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llvm-project/lldb/source/Core/ValueObject.cpp

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//===-- ValueObject.cpp -----------------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "lldb/Core/ValueObject.h"
#include "lldb/Core/Address.h"
#include "lldb/Core/Module.h"
#include "lldb/Core/ValueObjectCast.h"
#include "lldb/Core/ValueObjectChild.h"
#include "lldb/Core/ValueObjectConstResult.h"
#include "lldb/Core/ValueObjectDynamicValue.h"
#include "lldb/Core/ValueObjectMemory.h"
#include "lldb/Core/ValueObjectSyntheticFilter.h"
#include "lldb/DataFormatters/DataVisualization.h"
#include "lldb/DataFormatters/DumpValueObjectOptions.h"
#include "lldb/DataFormatters/FormatManager.h"
#include "lldb/DataFormatters/StringPrinter.h"
#include "lldb/DataFormatters/TypeFormat.h"
#include "lldb/DataFormatters/TypeSummary.h"
#include "lldb/DataFormatters/TypeValidator.h"
#include "lldb/DataFormatters/ValueObjectPrinter.h"
#include "lldb/Expression/ExpressionVariable.h"
#include "lldb/Symbol/ClangASTContext.h"
#include "lldb/Symbol/CompileUnit.h"
#include "lldb/Symbol/CompilerType.h"
#include "lldb/Symbol/Declaration.h"
#include "lldb/Symbol/SymbolContext.h"
#include "lldb/Symbol/Type.h"
#include "lldb/Symbol/Variable.h"
#include "lldb/Target/ExecutionContext.h"
#include "lldb/Target/Language.h"
#include "lldb/Target/LanguageRuntime.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/StackFrame.h"
#include "lldb/Target/Target.h"
#include "lldb/Target/Thread.h"
#include "lldb/Target/ThreadList.h"
#include "lldb/Utility/DataBuffer.h"
#include "lldb/Utility/DataBufferHeap.h"
#include "lldb/Utility/Flags.h"
#include "lldb/Utility/Log.h"
#include "lldb/Utility/Logging.h"
#include "lldb/Utility/Scalar.h"
#include "lldb/Utility/SharingPtr.h"
#include "lldb/Utility/Stream.h"
#include "lldb/Utility/StreamString.h"
#include "lldb/lldb-private-types.h"
#include "llvm/Support/Compiler.h"
#include <algorithm>
#include <cstdint>
#include <cstdlib>
#include <memory>
#include <tuple>
#include <assert.h>
#include <inttypes.h>
#include <stdio.h>
#include <string.h>
namespace lldb_private {
class ExecutionContextScope;
}
namespace lldb_private {
class SymbolContextScope;
}
using namespace lldb;
using namespace lldb_private;
static 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_root(nullptr),
m_update_point(parent.GetUpdatePoint()), 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_validation_result(),
m_manager(parent.GetManager()), m_children(), m_synthetic_children(),
m_dynamic_value(nullptr), m_synthetic_value(nullptr),
m_deref_valobj(nullptr), m_format(eFormatDefault),
m_last_format(eFormatDefault), m_last_format_mgr_revision(0),
m_type_summary_sp(), m_type_format_sp(), m_synthetic_children_sp(),
m_type_validator_sp(), m_user_id_of_forced_summary(),
m_address_type_of_ptr_or_ref_children(eAddressTypeInvalid),
m_value_checksum(),
m_preferred_display_language(lldb::eLanguageTypeUnknown),
m_language_flags(0), m_value_is_valid(false), m_value_did_change(false),
m_children_count_valid(false), m_old_value_valid(false),
m_is_deref_of_parent(false), m_is_array_item_for_pointer(false),
m_is_bitfield_for_scalar(false), m_is_child_at_offset(false),
m_is_getting_summary(false),
m_did_calculate_complete_objc_class_type(false),
m_is_synthetic_children_generated(
parent.m_is_synthetic_children_generated) {
m_data.SetByteOrder(parent.GetDataExtractor().GetByteOrder());
m_data.SetAddressByteSize(parent.GetDataExtractor().GetAddressByteSize());
m_manager->ManageObject(this);
}
// ValueObject constructor
ValueObject::ValueObject(ExecutionContextScope *exe_scope,
AddressType child_ptr_or_ref_addr_type)
: UserID(++g_value_obj_uid), // Unique identifier for every value object
m_parent(nullptr), m_root(nullptr), m_update_point(exe_scope), 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_validation_result(), m_manager(), m_children(), m_synthetic_children(),
m_dynamic_value(nullptr), m_synthetic_value(nullptr),
m_deref_valobj(nullptr), m_format(eFormatDefault),
m_last_format(eFormatDefault), m_last_format_mgr_revision(0),
m_type_summary_sp(), m_type_format_sp(), m_synthetic_children_sp(),
m_type_validator_sp(), m_user_id_of_forced_summary(),
m_address_type_of_ptr_or_ref_children(child_ptr_or_ref_addr_type),
m_value_checksum(),
m_preferred_display_language(lldb::eLanguageTypeUnknown),
m_language_flags(0), m_value_is_valid(false), m_value_did_change(false),
m_children_count_valid(false), m_old_value_valid(false),
m_is_deref_of_parent(false), m_is_array_item_for_pointer(false),
m_is_bitfield_for_scalar(false), m_is_child_at_offset(false),
m_is_getting_summary(false),
m_did_calculate_complete_objc_class_type(false),
m_is_synthetic_children_generated(false) {
if (exe_scope) {
TargetSP target_sp(exe_scope->CalculateTarget());
if (target_sp) {
const ArchSpec &arch = target_sp->GetArchitecture();
m_data.SetByteOrder(arch.GetByteOrder());
m_data.SetAddressByteSize(arch.GetAddressByteSize());
}
}
m_manager = new ValueObjectManager();
m_manager->ManageObject(this);
}
// Destructor
ValueObject::~ValueObject() {}
void ValueObject::UpdateChildrenAddressType() {
Value::ValueType value_type = m_value.GetValueType();
ExecutionContext exe_ctx(GetExecutionContextRef());
Process *process = exe_ctx.GetProcessPtr();
const bool process_is_alive = process && process->IsAlive();
const uint32_t type_info = GetCompilerType().GetTypeInfo();
const bool is_pointer_or_ref =
(type_info & (lldb::eTypeIsPointer | lldb::eTypeIsReference)) != 0;
switch (value_type) {
case Value::eValueTypeFileAddress:
// If this type is a pointer, then its children will be considered load
// addresses if the pointer or reference is dereferenced, but only if
// the process is alive.
//
// There could be global variables like in the following code:
// struct LinkedListNode { Foo* foo; LinkedListNode* next; };
// Foo g_foo1;
// Foo g_foo2;
// LinkedListNode g_second_node = { &g_foo2, NULL };
// LinkedListNode g_first_node = { &g_foo1, &g_second_node };
//
// When we aren't running, we should be able to look at these variables
// using the "target variable" command. Children of the "g_first_node"
// always will be of the same address type as the parent. But children
// of the "next" member of LinkedListNode will become load addresses if
// we have a live process, or remain a file address if it was a file
// address.
if (process_is_alive && is_pointer_or_ref)
SetAddressTypeOfChildren(eAddressTypeLoad);
else
SetAddressTypeOfChildren(eAddressTypeFile);
break;
case Value::eValueTypeHostAddress:
// Same as above for load addresses, except children of pointer or refs
// are always load addresses. Host addresses are used to store freeze
// dried variables. If this type is a struct, the entire struct
// contents will be copied into the heap of the
// LLDB process, but we do not currently follow any pointers.
if (is_pointer_or_ref)
SetAddressTypeOfChildren(eAddressTypeLoad);
else
SetAddressTypeOfChildren(eAddressTypeHost);
break;
case Value::eValueTypeLoadAddress:
case Value::eValueTypeScalar:
case Value::eValueTypeVector:
SetAddressTypeOfChildren(eAddressTypeLoad);
break;
}
}
bool ValueObject::UpdateValueIfNeeded(bool update_format) {
bool did_change_formats = false;
if (update_format)
did_change_formats = UpdateFormatsIfNeeded();
// If this is a constant value, then our success is predicated on whether we
// have an error or not
if (GetIsConstant()) {
// if you are constant, things might still have changed behind your back
// (e.g. you are a frozen object and things have changed deeper than you
// cared to freeze-dry yourself) in this case, your value has not changed,
// but "computed" entries might have, so you might now have a different
// summary, or a different object description. clear these so we will
// recompute them
if (update_format && !did_change_formats)
ClearUserVisibleData(eClearUserVisibleDataItemsSummary |
eClearUserVisibleDataItemsDescription);
return m_error.Success();
}
bool first_update = IsChecksumEmpty();
if (NeedsUpdating()) {
m_update_point.SetUpdated();
// 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);
ClearUserVisibleData(eClearUserVisibleDataItemsValue);
}
ClearUserVisibleData();
if (IsInScope()) {
const bool value_was_valid = GetValueIsValid();
SetValueDidChange(false);
m_error.Clear();
// Call the pure virtual function to update the value
bool need_compare_checksums = false;
llvm::SmallVector<uint8_t, 16> old_checksum;
if (!first_update && CanProvideValue()) {
need_compare_checksums = true;
old_checksum.resize(m_value_checksum.size());
std::copy(m_value_checksum.begin(), m_value_checksum.end(),
old_checksum.begin());
}
bool success = UpdateValue();
SetValueIsValid(success);
if (success) {
UpdateChildrenAddressType();
const uint64_t max_checksum_size = 128;
m_data.Checksum(m_value_checksum, max_checksum_size);
} else {
need_compare_checksums = false;
m_value_checksum.clear();
}
assert(!need_compare_checksums ||
(!old_checksum.empty() && !m_value_checksum.empty()));
if (first_update)
SetValueDidChange(false);
else if (!m_value_did_change && !success) {
// 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);
} else if (need_compare_checksums) {
SetValueDidChange(memcmp(&old_checksum[0], &m_value_checksum[0],
m_value_checksum.size()));
}
} else {
m_error.SetErrorString("out of scope");
}
}
return m_error.Success();
}
bool ValueObject::UpdateFormatsIfNeeded() {
Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_DATAFORMATTERS));
LLDB_LOGF(log,
"[%s %p] checking for FormatManager revisions. ValueObject "
"rev: %d - Global rev: %d",
GetName().GetCString(), static_cast<void *>(this),
m_last_format_mgr_revision,
DataVisualization::GetCurrentRevision());
bool any_change = false;
if ((m_last_format_mgr_revision != DataVisualization::GetCurrentRevision())) {
m_last_format_mgr_revision = DataVisualization::GetCurrentRevision();
any_change = true;
SetValueFormat(DataVisualization::GetFormat(*this, eNoDynamicValues));
SetSummaryFormat(
DataVisualization::GetSummaryFormat(*this, GetDynamicValueType()));
#ifndef LLDB_DISABLE_PYTHON
SetSyntheticChildren(
DataVisualization::GetSyntheticChildren(*this, GetDynamicValueType()));
#endif
SetValidator(DataVisualization::GetValidator(*this, GetDynamicValueType()));
}
return any_change;
}
void ValueObject::SetNeedsUpdate() {
m_update_point.SetNeedsUpdate();
// We have to clear the value string here so ConstResult children will notice
// if their values are changed by hand (i.e. with SetValueAsCString).
