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llvm-project/lldb/source/DataFormatters/FormatManager.cpp
Raphael Isemann 5b0de5756c [lldb] Unify type name matching in FormattersContainer 
Summary:

FormattersContainer stores LLDB's formatters. It's implemented as a templated
map-like data structures that supports any kind of value type and only allows
ConstString and RegularExpression as the key types. The keys are used for
matching type names (e.g., the ConstString key `std::vector` matches the type
with the same name while RegularExpression keys match any type where the
RegularExpression instance matches).

The fact that a single FormattersContainer can only match either by string
comparison or regex matching (depending on the KeyType) causes us to always have
two FormatterContainer instances in all the formatting code. This also leads to
us having every type name matching logic in LLDB twice. For example,
TypeCategory has to implement every method twice (one string matching one, one
regex matching one).

This patch changes FormattersContainer to instead have a single `TypeMatcher`
key that wraps the logic for string-based and regex-based type matching and is
now the only possible KeyType for the FormattersContainer. This means that a
single FormattersContainer can now match types with both regex and string
comparison.

To summarize the changes in this patch:
* Remove all the `*_Impl` methods from `FormattersContainer`
* Instead call the FormatMap functions from `FormattersContainer` with a
  `TypeMatcher` type that does the respective matching.
* Replace `ConstString` with `TypeMatcher` in the few places that directly
  interact with `FormattersContainer`.

I'm working on some follow up patches that I split up because they deserve their
own review:

* Unify FormatMap and FormattersContainer (they are nearly identical now).
* Delete the duplicated half of all the type matching code that can now use one
  interface.
* Propagate TypeMatcher through all the formatter code interfaces instead of
  always offering two functions for everything.

There is one ugly design part that I couldn't get rid of yet and that is that we
have to support getting back the string used to construct a `TypeMatcher` later
on. The reason for this is that LLDB only supports referencing existing type
matchers by just typing their respective input string again (without even
supplying if it's a regex or not).

Reviewers: davide, mib

Reviewed By: mib

Subscribers: mgorny, JDevlieghere

Differential Revision: https://reviews.llvm.org/D84151
2020-07-21 18:44:50 +02:00

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//===-- FormatManager.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/FormatManager.h"
#include "llvm/ADT/STLExtras.h"
#include "lldb/Core/Debugger.h"
#include "lldb/DataFormatters/FormattersHelpers.h"
#include "lldb/DataFormatters/LanguageCategory.h"
#include "lldb/Target/ExecutionContext.h"
#include "lldb/Target/Language.h"
#include "lldb/Utility/Log.h"
using namespace lldb;
using namespace lldb_private;
using namespace lldb_private::formatters;
struct FormatInfo {
Format format;
const char format_char; // One or more format characters that can be used for
// this format.
