublePtr', '+', Runtime.getNativeTypeSize(type)*i);
var offset;
if (type == 'double') {
if (ASM_JS) ptr = '(' + ptr + ')&' + memoryMask;
offset = '(' + ptr + ')>>3';
} else {
offset = getHeapOffset(ptr, type);
}
var ret = slab + '[' + offset + ']';
if (!forSet) ret = asmCoercion(ret, type);
return ret;
}
function makeSetTempDouble(i, type, value) {
return makeGetTempDouble(i, type, true) + '=' + asmEnsureFloat(value, type);
}
// See makeSetValue
function makeGetValue(ptr, pos, type, noNeedFirst, unsigned, ignore, align, noSafe, forceAsm) {
if (UNALIGNED_MEMORY) align = 1;
if (isStructType(type)) {
var typeData = Types.types[type];
var ret = [];
for (var i = 0; i < typeData.fields.length; i++) {
ret.push('f' + i + ': ' + makeGetValue(ptr, pos + typeData.flatIndexes[i], typeData.fields[i], noNeedFirst, unsigned));
}
return '{ ' + ret.join(', ') + ' }';
}
if (DOUBLE_MODE == 1 && USE_TYPED_ARRAYS == 2 && type == 'double') {
return '(' + makeSetTempDouble(0, 'i32', makeGetValue(ptr, pos, 'i32', noNeedFirst, unsigned, ignore, align)) + ',' +
makeSetTempDouble(1, 'i32', makeGetValue(ptr, getFastValue(pos, '+', Runtime.getNativeTypeSize('i32')), 'i32', noNeedFirst, unsigned, ignore, align)) + ',' +
makeGetTempDouble(0, 'double') + ')';
}
if (USE_TYPED_ARRAYS == 2 && align) {
// Alignment is important here. May need to split this up
var bytes = Runtime.getNativeTypeSize(type);
if (bytes > align) {
var ret = '(';
if (isIntImplemented(type)) {
if (bytes == 4 && align == 2) {
// Special case that we can optimize
ret += makeGetValue(ptr, pos, 'i16', noNeedFirst, 2, ignore) + '+' +
'(' + makeGetValue(ptr, getFastValue(pos, '+', 2), 'i16', noNeedFirst, 2, ignore) + '<<16)';
} else { // XXX we cannot truly handle > 4...
ret = '';
for (var i = 0; i < bytes; i++) {
ret += '(' + makeGetValue(ptr, getFastValue(pos, '+', i), 'i8', noNeedFirst, 1, ignore) + (i > 0 ? '<<' + (8*i) : '') + ')';
if (i < bytes-1) ret += '|';
}
ret = '(' + makeSignOp(ret, type, unsigned ? 'un' : 're', true);
}
} else {
if (type == 'float') {
ret += 'copyTempFloat(' + getFastValue(ptr, '+', pos) + '),' + makeGetTempDouble(0, 'float');
} else {
ret += 'copyTempDouble(' + getFastValue(ptr, '+', pos) + '),' + makeGetTempDouble(0, 'double');
}
}
ret += ')';
return ret;
}
}
var offset = calcFastOffset(ptr, pos, noNeedFirst);
if (SAFE_HEAP && !noSafe) {
if (type !== 'null' && type[0] !== '#') type = '"' + safeQuote(type) + '"';
if (type[0] === '#') type = type.substr(1);
return 'SAFE_HEAP_LOAD(' + offset + ', ' + type + ', ' + (!!unsigned+0) + ', ' + ((!checkSafeHeap() || ignore)|0) + ')';
} else {
var ret = makeGetSlabs(ptr, type, false, unsigned)[0] + '[' + getHeapOffset(offset, type, forceAsm) + ']';
if (ASM_JS && phase == 'funcs') {
ret = asmCoercion(ret, type);
}
return ret;
}
}
function makeGetValueAsm(ptr, pos, type) {
return makeGetValue(ptr, pos, type, null, null, null, null, null, true);
}
function indexizeFunctions(value, type) {
assert((type && type !== '?') || (typeof value === 'string' && value.substr(0, 6) === 'CHECK_'), 'No type given for function indexizing');
assert(value !== type, 'Type set to value');
var out = {};
if (type && isFunctionType(type, out) && value[0] === '_') { // checking for _ differentiates from $ (local vars)
// add signature to library functions that we now know need indexing
if (!(value in Functions.implementedFunctions) && !(value in Functions.unimplementedFunctions)) {
Functions.unimplementedFunctions[value] = Functions.getSignature(out.returnType, out.segments ? out.segments.map(function(segment) { return segment[0].text }) : []);
}
if (BUILD_AS_SHARED_LIB) {
return '(FUNCTION_TABLE_OFFSET + ' + Functions.getIndex(value) + ')';
} else {
return Functions.getIndex(value);
}
}
return value;
}
//! @param 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 pos The position in that slab - the offset. Added to any offset in the pointer itself.
//! @param value The value to set.
//! @param type A string defining the type. Used to find the slab (IHEAP, FHEAP, etc.).
//! 'null' means, in the context of SAFE_HEAP, that we should accept all types;
//! which means we should write to all slabs, ignore type differences if any on reads, etc.
//! @param noNeedFirst Whether to ignore the offset in the pointer itself.
function makeSetValue(ptr, pos, value, type, noNeedFirst, ignore, align, noSafe, sep, forcedAlign) {
if (UNALIGNED_MEMORY && !forcedAlign) align = 1;
sep = sep || ';';
if (isStructType(type)) {
var typeData = Types.types[type];
var ret = [];
// We can receive either an object - an object literal that was in the .ll - or a string,
// which is the ident of an aggregate struct
if (typeof value === 'string') {
value = range(typeData.fields.length).map(function(i) { return value + '.f' + i });
}
for (var i = 0; i < typeData.fields.length; i++) {
ret.push(makeSetValue(ptr, getFastValue(pos, '+', typeData.flatIndexes[i]), value[i], typeData.fields[i], noNeedFirst));
}
return ret.join('; ');
}
if (DOUBLE_MODE == 1 && USE_TYPED_ARRAYS == 2 && type == 'double') {
return '(' + makeSetTempDouble(0, 'double', value) + ',' +
makeSetValue(ptr, pos, makeGetTempDouble(0, 'i32'), 'i32', noNeedFirst, ignore, align, noSafe, ',') + ',' +
makeSetValue(ptr, getFastValue(pos, '+', Runtime.getNativeTypeSize('i32')), makeGetTempDouble(1, 'i32'), 'i32', noNeedFirst, ignore, align, noSafe, ',') + ')';
} else if (USE_TYPED_ARRAYS == 2 && type == 'i64') {
return '(tempI64 = [' + splitI64(value) + '],' +
makeSetValue(ptr, pos, 'tempI64[0]', 'i32', noNeedFirst, ignore, align, noSafe, ',') + ',' +
makeSetValue(ptr, getFastValue(pos, '+', Runtime.getNativeTypeSize('i32')), 'tempI64[1]', 'i32', noNeedFirst, ignore, align, noSafe, ',') + ')';
}
var bits = getBits(type);
var needSplitting = bits > 0 && !isPowerOfTwo(bits); // an unnatural type like i24
if (USE_TYPED_ARRAYS == 2 && (align || needSplitting)) {
// Alignment is important here, or we need to split this up for other reasons.
