//"use strict"; // Analyze intertype data. Calculates things that are necessary in order // to do the final conversion into JavaScript later, for example, // properties of variables, loop structures of functions, etc. var VAR_NATIVE = 'native'; var VAR_NATIVIZED = 'nativized'; var VAR_EMULATED = 'emulated'; var ENTRY_IDENT = toNiceIdent('%0'); var ENTRY_IDENT_IDS = set(0, 1); // XXX function recomputeLines(func) { func.lines = func.labels.map(function(label) { return label.lines }).reduce(concatenator, []); } // Handy sets var BRANCH_INVOKE = set('branch', 'invoke'); var LABEL_ENDERS = set('branch', 'return'); var SIDE_EFFECT_CAUSERS = set('call', 'invoke', 'atomic'); var UNUNFOLDABLE = set('value', 'structvalue', 'type', 'phiparam'); // Analyzer function analyzer(data, sidePass) { var mainPass = !sidePass; // Substrate var substrate = new Substrate('Analyzer'); // Sorter substrate.addActor('Sorter', { processItem: function(item) { item.items.sort(function (a, b) { return a.lineNum - b.lineNum }); this.forwardItem(item, 'Gatherer'); } }); // Gatherer substrate.addActor('Gatherer', { processItem: function(item) { // Single-liners ['globalVariable', 'functionStub', 'unparsedFunction', 'unparsedGlobals', 'unparsedTypes', 'alias'].forEach(function(intertype) { var temp = splitter(item.items, function(item) { return item.intertype == intertype }); item.items = temp.leftIn; item[intertype + 's'] = temp.splitOut; }); var temp = splitter(item.items, function(item) { return item.intertype == 'type' }); item.items = temp.leftIn; temp.splitOut.forEach(function(type) { //dprint('types', 'adding defined type: ' + type.name_); Types.types[type.name_] = type; if (QUANTUM_SIZE === 1) { Types.fatTypes[type.name_] = copy(type); } }); // Functions & labels item.functions = []; var currLabelFinished; // Sometimes LLVM puts a branch in the middle of a label. We need to ignore all lines after that. item.items.sort(function(a, b) { return a.lineNum - b.lineNum }); for (var i = 0; i < item.items.length; i++) { var subItem = item.items[i]; assert(subItem.lineNum); if (subItem.intertype == 'function') { item.functions.push(subItem); subItem.endLineNum = null; subItem.lines = []; // We will fill in the function lines after the legalizer, since it can modify them subItem.labels = []; subItem.forceEmulated = false; // no explicit 'entry' label in clang on LLVM 2.8 - most of the time, but not all the time! - so we add one if necessary if (item.items[i+1].intertype !== 'label') { item.items.splice(i+1, 0, { intertype: 'label', ident: ENTRY_IDENT, lineNum: subItem.lineNum + '.5' }); } } else if (subItem.intertype == 'functionEnd') { item.functions.slice(-1)[0].endLineNum = subItem.lineNum; } else if (subItem.intertype == 'label') { item.functions.slice(-1)[0].labels.push(subItem); subItem.lines = []; currLabelFinished = false; } else if (item.functions.length > 0 && item.functions.slice(-1)[0].endLineNum === null) { // Internal line if (!currLabelFinished) { item.functions.slice(-1)[0].labels.slice(-1)[0].lines.push(subItem); // If this line fails, perhaps missing a label? if (subItem.intertype in LABEL_ENDERS) { currLabelFinished = true; } } else { print('// WARNING: content after a branch in a label, line: ' + subItem.lineNum); } } else { throw 'ERROR: what is this? ' + dump(subItem); } } delete item.items; this.forwardItem(item, 'Legalizer'); } }); // Legalize LLVM unrealistic types into realistic types. // // With full LLVM optimizations, it can generate types like i888 which do not exist in // any actual hardware implementation, but are useful during optimization. LLVM then // legalizes these types into real ones during code generation. Sadly, there is no LLVM // IR pass to legalize them, which would have been useful and nice from a design perspective. // The LLVM community is also not interested in receiving patches to implement that // functionality, since it would duplicate existing code from the code generation // component. Therefore, we implement legalization here in Emscripten. // // Currently we just legalize completely unrealistic types into bundles of i32s, and just // the most common instructions that can be involved with such types: load, store, shifts, // trunc and zext. substrate.addActor('Legalizer', { processItem: function(data) { // Legalization if (USE_TYPED_ARRAYS == 2) { function getLegalVars(base, bits, allowLegal) { if (allowLegal && bits <= 32) return [{ ident: base, bits: bits }]; if (isNumber(base)) return getLegalLiterals(base, bits); var ret = new Array(Math.ceil(bits/32)); var i = 0; if (base == 'zeroinitializer' || base == 'undef') base = 0; while (bits > 0) { ret[i] = { ident: base ? base + '$' + i : '0', bits: Math.min(32, bits) }; bits -= 32; i++; } return ret; } function getLegalLiterals(text, bits) { var parsed = parseArbitraryInt(text, bits); var ret = new Array(Math.ceil(bits/32)); var i = 0; while (bits > 0) { ret[i] = { ident: (parsed[i]|0).toString(), bits: Math.min(32, bits) }; // resign all values bits -= 32; i++; } return ret; } function getLegalStructuralParts(value) { return value.params.slice(0); } function getLegalParams(params, bits) { return params.map(function(param) { var value = param.value || param; if (isNumber(value.ident)) { return getLegalLiterals(value.ident, bits); } else if (value.intertype == 'structvalue') { return getLegalStructuralParts(value).map(function(part) { return { ident: part.ident, bits: part.type.substr(1) }; }); } else { return getLegalVars(value.ident, bits); } }); } // Uses the right factor to multiply line numbers by so that they fit in between // the line[i] and the line after it function interpLines(lines, i, toAdd) { var prev = i >= 0 ? lines[i].lineNum : -1; var next = (i < lines.length-1) ? lines[i+1].lineNum : (lines[i].lineNum + 0.5); var factor = (next - prev)/(4*toAdd.length+3); for (var k = 0; k < toAdd.length; k++) { toAdd[k].lineNum = prev + ((k+1)*factor); } } function removeAndAdd(lines, i, toAdd) { var item = lines[i]; interpLines(lines, i, toAdd); Array.prototype.splice.apply(lines, [i, 1].concat(toAdd)); return toAdd.length; } function legalizeFunctionParameters(params) { var