const char *format_name; // Long format name that can be used to specify the
// current format
};
static constexpr FormatInfo g_format_infos[] = {
{eFormatDefault, '\0', "default"},
{eFormatBoolean, 'B', "boolean"},
{eFormatBinary, 'b', "binary"},
{eFormatBytes, 'y', "bytes"},
{eFormatBytesWithASCII, 'Y', "bytes with ASCII"},
{eFormatChar, 'c', "character"},
{eFormatCharPrintable, 'C', "printable character"},
{eFormatComplexFloat, 'F', "complex float"},
{eFormatCString, 's', "c-string"},
{eFormatDecimal, 'd', "decimal"},
{eFormatEnum, 'E', "enumeration"},
{eFormatHex, 'x', "hex"},
{eFormatHexUppercase, 'X', "uppercase hex"},
{eFormatFloat, 'f', "float"},
{eFormatOctal, 'o', "octal"},
{eFormatOSType, 'O', "OSType"},
{eFormatUnicode16, 'U', "unicode16"},
{eFormatUnicode32, '\0', "unicode32"},
{eFormatUnsigned, 'u', "unsigned decimal"},
{eFormatPointer, 'p', "pointer"},
{eFormatVectorOfChar, '\0', "char[]"},
{eFormatVectorOfSInt8, '\0', "int8_t[]"},
{eFormatVectorOfUInt8, '\0', "uint8_t[]"},
{eFormatVectorOfSInt16, '\0', "int16_t[]"},
{eFormatVectorOfUInt16, '\0', "uint16_t[]"},
{eFormatVectorOfSInt32, '\0', "int32_t[]"},
{eFormatVectorOfUInt32, '\0', "uint32_t[]"},
{eFormatVectorOfSInt64, '\0', "int64_t[]"},
{eFormatVectorOfUInt64, '\0', "uint64_t[]"},
{eFormatVectorOfFloat16, '\0', "float16[]"},
{eFormatVectorOfFloat32, '\0', "float32[]"},
{eFormatVectorOfFloat64, '\0', "float64[]"},
{eFormatVectorOfUInt128, '\0', "uint128_t[]"},
{eFormatComplexInteger, 'I', "complex integer"},
{eFormatCharArray, 'a', "character array"},
{eFormatAddressInfo, 'A', "address"},
{eFormatHexFloat, '\0', "hex float"},
{eFormatInstruction, 'i', "instruction"},
{eFormatVoid, 'v', "void"},
{eFormatUnicode8, 'u', "unicode8"},
};
static_assert((sizeof(g_format_infos) / sizeof(g_format_infos[0])) ==
kNumFormats,
"All formats must have a corresponding info entry.");
static uint32_t g_num_format_infos = llvm::array_lengthof(g_format_infos);
static bool GetFormatFromFormatChar(char format_char, Format &format) {
for (uint32_t i = 0; i < g_num_format_infos; ++i) {
if (g_format_infos[i].format_char == format_char) {
format = g_format_infos[i].format;
return true;
}
}
format = eFormatInvalid;
return false;
}
static bool GetFormatFromFormatName(const char *format_name,
bool partial_match_ok, Format &format) {
uint32_t i;
for (i = 0; i < g_num_format_infos; ++i) {
if (strcasecmp(g_format_infos[i].format_name, format_name) == 0) {
format = g_format_infos[i].format;
return true;
}
}
if (partial_match_ok) {
for (i = 0; i < g_num_format_infos; ++i) {
if (strcasestr(g_format_infos[i].format_name, format_name) ==
g_format_infos[i].format_name) {
format = g_format_infos[i].format;
return true;
}
}
}
format = eFormatInvalid;
return false;
}
void FormatManager::Changed() {
++m_last_revision;
m_format_cache.Clear();
std::lock_guard<std::recursive_mutex> guard(m_language_categories_mutex);
for (auto &iter : m_language_categories_map) {
if (iter.second)
iter.second->GetFormatCache().Clear();
}
}
bool FormatManager::GetFormatFromCString(const char *format_cstr,
bool partial_match_ok,
lldb::Format &format) {
bool success = false;
if (format_cstr && format_cstr[0]) {
if (format_cstr[1] == '\0') {
success = GetFormatFromFormatChar(format_cstr[0], format);
if (success)
return true;
}
success = GetFormatFromFormatName(format_cstr, partial_match_ok, format);
}
if (!success)
format = eFormatInvalid;
return success;
}