var bytes = Runtime.getNativeTypeSize(type);
if (bytes > align || needSplitting) {
var ret = '';
if (isIntImplemented(type)) {
if (bytes == 4 && align == 2) {
// Special case that we can optimize
ret += 'tempBigInt=' + value + sep;
ret += makeSetValue(ptr, pos, 'tempBigInt&0xffff', 'i16', noNeedFirst, ignore, 2) + sep;
ret += makeSetValue(ptr, getFastValue(pos, '+', 2), 'tempBigInt>>16', 'i16', noNeedFirst, ignore, 2);
} else {
ret += 'tempBigInt=' + value + sep;
for (var i = 0; i < bytes; i++) {
ret += makeSetValue(ptr, getFastValue(pos, '+', i), 'tempBigInt&0xff', 'i8', noNeedFirst, ignore, 1);
if (i < bytes-1) ret += sep + 'tempBigInt = tempBigInt>>8' + sep;
}
}
} else {
ret += makeSetValue('tempDoublePtr', 0, value, type, noNeedFirst, ignore, 8, null, null, true) + sep;
ret += makeCopyValues(getFastValue(ptr, '+', pos), 'tempDoublePtr', Runtime.getNativeTypeSize(type), type, null, align, sep);
}
return ret;
}
}
value = indexizeFunctions(value, type);
var offset = calcFastOffset(ptr, pos, noNeedFirst);
if (SAFE_HEAP && !noSafe) {
if (type !== 'null' && type[0] !== '#') type = '"' + safeQuote(type) + '"';
if (type[0] === '#') type = type.substr(1);
return 'SAFE_HEAP_STORE(' + offset + ', ' + value + ', ' + type + ', ' + ((!checkSafeHeap() || ignore)|0) + ')';
} else {
return makeGetSlabs(ptr, type, true).map(function(slab) { return slab + '[' + getHeapOffset(offset, type) + ']=' + value }).join(sep);
//return '(print("set:"+(' + value + ')+":"+(' + getHeapOffset(offset, type) + ')),' +
// makeGetSlabs(ptr, type, true).map(function(slab) { return slab + '[' + getHeapOffset(offset, type) + ']=' + value }).join('; ') + ')';
}
}
var SEEK_OPTIMAL_ALIGN_MIN = 20;
var UNROLL_LOOP_MAX = 8;
function makeSetValues(ptr, pos, value, type, num, align) {
function unroll(type, num, jump, value$) {
jump = jump || 1;
value$ = value$ || value;
return range(num).map(function(i) {
return makeSetValue(ptr, getFastValue(pos, '+', i*jump), value$, type);
}).join('; ');
}
if (USE_TYPED_ARRAYS <= 1) {
if (isNumber(num) && parseInt(num) <= UNROLL_LOOP_MAX) {
return unroll(type, num);
}
return 'for (var $$dest = ' + getFastValue(ptr, '+', pos) + ', $$stop = $$dest + ' + num + '; $$dest < $$stop; $$dest++) {\n' +
makeSetValue('$$dest', '0', value, type) + '\n}';
} else { // USE_TYPED_ARRAYS == 2
// If we don't know how to handle this at compile-time, or handling it is best done in a large amount of code, call memset
// TODO: optimize the case of numeric num but non-numeric value
if (!isNumber(num) || !isNumber(value) || (align < 4 && parseInt(num) >= SEEK_OPTIMAL_ALIGN_MIN)) {
return '_memset(' + getFastValue(ptr, '+', pos) + ', ' + value + ', ' + num + ', ' + align + ')';
}
num = parseInt(num);
value = parseInt(value);
if (value < 0) value += 256; // make it unsigned
var values = {
1: value,
2: value | (value << 8),
4: value | (value << 8) | (value << 16) | (value << 24)
};
var ret = [];
[4, 2, 1].forEach(function(possibleAlign) {
if (num == 0) return;
if (align >= possibleAlign) {
if (num <= UNROLL_LOOP_MAX*possibleAlign || ASM_JS) { // XXX test asm performance
ret.push(unroll('i' + (possibleAlign*8), Math.floor(num/possibleAlign), possibleAlign, values[possibleAlign]));
} else {
ret.push('for (var $$dest = ' + getFastValue(ptr, '+', pos) + (possibleAlign > 1 ? '>>' + log2(possibleAlign) : '') + ', ' +
'$$stop = $$dest + ' + Math.floor(num/possibleAlign) + '; $$dest < $$stop; $$dest++) {\n' +
' HEAP' + (possibleAlign*8) + '[$$dest] = ' + values[possibleAlign] + '\n}');
}
pos = getFastValue(pos, '+', Math.floor(num/possibleAlign)*possibleAlign);
num %= possibleAlign;
}
});
return ret.join('; ');
}
}
var TYPED_ARRAY_SET_MIN = Infinity; // .set() as memcpy seems to just slow us down
function makeCopyValues(dest, src, num, type, modifier, align, sep) {
sep = sep || ';';
function unroll(type, num, jump) {
jump = jump || 1;
return range(num).map(function(i) {
if (USE_TYPED_ARRAYS <= 1 && type === 'null') {
// Null is special-cased: We copy over all heaps
return makeGetSlabs(dest, 'null', true).map(function(slab) {
return slab + '[' + getFastValue(dest, '+', i) + ']=' + slab + '[' + getFastValue(src, '+', i) + ']';
}).join(sep) + (SAFE_HEAP ? sep + 'SAFE_HEAP_COPY_HISTORY(' + getFastValue(dest, '+', i) + ', ' + getFastValue(src, '+', i) + ')' : '');
} else {
return makeSetValue(dest, i*jump, makeGetValue(src, i*jump, type), type);
}
}).join(sep);
}
if (USE_TYPED_ARRAYS <= 1) {
if (isNumber(num) && parseInt(num) <= UNROLL_LOOP_MAX) {
return unroll(type, num);
}
var oldDest = dest, oldSrc = src;
dest = '$$dest';
src = '$$src';
return 'for (var $$src = ' + oldSrc + ', $$dest = ' + oldDest + ', $$stop = $$src + ' + num + '; $$src < $$stop; $$src++, $$dest++) {\n' +
unroll(type, 1) + ' }';
} else { // USE_TYPED_ARRAYS == 2
// If we don't know how to handle this at compile-time, or handling it is best done in a large amount of code, call memset
if (!isNumber(num) || (align < 4 && parseInt(num) >= SEEK_OPTIMAL_ALIGN_MIN)) {
return '_memcpy(' + dest + ', ' + src + ', ' + num + ')';
}
num = parseInt(num);
var ret = [];
[4, 2, 1].forEach(function(possibleAlign) {
if (num == 0) return;
if (align >= possibleAlign) {
// If we can unroll the loop, do so. Also do so if we must unroll it (we do not create real loops when inlined)
if (num <= UNROLL_LOOP_MAX*possibleAlign || sep == ',' || ASM_JS) { // XXX test asm performance
ret.push(unroll('i' + (possibleAlign*8), Math.floor(num/possibleAlign), possibleAlign));
} else {
assert(sep == ';');
ret.push('for (var $$src = ' + src + (possibleAlign > 1 ? '>>' + log2(possibleAlign) : '') + ', ' +
'$$dest = ' + dest + (possibleAlign > 1 ? '>>' + log2(possibleAlign) : '') + ', ' +
'$$stop = $$src + ' + Math.floor(num/possibleAlign) + '; $$src < $$stop; $$src++, $$dest++) {\n' +
' HEAP' + (possibleAlign*8) + '[$$dest] = HEAP' + (possibleAlign*8) + '[$$src]\n}');
}
src = getFastValue(src, '+', Math.floor(num/possibleAlign)*possibleAlign);
dest = getFastValue(dest, '+', Math.floor(num/possibleAlign)*possibleAlign);