i = 0; while (i < params.length) { var param = params[i]; if (param.intertype == 'value' && isIllegalType(param.type)) { var toAdd = getLegalVars(param.ident, getBits(param.type)).map(function(element) { return { intertype: 'value', type: 'i' + element.bits, ident: element.ident, byval: 0 }; }); Array.prototype.splice.apply(params, [i, 1].concat(toAdd)); i += toAdd.length; continue; } i++; } } function fixUnfolded(item) { // Unfolded items may need some correction to work properly in the global scope if (item.intertype in MATHOPS) { item.op = item.intertype; item.intertype = 'mathop'; } } data.functions.forEach(function(func) { // Legalize function params legalizeFunctionParameters(func.params); // Legalize lines in labels var tempId = 0; func.labels.forEach(function(label) { if (dcheck('legalizer')) dprint('zz legalizing: \n' + dump(label.lines)); var i = 0, bits; while (i < label.lines.length) { var item = label.lines[i]; var value = item; // Check if we need to legalize here, and do some trivial legalization along the way var isIllegal = false; walkInterdata(item, function(item) { if (item.intertype == 'getelementptr' || (item.intertype == 'call' && item.ident in LLVM.INTRINSICS_32)) { // Turn i64 args into i32 for (var i = 0; i < item.params.length; i++) { if (item.params[i].type == 'i64') item.params[i].type = 'i32'; } } else if (item.intertype == 'inttoptr') { var input = item.params[0]; if (input.type == 'i64') input.type = 'i32'; // inttoptr can only care about 32 bits anyhow since pointers are 32-bit } if (isIllegalType(item.valueType) || isIllegalType(item.type)) { isIllegal = true; } if ((item.intertype == 'load' || item.intertype == 'store') && isStructType(item.valueType)) { isIllegal = true; // storing an entire structure is illegal } }); if (!isIllegal) { //if (dcheck('legalizer')) dprint('no need to legalize \n' + dump(item)); i++; continue; } // Unfold this line. If we unfolded, we need to return and process the lines we just // generated - they may need legalization too var unfolded = []; walkAndModifyInterdata(item, function(subItem) { // Unfold all non-value interitems that we can, and also unfold all numbers (doing the latter // makes it easier later since we can then assume illegal expressions are always variables // accessible through ident$x, and not constants we need to parse then and there) if (subItem != item && (!(subItem.intertype in UNUNFOLDABLE) || (subItem.intertype == 'value' && isNumber(subItem.ident) && isIllegalType(subItem.type)))) { if (item.intertype == 'phi') { assert(subItem.intertype == 'value' || subItem.intertype == 'structvalue', 'We can only unfold illegal constants in phis'); // we must handle this in the phi itself, if we unfold normally it will not be pushed back with the phi } else { var tempIdent = '$$etemp$' + (tempId++); subItem.assignTo = tempIdent; unfolded.unshift(subItem); fixUnfolded(subItem); return { intertype: 'value', ident: tempIdent, type: subItem.type }; } } else if (subItem.intertype == 'switch' && isIllegalType(subItem.type)) { subItem.switchLabels.forEach(function(switchLabel) { if (switchLabel.value[0] != '$') { var tempIdent = '$$etemp$' + (tempId++); unfolded.unshift({ assignTo: tempIdent, intertype: 'value', ident: switchLabel.value, type: subItem.type }); switchLabel.value = tempIdent; } }); } }); if (unfolded.length > 0) { interpLines(label.lines, i-1, unfolded); Array.prototype.splice.apply(label.lines, [i, 0].concat(unfolded)); continue; // remain at this index, to unfold newly generated lines } // This is an illegal-containing line, and it is unfolded. Legalize it now dprint('legalizer', 'Legalizing ' + item.intertype + ' at line ' + item.lineNum); var finalizer = null; switch (item.intertype) { case 'store': { var toAdd = []; bits = getBits(item.valueType); var elements = getLegalParams([item.value], bits)[0]; var j = 0; elements.forEach(function(element) { var tempVar = '$st$' + i + '$' + j; toAdd.push({ intertype: 'getelementptr', assignTo: tempVar, ident: item.pointer.ident, type: '[0 x i32]*', params: [ { intertype: 'value', ident: item.pointer.ident, type: '[0 x i32]*' }, // technically a bitcase is needed in llvm, but not for us { intertype: 'value', ident: '0', type: 'i32' }, { intertype: 'value', ident: j.toString(), type: 'i32' } ], }); var actualSizeType = 'i' + element.bits; // The last one may be smaller than 32 bits toAdd.push({ intertype: 'store', valueType: actualSizeType, value: { intertype: 'value', ident: element.ident, type: actualSizeType }, pointer: { intertype: 'value', ident: tempVar, type: actualSizeType + '*' }, ident: tempVar, pointerType: actualSizeType + '*', align: item.align, }); j++; }); Types.needAnalysis['[0 x i32]'] = 0; i += removeAndAdd(label.lines, i, toAdd); continue; } // call, return: Return the first 32 bits, the rest are in temp case 'call': { bits = getBits(value.type); var elements = getLegalVars(item.assignTo, bits); var toAdd = [value]; // legalize parameters legalizeFunctionParameters(value.params); if (value.assignTo && isIllegalType(item.type)) { // legalize return value value.assignTo = elements[0].ident; for (var j = 1; j < elements.length; j++) { var element = elements[j]; toAdd.push({ intertype: 'value', assignTo: element.ident, type: element.bits, ident: 'tempRet' + (j - 1) }); assert(j<10); // TODO: dynamically create more than 10 tempRet-s } } i += removeAndAdd(label.lines, i, toAdd); continue; } case 'landingpad': { // not much to legalize i++; continue; } case 'return': { bits = getBits(item.type); var elements = getLegalVars(item.value.ident, bits); item.value.ident = '('; for (var j = 1; j < elements.length; j++) { item.value.ident += 'tempRet' + (j-1) + '=' + elements[j].ident + ','; } item.value.ident += elements[0].ident + ')'; i++; continue; } case 'invoke': { legalizeFunctionParameters(value.params); // We can't add lines after this, since invoke already modifies control flow. So we handle the return in invoke i++; continue; } case 'value': { bits = getBits(value.type); var elements = getLegalVars(item.assignTo, bits); var values = getLegalLiterals(item.ident, bits); var j = 