char FormatManager::GetFormatAsFormatChar(lldb::Format format) {
for (uint32_t i = 0; i < g_num_format_infos; ++i) {
if (g_format_infos[i].format == format)
return g_format_infos[i].format_char;
}
return '\0';
}
const char *FormatManager::GetFormatAsCString(Format format) {
if (format >= eFormatDefault && format < kNumFormats)
return g_format_infos[format].format_name;
return nullptr;
}
void FormatManager::EnableAllCategories() {
m_categories_map.EnableAllCategories();
std::lock_guard<std::recursive_mutex> guard(m_language_categories_mutex);
for (auto &iter : m_language_categories_map) {
if (iter.second)
iter.second->Enable();
}
}
void FormatManager::DisableAllCategories() {
m_categories_map.DisableAllCategories();
std::lock_guard<std::recursive_mutex> guard(m_language_categories_mutex);
for (auto &iter : m_language_categories_map) {
if (iter.second)
iter.second->Disable();
}
}
void FormatManager::GetPossibleMatches(
ValueObject &valobj, CompilerType compiler_type,
lldb::DynamicValueType use_dynamic, FormattersMatchVector &entries,
bool did_strip_ptr, bool did_strip_ref, bool did_strip_typedef,
bool root_level) {
compiler_type = compiler_type.GetTypeForFormatters();
ConstString type_name(compiler_type.GetTypeName());
if (valobj.GetBitfieldBitSize() > 0) {
StreamString sstring;
sstring.Printf("%s:%d", type_name.AsCString(), valobj.GetBitfieldBitSize());
ConstString bitfieldname(sstring.GetString());
entries.push_back(
{bitfieldname, did_strip_ptr, did_strip_ref, did_strip_typedef});
}
if (!compiler_type.IsMeaninglessWithoutDynamicResolution()) {
entries.push_back(
{type_name, did_strip_ptr, did_strip_ref, did_strip_typedef});
ConstString display_type_name(compiler_type.GetTypeName());
if (display_type_name != type_name)
entries.push_back({display_type_name, did_strip_ptr,
did_strip_ref, did_strip_typedef});
}
for (bool is_rvalue_ref = true, j = true;
j && compiler_type.IsReferenceType(nullptr, &is_rvalue_ref); j = false) {
CompilerType non_ref_type = compiler_type.GetNonReferenceType();
GetPossibleMatches(
valobj, non_ref_type,
use_dynamic, entries, did_strip_ptr, true, did_strip_typedef);
if (non_ref_type.IsTypedefType()) {
CompilerType deffed_referenced_type = non_ref_type.GetTypedefedType();
deffed_referenced_type =
is_rvalue_ref ? deffed_referenced_type.GetRValueReferenceType()
: deffed_referenced_type.GetLValueReferenceType();
GetPossibleMatches(
valobj, deffed_referenced_type,
use_dynamic, entries, did_strip_ptr, did_strip_ref,
true); // this is not exactly the usual meaning of stripping typedefs
}
}
if (compiler_type.IsPointerType()) {
CompilerType non_ptr_type = compiler_type.GetPointeeType();
GetPossibleMatches(
valobj, non_ptr_type,
use_dynamic, entries, true, did_strip_ref, did_strip_typedef);
if (non_ptr_type.IsTypedefType()) {
CompilerType deffed_pointed_type =
non_ptr_type.GetTypedefedType().GetPointerType();
const bool stripped_typedef = true;
GetPossibleMatches(
valobj, deffed_pointed_type,
use_dynamic, entries, did_strip_ptr, did_strip_ref,
stripped_typedef); // this is not exactly the usual meaning of
// stripping typedefs
}
}
// For arrays with typedef-ed elements, we add a candidate with the typedef
// stripped.
uint64_t array_size;
if (compiler_type.IsArrayType(nullptr, &array_size, nullptr)) {
CompilerType element_type = compiler_type.GetArrayElementType();
if (element_type.IsTypedefType()) {
// Get the stripped element type and compute the stripped array type
// from it.