num %= possibleAlign;
}
});
return ret.join(sep);
}
}
function makeHEAPView(which, start, end) {
// Assumes USE_TYPED_ARRAYS == 2
var size = parseInt(which.replace('U', '').replace('F', ''))/8;
var mod = size == 1 ? '' : ('>>' + log2(size));
return 'HEAP' + which + '.subarray((' + start + ')' + mod + ',(' + end + ')' + mod + ')';
}
var PLUS_MUL = set('+', '*');
var MUL_DIV = set('*', '/');
var PLUS_MINUS = set('+', '-');
// 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, type) {
a = a.toString();
b = b.toString();
if (isNumber(a) && isNumber(b)) {
if (op == 'pow') {
return Math.pow(a, b).toString();
} else {
return eval(a + op + '(' + b + ')').toString(); // parens protect us from "5 - -12" being seen as "5--12" which is "(5--)12"
}
}
if (op == 'pow') {
if (a == '2' && isIntImplemented(type)) {
return '(1 << (' + b + '))';
}
return 'Math.pow(' + a + ', ' + b + ')';
}
if (op in PLUS_MUL && isNumber(a)) { // if one of them is a number, keep it last
var c = b;
b = a;
a = c;
}
if (op in MUL_DIV) {
if (op == '*') {
if (a == 0 || b == 0) {
return '0';
} else if (a == 1) {
return b;
} else if (b == 1) {
return a;
} else if (isNumber(b) && type && isIntImplemented(type) && Runtime.getNativeTypeSize(type) <= 32) {
var shifts = Math.log(parseFloat(b))/Math.LN2;
if (shifts % 1 == 0) {
return '(' + a + '<<' + shifts + ')';
}
}
if (ASM_JS && !(type in Runtime.FLOAT_TYPES)) {
return asmMultiplyI32(a, b); // unoptimized multiply, do it using asm.js's special multiply operation
}
} else {
if (a == '0') {
return '0';
} else if (b == 1) {
return a;
} // Doing shifts for division is problematic, as getting the rounding right on negatives is tricky
}
} else if (op in PLUS_MINUS) {
if (b[0] == '-') {
op = op == '+' ? '-' : '+';
b = b.substr(1);
}
if (a == 0) {
return op == '+' ? b : '(-' + b + ')';
} else if (b == 0) {
return a;
}
}
return '(' + a + ')' + op + '(' + b + ')';
}
function getFastValues(list, op, type) {
assert(op == '+');
var changed = true;
while (changed) {
changed = false;
for (var i = 0; i < list.length-1; i++) {
var fast = getFastValue(list[i], op, list[i+1], type);
var raw = list[i] + op + list[i+1];
if (fast.length < raw.length || fast.indexOf(op) < 0) {
list[i] = fast;
list.splice(i+1, 1);
i--;
changed = true;
break;
}
}
}
if (list.length == 1) return list[0];
return list.reduce(function(a, b) { return a + op + b });
}
function calcFastOffset(ptr, pos, noNeedFirst) {
var offset = noNeedFirst ? '0' : makeGetPos(ptr);
return getFastValue(offset, '+', pos, 'i32');
}
function makeGetPos(ptr) {
return ptr;
}
var IHEAP_FHEAP = set('IHEAP', 'IHEAPU', 'FHEAP');
function makePointer(slab, pos, allocator, type, ptr) {
assert(type, 'makePointer requires type info');
if (slab.substr(0, 4) === 'HEAP' || (USE_TYPED_ARRAYS == 1 && slab in IHEAP_FHEAP)) return pos;
var types = generateStructTypes(type);
// compress type info and data if possible
var de;
try {
// compress all-zeros into a number (which will become zeros(..)).
// note that we cannot always eval the slab, e.g., if it contains ident,0,0 etc. In that case, no compression TODO: ensure we get arrays here, not str
var evaled = typeof slab === 'string' ? eval(slab) : slab;
de = dedup(evaled);
if (de.length === 1 && de[0] === 0) {
slab = types.length;
if (USE_TYPED_ARRAYS == 2) {
types = ['i8']; // if data is zeros, we don't need type info
}
}
// TODO: if not all zeros, at least filter out items with type === 0. requires cleverness to know how to skip at runtime though. also
// be careful of structure padding
} catch(e){}
de = dedup(types);
if (de.length === 1) {
types = de[0];
} else if (de.length === 2 && typeof slab === 'number') {
// If slab is all zeros, we can compress types even if we have i32,0,0,0,i32,0,0,0 etc. - we do not need the zeros
de = de.filter(function(x) { return x !== 0 });
if (de.length === 1) {
types = de[0];
}
}
// JS engines sometimes say array initializers are too large. Work around that by chunking and calling concat to combine at runtime
var chunkSize = 10240;
function chunkify(array) {
// break very large slabs into parts
var ret = '';
var index = 0;
while (index < array.length) {
ret = (ret ? ret + '.concat(' : '') + '[' + array.slice(index, index + chunkSize).map(JSON.stringify) + ']' + (ret ? ')' : '');
index += chunkSize;
}
return ret;
}
if (typeof slab == 'string' && evaled && evaled.length > chunkSize) {
slab = chunkify(evaled);
}
if (typeof types != 'string' && types.length > chunkSize) {
types = chunkify(types);
} else {
types = JSON.stringify(types);
}
return 'allocate(' + slab + ', ' + types + (allocator ? ', ' + allocator : '') + (allocator == 'ALLOC_NONE' ? ', ' + ptr : '') + ')';
}
function makeGetSlabs(ptr, type, allowMultiple, unsigned) {
assert(type);
if (!USE_TYPED_ARRAYS) {
return ['HEAP'];
} else if (USE_TYPED_ARRAYS == 1) {
if (type in Runtime.FLOAT_TYPES || type === 'int64') { // XXX should be i64, no?
return ['FHEAP']; // If USE_FHEAP is false, will fail at runtime. At compiletime we do need it for library stuff.
} else if (type in Runtime.INT_TYPES || isPointerType(type)) {
return [unsigned ? 'IHEAPU' : 'IHEAP'];
} else {
assert(allowMultiple, 'Unknown slab type and !allowMultiple: ' + type);
if (USE_FHEAP) {
return ['IHEAP', 'FHEAP']; // unknown, so assign to both typed arrays
} else {
return ['IHEAP'];
}
}
} else { // USE_TYPED_ARRAYS == 2)
if (isPointerType(type)) type = 'i32'; // Hardcoded 32-bit
switch(type) {
case 'i1': case 'i8': return [unsigned ? 'HEAPU8' : 'HEAP8']; break;
case 'i16': return [unsigned ? 'HEAPU16' : 'HEAP16']; break;
case 'i32': case 'i64': return [unsigned ? 'HEAPU32' : 'HEAP32']; break;
case 'float': case 'double': return ['HEAPF32']; break;
default: {
throw 'what, exactly, can we do for unknown types in TA2?! ' + new Error().stack;
}
}
}
return [];
}
function finalizeLLVMFunctionCall(item, noIndexizeFunctions) {
if (item.intertype == 'getelementptr') { // TODO finalizeLLVMParameter on the ident and the indexes?
