//===-- ValueObjectPrinter.cpp --------------------------------------------===// // // 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/DataFormatters/ValueObjectPrinter.h" #include "lldb/Core/ValueObject.h" #include "lldb/DataFormatters/DataVisualization.h" #include "lldb/Interpreter/CommandInterpreter.h" #include "lldb/Target/Language.h" #include "lldb/Target/Target.h" #include "lldb/Utility/Stream.h" #include "llvm/Support/MathExtras.h" #include using namespace lldb; using namespace lldb_private; ValueObjectPrinter::ValueObjectPrinter(ValueObject &valobj, Stream *s) : m_orig_valobj(valobj) { DumpValueObjectOptions options(valobj); Init(valobj, s, options, m_options.m_max_ptr_depth, 0, nullptr); } ValueObjectPrinter::ValueObjectPrinter(ValueObject &valobj, Stream *s, const DumpValueObjectOptions &options) : m_orig_valobj(valobj) { Init(valobj, s, options, m_options.m_max_ptr_depth, 0, nullptr); } ValueObjectPrinter::ValueObjectPrinter( ValueObject &valobj, Stream *s, const DumpValueObjectOptions &options, const DumpValueObjectOptions::PointerDepth &ptr_depth, uint32_t curr_depth, InstancePointersSetSP printed_instance_pointers) : m_orig_valobj(valobj) { Init(valobj, s, options, ptr_depth, curr_depth, printed_instance_pointers); } void ValueObjectPrinter::Init( ValueObject &valobj, Stream *s, const DumpValueObjectOptions &options, const DumpValueObjectOptions::PointerDepth &ptr_depth, uint32_t curr_depth, InstancePointersSetSP printed_instance_pointers) { m_cached_valobj = nullptr; m_stream = s; m_options = options; m_ptr_depth = ptr_depth; m_curr_depth = curr_depth; assert(m_stream && "cannot print to a NULL Stream"); m_should_print = eLazyBoolCalculate; m_is_nil = eLazyBoolCalculate; m_is_uninit = eLazyBoolCalculate; m_is_ptr = eLazyBoolCalculate; m_is_ref = eLazyBoolCalculate; m_is_aggregate = eLazyBoolCalculate; m_is_instance_ptr = eLazyBoolCalculate; m_summary_formatter = {nullptr, false}; m_value.assign(""); m_summary.assign(""); m_error.assign(""); m_val_summary_ok = false; m_printed_instance_pointers = printed_instance_pointers ? printed_instance_pointers : InstancePointersSetSP(new InstancePointersSet()); SetupMostSpecializedValue(); } llvm::Error ValueObjectPrinter::PrintValueObject() { // If the incoming ValueObject is in an error state, the best we're going to // get out of it is its type. But if we don't even have that, just print // the error and exit early. if (m_orig_valobj.GetError().Fail() && !m_orig_valobj.GetCompilerType().IsValid()) return m_orig_valobj.GetError().ToError(); if (ShouldPrintValueObject()) { PrintLocationIfNeeded(); m_stream->Indent(); PrintDecl(); } bool value_printed = false; bool summary_printed = false; m_val_summary_ok = PrintValueAndSummaryIfNeeded(value_printed, summary_printed); if (m_val_summary_ok) return PrintChildrenIfNeeded(value_printed, summary_printed); m_stream->EOL(); return llvm::Error::success(); } ValueObject &ValueObjectPrinter::GetMostSpecializedValue() { assert(m_cached_valobj && "ValueObjectPrinter must have a valid ValueObject"); return *m_cached_valobj; } void ValueObjectPrinter::SetupMostSpecializedValue() { bool update_success = m_orig_valobj.UpdateValueIfNeeded(true); // If we can't find anything better, we'll fall back on the original // ValueObject. m_cached_valobj = &m_orig_valobj; if (update_success) { if (m_orig_valobj.IsDynamic()) { if (m_options.m_use_dynamic == eNoDynamicValues) { ValueObject *static_value = m_orig_valobj.GetStaticValue().get(); if (static_value) m_cached_valobj = static_value; } } else { if (m_options.m_use_dynamic != eNoDynamicValues) { ValueObject *dynamic_value = m_orig_valobj.GetDynamicValue(m_options.m_use_dynamic).get(); if (dynamic_value) m_cached_valobj = dynamic_value; } } if (m_cached_valobj->IsSynthetic()) { if (!m_options.m_use_synthetic) { ValueObject *non_synthetic = m_cached_valobj->GetNonSyntheticValue().get(); if (non_synthetic) m_cached_valobj = non_synthetic; } } else { if (m_options.m_use_synthetic) { ValueObject *synthetic = m_cached_valobj->GetSyntheticValue().get(); if (synthetic) m_cached_valobj = synthetic; } } } m_compiler_type = m_cached_valobj->GetCompilerType(); m_type_flags = m_compiler_type.GetTypeInfo(); assert(m_cached_valobj && "SetupMostSpecialized value must compute a valid ValueObject"); } llvm::Expected ValueObjectPrinter::GetDescriptionForDisplay() { ValueObject &valobj = GetMostSpecializedValue(); llvm::Expected maybe_str = valobj.GetObjectDescription(); if (maybe_str) return maybe_str; const char *str = nullptr; if (!str) str = valobj.GetSummaryAsCString(); if (!str) str = valobj.GetValueAsCString(); if (!str) return maybe_str; llvm::consumeError(maybe_str.takeError()); return str; } const char *ValueObjectPrinter::GetRootNameForDisplay() { const char *root_valobj_name = m_options.m_root_valobj_name.empty() ? GetMostSpecializedValue().GetName().AsCString() : m_options.m_root_valobj_name.c_str(); return root_valobj_name ? root_valobj_name : ""; } bool ValueObjectPrinter::ShouldPrintValueObject() { if (m_should_print == eLazyBoolCalculate) m_should_print = (!m_options.m_flat_output || m_type_flags.Test(eTypeHasValue)) ? eLazyBoolYes : eLazyBoolNo; return m_should_print == eLazyBoolYes; } bool ValueObjectPrinter::IsNil() { if (m_is_nil == eLazyBoolCalculate) m_is_nil = GetMostSpecializedValue().IsNilReference() ? eLazyBoolYes : eLazyBoolNo; return m_is_nil == eLazyBoolYes; } bool ValueObjectPrinter::IsUninitialized() { if (m_is_uninit == eLazyBoolCalculate) m_is_uninit = GetMostSpecializedValue().IsUninitializedReference() ? eLazyBoolYes : eLazyBoolNo; return m_is_uninit == eLazyBoolYes; } bool ValueObjectPrinter::IsPtr() { if (m_is_ptr == eLazyBoolCalculate) m_is_ptr = m_type_flags.Test(eTypeIsPointer) ? eLazyBoolYes : eLazyBoolNo; return m_is_ptr == eLazyBoolYes; } bool ValueObjectPrinter::IsRef() { if (m_is_ref == eLazyBoolCalculate) m_is_ref = m_type_flags.Test(eTypeIsReference) ? eLazyBoolYes : eLazyBoolNo; return m_is_ref == eLazyBoolYes; } bool ValueObjectPrinter::IsAggregate() { if (m_is_aggregate == eLazyBoolCalculate) m_is_aggregate = m_type_flags.Test(eTypeHasChildren) ? eLazyBoolYes : eLazyBoolNo; return m_is_aggregate == eLazyBoolYes; } bool ValueObjectPrinter::IsInstancePointer() { // you need to do this check on the value's clang type ValueObject &valobj = GetMostSpecializedValue(); if (m_is_instance_ptr == eLazyBoolCalculate) m_is_instance_ptr = (valobj.GetValue().GetCompilerType().GetTypeInfo() & eTypeInstanceIsPointer) != 0 ? eLazyBoolYes : eLazyBoolNo; if ((eLazyBoolYes == m_is_instance_ptr) && valobj.IsBaseClass()) m_is_instance_ptr = eLazyBoolNo; return m_is_instance_ptr == eLazyBoolYes; } bool ValueObjectPrinter::PrintLocationIfNeeded() { if (m_options.m_show_location) { m_stream->Printf("%s: ", GetMostSpecializedValue().GetLocationAsCString()); return true; } return false; } void ValueObjectPrinter::PrintDecl() { bool show_type = true; // if we are at the root-level and been asked to hide the root's type, then // hide it if (m_curr_depth == 0 && m_options.m_hide_root_type) show_type = false; else // otherwise decide according to the usual rules (asked to show types - // always at the root level) show_type = m_options.m_show_types || (m_curr_depth == 0 && !m_options.m_flat_output); StreamString typeName; // Figure out which ValueObject we're acting on ValueObject &valobj = GetMostSpecializedValue(); // always show the type at the root