ClearUserVisibleData(eClearUserVisibleDataItemsValue);
}
void ValueObject::ClearDynamicTypeInformation() {
m_children_count_valid = false;
m_did_calculate_complete_objc_class_type = false;
m_last_format_mgr_revision = 0;
m_override_type = CompilerType();
SetValueFormat(lldb::TypeFormatImplSP());
SetSummaryFormat(lldb::TypeSummaryImplSP());
SetSyntheticChildren(lldb::SyntheticChildrenSP());
}
CompilerType ValueObject::MaybeCalculateCompleteType() {
CompilerType compiler_type(GetCompilerTypeImpl());
if (m_did_calculate_complete_objc_class_type) {
if (m_override_type.IsValid())
return m_override_type;
else
return compiler_type;
}
m_did_calculate_complete_objc_class_type = true;
ProcessSP process_sp(
GetUpdatePoint().GetExecutionContextRef().GetProcessSP());
if (!process_sp)
return compiler_type;
if (auto *runtime =
process_sp->GetLanguageRuntime(GetObjectRuntimeLanguage())) {
if (llvm::Optional<CompilerType> complete_type =
runtime->GetRuntimeType(compiler_type)) {
m_override_type = complete_type.getValue();
if (m_override_type.IsValid())
return m_override_type;
}
}
return compiler_type;
}
CompilerType ValueObject::GetCompilerType() {
return MaybeCalculateCompleteType();
}
TypeImpl ValueObject::GetTypeImpl() { return TypeImpl(GetCompilerType()); }
DataExtractor &ValueObject::GetDataExtractor() {
UpdateValueIfNeeded(false);
return m_data;
}
const Status &ValueObject::GetError() {
UpdateValueIfNeeded(false);
return m_error;
}
ConstString ValueObject::GetName() const { return m_name; }
const char *ValueObject::GetLocationAsCString() {
return GetLocationAsCStringImpl(m_value, m_data);
}
const char *ValueObject::GetLocationAsCStringImpl(const Value &value,
const DataExtractor &data) {
if (UpdateValueIfNeeded(false)) {
if (m_location_str.empty()) {
StreamString sstr;
Value::ValueType value_type = value.GetValueType();
switch (value_type) {
case Value::eValueTypeScalar:
case Value::eValueTypeVector:
if (value.GetContextType() == Value::eContextTypeRegisterInfo) {
RegisterInfo *reg_info = 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;
if (m_location_str.empty())
m_location_str = (reg_info->encoding == lldb::eEncodingVector)
? "vector"
: "scalar";
}
}
if (m_location_str.empty())
m_location_str =
(value_type == Value::eValueTypeVector) ? "vector" : "scalar";
break;
case Value::eValueTypeLoadAddress:
case Value::eValueTypeFileAddress:
case Value::eValueTypeHostAddress: {
uint32_t addr_nibble_size = data.GetAddressByteSize() * 2;
sstr.Printf("0x%*.*llx", addr_nibble_size, addr_nibble_size,
value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS));
m_location_str = 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(Scalar &scalar) {
if (UpdateValueIfNeeded(
false)) // make sure that you are up to date before returning anything
{
ExecutionContext exe_ctx(GetExecutionContextRef());
Value tmp_value(m_value);
scalar = tmp_value.ResolveValue(&exe_ctx);
if (scalar.IsValid()) {
const uint32_t bitfield_bit_size = GetBitfieldBitSize();
if (bitfield_bit_size)
return scalar.ExtractBitfield(bitfield_bit_size,
GetBitfieldBitOffset());
return true;
}
}
return false;
}
bool ValueObject::IsLogicalTrue(Status &error) {
if (Language *language = Language::FindPlugin(GetObjectRuntimeLanguage())) {
LazyBool is_logical_true = language->IsLogicalTrue(*this, error);
switch (is_logical_true) {
case eLazyBoolYes:
case eLazyBoolNo:
return (is_logical_true == true);
case eLazyBoolCalculate:
break;
}
}
Scalar scalar_value;
if (!ResolveValue(scalar_value)) {
error.SetErrorString("failed to get a scalar result");
return false;
}
bool ret;
ret = scalar_value.ULongLong(1) != 0;
error.Clear();
return ret;
}
bool ValueObject::GetValueIsValid() const { return m_value_is_valid; }
void ValueObject::SetValueIsValid(bool b) { m_value_is_valid = b; }
bool ValueObject::GetValueDidChange() { return m_value_did_change; }
void ValueObject::SetValueDidChange(bool value_changed) {
m_value_did_change = value_changed;
}
ValueObjectSP ValueObject::GetChildAtIndex(size_t idx, bool can_create) {
ValueObjectSP child_sp;
// We may need to update our value if we are dynamic
if (IsPossibleDynamicType())
UpdateValueIfNeeded(false);
if (idx < GetNumChildren()) {
// Check if we have already made the child value object?
if (can_create && !m_children.HasChildAtIndex(idx)) {
// 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.SetChildAtIndex(idx, CreateChildAtIndex(idx, false, 0));
}
ValueObject *child = m_children.GetChildAtIndex(idx);
if (child != nullptr)
return child->GetSP();
}
return child_sp;
}
lldb::ValueObjectSP
ValueObject::GetChildAtIndexPath(llvm::ArrayRef<size_t> idxs,
size_t *index_of_error) {
if (idxs.size() == 0)
return GetSP();
ValueObjectSP root(GetSP());
for (size_t idx : idxs) {
root = root->GetChildAtIndex(idx, true);
if (!root) {
if (index_of_error)
*index_of_error = idx;
return root;
}
}
return root;
}
lldb::ValueObjectSP ValueObject::GetChildAtIndexPath(
llvm::ArrayRef<std::pair<size_t, bool>> idxs, size_t *index_of_error) {
if (idxs.size() == 0)
return GetSP();
ValueObjectSP root(GetSP());
for (std::pair<size_t, bool> idx : idxs) {
root = root->GetChildAtIndex(idx.first, idx.second);
if (!root) {
if (index_of_error)
*index_of_error = idx.first;
return root;
}
}
return root;
}
lldb::ValueObjectSP
ValueObject::GetChildAtNamePath(llvm::ArrayRef<ConstString> names,
ConstString *name_of_error) {
if (names.size() == 0)
return GetSP();
ValueObjectSP root(GetSP());
for (ConstString name : names) {
root = root->GetChildMemberWithName(name, true);
if (!root) {
if (name_of_error)
*name_of_error = name;
return root;
}
}
return root;
}
lldb::ValueObjectSP ValueObject::GetChildAtNamePath(
llvm::ArrayRef<std::pair<ConstString, bool>> names,
ConstString *name_of_error) {
if (names.size() == 0)
return GetSP();
ValueObjectSP root(GetSP());
for (std::pair<ConstString, bool> name : names) {
root = root->GetChildMemberWithName(name.first, name.second);
if (!root) {
if (name_of_error)
*name_of_error = name.first;
return root;
}
}
return root;
}
size_t ValueObject::GetIndexOfChildWithName(ConstString name) {
bool omit_empty_base_classes = true;
return GetCompilerType().GetIndexOfChildWithName(name.GetCString(),
omit_empty_base_classes);
}
ValueObjectSP ValueObject::GetChildMemberWithName(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
ValueObjectSP child_sp;
// We may need to update our value if we are dynamic
if (IsPossibleDynamicType())
UpdateValueIfNeeded(false);
std::vector<uint32_t> child_indexes;
bool omit_empty_base_classes = true;
if (!GetCompilerType().IsValid())
return ValueObjectSP();
const size_t num_child_indexes =
GetCompilerType().GetIndexOfChildMemberWithName(
name.GetCString(), omit_empty_base_classes, child_indexes);
if (num_child_indexes > 0) {
std::vector<uint32_t>::const_iterator pos = child_indexes.begin();
std::vector<uint32_t>::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;
}
size_t ValueObject::GetNumChildren(uint32_t max) {
UpdateValueIfNeeded();
if (max < UINT32_MAX) {
if (m_children_count_valid) {
size_t children_count = m_children.GetChildrenCount();
return children_count <= max ? children_count : max;
} else
return CalculateNumChildren(max);
}
if (!m_children_count_valid) {
SetNumChildren(CalculateNumChildren());
}
return m_children.GetChildrenCount();
}
bool ValueObject::MightHaveChildren() {
bool has_children = false;
const uint32_t type_info = GetTypeInfo();
if (type_info) {
if (type_info & (eTypeHasChildren | eTypeIsPointer | eTypeIsReference))
has_children = true;
} else {
has_children = GetNumChildren() > 0;
}
return has_children;
}
// Should only be called by ValueObject::GetNumChildren()
void ValueObject::SetNumChildren(size_t num_children) {
m_children_count_valid = true;
m_children.SetChildrenCount(num_children);
}
void ValueObject::SetName(ConstString name) { m_name = name; }
ValueObject *ValueObject::CreateChildAtIndex(size_t idx,
bool synthetic_array_member,
int32_t synthetic_index) {
ValueObject *valobj = nullptr;
bool omit_empty_base_classes = true;
bool ignore_array_bounds = synthetic_array_member;
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;
bool child_is_deref_of_parent = false;
uint64_t language_flags = 0;
const bool transparent_pointers = !synthetic_array_member;
CompilerType child_compiler_type;
ExecutionContext exe_ctx(GetExecutionContextRef());
child_compiler_type = GetCompilerType().GetChildCompilerTypeAtIndex(
&exe_ctx, idx, transparent_pointers, omit_empty_base_classes,
ignore_array_bounds, child_name_str, child_byte_size, child_byte_offset,
child_bitfield_bit_size, child_bitfield_bit_offset, child_is_base_class,
child_is_deref_of_parent, this, language_flags);
if (child_compiler_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 = new ValueObjectChild(
*this, child_compiler_type, child_name, child_byte_size,
child_byte_offset, child_bitfield_bit_size, child_bitfield_bit_offset,
child_is_base_class, child_is_deref_of_parent, eAddressTypeInvalid,
language_flags);
}
return valobj;
}
bool ValueObject::GetSummaryAsCString(TypeSummaryImpl *summary_ptr,
std::string &destination,
lldb::LanguageType lang) {
return GetSummaryAsCString(summary_ptr, destination,
TypeSummaryOptions().SetLanguage(lang));
}
bool ValueObject::GetSummaryAsCString(TypeSummaryImpl *summary_ptr,
std::string &destination,
const TypeSummaryOptions &options) {
destination.clear();
// ideally we would like to bail out if passing NULL, but if we do so we end
// up not providing the summary for function pointers anymore
if (/*summary_ptr == NULL ||*/ m_is_getting_summary)
return false;
m_is_getting_summary = true;
TypeSummaryOptions actual_options(options);
if (actual_options.GetLanguage() == lldb::eLanguageTypeUnknown)
actual_options.SetLanguage(GetPreferredDisplayLanguage());
// this is a hot path in code and we prefer to avoid setting this string all
// too often also clearing out other information that we might care to see in
// a crash log. might be useful in very specific situations though.
/*Host::SetCrashDescriptionWithFormat("Trying to fetch a summary for %s %s.
Summary provider's description is %s",
GetTypeName().GetCString(),
GetName().GetCString(),
summary_ptr->GetDescription().c_str());*/
if (UpdateValueIfNeeded(false) && summary_ptr) {
if (HasSyntheticValue())
m_synthetic_value->UpdateValueIfNeeded(); // the summary might depend on
// the synthetic children being
// up-to-date (e.g. ${svar%#})
summary_ptr->FormatObject(this, destination, actual_options);
}
m_is_getting_summary = false;
return !destination.empty();
}
const char *ValueObject::GetSummaryAsCString(lldb::LanguageType lang) {
if (UpdateValueIfNeeded(true) && m_summary_str.empty()) {
TypeSummaryOptions summary_options;
summary_options.SetLanguage(lang);
GetSummaryAsCString(GetSummaryFormat().get(), m_summary_str,
summary_options);
}
if (m_summary_str.empty())
return nullptr;
return m_summary_str.c_str();
}
bool ValueObject::GetSummaryAsCString(std::string &destination,
const TypeSummaryOptions &options) {
return GetSummaryAsCString(GetSummaryFormat().get(), destination, options);
}
bool ValueObject::IsCStringContainer(bool check_pointer) {
CompilerType pointee_or_element_compiler_type;
const Flags type_flags(GetTypeInfo(&pointee_or_element_compiler_type));
bool is_char_arr_ptr(type_flags.AnySet(eTypeIsArray | eTypeIsPointer) &&
pointee_or_element_compiler_type.IsCharType());
if (!is_char_arr_ptr)
return false;
if (!check_pointer)
return true;
if (type_flags.Test(eTypeIsArray))
return true;
addr_t cstr_address = LLDB_INVALID_ADDRESS;
AddressType cstr_address_type = eAddressTypeInvalid;
cstr_address = GetAddressOf(true, &cstr_address_type);
return (cstr_address != LLDB_INVALID_ADDRESS);
}
size_t ValueObject::GetPointeeData(DataExtractor &data, uint32_t item_idx,
uint32_t item_count) {
CompilerType pointee_or_element_compiler_type;
const uint32_t type_info = GetTypeInfo(&pointee_or_element_compiler_type);
const bool is_pointer_type = type_info & eTypeIsPointer;
const bool is_array_type = type_info & eTypeIsArray;
if (!(is_pointer_type || is_array_type))
return 0;
if (item_count == 0)
return 0;
ExecutionContext exe_ctx(GetExecutionContextRef());
llvm::Optional<uint64_t> item_type_size =
pointee_or_element_compiler_type.GetByteSize(
exe_ctx.GetBestExecutionContextScope());
if (!item_type_size)
return 0;
const uint64_t bytes = item_count * *item_type_size;
const uint64_t offset = item_idx * *item_type_size;
if (item_idx == 0 && item_count == 1) // simply a deref
{
if (is_pointer_type) {
Status error;
ValueObjectSP pointee_sp = Dereference(error);
if (error.Fail() || pointee_sp.get() == nullptr)
return 0;
return pointee_sp->GetData(data, error);
} else {
ValueObjectSP child_sp = GetChildAtIndex(0, true);
if (child_sp.get() == nullptr)
return 0;
Status error;
return child_sp->GetData(data, error);
}
return true;
} else /* (items > 1) */
{
Status error;
lldb_private::DataBufferHeap *heap_buf_ptr = nullptr;
lldb::DataBufferSP data_sp(heap_buf_ptr =
new lldb_private::DataBufferHeap());
AddressType addr_type;
lldb::addr_t addr = is_pointer_type ? GetPointerValue(&addr_type)
: GetAddressOf(true, &addr_type);
switch (addr_type) {
case eAddressTypeFile: {
ModuleSP module_sp(GetModule());
if (module_sp) {
addr = addr + offset;
Address so_addr;
module_sp->ResolveFileAddress(addr, so_addr);
ExecutionContext exe_ctx(GetExecutionContextRef());
Target *target = exe_ctx.GetTargetPtr();
if (target) {
heap_buf_ptr->SetByteSize(bytes);
size_t bytes_read = target->ReadMemory(
so_addr, false, heap_buf_ptr->GetBytes(), bytes, error);
if (error.Success()) {
data.SetData(data_sp);
return bytes_read;
}
}
}
} break;
case eAddressTypeLoad: {
ExecutionContext exe_ctx(GetExecutionContextRef());
Process *process = exe_ctx.GetProcessPtr();
if (process) {
heap_buf_ptr->SetByteSize(bytes);
size_t bytes_read = process->ReadMemory(
addr + offset, heap_buf_ptr->GetBytes(), bytes, error);
if (error.Success() || bytes_read > 0) {
data.SetData(data_sp);
return bytes_read;
}
}
} break;
case eAddressTypeHost: {
auto max_bytes =
GetCompilerType().GetByteSize(exe_ctx.GetBestExecutionContextScope());
if (max_bytes && *max_bytes > offset) {
size_t bytes_read = std::min<uint64_t>(*max_bytes - offset, bytes);
addr = m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS);
if (addr == 0 || addr == LLDB_INVALID_ADDRESS)
break;
heap_buf_ptr->CopyData((uint8_t *)(addr + offset), bytes_read);
data.SetData(data_sp);
return bytes_read;
}
} break;
case eAddressTypeInvalid:
break;
}
}
return 0;
}
uint64_t ValueObject::GetData(DataExtractor &data, Status &error) {
UpdateValueIfNeeded(false);
ExecutionContext exe_ctx(GetExecutionContextRef());
error = m_value.GetValueAsData(&exe_ctx, data, GetModule().get());
if (error.Fail()) {
if (m_data.GetByteSize()) {
data = m_data;
error.Clear();
return data.GetByteSize();
} else {
return 0;
}
}
data.SetAddressByteSize(m_data.GetAddressByteSize());
data.SetByteOrder(m_data.GetByteOrder());
return data.GetByteSize();
}
bool ValueObject::SetData(DataExtractor &data, Status &error) {
error.Clear();
// Make sure our value is up to date first so that our location and location
// type is valid.