CompilerType deffed_array_type =
element_type.GetTypedefedType().GetArrayType(array_size);
const bool stripped_typedef = true;
GetPossibleMatches(
valobj, deffed_array_type,
use_dynamic, entries, did_strip_ptr, did_strip_ref,
stripped_typedef); // this is not exactly the usual meaning of
// stripping typedefs
}
}
for (lldb::LanguageType language_type :
GetCandidateLanguages(valobj.GetObjectRuntimeLanguage())) {
if (Language *language = Language::FindPlugin(language_type)) {
for (ConstString candidate :
language->GetPossibleFormattersMatches(valobj, use_dynamic)) {
entries.push_back(
{candidate,
did_strip_ptr, did_strip_ref, did_strip_typedef});
}
}
}
// try to strip typedef chains
if (compiler_type.IsTypedefType()) {
CompilerType deffed_type = compiler_type.GetTypedefedType();
GetPossibleMatches(
valobj, deffed_type,
use_dynamic, entries, did_strip_ptr, did_strip_ref, true);
}
if (root_level) {
do {
if (!compiler_type.IsValid())
break;
CompilerType unqual_compiler_ast_type =
compiler_type.GetFullyUnqualifiedType();
if (!unqual_compiler_ast_type.IsValid())
break;
if (unqual_compiler_ast_type.GetOpaqueQualType() !=
compiler_type.GetOpaqueQualType())
GetPossibleMatches(valobj, unqual_compiler_ast_type,
use_dynamic, entries, did_strip_ptr, did_strip_ref,
did_strip_typedef);
} while (false);
// if all else fails, go to static type
if (valobj.IsDynamic()) {
lldb::ValueObjectSP static_value_sp(valobj.GetStaticValue());
if (static_value_sp)
GetPossibleMatches(
*static_value_sp.get(), static_value_sp->GetCompilerType(),
use_dynamic, entries, did_strip_ptr, did_strip_ref,
did_strip_typedef, true);
}
}
}
lldb::TypeFormatImplSP
FormatManager::GetFormatForType(lldb::TypeNameSpecifierImplSP type_sp) {
if (!type_sp)
return lldb::TypeFormatImplSP();
lldb::TypeFormatImplSP format_chosen_sp;
uint32_t num_categories = m_categories_map.GetCount();
lldb::TypeCategoryImplSP category_sp;
uint32_t prio_category = UINT32_MAX;
for (uint32_t category_id = 0; category_id < num_categories; category_id++) {
category_sp = GetCategoryAtIndex(category_id);
if (!category_sp->IsEnabled())
continue;
lldb::TypeFormatImplSP format_current_sp =
category_sp->GetFormatForType(type_sp);
if (format_current_sp &&
(format_chosen_sp.get() == nullptr ||
(prio_category > category_sp->GetEnabledPosition()))) {
prio_category = category_sp->GetEnabledPosition();
format_chosen_sp = format_current_sp;
}
}
return format_chosen_sp;
}
lldb::TypeSummaryImplSP
FormatManager::GetSummaryForType(lldb::TypeNameSpecifierImplSP type_sp) {
if (!type_sp)
return lldb::TypeSummaryImplSP();
lldb::TypeSummaryImplSP summary_chosen_sp;
uint32_t num_categories = m_categories_map.GetCount();
lldb::TypeCategoryImplSP category_sp;
uint32_t prio_category = UINT32_MAX;
for (uint32_t category_id = 0; category_id < num_categories; category_id++) {
category_sp = GetCategoryAtIndex(category_id);
if (!category_sp->IsEnabled())
continue;
lldb::TypeSummaryImplSP summary_current_sp =
category_sp->GetSummaryForType(type_sp);
if (summary_current_sp &&
(summary_chosen_sp.get() == nullptr ||
(prio_category > category_sp->GetEnabledPosition()))) {
prio_category = category_sp->GetEnabledPosition();
summary_chosen_sp = summary_current_sp;
}
}
return summary_chosen_sp;
}
lldb::TypeFilterImplSP
FormatManager::GetFilterForType(lldb::TypeNameSpecifierImplSP type_sp) {
if (!type_sp)
return lldb::TypeFilterImplSP();
lldb::TypeFilterImplSP filter_chosen_sp;
uint32_t num_categories = m_categories_map.GetCount();