0; var toAdd = elements.map(function(element) { return { intertype: 'value', assignTo: element.ident, type: 'i' + bits, ident: values[j++].ident }; }); i += removeAndAdd(label.lines, i, toAdd); continue; } case 'structvalue': { bits = getBits(value.type); var elements = getLegalVars(item.assignTo, bits); var toAdd = []; for (var j = 0; j < item.params.length; j++) { toAdd[j] = { intertype: 'value', assignTo: elements[j].ident, type: 'i32', ident: item.params[j].ident }; } i += removeAndAdd(label.lines, i, toAdd); continue; } case 'load': { bits = getBits(value.valueType); var elements = getLegalVars(item.assignTo, bits); var j = 0; var toAdd = []; elements.forEach(function(element) { var tempVar = '$st$' + i + '$' + j; toAdd.push({ intertype: 'getelementptr', assignTo: tempVar, ident: value.pointer.ident, type: '[0 x i32]*', params: [ { intertype: 'value', ident: value.pointer.ident, type: '[0 x i32]*' }, // technically bitcast is needed in llvm, but not for us { intertype: 'value', ident: '0', type: 'i32' }, { intertype: 'value', ident: j.toString(), type: 'i32' } ] }); var actualSizeType = 'i' + element.bits; // The last one may be smaller than 32 bits toAdd.push({ intertype: 'load', assignTo: element.ident, pointerType: actualSizeType + '*', valueType: actualSizeType, type: actualSizeType, // XXX why is this missing from intertyper? pointer: { intertype: 'value', ident: tempVar, type: actualSizeType + '*' }, ident: tempVar, pointerType: actualSizeType + '*', align: value.align }); j++; }); Types.needAnalysis['[0 x i32]'] = 0; i += removeAndAdd(label.lines, i, toAdd); continue; } case 'phi': { bits = getBits(value.type); var toAdd = []; var elements = getLegalVars(item.assignTo, bits); var j = 0; var values = getLegalParams(value.params, bits); elements.forEach(function(element) { var k = 0; toAdd.push({ intertype: 'phi', assignTo: element.ident, type: 'i' + element.bits, params: value.params.map(function(param) { return { intertype: 'phiparam', label: param.label, value: { intertype: 'value', ident: values[k++][j].ident, type: 'i' + element.bits, } }; }) }); j++; }); i += removeAndAdd(label.lines, i, toAdd); continue; } case 'switch': { i++; continue; // special case, handled in makeComparison } case 'extractvalue': { // XXX we assume 32-bit alignment in extractvalue/insertvalue, // but in theory they can run on packed structs too (see use getStructuralTypePartBits) // potentially legalize the actual extracted value too if it is >32 bits, not just the extraction in general var index = item.indexes[0][0].text; var parts = getStructureTypeParts(item.type); var indexedType = parts[index]; var targetBits = getBits(indexedType); var sourceBits = getBits(item.type); var elements = getLegalVars(item.assignTo, targetBits, true); // possibly illegal var sourceElements = getLegalVars(item.ident, sourceBits); // definitely illegal var toAdd = []; var sourceIndex = 0; for (var partIndex = 0; partIndex < parts.length; partIndex++) { if (partIndex == index) { for (var j = 0; j < elements.length; j++) { toAdd.push({ intertype: 'value', assignTo: elements[j].ident, type: 'i' + elements[j].bits, ident: sourceElements[sourceIndex+j].ident }); } break; } sourceIndex += getStructuralTypePartBits(parts[partIndex])/32; } i += removeAndAdd(label.lines, i, toAdd); continue; } case 'insertvalue': { var index = item.indexes[0][0].text; // the modified index var parts = getStructureTypeParts(item.type); var indexedType = parts[index]; var indexBits = getBits(indexedType); var bits = getBits(item.type); // source and target bits = getBits(value.type); var toAdd = []; var elements = getLegalVars(item.assignTo, bits); var sourceElements = getLegalVars(item.ident, bits); var indexElements = getLegalVars(item.value.ident, indexBits, true); // possibly legal var sourceIndex = 0; for (var partIndex = 0; partIndex < parts.length; partIndex++) { var currNum = getStructuralTypePartBits(parts[partIndex])/32; for (var j = 0; j < currNum; j++) { toAdd.push({ intertype: 'value', assignTo: elements[sourceIndex+j].ident, type: 'i' + elements[sourceIndex+j].bits, ident: partIndex == index ? indexElements[j].ident : sourceElements[sourceIndex+j].ident }); } sourceIndex += currNum; } i += removeAndAdd(label.lines, i, toAdd); continue; } case 'bitcast': { var inType = item.type2; 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)) { i++; continue; // special case, handled in processMathop } // fall through } case 'inttoptr': case 'ptrtoint': case 'zext': case 'sext': case 'trunc': case 'ashr': case 'lshr': case 'shl': case 'or': case 'and': case 'xor': { value = { op: item.intertype, variant: item.variant, type: item.type, params: item.params }; // fall through } case 'mathop': { var toAdd = []; var sourceBits = getBits(value.params[0].type); // All mathops can be parametrized by how many shifts we do, and how big the source is var shifts = 0; var targetBits = sourceBits; var processor = null; var signed = false; switch (value.op) { case 'ashr': { signed = true; // fall through } case 'lshr': { shifts = parseInt(value.params[1].ident); break; } case 'shl': { shifts = -parseInt(value.params[1].ident); break; } case 'sext': { signed = true; // fall through } case 'trunc': case 'zext': case 'ptrtoint': { targetBits = getBits(value.params[1] ? value.params[1].ident : value.type); break; } case 'inttoptr': { targetBits = 32; break; } case 'bitcast': { if (!sourceBits) { // we can be asked to bitcast doubles or such to integers, handle that as best we can (if it's a double that // was an x86_fp80, this code will likely break when called) sourceBits = targetBits = Runtime.getNativeTypeSize(value.params[0].type); warn('legalizing non-integer bitcast on ll #' + item.lineNum); } break; } case 'select': { sourceBits = targetBits = getBits(value.params[1].type); var params = getLegalParams(value.params.slice(1), sourceBits); processor = function(result, j) { return { intertype: 'mathop', op: 'select', type: 'i' + params[0][j].bits, params: [ value.params[0], { intertype: 'value', ident: params[0][j].ident, type: 'i' + params[0][j].bits }, { intertype: 'value', ident: params[1][j].ident, type: 