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bazel / bazel / 25f10697e1bf217d54374efecf1c343539148552 / . / third_party / protobuf / 3.6.1 / src / google / protobuf / compiler / cpp / cpp_helpers.cc
blob: 163dac0aa0bc429285cb1d5590e590a91b87f230 [file] [log] [blame]
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
// https://developers.google.com/protocol-buffers/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Author: kenton@google.com (Kenton Varda)
// Based on original Protocol Buffers design by
// Sanjay Ghemawat, Jeff Dean, and others.
#include <google/protobuf/stubs/hash.h>
#include <limits>
#include <map>
#include <queue>
#include <vector>
#include <google/protobuf/stubs/logging.h>
#include <google/protobuf/stubs/common.h>
#include <google/protobuf/compiler/cpp/cpp_helpers.h>
#include <google/protobuf/io/printer.h>
#include <google/protobuf/io/zero_copy_stream.h>
#include <google/protobuf/stubs/strutil.h>
#include <google/protobuf/stubs/substitute.h>
namespace google {
namespace protobuf {
namespace compiler {
namespace cpp {
namespace {
static const char kAnyMessageName[] = "Any";
static const char kAnyProtoFile[] = "google/protobuf/any.proto";
static const char kGoogleProtobufPrefix[] = "google/protobuf/";
string DotsToUnderscores(const string& name) {
return StringReplace(name, ".", "_", true);
}
string DotsToColons(const string& name) {
return StringReplace(name, ".", "::", true);
}
const char* const kKeywordList[] = {
"alignas", "alignof", "and", "and_eq", "asm", "auto", "bitand", "bitor",
"bool", "break", "case", "catch", "char", "class", "compl", "const",
"constexpr", "const_cast", "continue", "decltype", "default", "delete", "do",
"double", "dynamic_cast", "else", "enum", "explicit", "export", "extern",
"false", "float", "for", "friend", "goto", "if", "inline", "int", "long",
"mutable", "namespace", "new", "noexcept", "not", "not_eq", "nullptr",
"operator", "or", "or_eq", "private", "protected", "public", "register",
"reinterpret_cast", "return", "short", "signed", "sizeof", "static",
"static_assert", "static_cast", "struct", "switch", "template", "this",
"thread_local", "throw", "true", "try", "typedef", "typeid", "typename",
"union", "unsigned", "using", "virtual", "void", "volatile", "wchar_t",
"while", "xor", "xor_eq"
};
hash_set<string> MakeKeywordsMap() {
hash_set<string> result;
for (int i = 0; i < GOOGLE_ARRAYSIZE(kKeywordList); i++) {
result.insert(kKeywordList[i]);
}
return result;
}
hash_set<string> kKeywords = MakeKeywordsMap();
// Returns whether the provided descriptor has an extension. This includes its
// nested types.
bool HasExtension(const Descriptor* descriptor) {
if (descriptor->extension_count() > 0) {
return true;
}
for (int i = 0; i < descriptor->nested_type_count(); ++i) {
if (HasExtension(descriptor->nested_type(i))) {
return true;
}
}
return false;
}
// Encode [0..63] as 'A'-'Z', 'a'-'z', '0'-'9', '_'
char Base63Char(int value) {
GOOGLE_CHECK_GE(value, 0);
if (value < 26) return 'A' + value;
value -= 26;
if (value < 26) return 'a' + value;
value -= 26;
if (value < 10) return '0' + value;
GOOGLE_CHECK_EQ(value, 10);
return '_';
}
// Given a c identifier has 63 legal characters we can't implement base64
// encoding. So we return the k least significant "digits" in base 63.
template <typename I>
string Base63(I n, int k) {
string res;
while (k-- > 0) {
res += Base63Char(static_cast<int>(n % 63));
n /= 63;
}
return res;
}
} // namespace
string UnderscoresToCamelCase(const string& input, bool cap_next_letter) {
string result;
// Note: I distrust ctype.h due to locales.
for (int i = 0; i < input.size(); i++) {
if ('a' <= input[i] && input[i] <= 'z') {
if (cap_next_letter) {
result += input[i] + ('A' - 'a');
} else {
result += input[i];
}
cap_next_letter = false;
} else if ('A' <= input[i] && input[i] <= 'Z') {
// Capital letters are left as-is.