level if it is invalid if (show_type) { // Some ValueObjects don't have types (like registers sets). Only print the // type if there is one to print ConstString type_name; if (m_compiler_type.IsValid()) { type_name = m_options.m_use_type_display_name ? valobj.GetDisplayTypeName() : valobj.GetQualifiedTypeName(); } else { // only show an invalid type name if the user explicitly triggered // show_type if (m_options.m_show_types) type_name = ConstString(""); } if (type_name) { std::string type_name_str(type_name.GetCString()); if (m_options.m_hide_pointer_value) { for (auto iter = type_name_str.find(" *"); iter != std::string::npos; iter = type_name_str.find(" *")) { type_name_str.erase(iter, 2); } } typeName << type_name_str.c_str(); } } StreamString varName; if (ShouldShowName()) { if (m_options.m_flat_output) valobj.GetExpressionPath(varName); else varName << GetRootNameForDisplay(); } bool decl_printed = false; if (!m_options.m_decl_printing_helper) { // if the user didn't give us a custom helper, pick one based upon the // language, either the one that this printer is bound to, or the preferred // one for the ValueObject lldb::LanguageType lang_type = (m_options.m_varformat_language == lldb::eLanguageTypeUnknown) ? valobj.GetPreferredDisplayLanguage() : m_options.m_varformat_language; if (Language *lang_plugin = Language::FindPlugin(lang_type)) { m_options.m_decl_printing_helper = lang_plugin->GetDeclPrintingHelper(); } } if (m_options.m_decl_printing_helper) { ConstString type_name_cstr(typeName.GetString()); ConstString var_name_cstr(varName.GetString()); DumpValueObjectOptions decl_print_options = m_options; // Pass printing helpers an option object that indicates whether the name // should be shown or hidden. decl_print_options.SetHideName(!ShouldShowName()); StreamString dest_stream; if (m_options.m_decl_printing_helper(type_name_cstr, var_name_cstr, decl_print_options, dest_stream)) { decl_printed = true; m_stream->PutCString(dest_stream.GetString()); } } // if the helper failed, or there is none, do a default thing if (!decl_printed) { if (!typeName.Empty()) m_stream->Printf("(%s) ", typeName.GetData()); if (!varName.Empty()) m_stream->Printf("%s =", varName.GetData()); else if (ShouldShowName()) m_stream->Printf(" ="); } } bool ValueObjectPrinter::CheckScopeIfNeeded() { if (m_options.m_scope_already_checked) return true; return GetMostSpecializedValue().IsInScope(); } TypeSummaryImpl *ValueObjectPrinter::GetSummaryFormatter(bool null_if_omitted) { if (!m_summary_formatter.second) { TypeSummaryImpl *entry = m_options.m_summary_sp ? m_options.m_summary_sp.get() : GetMostSpecializedValue().GetSummaryFormat().get(); if (m_options.m_omit_summary_depth > 0) entry = nullptr; m_summary_formatter.first = entry; m_summary_formatter.second = true; } if (m_options.m_omit_summary_depth > 0 && null_if_omitted) return nullptr; return m_summary_formatter.first; } static bool IsPointerValue(const CompilerType &type) { Flags type_flags(type.GetTypeInfo()); if (type_flags.AnySet(eTypeInstanceIsPointer | eTypeIsPointer)) return type_flags.AllClear(eTypeIsBuiltIn); return false; } void ValueObjectPrinter::GetValueSummaryError(std::string &value, std::string &summary, std::string &error) { lldb::Format format = m_options.m_format; ValueObject &valobj = GetMostSpecializedValue(); // if I am printing synthetized elements, apply the format to those elements // only if (m_options.m_pointer_as_array) valobj.GetValueAsCString(lldb::eFormatDefault, value); else if (format != eFormatDefault && format != valobj.GetFormat()) valobj.GetValueAsCString(format, value); else { const char *val_cstr = valobj.GetValueAsCString(); if (val_cstr) value.assign(val_cstr); } const