/**************************************************************************** ** ** Copyright (C) 2013 Digia Plc and/or its subsidiary(-ies). ** Contact: http://www.qt-project.org/legal ** ** This file is part of Qt Creator. ** ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and Digia. For licensing terms and ** conditions see http://qt.digia.com/licensing. For further information ** use the contact form at http://qt.digia.com/contact-us. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Digia gives you certain additional ** rights. These rights are described in the Digia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ****************************************************************************/ #include "containers.h" #include "symbolgroupvalue.h" #include "symbolgroup.h" #include "stringutils.h" #include #include typedef AbstractSymbolGroupNode::AbstractSymbolGroupNodePtrVector AbstractSymbolGroupNodePtrVector; typedef std::vector SymbolGroupValueVector; typedef std::vector::size_type VectorIndexType; // Read a pointer array from debuggee memory (ULONG64/32 according pointer size) static void *readPointerArray(ULONG64 address, unsigned count, const SymbolGroupValueContext &ctx) { const unsigned pointerSize = SymbolGroupValue::pointerSize(); const ULONG allocSize = pointerSize * count; ULONG bytesRead = 0; void *data = new unsigned char[allocSize]; const HRESULT hr = ctx.dataspaces->ReadVirtual(address, data, allocSize, &bytesRead); if (FAILED(hr) || bytesRead != allocSize) { delete [] data; return 0; } return data; } template inline void dumpHexArray(std::ostream &os, const UInt *a, int count) { os << std::showbase << std::hex; std::copy(a, a + count, std::ostream_iterator(os, ", ")); os << std::noshowbase << std::dec; } static inline void dump32bitPointerArray(std::ostream &os, const void *a, int count) { dumpHexArray(os, reinterpret_cast(a), count); } static inline void dump64bitPointerArray(std::ostream &os, const void *a, int count) { dumpHexArray(os, reinterpret_cast(a), count); } // Fix the inner type of containers (that is, make it work smoothly with AddSymbol) // by prefixing it with the module except for well-known types like STL/Qt types static inline std::string fixInnerType(std::string type, const SymbolGroupValue &container) { std::string stripped = SymbolGroupValue::stripConst(SymbolGroupValue::stripClassPrefixes(type)); // Unfortunately the cdb can not handle the vc exclusiv 64 bit integer // "__int64" but works fine with "int64", so we have to strip down "__" const size_t __int64pos = stripped.find("__int64"); if (__int64pos != std::string::npos) stripped.erase(__int64pos, 2); const KnownType kt = knownType(stripped, 0); // Resolve types unless they are POD or pointers to POD (that is, qualify 'Foo' and 'Foo*') const bool needResolve = kt == KT_Unknown || kt == KT_PointerType || !(kt & KT_POD_Type); const std::string fixed = needResolve ? SymbolGroupValue::resolveType(stripped, container.context(), container.module()) : stripped; if (SymbolGroupValue::verbose) { DebugPrint dp; dp << "fixInnerType (resolved=" << needResolve << ") '" << type << "' ["; formatKnownTypeFlags(dp, kt); dp << "] -> '" << fixed <<"'\n"; } return fixed; } // Return size from an STL vector (last/first iterators). static inline int msvcStdVectorSize(const SymbolGroupValue &v) { // MSVC2012 has 2 base classes, MSVC2010 1, MSVC2008 none if (const SymbolGroupValue myFirstPtrV = SymbolGroupValue::findMember(v, "_Myfirst")) { if (const SymbolGroupValue myLastPtrV = myFirstPtrV.parent()["_Mylast"]) { const ULONG64 firstPtr = myFirstPtrV.pointerValue(); const ULONG64 lastPtr = myLastPtrV.pointerValue(); if (!firstPtr || lastPtr < firstPtr) return -1; if (lastPtr == firstPtr) return 0; // Subtract the pointers: We need to do the pointer arithmetics ourselves // as we get char *pointers. const std::string innerType = fixInnerType(SymbolGroupValue::stripPointerType(myFirstPtrV.type()), v); const size_t size = SymbolGroupValue::sizeOf(innerType.c_str()); if (size == 0) return -1; return static_cast((lastPtr - firstPtr) / size); } } return -1; } // Return size of container or -1 int containerSize(KnownType kt, SymbolGroupNode *n, const SymbolGroupValueContext &ctx) { QTC_TRACE_IN if ((kt & KT_ContainerType) == 0) return -1; const int ct = containerSize(kt, SymbolGroupValue(n, ctx)); QTC_TRACE_OUT return ct; } /*! Determine size of containers \ingroup qtcreatorcdbext */ int containerSize(KnownType kt, const SymbolGroupValue &v) { switch (kt) { case KT_QStringList: if (const SymbolGroupValue base = v[unsigned(0)]) return containerSize(KT_QList, base); break; case KT_QList: if (const SymbolGroupValue dV = v["d"]) { if (const SymbolGroupValue beginV = dV["begin"]) { const int begin = beginV.intValue(); const int end = dV["end"].intValue(); if (begin >= 0 && end >= begin) return end - begin; } } break; case KT_QLinkedList: case KT_QHash: if (const SymbolGroupValue sizeV = v["d"]["size"]) return sizeV.intValue(); break; case KT_QMap: case KT_QVector: { // Inheritance from QVectorTypedData, QMapData<> in Qt 5. const