result += input[i];
cap_next_letter = false;
} else if ('0' <= input[i] && input[i] <= '9') {
result += input[i];
cap_next_letter = true;
} else {
cap_next_letter = true;
}
}
return result;
}
const char kThickSeparator[] =
"// ===================================================================\n";
const char kThinSeparator[] =
"// -------------------------------------------------------------------\n";
bool CanInitializeByZeroing(const FieldDescriptor* field) {
if (field->is_repeated() || field->is_extension()) return false;
switch (field->cpp_type()) {
case FieldDescriptor::CPPTYPE_ENUM:
return field->default_value_enum()->number() == 0;
case FieldDescriptor::CPPTYPE_INT32:
return field->default_value_int32() == 0;
case FieldDescriptor::CPPTYPE_INT64:
return field->default_value_int64() == 0;
case FieldDescriptor::CPPTYPE_UINT32:
return field->default_value_uint32() == 0;
case FieldDescriptor::CPPTYPE_UINT64:
return field->default_value_uint64() == 0;
case FieldDescriptor::CPPTYPE_FLOAT:
return field->default_value_float() == 0;
case FieldDescriptor::CPPTYPE_DOUBLE:
return field->default_value_double() == 0;
case FieldDescriptor::CPPTYPE_BOOL:
return field->default_value_bool() == false;
default:
return false;
}
}
string ClassName(const Descriptor* descriptor) {
const Descriptor* parent = descriptor->containing_type();
string res;
if (parent) res += ClassName(parent) + "_";
res += descriptor->name();
if (IsMapEntryMessage(descriptor)) res += "_DoNotUse";
return res;
}
string ClassName(const EnumDescriptor* enum_descriptor) {
if (enum_descriptor->containing_type() == NULL) {
return enum_descriptor->name();
} else {
return ClassName(enum_descriptor->containing_type()) + "_" +
enum_descriptor->name();
}
}
string Namespace(const string& package) {
if (package.empty()) return "";
return "::" + DotsToColons(package);
}
string DefaultInstanceName(const Descriptor* descriptor) {
string prefix = descriptor->file()->package().empty() ? "" : "::";
return prefix + DotsToColons(descriptor->file()->package()) + "::_" +
ClassName(descriptor, false) + "_default_instance_";
}
string ReferenceFunctionName(const Descriptor* descriptor) {
return QualifiedClassName(descriptor) + "_ReferenceStrong";
}
string SuperClassName(const Descriptor* descriptor, const Options& options) {
return HasDescriptorMethods(descriptor->file(), options)
? "::google::protobuf::Message"
: "::google::protobuf::MessageLite";
}
string FieldName(const FieldDescriptor* field) {
string result = field->name();
LowerString(&result);
if (kKeywords.count(result) > 0) {
result.append("_");
}
return result;
}
string EnumValueName(const EnumValueDescriptor* enum_value) {
string result = enum_value->name();
if (kKeywords.count(result) > 0) {
result.append("_");
}
return result;
}
int EstimateAlignmentSize(const FieldDescriptor* field) {
if (field == NULL) return 0;
if (field->is_repeated()) return 8;
switch (field->cpp_type()) {
case FieldDescriptor::CPPTYPE_BOOL:
return 1;
case FieldDescriptor::CPPTYPE_INT32:
case FieldDescriptor::CPPTYPE_UINT32:
case FieldDescriptor::CPPTYPE_ENUM:
case FieldDescriptor::CPPTYPE_FLOAT:
return 4;
case FieldDescriptor::CPPTYPE_INT64:
case FieldDescriptor::CPPTYPE_UINT64:
case FieldDescriptor::CPPTYPE_DOUBLE:
case FieldDescriptor::CPPTYPE_STRING:
case FieldDescriptor::CPPTYPE_MESSAGE:
return 8;
}
GOOGLE_LOG(FATAL) << "Can't get here.";
return -1; // Make compiler happy.