return makePointer(makeGetSlabs(item.ident, item.type)[0], getGetElementPtrIndexes(item), null, item.type);
}
if (item.intertype == 'bitcast') {
// Warn about some types of casts, then fall through to the handling code below
var oldType = item.params[0].type;
var newType = item.type;
if (isPossiblyFunctionType(oldType) && isPossiblyFunctionType(newType)) {
var oldCount = countNormalArgs(oldType);
var newCount = countNormalArgs(newType);
if (oldCount != newCount && oldCount && newCount) {
warnOnce('Casting a function pointer type to another with a different number of arguments. See more info in the compiler source');
if (VERBOSE) {
warnOnce('Casting a function pointer type to another with a different number of arguments: ' + oldType + ' vs. ' + newType + ', on ' + item.params[0].ident);
}
// This may be dangerous as clang generates different code for C and C++ calling conventions. The only problem
// case appears to be passing a structure by value, C will have (field1, field2) as function args, and the
// function will internally create a structure with that data, while C++ will have (struct* byVal) and it
// will create a copy before calling the function, then call it with a pointer to the copy. Mixing the two
// first of all leads to two copies being made, so this is a bad idea even regardless of Emscripten. But,
// what is a problem for Emscr ipten is that mixing these two calling conventions (say, calling a C one from
// C++) will then assume that (struct* byVal) is actually the same as (field1, field2). In native code, this
// is easily possible, you place the two fields on the stack and call the function (you know to place the
// values since there is 'byVal'). In Emscripten, though, this means we would need to always do one or the
// other of the two possibilities, for example, always passing by-value structs as (field1, field2). This
// would slow down everything, just to handle this corner case. (Which, just to point out how much of a
// corner case it is, does not appear to happen with nested structures!)
//
// The recommended solution for this problem is not to mix C and C++ calling conventions when passing structs
// by value. Either always pass structs by value within C code or C++ code, but not mixing the two by
// defining a function in one and calling it from the other (so, just changing .c to .cpp, or moving code
// from one file to another, would be enough to fix this), or, do not pass structs by value (which in general
// is inefficient, and worth avoiding if you can).
//
// Note that removing all arguments is acceptable, as a vast to void ()*.
}
}
}
var temp = {
op: item.intertype,
variant: item.variant,
type: item.type,
params: item.params.slice(0) // XXX slice?
};
return processMathop(temp);
}
function getGetElementPtrIndexes(item) {
var type = item.params[0].type;
if (USE_TYPED_ARRAYS == 2) {
// GEP indexes are marked as i64s, but they are just numbers to us
item.params.forEach(function(param) { param.type = 'i32' });
}
item.params = item.params.map(finalizeLLVMParameter);
var ident = item.params[0];
// struct pointer, struct*, and getting a ptr to an element in that struct. Param 1 is which struct, then we have items in that
// struct, and possibly further substructures, all embedded
// can also be to 'blocks': [8 x i32]*, not just structs
type = removePointing(type);
var indexes = [makeGetPos(ident)];
var offset = item.params[1];
if (offset != 0) {
if (isStructType(type)) {
indexes.push(getFastValue(Types.types[type].flatSize, '*', offset, 'i32'));
} else {
indexes.push(getFastValue(Runtime.getNativeTypeSize(type), '*', offset, 'i32'));
}
}
item.params.slice(2, item.params.length).forEach(function(arg) {
var curr = arg;
// TODO: If index is constant, optimize
var typeData = Types.types[type];
if (isStructType(type) && typeData.needsFlattening) {
if (typeData.flatFactor) {
indexes.push(getFastValue(curr, '*', typeData.flatFactor, 'i32'));
} else {
if (isNumber(curr)) {
indexes.push(typeData.flatIndexes[curr]);
} else {
indexes.push(toNiceIdent(type) + '___FLATTENER[' + curr + ']'); // TODO: If curr is constant, optimize out the flattener struct
}
}
} else {
if (curr != 0) {
indexes.push(curr);
}
}
if (!isNumber(curr) || parseInt(curr) < 0) {
// We have a *variable* to index with, or a negative number. In both
// cases, in theory we might need to do something dynamic here. FIXME?
// But, most likely all the possible types are the same, so do that case here now...
for (var i = 1; i < typeData.fields.length; i++) {
assert(typeData.fields[0] === typeData.fields[i]);
}
curr = 0;
}
type = typeData && typeData.fields[curr] ? typeData.fields[curr] : '';
});
var ret = getFastValues(indexes, '+', 'i32');
ret = handleOverflow(ret, 32); // XXX - we assume a 32-bit arch here. If you fail on this, change to 64
return ret;
}
function handleOverflow(text, bits) {
// TODO: handle overflows of i64s
if (!bits) return text;
var correct = correctOverflows();
warnOnce(!correct || bits <= 32, 'Cannot correct overflows of this many bits: ' + bits);
if (CHECK_OVERFLOWS) return 'CHECK_OVERFLOW(' + text + ', ' + bits + ', ' + Math.floor(correctSpecificOverflow() && !PGO) + (
PGO ? ', "' + Debugging.getIdentifier() + '"' : ''
) + ')';
if (!correct) return text;
if (bits == 32) {
return '((' + text + ')|0)';
} else if (bits < 32) {
return '((' + text + ')&' + (Math.pow(2, bits) - 1) + ')';
} else {
return text; // We warned about this earlier
}
}
function makeLLVMStruct(values) {
if (USE_TYPED_ARRAYS == 2) {
return 'DEPRECATED' + (new Error().stack) + 'XXX';
} else {
return '{ ' + values.map(function(value, i) { return 'f' + i + ': ' + value }).join(', ') + ' }'
}
}
function makeStructuralReturn(values) {
if (USE_TYPED_ARRAYS == 2) {
var i = 0;
return 'return (' + values.slice(1).map(function(value) {
return ASM_JS ? 'asm.setTempRet' + (i++) + '(' + value + ')'
: 'tempRet' + (i++) + ' = ' + value;
}).concat([values[0]]).join(',') + ')';
} else {
var i = 0;
return 'return { ' + values.map(function(value) {
return 'f' + (i++) + ': ' + value;
}).join(', ') + ' }';
}
}
function makeStructuralAccess(ident, i) {
if (USE_TYPED_ARRAYS == 2) {
return ident + '$' + i;
} else {
return ident + '.f' + i;
}
}
function makeThrow(what) {
return 'throw ' + what + (DISABLE_EXCEPTION_CATCHING == 1 ? ' + " - Exception catching is disabled, this exception cannot be caught. Compile with -s DISABLE_EXCEPTION_CATCHING=0 or DISABLE_EXCEPTION_CATCHING=2 to catch."' : '') + ';';
}
// From parseLLVMSegment
function finalizeLLVMParameter(param, noIndexizeFunctions) {
var ret;
if (isNumber(param)) {
return param;
} else if (typeof param === 'string') {
return toNiceIdentCarefully(param);
} else if (param.intertype in PARSABLE_LLVM_FUNCTIONS) {
ret = finalizeLLVMFunctionCall(param, noIndexizeFunctions);
} else if (param.ident == 'zeroinitializer') {
if (isStructType(param.type)) {
return makeLLVMStruct(zeros(Types.types[param.type].fields.length));
} else {
return '0';
}
} else if (param.intertype == 'value') {
ret = param.ident;
if (ret in Variables.globals) {
ret = makeGlobalUse(ret);
}
if (param.type == 'i64' && USE_TYPED_ARRAYS == 2) {
ret = parseI64Constant(ret);
}
ret = parseNumerical(ret, param.type);
ret = asmEnsureFloat(ret, param.type);
} else if (param.intertype == 'structvalue') {
ret = makeLLVMStruct(param.params.map(function(value) { return finalizeLLVMParameter(value, noIndexizeFunctions) }));
} else if (param.intertype === 'blockaddress') {
return finalizeBlockAddress(param);
} else if (param.intertype === 'type') {
return param.ident; // we don't really want the type here
} else if (param.intertype == 'mathop') {
return processMathop(param);
} else {
throw 'invalid llvm parameter: ' + param.intertype;
}
assert(param.type || (typeof param === 'string' && param.substr(0, 6) === 'CHECK_'), 'Missing type for param!');
if (!noIndexizeFunctions) ret = indexizeFunctions(ret, param.type);
return ret;
}
function makeComparison(a, b, type) {
if (!isIllegalType(type)) {
return a + ' == ' + b;
} else {
assert(type == 'i64');
return a + '$0 == ' + b + '$0 && ' + a + '$1 == ' + b + '$1';
}
}
function makeSignOp(value, type, op, force, ignore) {
if (USE_TYPED_ARRAYS == 2 && type == 'i64') {
return value; // these are always assumed to be two 32-bit unsigneds.