if (!UpdateValueIfNeeded(false)) {
error.SetErrorString("unable to read value");
return false;
}
uint64_t count = 0;
const Encoding encoding = GetCompilerType().GetEncoding(count);
const size_t byte_size = GetByteSize();
Value::ValueType value_type = m_value.GetValueType();
switch (value_type) {
case Value::eValueTypeScalar: {
Status set_error =
m_value.GetScalar().SetValueFromData(data, encoding, byte_size);
if (!set_error.Success()) {
error.SetErrorStringWithFormat("unable to set scalar value: %s",
set_error.AsCString());
return false;
}
} break;
case Value::eValueTypeLoadAddress: {
// If it is a load address, then the scalar value is the storage location
// of the data, and we have to shove this value down to that load location.
ExecutionContext exe_ctx(GetExecutionContextRef());
Process *process = exe_ctx.GetProcessPtr();
if (process) {
addr_t target_addr = m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS);
size_t bytes_written = process->WriteMemory(
target_addr, data.GetDataStart(), byte_size, error);
if (!error.Success())
return false;
if (bytes_written != byte_size) {
error.SetErrorString("unable to write value to memory");
return false;
}
}
} break;
case Value::eValueTypeHostAddress: {
// If it is a host address, then we stuff the scalar as a DataBuffer into
// the Value's data.
DataBufferSP buffer_sp(new DataBufferHeap(byte_size, 0));
m_data.SetData(buffer_sp, 0);
data.CopyByteOrderedData(0, byte_size,
const_cast<uint8_t *>(m_data.GetDataStart()),
byte_size, m_data.GetByteOrder());
m_value.GetScalar() = (uintptr_t)m_data.GetDataStart();
} break;
case Value::eValueTypeFileAddress:
case Value::eValueTypeVector:
break;
}
// If we have reached this point, then we have successfully changed the
// value.
SetNeedsUpdate();
return true;
}
static bool CopyStringDataToBufferSP(const StreamString &source,
lldb::DataBufferSP &destination) {
destination = std::make_shared<DataBufferHeap>(source.GetSize() + 1, 0);
memcpy(destination->GetBytes(), source.GetString().data(), source.GetSize());
return true;
}
std::pair<size_t, bool>
ValueObject::ReadPointedString(lldb::DataBufferSP &buffer_sp, Status &error,
uint32_t max_length, bool honor_array,
Format item_format) {
bool was_capped = false;
StreamString s;
ExecutionContext exe_ctx(GetExecutionContextRef());
Target *target = exe_ctx.GetTargetPtr();
if (!target) {
s << "<no target to read from>";
error.SetErrorString("no target to read from");
CopyStringDataToBufferSP(s, buffer_sp);
return {0, was_capped};
}
if (max_length == 0)
max_length = target->GetMaximumSizeOfStringSummary();
size_t bytes_read = 0;
size_t total_bytes_read = 0;
CompilerType compiler_type = GetCompilerType();
CompilerType elem_or_pointee_compiler_type;
const Flags type_flags(GetTypeInfo(&elem_or_pointee_compiler_type));
if (type_flags.AnySet(eTypeIsArray | eTypeIsPointer) &&
elem_or_pointee_compiler_type.IsCharType()) {
addr_t cstr_address = LLDB_INVALID_ADDRESS;
AddressType cstr_address_type = eAddressTypeInvalid;
size_t cstr_len = 0;
bool capped_data = false;
const bool is_array = type_flags.Test(eTypeIsArray);
if (is_array) {
// We have an array
uint64_t array_size = 0;
if (compiler_type.IsArrayType(nullptr, &array_size, nullptr)) {
cstr_len = array_size;
if (cstr_len > max_length) {
capped_data = true;
cstr_len = max_length;
}
}
cstr_address = GetAddressOf(true, &cstr_address_type);
} else {
// We have a pointer
cstr_address = GetPointerValue(&cstr_address_type);
}
if (cstr_address == 0 || cstr_address == LLDB_INVALID_ADDRESS) {
if (cstr_address_type == eAddressTypeHost && is_array) {
const char *cstr = GetDataExtractor().PeekCStr(0);
if (cstr == nullptr) {
s << "<invalid address>";
error.SetErrorString("invalid address");
CopyStringDataToBufferSP(s, buffer_sp);
return {0, was_capped};
}
buffer_sp = std::make_shared<DataBufferHeap>(cstr_len, 0);
memcpy(buffer_sp->GetBytes(), cstr, cstr_len);
return {cstr_len, was_capped};
} else {
s << "<invalid address>";
error.SetErrorString("invalid address");
CopyStringDataToBufferSP(s, buffer_sp);
return {0, was_capped};
}
}
Address cstr_so_addr(cstr_address);
DataExtractor data;
if (cstr_len > 0 && honor_array) {
// I am using GetPointeeData() here to abstract the fact that some
// ValueObjects are actually frozen pointers in the host but the pointed-
// to data lives in the debuggee, and GetPointeeData() automatically
// takes care of this
GetPointeeData(data, 0, cstr_len);
if ((bytes_read = data.GetByteSize()) > 0) {
total_bytes_read = bytes_read;
for (size_t offset = 0; offset < bytes_read; offset++)
s.Printf("%c", *data.PeekData(offset, 1));
if (capped_data)
was_capped = true;
}
} else {
cstr_len = max_length;
const size_t k_max_buf_size = 64;
size_t offset = 0;
int cstr_len_displayed = -1;
bool capped_cstr = false;
// I am using GetPointeeData() here to abstract the fact that some
// ValueObjects are actually frozen pointers in the host but the pointed-
// to data lives in the debuggee, and GetPointeeData() automatically
// takes care of this
while ((bytes_read = GetPointeeData(data, offset, k_max_buf_size)) > 0) {
total_bytes_read += bytes_read;
const char *cstr = data.PeekCStr(0);
size_t len = strnlen(cstr, k_max_buf_size);
if (cstr_len_displayed < 0)
cstr_len_displayed = len;
if (len == 0)
break;
cstr_len_displayed += len;
if (len > bytes_read)
len = bytes_read;
if (len > cstr_len)
len = cstr_len;
for (size_t offset = 0; offset < bytes_read; offset++)
s.Printf("%c", *data.PeekData(offset, 1));
if (len < k_max_buf_size)
break;
if (len >= cstr_len) {
capped_cstr = true;
break;
}
cstr_len -= len;
offset += len;
}
if (cstr_len_displayed >= 0) {
if (capped_cstr)
was_capped = true;
}
}
} else {
error.SetErrorString("not a string object");
s << "<not a string object>";
}
CopyStringDataToBufferSP(s, buffer_sp);
return {total_bytes_read, was_capped};
}
std::pair<TypeValidatorResult, std::string> ValueObject::GetValidationStatus() {
if (!UpdateValueIfNeeded(true))
return {TypeValidatorResult::Success,
""}; // not the validator's job to discuss update problems
if (m_validation_result.hasValue())
return m_validation_result.getValue();
if (!m_type_validator_sp)
return {TypeValidatorResult::Success, ""}; // no validator no failure
auto outcome = m_type_validator_sp->FormatObject(this);
return (m_validation_result = {outcome.m_result, outcome.m_message})
.getValue();
}
const char *ValueObject::GetObjectDescription() {
if (!UpdateValueIfNeeded(true))
return nullptr;
// Return cached value.
if (!m_object_desc_str.empty())
return m_object_desc_str.c_str();
ExecutionContext exe_ctx(GetExecutionContextRef());
Process *process = exe_ctx.GetProcessPtr();
if (!process)
return nullptr;
// Returns the object description produced by one language runtime.
auto get_object_description = [&](LanguageType language) -> const char * {
if (LanguageRuntime *runtime = process->GetLanguageRuntime(language)) {
StreamString s;
if (runtime->GetObjectDescription(s, *this)) {
m_object_desc_str.append(s.GetString());
return m_object_desc_str.c_str();
}
}
return nullptr;
};
// Try the native language runtime first.
LanguageType native_language = GetObjectRuntimeLanguage();
if (const char *desc = get_object_description(native_language))
return desc;
// Try the Objective-C language runtime. This fallback is necessary
// for Objective-C++ and mixed Objective-C / C++ programs.
if (Language::LanguageIsCFamily(native_language))
return get_object_description(eLanguageTypeObjC);
return nullptr;
}
bool ValueObject::GetValueAsCString(const lldb_private::TypeFormatImpl &format,
std::string &destination) {
if (UpdateValueIfNeeded(false))
return format.FormatObject(this, destination);
else
return false;
}
bool ValueObject::GetValueAsCString(lldb::Format format,
std::string &destination) {
return GetValueAsCString(TypeFormatImpl_Format(format), destination);
}
const char *ValueObject::GetValueAsCString() {
if (UpdateValueIfNeeded(true)) {
lldb::TypeFormatImplSP format_sp;
lldb::Format my_format = GetFormat();
if (my_format == lldb::eFormatDefault) {
if (m_type_format_sp)
format_sp = m_type_format_sp;
else {
if (m_is_bitfield_for_scalar)
my_format = eFormatUnsigned;
else {
if (m_value.GetContextType() == Value::eContextTypeRegisterInfo) {
const RegisterInfo *reg_info = m_value.GetRegisterInfo();
if (reg_info)
my_format = reg_info->format;
} else {
my_format = GetValue().GetCompilerType().GetFormat();
}
}
}
}
if (my_format != m_last_format || m_value_str.empty()) {
m_last_format = my_format;
if (!format_sp)
format_sp = std::make_shared<TypeFormatImpl_Format>(my_format);
if (GetValueAsCString(*format_sp.get(), m_value_str)) {
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 nullptr;
return m_value_str.c_str();
}
// if > 8bytes, 0 is returned. this method should mostly be used to read
// address values out of pointers
uint64_t ValueObject::GetValueAsUnsigned(uint64_t fail_value, bool *success) {
// If our byte size is zero this is an aggregate type that has children
if (CanProvideValue()) {
Scalar scalar;
if (ResolveValue(scalar)) {
if (success)
*success = true;
return scalar.ULongLong(fail_value);
}
// fallthrough, otherwise...
}
if (success)
*success = false;
return fail_value;
}
int64_t ValueObject::GetValueAsSigned(int64_t fail_value, bool *success) {
// If our byte size is zero this is an aggregate type that has children
if (CanProvideValue()) {
Scalar scalar;
if (ResolveValue(scalar)) {
if (success)
*success = true;
return scalar.SLongLong(fail_value);
}
// fallthrough, otherwise...
