/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this file, * You can obtain one at http://mozilla.org/MPL/2.0/. */ loadRelativeToScript('utility.js'); loadRelativeToScript('annotations.js'); loadRelativeToScript('CFG.js'); // Map from csu => set of immediate subclasses var subclasses = new Map(); // Map from csu => set of immediate superclasses var superclasses = new Map(); // Map from "csu.name:nargs" => set of full method name var virtualDefinitions = new Map(); // Every virtual method declaration, anywhere. // // Map from csu => Set of function-info. // function-info: { // name : simple string // typedfield : "name:nargs" ("mangled" field name) // field: full Field datastructure // annotations : Set of [annotation-name, annotation-value] 2-element arrays // inherited : whether the method is inherited from a base class // pureVirtual : whether the method is pure virtual on this CSU // dtor : if this is a virtual destructor with a definition in this class or // a superclass, then the full name of the definition as if it were defined // in this class. This is weird, but it's how gcc emits it. We will add a // synthetic call from this function to its immediate base classes' dtors, // so even if the function does not actually exist and is inherited from a // base class, we will get a path to the inherited function. (Regular // virtual methods are *not* claimed to exist when they don't.) // } var virtualDeclarations = new Map(); var virtualResolutionsSeen = new Set(); var ID = { jscode: 1, anyfunc: 2, nogcfunc: 3, gc: 4, }; // map is a map from names to sets of entries. function addToNamedSet(map, name, entry) { if (!map.has(name)) map.set(name, new Set()); const s = map.get(name); s.add(entry); return s; } // CSU is "Class/Struct/Union" function processCSU(csuName, csu) { if (!("FunctionField" in csu)) return; for (const {Base} of (csu.CSUBaseClass || [])) { addToNamedSet(subclasses, Base, csuName); addToNamedSet(superclasses, csuName, Base); } for (const {Field, Variable} of csu.FunctionField) { // Virtual method const info = Field[0]; const name = info.Name[0]; const annotations = new Set(); const funcInfo = { name, typedfield: typedField(info), field: info, annotations, inherited: (info.FieldCSU.Type.Name != csuName), // Always false for virtual dtors pureVirtual: Boolean(Variable), dtor: false, }; if (Variable && isSyntheticVirtualDestructor(name)) { // This is one of gcc's artificial dtors. funcInfo.dtor = Variable.Name[0]; funcInfo.pureVirtual = false; } addToNamedSet(virtualDeclarations, csuName, funcInfo); if ('Annotation' in info) { for (const {Name: [annType, annValue]} of info.Annotation) { annotations.add([annType, annValue]); } } if (Variable) { // Note: not dealing with overloading correctly. const name = Variable.Name[0]; addToNamedSet(virtualDefinitions, fieldKey(csuName, Field[0]), name); } } } // Return a list of all callees that the given edge might be a call to. Each // one is represented by an object with a 'kind' field that is one of // ('direct', 'field', 'resolved-field', 'indirect', 'unknown'), though note // that 'resolved-field' is really a global record of virtual method // resolutions, indepedent of this particular edge. function getCallees(edge) { if (edge.Kind != "Call") return []; const callee = edge.Exp[0]; if (callee.Kind == "Var") { assert(callee.Variable.Kind == "Func"); return [{'kind': 'direct', 'name': callee.Variable.Name[0]}]; } // At some point, we were intentionally invoking invalid function pointers // (as in, a small integer cast to a function pointer type) to convey a // small amount of information in the crash address. if (callee.Kind == "Int") return []; // Intentional crash assert(callee.Kind == "Drf"); const called = callee.Exp[0]; if (called.Kind == "Var") { // indirect call through a variable. return [{'kind': "indirect", 'variable': callee.Exp[0].Variable.Name[0]}]; } if (called.Kind != "Fld") { // unknown call target. return [{'kind': "unknown"}]; } // Return one 'field' callee record giving the full description of what's // happening here (which is either a virtual method call, or a call through // a function pointer stored in a field), and then boil the call down to a // synthetic function that incorporates both the name of the field and the // static type of whatever you're calling the method on. Both refer to the // same call; they're just different ways of describing it. const callees = []; const field = callee.Exp[0].Field; callees.push({'kind': "field", 'csu': field.FieldCSU.Type.Name, 'field': field.Name[0], 'isVirtual': ("FieldInstanceFunction" in field)}); const staticCSU = getFieldCallInstanceCSU(edge, field); callees.push({'kind': "direct", 'name': fieldKey(staticCSU, field)}); return callees; } function loadTypes(type_xdb_filename) { const xdb = xdbLibrary(); xdb.open(type_xdb_filename); const minStream = xdb.min_data_stream(); const maxStream = xdb.max_data_stream(); for (var csuIndex = minStream; csuIndex <= maxStream; csuIndex++) { const csu = xdb.read_key(csuIndex); const data = xdb.read_entry(csu); const json = JSON.parse(data.readString()); processCSU(csu.readString(), json[0]); xdb.free_string(csu); xdb.free_string(data); } } function loadTypesWithCache(type_xdb_filename, cache_filename) { try { const cacheAB = os.file.readFile(cache_filename, "binary"); const cb = serialize(); cb.clonebuffer = cacheAB.buffer; const cacheData = deserialize(cb); subclasses = cacheData.subclasses; superclasses = cacheData.superclasses; virtualDefinitions = cacheData.virtualDefinitions; } catch (e) { loadTypes(type_xdb_filename); const cb = serialize({subclasses, superclasses, virtualDefinitions}); os.file.writeTypedArrayToFile(cache_filename, new Uint8Array(cb.arraybuffer)); } }