}
string FieldConstantName(const FieldDescriptor *field) {
string field_name = UnderscoresToCamelCase(field->name(), true);
string result = "k" + field_name + "FieldNumber";
if (!field->is_extension() &&
field->containing_type()->FindFieldByCamelcaseName(
field->camelcase_name()) != field) {
// This field's camelcase name is not unique. As a hack, add the field
// number to the constant name. This makes the constant rather useless,
// but what can we do?
result += "_" + SimpleItoa(field->number());
}
return result;
}
string FieldMessageTypeName(const FieldDescriptor* field) {
// Note: The Google-internal version of Protocol Buffers uses this function
// as a hook point for hacks to support legacy code.
return ClassName(field->message_type(), true);
}
string StripProto(const string& filename) {
if (HasSuffixString(filename, ".protodevel")) {
return StripSuffixString(filename, ".protodevel");
} else {
return StripSuffixString(filename, ".proto");
}
}
const char* PrimitiveTypeName(FieldDescriptor::CppType type) {
switch (type) {
case FieldDescriptor::CPPTYPE_INT32 : return "::google::protobuf::int32";
case FieldDescriptor::CPPTYPE_INT64 : return "::google::protobuf::int64";
case FieldDescriptor::CPPTYPE_UINT32 : return "::google::protobuf::uint32";
case FieldDescriptor::CPPTYPE_UINT64 : return "::google::protobuf::uint64";
case FieldDescriptor::CPPTYPE_DOUBLE : return "double";
case FieldDescriptor::CPPTYPE_FLOAT : return "float";
case FieldDescriptor::CPPTYPE_BOOL : return "bool";
case FieldDescriptor::CPPTYPE_ENUM : return "int";
case FieldDescriptor::CPPTYPE_STRING : return "::std::string";
case FieldDescriptor::CPPTYPE_MESSAGE: return NULL;
// No default because we want the compiler to complain if any new
// CppTypes are added.
}
GOOGLE_LOG(FATAL) << "Can't get here.";
return NULL;
}
const char* DeclaredTypeMethodName(FieldDescriptor::Type type) {
switch (type) {
case FieldDescriptor::TYPE_INT32 : return "Int32";
case FieldDescriptor::TYPE_INT64 : return "Int64";
case FieldDescriptor::TYPE_UINT32 : return "UInt32";
case FieldDescriptor::TYPE_UINT64 : return "UInt64";
case FieldDescriptor::TYPE_SINT32 : return "SInt32";
case FieldDescriptor::TYPE_SINT64 : return "SInt64";
case FieldDescriptor::TYPE_FIXED32 : return "Fixed32";
case FieldDescriptor::TYPE_FIXED64 : return "Fixed64";
case FieldDescriptor::TYPE_SFIXED32: return "SFixed32";
case FieldDescriptor::TYPE_SFIXED64: return "SFixed64";
case FieldDescriptor::TYPE_FLOAT : return "Float";
case FieldDescriptor::TYPE_DOUBLE : return "Double";
case FieldDescriptor::TYPE_BOOL : return "Bool";
case FieldDescriptor::TYPE_ENUM : return "Enum";
case FieldDescriptor::TYPE_STRING : return "String";
case FieldDescriptor::TYPE_BYTES : return "Bytes";
case FieldDescriptor::TYPE_GROUP : return "Group";
case FieldDescriptor::TYPE_MESSAGE : return "Message";
// No default because we want the compiler to complain if any new
// types are added.
}
GOOGLE_LOG(FATAL) << "Can't get here.";
return "";
}
string Int32ToString(int number) {
// gcc rejects the decimal form of kint32min.
if (number == kint32min) {
GOOGLE_COMPILE_ASSERT(kint32min == (~0x7fffffff), kint32min_value_error);
return "(~0x7fffffff)";
} else {
return SimpleItoa(number);
}
}
string Int64ToString(int64 number) {
// gcc rejects the decimal form of kint64min
if (number == kint64min) {
// Make sure we are in a 2's complement system.