}
if (success)
*success = false;
return fail_value;
}
// if any more "special cases" are added to
// ValueObject::DumpPrintableRepresentation() please keep this call up to date
// by returning true for your new special cases. We will eventually move to
// checking this call result before trying to display special cases
bool ValueObject::HasSpecialPrintableRepresentation(
ValueObjectRepresentationStyle val_obj_display, Format custom_format) {
Flags flags(GetTypeInfo());
if (flags.AnySet(eTypeIsArray | eTypeIsPointer) &&
val_obj_display == ValueObject::eValueObjectRepresentationStyleValue) {
if (IsCStringContainer(true) &&
(custom_format == eFormatCString || custom_format == eFormatCharArray ||
custom_format == eFormatChar || custom_format == eFormatVectorOfChar))
return true;
if (flags.Test(eTypeIsArray)) {
if ((custom_format == eFormatBytes) ||
(custom_format == eFormatBytesWithASCII))
return true;
if ((custom_format == eFormatVectorOfChar) ||
(custom_format == eFormatVectorOfFloat32) ||
(custom_format == eFormatVectorOfFloat64) ||
(custom_format == eFormatVectorOfSInt16) ||
(custom_format == eFormatVectorOfSInt32) ||
(custom_format == eFormatVectorOfSInt64) ||
(custom_format == eFormatVectorOfSInt8) ||
(custom_format == eFormatVectorOfUInt128) ||
(custom_format == eFormatVectorOfUInt16) ||
(custom_format == eFormatVectorOfUInt32) ||
(custom_format == eFormatVectorOfUInt64) ||
(custom_format == eFormatVectorOfUInt8))
return true;
}
}
return false;
}
bool ValueObject::DumpPrintableRepresentation(
Stream &s, ValueObjectRepresentationStyle val_obj_display,
Format custom_format, PrintableRepresentationSpecialCases special,
bool do_dump_error) {
Flags flags(GetTypeInfo());
bool allow_special =
(special == ValueObject::PrintableRepresentationSpecialCases::eAllow);
const bool only_special = false;
if (allow_special) {
if (flags.AnySet(eTypeIsArray | eTypeIsPointer) &&
val_obj_display == ValueObject::eValueObjectRepresentationStyleValue) {
// when being asked to get a printable display an array or pointer type
// directly, try to "do the right thing"
if (IsCStringContainer(true) &&
(custom_format == eFormatCString ||
custom_format == eFormatCharArray || custom_format == eFormatChar ||
custom_format ==
eFormatVectorOfChar)) // print char[] & char* directly
{
Status error;
lldb::DataBufferSP buffer_sp;
std::pair<size_t, bool> read_string = ReadPointedString(
buffer_sp, error, 0, (custom_format == eFormatVectorOfChar) ||
(custom_format == eFormatCharArray));
lldb_private::formatters::StringPrinter::
ReadBufferAndDumpToStreamOptions options(*this);
options.SetData(DataExtractor(
buffer_sp, lldb::eByteOrderInvalid,
8)); // none of this matters for a string - pass some defaults
options.SetStream(&s);
options.SetPrefixToken(nullptr);
options.SetQuote('"');
options.SetSourceSize(buffer_sp->GetByteSize());
options.SetIsTruncated(read_string.second);
formatters::StringPrinter::ReadBufferAndDumpToStream<
lldb_private::formatters::StringPrinter::StringElementType::ASCII>(
options);
return !error.Fail();
}
if (custom_format == eFormatEnum)
return false;
// this only works for arrays, because I have no way to know when the
// pointed memory ends, and no special \0 end of data marker
if (flags.Test(eTypeIsArray)) {
if ((custom_format == eFormatBytes) ||
(custom_format == eFormatBytesWithASCII)) {
const size_t count = GetNumChildren();
s << '[';
for (size_t low = 0; low < count; low++) {
if (low)
s << ',';
ValueObjectSP child = GetChildAtIndex(low, true);
if (!child.get()) {
s << "<invalid child>";
continue;
}
child->DumpPrintableRepresentation(
s, ValueObject::eValueObjectRepresentationStyleValue,
custom_format);
}
s << ']';
return true;
}
if ((custom_format == eFormatVectorOfChar) ||
(custom_format == eFormatVectorOfFloat32) ||
(custom_format == eFormatVectorOfFloat64) ||
(custom_format == eFormatVectorOfSInt16) ||
(custom_format == eFormatVectorOfSInt32) ||
(custom_format == eFormatVectorOfSInt64) ||
(custom_format == eFormatVectorOfSInt8) ||
(custom_format == eFormatVectorOfUInt128) ||
(custom_format == eFormatVectorOfUInt16) ||
(custom_format == eFormatVectorOfUInt32) ||
(custom_format == eFormatVectorOfUInt64) ||
(custom_format == eFormatVectorOfUInt8)) // arrays of bytes, bytes
// with ASCII or any vector
// format should be printed
// directly
{
const size_t count = GetNumChildren();
Format format = FormatManager::GetSingleItemFormat(custom_format);
s << '[';
for (size_t low = 0; low < count; low++) {
if (low)
s << ',';
ValueObjectSP child = GetChildAtIndex(low, true);
if (!child.get()) {
s << "<invalid child>";
continue;
}
child->DumpPrintableRepresentation(
s, ValueObject::eValueObjectRepresentationStyleValue, format);
}
s << ']';
return true;
}
}
if ((custom_format == eFormatBoolean) ||
(custom_format == eFormatBinary) || (custom_format == eFormatChar) ||
(custom_format == eFormatCharPrintable) ||
(custom_format == eFormatComplexFloat) ||
(custom_format == eFormatDecimal) || (custom_format == eFormatHex) ||
(custom_format == eFormatHexUppercase) ||
(custom_format == eFormatFloat) || (custom_format == eFormatOctal) ||
(custom_format == eFormatOSType) ||
(custom_format == eFormatUnicode16) ||
(custom_format == eFormatUnicode32) ||
(custom_format == eFormatUnsigned) ||
(custom_format == eFormatPointer) ||
(custom_format == eFormatComplexInteger) ||
(custom_format == eFormatComplex) ||
(custom_format == eFormatDefault)) // use the [] operator
return false;
}
}
if (only_special)
return false;
bool var_success = false;
{
llvm::StringRef str;
// this is a local stream that we are using to ensure that the data pointed
// to by cstr survives long enough for us to copy it to its destination -
// it is necessary to have this temporary storage area for cases where our
// desired output is not backed by some other longer-term storage
StreamString strm;
if (custom_format != eFormatInvalid)
SetFormat(custom_format);
switch (val_obj_display) {
case eValueObjectRepresentationStyleValue:
str = GetValueAsCString();
break;
case eValueObjectRepresentationStyleSummary:
str = GetSummaryAsCString();
break;
case eValueObjectRepresentationStyleLanguageSpecific:
str = GetObjectDescription();
break;
case eValueObjectRepresentationStyleLocation:
str = GetLocationAsCString();
break;
case eValueObjectRepresentationStyleChildrenCount:
strm.Printf("%" PRIu64 "", (uint64_t)GetNumChildren());
str = strm.GetString();
break;
case eValueObjectRepresentationStyleType:
str = GetTypeName().GetStringRef();
break;
case eValueObjectRepresentationStyleName:
str = GetName().GetStringRef();
break;
case eValueObjectRepresentationStyleExpressionPath:
GetExpressionPath(strm, false);
str = strm.GetString();
break;
}
if (str.empty()) {
if (val_obj_display == eValueObjectRepresentationStyleValue)
str = GetSummaryAsCString();
else if (val_obj_display == eValueObjectRepresentationStyleSummary) {
if (!CanProvideValue()) {
strm.Printf("%s @ %s", GetTypeName().AsCString(),
GetLocationAsCString());
str = strm.GetString();
} else
str = GetValueAsCString();
}
}
if (!str.empty())
s << str;
else {
if (m_error.Fail()) {
if (do_dump_error)
s.Printf("<%s>", m_error.AsCString());
else
return false;
} else if (val_obj_display == eValueObjectRepresentationStyleSummary)
s.PutCString("<no summary available>");
else if (val_obj_display == eValueObjectRepresentationStyleValue)
s.PutCString("<no value available>");
else if (val_obj_display ==
eValueObjectRepresentationStyleLanguageSpecific)
s.PutCString("<not a valid Objective-C object>"); // edit this if we
// have other runtimes
// that support a
// description
else
s.PutCString("<no printable representation>");
}
// we should only return false here if we could not do *anything* even if
// we have an error message as output, that's a success from our callers'
// perspective, so return true
var_success = true;
if (custom_format != eFormatInvalid)
SetFormat(eFormatDefault);
}
return var_success;
}
addr_t ValueObject::GetAddressOf(bool scalar_is_load_address,
AddressType *address_type) {
// Can't take address of a bitfield
if (IsBitfield())
return LLDB_INVALID_ADDRESS;
if (!UpdateValueIfNeeded(false))
return LLDB_INVALID_ADDRESS;
switch (m_value.GetValueType()) {
case Value::eValueTypeScalar:
case Value::eValueTypeVector:
if (scalar_is_load_address) {
if (address_type)
*address_type = eAddressTypeLoad;
return m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS);
}
break;
case Value::eValueTypeLoadAddress:
case Value::eValueTypeFileAddress: {
if (address_type)
*address_type = m_value.GetValueAddressType();
return m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS);
} break;
case Value::eValueTypeHostAddress: {
if (address_type)
*address_type = m_value.GetValueAddressType();
return LLDB_INVALID_ADDRESS;
} break;
}
if (address_type)
*address_type = eAddressTypeInvalid;
return LLDB_INVALID_ADDRESS;
}
addr_t ValueObject::GetPointerValue(AddressType *address_type) {
addr_t address = LLDB_INVALID_ADDRESS;
if (address_type)
*address_type = eAddressTypeInvalid;
if (!UpdateValueIfNeeded(false))
return address;
switch (m_value.GetValueType()) {
case Value::eValueTypeScalar:
case Value::eValueTypeVector:
address = m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS);
break;
case Value::eValueTypeHostAddress:
case Value::eValueTypeLoadAddress:
case Value::eValueTypeFileAddress: {
lldb::offset_t data_offset = 0;
address = m_data.GetPointer(&data_offset);
} break;
}
if (address_type)
*address_type = GetAddressTypeOfChildren();
return address;
}
bool ValueObject::SetValueFromCString(const char *value_str, Status &error) {
error.Clear();
// Make sure our value is up to date first so that our location and location
// type is valid.
if (!UpdateValueIfNeeded(false)) {
error.SetErrorString("unable to read value");
return false;
}
uint64_t count = 0;
const Encoding encoding = GetCompilerType().GetEncoding(count);
const size_t byte_size = GetByteSize();
Value::ValueType value_type = m_value.GetValueType();
if (value_type == Value::eValueTypeScalar) {
// If the value is already a scalar, then let the scalar change itself:
m_value.GetScalar().SetValueFromCString(value_str, encoding, byte_size);
} else if (byte_size <= 16) {
// If the value fits in a scalar, then make a new scalar and again let the
// scalar code do the conversion, then figure out where to put the new
// value.
Scalar new_scalar;
error = new_scalar.SetValueFromCString(value_str, encoding, byte_size);
if (error.Success()) {
switch (value_type) {
case Value::eValueTypeLoadAddress: {
// If it is a load address, then the scalar value is the storage
// location of the data, and we have to shove this value down to that
// load location.
ExecutionContext exe_ctx(GetExecutionContextRef());
Process *process = exe_ctx.GetProcessPtr();
if (process) {
addr_t target_addr =
m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS);
size_t bytes_written = process->WriteScalarToMemory(
target_addr, new_scalar, byte_size, error);
if (!error.Success())
return false;
if (bytes_written != byte_size) {
error.SetErrorString("unable to write value to memory");
return false;
}
}
} break;
case Value::eValueTypeHostAddress: {
// If it is a host address, then we stuff the scalar as a DataBuffer
// into the Value's data.
DataExtractor new_data;
new_data.SetByteOrder(m_data.GetByteOrder());
DataBufferSP buffer_sp(new DataBufferHeap(byte_size, 0));
m_data.SetData(buffer_sp, 0);
bool success = new_scalar.GetData(new_data);
if (success) {
new_data.CopyByteOrderedData(
0, byte_size, const_cast<uint8_t *>(m_data.GetDataStart()),
byte_size, m_data.GetByteOrder());
}
m_value.GetScalar() = (uintptr_t)m_data.GetDataStart();
} break;
case Value::eValueTypeFileAddress:
case Value::eValueTypeScalar:
case Value::eValueTypeVector:
break;
}
} else {
return false;
}
} else {
// We don't support setting things bigger than a scalar at present.
error.SetErrorString("unable to write aggregate data type");
return false;
}
// If we have reached this point, then we have successfully changed the
// value.