SymbolGroupValue sizeV = QtInfo::get(v.context()).version >= 5 ? v["d"][unsigned(0)]["size"] : v["d"]["size"]; if (sizeV) return sizeV.intValue(); } break; case KT_QMultiHash: if (const SymbolGroupValue qHash = v[unsigned(0)]) return containerSize(KT_QHash, qHash); break; case KT_QQueue: if (const SymbolGroupValue qList= v[unsigned(0)]) return containerSize(KT_QList, qList); break; case KT_QStack: if (const SymbolGroupValue qVector = v[unsigned(0)]) return containerSize(KT_QVector, qVector); break; case KT_QSet: if (const SymbolGroupValue base = v[unsigned(0)]) return containerSize(KT_QHash, base); break; case KT_QMultiMap: if (const SymbolGroupValue base = v[unsigned(0)]) return containerSize(KT_QMap, base); break; case KT_StdVector: return msvcStdVectorSize(v); case KT_StdDeque: // MSVC2012 has many base classes, MSVC2010 1, MSVC2008 none case KT_StdSet: case KT_StdMap: case KT_StdMultiMap: case KT_StdList: if (const SymbolGroupValue size = SymbolGroupValue::findMember(v, "_Mysize")) return size.intValue(); break; case KT_StdStack: if (const SymbolGroupValue deque = v[unsigned(0)]) return containerSize(KT_StdDeque, deque); break; } return -1; } /* Generate a list of children by invoking the functions to obtain the value * and the next link */ template AbstractSymbolGroupNodePtrVector linkedListChildList(SymbolGroupValue headNode, int count, ValueFunction valueFunc, NextFunction nextFunc) { AbstractSymbolGroupNodePtrVector rc; rc.reserve(count); for (int i =0; i < count && headNode; i++) { if (const SymbolGroupValue value = valueFunc(headNode)) { rc.push_back(ReferenceSymbolGroupNode::createArrayNode(i, value.node())); headNode = nextFunc(headNode); } else { break; } } return rc; } // Helper function for linkedListChildList that returns a member by name class MemberByName : public std::unary_function { public: explicit MemberByName(const char *name) : m_name(name) {} SymbolGroupValue operator()(const SymbolGroupValue &v) { return v[m_name]; } private: const char *m_name; }; // std::list: Skip dummy head node and then a linked list of "_Next", "_Myval". static inline AbstractSymbolGroupNodePtrVector stdListChildList(SymbolGroupNode *n, int count, const SymbolGroupValueContext &ctx) { if (!count) return AbstractSymbolGroupNodePtrVector(); const SymbolGroupValue head = SymbolGroupValue::findMember(SymbolGroupValue(n, ctx), "_Myhead")["_Next"]; if (head) return linkedListChildList(head, count, MemberByName("_Myval"), MemberByName("_Next")); if (SymbolGroupValue::verbose) DebugPrint() << "std::list failure: " << head; return AbstractSymbolGroupNodePtrVector(); } // QLinkedList: Dummy head node and then a linked list of "n", "t". static inline AbstractSymbolGroupNodePtrVector qLinkedListChildList(SymbolGroupNode *n, int count, const SymbolGroupValueContext &ctx) { if (count) if (const SymbolGroupValue head = SymbolGroupValue(n, ctx)["e"]["n"]) return linkedListChildList(head, count, MemberByName("t"), MemberByName("n")); return AbstractSymbolGroupNodePtrVector(); } /* Helper for array-type containers: * Add a series of "*(innertype *)0x (address + n * size)" fake child symbols. * for a function generating a sequence of addresses. */ template AbstractSymbolGroupNodePtrVector arrayChildList(SymbolGroup *sg, AddressFunc addressFunc, const std::string &module, const std::string &innerType, int count) { AbstractSymbolGroupNodePtrVector rc; if (!count) return rc; std::string errorMessage; rc.reserve(count); for (int i = 0; i < count; i++) { const std::string name = SymbolGroupValue::pointedToSymbolName(addressFunc(), innerType); if (SymbolGroupNode *child = sg->addSymbol(module, name, std::string(), &errorMessage)) { rc.push_back(ReferenceSymbolGroupNode::createArrayNode(i, child)); } else { if (SymbolGroupValue::verbose) DebugPrint() << "addSymbol fails in arrayChildList"; break; } } if (SymbolGroupValue::verbose) DebugPrint() << "arrayChildList '" << innerType << "' count=" << count << " returns " << rc.size() << " elements"; return rc; } // Helper function for arrayChildList() taking a reference to an address and simply generating // a sequence of address, address + delta, address + 2 * delta... class AddressSequence { public: explicit inline AddressSequence(ULONG64 &address, ULONG delta) : m_address(address), m_delta(delta) {} inline ULONG64 operator()() { const ULONG64 rc = m_address; m_address += m_delta; return rc; } private: ULONG64 &m_address; const ULONG m_delta; }; static inline AbstractSymbolGroupNodePtrVector arrayChildList(SymbolGroup *sg, ULONG64 address, const std::string &module, const std::string &innerType, int count) { if (const unsigned innerTypeSize = SymbolGroupValue::sizeOf(innerType.c_str())) return arrayChildList(sg, AddressSequence(address, innerTypeSize), module, innerType, count); return AbstractSymbolGroupNodePtrVector(); } // std::vector static inline AbstractSymbolGroupNodePtrVector stdVectorChildList(SymbolGroupNode *n, int count, const SymbolGroupValueContext &ctx) { if (!count) return AbstractSymbolGroupNodePtrVector(); // MSVC2012 has 2 base classes, MSVC2010 1, MSVC2008 