}
if (isPointerType(type)) type = 'i32'; // Pointers are treated as 32-bit ints
if (!value) return value;
var bits, full;
if (type in Runtime.INT_TYPES) {
bits = parseInt(type.substr(1));
full = op + 'Sign(' + value + ', ' + bits + ', ' + Math.floor(ignore || (correctSpecificSign() && !PGO)) + (
PGO ? ', "' + (ignore ? '' : Debugging.getIdentifier()) + '"' : ''
) + ')';
// Always sign/unsign constants at compile time, regardless of CHECK/CORRECT
if (isNumber(value)) {
return eval(full).toString();
}
}
if ((ignore || !correctSigns()) && !CHECK_SIGNS && !force) return value;
if (type in Runtime.INT_TYPES) {
// shortcuts
if (!CHECK_SIGNS || ignore) {
if (bits === 32) {
if (op === 're') {
return '((' + value + ')|0)';
} else {
return '((' + value + ')>>>0)';
// Alternatively, we can consider the lengthier
// return makeInlineCalculation('VALUE >= 0 ? VALUE : ' + Math.pow(2, bits) + ' + VALUE', value, 'tempBigInt');
// which does not always turn us into a 32-bit *un*signed value
}
} else if (bits < 32) {
if (op === 're') {
return makeInlineCalculation('(VALUE << ' + (32-bits) + ') >> ' + (32-bits), value, 'tempInt');
} else {
return '((' + value + ')&' + (Math.pow(2, bits)-1) + ')';
}
} else { // bits > 32
if (op === 're') {
return makeInlineCalculation('VALUE >= ' + Math.pow(2, bits-1) + ' ? VALUE-' + Math.pow(2, bits) + ' : VALUE', value, 'tempBigIntS');
} else {
return makeInlineCalculation('VALUE >= 0 ? VALUE : ' + Math.pow(2, bits) + '+VALUE', value, 'tempBigIntS');
}
}
}
return full;
}
return value;
}
// @param floatConversion Means that we are receiving a float and rounding it to
// an integer. We must be careful here, the input has *not*
// already been converted to a signed/unsigned value (that
// would already do rounding, before us!)
function makeRounding(value, bits, signed, floatConversion) {
// TODO: handle roundings of i64s
assert(bits);
if (!ASM_JS) {
// C rounds to 0 (-5.5 to -5, +5.5 to 5), while JS has no direct way to do that.
if (bits <= 32 && signed) return '((' + value + ')&-1)'; // This is fast and even correct, for all cases. Note that it is the same
// as |0, but &-1 hints to the js optimizer that this is a rounding correction
// Do Math.floor, which is reasonably fast, if we either don't care, or if we can be sure
// the value is non-negative
if (!correctRoundings() || (!signed && !floatConversion)) return 'Math.floor(' + value + ')';
// We are left with >32 bits signed, or a float conversion. Check and correct inline
// Note that if converting a float, we may have the wrong sign at this point! But, we have
// been rounded properly regardless, and we will be sign-corrected later when actually used, if
// necessary.
return makeInlineCalculation('VALUE >= 0 ? Math.floor(VALUE) : Math.ceil(VALUE)', value, 'tempBigIntR');
} else {
// asm.js mode, cleaner refactoring of this function as well. TODO: use in non-asm case, most of this
if (floatConversion && bits <= 32) {
return '(~~(' + value + '))'; // explicit float-to-int conversion
}
if (bits <= 32) {
if (signed) {
return '((' + value + ')&-1)'; // &-1 (instead of |0) hints to the js optimizer that this is a rounding correction
} else {
return '((' + value + ')>>>0)';
}
}
// Math.floor is reasonably fast if we don't care about corrections (and even correct if unsigned)
if (!correctRoundings() || !signed) return 'Math.floor(' + value + ')';
// We are left with >32 bits
return makeInlineCalculation('VALUE >= 0 ? Math.floor(VALUE) : Math.ceil(VALUE)', value, 'tempBigIntR');
}
}
// fptoui and fptosi are not in these, because we need to be careful about what we do there. We can't
// just sign/unsign the input first.