GOOGLE_COMPILE_ASSERT(kint64min == GOOGLE_LONGLONG(~0x7fffffffffffffff),
kint64min_value_error);
return "GOOGLE_LONGLONG(~0x7fffffffffffffff)";
}
return "GOOGLE_LONGLONG(" + SimpleItoa(number) + ")";
}
string DefaultValue(const FieldDescriptor* field) {
switch (field->cpp_type()) {
case FieldDescriptor::CPPTYPE_INT32:
return Int32ToString(field->default_value_int32());
case FieldDescriptor::CPPTYPE_UINT32:
return SimpleItoa(field->default_value_uint32()) + "u";
case FieldDescriptor::CPPTYPE_INT64:
return Int64ToString(field->default_value_int64());
case FieldDescriptor::CPPTYPE_UINT64:
return "GOOGLE_ULONGLONG(" + SimpleItoa(field->default_value_uint64())+ ")";
case FieldDescriptor::CPPTYPE_DOUBLE: {
double value = field->default_value_double();
if (value == std::numeric_limits<double>::infinity()) {
return "::google::protobuf::internal::Infinity()";
} else if (value == -std::numeric_limits<double>::infinity()) {
return "-::google::protobuf::internal::Infinity()";
} else if (value != value) {
return "::google::protobuf::internal::NaN()";
} else {
return SimpleDtoa(value);
}
}
case FieldDescriptor::CPPTYPE_FLOAT:
{
float value = field->default_value_float();
if (value == std::numeric_limits<float>::infinity()) {
return "static_cast<float>(::google::protobuf::internal::Infinity())";
} else if (value == -std::numeric_limits<float>::infinity()) {
return "static_cast<float>(-::google::protobuf::internal::Infinity())";
} else if (value != value) {
return "static_cast<float>(::google::protobuf::internal::NaN())";
} else {
string float_value = SimpleFtoa(value);
// If floating point value contains a period (.) or an exponent
// (either E or e), then append suffix 'f' to make it a float
// literal.
if (float_value.find_first_of(".eE") != string::npos) {
float_value.push_back('f');
}
return float_value;
}
}
case FieldDescriptor::CPPTYPE_BOOL:
return field->default_value_bool() ? "true" : "false";
case FieldDescriptor::CPPTYPE_ENUM:
// Lazy: Generate a static_cast because we don't have a helper function
// that constructs the full name of an enum value.
return strings::Substitute(
"static_cast< $0 >($1)",
ClassName(field->enum_type(), true),
Int32ToString(field->default_value_enum()->number()));
case FieldDescriptor::CPPTYPE_STRING:
return "\"" + EscapeTrigraphs(
CEscape(field->default_value_string())) +
"\"";
case FieldDescriptor::CPPTYPE_MESSAGE:
return "*" + FieldMessageTypeName(field) +
"::internal_default_instance()";
}
// Can't actually get here; make compiler happy. (We could add a default
// case above but then we wouldn't get the nice compiler warning when a
// new type is added.)
GOOGLE_LOG(FATAL) << "Can't get here.";
return "";
}
// Convert a file name into a valid identifier.
string FilenameIdentifier(const string& filename) {
string result;
for (int i = 0; i < filename.size(); i++) {
if (ascii_isalnum(filename[i])) {
result.push_back(filename[i]);
} else {
// Not alphanumeric. To avoid any possibility of name conflicts we
// use the hex code for the character.
StrAppend(&result, "_", strings::Hex(static_cast<uint8>(filename[i])));
}
}
return result;
}
string FileLevelNamespace(const string& filename) {
return "protobuf_" + FilenameIdentifier(filename);
}
// Return the qualified C++ name for a file level symbol.
string QualifiedFileLevelSymbol(const string& package, const string& name) {
if (package.empty()) {
return StrCat("::", name);
}
return StrCat("::", DotsToColons(package), "::", name);
}
// Escape C++ trigraphs by escaping question marks to \?
string EscapeTrigraphs(const string& to_escape) {
return StringReplace(to_escape, "?", "\\?", true);
}
// Escaped function name to eliminate naming conflict.
string SafeFunctionName(const Descriptor* descriptor,
const FieldDescriptor* field,
const string& prefix) {
// Do not use FieldName() since it will escape keywords.
string name = field->name();
LowerString(&name);
string function_name = prefix + name;
if (descriptor->FindFieldByName(function_name)) {
// Single underscore will also make it conflicting with the private data
// member. We use double underscore to escape function names.
function_name.append("__");
} else if (kKeywords.count(name) > 0) {
// If the field name is a keyword, we append the underscore back to keep it
// consistent with other function names.