none const SymbolGroupValue vec = SymbolGroupValue(n, ctx); SymbolGroupValue myFirst = SymbolGroupValue::findMember(vec, "_Myfirst"); if (!myFirst) return AbstractSymbolGroupNodePtrVector(); // std::vector: _Myfirst is a pointer of T*. Get address // element to obtain address. const ULONG64 address = myFirst.pointerValue(); if (!address) return AbstractSymbolGroupNodePtrVector(); const std::string firstType = myFirst.type(); const std::string innerType = fixInnerType(SymbolGroupValue::stripPointerType(firstType), vec); if (SymbolGroupValue::verbose) DebugPrint() << n->name() << " inner type: '" << innerType << "' from '" << firstType << '\''; return arrayChildList(n->symbolGroup(), address, n->module(), innerType, count); } // Helper for std::deque<>: From the array of deque blocks, read out the values. template AbstractSymbolGroupNodePtrVector stdDequeChildrenHelper(SymbolGroup *sg, const AddressType *blockArray, ULONG64 blockArraySize, const std::string &module, const std::string &innerType, ULONG64 innerTypeSize, ULONG64 startOffset, ULONG64 dequeSize, int count) { AbstractSymbolGroupNodePtrVector rc; rc.reserve(count); std::string errorMessage; // Determine block number and offset in the block array T[][dequeSize] // and create symbol by address. for (int i = 0; i < count; i++) { // see -header: std::deque::iterator::operator* const ULONG64 offset = startOffset + i; ULONG64 block = offset / dequeSize; if (block >= blockArraySize) block -= blockArraySize; const ULONG64 blockOffset = offset % dequeSize; const ULONG64 address = blockArray[block] + innerTypeSize * blockOffset; if (SymbolGroupNode *n = sg->addSymbol(module, SymbolGroupValue::pointedToSymbolName(address, innerType), std::string(), &errorMessage)) rc.push_back(ReferenceSymbolGroupNode::createArrayNode(i, n)); else return AbstractSymbolGroupNodePtrVector(); } return rc; } // std::deque<> static inline AbstractSymbolGroupNodePtrVector stdDequeChildList(const SymbolGroupValue &dequeIn, int count) { if (!count) return AbstractSymbolGroupNodePtrVector(); // From MSVC10 on, there is an additional base class, MSVC2012 more. const SymbolGroupValue map = SymbolGroupValue::findMember(dequeIn, "_Map"); if (!map) return AbstractSymbolGroupNodePtrVector(); const SymbolGroupValue deque = map.parent(); const ULONG64 arrayAddress = map.pointerValue(); const int startOffset = deque["_Myoff"].intValue(); const int mapSize = deque["_Mapsize"].intValue(); if (!arrayAddress || startOffset < 0 || mapSize <= 0) return AbstractSymbolGroupNodePtrVector(); const std::vector innerTypes = dequeIn.innerTypes(); if (innerTypes.empty()) return AbstractSymbolGroupNodePtrVector(); const std::string innerType = fixInnerType(innerTypes.front(), deque); // Get the deque size (block size) which is an unavailable static member // (cf for the actual expression). const unsigned innerTypeSize = SymbolGroupValue::sizeOf(innerType.c_str()); if (!innerTypeSize) return AbstractSymbolGroupNodePtrVector(); const int dequeSize = innerTypeSize <= 1 ? 16 : innerTypeSize <= 2 ? 8 : innerTypeSize <= 4 ? 4 : innerTypeSize <= 8 ? 2 : 1; // Read out map array (pointing to the blocks) void *mapArray = readPointerArray(arrayAddress, mapSize, deque.context()); if (!mapArray) return AbstractSymbolGroupNodePtrVector(); const AbstractSymbolGroupNodePtrVector rc = SymbolGroupValue::pointerSize() == 8 ? stdDequeChildrenHelper(deque.node()->symbolGroup(), reinterpret_cast(mapArray), mapSize, deque.module(), innerType, innerTypeSize, startOffset, dequeSize, count) : stdDequeChildrenHelper(deque.node()->symbolGroup(), reinterpret_cast(mapArray), mapSize, deque.module(), innerType, innerTypeSize, startOffset, dequeSize, count); delete [] mapArray; return rc; } /* Helper class for red-black trees (std::map<>,std::set<> based on std::__Tree: * or Qt 5 maps). * We locally rebuild the structure in using instances of below class 'RedBlackTreeNode' * with 'left' and 'right' pointers and the values. Reason being that while it is * possible to write the iteration in terms of class SymbolGroupValue, it involves * going back up the tree over the flat node->parent pointers. Doing that in the debugger * sometimes ends up in nirvana, apparently due to it not being able to properly expand it. * RedBlackTreeNode has a buildMapRecursion() to build a hierarchy from a STL __Tree or * Qt 5 map header value, taking a helper providing node creation and left/right symbol names. * Use begin() to return the first node and next() to iterate. The latter are modeled * after the _Tree::iterator base classes. (_Tree::begin, _Tree::iterator::operator++() * STL tree nodes have a "value" member which is the pair of map data. * In Qt 5, the node is a QMapNodeBase which needs to be casted to a QMapNode. */ class RedBlackTreeNode { private: RedBlackTreeNode(const RedBlackTreeNode &); RedBlackTreeNode &operator=(const RedBlackTreeNode &); public: explicit RedBlackTreeNode(RedBlackTreeNode *p, const SymbolGroupValue &nodeValue); ~RedBlackTreeNode() { delete m_left; delete m_right; } const SymbolGroupValue &nodeValue() const { return