SetNeedsUpdate();
return true;
}
bool ValueObject::GetDeclaration(Declaration &decl) {
decl.Clear();
return false;
}
ConstString ValueObject::GetTypeName() {
return GetCompilerType().GetConstTypeName();
}
ConstString ValueObject::GetDisplayTypeName() { return GetTypeName(); }
ConstString ValueObject::GetQualifiedTypeName() {
return GetCompilerType().GetConstQualifiedTypeName();
}
LanguageType ValueObject::GetObjectRuntimeLanguage() {
return GetCompilerType().GetMinimumLanguage();
}
void ValueObject::AddSyntheticChild(ConstString key,
ValueObject *valobj) {
m_synthetic_children[key] = valobj;
}
ValueObjectSP ValueObject::GetSyntheticChild(ConstString key) const {
ValueObjectSP synthetic_child_sp;
std::map<ConstString, ValueObject *>::const_iterator pos =
m_synthetic_children.find(key);
if (pos != m_synthetic_children.end())
synthetic_child_sp = pos->second->GetSP();
return synthetic_child_sp;
}
uint32_t
ValueObject::GetTypeInfo(CompilerType *pointee_or_element_compiler_type) {
return GetCompilerType().GetTypeInfo(pointee_or_element_compiler_type);
}
bool ValueObject::IsPointerType() { return GetCompilerType().IsPointerType(); }
bool ValueObject::IsArrayType() {
return GetCompilerType().IsArrayType(nullptr, nullptr, nullptr);
}
bool ValueObject::IsScalarType() { return GetCompilerType().IsScalarType(); }
bool ValueObject::IsIntegerType(bool &is_signed) {
return GetCompilerType().IsIntegerType(is_signed);
}
bool ValueObject::IsPointerOrReferenceType() {
return GetCompilerType().IsPointerOrReferenceType();
}
bool ValueObject::IsPossibleDynamicType() {
ExecutionContext exe_ctx(GetExecutionContextRef());
Process *process = exe_ctx.GetProcessPtr();
if (process)
return process->IsPossibleDynamicValue(*this);
else
return GetCompilerType().IsPossibleDynamicType(nullptr, true, true);
}
bool ValueObject::IsRuntimeSupportValue() {
Process *process(GetProcessSP().get());
if (!process)
return false;
// We trust the the compiler did the right thing and marked runtime support
// values as artificial.
if (!GetVariable() || !GetVariable()->IsArtificial())
return false;
if (auto *runtime = process->GetLanguageRuntime(GetVariable()->GetLanguage()))
if (runtime->IsWhitelistedRuntimeValue(GetName()))
return false;
return true;
}
bool ValueObject::IsNilReference() {
if (Language *language = Language::FindPlugin(GetObjectRuntimeLanguage())) {
return language->IsNilReference(*this);
}
return false;
}
bool ValueObject::IsUninitializedReference() {
if (Language *language = Language::FindPlugin(GetObjectRuntimeLanguage())) {
return language->IsUninitializedReference(*this);
}
return false;
}
// This allows you to create an array member using and index that doesn't not
// fall in the normal bounds of the array. Many times structure can be defined
// as: struct Collection {
// uint32_t item_count;
// Item item_array[0];
// };
// The size of the "item_array" is 1, but many times in practice there are more
// items in "item_array".
ValueObjectSP ValueObject::GetSyntheticArrayMember(size_t index,
bool can_create) {
ValueObjectSP synthetic_child_sp;
if (IsPointerType() || IsArrayType()) {
char index_str[64];
snprintf(index_str, sizeof(index_str), "[%" PRIu64 "]", (uint64_t)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) {
ValueObject *synthetic_child;
// We haven't made a synthetic array member for INDEX yet, so lets make
// one and cache it for any future reference.
synthetic_child = CreateChildAtIndex(0, true, index);
// Cache the value if we got one back...
if (synthetic_child) {
AddSyntheticChild(index_const_str, synthetic_child);
synthetic_child_sp = synthetic_child->GetSP();
synthetic_child_sp->SetName(ConstString(index_str));
synthetic_child_sp->m_is_array_item_for_pointer = true;
}
}
}
return synthetic_child_sp;
}
ValueObjectSP ValueObject::GetSyntheticBitFieldChild(uint32_t from, uint32_t to,
bool can_create) {
ValueObjectSP synthetic_child_sp;
if (IsScalarType()) {
char index_str[64];
snprintf(index_str, sizeof(index_str), "[%i-%i]", from, to);
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) {
uint32_t bit_field_size = to - from + 1;
uint32_t bit_field_offset = from;
if (GetDataExtractor().GetByteOrder() == eByteOrderBig)
bit_field_offset =
GetByteSize() * 8 - bit_field_size - bit_field_offset;
// We haven't made a synthetic array member for INDEX yet, so lets make
// one and cache it for any future reference.
ValueObjectChild *synthetic_child = new ValueObjectChild(
*this, GetCompilerType(), index_const_str, GetByteSize(), 0,
bit_field_size, bit_field_offset, false, false, eAddressTypeInvalid,
0);
// Cache the value if we got one back...
if (synthetic_child) {
AddSyntheticChild(index_const_str, synthetic_child);
synthetic_child_sp = synthetic_child->GetSP();
synthetic_child_sp->SetName(ConstString(index_str));
synthetic_child_sp->m_is_bitfield_for_scalar = true;
}
}
}
return synthetic_child_sp;
}
ValueObjectSP ValueObject::GetSyntheticChildAtOffset(
uint32_t offset, const CompilerType &type, bool can_create,
ConstString name_const_str) {
ValueObjectSP synthetic_child_sp;
if (name_const_str.IsEmpty()) {
char name_str[64];
snprintf(name_str, sizeof(name_str), "@%i", offset);
name_const_str.SetCString(name_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(name_const_str);
if (synthetic_child_sp.get())
return synthetic_child_sp;
if (!can_create)
return {};
ExecutionContext exe_ctx(GetExecutionContextRef());
llvm::Optional<uint64_t> size =
type.GetByteSize(exe_ctx.GetBestExecutionContextScope());
if (!size)
return {};
ValueObjectChild *synthetic_child =
new ValueObjectChild(*this, type, name_const_str, *size, offset, 0, 0,
false, false, eAddressTypeInvalid, 0);
if (synthetic_child) {
AddSyntheticChild(name_const_str, synthetic_child);
synthetic_child_sp = synthetic_child->GetSP();
synthetic_child_sp->SetName(name_const_str);
synthetic_child_sp->m_is_child_at_offset = true;
}
return synthetic_child_sp;
}
ValueObjectSP ValueObject::GetSyntheticBase(uint32_t offset,
const CompilerType &type,
bool can_create,
ConstString name_const_str) {
ValueObjectSP synthetic_child_sp;
if (name_const_str.IsEmpty()) {
char name_str[128];
snprintf(name_str, sizeof(name_str), "base%s@%i",
type.GetTypeName().AsCString("<unknown>"), offset);
name_const_str.SetCString(name_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(name_const_str);
if (synthetic_child_sp.get())
return synthetic_child_sp;
if (!can_create)
return {};
const bool is_base_class = true;
ExecutionContext exe_ctx(GetExecutionContextRef());
llvm::Optional<uint64_t> size =
type.GetByteSize(exe_ctx.GetBestExecutionContextScope());
if (!size)
return {};
ValueObjectChild *synthetic_child =
new ValueObjectChild(*this, type, name_const_str, *size, offset, 0, 0,
is_base_class, false, eAddressTypeInvalid, 0);
if (synthetic_child) {
AddSyntheticChild(name_const_str, synthetic_child);
synthetic_child_sp = synthetic_child->GetSP();
synthetic_child_sp->SetName(name_const_str);
}
return synthetic_child_sp;
}
// your expression path needs to have a leading . or -> (unless it somehow
// "looks like" an array, in which case it has a leading [ symbol). while the [
// is meaningful and should be shown to the user, . and -> are just parser
// design, but by no means added information for the user.. strip them off
static const char *SkipLeadingExpressionPathSeparators(const char *expression) {
if (!expression || !expression[0])
return expression;
if (expression[0] == '.')
return expression + 1;
if (expression[0] == '-' && expression[1] == '>')
return expression + 2;
return expression;
}
ValueObjectSP
ValueObject::GetSyntheticExpressionPathChild(const char *expression,
bool can_create) {
ValueObjectSP synthetic_child_sp;
ConstString name_const_string(expression);
// 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(name_const_string);
if (!synthetic_child_sp) {
// We haven't made a synthetic array member for expression yet, so lets
// make one and cache it for any future reference.
synthetic_child_sp = GetValueForExpressionPath(
expression, nullptr, nullptr,
GetValueForExpressionPathOptions().SetSyntheticChildrenTraversal(
GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
None));
// Cache the value if we got one back...
if (synthetic_child_sp.get()) {
// FIXME: this causes a "real" child to end up with its name changed to
// the contents of expression
AddSyntheticChild(name_const_string, synthetic_child_sp.get());
synthetic_child_sp->SetName(
ConstString(SkipLeadingExpressionPathSeparators(expression)));
}
}
return synthetic_child_sp;
}
void ValueObject::CalculateSyntheticValue(bool use_synthetic) {
if (!use_synthetic)
return;
TargetSP target_sp(GetTargetSP());
if (target_sp && !target_sp->GetEnableSyntheticValue()) {
m_synthetic_value = nullptr;
return;
}
lldb::SyntheticChildrenSP current_synth_sp(m_synthetic_children_sp);
if (!UpdateFormatsIfNeeded() && m_synthetic_value)
return;
if (m_synthetic_children_sp.get() == nullptr)
return;
if (current_synth_sp == m_synthetic_children_sp && m_synthetic_value)
return;
m_synthetic_value = new ValueObjectSynthetic(*this, m_synthetic_children_sp);
}
void ValueObject::CalculateDynamicValue(DynamicValueType use_dynamic) {
if (use_dynamic == eNoDynamicValues)
return;
if (!m_dynamic_value && !IsDynamic()) {
ExecutionContext exe_ctx(GetExecutionContextRef());
Process *process = exe_ctx.GetProcessPtr();
if (process && process->IsPossibleDynamicValue(*this)) {
ClearDynamicTypeInformation();
m_dynamic_value = new ValueObjectDynamicValue(*this, use_dynamic);
}
}
}
ValueObjectSP ValueObject::GetDynamicValue(DynamicValueType use_dynamic) {
if (use_dynamic == eNoDynamicValues)
return ValueObjectSP();
if (!IsDynamic() && m_dynamic_value == nullptr) {
CalculateDynamicValue(use_dynamic);
}
if (m_dynamic_value)
return m_dynamic_value->GetSP();
else
return ValueObjectSP();
}
ValueObjectSP ValueObject::GetStaticValue() { return GetSP(); }
lldb::ValueObjectSP ValueObject::GetNonSyntheticValue() { return GetSP(); }
ValueObjectSP ValueObject::GetSyntheticValue(bool use_synthetic) {
if (!use_synthetic)
return ValueObjectSP();
CalculateSyntheticValue(use_synthetic);
if (m_synthetic_value)
return m_synthetic_value->GetSP();
else
return ValueObjectSP();
}
bool ValueObject::HasSyntheticValue() {
UpdateFormatsIfNeeded();
if (m_synthetic_children_sp.get() == nullptr)
return false;
CalculateSyntheticValue(true);
return m_synthetic_value != nullptr;
}
bool ValueObject::GetBaseClassPath(Stream &s) {
if (IsBaseClass()) {
bool parent_had_base_class =
GetParent() && GetParent()->GetBaseClassPath(s);
CompilerType compiler_type = GetCompilerType();
llvm::Optional<std::string> cxx_class_name =
ClangASTContext::GetCXXClassName(compiler_type);
if (cxx_class_name) {
if (parent_had_base_class)
s.PutCString("::");
s.PutCString(cxx_class_name.getValue());
}
return parent_had_base_class || cxx_class_name;
}
return false;
}
ValueObject *ValueObject::GetNonBaseClassParent() {
if (GetParent()) {
if (GetParent()->IsBaseClass())
return GetParent()->GetNonBaseClassParent();
else
return GetParent();
}
return nullptr;
}
bool ValueObject::IsBaseClass(uint32_t &depth) {
if (!IsBaseClass()) {
depth = 0;
return false;
}
if (GetParent()) {
GetParent()->IsBaseClass(depth);
depth = depth + 1;
return true;
}
// TODO: a base of no parent? weird..