var UNSIGNED_OP = set('udiv', 'urem', 'uitofp', 'zext', 'lshr');
var SIGNED_OP = set('sdiv', 'srem', 'sitofp', 'sext', 'ashr');
function isUnsignedOp(op, variant) {
return op in UNSIGNED_OP || (variant && variant[0] == 'u');
}
function isSignedOp(op, variant) {
return op in SIGNED_OP || (variant && variant[0] == 's');
}
var legalizedI64s = USE_TYPED_ARRAYS == 2; // We do not legalize globals, but do legalize function lines. This will be true in the latter case
function processMathop(item) {
var op = item.op;
var variant = item.variant;
var type = item.type;
var paramTypes = ['', '', '', ''];
var idents = [];
for (var i = 0; i < 3; i++) {
if (item.params[i]) {
paramTypes[i] = item.params[i].type || type;
idents[i] = finalizeLLVMParameter(item.params[i]);
if (!isNumber(idents[i]) && !isNiceIdent(idents[i])) {
idents[i] = '(' + idents[i] + ')'; // we may have nested expressions. So enforce the order of operations we want
}
} else {
idents[i] = null; // just so it exists for purposes of reading idents[1] etc. later on, and no exception is thrown
}
}
var originalIdents = idents.slice(0);
if (isUnsignedOp(op, variant)) {
idents[0] = makeSignOp(idents[0], paramTypes[0], 'un');
idents[1] = makeSignOp(idents[1], paramTypes[1], 'un');
} else if (isSignedOp(op, variant)) {
idents[0] = makeSignOp(idents[0], paramTypes[0], 're');
idents[1] = makeSignOp(idents[1], paramTypes[1], 're');
}
var bits = null;
if (item.type[0] === 'i') {
bits = parseInt(item.type.substr(1));
}
var bitsLeft = parseInt(((item.params[1] && item.params[1].ident) ? item.params[1].ident : item.type).substr(1)); // remove i to leave the number of bits left after this operation
function integerizeBignum(value) {
return makeInlineCalculation('VALUE-VALUE%1', value, 'tempBigIntI');
}
if ((type == 'i64' || paramTypes[0] == 'i64' || paramTypes[1] == 'i64' || idents[1] == '(i64)') && USE_TYPED_ARRAYS == 2) {
var warnI64_1 = function() {
warnOnce('Arithmetic on 64-bit integers in mode 1 is rounded and flaky, like mode 0!');
};
// In ops that can be either legalized or not, we need to differentiate how we access low and high parts
var low1 = idents[0] + (legalizedI64s ? '$0' : '[0]');
var high1 = idents[0] + (legalizedI64s ? '$1' : '[1]');
var low2 = idents[1] + (legalizedI64s ? '$0' : '[0]');
var high2 = idents[1] + (legalizedI64s ? '$1' : '[1]');
function finish(result) {
// If this is in legalization mode, steal the assign and assign into two vars
if (legalizedI64s) {
assert(item.assignTo);
var ret = 'var ' + item.assignTo + '$0 = ' + result[0] + '; var ' + item.assignTo + '$1 = ' + result[1] + ';';
item.assignTo = null;
return ret;
} else {
return result;
}
}
function i64PreciseOp(type, lastArg) {
Types.preciseI64MathUsed = true;
return finish(['(i64Math' + (ASM_JS ? '_' : '.') + type + '(' + asmCoercion(low1, 'i32') + ',' + asmCoercion(high1, 'i32') + ',' + asmCoercion(low2, 'i32') + ',' + asmCoercion(high2, 'i32') +
(lastArg ? ',' + asmCoercion(+lastArg, 'i32') : '') + '),' + makeGetValue('tempDoublePtr', 0, 'i32') + ')', makeGetValue('tempDoublePtr', Runtime.getNativeTypeSize('i32'), 'i32')]);
}
switch (op) {
// basic integer ops
case 'or': {
return '[' + idents[0] + '[0] | ' + idents[1] + '[0], ' + idents[0] + '[1] | ' + idents[1] + '[1]]';
}
case 'and': {
return '[' + idents[0] + '[0] & ' + idents[1] + '[0], ' + idents[0] + '[1] & ' + idents[1] + '[1]]';
}
case 'xor': {
return '[' + idents[0] + '[0] ^ ' + idents[1] + '[0], ' + idents[0] + '[1] ^ ' + idents[1] + '[1]]';
}
case 'shl':
case 'ashr':
case 'lshr': {
if (!isNumber(idents[1])) {
return '(Runtime' + (ASM_JS ? '_' : '.') + 'bitshift64(' + idents[0] + '[0], ' + idents[0] + '[1],' + Runtime['BITSHIFT64_' + op.toUpperCase()] + ',' + stripCorrections(idents[1]) + '[0]|0),' +
'[' + makeGetTempDouble(0, 'i32') + ',' + makeGetTempDouble(1, 'i32') + '])';
}
bits = parseInt(idents[1]);
var ander = Math.pow(2, bits)-1;
if (bits < 32) {
switch (op) {
case 'shl':
return '[' + idents[0] + '[0] << ' + idents[1] + ', ' +
'('+idents[0] + '[1] << ' + idents[1] + ') | ((' + idents[0] + '[0]&(' + ander + '<<' + (32 - bits) + ')) >>> (32-' + idents[1] + '))]';
case 'ashr':
return '[((('+idents[0] + '[0] >>> ' + idents[1] + ') | ((' + idents[0] + '[1]&' + ander + ')<<' + (32 - bits) + ')) >> 0) >>> 0,' +
'(' + idents[0] + '[1] >> ' + idents[1] + ') >>> 0]';
case 'lshr':
return '[(('+idents[0] + '[0] >>> ' + idents[1] + ') | ((' + idents[0] + '[1]&' + ander + ')<<' + (32 - bits) + ')) >>> 0,' +
idents[0] + '[1] >>> ' + idents[1] + ']';
}
} else if (bits == 32) {
switch (op) {
case 'shl':
return '[0, ' + idents[0] + '[0]]';
case 'ashr':
return '[' + idents[0] + '[1], (' + idents[0] + '[1]|0) < 0 ? ' + ander + ' : 0]';
case 'lshr':
return '[' + idents[0] + '[1], 0]';
}
} else { // bits > 32
switch (op) {
case 'shl':
return '[0, ' + idents[0] + '[0] << ' + (bits - 32) + ']';
case 'ashr':
return '[(' + idents[0] + '[1] >> ' + (bits - 32) + ') >>> 0, (' + idents[0] + '[1]|0) < 0 ? ' + ander + ' : 0]';
case 'lshr':
return '[' + idents[0] + '[1] >>> ' + (bits - 32) + ', 0]';
}
}
}
case 'uitofp': case 'sitofp': return RuntimeGenerator.makeBigInt(low1, high1, op[0] == 'u');
case 'fptoui': case 'fptosi': return finish(splitI64(idents[0]));
case 'icmp': {
switch (variant) {
case 'uge': return '((' + high1 + '>>>0) >= (' + high2 + '>>>0)) & ((((' + high1 + '>>>0) > (' + high2 + '>>>0)) | ' +
'(' + low1 + '>>>0) >= (' + low2 + '>>>0)))';
case 'sge': return '((' + high1 + '|0) >= (' + high2 + '|0)) & ((((' + high1 + '|0) > (' + high2 + '|0)) | ' +
'(' + low1 + '>>>0) >= (' + low2 + '>>>0)))';
case 'ule': return '((' + high1 + '>>>0) <= (' + high2 + '>>>0)) & ((((' + high1 + '>>>0) < (' + high2 + '>>>0)) | ' +
'(' + low1 + '>>>0) <= (' + low2 + '>>>0)))';
case 'sle': return '((' + high1 + '|0) <= (' + high2 + '|0)) & ((((' + high1 + '|0) < (' + high2 + '|0)) | ' +
'(' + low1 + '>>>0) <= (' + low2 + '>>>0)))';
case 'ugt': return '((' + high1 + '>>>0) > (' + high2 + '>>>0)) | ((((' + high1 + '>>>0) == (' + high2 + '>>>0) & ' +
'(' + low1 + '>>>0) > (' + low2 + '>>>0))))';
case 'sgt': return '((' + high1 + '|0) > (' + high2 + '|0)) | ((((' + high1 + '|0) == (' + high2 + '|0) & ' +
'(' + low1 + '>>>0) > (' + low2 + '>>>0))))';
case 'ult': return '((' + high1 + '>>>0) < (' + high2 + '>>>0)) | ((((' + high1 + '>>>0) == (' + high2 + '>>>0) & ' +
'(' + low1 + '>>>0) < (' + low2 + '>>>0))))';
