ValueObjectVTable.cpp source code [lldb/source/Core/ValueObjectVTable.cpp]

1	//===-- ValueObjectVTable.cpp ---------------------------------------------===//
2	//
3	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4	// See https://llvm.org/LICENSE.txt for license information.
5	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6	//
7	//===----------------------------------------------------------------------===//
8
9	#include "lldb/Core/ValueObjectVTable.h"
10	#include "lldb/Core/Module.h"
11	#include "lldb/Core/ValueObjectChild.h"
12	#include "lldb/Symbol/Function.h"
13	#include "lldb/Target/Language.h"
14	#include "lldb/Target/LanguageRuntime.h"
15	#include "lldb/lldb-defines.h"
16	#include "lldb/lldb-enumerations.h"
17	#include "lldb/lldb-forward.h"
18	#include "lldb/lldb-private-enumerations.h"
19
20	using namespace lldb;
21	using namespace lldb_private;
22
23	class ValueObjectVTableChild : public ValueObject {
24	public:
25	ValueObjectVTableChild(ValueObject &parent, uint32_t func_idx,
26	uint64_t addr_size)
27	: ValueObject (parent), m_func_idx(func_idx), m_addr_size(addr_size) {
28	SetFormat(eFormatPointer);
29	SetName(ConstString (llvm::formatv(Fmt: "[{0}]", Vals&: func_idx).str()));
30	}
31
32	~ValueObjectVTableChild() override = default;
33
34	std::optional<uint64_t> GetByteSize() override { return m_addr_size; };
35
36	llvm::Expected<uint32_t> CalculateNumChildren(uint32_t max) override {
37	return `0`;
38	};
39
40	ValueType GetValueType() const override { return eValueTypeVTableEntry; };
41
42	bool IsInScope() override {
43	if (ValueObject *parent = GetParent())
44	return parent->IsInScope();
45	return false;
46	};
47
48	protected:
49	bool UpdateValue() override {
50	SetValueIsValid(false);
51	m_value.Clear();
52	ValueObject *parent = GetParent();
53	if (!parent) {
54	m_error.SetErrorString("owning vtable object not valid");
55	return false;
56	}
57
58	addr_t parent_addr = parent->GetValueAsUnsigned(LLDB_INVALID_ADDRESS);
59	if (parent_addr == LLDB_INVALID_ADDRESS) {
60	m_error.SetErrorString("invalid vtable address");
61	return false;
62	}
63
64	ProcessSP process_sp = GetProcessSP();
65	if (!process_sp) {
66	m_error.SetErrorString("no process");
67	return false;
68	}
69
70	TargetSP target_sp = GetTargetSP();
71	if (!target_sp) {
72	m_error.SetErrorString("no target");
73	return false;
74	}
75
76	// Each `vtable_entry_addr` points to the function pointer.
77	addr_t vtable_entry_addr = parent_addr + m_func_idx * m_addr_size;
78	addr_t vfunc_ptr =
79	process_sp ->ReadPointerFromMemory(vm_addr: vtable_entry_addr, error&: m_error);
80	if (m_error.Fail()) {
81	m_error.SetErrorStringWithFormat(
82	"failed to read virtual function entry 0x%16.16" PRIx64,
83	vtable_entry_addr);
84	return false;
85	}
86
87
88	// Set our value to be the load address of the function pointer in memory
89	// and our type to be the function pointer type.
90	m_value.SetValueType(Value::ValueType::LoadAddress);
91	m_value.GetScalar() = vtable_entry_addr;
92
93	// See if our resolved address points to a function in the debug info. If
94	// it does, then we can report the type as a function prototype for this
95	// function.
96	Function function = nullptr*;
97	Address resolved_vfunc_ptr_address;
98	target_sp ->ResolveLoadAddress(load_addr: vfunc_ptr, so_addr&: resolved_vfunc_ptr_address);
99	if (resolved_vfunc_ptr_address.IsValid())
100	function = resolved_vfunc_ptr_address.CalculateSymbolContextFunction();
101	if (function) {
102	m_value.SetCompilerType(function->GetCompilerType().GetPointerType());
103	} else {
104	// Set our value's compiler type to a generic function protoype so that
105	// it displays as a hex function pointer for the value and the summary
106	// will display the address description.
107
108	// Get the original type that this vtable is based off of so we can get
109	// the language from it correctly.
110	ValueObject *val = parent->GetParent();
111	auto type_system = target_sp ->GetScratchTypeSystemForLanguage(
112	language: val ? val->GetObjectRuntimeLanguage() : eLanguageTypeC_plus_plus);
113	if (type_system) {
114	m_value.SetCompilerType(
115	(*type_system)->CreateGenericFunctionPrototype().GetPointerType());
116	} else {
117	consumeError(Err: type_system.takeError());
118	}
119	}
120
121	// Now read our value into m_data so that our we can use the default
122	// summary provider for C++ for function pointers which will get the
123	// address description for our function pointer.