'i' + params[1][j].bits } ] }; }; break; } case 'or': case 'and': case 'xor': case 'icmp': { var otherElements = getLegalVars(value.params[1].ident, sourceBits); processor = function(result, j) { return { intertype: 'mathop', op: value.op, variant: value.variant, type: 'i' + otherElements[j].bits, params: [ result, { intertype: 'value', ident: otherElements[j].ident, type: 'i' + otherElements[j].bits } ] }; }; if (value.op == 'icmp') { if (sourceBits == 64) { // handle the i64 case in processMathOp, where we handle full i64 math i++; continue; } finalizer = function() { var ident = ''; for (var i = 0; i < targetElements.length; i++) { if (i > 0) { switch(value.variant) { case 'eq': ident += '&'; break; case 'ne': ident += '|'; break; default: throw 'unhandleable illegal icmp: ' + value.variant; } } ident += targetElements[i].ident; } return { intertype: 'value', ident: ident, type: 'rawJS', assignTo: item.assignTo }; } } break; } case 'add': case 'sub': case 'sdiv': case 'udiv': case 'mul': case 'urem': case 'srem': case 'uitofp': case 'sitofp': case 'fptosi': case 'fptoui': { // We cannot do these in parallel chunks of 32-bit operations. We will handle these in processMathop i++; continue; } default: throw 'Invalid mathop for legalization: ' + [value.op, item.lineNum, dump(item)]; } // Do the legalization var sourceElements; if (sourceBits <= 32) { // The input is a legal type sourceElements = [{ ident: value.params[0].ident, bits: sourceBits }]; } else { sourceElements = getLegalVars(value.params[0].ident, sourceBits); } if (!isNumber(shifts)) { // We can't statically legalize this, do the operation at runtime TODO: optimize assert(sourceBits == 64, 'TODO: handle nonconstant shifts on != 64 bits'); value.intertype = 'value'; value.ident = 'Runtime' + (ASM_JS ? '_' : '.') + 'bitshift64(' + asmCoercion(sourceElements[0].ident, 'i32') + ',' + asmCoercion(sourceElements[1].ident, 'i32') + ',' + Runtime['BITSHIFT64_' + value.op.toUpperCase()] + ',' + asmCoercion(value.params[1].ident + '$0', 'i32') + ');' + 'var ' + value.assignTo + '$0 = ' + makeGetTempDouble(0, 'i32') + ', ' + value.assignTo + '$1 = ' + makeGetTempDouble(1, 'i32') + ';'; value.assignTo = null; i++; continue; } var targetElements = getLegalVars(item.assignTo, targetBits); var sign = shifts >= 0 ? 1 : -1; var shiftOp = shifts >= 0 ? 'shl' : 'lshr'; var shiftOpReverse = shifts >= 0 ? 'lshr' : 'shl'; var whole = shifts >= 0 ? Math.floor(shifts/32) : Math.ceil(shifts/32); var fraction = Math.abs(shifts % 32); if (signed) { var signedFill = '(' + makeSignOp(sourceElements[sourceElements.length-1].ident, 'i' + sourceElements[sourceElements.length-1].bits, 're', 1, 1) + ' < 0 ? -1 : 0)'; var signedKeepAlive = { intertype: 'value', ident: sourceElements[sourceElements.length-1].ident, type: 'i32' }; } for (var j = 0; j < targetElements.length; j++) { var result = { intertype: 'value', ident: (j + whole >= 0 && j + whole < sourceElements.length) ? sourceElements[j + whole].ident : (signed ? signedFill : '0'), params: [(signed && j + whole > sourceElements.length) ? signedKeepAlive : null], type: 'i32', }; if (j == 0 && sourceBits < 32) { // zext sign correction result.ident = makeSignOp(result.ident, 'i' + sourceBits, isUnsignedOp(value.op) ? 'un' : 're', 1, 1); } if (fraction != 0) { var other = { intertype: 'value', ident: (j + sign + whole >= 0 && j + sign + whole < sourceElements.length) ? sourceElements[j + sign + whole].ident : (signed ? signedFill : '0'), params: [(signed && j + sign + whole > sourceElements.length) ? signedKeepAlive : null], type: 'i32', }; other = { intertype: 'mathop', op: shiftOp, type: 'i32', params: [ other, { intertype: 'value', ident: (32 - fraction).toString(), type: 'i32' } ] }; result = { intertype: 'mathop', // shifting in 1s from the top is a special case op: (signed && shifts >= 0 && j + sign + whole >= sourceElements.length) ? 'ashr' : shiftOpReverse, type: 'i32', params: [ result, { intertype: 'value', ident: fraction.toString(), type: 'i32' } ] }; result = { intertype: 'mathop', op: 'or', type: 'i32', params: [ result, other ] } } if (targetElements[j].bits < 32 && shifts < 0) { // truncate bits that fall off the end. This is not needed in most cases, can probably be optimized out result = { intertype: 'mathop', op: 'and', type: 'i32', params: [ result, { intertype: 'value', ident: (Math.pow(2, targetElements[j].bits)-1).toString(), type: 'i32' } ] } } if (processor) { result = processor(result, j); } result.assignTo = targetElements[j].ident; toAdd.push(result); } if (targetBits <= 32) { // We are generating a normal legal type here legalValue = { intertype: 'value', ident: targetElements[0].ident + (targetBits < 32 ? '&' + (Math.pow(2, targetBits)-1) : ''), type: 'rawJS' }; legalValue.assignTo = item.assignTo; toAdd.push(legalValue); } else if (finalizer) { toAdd.push(finalizer()); } i += removeAndAdd(label.lines, i, toAdd); continue; } } assert(0, 'Could not legalize illegal line: ' + [item.lineNum, dump(item)]); } if (dcheck('legalizer')) dprint('zz legalized: \n' + dump(label.lines)); }); }); } // Add function lines to func.lines, after our modifications to the label lines data.functions.forEach(function(func) { func.labels.forEach(function(label) { func.lines = func.lines.concat(label.lines); }); }); this.forwardItem(data, 'Typevestigator'); } }); function addTypeInternal(type, data) { if (type.length == 1) return; if (Types.types[type]) return; if (['internal', 'hidden', 'inbounds', 'void'].indexOf(type) != -1) return; if (Runtime.isNumberType(type)) return; dprint('types', 'Adding type: ' + type); // 'blocks': [14 x %struct.X] etc. If this is a pointer, we need // to look at the underlying type - it was not defined explicitly // anywhere else. var nonPointing = removeAllPointing(type); var check = /^\[(\d+)\ x\ (.