//===-- ValueObject.cpp -----------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "lldb/Core/ValueObject.h" // C Includes #include // C++ Includes // Other libraries and framework includes #include "llvm/Support/raw_ostream.h" #include "clang/AST/Type.h" // Project includes #include "lldb/Core/DataBufferHeap.h" #include "lldb/Core/StreamString.h" #include "lldb/Core/ValueObjectChild.h" #include "lldb/Core/ValueObjectConstResult.h" #include "lldb/Core/ValueObjectList.h" #include "lldb/Symbol/ClangASTType.h" #include "lldb/Symbol/ClangASTContext.h" #include "lldb/Symbol/Type.h" #include "lldb/Target/ExecutionContext.h" #include "lldb/Target/LanguageRuntime.h" #include "lldb/Target/Process.h" #include "lldb/Target/RegisterContext.h" #include "lldb/Target/Target.h" #include "lldb/Target/Thread.h" using namespace lldb; using namespace lldb_private; static lldb::user_id_t g_value_obj_uid = 0; //---------------------------------------------------------------------- // ValueObject constructor //---------------------------------------------------------------------- ValueObject::ValueObject (ValueObject *parent) : UserID (++g_value_obj_uid), // Unique identifier for every value object m_parent (parent), m_update_id (0), // Value object lists always start at 1, value objects start at zero m_name (), m_data (), m_value (), m_error (), m_value_str (), m_old_value_str (), m_location_str (), m_summary_str (), m_object_desc_str (), m_children (), m_synthetic_children (), m_dynamic_value_sp (), m_format (eFormatDefault), m_value_is_valid (false), m_value_did_change (false), m_children_count_valid (false), m_old_value_valid (false), m_pointers_point_to_load_addrs (false) { } //---------------------------------------------------------------------- // Destructor //---------------------------------------------------------------------- ValueObject::~ValueObject () { } user_id_t ValueObject::GetUpdateID() const { return m_update_id; } bool ValueObject::UpdateValueIfNeeded (ExecutionContextScope *exe_scope) { // If this is a constant value, then our success is predicated on whether // we have an error or not if (GetIsConstant()) return m_error.Success(); if (exe_scope) { Process *process = exe_scope->CalculateProcess(); if (process) { const user_id_t stop_id = process->GetStopID(); if (m_update_id != stop_id) { bool first_update = m_update_id == 0; // Save the old value using swap to avoid a string copy which // also will clear our m_value_str if (m_value_str.empty()) { m_old_value_valid = false; } else { m_old_value_valid = true; m_old_value_str.swap (m_value_str); m_value_str.clear(); } m_location_str.clear(); m_summary_str.clear(); m_object_desc_str.clear(); const bool value_was_valid = GetValueIsValid(); SetValueDidChange (false); m_error.Clear(); // Call the pure virtual function to update the value UpdateValue (exe_scope); // Update the fact that we tried to update the value for this // value object whether or not we succeed m_update_id = stop_id; bool success = m_error.Success(); SetValueIsValid (success); if (first_update) SetValueDidChange (false); else if (!m_value_did_change && success == false) { // The value wasn't gotten successfully, so we mark this // as changed if the value used to be valid and now isn't SetValueDidChange (value_was_valid); } } } } return m_error.Success(); } const DataExtractor & ValueObject::GetDataExtractor () const { return m_data; } DataExtractor & ValueObject::GetDataExtractor () { return m_data; } const Error & ValueObject::GetError() const { return m_error; } const ConstString & ValueObject::GetName() const { return m_name; } const char * ValueObject::GetLocationAsCString (ExecutionContextScope *exe_scope) { if (UpdateValueIfNeeded(exe_scope)) { if (m_location_str.empty()) { StreamString sstr; switch (m_value.GetValueType()) { default: break; case Value::eValueTypeScalar: if (m_value.GetContextType() == Value::eContextTypeRegisterInfo) { RegisterInfo *reg_info = m_value.GetRegisterInfo(); if (reg_info) { if (reg_info->name) m_location_str = reg_info->name; else if (reg_info->alt_name) m_location_str = reg_info->alt_name; break; } } m_location_str = "scalar"; break; case Value::eValueTypeLoadAddress: case Value::eValueTypeFileAddress: case Value::eValueTypeHostAddress: { uint32_t addr_nibble_size = m_data.GetAddressByteSize() * 2; sstr.Printf("0x%*.*llx", addr_nibble_size, addr_nibble_size, m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS)); m_location_str.swap(sstr.GetString()); } break; } } } return m_location_str.c_str(); } Value & ValueObject::GetValue() { return m_value; } const Value & ValueObject::GetValue() const { return m_value; } bool ValueObject::ResolveValue (ExecutionContextScope *exe_scope, Scalar &scalar) { ExecutionContext exe_ctx; exe_scope->CalculateExecutionContext(exe_ctx); scalar = m_value.ResolveValue(&exe_ctx, GetClangAST ()); return scalar.IsValid(); } bool ValueObject::GetValueIsValid () const { return m_value_is_valid; } void ValueObject::SetValueIsValid (bool b) { m_value_is_valid = b; } bool ValueObject::GetValueDidChange (ExecutionContextScope *exe_scope) { GetValueAsCString (exe_scope); return m_value_did_change; } void ValueObject::SetValueDidChange (bool value_changed) { m_value_did_change = value_changed; } ValueObjectSP ValueObject::GetChildAtIndex (uint32_t idx, bool can_create) { ValueObjectSP child_sp; if (idx < GetNumChildren()) { // Check if we have already made the child value object? if (can_create && m_children[idx].get() == NULL) { // No we haven't created the child at this index, so lets have our // subclass do it and cache the result for quick future access. m_children[idx] = CreateChildAtIndex (idx, false, 0); } child_sp = m_children[idx]; } return child_sp; } uint32_t ValueObject::GetIndexOfChildWithName (const ConstString &name) { bool omit_empty_base_classes = true; return ClangASTContext::GetIndexOfChildWithName (GetClangAST(), GetClangType(), name.GetCString(), omit_empty_base_classes); } ValueObjectSP ValueObject::GetChildMemberWithName (const ConstString &name, bool can_create) { // when getting a child by name, it could be buried inside some base // classes (which really aren't part of the expression path), so we // need a vector of indexes that can get us down to the correct child std::vector child_indexes; clang::ASTContext *clang_ast = GetClangAST(); void *clang_type = GetClangType(); bool omit_empty_base_classes = true; const size_t num_child_indexes = ClangASTContext::GetIndexOfChildMemberWithName (clang_ast, clang_type, name.GetCString(), omit_empty_base_classes, child_indexes); ValueObjectSP child_sp; if (num_child_indexes > 0) { std::vector::const_iterator pos = child_indexes.begin (); std::vector::const_iterator end = child_indexes.end (); child_sp = GetChildAtIndex(*pos, can_create); for (++pos; pos != end; ++pos) { if (child_sp) { ValueObjectSP new_child_sp(child_sp->GetChildAtIndex (*pos, can_create)); child_sp = new_child_sp; } else { child_sp.reset(); } } } return child_sp; } uint32_t ValueObject::GetNumChildren () { if (!m_children_count_valid) { SetNumChildren (CalculateNumChildren()); } return m_children.size(); } void ValueObject::SetNumChildren (uint32_t num_children) { m_children_count_valid = true; m_children.resize(num_children); } void ValueObject::SetName (const char *name) { m_name.SetCString(name); } void ValueObject::SetName (const ConstString &name) { m_name = name; } ValueObjectSP ValueObject::CreateChildAtIndex (uint32_t idx, bool synthetic_array_member, int32_t synthetic_index) { ValueObjectSP valobj_sp; bool omit_empty_base_classes = true; std::string child_name_str; uint32_t child_byte_size = 0; int32_t child_byte_offset = 0; uint32_t child_bitfield_bit_size = 0; uint32_t child_bitfield_bit_offset = 0; bool child_is_base_class = false; const bool transparent_pointers = synthetic_array_member == false; clang::ASTContext *clang_ast = GetClangAST(); clang_type_t clang_type = GetClangType(); clang_type_t child_clang_type; child_clang_type = ClangASTContext::GetChildClangTypeAtIndex (clang_ast, GetName().GetCString(), clang_type, idx, transparent_pointers, omit_empty_base_classes, child_name_str, child_byte_size, child_byte_offset, child_bitfield_bit_size, child_bitfield_bit_offset, child_is_base_class); if (child_clang_type) { if (synthetic_index) child_byte_offset += child_byte_size * synthetic_index; ConstString child_name; if (!child_name_str.empty()) child_name.SetCString (child_name_str.c_str()); valobj_sp.reset (new ValueObjectChild (this, clang_ast, child_clang_type, child_name, child_byte_size, child_byte_offset, child_bitfield_bit_size, child_bitfield_bit_offset, child_is_base_class)); if (m_pointers_point_to_load_addrs) valobj_sp->SetPointersPointToLoadAddrs (m_pointers_point_to_load_addrs); } return valobj_sp; } const char * ValueObject::GetSummaryAsCString (ExecutionContextScope *exe_scope) { if (UpdateValueIfNeeded (exe_scope)) { if (m_summary_str.empty()) { clang_type_t clang_type = GetClangType(); // See if this is a pointer to a C string? if (clang_type) { StreamString sstr; clang_type_t elem_or_pointee_clang_type; const Flags type_flags (ClangASTContext::GetTypeInfo (clang_type, GetClangAST(), &elem_or_pointee_clang_type)); if (type_flags.AnySet (ClangASTContext::eTypeIsArray | ClangASTContext::eTypeIsPointer) && ClangASTContext::IsCharType (elem_or_pointee_clang_type)) { Process *process = exe_scope->CalculateProcess(); if (process != NULL) { lldb::addr_t cstr_address = LLDB_INVALID_ADDRESS; lldb::AddressType cstr_address_type = eAddressTypeInvalid; size_t cstr_len = 0; if (type_flags.Test (ClangASTContext::eTypeIsArray)) { // We have an array cstr_len = ClangASTContext::GetArraySize (clang_type); cstr_address = GetAddressOf (cstr_address_type, true); } else { // We have a pointer cstr_address = GetPointerValue (cstr_address_type, true); } if (cstr_address != LLDB_INVALID_ADDRESS) { DataExtractor data; size_t bytes_read = 0; std::vector data_buffer; std::vector cstr_buffer; size_t cstr_length; Error error; if (cstr_len > 0) { data_buffer.resize(cstr_len); // Resize the formatted buffer in case every character // uses the "\xXX" format and one extra byte for a NULL cstr_buffer.resize(data_buffer.size() * 4 + 1); data.SetData (&data_buffer.front(), data_buffer.size(), eByteOrderHost); bytes_read = process->ReadMemory (cstr_address, &data_buffer.front(), cstr_len, error); if (bytes_read > 0) { sstr << '"'; cstr_length = data.Dump (&sstr, 0, // Start offset in "data" eFormatChar, // Print as characters 1, // Size of item (1 byte for a char!) bytes_read, // How many bytes to print? UINT32_MAX, // num per line LLDB_INVALID_ADDRESS,// base address 0, // bitfield bit size 0); // bitfield bit offset sstr << '"'; } } else { const size_t k_max_buf_size = 256; data_buffer.resize (k_max_buf_size + 1); // NULL terminate in case we don't get the entire C string data_buffer.back() = '\0'; // Make a formatted buffer that can contain take 4 // bytes per character in case each byte uses the // "\xXX" format and one extra byte for a NULL cstr_buffer.resize (k_max_buf_size * 4 + 1); data.SetData (&data_buffer.front(), data_buffer.size(), eByteOrderHost); size_t total_cstr_len = 0; while ((bytes_read = process->ReadMemory (cstr_address, &data_buffer.front(), k_max_buf_size, error)) > 0) { size_t len = strlen(&data_buffer.front()); if (len == 0) break; if (len > bytes_read) len = bytes_read; if (sstr.GetSize() == 0) sstr << '"'; cstr_length = data.Dump (&sstr, 0, // Start offset in "data" eFormatChar, // Print as characters 1, // Size of item (1 byte for a char!) len, // How many bytes to print? UINT32_MAX, // num per line LLDB_INVALID_ADDRESS,// base address 0, // bitfield bit size 0); // bitfield bit offset if (len < k_max_buf_size) break; cstr_address += total_cstr_len; } if (sstr.GetSize() > 0) sstr << '"'; } } } if (sstr.GetSize() > 0) m_summary_str.assign (sstr.GetData(), sstr.GetSize()); } else if (ClangASTContext::IsFunctionPointerType (clang_type)) { lldb::AddressType func_ptr_address_type = eAddressTypeInvalid; lldb::addr_t func_ptr_address = GetPointerValue (func_ptr_address_type, true); if (func_ptr_address != 0 && func_ptr_address != LLDB_INVALID_ADDRESS) { switch (func_ptr_address_type) { case eAddressTypeInvalid: case eAddressTypeFile: break; case eAddressTypeLoad: { Address so_addr; Target *target = exe_scope->CalculateTarget(); if (target && target->GetSectionLoadList().IsEmpty() == false) { if (target->GetSectionLoadList().ResolveLoadAddress(func_ptr_address, so_addr)) { so_addr.Dump (&sstr, exe_scope, Address::DumpStyleResolvedDescription, Address::DumpStyleSectionNameOffset); } } } break; case eAddressTypeHost: break; } } if (sstr.GetSize() > 0) { m_summary_str.assign (1, '('); m_summary_str.append (sstr.GetData(), sstr.GetSize()); m_summary_str.append (1, ')'); } } } } } if (m_summary_str.empty()) return NULL; return m_summary_str.c_str(); } const char * ValueObject::GetObjectDescription (ExecutionContextScope *exe_scope) { if (!m_object_desc_str.empty()) return m_object_desc_str.c_str(); if (!GetValueIsValid()) return NULL; Process *process = exe_scope->CalculateProcess(); if (process == NULL) return NULL; StreamString s; lldb::LanguageType language = GetObjectRuntimeLanguage(); LanguageRuntime *runtime = process->GetLanguageRuntime(language); if (runtime == NULL) { // Aw, hell, if the things a pointer, let's try ObjC anyway... clang_type_t opaque_qual_type = GetClangType(); if (opaque_qual_type != NULL) { clang::QualType qual_type (clang::QualType::getFromOpaquePtr(opaque_qual_type).getNonReferenceType()); if (qual_type->isAnyPointerType()) runtime = process->GetLanguageRuntime(lldb::eLanguageTypeObjC); } } if (runtime && runtime->GetObjectDescription(s, *this, exe_scope)) { m_object_desc_str.append (s.GetData()); } if (m_object_desc_str.empty()) return NULL; else return m_object_desc_str.c_str(); } const char * ValueObject::GetValueAsCString (ExecutionContextScope *exe_scope) { // If our byte size is zero this is an aggregate type that has children if (ClangASTContext::IsAggregateType (GetClangType()) == false) { if (UpdateValueIfNeeded(exe_scope)) { if (m_value_str.empty()) { const Value::ContextType context_type = m_value.GetContextType(); switch (context_type) { case Value::eContextTypeClangType: case Value::eContextTypeLLDBType: case Value::eContextTypeVariable: { clang_type_t clang_type = GetClangType (); if (clang_type) { StreamString sstr; if (m_format == eFormatDefault) m_format = ClangASTType::GetFormat(clang_type); if (ClangASTType::DumpTypeValue (GetClangAST(), // The clang AST clang_type, // The