char *err_cstr = valobj.GetError().AsCString(); if (err_cstr) error.assign(err_cstr); if (!ShouldPrintValueObject()) return; if (IsNil()) { lldb::LanguageType lang_type = (m_options.m_varformat_language == lldb::eLanguageTypeUnknown) ? valobj.GetPreferredDisplayLanguage() : m_options.m_varformat_language; if (Language *lang_plugin = Language::FindPlugin(lang_type)) { summary.assign(lang_plugin->GetNilReferenceSummaryString().str()); } else { // We treat C as the fallback language rather than as a separate Language // plugin. summary.assign("NULL"); } } else if (IsUninitialized()) { summary.assign(""); } else if (m_options.m_omit_summary_depth == 0) { TypeSummaryImpl *entry = GetSummaryFormatter(); if (entry) { valobj.GetSummaryAsCString(entry, summary, m_options.m_varformat_language); } else { const char *sum_cstr = valobj.GetSummaryAsCString(m_options.m_varformat_language); if (sum_cstr) summary.assign(sum_cstr); } } } bool ValueObjectPrinter::PrintValueAndSummaryIfNeeded(bool &value_printed, bool &summary_printed) { bool error_printed = false; if (ShouldPrintValueObject()) { if (!CheckScopeIfNeeded()) m_error.assign("out of scope"); if (m_error.empty()) { GetValueSummaryError(m_value, m_summary, m_error); } if (m_error.size()) { // we need to support scenarios in which it is actually fine for a value // to have no type but - on the other hand - if we get an error *AND* // have no type, we try to get out gracefully, since most often that // combination means "could not resolve a type" and the default failure // mode is quite ugly if (!m_compiler_type.IsValid()) { m_stream->Printf(" "); return false; } error_printed = true; m_stream->Printf(" <%s>\n", m_error.c_str()); } else { // Make sure we have a value and make sure the summary didn't specify // that the value should not be printed - and do not print the value if // this thing is nil (but show the value if the user passes a format // explicitly) TypeSummaryImpl *entry = GetSummaryFormatter(); ValueObject &valobj = GetMostSpecializedValue(); const bool has_nil_or_uninitialized_summary = (IsNil() || IsUninitialized()) && !m_summary.empty(); if (!has_nil_or_uninitialized_summary && !m_value.empty() && (entry == nullptr || (entry->DoesPrintValue(&valobj) || m_options.m_format != eFormatDefault) || m_summary.empty()) && !m_options.m_hide_value) { if (m_options.m_hide_pointer_value && IsPointerValue(valobj.GetCompilerType())) { } else { if (ShouldShowName()) m_stream->PutChar(' '); m_stream->PutCString(m_value); value_printed = true; } } if (m_summary.size()) { if (ShouldShowName() || value_printed) m_stream->PutChar(' '); m_stream->PutCString(m_summary); summary_printed = true; } } } return !error_printed; } llvm::Error ValueObjectPrinter::PrintObjectDescriptionIfNeeded(bool value_printed, bool summary_printed) { if (ShouldPrintValueObject()) { // let's avoid the overly verbose no description error for a nil thing if (m_options.m_use_objc && !IsNil() && !IsUninitialized() && (!m_options.m_pointer_as_array)) { if (!m_options.m_hide_value || ShouldShowName()) *m_stream << ' '; llvm::Expected object_desc = (value_printed || summary_printed) ? GetMostSpecializedValue().GetObjectDescription() : GetDescriptionForDisplay(); if (!object_desc) { // If no value or summary was printed, surface the error. if (!value_printed && !summary_printed) return object_desc.takeError(); // Otherwise gently nudge the user that they should have used // `p` instead of `po`. Unfortunately we cannot be more direct // about this, because we don't actually know what the user did. *m_stream << "warning: no object description available\n"; llvm::consumeError(object_desc.takeError()); } else { *m_stream << *object_desc; // If the