*)\]$/.exec(nonPointing); if (check && !Types.types[nonPointing]) { var num = parseInt(check[1]); num = Math.max(num, 1); // [0 x something] is used not for allocations and such of course, but // for indexing - for an |array of unknown length|, basically. So we // define the 'type' as having a single field. TODO: Ensure as a sanity // check that we never allocate with this (either as a child structure // in the analyzer, or in calcSize in alloca). var subType = check[2]; addTypeInternal(subType, data); // needed for anonymous structure definitions (see below) // Huge structural types are represented very inefficiently, both here and in generated JS. Best to avoid them - for example static char x[10*1024*1024]; is bad, while static char *x = malloc(10*1024*1024) is fine. if (num >= 10*1024*1024) warnOnce('warning: very large fixed-size structural type: ' + type + ' - can you reduce it? (compilation may be slow)'); Types.types[nonPointing] = { name_: nonPointing, fields: range(num).map(function() { return subType }), lineNum: '?' }; // Also add a |[0 x type]| type var zerod = '[0 x ' + subType + ']'; if (!Types.types[zerod]) { Types.types[zerod] = { name_: zerod, fields: [subType, subType], // Two, so we get the flatFactor right. We care about the flatFactor, not the size here lineNum: '?' }; } return; } // anonymous structure definition, for example |{ i32, i8*, void ()*, i32 }| if (type[0] == '{' || type[0] == '<') { type = nonPointing; var packed = type[0] == '<'; Types.types[type] = { name_: type, fields: splitTokenList(tokenize(type.substr(2 + packed, type.length - 4 - 2*packed)).tokens).map(function(segment) { return segment[0].text; }), packed: packed, lineNum: '?' }; return; } if (isPointerType(type)) return; if (['['].indexOf(type) != -1) return; Types.types[type] = { name_: type, fields: [ 'i' + (QUANTUM_SIZE*8) ], // a single quantum size flatSize: 1, lineNum: '?' }; } function addType(type, data) { addTypeInternal(type, data); if (QUANTUM_SIZE === 1) { Types.flipTypes(); addTypeInternal(type, data); Types.flipTypes(); } } // Typevestigator substrate.addActor('Typevestigator', { processItem: function(data) { if (sidePass) { // Do not investigate in the main pass - it is only valid to start to do so in the first side pass, // which handles type definitions, and later. Doing so before the first side pass will result in // making bad guesses about types which are actually defined for (var type in Types.needAnalysis) { if (type) addType(type, data); } Types.needAnalysis = {}; } this.forwardItem(data, 'Typeanalyzer'); } }); // Type analyzer substrate.addActor('Typeanalyzer', { processItem: function analyzeTypes(item, fatTypes) { var types = Types.types; // 'fields' is the raw list of LLVM fields. However, we embed // child structures into parent structures, basically like C. // So { int, { int, int }, int } would be represented as // an Array of 4 ints. getelementptr on the parent would take // values 0, 1, 2, where 2 is the entire middle structure. // We also need to be careful with getelementptr to child // structures - we return a pointer to the same slab, just // a different offset. Likewise, need to be careful for // getelementptr of 2 (the last int) - it's real index is 4. // The benefit of this approach is inheritance - // { { ancestor } , etc. } = descendant // In this case it is easy to bitcast ancestor to descendant // pointers - nothing needs to be done. If the ancestor were // a new slab, it would need some pointer to the outer one // for casting in that direction. // TODO: bitcasts of non-inheritance cases of embedding (not at start) var more = true; while (more) { more = false; for (var typeName in types) { var type = types[typeName]; if (type.flatIndexes) continue; var ready = true; type.fields.forEach(function(field) { if (isStructType(field)) { if (!types[field]) { addType(field, item); ready = false; } else { if (!types[field].flatIndexes) { ready = false; } } } }); if (!ready) { more = true; continue; } Runtime.calculateStructAlignment(type); if (dcheck('types')) dprint('type (fat=' + !!fatTypes + '): ' + type.name_ + ' : ' + JSON.stringify(type.fields)); if (dcheck('types')) dprint(' has final size of ' + type.flatSize + ', flatting: ' + type.needsFlattening + ' ? ' + (type.flatFactor ? type.flatFactor : JSON.stringify(type.flatIndexes))); } } if (QUANTUM_SIZE === 1 && !fatTypes) { Types.flipTypes(); // Fake a quantum size of 4 for fat types. TODO: Might want non-4 for some reason? var trueQuantumSize = QUANTUM_SIZE; Runtime.QUANTUM_SIZE = 4; analyzeTypes(item, true); Runtime.QUANTUM_SIZE = trueQuantumSize; Types.flipTypes(); } if (!fatTypes) { this.forwardItem(item, 'VariableAnalyzer'); } } }); // Variable analyzer substrate.addActor('VariableAnalyzer', { processItem: function(item) { // Globals var old = item.globalVariables; item.globalVariables = {}; old.forEach(function(variable) { variable.impl = 'emulated'; // All global variables are emulated, for now. Consider optimizing later if useful item.globalVariables[variable.ident] = variable; }); // Function locals item.functions.forEach(function(func) { func.variables = {}; // LLVM is SSA, so we always have a single assignment/write. We care about // the reads/other uses. // Function parameters func.params.forEach(function(param) { if (param.intertype !== 'varargs') { func.variables[param.ident] = { ident: param.ident, type: param.type, origin: 'funcparam', lineNum: func.lineNum, rawLinesIndex: -1 }; } }); // Normal variables func.lines.forEach(function(item, i) { if (item.assignTo) { var variable = func.variables[item.assignTo] = { ident: item.assignTo, type: item.type, origin: item.intertype, lineNum: item.lineNum, rawLinesIndex: i }; if (variable.origin === 'alloca') { variable.allocatedNum = item.allocatedNum; } } }); if (QUANTUM_SIZE === 1) { // Second pass over variables - notice when types are crossed by bitcast func.lines.forEach(function(item) { if (item.assignTo && item.intertype === 'bitcast') { // bitcasts are unique in that they convert one pointer to another. We // sometimes need to know the original type of a pointer, so we save that. // // originalType is the type this variable is created from // derivedTypes are the types that this variable is cast into func.variables[item.assignTo].originalType = item.type2; if (!isNumber(item.assignTo)) { if (!func.variables[item.assignTo].derivedTypes) { func.variables[item.assignTo].derivedTypes = []; } func.variables[item.assignTo].derivedTypes.push(item.type); } } }); } // Analyze variable uses function analyzeVariableUses() { dprint('vars', 'Analyzing variables for ' + func.ident + '\n'); for (vname in func.variables) { var variable = func.variables[vname]; // Whether the value itself is used. For an int, always yes. For a pointer, // we might never use the pointer's value - we might always just store to it / // read from it. If so, then we can optimize away the pointer. variable.hasValueTaken = false; variable.pointingLevels = pointingLevels(variable.type); variable.uses = 0; } // TODO: improve the analysis precision. bitcast, for example, means we take the value, but perhaps we only use it to load/store var inNoop = 0; func.lines.forEach(function(line) { walkInterdata(line, function(item) { if (item.intertype == 'noop') inNoop++; if (!inNoop) { if (item.ident in func.variables) { func.variables[item.ident].uses++; if (item.intertype != 'load' && item.intertype != 'store') { func.variables[item.ident].hasValueTaken = true; } } } }, function(item) { if (item.intertype == 'noop') inNoop--; }); }); //if (dcheck('vars')) dprint('analyzed variables: ' + dump(func.variables)); } analyzeVariableUses(); // Decision time for (vname in func.variables) { var variable = func.variables[vname]; var pointedType = pointingLevels(variable.type) > 0 ? removePointing(variable.type) : null; if (variable.origin == 'getelementptr') { // Use our implementation that emulates pointers etc. // TODO Can we perhaps nativize some of these? However to do so, we need to discover their // true types; we have '?' for them now, as they cannot be discovered in the intertyper. variable.impl = VAR_EMULATED; } else if (variable.origin == 'funcparam') { variable.impl = VAR_EMULATED; } else if (variable.type == 'i64*' && USE_TYPED_ARRAYS == 2) { variable.impl = VAR_EMULATED; } else if (MICRO_OPTS && variable.pointingLevels === 0) { // A simple int value, can be implemented as a native variable variable.impl = VAR_NATIVE; } else if (MICRO_OPTS && variable.origin === 'alloca' && !variable.hasValueTaken && variable.allocatedNum === 1 && (Runtime.isNumberType(pointedType) || Runtime.isPointerType(pointedType))) { // A pointer to a value which is only accessible through this pointer. Basically // a local value on the stack, which nothing fancy is done on. So we can // optimize away the pointing altogether, and just have a native variable variable.impl = VAR_NATIVIZED; } else { variable.impl = VAR_EMULATED; } if (dcheck('vars')) dprint('// var ' + vname + ': ' + JSON.stringify(variable)); } }); this.forwardItem(item, 'Signalyzer'); } }); // Sign analyzer // // Analyze our variables and detect their signs. In USE_TYPED_ARRAYS == 2, // we can read signed or unsigned values and prevent the need for signing // corrections. If on the other hand we are doing corrections anyhow, then // we can skip this pass. // // For each variable that is the result of a Load, we look a little forward // to see where it is used. We only care about mathops, since only they // need signs. // substrate.addActor('Signalyzer', { processItem: function(item) { this.forwardItem(item, 'QuantumFixer'); if (USE_TYPED_ARRAYS != 2 || CORRECT_SIGNS == 1) return; function seekIdent(item, obj) { if (item.ident === obj.ident) { obj.found++; } } function seekMathop(item, obj) { if (item.intertype === 'mathop' && obj.found && !obj.decided) { if (isUnsignedOp(item.op, item.variant)) { obj.unsigned++; } else { obj.signed++; } } } item.functions.forEach(function(func) { func.lines.forEach(function(line, i) { if (line.intertype === 'load') { // Floats have no concept of signedness. Mark them as 'signed', which is the default, for which we do nothing if (line.type in Runtime.FLOAT_TYPES) { line.unsigned = false; return; } // Booleans are always unsigned var data = func.variables[line.assignTo]; if (data.type === 'i1') { line.unsigned = true; return; } var total = data.uses; if (total === 0) return; var obj = { ident: line.assignTo, found: 0, unsigned: 0, signed: 0, total: total }; // in loops with phis, we can also be used *before* we are defined var j = i-1, k = i+1; while(1) { assert(j >= 0 || k < func.lines.length, 'Signalyzer ran out of space to look for sign indications for line ' + line.lineNum); if (j >= 0 && walkInterdata(func.lines[j], seekIdent, seekMathop, obj)) break; if (k < func.lines.length && walkInterdata(func.lines[k], seekIdent, seekMathop, obj)) break; if (obj.total && obj.found >= obj.total) break; // see comment below j -= 1; k += 1; } // unsigned+signed might be < total, since the same ident can appear multiple times in the same mathop. // found can actually be > total, since we currently have the same ident in a GEP (see cubescript test) // in the GEP item, and a child item (we have the ident copied onto the GEP item as a convenience). // probably not a bug-causer, but FIXME. see also a reference to this above // we also leave the loop above potentially early due to this. otherwise, though, we end up scanning the // entire function in some cases which is very slow assert(obj.found >= obj.total, 'Could not Signalyze line ' + line.lineNum); line.unsigned = obj.unsigned > 0; dprint('vars', 'Signalyzer: ' + line.assignTo + ' has unsigned == ' + line.unsigned + ' (line ' + line.lineNum + ')'); } }); }); } }); // Quantum fixer // // See settings.js for the meaning of QUANTUM_SIZE. The issue we fix here is, // to correct the .ll assembly code so that things work with QUANTUM_SIZE=1. // substrate.addActor('QuantumFixer', { processItem: function(item) { this.forwardItem(item, 'LabelAnalyzer'); if (QUANTUM_SIZE !