case 'slt': return '((' + high1 + '|0) < (' + high2 + '|0)) | ((((' + high1 + '|0) == (' + high2 + '|0) & ' +
'(' + low1 + '>>>0) < (' + low2 + '>>>0))))';
case 'ne': return '((' + low1 + '|0) != (' + low2 + '|0)) | ((' + high1 + '|0) != (' + high2 + '|0))';
case 'eq': return '((' + low1 + '|0) == (' + low2 + '|0)) & ((' + high1 + '|0) == (' + high2 + '|0))';
default: throw 'Unknown icmp variant: ' + variant;
}
}
case 'zext': return makeI64(idents[0], 0);
case 'sext': return makeInlineCalculation(makeI64('VALUE', 'VALUE<0 ? 4294967295 : 0'), idents[0], 'tempBigIntD');
case 'trunc': {
return '((' + idents[0] + '[0]) & ' + (Math.pow(2, bitsLeft)-1) + ')';
}
case 'select': return idents[0] + ' ? ' + makeCopyI64(idents[1]) + ' : ' + makeCopyI64(idents[2]);
case 'ptrtoint': return makeI64(idents[0], 0);
case 'inttoptr': return '(' + idents[0] + '[0])'; // just directly truncate the i64 to a 'pointer', which is an i32
// Dangerous, rounded operations. TODO: Fully emulate
case 'add': {
if (PRECISE_I64_MATH) {
return i64PreciseOp('add');
} else {
warnI64_1();
return finish(splitI64(mergeI64(idents[0]) + '+' + mergeI64(idents[1])));
}
}
case 'sub': {
if (PRECISE_I64_MATH) {
return i64PreciseOp('subtract');
} else {
warnI64_1();
return finish(splitI64(mergeI64(idents[0]) + '-' + mergeI64(idents[1])));
}
}
case 'sdiv': case 'udiv': {
if (PRECISE_I64_MATH) {
return i64PreciseOp('divide', op[0] === 'u');
} else {
warnI64_1();
return finish(splitI64(makeRounding(mergeI64(idents[0], op[0] === 'u') + '/' + mergeI64(idents[1], op[0] === 'u'), bits, op[0] === 's')));
}
}
case 'mul': {
if (PRECISE_I64_MATH) {
return i64PreciseOp('multiply');
} else {
warnI64_1();
return finish(splitI64(mergeI64(idents[0], op[0] === 'u') + '*' + mergeI64(idents[1], op[0] === 'u')));
}
}
case 'urem': case 'srem': {
if (PRECISE_I64_MATH) {
return i64PreciseOp('modulo', op[0] === 'u');
} else {
warnI64_1();
return finish(splitI64(mergeI64(idents[0], op[0] === 'u') + '%' + mergeI64(idents[1], op[0] === 'u')));
}
}
case 'bitcast': {
// Pointers are not 64-bit, so there is really only one possible type of bitcast here, int to float or vice versa
assert(USE_TYPED_ARRAYS == 2, 'Can only bitcast ints <-> floats with typed arrays mode 2');
var inType = item.params[0].type;
var outType = item.type;
if (inType in Runtime.INT_TYPES && outType in Runtime.FLOAT_TYPES) {
if (legalizedI64s) {
return '(' + makeSetTempDouble(0, 'i32', idents[0] + '$0') + ', ' + makeSetTempDouble(1, 'i32', idents[0] + '$1') + ', ' + makeGetTempDouble(0, 'double') + ')';
} else {
return makeInlineCalculation(makeSetTempDouble(0, 'i32', 'VALUE[0]') + ',' + makeSetTempDouble(1, 'i32', 'VALUE[1]') + ',' + makeGetTempDouble(0, 'double'), idents[0], 'tempI64');
}
} else if (inType in Runtime.FLOAT_TYPES && outType in Runtime.INT_TYPES) {
if (legalizedI64s) {
return makeSetTempDouble(0, 'double', idents[0]) + '; ' + finish([makeGetTempDouble(0, 'i32'), makeGetTempDouble(1, 'i32')]);
} else {
return '(' + makeSetTempDouble(0, 'double', idents[0]) + ',[' + makeGetTempDouble(0, 'i32') + ',' + makeGetTempDouble(1, 'i32') + '])';
}
} else {
throw 'Invalid USE_TYPED_ARRAYS == 2 bitcast: ' + dump(item) + ' : ' + item.params[0].type;
}
}
default: throw 'Unsupported i64 mode 1 op: ' + item.op + ' : ' + dump(item);
}
}
switch (op) {
// basic integer ops
case 'add': return handleOverflow(getFastValue(idents[0], '+', idents[1], item.type), bits);
case 'sub': return handleOverflow(getFastValue(idents[0], '-', idents[1], item.type), bits);
case 'sdiv': case 'udiv': return makeRounding(getFastValue(idents[0], '/', idents[1], item.type), bits, op[0] === 's');
case 'mul': {
if (bits == 32 && PRECISE_I32_MUL) {
Types.preciseI64MathUsed = true;
return '(i64Math' + (ASM_JS ? '_' : '.') + 'multiply(' + asmCoercion(idents[0], 'i32') + ',0,' + asmCoercion(idents[1], 'i32') + ',0),' + makeGetValue('tempDoublePtr', 0, 'i32') + ')';
} else {
return handleOverflow(getFastValue(idents[0], '*', idents[1], item.type), bits);
}
}
case 'urem': case 'srem': return getFastValue(idents[0], '%', idents[1], item.type);
case 'or': {
if (bits > 32) {
assert(bits === 64, 'Too many bits for or: ' + bits);
dprint('Warning: 64 bit OR - precision limit may be hit on llvm line ' + item.lineNum);
return 'Runtime.or64(' + idents[0] + ', ' + idents[1] + ')';
}
return idents[0] + ' | ' + idents[1];
}
case 'and': {
if (bits > 32) {
assert(bits === 64, 'Too many bits for and: ' + bits);
dprint('Warning: 64 bit AND - precision limit may be hit on llvm line ' + item.lineNum);
return 'Runtime.and64(' + idents[0] + ', ' + idents[1] + ')';
}
return idents[0] + ' & ' + idents[1];
}
case 'xor': {
if (bits > 32) {
assert(bits === 64, 'Too many bits for xor: ' + bits);
dprint('Warning: 64 bit XOR - precision limit may be hit on llvm line ' + item.lineNum);
return 'Runtime.xor64(' + idents[0] + ', ' + idents[1] + ')';
}
return idents[0] + ' ^ ' + idents[1];
}
case 'shl': {
if (bits > 32) return idents[0] + '*' + getFastValue(2, 'pow', idents[1]);
return idents[0] + ' << ' + idents[1];
}
case 'ashr': {
if (bits > 32) return integerizeBignum(idents[0] + '/' + getFastValue(2, 'pow', idents[1]));
if (bits === 32) return originalIdents[0] + ' >> ' + idents[1]; // No need to reSign in this case
return idents[0] + ' >> ' + idents[1];
}
case 'lshr': {
if (bits > 32) return integerizeBignum(idents[0] + '/' + getFastValue(2, 'pow', idents[1]));
if (bits === 32) return originalIdents[0] + ' >>> ' + idents[1]; // No need to unSign in this case
return idents[0] + ' >>> ' + idents[1];
}
// basic float ops
case 'fadd': return getFastValue(idents[0], '+', idents[1], item.type);
case 'fsub': return getFastValue(idents[0], '-', idents[1], item.type);
case 'fdiv': return getFastValue(idents[0], '/', idents[1], item.type);
case 'fmul': return getFastValue(idents[0], '*', idents[1], item.type);
case 'frem': return getFastValue(idents[0], '%', idents[1], item.type);
case 'uitofp': case 'sitofp': return asmCoercion(idents[0], 'double', op[0]);
case 'fptoui': case 'fptosi': return makeRounding(idents[0], bitsLeft, op === 'fptosi', true);
// TODO: We sometimes generate false instead of 0, etc., in the *cmps. It seemed slightly faster before, but worth rechecking
// Note that with typed arrays, these become 0 when written. So that is a potential difference with non-typed array runs.