description already ends with a \n don't add another one. if (object_desc->empty() || object_desc->back() != '\n') *m_stream << '\n'; } return llvm::Error::success(); } } return llvm::Error::success(); } bool DumpValueObjectOptions::PointerDepth::CanAllowExpansion() const { switch (m_mode) { case Mode::Always: case Mode::Default: return m_count > 0; case Mode::Never: return false; } return false; } bool ValueObjectPrinter::ShouldPrintChildren( DumpValueObjectOptions::PointerDepth &curr_ptr_depth) { const bool is_ref = IsRef(); const bool is_ptr = IsPtr(); const bool is_uninit = IsUninitialized(); if (is_uninit) return false; // If we have reached the maximum depth we shouldn't print any more children. if (HasReachedMaximumDepth()) return false; // if the user has specified an element count, always print children as it is // explicit user demand being honored if (m_options.m_pointer_as_array) return true; if (m_options.m_use_objc) return false; bool print_children = true; ValueObject &valobj = GetMostSpecializedValue(); if (TypeSummaryImpl *type_summary = GetSummaryFormatter()) print_children = type_summary->DoesPrintChildren(&valobj); // We will show children for all concrete types. We won't show pointer // contents unless a pointer depth has been specified. We won't reference // contents unless the reference is the root object (depth of zero). // Use a new temporary pointer depth in case we override the current // pointer depth below... if (is_ptr || is_ref) { // We have a pointer or reference whose value is an address. Make sure // that address is not NULL AddressType ptr_address_type; if (valobj.GetPointerValue(&ptr_address_type) == 0) return false; const bool is_root_level = m_curr_depth == 0; if (is_ref && is_root_level && print_children) { // If this is the root object (depth is zero) that we are showing and // it is a reference, and no pointer depth has been supplied print out // what it references. Don't do this at deeper depths otherwise we can // end up with infinite recursion... return true; } return curr_ptr_depth.CanAllowExpansion(); } return print_children || m_summary.empty(); } bool ValueObjectPrinter::ShouldExpandEmptyAggregates() { TypeSummaryImpl *entry = GetSummaryFormatter(); if (!entry) return true; return entry->DoesPrintEmptyAggregates(); } ValueObject &ValueObjectPrinter::GetValueObjectForChildrenGeneration() { return GetMostSpecializedValue(); } void ValueObjectPrinter::PrintChildrenPreamble(bool value_printed, bool summary_printed) { if (m_options.m_flat_output) { if (ShouldPrintValueObject()) m_stream->EOL(); } else { if (ShouldPrintValueObject()) { if (IsRef()) { m_stream->PutCString(": "); } else if (value_printed || summary_printed || ShouldShowName()) { m_stream->PutChar(' '); } m_stream->PutCString("{\n"); } m_stream->IndentMore(); } } void ValueObjectPrinter::PrintChild( ValueObjectSP child_sp, const DumpValueObjectOptions::PointerDepth &curr_ptr_depth) { const uint32_t consumed_summary_depth = m_options.m_pointer_as_array ? 0 : 1; const bool does_consume_ptr_depth = ((IsPtr() && !m_options.m_pointer_as_array) || IsRef()); DumpValueObjectOptions child_options(m_options); child_options.SetFormat(m_options.m_format) .SetSummary() .SetRootValueObjectName(); child_options.SetScopeChecked(true) .SetHideName(m_options.m_hide_name) .SetHideValue(m_options.m_hide_value) .SetOmitSummaryDepth(child_options.m_omit_summary_depth > 1 ? child_options.m_omit_summary_depth - consumed_summary_depth : 0) .SetElementCount(0); if (child_sp.get()) { auto ptr_depth = curr_ptr_depth; if (does_consume_ptr_depth) ptr_depth = curr_ptr_depth.Decremented(); ValueObjectPrinter child_printer(*(child_sp.get()), m_stream, child_options, ptr_depth, m_curr_depth + 1, m_printed_instance_pointers); llvm::Error error = child_printer.PrintValueObject(); if (error) { if (m_stream) *m_stream << "error: " << toString(std::move(error)); else llvm::consumeError(std::move(error)); } } } llvm::Expected ValueObjectPrinter::GetMaxNumChildrenToPrint(bool &print_dotdotdot) { ValueObject &synth_valobj = GetValueObjectForChildrenGeneration(); if (m_options.m_pointer_as_array) return m_options.m_pointer_as_array.m_element_count; const uint32_t max_num_children = m_options.m_ignore_cap ? UINT32_MAX : GetMostSpecializedValue() .GetTargetSP() ->GetMaximumNumberOfChildrenToDisplay(); // Ask for one more child than the maximum to see if we should print "...". auto num_children_or_err = synth_valobj.GetNumChildren( llvm::SaturatingAdd(max_num_children, uint32_t(1))); if (!num_children_or_err) return num_children_or_err; if (*num_children_or_err > max_num_children) { print_dotdotdot = true; return max_num_children; } return num_children_or_err; } void ValueObjectPrinter::PrintChildrenPostamble(bool print_dotdotdot) { if (!m_options.m_flat_output) { if (print_dotdotdot) { GetMostSpecializedValue() .GetTargetSP() ->GetDebugger() .GetCommandInterpreter() .ChildrenTruncated(); m_stream->Indent("...\n"); } m_stream->IndentLess(); m_stream->Indent("}\n"); } } bool ValueObjectPrinter::ShouldPrintEmptyBrackets(bool value_printed, bool summary_printed) { ValueObject &synth_valobj = GetValueObjectForChildrenGeneration(); if (!IsAggregate()) return false; if (!m_options.m_reveal_empty_aggregates) { if (value_printed || summary_printed) return false; } if (synth_valobj.MightHaveChildren()) return true; if (m_val_summary_ok) return false; return true; } static constexpr size_t PhysicalIndexForLogicalIndex(size_t base, size_t stride, size_t logical) { return base + logical * stride; } ValueObjectSP ValueObjectPrinter::GenerateChild(ValueObject &synth_valobj, size_t idx) { if (m_options.m_pointer_as_array) { // if generating pointer-as-array children, use GetSyntheticArrayMember return synth_valobj.GetSyntheticArrayMember( PhysicalIndexForLogicalIndex( m_options.m_pointer_as_array.m_base_element, m_options.m_pointer_as_array.m_stride, idx), true); } else { // otherwise, do the usual thing return synth_valobj.GetChildAtIndex(idx); } } void ValueObjectPrinter::PrintChildren( bool value_printed, bool summary_printed, const DumpValueObjectOptions::PointerDepth &curr_ptr_depth) { ValueObject &synth_valobj = GetValueObjectForChildrenGeneration(); bool print_dotdotdot = false; auto num_children_or_err = GetMaxNumChildrenToPrint(print_dotdotdot); if (!num_children_or_err) { *m_stream << " <" << llvm::toString(num_children_or_err.takeError()) << '>'; return; } uint32_t num_children = *num_children_or_err; if (num_children) { bool any_children_printed = false; for (size_t idx = 0; idx < num_children; ++idx) { if (ValueObjectSP child_sp = GenerateChild(synth_valobj, idx)) { if (m_options.m_child_printing_decider && !m_options.m_child_printing_decider(child_sp->GetName())) continue; if (!any_children_printed) { PrintChildrenPreamble(value_printed, summary_printed); any_children_printed = true; } PrintChild(child_sp, curr_ptr_depth); } } if (any_children_printed) PrintChildrenPostamble(print_dotdotdot); else { if (ShouldPrintEmptyBrackets(value_printed, summary_printed)) { if (ShouldPrintValueObject()) m_stream->PutCString(" {}\n"); else m_stream->EOL(); } else m_stream->EOL(); } } else if (ShouldPrintEmptyBrackets(value_printed, summary_printed)) { // Aggregate, no children... if (ShouldPrintValueObject()) { // if it has a synthetic value, then don't print {}, the synthetic // children are probably only being used to vend a value if (GetMostSpecializedValue().DoesProvideSyntheticValue() || !ShouldExpandEmptyAggregates()) m_stream->PutCString("\n"); else m_stream->PutCString(" {}\n"); } } else { if (ShouldPrintValueObject()) m_stream->EOL(); } } bool ValueObjectPrinter::PrintChildrenOneLiner(bool hide_names) { ValueObject &synth_valobj = GetValueObjectForChildrenGeneration(); bool print_dotdotdot = false; auto num_children_or_err = GetMaxNumChildrenToPrint(print_dotdotdot); if (!num_children_or_err) { *m_stream << '<' << llvm::toString(num_children_or_err.takeError()) << '>'; return true; } uint32_t num_children = *num_children_or_err; if (num_children) { m_stream->PutChar('('); bool did_print_children = false; for (uint32_t idx = 0; idx < num_children; ++idx) { lldb::ValueObjectSP child_sp(synth_valobj.GetChildAtIndex(idx)); if (child_sp) child_sp = child_sp->GetQualifiedRepresentationIfAvailable( m_options.m_use_dynamic, m_options.m_use_synthetic); if (child_sp) { if (m_options.m_child_printing_decider && !m_options.m_child_printing_decider(child_sp->GetName())) continue; if (idx && did_print_children) m_stream->PutCString(", "); did_print_children = true; if (!hide_names) { const char *name = child_sp.get()->GetName().AsCString(); if (name && *name) { m_stream->PutCString(name); m_stream->PutCString(" = "); } } child_sp->DumpPrintableRepresentation( *m_stream, ValueObject::eValueObjectRepresentationStyleSummary, m_options.m_format, ValueObject::PrintableRepresentationSpecialCases::eDisable); } } if (print_dotdotdot) m_stream->PutCString(", ...)"); else m_stream->PutChar(')'); } return true; } llvm::Error ValueObjectPrinter::PrintChildrenIfNeeded(bool value_printed, bool summary_printed) { auto error = PrintObjectDescriptionIfNeeded(value_printed, summary_printed); if (error) return error; ValueObject &valobj = GetMostSpecializedValue(); DumpValueObjectOptions::PointerDepth curr_ptr_depth = m_ptr_depth; const bool print_children = ShouldPrintChildren(curr_ptr_depth); const bool print_oneline = (curr_ptr_depth.CanAllowExpansion() || m_options.m_show_types || !m_options.m_allow_oneliner_mode || m_options.m_flat_output || (m_options.m_pointer_as_array) || m_options.m_show_location) ? false : DataVisualization::ShouldPrintAsOneLiner(valobj); if (print_children && IsInstancePointer()) { uint64_t instance_ptr_value = valobj.GetValueAsUnsigned(0); if (m_printed_instance_pointers->count(instance_ptr_value)) { // We already printed this instance-is-pointer thing, so don't expand it. m_stream->PutCString(" {...}\n"); return llvm::Error::success(); } else { // Remember this guy for future reference. m_printed_instance_pointers->emplace(instance_ptr_value); } } if (print_children) { if (print_oneline) { m_stream->PutChar(' '); PrintChildrenOneLiner(false); m_stream->EOL(); } else PrintChildren(value_printed, summary_printed, curr_ptr_depth); } else if (HasReachedMaximumDepth() && IsAggregate() && ShouldPrintValueObject()) { m_stream->PutCString("{...}\n"); // The maximum child depth has been reached. If `m_max_depth` is the default // (i.e. the user has _not_ customized it), then lldb presents a warning to // the user. The warning tells the user that the limit has been reached, but // more importantly tells them how to expand the limit if desired. if (m_options.m_max_depth_is_default) valobj.GetTargetSP() ->GetDebugger() .GetCommandInterpreter() .SetReachedMaximumDepth(); } else m_stream->EOL(); return llvm::Error::success(); } bool ValueObjectPrinter::HasReachedMaximumDepth() { return m_curr_depth >= m_options.m_max_depth; } bool ValueObjectPrinter::ShouldShowName() const { if (m_curr_depth == 0) return !m_options.m_hide_root_name && !m_options.m_hide_name; return !m_options.m_hide_name; }