depth = 1;
return true;
}
void ValueObject::GetExpressionPath(Stream &s, bool qualify_cxx_base_classes,
GetExpressionPathFormat epformat) {
// synthetic children do not actually "exist" as part of the hierarchy, and
// sometimes they are consed up in ways that don't make sense from an
// underlying language/API standpoint. So, use a special code path here to
// return something that can hopefully be used in expression
if (m_is_synthetic_children_generated) {
UpdateValueIfNeeded();
if (m_value.GetValueType() == Value::eValueTypeLoadAddress) {
if (IsPointerOrReferenceType()) {
s.Printf("((%s)0x%" PRIx64 ")", GetTypeName().AsCString("void"),
GetValueAsUnsigned(0));
return;
} else {
uint64_t load_addr =
m_value.GetScalar().ULongLong(LLDB_INVALID_ADDRESS);
if (load_addr != LLDB_INVALID_ADDRESS) {
s.Printf("(*( (%s *)0x%" PRIx64 "))", GetTypeName().AsCString("void"),
load_addr);
return;
}
}
}
if (CanProvideValue()) {
s.Printf("((%s)%s)", GetTypeName().AsCString("void"),
GetValueAsCString());
return;
}
return;
}
const bool is_deref_of_parent = IsDereferenceOfParent();
if (is_deref_of_parent &&
epformat == eGetExpressionPathFormatDereferencePointers) {
// this is the original format of GetExpressionPath() producing code like
// *(a_ptr).memberName, which is entirely fine, until you put this into
// StackFrame::GetValueForVariableExpressionPath() which prefers to see
// a_ptr->memberName. the eHonorPointers mode is meant to produce strings
// in this latter format
s.PutCString("*(");
}
ValueObject *parent = GetParent();
if (parent)
parent->GetExpressionPath(s, qualify_cxx_base_classes, epformat);
// if we are a deref_of_parent just because we are synthetic array members
// made up to allow ptr[%d] syntax to work in variable printing, then add our
// name ([%d]) to the expression path
if (m_is_array_item_for_pointer &&
epformat == eGetExpressionPathFormatHonorPointers)
s.PutCString(m_name.AsCString());
if (!IsBaseClass()) {
if (!is_deref_of_parent) {
ValueObject *non_base_class_parent = GetNonBaseClassParent();
if (non_base_class_parent &&
!non_base_class_parent->GetName().IsEmpty()) {
CompilerType non_base_class_parent_compiler_type =
non_base_class_parent->GetCompilerType();
if (non_base_class_parent_compiler_type) {
if (parent && parent->IsDereferenceOfParent() &&
epformat == eGetExpressionPathFormatHonorPointers) {
s.PutCString("->");
} else {
const uint32_t non_base_class_parent_type_info =
non_base_class_parent_compiler_type.GetTypeInfo();
if (non_base_class_parent_type_info & eTypeIsPointer) {
s.PutCString("->");
} else if ((non_base_class_parent_type_info & eTypeHasChildren) &&
!(non_base_class_parent_type_info & eTypeIsArray)) {
s.PutChar('.');
}
}
}
}
const char *name = GetName().GetCString();
if (name) {
if (qualify_cxx_base_classes) {
if (GetBaseClassPath(s))
s.PutCString("::");
}
s.PutCString(name);
}
}
}
if (is_deref_of_parent &&
epformat == eGetExpressionPathFormatDereferencePointers) {
s.PutChar(')');
}
}
ValueObjectSP ValueObject::GetValueForExpressionPath(
llvm::StringRef expression, ExpressionPathScanEndReason *reason_to_stop,
ExpressionPathEndResultType *final_value_type,
const GetValueForExpressionPathOptions &options,
ExpressionPathAftermath *final_task_on_target) {
ExpressionPathScanEndReason dummy_reason_to_stop =
ValueObject::eExpressionPathScanEndReasonUnknown;
ExpressionPathEndResultType dummy_final_value_type =
ValueObject::eExpressionPathEndResultTypeInvalid;
ExpressionPathAftermath dummy_final_task_on_target =
ValueObject::eExpressionPathAftermathNothing;
ValueObjectSP ret_val = GetValueForExpressionPath_Impl(
expression, reason_to_stop ? reason_to_stop : &dummy_reason_to_stop,
final_value_type ? final_value_type : &dummy_final_value_type, options,
final_task_on_target ? final_task_on_target
: &dummy_final_task_on_target);
if (!final_task_on_target ||
*final_task_on_target == ValueObject::eExpressionPathAftermathNothing)
return ret_val;
if (ret_val.get() &&
((final_value_type ? *final_value_type : dummy_final_value_type) ==
eExpressionPathEndResultTypePlain)) // I can only deref and takeaddress
// of plain objects
{
if ((final_task_on_target ? *final_task_on_target
: dummy_final_task_on_target) ==
ValueObject::eExpressionPathAftermathDereference) {
Status error;
ValueObjectSP final_value = ret_val->Dereference(error);
if (error.Fail() || !final_value.get()) {
if (reason_to_stop)
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonDereferencingFailed;
if (final_value_type)
*final_value_type = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
} else {
if (final_task_on_target)
*final_task_on_target = ValueObject::eExpressionPathAftermathNothing;
return final_value;
}
}
if (*final_task_on_target ==
ValueObject::eExpressionPathAftermathTakeAddress) {
Status error;
ValueObjectSP final_value = ret_val->AddressOf(error);
if (error.Fail() || !final_value.get()) {
if (reason_to_stop)
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonTakingAddressFailed;
if (final_value_type)
*final_value_type = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
} else {
if (final_task_on_target)
*final_task_on_target = ValueObject::eExpressionPathAftermathNothing;
return final_value;
}
}
}
return ret_val; // final_task_on_target will still have its original value, so
// you know I did not do it
}
ValueObjectSP ValueObject::GetValueForExpressionPath_Impl(
llvm::StringRef expression, ExpressionPathScanEndReason *reason_to_stop,
ExpressionPathEndResultType *final_result,
const GetValueForExpressionPathOptions &options,
ExpressionPathAftermath *what_next) {
ValueObjectSP root = GetSP();
if (!root)
return nullptr;
llvm::StringRef remainder = expression;
while (true) {
llvm::StringRef temp_expression = remainder;
CompilerType root_compiler_type = root->GetCompilerType();
CompilerType pointee_compiler_type;
Flags pointee_compiler_type_info;
Flags root_compiler_type_info(
root_compiler_type.GetTypeInfo(&pointee_compiler_type));
if (pointee_compiler_type)
pointee_compiler_type_info.Reset(pointee_compiler_type.GetTypeInfo());
if (temp_expression.empty()) {
*reason_to_stop = ValueObject::eExpressionPathScanEndReasonEndOfString;
return root;
}
switch (temp_expression.front()) {
case '-': {
temp_expression = temp_expression.drop_front();
if (options.m_check_dot_vs_arrow_syntax &&
root_compiler_type_info.Test(eTypeIsPointer)) // if you are trying to
// use -> on a
// non-pointer and I
// must catch the error
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonArrowInsteadOfDot;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
}
if (root_compiler_type_info.Test(eTypeIsObjC) && // if yo are trying to
// extract an ObjC IVar
// when this is forbidden
root_compiler_type_info.Test(eTypeIsPointer) &&
options.m_no_fragile_ivar) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonFragileIVarNotAllowed;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
}
if (!temp_expression.startswith(">")) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonUnexpectedSymbol;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
}
}
LLVM_FALLTHROUGH;
case '.': // or fallthrough from ->
{
if (options.m_check_dot_vs_arrow_syntax &&
temp_expression.front() == '.' &&
root_compiler_type_info.Test(eTypeIsPointer)) // if you are trying to
// use . on a pointer
// and I must catch the
// error
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonDotInsteadOfArrow;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
temp_expression = temp_expression.drop_front(); // skip . or >
size_t next_sep_pos = temp_expression.find_first_of("-.[", 1);
ConstString child_name;
if (next_sep_pos == llvm::StringRef::npos) // if no other separator just
// expand this last layer
{
child_name.SetString(temp_expression);
ValueObjectSP child_valobj_sp =
root->GetChildMemberWithName(child_name, true);
if (child_valobj_sp.get()) // we know we are done, so just return
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonEndOfString;
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
return child_valobj_sp;
} else {
switch (options.m_synthetic_children_traversal) {
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
None:
break;
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
FromSynthetic:
if (root->IsSynthetic()) {
child_valobj_sp = root->GetNonSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
}
break;
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
ToSynthetic:
if (!root->IsSynthetic()) {
child_valobj_sp = root->GetSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
}
break;
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
Both:
if (root->IsSynthetic()) {
child_valobj_sp = root->GetNonSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
} else {
child_valobj_sp = root->GetSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
}
break;
}
}
// if we are here and options.m_no_synthetic_children is true,
// child_valobj_sp is going to be a NULL SP, so we hit the "else"
// branch, and return an error
if (child_valobj_sp.get()) // if it worked, just return
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonEndOfString;
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
return child_valobj_sp;
} else {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
} else // other layers do expand
{
llvm::StringRef next_separator = temp_expression.substr(next_sep_pos);
child_name.SetString(temp_expression.slice(0, next_sep_pos));
ValueObjectSP child_valobj_sp =
root->GetChildMemberWithName(child_name, true);
if (child_valobj_sp.get()) // store the new root and move on
{
root = child_valobj_sp;
remainder = next_separator;
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
continue;
} else {
switch (options.m_synthetic_children_traversal) {
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
None:
break;
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
FromSynthetic:
if (root->IsSynthetic()) {
child_valobj_sp = root->GetNonSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
}
break;
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
ToSynthetic:
if (!root->IsSynthetic()) {
child_valobj_sp = root->GetSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
}
break;
case GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
Both:
if (root->IsSynthetic()) {
child_valobj_sp = root->GetNonSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
} else {
child_valobj_sp = root->GetSyntheticValue();
if (child_valobj_sp.get())
child_valobj_sp =
child_valobj_sp->GetChildMemberWithName(child_name, true);
}
break;
}
}
// if we are here and options.m_no_synthetic_children is true,
// child_valobj_sp is going to be a NULL SP, so we hit the "else"
// branch, and return an error
if (child_valobj_sp.get()) // if it worked, move on
{
root = child_valobj_sp;
remainder = next_separator;
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
continue;
} else {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
}
break;
}
case '[': {
if (!root_compiler_type_info.Test(eTypeIsArray) &&
!root_compiler_type_info.Test(eTypeIsPointer) &&
!root_compiler_type_info.Test(
eTypeIsVector)) // if this is not a T[] nor a T*
{
if (!root_compiler_type_info.Test(
eTypeIsScalar)) // if this is not even a scalar...
{
if (options.m_synthetic_children_traversal ==
GetValueForExpressionPathOptions::SyntheticChildrenTraversal::
None) // ...only chance left is synthetic
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonRangeOperatorInvalid;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
}
} else if (!options.m_allow_bitfields_syntax) // if this is a scalar,
// check that we can
// expand bitfields
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonRangeOperatorNotAllowed;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
}
}
if (temp_expression[1] ==
']') // if this is an unbounded range it only works for arrays
{
if (!root_compiler_type_info.Test(eTypeIsArray)) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonEmptyRangeNotAllowed;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
} else // even if something follows, we cannot expand unbounded ranges,
// just let the caller do it
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonArrayRangeOperatorMet;
*final_result =
ValueObject::eExpressionPathEndResultTypeUnboundedRange;
return root;
}
}
size_t close_bracket_position = temp_expression.find(']', 1);
if (close_bracket_position ==
llvm::StringRef::npos) // if there is no ], this is a syntax error
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonUnexpectedSymbol;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
llvm::StringRef bracket_expr =
temp_expression.slice(1, close_bracket_position);
// If this was an empty expression it would have been caught by the if
// above.
assert(!bracket_expr.empty());
if (!bracket_expr.contains('-')) {
// if no separator, this is of the form [N]. Note that this cannot be
// an unbounded range of the form [], because that case was handled
// above with an unconditional return.