lldb::TypeCategoryImplSP category_sp;
uint32_t prio_category = UINT32_MAX;
for (uint32_t category_id = 0; category_id < num_categories; category_id++) {
category_sp = GetCategoryAtIndex(category_id);
if (!category_sp->IsEnabled())
continue;
lldb::TypeFilterImplSP filter_current_sp(
(TypeFilterImpl *)category_sp->GetFilterForType(type_sp).get());
if (filter_current_sp &&
(filter_chosen_sp.get() == nullptr ||
(prio_category > category_sp->GetEnabledPosition()))) {
prio_category = category_sp->GetEnabledPosition();
filter_chosen_sp = filter_current_sp;
}
}
return filter_chosen_sp;
}
lldb::ScriptedSyntheticChildrenSP
FormatManager::GetSyntheticForType(lldb::TypeNameSpecifierImplSP type_sp) {
if (!type_sp)
return lldb::ScriptedSyntheticChildrenSP();
lldb::ScriptedSyntheticChildrenSP synth_chosen_sp;
uint32_t num_categories = m_categories_map.GetCount();
lldb::TypeCategoryImplSP category_sp;
uint32_t prio_category = UINT32_MAX;
for (uint32_t category_id = 0; category_id < num_categories; category_id++) {
category_sp = GetCategoryAtIndex(category_id);
if (!category_sp->IsEnabled())
continue;
lldb::ScriptedSyntheticChildrenSP synth_current_sp(
(ScriptedSyntheticChildren *)category_sp->GetSyntheticForType(type_sp)
.get());
if (synth_current_sp &&
(synth_chosen_sp.get() == nullptr ||
(prio_category > category_sp->GetEnabledPosition()))) {
prio_category = category_sp->GetEnabledPosition();
synth_chosen_sp = synth_current_sp;
}
}
return synth_chosen_sp;
}
void FormatManager::ForEachCategory(TypeCategoryMap::ForEachCallback callback) {
m_categories_map.ForEach(callback);
std::lock_guard<std::recursive_mutex> guard(m_language_categories_mutex);
for (const auto &entry : m_language_categories_map) {
if (auto category_sp = entry.second->GetCategory()) {
if (!callback(category_sp))
break;
}
}
}
lldb::TypeCategoryImplSP
FormatManager::GetCategory(ConstString category_name, bool can_create) {
if (!category_name)
return GetCategory(m_default_category_name);
lldb::TypeCategoryImplSP category;
if (m_categories_map.Get(category_name, category))
return category;
if (!can_create)
return lldb::TypeCategoryImplSP();
m_categories_map.Add(
category_name,
lldb::TypeCategoryImplSP(new TypeCategoryImpl(this, category_name)));
return GetCategory(category_name);
}
lldb::Format FormatManager::GetSingleItemFormat(lldb::Format vector_format) {
switch (vector_format) {
case eFormatVectorOfChar:
return eFormatCharArray;
case eFormatVectorOfSInt8:
case eFormatVectorOfSInt16:
case eFormatVectorOfSInt32:
case eFormatVectorOfSInt64:
return eFormatDecimal;
case eFormatVectorOfUInt8:
case eFormatVectorOfUInt16:
case eFormatVectorOfUInt32:
case eFormatVectorOfUInt64:
case eFormatVectorOfUInt128:
return eFormatHex;
case eFormatVectorOfFloat16:
case eFormatVectorOfFloat32:
case eFormatVectorOfFloat64:
return eFormatFloat;
default:
return lldb::eFormatInvalid;
}
}
bool FormatManager::ShouldPrintAsOneLiner(ValueObject &valobj) {
// if settings say no oneline whatsoever
if (valobj.GetTargetSP().get() &&
!valobj.GetTargetSP()->GetDebugger().GetAutoOneLineSummaries())
return false; // then don't oneline
// if this object has a summary, then ask the summary
if (valobj.GetSummaryFormat().get() != nullptr)
return valobj.GetSummaryFormat()->IsOneLiner();
// no children, no party
if (valobj.GetNumChildren() == 0)
return false;
// ask the type if it has any opinion about this eLazyBoolCalculate == no
// opinion; other values should be self explanatory