clang type to display &sstr, m_format, // Format to display this type with m_data, // Data to extract from 0, // Byte offset into "m_data" GetByteSize(), // Byte size of item in "m_data" GetBitfieldBitSize(), // Bitfield bit size GetBitfieldBitOffset())) // Bitfield bit offset m_value_str.swap(sstr.GetString()); else m_value_str.clear(); } } break; case Value::eContextTypeRegisterInfo: { const RegisterInfo *reg_info = m_value.GetRegisterInfo(); if (reg_info) { StreamString reg_sstr; m_data.Dump(®_sstr, 0, reg_info->format, reg_info->byte_size, 1, UINT32_MAX, LLDB_INVALID_ADDRESS, 0, 0); m_value_str.swap(reg_sstr.GetString()); } } break; default: break; } } if (!m_value_did_change && m_old_value_valid) { // The value was gotten successfully, so we consider the // value as changed if the value string differs SetValueDidChange (m_old_value_str != m_value_str); } } } if (m_value_str.empty()) return NULL; return m_value_str.c_str(); } addr_t ValueObject::GetAddressOf (lldb::AddressType &address_type, bool scalar_is_load_address) { switch (m_value.GetValueType()) { case Value::eValueTypeScalar: if (scalar_is_load_address) { address_type = eAddressTypeLoad; return m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS); } break; case Value::eValueTypeLoadAddress: case Value::eValueTypeFileAddress: case Value::eValueTypeHostAddress: { address_type = m_value.GetValueAddressType (); return m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS); } break; } address_type = eAddressTypeInvalid; return LLDB_INVALID_ADDRESS; } addr_t ValueObject::GetPointerValue (lldb::AddressType &address_type, bool scalar_is_load_address) { lldb::addr_t address = LLDB_INVALID_ADDRESS; address_type = eAddressTypeInvalid; switch (m_value.GetValueType()) { case Value::eValueTypeScalar: if (scalar_is_load_address) { address = m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS); address_type = eAddressTypeLoad; } break; case Value::eValueTypeLoadAddress: case Value::eValueTypeFileAddress: case Value::eValueTypeHostAddress: { uint32_t data_offset = 0; address = m_data.GetPointer(&data_offset); address_type = m_value.GetValueAddressType(); if (address_type == eAddressTypeInvalid) address_type = eAddressTypeLoad; } break; } if (m_pointers_point_to_load_addrs) address_type = eAddressTypeLoad; return address; } bool ValueObject::SetValueFromCString (ExecutionContextScope *exe_scope, const char *value_str) { // Make sure our value is up to date first so that our location and location // type is valid. if (!UpdateValueIfNeeded(exe_scope)) return false; uint32_t count = 0; lldb::Encoding encoding = ClangASTType::GetEncoding (GetClangType(), count); char *end = NULL; const size_t byte_size = GetByteSize(); switch (encoding) { case eEncodingInvalid: return false; case eEncodingUint: if (byte_size > sizeof(unsigned long long)) { return false; } else { unsigned long long ull_val = strtoull(value_str, &end, 0); if (end && *end != '\0') return false; m_value = ull_val; // Limit the bytes in our m_data appropriately. m_value.GetScalar().GetData (m_data, byte_size); } break; case eEncodingSint: if (byte_size > sizeof(long long)) { return false; } else { long long sll_val = strtoll(value_str, &end, 0); if (end && *end != '\0') return false; m_value = sll_val; // Limit the bytes in our m_data appropriately. m_value.GetScalar().GetData (m_data, byte_size); } break; case eEncodingIEEE754: { const off_t byte_offset = GetByteOffset(); uint8_t *dst = const_cast(m_data.PeekData(byte_offset, byte_size)); if (dst != NULL) { // We are decoding a float into host byte order below, so make // sure m_data knows what it contains. m_data.SetByteOrder(eByteOrderHost); const