unsigned long index = 0;
if (bracket_expr.getAsInteger(0, index)) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonUnexpectedSymbol;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
// from here on we do have a valid index
if (root_compiler_type_info.Test(eTypeIsArray)) {
ValueObjectSP child_valobj_sp = root->GetChildAtIndex(index, true);
if (!child_valobj_sp)
child_valobj_sp = root->GetSyntheticArrayMember(index, true);
if (!child_valobj_sp)
if (root->HasSyntheticValue() &&
root->GetSyntheticValue()->GetNumChildren() > index)
child_valobj_sp =
root->GetSyntheticValue()->GetChildAtIndex(index, true);
if (child_valobj_sp) {
root = child_valobj_sp;
remainder =
temp_expression.substr(close_bracket_position + 1); // skip ]
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
continue;
} else {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
} else if (root_compiler_type_info.Test(eTypeIsPointer)) {
if (*what_next ==
ValueObject::
eExpressionPathAftermathDereference && // if this is a
// ptr-to-scalar, I
// am accessing it
// by index and I
// would have
// deref'ed anyway,
// then do it now
// and use this as
// a bitfield
pointee_compiler_type_info.Test(eTypeIsScalar)) {
Status error;
root = root->Dereference(error);
if (error.Fail() || !root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonDereferencingFailed;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
} else {
*what_next = eExpressionPathAftermathNothing;
continue;
}
} else {
if (root->GetCompilerType().GetMinimumLanguage() ==
eLanguageTypeObjC &&
pointee_compiler_type_info.AllClear(eTypeIsPointer) &&
root->HasSyntheticValue() &&
(options.m_synthetic_children_traversal ==
GetValueForExpressionPathOptions::
SyntheticChildrenTraversal::ToSynthetic ||
options.m_synthetic_children_traversal ==
GetValueForExpressionPathOptions::
SyntheticChildrenTraversal::Both)) {
root = root->GetSyntheticValue()->GetChildAtIndex(index, true);
} else
root = root->GetSyntheticArrayMember(index, true);
if (!root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
} else {
remainder =
temp_expression.substr(close_bracket_position + 1); // skip ]
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
continue;
}
}
} else if (root_compiler_type_info.Test(eTypeIsScalar)) {
root = root->GetSyntheticBitFieldChild(index, index, true);
if (!root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
} else // we do not know how to expand members of bitfields, so we
// just return and let the caller do any further processing
{
*reason_to_stop = ValueObject::
eExpressionPathScanEndReasonBitfieldRangeOperatorMet;
*final_result = ValueObject::eExpressionPathEndResultTypeBitfield;
return root;
}
} else if (root_compiler_type_info.Test(eTypeIsVector)) {
root = root->GetChildAtIndex(index, true);
if (!root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return ValueObjectSP();
} else {
remainder =
temp_expression.substr(close_bracket_position + 1); // skip ]
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
continue;
}
} else if (options.m_synthetic_children_traversal ==
GetValueForExpressionPathOptions::
SyntheticChildrenTraversal::ToSynthetic ||
options.m_synthetic_children_traversal ==
GetValueForExpressionPathOptions::
SyntheticChildrenTraversal::Both) {
if (root->HasSyntheticValue())
root = root->GetSyntheticValue();
else if (!root->IsSynthetic()) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonSyntheticValueMissing;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
// if we are here, then root itself is a synthetic VO.. should be
// good to go
if (!root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonSyntheticValueMissing;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
root = root->GetChildAtIndex(index, true);
if (!root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
} else {
remainder =
temp_expression.substr(close_bracket_position + 1); // skip ]
*final_result = ValueObject::eExpressionPathEndResultTypePlain;
continue;
}
} else {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
} else {
// we have a low and a high index
llvm::StringRef sleft, sright;
unsigned long low_index, high_index;
std::tie(sleft, sright) = bracket_expr.split('-');
if (sleft.getAsInteger(0, low_index) ||
sright.getAsInteger(0, high_index)) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonUnexpectedSymbol;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
if (low_index > high_index) // swap indices if required
std::swap(low_index, high_index);
if (root_compiler_type_info.Test(
eTypeIsScalar)) // expansion only works for scalars
{
root = root->GetSyntheticBitFieldChild(low_index, high_index, true);
if (!root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonNoSuchChild;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
} else {
*reason_to_stop = ValueObject::
eExpressionPathScanEndReasonBitfieldRangeOperatorMet;
*final_result = ValueObject::eExpressionPathEndResultTypeBitfield;
return root;
}
} else if (root_compiler_type_info.Test(
eTypeIsPointer) && // if this is a ptr-to-scalar, I am
// accessing it by index and I would
// have deref'ed anyway, then do it
// now and use this as a bitfield
*what_next ==
ValueObject::eExpressionPathAftermathDereference &&
pointee_compiler_type_info.Test(eTypeIsScalar)) {
Status error;
root = root->Dereference(error);
if (error.Fail() || !root) {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonDereferencingFailed;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
} else {
*what_next = ValueObject::eExpressionPathAftermathNothing;
continue;
}
} else {
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonArrayRangeOperatorMet;
*final_result = ValueObject::eExpressionPathEndResultTypeBoundedRange;
return root;
}
}
break;
}
default: // some non-separator is in the way
{
*reason_to_stop =
ValueObject::eExpressionPathScanEndReasonUnexpectedSymbol;
*final_result = ValueObject::eExpressionPathEndResultTypeInvalid;
return nullptr;
}
}
}
}
void ValueObject::LogValueObject(Log *log) {
if (log)
return LogValueObject(log, DumpValueObjectOptions(*this));
}
void ValueObject::LogValueObject(Log *log,
const DumpValueObjectOptions &options) {
if (log) {
StreamString s;
Dump(s, options);
if (s.GetSize())
log->PutCString(s.GetData());
}
}
void ValueObject::Dump(Stream &s) { Dump(s, DumpValueObjectOptions(*this)); }
void ValueObject::Dump(Stream &s, const DumpValueObjectOptions &options) {
ValueObjectPrinter printer(this, &s, options);
printer.PrintValueObject();
}
ValueObjectSP ValueObject::CreateConstantValue(ConstString name) {
ValueObjectSP valobj_sp;
if (UpdateValueIfNeeded(false) && m_error.Success()) {
ExecutionContext exe_ctx(GetExecutionContextRef());
DataExtractor data;
data.SetByteOrder(m_data.GetByteOrder());
data.SetAddressByteSize(m_data.GetAddressByteSize());
if (IsBitfield()) {
Value v(Scalar(GetValueAsUnsigned(UINT64_MAX)));
m_error = v.GetValueAsData(&exe_ctx, data, GetModule().get());
} else
m_error = m_value.GetValueAsData(&exe_ctx, data, GetModule().get());
valobj_sp = ValueObjectConstResult::Create(
exe_ctx.GetBestExecutionContextScope(), GetCompilerType(), name, data,
GetAddressOf());
}
if (!valobj_sp) {
ExecutionContext exe_ctx(GetExecutionContextRef());
valobj_sp = ValueObjectConstResult::Create(
exe_ctx.GetBestExecutionContextScope(), m_error);
}
return valobj_sp;
}
ValueObjectSP ValueObject::GetQualifiedRepresentationIfAvailable(
lldb::DynamicValueType dynValue, bool synthValue) {
ValueObjectSP result_sp(GetSP());
switch (dynValue) {
case lldb::eDynamicCanRunTarget:
case lldb::eDynamicDontRunTarget: {
if (!result_sp->IsDynamic()) {
if (result_sp->GetDynamicValue(dynValue))
result_sp = result_sp->GetDynamicValue(dynValue);
}
} break;
case lldb::eNoDynamicValues: {
if (result_sp->IsDynamic()) {
if (result_sp->GetStaticValue())
result_sp = result_sp->GetStaticValue();
}
} break;
}
if (synthValue) {
if (!result_sp->IsSynthetic()) {
if (result_sp->GetSyntheticValue())
result_sp = result_sp->GetSyntheticValue();
}
} else {
if (result_sp->IsSynthetic()) {
if (result_sp->GetNonSyntheticValue())
result_sp = result_sp->GetNonSyntheticValue();
}
}
return result_sp;
}
ValueObjectSP ValueObject::Dereference(Status &error) {
if (m_deref_valobj)
return m_deref_valobj->GetSP();
const bool is_pointer_or_reference_type = IsPointerOrReferenceType();
if (is_pointer_or_reference_type) {
bool omit_empty_base_classes = true;
bool ignore_array_bounds = false;
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;
bool child_is_deref_of_parent = false;
const bool transparent_pointers = false;
CompilerType compiler_type = GetCompilerType();
CompilerType child_compiler_type;
uint64_t language_flags;
ExecutionContext exe_ctx(GetExecutionContextRef());
child_compiler_type = compiler_type.GetChildCompilerTypeAtIndex(
&exe_ctx, 0, transparent_pointers, omit_empty_base_classes,
ignore_array_bounds, child_name_str, child_byte_size, child_byte_offset,
child_bitfield_bit_size, child_bitfield_bit_offset, child_is_base_class,
child_is_deref_of_parent, this, language_flags);
if (child_compiler_type && child_byte_size) {
ConstString child_name;
if (!child_name_str.empty())
child_name.SetCString(child_name_str.c_str());
m_deref_valobj = new ValueObjectChild(
*this, child_compiler_type, child_name, child_byte_size,
child_byte_offset, child_bitfield_bit_size, child_bitfield_bit_offset,
child_is_base_class, child_is_deref_of_parent, eAddressTypeInvalid,
language_flags);
}
} else if (HasSyntheticValue()) {
m_deref_valobj =
GetSyntheticValue()
->GetChildMemberWithName(ConstString("$$dereference$$"), true)
.get();
}
if (m_deref_valobj) {
error.Clear();
return m_deref_valobj->GetSP();
} else {
StreamString strm;
GetExpressionPath(strm, true);
if (is_pointer_or_reference_type)
error.SetErrorStringWithFormat("dereference failed: (%s) %s",
GetTypeName().AsCString("<invalid type>"),
strm.GetData());
else
error.SetErrorStringWithFormat("not a pointer or reference type: (%s) %s",
GetTypeName().AsCString("<invalid type>"),
strm.GetData());
return ValueObjectSP();
}
}
ValueObjectSP ValueObject::AddressOf(Status &error) {
if (m_addr_of_valobj_sp)
return m_addr_of_valobj_sp;
AddressType address_type = eAddressTypeInvalid;
const bool scalar_is_load_address = false;
addr_t addr = GetAddressOf(scalar_is_load_address, &address_type);
error.Clear();
if (addr != LLDB_INVALID_ADDRESS && address_type != eAddressTypeHost) {
switch (address_type) {
case eAddressTypeInvalid: {
StreamString expr_path_strm;
GetExpressionPath(expr_path_strm, true);
error.SetErrorStringWithFormat("'%s' is not in memory",
expr_path_strm.GetData());
} break;
case eAddressTypeFile:
case eAddressTypeLoad: {
CompilerType compiler_type = GetCompilerType();
if (compiler_type) {
std::string name(1, '&');
name.append(m_name.AsCString(""));
ExecutionContext exe_ctx(GetExecutionContextRef());
m_addr_of_valobj_sp = ValueObjectConstResult::Create(
exe_ctx.GetBestExecutionContextScope(),
compiler_type.GetPointerType(), ConstString(name.c_str()), addr,
eAddressTypeInvalid, m_data.GetAddressByteSize());
}
} break;
default:
break;
}
} else {
StreamString expr_path_strm;
GetExpressionPath(expr_path_strm, true);
error.SetErrorStringWithFormat("'%s' doesn't have a valid address",
expr_path_strm.GetData());
}
return m_addr_of_valobj_sp;
}
ValueObjectSP ValueObject::Cast(const CompilerType &compiler_type) {
return ValueObjectCast::Create(*this, GetName(), compiler_type);
}
lldb::ValueObjectSP ValueObject::Clone(ConstString new_name) {
return ValueObjectCast::Create(*this, new_name, GetCompilerType());
}
ValueObjectSP ValueObject::CastPointerType(const char *name,
CompilerType &compiler_type) {
ValueObjectSP valobj_sp;
AddressType address_type;
addr_t ptr_value = GetPointerValue(&address_type);
if (ptr_value != LLDB_INVALID_ADDRESS) {
Address ptr_addr(ptr_value);
ExecutionContext exe_ctx(GetExecutionContextRef());
valobj_sp = ValueObjectMemory::Create(
exe_ctx.GetBestExecutionContextScope(), name, ptr_addr, compiler_type);
}
return valobj_sp;
}
ValueObjectSP ValueObject::CastPointerType(const char *name, TypeSP &type_sp) {
ValueObjectSP valobj_sp;
AddressType address_type;
addr_t ptr_value = GetPointerValue(&address_type);
if (ptr_value != LLDB_INVALID_ADDRESS) {
Address ptr_addr(ptr_value);
ExecutionContext exe_ctx(GetExecutionContextRef());
valobj_sp = ValueObjectMemory::Create(
exe_ctx.GetBestExecutionContextScope(), name, ptr_addr, type_sp);
}
return valobj_sp;
}
ValueObject::EvaluationPoint::EvaluationPoint()
: m_mod_id(), m_exe_ctx_ref(), m_needs_update(true) {}
ValueObject::EvaluationPoint::EvaluationPoint(ExecutionContextScope *exe_scope,
bool use_selected)
: m_mod_id(), m_exe_ctx_ref(), m_needs_update(true) {
ExecutionContext exe_ctx(exe_scope);
TargetSP target_sp(exe_ctx.GetTargetSP());
if (target_sp) {
m_exe_ctx_ref.SetTargetSP(target_sp);
ProcessSP process_sp(exe_ctx.GetProcessSP());
if (!process_sp)
process_sp = target_sp->GetProcessSP();
if (process_sp) {
m_mod_id = process_sp->GetModID();
m_exe_ctx_ref.SetProcessSP(process_sp);
ThreadSP thread_sp(exe_ctx.GetThreadSP());
if (!thread_sp) {
if (use_selected)
thread_sp = process_sp->GetThreadList().GetSelectedThread();
}
if (thread_sp) {
m_exe_ctx_ref.SetThreadSP(thread_sp);
StackFrameSP frame_sp(exe_ctx.GetFrameSP());
if (!frame_sp) {
if (use_selected)
frame_sp = thread_sp->GetSelectedFrame();
}
if (frame_sp)
m_exe_ctx_ref.SetFrameSP(frame_sp);
}
}
}
}
ValueObject::EvaluationPoint::EvaluationPoint(
const ValueObject::EvaluationPoint &rhs)
: m_mod_id(), m_exe_ctx_ref(rhs.m_exe_ctx_ref), m_needs_update(true) {}
ValueObject::EvaluationPoint::~EvaluationPoint() {}
// This function checks the EvaluationPoint against the current process state.
// If the current state matches the evaluation point, or the evaluation point
// is already invalid, then we return false, meaning "no change". If the
// current state is different, we update our state, and return true meaning
// "yes, change". If we did see a change, we also set m_needs_update to true,
// so future calls to NeedsUpdate will return true. exe_scope will be set to
// the current execution context scope.
bool ValueObject::EvaluationPoint::SyncWithProcessState(
bool accept_invalid_exe_ctx) {
// Start with the target, if it is NULL, then we're obviously not going to
// get any further:
const bool thread_and_frame_only_if_stopped = true;
ExecutionContext exe_ctx(
m_exe_ctx_ref.Lock(thread_and_frame_only_if_stopped));
if (exe_ctx.GetTargetPtr() == nullptr)
return false;
// If we don't have a process nothing can change.