m_node; } // Iterator helpers: Return first and move to next const RedBlackTreeNode *begin() const { return RedBlackTreeNode::leftMost(this); } static const RedBlackTreeNode *next(const RedBlackTreeNode *s); // Debug helpers template void debug(std::ostream &os, DebugFunction df, unsigned depth = 0) const; static RedBlackTreeNode *buildMapRecursion(const SymbolGroupValue &n, ULONG64 headAddress, RedBlackTreeNode *parent, const char *leftSymbol, const char *rightSymbol); static const RedBlackTreeNode *leftMost(const RedBlackTreeNode *n); private: RedBlackTreeNode *const m_parent; RedBlackTreeNode *m_left; RedBlackTreeNode *m_right; const SymbolGroupValue m_node; }; RedBlackTreeNode::RedBlackTreeNode(RedBlackTreeNode *p, const SymbolGroupValue &node) : m_parent(p), m_left(0), m_right(0), m_node(node) { } const RedBlackTreeNode *RedBlackTreeNode::leftMost(const RedBlackTreeNode *n) { for ( ; n->m_left ; n = n->m_left ) ; return n; } const RedBlackTreeNode *RedBlackTreeNode::next(const RedBlackTreeNode *s) { if (s->m_right) // If we have a right node, return its left-most return RedBlackTreeNode::leftMost(s->m_right); do { // Climb looking for 'right' subtree, that is, we are left of it RedBlackTreeNode *parent = s->m_parent; if (!parent || parent->m_right != s) return parent; s = parent; } while (true); return 0; } /* Build the tree using the helper which is asked to create the node * and provide the names of the "left" and "right" nodes. */ RedBlackTreeNode *RedBlackTreeNode::buildMapRecursion(const SymbolGroupValue &n, ULONG64 headAddress, RedBlackTreeNode *parent, const char *leftSymbol, const char *rightSymbol) { RedBlackTreeNode *node = new RedBlackTreeNode(parent, n); // Get left and right nodes. A node pointing to 0 (Qt) or 'head' (STL) terminates the recursion if (const SymbolGroupValue left = n[leftSymbol]) if (const ULONG64 leftAddr = left.pointerValue()) if (leftAddr && leftAddr != headAddress) node->m_left = buildMapRecursion(left, headAddress, node, leftSymbol, rightSymbol); if (const SymbolGroupValue right = n[rightSymbol]) if (const ULONG64 rightAddr = right.pointerValue()) if (rightAddr && rightAddr != headAddress) node->m_right = buildMapRecursion(right, headAddress, node, leftSymbol, rightSymbol); return node; } template void RedBlackTreeNode::debug(std::ostream &os, DebugFunction df, unsigned depth) const { df(m_node, os, 2 * depth); if (m_left) m_left->debug(os, df, depth + 1); if (m_right) m_right->debug(os, df, depth + 1); } static inline void indentStream(std::ostream &os, unsigned indent) { for (unsigned i = 0; i < indent; ++i) os << ' '; } // Debugging helper for a SymbolGroupValue containing a __Tree::node of // a map (assuming a std::pair inside). static void debugMSVC2010MapNode(const SymbolGroupValue &n, std::ostream &os, unsigned indent = 0) { indentStream(os, indent); os << "Node at " << std::hex << std::showbase << n.address() << std::dec << std::noshowbase << " Value='" << wStringToString(n.value()) << "', Parent=" << wStringToString(n["_Parent"].value()) << ", Left=" << wStringToString(n["_Left"].value()) << ", Right=" << wStringToString(n["_Right"].value()) << ", nil='" << wStringToString(n["_Isnil"].value()); if (const SymbolGroupValue pairBase = n["_Myval"][unsigned(0)]) { os << "', key='" << wStringToString(pairBase["first"].value()) << "', value='" << wStringToString(pairBase["second"].value()) << '\''; } else { os << "', key='" << wStringToString(n["_Myval"].value()) << '\''; } os << '\n'; } // Helper for std::map<>,std::set<> based on std::__Tree: // Return the list of children (pair for maps, direct children for set) static inline SymbolGroupValueVector stdTreeChildList(const SymbolGroupValue &treeIn, int count) { if (!count) return SymbolGroupValueVector(); // MSVC2012: many base classes. // MSVC2010: "class _Tree : public _Tree_val: public _Tree_nod". // MSVC2008: Direct class const SymbolGroupValue sizeV = SymbolGroupValue::findMember(treeIn, "_Mysize"); const SymbolGroupValue tree = sizeV.parent(); const int size = sizeV.intValue(); if (!tree|| size <= 0) return SymbolGroupValueVector(); // Build the tree and iterate it. // Goto root of tree (see _Tree::_Root()) RedBlackTreeNode *nodeTree = 0; if (const SymbolGroupValue head = tree["_Myhead"]) if (const ULONG64 headAddress = head.pointerValue()) nodeTree = RedBlackTreeNode::buildMapRecursion(head["_Parent"], headAddress, 0, "_Left", "_Right"); if (!nodeTree) return SymbolGroupValueVector(); if (SymbolGroupValue::verbose > 1) nodeTree->debug(DebugPrint(), debugMSVC2010MapNode); SymbolGroupValueVector rc; rc.reserve(count); int i = 0; for (const RedBlackTreeNode *n = nodeTree->begin() ; n && i < count; n = RedBlackTreeNode::next(n), i++) { const SymbolGroupValue value = n->nodeValue()["_Myval"]; if (!value) { delete nodeTree; return SymbolGroupValueVector(); } rc.push_back(value); } delete nodeTree; if (rc.size() != count) return SymbolGroupValueVector(); return rc; } // std::set<>: Children directly contained in list static inline AbstractSymbolGroupNodePtrVector stdSetChildList(const SymbolGroupValue &set, int count) { const SymbolGroupValueVector children = stdTreeChildList(set, count); if (int(children.size()) != count) return AbstractSymbolGroupNodePtrVector(); AbstractSymbolGroupNodePtrVector rc; rc.reserve(count); for (int i = 0; i < count; i++) rc.push_back(ReferenceSymbolGroupNode::createArrayNode(i, children.at(i).node())); return rc; } // std::map: A list of std::pair (derived from std::pair_base) static inline AbstractSymbolGroupNodePtrVector stdMapChildList(const SymbolGroupValue &map, int count) { const SymbolGroupValueVector children = stdTreeChildList(map[unsigned(0)], count); if (int(children.size()) != count) return AbstractSymbolGroupNodePtrVector(); AbstractSymbolGroupNodePtrVector rc; rc.reserve(count); const std::string firstName = "first"; for (int i = 0; i < count; i++) { // MSVC2010 (only) has a std::pair_base class. const SymbolGroupValue key = SymbolGroupValue::findMember(children.at(i), firstName); const SymbolGroupValue pairBase = key.parent(); const SymbolGroupValue value = pairBase["second"]; if (key && value) { rc.push_back(MapNodeSymbolGroupNode::create(i, pairBase.address(), pairBase.type(), key.node(), value.node())); } else { return AbstractSymbolGroupNodePtrVector(); } } return rc; } // QVector static inline AbstractSymbolGroupNodePtrVector qVectorChildList(SymbolGroupNode *n, int count, const SymbolGroupValueContext &ctx) { if (!count) return AbstractSymbolGroupNodePtrVector(); const SymbolGroupValue vec(n, ctx); const int qtVersion = QtInfo::get(vec.context()).version; if (qtVersion < 5) { // Qt 4: QVector: p/array is declared as array of T. Dereference first // element to obtain address. if (const SymbolGroupValue firstElementV = vec["p"]["array"][unsigned(0)]) { if (const ULONG64 arrayAddress = firstElementV.address()) { const std::string fixedInnerType = fixInnerType(firstElementV.type(), vec); return arrayChildList(n->symbolGroup(), arrayAddress, n->module(), fixedInnerType, count); } } return AbstractSymbolGroupNodePtrVector(); } // Qt 5: Data are located in a pool behind 'd' (similar to QString, // QByteArray). const SymbolGroupValue dV = vec["d"][unsigned(0)]; const SymbolGroupValue offsetV = dV["offset"]; if (!dV || !offsetV) return AbstractSymbolGroupNodePtrVector(); const ULONG64 arrayAddress = dV.address() + offsetV.intValue(); std::vector innerTypes = SymbolGroupValue::innerTypesOf(vec.type()); if (arrayAddress && !innerTypes.empty()) { return arrayChildList(n->symbolGroup(), arrayAddress, n->module(), fixInnerType(innerTypes.front(), vec), count); } return AbstractSymbolGroupNodePtrVector(); } // Helper function for arrayChildList() for use with QLists of large types that are an // array of pointers to allocated elements: Generate a pointer sequence by reading out the array. template class AddressArraySequence { public: explicit inline AddressArraySequence(const AddressType *array) : m_array(array) {} inline ULONG64 operator()() { return *m_array++; } private: const AddressType *m_array; }; // QList<>. static inline AbstractSymbolGroupNodePtrVector qListChildList(const SymbolGroupValue &v, int count) { // QList: d/array is declared as array of void *[]. Dereference first // element to obtain address. if (!count) return AbstractSymbolGroupNodePtrVector(); const SymbolGroupValue dV = v["d"]; if (!dV) return AbstractSymbolGroupNodePtrVector(); const int begin = dV["begin"].intValue(); if (begin < 0) return AbstractSymbolGroupNodePtrVector(); const SymbolGroupValue firstElementV = dV["array"][unsigned(0)]; if (!firstElementV) return AbstractSymbolGroupNodePtrVector(); ULONG64 arrayAddress = firstElementV.address(); if (!arrayAddress) return AbstractSymbolGroupNodePtrVector(); const std::vector innerTypes = v.innerTypes(); if (innerTypes.size() != 1) return AbstractSymbolGroupNodePtrVector(); const std::string innerType = fixInnerType(innerTypes.front(), v); const unsigned innerTypeSize = SymbolGroupValue::sizeOf(innerType.c_str()); if (SymbolGroupValue::verbose) DebugPrint() << "QList " << v.name() << " inner type " << innerType << ' ' << innerTypeSize; if (!innerTypeSize) return AbstractSymbolGroupNodePtrVector(); /* QList<> is: * 1) An array of 'void *[]' where T values are coerced into the elements for * POD/pointer types and small, movable or primitive Qt types. That is, smaller * elements are also aligned at 'void *' boundaries. * 2) An array of 'T *[]' (pointer to allocated instances) for anything else * (QTypeInfo::isLarge || QTypeInfo::isStatic) * isStatic depends on QTypeInfo specializations and hardcoded flags for types. */ const unsigned pointerSize = SymbolGroupValue::pointerSize(); arrayAddress += begin * pointerSize; if (SymbolGroupValue::isPointerType(innerType)) // Quick check: Any pointer is T[] return arrayChildList(v.node()->symbolGroup(), AddressSequence(arrayAddress, pointerSize), v.module(), innerType, count); // Check condition for large||static. bool isLargeOrStatic = innerTypeSize > pointerSize; if (!isLargeOrStatic && !SymbolGroupValue::isPointerType(innerType)) { const KnownType kt = knownType(innerType, false); // inner type, no 'class ' prefix. if (kt != KT_Unknown && !