size_t converted_byte_size = ClangASTContext::ConvertStringToFloatValue ( GetClangAST(), GetClangType(), value_str, dst, byte_size); if (converted_byte_size == byte_size) { } } } break; case eEncodingVector: return false; default: return false; } // If we have made it here the value is in m_data and we should write it // out to the target return Write (); } bool ValueObject::Write () { // Clear the update ID so the next time we try and read the value // we try and read it again. m_update_id = 0; // TODO: when Value has a method to write a value back, call it from here. return false; } lldb::LanguageType ValueObject::GetObjectRuntimeLanguage () { clang_type_t opaque_qual_type = GetClangType(); if (opaque_qual_type == NULL) return lldb::eLanguageTypeC; // If the type is a reference, then resolve it to what it refers to first: clang::QualType qual_type (clang::QualType::getFromOpaquePtr(opaque_qual_type).getNonReferenceType()); if (qual_type->isAnyPointerType()) { if (qual_type->isObjCObjectPointerType()) return lldb::eLanguageTypeObjC; clang::QualType pointee_type (qual_type->getPointeeType()); if (pointee_type->getCXXRecordDeclForPointerType() != NULL) return lldb::eLanguageTypeC_plus_plus; if (pointee_type->isObjCObjectOrInterfaceType()) return lldb::eLanguageTypeObjC; if (pointee_type->isObjCClassType()) return lldb::eLanguageTypeObjC; } else { if (ClangASTContext::IsObjCClassType (opaque_qual_type)) return lldb::eLanguageTypeObjC; if (ClangASTContext::IsCXXClassType (opaque_qual_type)) return lldb::eLanguageTypeC_plus_plus; } return lldb::eLanguageTypeC; } void ValueObject::AddSyntheticChild (const ConstString &key, ValueObjectSP& valobj_sp) { m_synthetic_children[key] = valobj_sp; } ValueObjectSP ValueObject::GetSyntheticChild (const ConstString &key) const { ValueObjectSP synthetic_child_sp; std::map::const_iterator pos = m_synthetic_children.find (key); if (pos != m_synthetic_children.end()) synthetic_child_sp = pos->second; return synthetic_child_sp; } bool ValueObject::IsPointerType () { return ClangASTContext::IsPointerType (GetClangType()); } bool ValueObject::IsPointerOrReferenceType () { return ClangASTContext::IsPointerOrReferenceType(GetClangType()); } ValueObjectSP ValueObject::GetSyntheticArrayMemberFromPointer (int32_t index, bool can_create) { ValueObjectSP synthetic_child_sp; if (IsPointerType ()) { char index_str[64]; snprintf(index_str, sizeof(index_str), "[%i]", index); ConstString index_const_str(index_str); // Check if we have already created a synthetic array member in this // valid object. If we have we will re-use it. synthetic_child_sp = GetSyntheticChild (index_const_str); if (!synthetic_child_sp) { // We haven't made a synthetic array member for INDEX yet, so // lets make one and cache it for any future reference. synthetic_child_sp = CreateChildAtIndex(0, true, index); // Cache the value if we got one back... if (synthetic_child_sp) AddSyntheticChild(index_const_str, synthetic_child_sp); } } return synthetic_child_sp; } bool ValueObject::SetDynamicValue () { if (!IsPointerOrReferenceType()) return false; // Check that the runtime class is correct for determining the most specific class. // If it is a C++ class, see if it is dynamic: return true; } void ValueObject::GetExpressionPath (Stream &s) { if (m_parent) { m_parent->GetExpressionPath (s); clang_type_t parent_clang_type = m_parent->GetClangType(); if (parent_clang_type) { if (ClangASTContext::IsPointerType(parent_clang_type)) { s.PutCString("->"); } else if (ClangASTContext::IsAggregateType (parent_clang_type)) { if (ClangASTContext::IsArrayType (parent_clang_type) == false && m_parent->IsBaseClass() == false) s.PutChar('.'); } } } if (IsBaseClass()) { clang_type_t clang_type = GetClangType(); std::string cxx_class_name; if (ClangASTContext::GetCXXClassName (clang_type, cxx_class_name)) { s << cxx_class_name.c_str() << "::"; } } else { const char *name = GetName().GetCString(); if (name) s.PutCString(name); } } void ValueObject::DumpValueObject ( Stream &s, ExecutionContextScope *exe_scope, ValueObject *valobj, const char *root_valobj_name, uint32_t ptr_depth, uint32_t curr_depth, uint32_t max_depth, bool show_types, bool show_location, bool use_objc, bool scope_already_checked, bool flat_output ) { if (valobj) { clang_type_t clang_type = valobj->GetClangType(); const Flags type_flags (ClangASTContext::GetTypeInfo (clang_type, NULL, NULL)); const char *err_cstr = NULL; const bool has_children = type_flags.Test (ClangASTContext::eTypeHasChildren); const bool has_value = type_flags.Test (ClangASTContext::eTypeHasValue); const bool print_valobj = flat_output == false || has_value; if (print_valobj) { if (show_location) { s.Printf("%s: ", valobj->GetLocationAsCString(exe_scope)); } s.Indent(); // Always show the type for the top level items. if (show_types || curr_depth == 0) s.Printf("(%s) ", valobj->GetTypeName().AsCString("")); if (flat_output) { valobj->GetExpressionPath(s); s.PutCString(" ="); } else { const char *name_cstr = root_valobj_name ? root_valobj_name : valobj->GetName().AsCString(""); s.Printf ("%s =", name_cstr); } if (!scope_already_checked && !valobj->IsInScope(exe_scope->CalculateStackFrame())) { err_cstr = "error: out of scope"; } } const char *val_cstr = NULL; if (err_cstr == NULL) { val_cstr = valobj->GetValueAsCString(exe_scope); err_cstr = valobj->GetError().AsCString(); } if (err_cstr) { s.Printf (" error: %s\n", err_cstr); } else { const bool is_ref = type_flags.Test (ClangASTContext::eTypeIsReference); if (print_valobj) { const char *sum_cstr = valobj->GetSummaryAsCString(exe_scope); if (val_cstr) s.Printf(" %s", val_cstr); if (sum_cstr) s.Printf(" %s", sum_cstr); if (use_objc) { const char *object_desc = valobj->GetObjectDescription(exe_scope); if (object_desc) s.Printf(" %s\n", object_desc); else s.Printf (" [no Objective-C description available]\n"); return; } } if (curr_depth < max_depth) { // We will show children for all concrete types. We won't show // pointer contents unless a pointer depth has been specified. // We won't reference contents unless the reference is the // root object (depth of zero). bool print_children = true; // Use a new temporary pointer depth in case we override the // current pointer depth below... uint32_t curr_ptr_depth = ptr_depth; const bool is_ptr = type_flags.Test (ClangASTContext::eTypeIsPointer); if (is_ptr || is_ref) { // We have a pointer or reference whose value is an address. // Make sure that address is not NULL lldb::AddressType ptr_address_type; if (valobj->GetPointerValue (ptr_address_type, true) == 0) print_children = false; else if (is_ref && curr_depth == 0) { // If this is the root object (depth is zero) that we are showing // and it is a reference, and no pointer depth has been supplied // print out what it references. Don't do this at deeper depths // otherwise we can end up with infinite recursion... curr_ptr_depth = 1; } if (curr_ptr_depth == 0) print_children = false; } if (print_children) { const uint32_t num_children = valobj->GetNumChildren(); if (num_children) { if (flat_output) { if (print_valobj) s.EOL(); } else { if (print_valobj) s.PutCString(is_ref ? ": {\n" : " {\n"); s.IndentMore(); } for (uint32_t idx=0; idxGetChildAtIndex(idx, true)); if (child_sp.get()) { DumpValueObject (s, exe_scope, child_sp.get(), NULL, (is_ptr || is_ref) ? curr_ptr_depth - 1 : curr_ptr_depth, curr_depth + 1, max_depth, show_types, show_location, false, true, flat_output); } } if (!flat_output) { s.IndentLess(); s.Indent("}\n"); } } else if (has_children) { // Aggregate, no children... if (print_valobj) s.PutCString(" {}\n"); } else { if (print_valobj) s.EOL(); } } else { s.EOL(); } } else { if (has_children && print_valobj) { s.PutCString("{...