124	if (m_error.Success()) {
125	const bool thread_and_frame_only_if_stopped = true;
126	ExecutionContext exe_ctx(
127	GetExecutionContextRef().Lock(thread_and_frame_only_if_stopped));
128	m_error = m_value.GetValueAsData(exe_ctx: &exe_ctx, data&: m_data, module: GetModule().get());
129	}
130	SetValueDidChange(true);
131	SetValueIsValid(true);
132	return true;
133	};
134
135	CompilerType GetCompilerTypeImpl() override {
136	return m_value.GetCompilerType();
137	};
138
139	const uint32_t m_func_idx;
140	const uint64_t m_addr_size;
141
142	private:
143	// For ValueObject only
144	ValueObjectVTableChild(const ValueObjectVTableChild &) = delete;
145	const ValueObjectVTableChild &
146	operator=(const ValueObjectVTableChild &) = delete;
147	};
148
149	ValueObjectSP ValueObjectVTable::Create(ValueObject &parent) {
150	return (new ValueObjectVTable (parent))->GetSP();
151	}
152
153	ValueObjectVTable::ValueObjectVTable(ValueObject &parent)
154	: ValueObject (parent) {
155	SetFormat(eFormatPointer);
156	}
157
158	std::optional<uint64_t> ValueObjectVTable::GetByteSize() {
159	if (m_vtable_symbol)
160	return m_vtable_symbol->GetByteSize();
161	return std::nullopt;
162	}
163
164	llvm::Expected<uint32_t> ValueObjectVTable::CalculateNumChildren(uint32_t max) {
165	if (UpdateValueIfNeeded(update_format: false))
166	return m_num_vtable_entries <= max ? m_num_vtable_entries : max;
167	return `0`;
168	}
169
170	ValueType ValueObjectVTable::GetValueType() const { return eValueTypeVTable; }
171
172	ConstString ValueObjectVTable::GetTypeName() {
173	if (m_vtable_symbol)
174	return m_vtable_symbol->GetName();
175	return ConstString ();
176	}
177
178	ConstString ValueObjectVTable::GetQualifiedTypeName() { return GetTypeName(); }
179
180	ConstString ValueObjectVTable::GetDisplayTypeName() {
181	if (m_vtable_symbol)
182	return m_vtable_symbol->GetDisplayName();
183	return ConstString ();
184	}
185
186	bool ValueObjectVTable::IsInScope() { return GetParent()->IsInScope(); }
187
188	ValueObject *ValueObjectVTable::CreateChildAtIndex(size_t idx,
189	bool synthetic_array_member,
190	int32_t synthetic_index) {
191	if (synthetic_array_member)
192	return nullptr;
193	return new ValueObjectVTableChild (*this, idx, m_addr_size);
194	}
195
196	bool ValueObjectVTable::UpdateValue() {
197	m_error.Clear();
198	m_flags.m_children_count_valid = false;
199	SetValueIsValid(false);
200	m_num_vtable_entries = `0`;
201	ValueObject *parent = GetParent();
202	if (!parent) {
203	m_error.SetErrorString("no parent object");
204	return false;
205	}
206
207	ProcessSP process_sp = GetProcessSP();
208	if (!process_sp) {
209	m_error.SetErrorString("no process");
210	return false;
211	}
212
213	const LanguageType language = parent->GetObjectRuntimeLanguage();
214	LanguageRuntime *language_runtime = process_sp ->GetLanguageRuntime(language);
215
216	if (language_runtime == nullptr) {
217	m_error.SetErrorStringWithFormat(
218	"no language runtime support for the language \"%s\"",
219	Language::GetNameForLanguageType(language));
220	return false;
221	}
222
223	// Get the vtable information from the language runtime.
224	llvm::Expected<LanguageRuntime::VTableInfo> vtable_info_or_err =
225	language_runtime->GetVTableInfo(in_value&: parent, /check_type=/*true);
226	if (!vtable_info_or_err) {
227	m_error = vtable_info_or_err.takeError();
228	return false;
229	}
230
231	TargetSP target_sp = GetTargetSP();
232	const addr_t vtable_start_addr =
233	vtable_info_or_err ->addr.GetLoadAddress(target: target_sp.get());
234
235	m_vtable_symbol = vtable_info_or_err ->symbol;
236	if (!m_vtable_symbol) {
237	m_error.SetErrorStringWithFormat(
238	"no vtable symbol found containing 0x%" PRIx64, vtable_start_addr);
239	return false;
240	}
241
242	// Now that we know it's a vtable, we update the object's state.
243	SetName(GetTypeName());
244
245	// Calculate the number of entries
246	if (!m_vtable_symbol->GetByteSizeIsValid()) {
247	m_error.SetErrorStringWithFormat(
248	"vtable symbol \"%s\" doesn't have a valid size",
249	m_vtable_symbol->GetMangled().GetDemangledName().GetCString());
250	return false;
251	}
252
253	m_addr_size = process_sp ->GetAddressByteSize();
254	const addr_t vtable_end_addr =
255	m_vtable_symbol->GetLoadAddress(target: target_sp.get()) +
256	m_vtable_symbol->GetByteSize();
257	m_num_vtable_entries = (vtable_end_addr - vtable_start_addr) / m_addr_size;
258
259	m_value.SetValueType(Value::ValueType::LoadAddress);
260	m_value.GetScalar() = parent->GetAddressOf();
261	auto type_system_or_err =
262	target_sp ->GetScratchTypeSystemForLanguage(language: eLanguageTypeC_plus_plus);
263	if (type_system_or_err) {
264	m_value.SetCompilerType(
265	(*type_system_or_err)->GetBasicTypeFromAST(basic_type: eBasicTypeUnsignedLong));
266	} else {
267	consumeError(Err: type_system_or_err.takeError());
268	}
269	SetValueDidChange(true);
270	SetValueIsValid(true);
271	return true;
272	}
273
274	CompilerType ValueObjectVTable::GetCompilerTypeImpl() { return CompilerType (); }
275
276	ValueObjectVTable::~ValueObjectVTable() = default;
277

source code of lldb/source/Core/ValueObjectVTable.cpp