== 1) return; // ptrs: the indexes of parameters that are pointers, whose originalType is what we want // bytes: the index of the 'bytes' parameter // TODO: malloc, realloc? var FIXABLE_CALLS = { 'memcpy': { ptrs: [0,1], bytes: 2 }, 'memmove': { ptrs: [0,1], bytes: 2 }, 'memset': { ptrs: [0], bytes: 2 }, 'qsort': { ptrs: [0], bytes: 2 } }; function getSize(types, type, fat) { if (types[type]) return types[type].flatSize; if (fat) { Runtime.QUANTUM_SIZE = 4; } var ret = Runtime.getNativeTypeSize(type); if (fat) { Runtime.QUANTUM_SIZE = 1; } return ret; } function getFlatIndexes(types, type) { if (types[type]) return types[type].flatIndexes; return [0]; } item.functions.forEach(function(func) { function getOriginalType(param) { function get() { if (param.intertype === 'value' && !isNumber(param.ident)) { if (func.variables[param.ident]) { return func.variables[param.ident].originalType || null; } else { return item.globalVariables[param.ident].originalType; } } else if (param.intertype === 'bitcast') { return param.params[0].type; } else if (param.intertype === 'getelementptr') { if (param.params[0].type[0] === '[') return param.params[0].type; } return null; } var ret = get(); if (ret && ret[0] === '[') { var check = /^\[(\d+)\ x\ (.*)\]\*$/.exec(ret); assert(check); ret = check[2] + '*'; } return ret; } func.lines.forEach(function(line) { // Call if (line.intertype === 'call') { var funcIdent = LibraryManager.getRootIdent(line.ident.substr(1)); var fixData = FIXABLE_CALLS[funcIdent]; if (!fixData) return; var ptrs = fixData.ptrs.map(function(ptr) { return line.params[ptr] }); var bytes = line.params[fixData.bytes].ident; // Only consider original types. This assumes memcpy always has pointers bitcast to i8* var originalTypes = ptrs.map(getOriginalType); for (var i = 0; i < originalTypes.length; i++) { if (!originalTypes[i]) return; } originalTypes = originalTypes.map(function(type) { return removePointing(type) }); var sizes = originalTypes.map(function(type) { return getSize(Types.types, type) }); var fatSizes = originalTypes.map(function(type) { return getSize(Types.fatTypes, type, true) }); // The sizes may not be identical, if we copy a descendant class into a parent class. We use // the smaller size in that case. However, this may also be a bug, it is hard to tell, hence a warning warn(dedup(sizes).length === 1, 'All sizes should probably be identical here: ' + dump(originalTypes) + ':' + dump(sizes) + ':' + line.lineNum); warn(dedup(fatSizes).length === 1, 'All fat sizes should probably be identical here: ' + dump(originalTypes) + ':' + dump(sizes) + ':' + line.lineNum); var size = Math.min.apply(null, sizes); var fatSize = Math.min.apply(null, fatSizes); if (isNumber(bytes)) { // Figure out how much to copy. var fixedBytes; if (bytes % fatSize === 0) { fixedBytes = size*(bytes/fatSize); } else if (fatSize % bytes === 0 && size % (fatSize/bytes) === 0) { // Assume this is a simple array. XXX We can be wrong though! See next TODO fixedBytes = size/(fatSize/bytes); } else { // Just part of a structure. Align them to see how many fields. Err on copying more. // TODO: properly generate a complete structure, including nesteds, and calculate on that var flatIndexes = getFlatIndexes(Types.types, originalTypes[0]).concat(size); var fatFlatIndexes = getFlatIndexes(Types.fatTypes, originalTypes[0]).concat(fatSize); var index = 0; var left = bytes; fixedBytes = 0; while (left > 0) { left -= fatFlatIndexes[index+1] - fatFlatIndexes[index]; // note: we copy the alignment bytes too, which is unneeded fixedBytes += flatIndexes[index+1] - flatIndexes[index]; } } line.params[fixData.bytes].ident = fixedBytes; } else { line.params[fixData.bytes].intertype = 'jsvalue'; // We have an assertion in library::memcpy() that this is round line.params[fixData.bytes].ident = size + '*(' + bytes + '/' + fatSize + ')'; } } }); }); // 2nd part - fix hardcoded constant offsets in global constants values(item.globalVariables).forEach(function(variable) { function recurse(item) { if (item.contents) { item.contents.forEach(recurse); } else if (item.intertype === 'getelementptr' && item.params[0].intertype === 'bitcast' && item.params[0].type === 'i8*') { var originalType = removePointing(item.params[0].params[0].type); var fatSize = getSize(Types.fatTypes, originalType, true); var slimSize = getSize(Types.types, originalType, false); assert(fatSize % slimSize === 0); item.params.slice(1).forEach(function(param) { if (param.intertype === 'value' && isNumber(param.ident)) { var corrected = parseInt(param.ident)/(fatSize/slimSize); assert(corrected % 1 === 0); param.ident = corrected.toString(); } }); } else if (item.params) { item.params.forEach(recurse); } } if (!variable.external && variable.value) recurse(variable.value); }); } }); function operateOnLabels(line, func) { function process(item, id) { ['label', 'labelTrue', 'labelFalse', 'toLabel', 'unwindLabel', 'defaultLabel'].forEach(function(id) { if (item[id]) { func(item, id); } }); } if (line.intertype in BRANCH_INVOKE) { process(line); } else if (line.intertype == 'switch') { process(line); line.switchLabels.forEach(process); } } // Label analyzer substrate.addActor('LabelAnalyzer', { processItem: function(item) { item.functions.forEach(function(func) { func.labelsDict = {}; func.labelIds = {}; func.labelIdsInverse = {}; func.labelIds[toNiceIdent('%0')] = 0; func.labelIdsInverse[0] = toNiceIdent('%0'); func.labelIds[toNiceIdent('%1')] = 1; func.labelIdsInverse[1] = toNiceIdent('%1'); func.labelIdCounter = 2; func.labels.forEach(function(label) { func.labelIds[label.ident] = func.labelIdCounter++; func.labelIdsInverse[func.labelIdCounter-1] = label.ident; }); // Minify label ids to numeric ids. func.labels.forEach(function(label) { label.ident = func.labelIds[label.ident]; label.lines.forEach(function(line) { operateOnLabels(line, function(item, id) { item[id] = func.labelIds[item[id]].toString(); // strings, because we will append as we process }); }); }); func.labels.forEach(function(label) { func.labelsDict[label.ident] = label; }); // Correct phis func.labels.forEach(function(label) { label.lines.forEach(function(phi) { if (phi.intertype == 'phi') { for (var i = 0; i < phi.params.length; i++) { phi.params[i].label = func.labelIds[phi.params[i].label]; if (VERBOSE && !phi.params[i].label) warn('phi refers to nonexistent label on line ' + phi.lineNum); } } }); }); func.lines.forEach(function(line) { if (line.intertype == 'indirectbr') { func.forceEmulated = true; } }); // The entry might not have an explicit label, and there is no consistent naming convention for it - it can be %0 or %1 // So