function_name.append("_");
}
return function_name;
}
static bool HasMapFields(const Descriptor* descriptor) {
for (int i = 0; i < descriptor->field_count(); ++i) {
if (descriptor->field(i)->is_map()) {
return true;
}
}
for (int i = 0; i < descriptor->nested_type_count(); ++i) {
if (HasMapFields(descriptor->nested_type(i))) return true;
}
return false;
}
bool HasMapFields(const FileDescriptor* file) {
for (int i = 0; i < file->message_type_count(); ++i) {
if (HasMapFields(file->message_type(i))) return true;
}
return false;
}
static bool HasEnumDefinitions(const Descriptor* message_type) {
if (message_type->enum_type_count() > 0) return true;
for (int i = 0; i < message_type->nested_type_count(); ++i) {
if (HasEnumDefinitions(message_type->nested_type(i))) return true;
}
return false;
}
bool HasEnumDefinitions(const FileDescriptor* file) {
if (file->enum_type_count() > 0) return true;
for (int i = 0; i < file->message_type_count(); ++i) {
if (HasEnumDefinitions(file->message_type(i))) return true;
}
return false;
}
bool IsStringOrMessage(const FieldDescriptor* field) {
switch (field->cpp_type()) {
case FieldDescriptor::CPPTYPE_INT32:
case FieldDescriptor::CPPTYPE_INT64:
case FieldDescriptor::CPPTYPE_UINT32:
case FieldDescriptor::CPPTYPE_UINT64:
case FieldDescriptor::CPPTYPE_DOUBLE:
case FieldDescriptor::CPPTYPE_FLOAT:
case FieldDescriptor::CPPTYPE_BOOL:
case FieldDescriptor::CPPTYPE_ENUM:
return false;
case FieldDescriptor::CPPTYPE_STRING:
case FieldDescriptor::CPPTYPE_MESSAGE:
return true;
}
GOOGLE_LOG(FATAL) << "Can't get here.";
return false;
}
FieldOptions::CType EffectiveStringCType(const FieldDescriptor* field) {
GOOGLE_DCHECK(field->cpp_type() == FieldDescriptor::CPPTYPE_STRING);
// Open-source protobuf release only supports STRING ctype.
return FieldOptions::STRING;
}
bool IsAnyMessage(const FileDescriptor* descriptor) {
return descriptor->name() == kAnyProtoFile;
}
bool IsAnyMessage(const Descriptor* descriptor) {
return descriptor->name() == kAnyMessageName &&
descriptor->file()->name() == kAnyProtoFile;
}
bool IsWellKnownMessage(const FileDescriptor* descriptor) {
return !descriptor->name().compare(0, 16, kGoogleProtobufPrefix);
}
enum Utf8CheckMode {
STRICT = 0, // Parsing will fail if non UTF-8 data is in string fields.
VERIFY = 1, // Only log an error but parsing will succeed.
NONE = 2, // No UTF-8 check.
};
// Which level of UTF-8 enforcemant is placed on this file.