CompilerType compiler_type(valobj.GetCompilerType());
if (compiler_type.IsValid()) {
switch (compiler_type.ShouldPrintAsOneLiner(&valobj)) {
case eLazyBoolNo:
return false;
case eLazyBoolYes:
return true;
case eLazyBoolCalculate:
break;
}
}
size_t total_children_name_len = 0;
for (size_t idx = 0; idx < valobj.GetNumChildren(); idx++) {
bool is_synth_val = false;
ValueObjectSP child_sp(valobj.GetChildAtIndex(idx, true));
// something is wrong here - bail out
if (!child_sp)
return false;
// also ask the child's type if it has any opinion
CompilerType child_compiler_type(child_sp->GetCompilerType());
if (child_compiler_type.IsValid()) {
switch (child_compiler_type.ShouldPrintAsOneLiner(child_sp.get())) {
case eLazyBoolYes:
// an opinion of yes is only binding for the child, so keep going
case eLazyBoolCalculate:
break;
case eLazyBoolNo:
// but if the child says no, then it's a veto on the whole thing
return false;
}
}
// if we decided to define synthetic children for a type, we probably care
// enough to show them, but avoid nesting children in children
if (child_sp->GetSyntheticChildren().get() != nullptr) {
ValueObjectSP synth_sp(child_sp->GetSyntheticValue());
// wait.. wat? just get out of here..
if (!synth_sp)
return false;
// but if we only have them to provide a value, keep going
if (!synth_sp->MightHaveChildren() &&
synth_sp->DoesProvideSyntheticValue())
is_synth_val = true;
else
return false;
}
total_children_name_len += child_sp->GetName().GetLength();
// 50 itself is a "randomly" chosen number - the idea is that
// overly long structs should not get this treatment
// FIXME: maybe make this a user-tweakable setting?
if (total_children_name_len > 50)
return false;
// if a summary is there..
if (child_sp->GetSummaryFormat()) {
// and it wants children, then bail out
if (child_sp->GetSummaryFormat()->DoesPrintChildren(child_sp.get()))
return false;
}
// if this child has children..
if (child_sp->GetNumChildren()) {
// ...and no summary...
// (if it had a summary and the summary wanted children, we would have
// bailed out anyway
// so this only makes us bail out if this has no summary and we would
// then print children)
if (!child_sp->GetSummaryFormat() && !is_synth_val) // but again only do
// that if not a
// synthetic valued
// child
return false; // then bail out
}
}
return true;
}
ConstString FormatManager::GetTypeForCache(ValueObject &valobj,
lldb::DynamicValueType use_dynamic) {
ValueObjectSP valobj_sp = valobj.GetQualifiedRepresentationIfAvailable(
use_dynamic, valobj.IsSynthetic());
if (valobj_sp && valobj_sp->GetCompilerType().IsValid()) {
if (!valobj_sp->GetCompilerType().IsMeaninglessWithoutDynamicResolution())
return valobj_sp->GetQualifiedTypeName();
}
return ConstString();
}
std::vector<lldb::LanguageType>
FormatManager::GetCandidateLanguages(lldb::LanguageType lang_type) {
switch (lang_type) {
case lldb::eLanguageTypeC:
case lldb::eLanguageTypeC89:
case lldb::eLanguageTypeC99:
case lldb::eLanguageTypeC11:
case lldb::eLanguageTypeC_plus_plus:
case lldb::eLanguageTypeC_plus_plus_03:
case lldb::eLanguageTypeC_plus_plus_11:
case lldb::eLanguageTypeC_plus_plus_14:
return {lldb::eLanguageTypeC_plus_plus, lldb::eLanguageTypeObjC};
default:
return {lang_type};
}
llvm_unreachable("Fully covered switch");
}
LanguageCategory *
FormatManager::GetCategoryForLanguage(lldb::LanguageType lang_type) {
std::lock_guard<std::recursive_mutex> guard(m_language_categories_mutex);