case 'icmp': {
switch (variant) {
case 'uge': case 'sge': return idents[0] + ' >= ' + idents[1];
case 'ule': case 'sle': return idents[0] + ' <= ' + idents[1];
case 'ugt': case 'sgt': return idents[0] + ' > ' + idents[1];
case 'ult': case 'slt': return idents[0] + ' < ' + idents[1];
// We use loose comparisons, which allows false == 0 to be true, etc. Ditto in fcmp
case 'ne': case 'eq': {
// We must sign them, so we do not compare -1 to 255 (could have unsigned them both too)
// since LLVM tells us if <=, >= etc. comparisons are signed, but not == and !=.
assert(paramTypes[0] == paramTypes[1]);
idents[0] = makeSignOp(idents[0], paramTypes[0], 're');
idents[1] = makeSignOp(idents[1], paramTypes[1], 're');
return idents[0] + (variant === 'eq' ? '==' : '!=') + idents[1];
}
default: throw 'Unknown icmp variant: ' + variant;
}
}
case 'fcmp': {
switch (variant) {
// TODO 'o' ones should be 'ordered (no NaN) and',
// 'u' ones should be 'unordered or'.
case 'uge': case 'oge': return idents[0] + ' >= ' + idents[1];
case 'ule': case 'ole': return idents[0] + ' <= ' + idents[1];
case 'ugt': case 'ogt': return idents[0] + ' > ' + idents[1];
case 'ult': case 'olt': return idents[0] + ' < ' + idents[1];
case 'une': case 'one': return idents[0] + ' != ' + idents[1];
case 'ueq': case 'oeq': return idents[0] + ' == ' + idents[1];
case 'ord': return '!isNaN(' + idents[0] + ') && !isNaN(' + idents[1] + ')';
case 'uno': return 'isNaN(' + idents[0] + ') || isNaN(' + idents[1] + ')';
case 'true': return '1';
default: throw 'Unknown fcmp variant: ' + variant;
}
}
// Note that zext has sign checking, see above. We must guard against -33 in i8 turning into -33 in i32
// then unsigning that i32... which would give something huge.
case 'zext': case 'fpext': case 'sext': return idents[0];
case 'fptrunc': return idents[0];
case 'select': return idents[0] + ' ? ' + asmEnsureFloat(idents[1], item.type) + ' : ' + asmEnsureFloat(idents[2], item.type);
case 'ptrtoint': case 'inttoptr': {
var ret = '';
if (QUANTUM_SIZE == 1) {
warnOnce('.ll contains ptrtoint and/or inttoptr. These may be dangerous in QUANTUM == 1. ' +
'The safest thing is to investigate every appearance, and modify the source code to avoid this. ' +
'Emscripten will print a list of the .ll lines, and also annotate the .js.');
dprint(' ' + op + ' on .ll line ' + item.lineNum);
idents[0] += ' /* Warning: ' + op + ', .ll line ' + item.lineNum + ' */';
}
if (op == 'inttoptr' || bitsLeft >= 32) return idents[0];
// For ptrtoint and <32 bits, fall through into trunc since we need to truncate here
}
case 'trunc': {
// Unlike extending, which we just 'do' (by doing nothing),
// truncating can change the number, e.g. by truncating to an i1
// in order to get the first bit
assert(bitsLeft <= 32, 'Cannot truncate to more than 32 bits, since we use a native & op');
return '((' + idents[0] + ') & ' + (Math.pow(2, bitsLeft)-1) + ')';
}
case 'bitcast': {
// Most bitcasts are no-ops for us. However, the exception is int to float and float to int
var inType = item.params[0].type;
var outType = item.type;
if ((inType in Runtime.INT_TYPES && outType in Runtime.FLOAT_TYPES) ||
(inType in Runtime.FLOAT_TYPES && outType in Runtime.INT_TYPES)) {
assert(USE_TYPED_ARRAYS == 2, 'Can only bitcast ints <-> floats with typed arrays mode 2');
if (inType in Runtime.INT_TYPES) {
return '(' + makeSetTempDouble(0, 'i32', idents[0]) + ',' + makeGetTempDouble(0, 'float') + ')';
} else {
return '(' + makeSetTempDouble(0, 'float', idents[0]) + ',' + makeGetTempDouble(0, 'i32') + ')';
}
}
return idents[0];
}
default: throw 'Unknown mathcmp op: ' + item.op;
}
}
// Walks through some intertype data, calling a function at every item. If
// the function returns true, will stop the walk.
// TODO: Use this more in analyzer, possibly also in jsifier
function walkInterdata(item, pre, post, obj) {
if (!item || !item.intertype) return false;
if (pre && pre(item, obj)) return true;
var originalObj = obj;
if (obj && obj.replaceWith) obj = obj.replaceWith; // allow pre to replace the object we pass to all its children
if (item.value && walkInterdata(item.value, pre, post, obj)) return true;
// TODO if (item.pointer && walkInterdata(item.pointer, pre, post, obj)) return true;
if (item.dependent && walkInterdata(item.dependent, pre, post, obj)) return true;
var i;
if (item.params) {
for (i = 0; i <= item.params.length; i++) {
if (walkInterdata(item.params[i], pre, post, obj)) return true;
}
}
if (item.possibleVars) { // other attributes that might contain interesting data; here, variables
var box = { intertype: 'value', ident: '' };
for (i = 0; i <= item.possibleVars.length; i++) {
box.ident = item[item.possibleVars[i]];
if (walkInterdata(box, pre, post, obj)) return true;
}
}
return post && post(item, originalObj, obj);
}
// Separate from walkInterdata so that the former is as fast as possible
// If the callback returns a value, we replace the current item with that
// value, and do *not* walk the children.
function walkAndModifyInterdata(item, pre) {
if (!item || !item.intertype) return false;
var ret = pre(item);
if (ret) return ret;
var repl;
if (item.value && (repl = walkAndModifyInterdata(item.value, pre))) item.value = repl;
if (item.pointer && (repl = walkAndModifyInterdata(item.pointer, pre))) item.pointer = repl;
if (item.dependent && (repl = walkAndModifyInterdata(item.dependent, pre))) item.dependent = repl;
if (item.params) {
for (var i = 0; i <= item.params.length; i++) {
if (repl = walkAndModifyInterdata(item.params[i], pre)) item.params[i] = repl;
}
}
// Ignore possibleVars because we can't replace them anyhow
}
function parseBlockAddress(segment) {
return { intertype: 'blockaddress', func: toNiceIdent(segment[2].item.tokens[0].text), label: toNiceIdent(segment[2].item.tokens[2].text), type: 'i32' };
}
function finalizeBlockAddress(param) {
return '{{{ BA_' + param.func + '|' + param.label + ' }}}'; // something python will replace later
}
function stripCorrections(param) {
var m;
while (true) {
if (m = /^\((.*)\)$/.exec(param)) {
param = m[1];
continue;
}
if (m = /^\(([$_\w]+)\)&\d+$/.exec(param)) {
param = m[1];
continue;
}
if (m = /^\(([$_\w()]+)\)\|0$/.exec(param)) {
param = m[1];
continue;
}
if (m = /^\(([$_\w()]+)\)\>>>0$/.exec(param)) {
param = m[1];
continue;
}
if (m = /CHECK_OVERFLOW\(([^,)]*),.*/.exec(param)) {
param = m[1];
continue;
}
break;
}
return param;
}
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