}\n"); } } } } } ValueObjectSP ValueObject::CreateConstantValue (ExecutionContextScope *exe_scope, const ConstString &name) { ValueObjectSP valobj_sp; if (UpdateValueIfNeeded(exe_scope) && m_error.Success()) { ExecutionContext exe_ctx; exe_scope->CalculateExecutionContext(exe_ctx); clang::ASTContext *ast = GetClangAST (); DataExtractor data; data.SetByteOrder (m_data.GetByteOrder()); data.SetAddressByteSize(m_data.GetAddressByteSize()); m_error = m_value.GetValueAsData (&exe_ctx, ast, data, 0); valobj_sp.reset (new ValueObjectConstResult (ast, GetClangType(), name, data)); } else { valobj_sp.reset (new ValueObjectConstResult (m_error)); } return valobj_sp; } lldb::ValueObjectSP ValueObject::Dereference (Error &error) { lldb::ValueObjectSP valobj_sp; const bool is_pointer_type = IsPointerType(); if (is_pointer_type) { bool omit_empty_base_classes = true; std::string child_name_str; uint32_t child_byte_size = 0; int32_t child_byte_offset = 0; uint32_t child_bitfield_bit_size = 0; uint32_t child_bitfield_bit_offset = 0; bool child_is_base_class = false; const bool transparent_pointers = false; clang::ASTContext *clang_ast = GetClangAST(); clang_type_t clang_type = GetClangType(); clang_type_t child_clang_type; child_clang_type = ClangASTContext::GetChildClangTypeAtIndex (clang_ast, GetName().GetCString(), clang_type, 0, transparent_pointers, omit_empty_base_classes, child_name_str, child_byte_size, child_byte_offset, child_bitfield_bit_size, child_bitfield_bit_offset, child_is_base_class); if (child_clang_type) { ConstString child_name; if (!child_name_str.empty()) child_name.SetCString (child_name_str.c_str()); valobj_sp.reset (new ValueObjectChild (this, clang_ast, child_clang_type, child_name, child_byte_size, child_byte_offset, child_bitfield_bit_size, child_bitfield_bit_offset, child_is_base_class)); } } if (valobj_sp) { error.Clear(); } else { StreamString strm; GetExpressionPath(strm); if (is_pointer_type) error.SetErrorStringWithFormat("dereference failed: (%s) %s", GetTypeName().AsCString(""), strm.GetString().c_str()); else error.SetErrorStringWithFormat("not a pointer type: (%s) %s", GetTypeName().AsCString(""), strm.GetString().c_str()); } return valobj_sp; } lldb::ValueObjectSP ValueObject::AddressOf (Error &error) { lldb::ValueObjectSP valobj_sp; lldb::AddressType address_type = eAddressTypeInvalid; const bool scalar_is_load_address = false; lldb::addr_t addr = GetAddressOf (address_type, scalar_is_load_address); error.Clear(); if (addr != LLDB_INVALID_ADDRESS) { switch (address_type) { default: case eAddressTypeInvalid: { StreamString expr_path_strm; GetExpressionPath(expr_path_strm); error.SetErrorStringWithFormat("'%s' is not in memory", expr_path_strm.GetString().c_str()); } break; case eAddressTypeFile: case eAddressTypeLoad: case eAddressTypeHost: { clang::ASTContext *ast = GetClangAST(); clang_type_t clang_type = GetClangType(); if (ast && clang_type) { std::string name (1, '&'); name.append (m_name.AsCString("")); valobj_sp.reset (new ValueObjectConstResult (ast, ClangASTContext::CreatePointerType (ast, clang_type), ConstString (name.c_str()), addr, address_type, m_data.GetAddressByteSize())); } } break; } } return valobj_sp; }