auto iter = m_language_categories_map.find(lang_type),
end = m_language_categories_map.end();
if (iter != end)
return iter->second.get();
LanguageCategory *lang_category = new LanguageCategory(lang_type);
m_language_categories_map[lang_type] =
LanguageCategory::UniquePointer(lang_category);
return lang_category;
}
template <typename ImplSP>
ImplSP FormatManager::GetHardcoded(FormattersMatchData &match_data) {
ImplSP retval_sp;
for (lldb::LanguageType lang_type : match_data.GetCandidateLanguages()) {
if (LanguageCategory *lang_category = GetCategoryForLanguage(lang_type)) {
if (lang_category->GetHardcoded(*this, match_data, retval_sp))
return retval_sp;
}
}
return retval_sp;
}
template <typename ImplSP>
ImplSP FormatManager::Get(ValueObject &valobj,
lldb::DynamicValueType use_dynamic) {
FormattersMatchData match_data(valobj, use_dynamic);
if (ImplSP retval_sp = GetCached<ImplSP>(match_data))
return retval_sp;
Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_DATAFORMATTERS));
LLDB_LOGF(log, "[%s] Search failed. Giving language a chance.", __FUNCTION__);
for (lldb::LanguageType lang_type : match_data.GetCandidateLanguages()) {
if (LanguageCategory *lang_category = GetCategoryForLanguage(lang_type)) {
ImplSP retval_sp;
if (lang_category->Get(match_data, retval_sp))
if (retval_sp) {
LLDB_LOGF(log, "[%s] Language search success. Returning.",
__FUNCTION__);
return retval_sp;
}
}
}
LLDB_LOGF(log, "[%s] Search failed. Giving hardcoded a chance.",
__FUNCTION__);
return GetHardcoded<ImplSP>(match_data);
}
template <typename ImplSP>
ImplSP FormatManager::GetCached(FormattersMatchData &match_data) {
ImplSP retval_sp;
Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_DATAFORMATTERS));
if (match_data.GetTypeForCache()) {
LLDB_LOGF(log, "\n\n[%s] Looking into cache for type %s", __FUNCTION__,
match_data.GetTypeForCache().AsCString("<invalid>"));
if (m_format_cache.Get(match_data.GetTypeForCache(), retval_sp)) {
if (log) {
LLDB_LOGF(log, "[%s] Cache search success. Returning.", __FUNCTION__);
LLDB_LOGV(log, "Cache hits: {0} - Cache Misses: {1}",
m_format_cache.GetCacheHits(),
m_format_cache.GetCacheMisses());
}
return retval_sp;
}
LLDB_LOGF(log, "[%s] Cache search failed. Going normal route",
__FUNCTION__);
}
m_categories_map.Get(match_data, retval_sp);
if (match_data.GetTypeForCache() && (!retval_sp || !retval_sp->NonCacheable())) {
LLDB_LOGF(log, "[%s] Caching %p for type %s", __FUNCTION__,
static_cast<void *>(retval_sp.get()),
match_data.GetTypeForCache().AsCString("<invalid>"));
m_format_cache.Set(match_data.GetTypeForCache(), retval_sp);
}
LLDB_LOGV(log, "Cache hits: {0} - Cache Misses: {1}",
m_format_cache.GetCacheHits(), m_format_cache.GetCacheMisses());
return retval_sp;
}
lldb::TypeFormatImplSP
FormatManager::GetFormat(ValueObject &valobj,
lldb::DynamicValueType use_dynamic) {
return Get<lldb::TypeFormatImplSP>(valobj, use_dynamic);
}
lldb::TypeSummaryImplSP
FormatManager::GetSummaryFormat(ValueObject &valobj,
lldb::DynamicValueType use_dynamic) {
return Get<lldb::TypeSummaryImplSP>(valobj, use_dynamic);
}
lldb::SyntheticChildrenSP
FormatManager::GetSyntheticChildren(ValueObject &valobj,
lldb::DynamicValueType use_dynamic) {
return Get<lldb::SyntheticChildrenSP>(valobj, use_dynamic);
}
FormatManager::FormatManager()
: m_last_revision(0), m_format_cache(), m_language_categories_mutex(),
m_language_categories_map(), m_named_summaries_map(this),
m_categories_map(this), m_default_category_name(ConstString("default")),