Process *process = exe_ctx.GetProcessPtr();
if (process == nullptr)
return false;
// If our stop id is the current stop ID, nothing has changed:
ProcessModID current_mod_id = process->GetModID();
// If the current stop id is 0, either we haven't run yet, or the process
// state has been cleared. In either case, we aren't going to be able to sync
// with the process state.
if (current_mod_id.GetStopID() == 0)
return false;
bool changed = false;
const bool was_valid = m_mod_id.IsValid();
if (was_valid) {
if (m_mod_id == current_mod_id) {
// Everything is already up to date in this object, no need to update the
// execution context scope.
changed = false;
} else {
m_mod_id = current_mod_id;
m_needs_update = true;
changed = true;
}
}
// Now re-look up the thread and frame in case the underlying objects have
// gone away & been recreated. That way we'll be sure to return a valid
// exe_scope. If we used to have a thread or a frame but can't find it
// anymore, then mark ourselves as invalid.
if (!accept_invalid_exe_ctx) {
if (m_exe_ctx_ref.HasThreadRef()) {
ThreadSP thread_sp(m_exe_ctx_ref.GetThreadSP());
if (thread_sp) {
if (m_exe_ctx_ref.HasFrameRef()) {
StackFrameSP frame_sp(m_exe_ctx_ref.GetFrameSP());
if (!frame_sp) {
// We used to have a frame, but now it is gone
SetInvalid();
changed = was_valid;
}
}
} else {
// We used to have a thread, but now it is gone
SetInvalid();
changed = was_valid;
}
}
}
return changed;
}
void ValueObject::EvaluationPoint::SetUpdated() {
ProcessSP process_sp(m_exe_ctx_ref.GetProcessSP());
if (process_sp)
m_mod_id = process_sp->GetModID();
m_needs_update = false;
}
void ValueObject::ClearUserVisibleData(uint32_t clear_mask) {
if ((clear_mask & eClearUserVisibleDataItemsValue) ==
eClearUserVisibleDataItemsValue)
m_value_str.clear();
if ((clear_mask & eClearUserVisibleDataItemsLocation) ==
eClearUserVisibleDataItemsLocation)
m_location_str.clear();
if ((clear_mask & eClearUserVisibleDataItemsSummary) ==
eClearUserVisibleDataItemsSummary)
m_summary_str.clear();
if ((clear_mask & eClearUserVisibleDataItemsDescription) ==
eClearUserVisibleDataItemsDescription)
m_object_desc_str.clear();
if ((clear_mask & eClearUserVisibleDataItemsSyntheticChildren) ==
eClearUserVisibleDataItemsSyntheticChildren) {
if (m_synthetic_value)
m_synthetic_value = nullptr;
}
if ((clear_mask & eClearUserVisibleDataItemsValidator) ==
eClearUserVisibleDataItemsValidator)
m_validation_result.reset();
}
SymbolContextScope *ValueObject::GetSymbolContextScope() {
if (m_parent) {
if (!m_parent->IsPointerOrReferenceType())
return m_parent->GetSymbolContextScope();
}
return nullptr;
}
lldb::ValueObjectSP
ValueObject::CreateValueObjectFromExpression(llvm::StringRef name,
llvm::StringRef expression,
const ExecutionContext &exe_ctx) {
return CreateValueObjectFromExpression(name, expression, exe_ctx,
EvaluateExpressionOptions());
}
lldb::ValueObjectSP ValueObject::CreateValueObjectFromExpression(
llvm::StringRef name, llvm::StringRef expression,
const ExecutionContext &exe_ctx, const EvaluateExpressionOptions &options) {
lldb::ValueObjectSP retval_sp;
lldb::TargetSP target_sp(exe_ctx.GetTargetSP());
if (!target_sp)
return retval_sp;
if (expression.empty())
return retval_sp;
target_sp->EvaluateExpression(expression, exe_ctx.GetFrameSP().get(),
retval_sp, options);
if (retval_sp && !name.empty())
retval_sp->SetName(ConstString(name));
return retval_sp;
}
lldb::ValueObjectSP ValueObject::CreateValueObjectFromAddress(
llvm::StringRef name, uint64_t address, const ExecutionContext &exe_ctx,
CompilerType type) {
if (type) {
CompilerType pointer_type(type.GetPointerType());
if (pointer_type) {
lldb::DataBufferSP buffer(
new lldb_private::DataBufferHeap(&address, sizeof(lldb::addr_t)));
lldb::ValueObjectSP ptr_result_valobj_sp(ValueObjectConstResult::Create(
exe_ctx.GetBestExecutionContextScope(), pointer_type,
ConstString(name), buffer, exe_ctx.GetByteOrder(),
exe_ctx.GetAddressByteSize()));
if (ptr_result_valobj_sp) {
ptr_result_valobj_sp->GetValue().SetValueType(
Value::eValueTypeLoadAddress);
Status err;
ptr_result_valobj_sp = ptr_result_valobj_sp->Dereference(err);
if (ptr_result_valobj_sp && !name.empty())
ptr_result_valobj_sp->SetName(ConstString(name));
}
return ptr_result_valobj_sp;
}
}
return lldb::ValueObjectSP();
}
lldb::ValueObjectSP ValueObject::CreateValueObjectFromData(
llvm::StringRef name, const DataExtractor &data,
const ExecutionContext &exe_ctx, CompilerType type) {
lldb::ValueObjectSP new_value_sp;
new_value_sp = ValueObjectConstResult::Create(
exe_ctx.GetBestExecutionContextScope(), type, ConstString(name), data,
LLDB_INVALID_ADDRESS);
new_value_sp->SetAddressTypeOfChildren(eAddressTypeLoad);
if (new_value_sp && !name.empty())
new_value_sp->SetName(ConstString(name));
return new_value_sp;
}
ModuleSP ValueObject::GetModule() {
ValueObject *root(GetRoot());
if (root != this)
return root->GetModule();
return lldb::ModuleSP();
}
ValueObject *ValueObject::GetRoot() {
if (m_root)
return m_root;
return (m_root = FollowParentChain([](ValueObject *vo) -> bool {
return (vo->m_parent != nullptr);
}));
}
ValueObject *
ValueObject::FollowParentChain(std::function<bool(ValueObject *)> f) {
ValueObject *vo = this;
while (vo) {
if (!f(vo))
break;
vo = vo->m_parent;
}
return vo;
}
AddressType ValueObject::GetAddressTypeOfChildren() {
if (m_address_type_of_ptr_or_ref_children == eAddressTypeInvalid) {
ValueObject *root(GetRoot());
if (root != this)
return root->GetAddressTypeOfChildren();
}
return m_address_type_of_ptr_or_ref_children;
}
lldb::DynamicValueType ValueObject::GetDynamicValueType() {
ValueObject *with_dv_info = this;
while (with_dv_info) {
if (with_dv_info->HasDynamicValueTypeInfo())
return with_dv_info->GetDynamicValueTypeImpl();
with_dv_info = with_dv_info->m_parent;
}
return lldb::eNoDynamicValues;
}
lldb::Format ValueObject::GetFormat() const {
const ValueObject *with_fmt_info = this;
while (with_fmt_info) {
if (with_fmt_info->m_format != lldb::eFormatDefault)
return with_fmt_info->m_format;
with_fmt_info = with_fmt_info->m_parent;
}
return m_format;
}
lldb::LanguageType ValueObject::GetPreferredDisplayLanguage() {
lldb::LanguageType type = m_preferred_display_language;
if (m_preferred_display_language == lldb::eLanguageTypeUnknown) {
if (GetRoot()) {
if (GetRoot() == this) {
if (StackFrameSP frame_sp = GetFrameSP()) {
const SymbolContext &sc(
frame_sp->GetSymbolContext(eSymbolContextCompUnit));
if (CompileUnit *cu = sc.comp_unit)
type = cu->GetLanguage();
}
} else {
type = GetRoot()->GetPreferredDisplayLanguage();
}
}
}
return (m_preferred_display_language = type); // only compute it once
}
void ValueObject::SetPreferredDisplayLanguage(lldb::LanguageType lt) {
m_preferred_display_language = lt;
}
void ValueObject::SetPreferredDisplayLanguageIfNeeded(lldb::LanguageType lt) {
if (m_preferred_display_language == lldb::eLanguageTypeUnknown)
SetPreferredDisplayLanguage(lt);
}
bool ValueObject::CanProvideValue() {
// we need to support invalid types as providers of values because some bare-
// board debugging scenarios have no notion of types, but still manage to
// have raw numeric values for things like registers. sigh.
const CompilerType &type(GetCompilerType());
return (!type.IsValid()) || (0 != (type.GetTypeInfo() & eTypeHasValue));
}
bool ValueObject::IsChecksumEmpty() { return m_value_checksum.empty(); }
ValueObjectSP ValueObject::Persist() {
if (!UpdateValueIfNeeded())
return nullptr;
TargetSP target_sp(GetTargetSP());
if (!target_sp)
return nullptr;
PersistentExpressionState *persistent_state =
target_sp->GetPersistentExpressionStateForLanguage(
GetPreferredDisplayLanguage());
if (!persistent_state)
return nullptr;
auto prefix = persistent_state->GetPersistentVariablePrefix();
ConstString name =
persistent_state->GetNextPersistentVariableName(*target_sp, prefix);
ValueObjectSP const_result_sp =
ValueObjectConstResult::Create(target_sp.get(), GetValue(), name);
ExpressionVariableSP clang_var_sp =
persistent_state->CreatePersistentVariable(const_result_sp);
clang_var_sp->m_live_sp = clang_var_sp->m_frozen_sp;
clang_var_sp->m_flags |= ExpressionVariable::EVIsProgramReference;
return clang_var_sp->GetValueObject();
}
bool ValueObject::IsSyntheticChildrenGenerated() {
return m_is_synthetic_children_generated;
}
void ValueObject::SetSyntheticChildrenGenerated(bool b) {
m_is_synthetic_children_generated = b;
}
uint64_t ValueObject::GetLanguageFlags() { return m_language_flags; }
void ValueObject::SetLanguageFlags(uint64_t flags) { m_language_flags = flags; }
ValueObjectManager::ValueObjectManager(lldb::ValueObjectSP in_valobj_sp,
lldb::DynamicValueType use_dynamic,
bool use_synthetic) : m_root_valobj_sp(),
m_user_valobj_sp(), m_use_dynamic(use_dynamic), m_stop_id(UINT32_MAX),
m_use_synthetic(use_synthetic) {
if (!in_valobj_sp)
return;
// If the user passes in a value object that is dynamic or synthetic, then
// water it down to the static type.
m_root_valobj_sp = in_valobj_sp->GetQualifiedRepresentationIfAvailable(lldb::eNoDynamicValues, false);
}
bool ValueObjectManager::IsValid() const {
if (!m_root_valobj_sp)
return false;
lldb::TargetSP target_sp = GetTargetSP();
if (target_sp)
return target_sp->IsValid();
return false;
}
lldb::ValueObjectSP ValueObjectManager::GetSP() {
lldb::ProcessSP process_sp = GetProcessSP();
if (!process_sp)
return lldb::ValueObjectSP();
const uint32_t current_stop_id = process_sp->GetLastNaturalStopID();
if (current_stop_id == m_stop_id)
return m_user_valobj_sp;
m_stop_id = current_stop_id;
if (!m_root_valobj_sp) {
m_user_valobj_sp.reset();
return m_root_valobj_sp;
}
m_user_valobj_sp = m_root_valobj_sp;
if (m_use_dynamic != lldb::eNoDynamicValues) {
lldb::ValueObjectSP dynamic_sp = m_user_valobj_sp->GetDynamicValue(m_use_dynamic);
if (dynamic_sp)
m_user_valobj_sp = dynamic_sp;
}
if (m_use_synthetic) {
lldb::ValueObjectSP synthetic_sp = m_user_valobj_sp->GetSyntheticValue(m_use_synthetic);
if (synthetic_sp)
m_user_valobj_sp = synthetic_sp;
}
return m_user_valobj_sp;
}
void ValueObjectManager::SetUseDynamic(lldb::DynamicValueType use_dynamic) {
if (use_dynamic != m_use_dynamic) {
m_use_dynamic = use_dynamic;
m_user_valobj_sp.reset();
m_stop_id = UINT32_MAX;
}
}
void ValueObjectManager::SetUseSynthetic(bool use_synthetic) {
if (m_use_synthetic != use_synthetic) {
m_use_synthetic = use_synthetic;
m_user_valobj_sp.reset();
m_stop_id = UINT32_MAX;
}
}
lldb::TargetSP ValueObjectManager::GetTargetSP() const {
if (!m_root_valobj_sp)
return m_root_valobj_sp->GetTargetSP();
return lldb::TargetSP();
}
lldb::ProcessSP ValueObjectManager::GetProcessSP() const {
if (m_root_valobj_sp)
return m_root_valobj_sp->GetProcessSP();
return lldb::ProcessSP();
}
lldb::ThreadSP ValueObjectManager::GetThreadSP() const {
if (m_root_valobj_sp)
return m_root_valobj_sp->GetThreadSP();
return lldb::ThreadSP();
}
lldb::StackFrameSP ValueObjectManager::GetFrameSP() const {
if (m_root_valobj_sp)
return m_root_valobj_sp->GetFrameSP();
return lldb::StackFrameSP();
}
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