static Utf8CheckMode GetUtf8CheckMode(const FieldDescriptor* field,
const Options& options) {
if (field->file()->syntax() == FileDescriptor::SYNTAX_PROTO3) {
return STRICT;
} else if (GetOptimizeFor(field->file(), options) !=
FileOptions::LITE_RUNTIME) {
return VERIFY;
} else {
return NONE;
}
}
static void GenerateUtf8CheckCode(const FieldDescriptor* field,
const Options& options, bool for_parse,
const std::map<string, string>& variables,
const char* parameters,
const char* strict_function,
const char* verify_function,
io::Printer* printer) {
switch (GetUtf8CheckMode(field, options)) {
case STRICT: {
if (for_parse) {
printer->Print("DO_(");
}
printer->Print(
"::google::protobuf::internal::WireFormatLite::$function$(\n",
"function", strict_function);
printer->Indent();
printer->Print(variables, parameters);
if (for_parse) {
printer->Print("::google::protobuf::internal::WireFormatLite::PARSE,\n");
} else {
printer->Print("::google::protobuf::internal::WireFormatLite::SERIALIZE,\n");
}
printer->Print("\"$full_name$\")", "full_name", field->full_name());
if (for_parse) {
printer->Print(")");
}
printer->Print(";\n");
printer->Outdent();
break;
}
case VERIFY: {
printer->Print(
"::google::protobuf::internal::WireFormat::$function$(\n",
"function", verify_function);
printer->Indent();
printer->Print(variables, parameters);
if (for_parse) {
printer->Print("::google::protobuf::internal::WireFormat::PARSE,\n");
} else {
printer->Print("::google::protobuf::internal::WireFormat::SERIALIZE,\n");
}
printer->Print("\"$full_name$\");\n", "full_name", field->full_name());
printer->Outdent();
break;
}
case NONE:
break;
}
}
void GenerateUtf8CheckCodeForString(const FieldDescriptor* field,
const Options& options, bool for_parse,
const std::map<string, string>& variables,
const char* parameters,
io::Printer* printer) {
GenerateUtf8CheckCode(field, options, for_parse, variables, parameters,
"VerifyUtf8String", "VerifyUTF8StringNamedField",
printer);
}
void GenerateUtf8CheckCodeForCord(const FieldDescriptor* field,
const Options& options, bool for_parse,
const std::map<string, string>& variables,
const char* parameters,
io::Printer* printer) {
GenerateUtf8CheckCode(field, options, for_parse, variables, parameters,
"VerifyUtf8Cord", "VerifyUTF8CordNamedField", printer);
}
namespace {
void Flatten(const Descriptor* descriptor,
std::vector<const Descriptor*>* flatten) {
for (int i = 0; i < descriptor->nested_type_count(); i++)
Flatten(descriptor->nested_type(i), flatten);
flatten->push_back(descriptor);
}
} // namespace
void FlattenMessagesInFile(const FileDescriptor* file,
std::vector<const Descriptor*>* result) {
for (int i = 0; i < file->message_type_count(); i++) {
Flatten(file->message_type(i), result);
}
}
bool HasWeakFields(const Descriptor* descriptor) {
return false;
}
bool HasWeakFields(const FileDescriptor* file) {
return false;
}
bool UsingImplicitWeakFields(const FileDescriptor* file,
const Options& options) {
return options.lite_implicit_weak_fields &&
GetOptimizeFor(file, options) == FileOptions::LITE_RUNTIME;
}
bool IsImplicitWeakField(const FieldDescriptor* field, const Options& options,
SCCAnalyzer* scc_analyzer) {
return UsingImplicitWeakFields(field->file(), options) &&
field->type() == FieldDescriptor::TYPE_MESSAGE &&
!field->is_required() && !field->is_map() &&
field->containing_oneof() == NULL &&
!IsWellKnownMessage(field->message_type()->file()) &&
// We do not support implicit weak fields between messages in the same
// strongly-connected component.
scc_analyzer->GetSCC(field->containing_type()) !=
scc_analyzer->GetSCC(field->message_type());
}
struct CompareDescriptors {
bool operator()(const Descriptor* a, const Descriptor* b) {
return a->full_name() < b->full_name();
}
};
SCCAnalyzer::NodeData SCCAnalyzer::DFS(const Descriptor* descriptor) {
// Must not have visited already.
GOOGLE_DCHECK_EQ(cache_.count(descriptor), 0);
// Mark visited by inserting in map.
NodeData& result = cache_[descriptor];
// Initialize data structures.
result.index = result.lowlink = index_++;
stack_.push_back(descriptor);
// Recurse the fields / nodes in graph
for (int i = 0; i < descriptor->field_count(); i++) {
const Descriptor* child = descriptor->field(i)->message_type();
if (child) {
if (cache_.count(child) == 0) {
// unexplored node
NodeData child_data = DFS(child);
result.lowlink = std::min(result.lowlink, child_data.lowlink);
} else {
NodeData child_data = cache_[child];
if (child_data.scc == NULL) {
// Still in the stack_ so we found a back edge
result.lowlink = std::min(result.lowlink, child_data.index);
}
}
}
}
if (result.index == result.lowlink) {
// This is the root of a strongly connected component
SCC* scc = CreateSCC();
while (true) {
const Descriptor* scc_desc = stack_.back();
scc->descriptors.push_back(scc_desc);
// Remove from stack
stack_.pop_back();
cache_[scc_desc].scc = scc;
if (scc_desc == descriptor) break;
}
// The order of descriptors is random and depends how this SCC was
// discovered. In-order to ensure maximum stability we sort it by name.