m_system_category_name(ConstString("system")),
m_vectortypes_category_name(ConstString("VectorTypes")) {
LoadSystemFormatters();
LoadVectorFormatters();
EnableCategory(m_vectortypes_category_name, TypeCategoryMap::Last,
lldb::eLanguageTypeObjC_plus_plus);
EnableCategory(m_system_category_name, TypeCategoryMap::Last,
lldb::eLanguageTypeObjC_plus_plus);
}
void FormatManager::LoadSystemFormatters() {
TypeSummaryImpl::Flags string_flags;
string_flags.SetCascades(true)
.SetSkipPointers(true)
.SetSkipReferences(false)
.SetDontShowChildren(true)
.SetDontShowValue(false)
.SetShowMembersOneLiner(false)
.SetHideItemNames(false);
TypeSummaryImpl::Flags string_array_flags;
string_array_flags.SetCascades(true)
.SetSkipPointers(true)
.SetSkipReferences(false)
.SetDontShowChildren(true)
.SetDontShowValue(true)
.SetShowMembersOneLiner(false)
.SetHideItemNames(false);
lldb::TypeSummaryImplSP string_format(
new StringSummaryFormat(string_flags, "${var%s}"));
lldb::TypeSummaryImplSP string_array_format(
new StringSummaryFormat(string_array_flags, "${var%s}"));
RegularExpression any_size_char_arr(llvm::StringRef("char \\[[0-9]+\\]"));
TypeCategoryImpl::SharedPointer sys_category_sp =
GetCategory(m_system_category_name);
sys_category_sp->GetTypeSummariesContainer()->Add(ConstString("char *"),
string_format);
sys_category_sp->GetTypeSummariesContainer()->Add(
ConstString("unsigned char *"), string_format);
sys_category_sp->GetRegexTypeSummariesContainer()->Add(
std::move(any_size_char_arr), string_array_format);
lldb::TypeSummaryImplSP ostype_summary(
new StringSummaryFormat(TypeSummaryImpl::Flags()
.SetCascades(false)
.SetSkipPointers(true)
.SetSkipReferences(true)
.SetDontShowChildren(true)
.SetDontShowValue(false)
.SetShowMembersOneLiner(false)
.SetHideItemNames(false),
"${var%O}"));
sys_category_sp->GetTypeSummariesContainer()->Add(ConstString("OSType"),
ostype_summary);
TypeFormatImpl::Flags fourchar_flags;
fourchar_flags.SetCascades(true).SetSkipPointers(true).SetSkipReferences(
true);
AddFormat(sys_category_sp, lldb::eFormatOSType, ConstString("FourCharCode"),
fourchar_flags);
}
void FormatManager::LoadVectorFormatters() {
TypeCategoryImpl::SharedPointer vectors_category_sp =
GetCategory(m_vectortypes_category_name);
TypeSummaryImpl::Flags vector_flags;
vector_flags.SetCascades(true)
.SetSkipPointers(true)
.SetSkipReferences(false)
.SetDontShowChildren(true)
.SetDontShowValue(false)
.SetShowMembersOneLiner(true)
.SetHideItemNames(true);
AddStringSummary(vectors_category_sp, "${var.uint128}",
ConstString("builtin_type_vec128"), vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("float [4]"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("int32_t [4]"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("int16_t [8]"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vDouble"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vFloat"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vSInt8"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vSInt16"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vSInt32"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vUInt16"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vUInt8"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vUInt16"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vUInt32"),
vector_flags);
AddStringSummary(vectors_category_sp, "", ConstString("vBool32"),
vector_flags);
}
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