(kt & (KT_POD_Type|KT_Qt_PrimitiveType|KT_Qt_MovableType))) isLargeOrStatic = true; } if (SymbolGroupValue::verbose) DebugPrint() << "isLargeOrStatic " << isLargeOrStatic; if (isLargeOrStatic) { // Retrieve the pointer array ourselves to avoid having to evaluate '*(class foo**)' if (void *data = readPointerArray(arrayAddress, count, v.context())) { // Generate sequence of addresses from pointer array const AbstractSymbolGroupNodePtrVector rc = pointerSize == 8 ? arrayChildList(v.node()->symbolGroup(), AddressArraySequence(reinterpret_cast(data)), v.module(), innerType, count) : arrayChildList(v.node()->symbolGroup(), AddressArraySequence(reinterpret_cast(data)), v.module(), innerType, count); delete [] data; return rc; } return AbstractSymbolGroupNodePtrVector(); } return arrayChildList(v.node()->symbolGroup(), AddressSequence(arrayAddress, pointerSize), v.module(), innerType, count); } // Return the list of buckets of a 'QHash<>' as 'QHashData::Node *' values from // the list of addresses passed in template SymbolGroupValueVector hashBuckets(SymbolGroup *sg, const std::string &hashNodeType, const AddressType *pointerArray, int numBuckets, AddressType ePtr, const std::string &module, const SymbolGroupValueContext &ctx) { SymbolGroupValueVector rc; rc.reserve(numBuckets); const AddressType *end = pointerArray + numBuckets; std::string errorMessage; // Skip 'e' special values as they are used as placeholder for reserve(d) // empty array elements. for (const AddressType *p = pointerArray; p < end; p++) { if (*p != ePtr) { const std::string name = SymbolGroupValue::pointedToSymbolName(*p, hashNodeType); if (SymbolGroupNode *child = sg->addSymbol(module, name, std::string(), &errorMessage)) { rc.push_back(SymbolGroupValue(child, ctx)); } else { return std::vector(); break; } } } return rc; } // Return the node type of a QHash/QMap: // "class QHash[ *]" -> [struct] "QtCored4!QHashNode"; static inline std::string qHashNodeType(const SymbolGroupValue &v, const char *nodeType) { std::string qHashType = SymbolGroupValue::stripPointerType(v.type()); const std::string::size_type pos = qHashType.find('<'); if (pos != std::string::npos) qHashType.insert(pos, nodeType); // A map node must be qualified with the current module and // the Qt namespace (particularly QMapNode, QHashNodes work also for // the unqualified case). const QtInfo &qtInfo = QtInfo::get(v.context()); const std::string currentModule = v.module(); return QtInfo::prependModuleAndNameSpace(qHashType, currentModule, qtInfo.nameSpace); } // Return up to count nodes of type "QHashNode" of a "class QHash". SymbolGroupValueVector qHashNodes(const SymbolGroupValue &v, VectorIndexType count) { if (!count) return SymbolGroupValueVector(); const SymbolGroupValue hashData = v["d"]; // 'e' is used as a special value to indicate empty hash buckets in the array. const ULONG64 ePtr = v["e"].pointerValue(); if (SymbolGroupValue::verbose) DebugPrint() << v << " Count=" << count << ",ePtr=0x" << std::hex << ePtr; if (!hashData || !ePtr) return SymbolGroupValueVector(); // Retrieve the array of buckets of 'd' const int numBuckets = hashData["numBuckets"].intValue(); const ULONG64 bucketArray = hashData["buckets"].pointerValue(); if (numBuckets <= 0 || !bucketArray) return SymbolGroupValueVector(); void *bucketPointers = readPointerArray(bucketArray, numBuckets, v.context()); if (!bucketPointers) return SymbolGroupValueVector(); // Get list of buckets (starting elements of 'QHashData::Node') const std::string dummyNodeType = QtInfo::get(v.context()).prependQtCoreModule("QHashData::Node"); const SymbolGroupValueVector buckets = SymbolGroupValue::pointerSize() == 8 ? hashBuckets(v.node()->symbolGroup(), dummyNodeType, reinterpret_cast(bucketPointers), numBuckets, ePtr, v.module(), v.context()) : hashBuckets(v.node()->symbolGroup(), dummyNodeType, reinterpret_cast(bucketPointers), numBuckets, ULONG32(ePtr), v.module(), v.context()); delete [] bucketPointers ; // Generate the list 'QHashData::Node *' by iterating over the linked list of // nodes starting at each bucket. Using the 'QHashData::Node *' instead of // the 'QHashNode' is much faster. Each list has a trailing, unused // dummy element. The initial element as such is skipped due to the pointer/value // duality (since its 'next' element is identical to it when using typecast<> later on). SymbolGroupValueVector dummyNodeList; dummyNodeList.reserve(count); bool notEnough = true; const SymbolGroupValueVector::const_iterator ncend = buckets.end(); for (SymbolGroupValueVector::const_iterator it = buckets.begin(); notEnough && it != ncend; ++it) { for (SymbolGroupValue l = *it; notEnough && l ; ) { const SymbolGroupValue next = l["next"]; if (next && next.pointerValue()) { // Stop at trailing dummy element dummyNodeList.push_back(next); if (dummyNodeList.size() >= count) // Stop at maximum count notEnough = false; if (SymbolGroupValue::verbose > 1) DebugPrint() << '#' << (dummyNodeList.size() - 1) << " l=" << l << ",next=" << next; l = next; } else { break; } } } // Finally