we need to handle that in a special way here. function getActualLabelId(labelId) { if (func.labelsDict[labelId]) return labelId; if (labelId in ENTRY_IDENT_IDS) { labelId = func.labelIds[ENTRY_IDENT]; assert(func.labelsDict[labelId]); return labelId; } return null; } // Basic longjmp support, see library.js setjmp/longjmp var setjmp = toNiceIdent('@setjmp'); func.setjmpTable = null; for (var i = 0; i < func.labels.length; i++) { var label = func.labels[i]; for (var j = 0; j < label.lines.length; j++) { var line = label.lines[j]; if (line.intertype == 'call' && line.ident == setjmp) { // Add a new label var oldIdent = label.ident; var newIdent = func.labelIdCounter++; if (!func.setjmpTable) func.setjmpTable = []; func.setjmpTable.push([oldIdent, newIdent, line.assignTo]); func.labels.splice(i+1, 0, { intertype: 'label', ident: newIdent, lineNum: label.lineNum + 0.5, lines: label.lines.slice(j+1) }); label.lines = label.lines.slice(0, j+1); label.lines.push({ intertype: 'branch', label: toNiceIdent(newIdent), lineNum: line.lineNum + 0.01, // XXX legalizing might confuse this }); // Correct phis func.labels.forEach(function(label) { label.lines.forEach(function(phi) { if (phi.intertype == 'phi') { for (var i = 0; i < phi.params.length; i++) { var sourceLabelId = getActualLabelId(phi.params[i].label); if (sourceLabelId == oldIdent) { phi.params[i].label = newIdent; } } } }); }); } } } if (func.setjmpTable) { func.forceEmulated = true; recomputeLines(func); } // Properly implement phis, by pushing them back into the branch // that leads to here. We will only have the |var| definition in this location. // First, push phis back func.labels.forEach(function(label) { label.lines.forEach(function(phi) { if (phi.intertype == 'phi') { for (var i = 0; i < phi.params.length; i++) { var param = phi.params[i]; if (VERBOSE && !param.label) warn('phi refers to nonexistent label on line ' + phi.lineNum); var sourceLabelId = getActualLabelId(param.label); if (sourceLabelId) { var sourceLabel = func.labelsDict[sourceLabelId]; var lastLine = sourceLabel.lines.slice(-1)[0]; assert(lastLine.intertype in LLVM.PHI_REACHERS, 'Only some can lead to labels with phis:' + [func.ident, label.ident, lastLine.intertype]); if (!lastLine.phi) { lastLine.phi = true; assert(!lastLine.dependent); lastLine.dependent = { intertype: 'phiassigns', params: [] }; }; lastLine.dependent.params.push({ intertype: 'phiassign', ident: phi.assignTo, value: param.value, targetLabel: label.ident }); } } // The assign to phi is now just a var phi.intertype = 'var'; phi.ident = phi.assignTo; phi.assignTo = null; } }); }); if (func.ident in NECESSARY_BLOCKADDRS) { Functions.blockAddresses[func.ident] = {}; for (var needed in NECESSARY_BLOCKADDRS[func.ident]) { assert(needed in func.labelIds); Functions.blockAddresses[func.ident][needed] = func.labelIds[needed]; } } }); this.forwardItem(item, 'StackAnalyzer'); } }); // Stack analyzer - calculate the base stack usage substrate.addActor('StackAnalyzer', { processItem: function(data) { data.functions.forEach(function(func) { var lines = func.labels[0].lines; for (var i = 0; i < lines.length; i++) { var item = lines[i]; if (!item.assignTo || item.intertype != 'alloca' || !isNumber(item.allocatedNum)) break; item.allocatedSize = func.variables[item.assignTo].impl === VAR_EMULATED ? calcAllocatedSize(item.allocatedType)*item.allocatedNum: 0; if (USE_TYPED_ARRAYS === 2) { // We need to keep the stack aligned item.allocatedSize = Runtime.forceAlign(item.allocatedSize, QUANTUM_SIZE); } } var index = 0; for (var i = 0; i < lines.length; i++) { var item = lines[i]; if (!item.assignTo || item.intertype != 'alloca' || !isNumber(item.allocatedNum)) break; item.allocatedIndex = index; index += item.allocatedSize; delete item.allocatedSize; } func.initialStack = index; func.otherStackAllocations = false; while (func.initialStack == 0) { // one-time loop with possible abort in the middle // If there is no obvious need for stack management, perhaps we don't need it // (we try to optimize that way with SKIP_STACK_IN_SMALL). However, // we need to note if stack allocations other than initial allocs can happen here // If so, we need to rewind the stack when we leave. // By-value params are causes of additional allocas (although we could in theory make them normal allocas too) func.params.forEach(function(param) { if (param.byVal) { func.otherStackAllocations = true; } }); if (func.otherStackAllocations) break; // Allocas var finishedInitial = false; lines = func.lines; // We need to consider all the function lines now, not just the first label for (var i = 0; i < lines.length; i++) { var item = lines[i]; if (!finishedInitial && (!item.assignTo || item.intertype != 'alloca' || !isNumber(item.allocatedNum))) { finishedInitial = true; } if (item.intertype == 'alloca' && finishedInitial) { func.otherStackAllocations = true; break; } } if (func.otherStackAllocations) break; // Varargs for (var i = 0; i < lines.length; i++) { var item = lines[i]; if (item.intertype == 'call' && isVarArgsFunctionType(item.type)) { func.otherStackAllocations = true; break; } } if (func.otherStackAllocations) break; break; } }); this.forwardItem(data, 'Relooper'); } }); // ReLooper - reconstruct nice loops, as much as possible // This is now done in the jsify stage, using compiled relooper2 substrate.addActor('Relooper', { processItem: function(item) { function finish() { item.__finalResult__ = true; return [item]; } function makeBlock(labels, entries, labelsDict, forceEmulated) { if (labels.length == 0) return null; dprint('relooping', 'prelooping: ' + entries + ',' + labels.length + ' labels'); assert(entries && entries[0]); // need at least 1 entry var emulated = { type: 'emulated', id: 'B', labels: labels, entries: entries.slice(0) }; return emulated; } item.functions.forEach(function(func) { dprint('relooping', "// relooping function: " + func.ident); func.block = makeBlock(func.labels, [toNiceIdent(func.labels[0].ident)], func.labelsDict, func.forceEmulated); }); return finish(); } }); // Data substrate.addItem({ items: data }, 'Sorter'); // Solve it return substrate.solve(); }