std::sort(scc->descriptors.begin(), scc->descriptors.end(),
CompareDescriptors());
AddChildren(scc);
}
return result;
}
void SCCAnalyzer::AddChildren(SCC* scc) {
std::set<const SCC*> seen;
for (int i = 0; i < scc->descriptors.size(); i++) {
const Descriptor* descriptor = scc->descriptors[i];
for (int j = 0; j < descriptor->field_count(); j++) {
const Descriptor* child_msg = descriptor->field(j)->message_type();
if (child_msg) {
const SCC* child = GetSCC(child_msg);
if (child == scc) continue;
if (seen.insert(child).second) {
scc->children.push_back(child);
}
}
}
}
}
MessageAnalysis SCCAnalyzer::GetSCCAnalysis(const SCC* scc) {
if (analysis_cache_.count(scc)) return analysis_cache_[scc];
MessageAnalysis result = MessageAnalysis();
for (int i = 0; i < scc->descriptors.size(); i++) {
const Descriptor* descriptor = scc->descriptors[i];
if (descriptor->extension_range_count() > 0) {
result.contains_extension = true;
}
for (int i = 0; i < descriptor->field_count(); i++) {
const FieldDescriptor* field = descriptor->field(i);
if (field->is_required()) {
result.contains_required = true;
}
switch (field->type()) {
case FieldDescriptor::TYPE_STRING:
case FieldDescriptor::TYPE_BYTES: {
if (field->options().ctype() == FieldOptions::CORD) {
result.contains_cord = true;
}
break;
}
case FieldDescriptor::TYPE_GROUP:
case FieldDescriptor::TYPE_MESSAGE: {
const SCC* child = GetSCC(field->message_type());
if (child != scc) {
MessageAnalysis analysis = GetSCCAnalysis(child);
result.contains_cord |= analysis.contains_cord;
result.contains_extension |= analysis.contains_extension;
if (!ShouldIgnoreRequiredFieldCheck(field, options_)) {
result.contains_required |= analysis.contains_required;
}
} else {
// This field points back into the same SCC hence the messages
// in the SCC are recursive. Note if SCC contains more than two
// nodes it has to be recursive, however this test also works for
// a single node that is recursive.
result.is_recursive = true;
}
break;
}
default:
break;
}
}
}
// We deliberately only insert the result here. After we contracted the SCC
// in the graph, the graph should be a DAG. Hence we shouldn't need to mark
// nodes visited as we can never return to them. By inserting them here
// we will go in an infinite loop if the SCC is not correct.
return analysis_cache_[scc] = result;
}
void ListAllFields(const Descriptor* d,
std::vector<const FieldDescriptor*>* fields) {
// Collect sub messages
for (int i = 0; i < d->nested_type_count(); i++) {
ListAllFields(d->nested_type(i), fields);
}
// Collect message level extensions.
for (int i = 0; i < d->extension_count(); i++) {
fields->push_back(d->extension(i));
}
// Add types of fields necessary
for (int i = 0; i < d->field_count(); i++) {
fields->push_back(d->field(i));
}
}
void ListAllFields(const FileDescriptor* d,
std::vector<const FieldDescriptor*>* fields) {
// Collect file level message.
for (int i = 0; i < d->message_type_count(); i++) {
ListAllFields(d->message_type(i), fields);
}
// Collect message level extensions.
for (int i = 0; i < d->extension_count(); i++) {
fields->push_back(d->extension(i));
}
}
void ListAllTypesForServices(const FileDescriptor* fd,
std::vector<const Descriptor*>* types) {
for (int i = 0; i < fd->service_count(); i++) {
const ServiceDescriptor* sd = fd->service(i);
for (int j = 0; j < sd->method_count(); j++) {
const MethodDescriptor* method = sd->method(j);
types->push_back(method->input_type());
types->push_back(method->output_type());
}
}
}
} // namespace cpp
} // namespace compiler
} // namespace protobuf
} // namespace google