convert them into real nodes 'QHashNode (potentially expensive) const std::string nodeType = qHashNodeType(v, "Node"); if (SymbolGroupValue::verbose) DebugPrint() << "Converting into " << nodeType; SymbolGroupValueVector nodeList; nodeList.reserve(count); const SymbolGroupValueVector::const_iterator dcend = dummyNodeList.end(); for (SymbolGroupValueVector::const_iterator it = dummyNodeList.begin(); it != dcend; ++it) { if (const SymbolGroupValue n = (*it).typeCast(nodeType.c_str())) nodeList.push_back(n); else return SymbolGroupValueVector(); } return nodeList; } // QSet<>: Contains a 'QHash' as member 'q_hash'. // Just dump the keys as an array. static inline AbstractSymbolGroupNodePtrVector qSetChildList(const SymbolGroupValue &v, int count) { const SymbolGroupValue qHash = v["q_hash"]; AbstractSymbolGroupNodePtrVector rc; if (!count || !qHash) return rc; const SymbolGroupValueVector nodes = qHashNodes(qHash, count); if (nodes.size() != VectorIndexType(count)) return rc; rc.reserve(count); for (int i = 0; i < count; i++) { if (const SymbolGroupValue key = nodes.at(i)["key"]) rc.push_back(ReferenceSymbolGroupNode::createArrayNode(i, key.node())); else return AbstractSymbolGroupNodePtrVector(); } return rc; } // QHash<>: Add with fake map nodes. static inline AbstractSymbolGroupNodePtrVector qHashChildList(const SymbolGroupValue &v, int count) { AbstractSymbolGroupNodePtrVector rc; if (!count) return rc; const SymbolGroupValueVector nodes = qHashNodes(v, count); if (nodes.size() != count) return rc; rc.reserve(count); for (int i = 0; i < count; i++) { const SymbolGroupValue &mapNode = nodes.at(i); const SymbolGroupValue key = mapNode["key"]; const SymbolGroupValue value = mapNode["value"]; if (!key || !value) return AbstractSymbolGroupNodePtrVector(); rc.push_back(MapNodeSymbolGroupNode::create(i, mapNode.address(), mapNode.type(), key.node(), value.node())); } return rc; } // Qt 4: QMap<>: Return the list of QMapData::Node static inline SymbolGroupValueVector qMap4Nodes(const SymbolGroupValue &v, VectorIndexType count) { const SymbolGroupValue e = v["e"]; const ULONG64 ePtr = e.pointerValue(); if (SymbolGroupValue::verbose) DebugPrint() << v.type() << " E=0x" << std::hex << ePtr; if (!ePtr) return SymbolGroupValueVector(); if (SymbolGroupValue::verbose) DebugPrint() << v.type() << " E=0x" << std::hex << ePtr; SymbolGroupValueVector rc; rc.reserve(count); SymbolGroupValue n = e["forward"][unsigned(0)]; for (VectorIndexType i = 0; i < count && n && n.pointerValue() != ePtr; ++i) { rc.push_back(n); n = n["forward"][unsigned(0)]; } return rc; } static void debugQMap5Node(const SymbolGroupValue &n, std::ostream &os, unsigned indent = 0) { const char *color = (n["p"].intValue() & 1) ? "black" : "red"; indentStream(os, indent); os << n.address() << ' ' <: Return the list of QMapNode static inline AbstractSymbolGroupNodePtrVector qMap5Nodes(const SymbolGroupValue &v, VectorIndexType count) { const SymbolGroupValue head = SymbolGroupValue::findMember(v["d"], "header"); SymbolGroupValue root = head["left"]; if (!root) return AbstractSymbolGroupNodePtrVector(); RedBlackTreeNode *nodeTree = RedBlackTreeNode::buildMapRecursion(root, head.address(), 0, "left", "right"); if (!nodeTree) return AbstractSymbolGroupNodePtrVector(); if (SymbolGroupValue::verbose > 1) nodeTree->debug(DebugPrint(), debugQMap5Node); VectorIndexType i = 0; // Finally convert them into real nodes 'QHashNode (potentially expensive) const std::string nodeType = qHashNodeType(v, "Node"); const std::string nodePtrType = nodeType + " *"; if (SymbolGroupValue::verbose) DebugPrint() << v.type() << "," << nodeType; AbstractSymbolGroupNodePtrVector result; result.reserve(count); for (const RedBlackTreeNode *n = nodeTree->begin() ; n && i < count; n = RedBlackTreeNode::next(n), i++) { if (const SymbolGroupValue qmapNode = n->nodeValue().pointerTypeCast(nodePtrType.c_str())) { const SymbolGroupValue key = qmapNode["key"]; const SymbolGroupValue value = qmapNode["value"]; if (!key || !value) { delete nodeTree; return AbstractSymbolGroupNodePtrVector(); } result.push_back(MapNodeSymbolGroupNode::create(i, key.address(), nodeType, key.node(), value.node())); } } delete nodeTree; return result; } // QMap<>: Add with fake map nodes. static inline AbstractSymbolGroupNodePtrVector qMapChildList(const SymbolGroupValue &v, VectorIndexType count) { if (SymbolGroupValue::verbose) DebugPrint() << v.type() << "," << count; if (!count) return AbstractSymbolGroupNodePtrVector(); if (QtInfo::get(v.context()).version >= 5) return qMap5Nodes(v, count); // Get node type: 'class namespace::QMap' // ->'QtCored4!namespace::QMapNode' // Note: Any types QMapNode<> will not be found without modules! const std::string mapNodeType = qHashNodeType(v, "Node"); const std::string mapPayloadNodeType = qHashNodeType(v, "PayloadNode"); // Calculate the offset needed (see QMap::concrete() used by the iterator). const unsigned payloadNodeSize = SymbolGroupValue::sizeOf(mapPayloadNodeType.c_str()); if (SymbolGroupValue::verbose) { DebugPrint() << v.type() << "," << mapNodeType << ':' << mapPayloadNodeType << ':' << payloadNodeSize << ", pointerSize=" << SymbolGroupValue::pointerSize(); } if (!payloadNodeSize) return AbstractSymbolGroupNodePtrVector(); const ULONG64 payLoad = payloadNodeSize - SymbolGroupValue::pointerSize(); // Get the value offset. Manually determine the alignment to be able // to retrieve key/value without having to deal with QMapNode<> (see below). // Subtract the 2 trailing pointers of the node. const std::vector innerTypes = v.innerTypes(); if (innerTypes.size() != 2u) return AbstractSymbolGroupNodePtrVector(); const std::string keyType = fixInnerType(innerTypes.front(), v); const std::string valueType = fixInnerType(innerTypes.at(1), v); const unsigned valueSize = SymbolGroupValue::sizeOf(valueType.c_str()); const unsigned valueOffset = SymbolGroupValue::fieldOffset(mapNodeType.c_str(), "value"); if (SymbolGroupValue::verbose) DebugPrint() << "Payload=" << payLoad << ",valueOffset=" << valueOffset << ',' << innerTypes.front() << ',' << innerTypes.back() << ':' << valueSize; if (!valueOffset || !valueSize) return AbstractSymbolGroupNodePtrVector(); // Get the children. const SymbolGroupValueVector childNodes = qMap4Nodes(v, count); if (SymbolGroupValue::verbose) DebugPrint() << "children: " << childNodes.size() << " of " << count; // Deep expansion of the forward[0] sometimes fails. In that case, // take what we can get. if (childNodes.size() != count) count = childNodes.size(); // The correct way of doing this would be to construct additional symbols // '*(QMapNode *)(node_address)'. However, when doing this as of // 'CDB 6.12.0002.633' (21.12.2010) IDebugSymbolGroup::AddSymbol() // just fails, returning DEBUG_ANY_ID without actually doing something. So, // we circumvent the map nodes and directly create key and values at their addresses. AbstractSymbolGroupNodePtrVector rc; rc.reserve(count); std::string errorMessage; SymbolGroup *sg = v.node()->symbolGroup(); for (VectorIndexType i = 0; i < count ; ++i) { const ULONG64 nodePtr = childNodes.at(i).pointerValue(); if (!nodePtr) return AbstractSymbolGroupNodePtrVector(); const ULONG64 keyAddress = nodePtr - payLoad; const std::string keyExp = SymbolGroupValue::pointedToSymbolName(keyAddress, keyType); const std::string valueExp = SymbolGroupValue::pointedToSymbolName(keyAddress + valueOffset, valueType); if (SymbolGroupValue::verbose) { DebugPrint() << '#' << i << '/' << count << ' ' << std::hex << ",node=0x" << nodePtr << ',' <addSymbol(v.module(), keyExp, std::string(), &errorMessage); SymbolGroupNode *valueNode = sg->addSymbol(v.module(), valueExp, std::string(), &errorMessage); if (!keyNode || !valueNode) return AbstractSymbolGroupNodePtrVector(); rc.push_back(MapNodeSymbolGroupNode::create(int(i), keyAddress, mapNodeType, keyNode, valueNode)); } return rc; } /*! Determine children of containers \ingroup qtcreatorcdbext */ AbstractSymbolGroupNodePtrVector containerChildren(SymbolGroupNode *node, int type, int size, const SymbolGroupValueContext &ctx) { if (SymbolGroupValue::verbose) { DebugPrint dp; dp << "containerChildren " << node->name() << '/' << node->iName() << '/' << node->type() << " at 0x" << std::hex << node->address() << std::dec << " count=" << size << ",knowntype=" << type << " ["; formatKnownTypeFlags(dp, static_cast(type)); dp << ']'; } if (!size) return AbstractSymbolGroupNodePtrVector(); if (size > 100) size = 100; switch (type) { case KT_QVector: return qVectorChildList(node, size, ctx); case KT_StdVector: return stdVectorChildList(node, size, ctx); case KT_QLinkedList: return qLinkedListChildList(node, size, ctx); case KT_QList: return qListChildList(SymbolGroupValue(node, ctx), size); case KT_QQueue: if (const SymbolGroupValue qList = SymbolGroupValue(node, ctx)[unsigned(0)]) return qListChildList(qList, size); break; case KT_QStack: if (const SymbolGroupValue qVector = SymbolGroupValue(node, ctx)[unsigned(0)]) return qVectorChildList(qVector.node(), size, ctx); break; case KT_QHash: return qHashChildList(SymbolGroupValue(node, ctx), size); case KT_QMultiHash: if (const SymbolGroupValue hash = SymbolGroupValue(node, ctx)[unsigned(0)]) return qHashChildList(hash, size); break; case KT_QSet: return qSetChildList(SymbolGroupValue(node, ctx), size); case KT_QMap: return qMapChildList(SymbolGroupValue(node, ctx), size); case KT_QMultiMap: if (const SymbolGroupValue qmap = SymbolGroupValue(node, ctx)[unsigned(0)]) return qMapChildList(qmap, size); break; case KT_QStringList: if (const SymbolGroupValue qList = SymbolGroupValue(node, ctx)[unsigned(0)]) return qListChildList(qList, size); break; case KT_StdList: return stdListChildList(node, size , ctx); case KT_StdDeque: return stdDequeChildList(SymbolGroupValue(node, ctx), size); case KT_StdStack: if (const SymbolGroupValue deque = SymbolGroupValue(node, ctx)[unsigned(0)]) return stdDequeChildList(deque, size); break; case KT_StdSet: return stdSetChildList(SymbolGroupValue(node, ctx), size); case KT_StdMap: case KT_StdMultiMap: return stdMapChildList(SymbolGroupValue(node, ctx), size); } return AbstractSymbolGroupNodePtrVector(); }