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+// 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: jschorr@google.com (Joseph Schorr)
+// Based on original Protocol Buffers design by
+// Sanjay Ghemawat, Jeff Dean, and others.
+
+#include <util/message_differencer.h>
+
+#include <algorithm>
+#include <cstddef>
+#include <cstdint>
+#include <functional>
+#include <limits>
+#include <memory>
+#include <utility>
+
+#include <stubs/logging.h>
+#include <stubs/common.h>
+#include <stubs/stringprintf.h>
+#include <io/printer.h>
+#include <io/zero_copy_stream.h>
+#include <io/zero_copy_stream_impl.h>
+#include <descriptor.pb.h>
+#include <descriptor.h>
+#include <dynamic_message.h>
+#include <generated_enum_reflection.h>
+#include <map_field.h>
+#include <message.h>
+#include <text_format.h>
+#include <util/field_comparator.h>
+#include <stubs/strutil.h>
+
+// Always include as last one, otherwise it can break compilation
+#include <port_def.inc>
+
+namespace google {
+namespace protobuf {
+
+namespace util {
+
+// A reporter to report the total number of diffs.
+// TODO(ykzhu): we can improve this to take into account the value differencers.
+class NumDiffsReporter : public google::protobuf::util::MessageDifferencer::Reporter {
+ public:
+ NumDiffsReporter() : num_diffs_(0) {}
+
+ // Returns the total number of diffs.
+ int32_t GetNumDiffs() const { return num_diffs_; }
+ void Reset() { num_diffs_ = 0; }
+
+ // Report that a field has been added into Message2.
+ void ReportAdded(
+ const google::protobuf::Message& /* message1 */,
+ const google::protobuf::Message& /* message2 */,
+ const std::vector<google::protobuf::util::MessageDifferencer::SpecificField>&
+ /*field_path*/) override {
+ ++num_diffs_;
+ }
+
+ // Report that a field has been deleted from Message1.
+ void ReportDeleted(
+ const google::protobuf::Message& /* message1 */,
+ const google::protobuf::Message& /* message2 */,
+ const std::vector<google::protobuf::util::MessageDifferencer::SpecificField>&
+ /*field_path*/) override {
+ ++num_diffs_;
+ }
+
+ // Report that the value of a field has been modified.
+ void ReportModified(
+ const google::protobuf::Message& /* message1 */,
+ const google::protobuf::Message& /* message2 */,
+ const std::vector<google::protobuf::util::MessageDifferencer::SpecificField>&
+ /*field_path*/) override {
+ ++num_diffs_;
+ }
+
+ private:
+ int32_t num_diffs_;
+};
+
+// When comparing a repeated field as map, MultipleFieldMapKeyComparator can
+// be used to specify multiple fields as key for key comparison.
+// Two elements of a repeated field will be regarded as having the same key
+// iff they have the same value for every specified key field.
+// Note that you can also specify only one field as key.
+class MessageDifferencer::MultipleFieldsMapKeyComparator
+ : public MessageDifferencer::MapKeyComparator {
+ public:
+ MultipleFieldsMapKeyComparator(
+ MessageDifferencer* message_differencer,
+ const std::vector<std::vector<const FieldDescriptor*> >& key_field_paths)
+ : message_differencer_(message_differencer),
+ key_field_paths_(key_field_paths) {
+ GOOGLE_CHECK(!key_field_paths_.empty());
+ for (const auto& path : key_field_paths_) {
+ GOOGLE_CHECK(!path.empty());
+ }
+ }
+ MultipleFieldsMapKeyComparator(MessageDifferencer* message_differencer,
+ const FieldDescriptor* key)
+ : message_differencer_(message_differencer) {
+ std::vector<const FieldDescriptor*> key_field_path;
+ key_field_path.push_back(key);
+ key_field_paths_.push_back(key_field_path);
+ }
+ bool IsMatch(const Message& message1, const Message& message2,
+ const std::vector<SpecificField>& parent_fields) const override {
+ for (const auto& path : key_field_paths_) {
+ if (!IsMatchInternal(message1, message2, parent_fields, path, 0)) {
+ return false;
+ }
+ }
+ return true;
+ }
+
+ private:
+ bool IsMatchInternal(
+ const Message& message1, const Message& message2,
+ const std::vector<SpecificField>& parent_fields,
+ const std::vector<const FieldDescriptor*>& key_field_path,
+ int path_index) const {
+ const FieldDescriptor* field = key_field_path[path_index];
+ std::vector<SpecificField> current_parent_fields(parent_fields);
+ if (path_index == static_cast<int64_t>(key_field_path.size() - 1)) {
+ if (field->is_map()) {
+ return message_differencer_->CompareMapField(message1, message2, field,
+ &current_parent_fields);
+ } else if (field->is_repeated()) {
+ return message_differencer_->CompareRepeatedField(
+ message1, message2, field, &current_parent_fields);
+ } else {
+ return message_differencer_->CompareFieldValueUsingParentFields(
+ message1, message2, field, -1, -1, &current_parent_fields);
+ }
+ } else {
+ const Reflection* reflection1 = message1.GetReflection();
+ const Reflection* reflection2 = message2.GetReflection();
+ bool has_field1 = reflection1->HasField(message1, field);
+ bool has_field2 = reflection2->HasField(message2, field);
+ if (!has_field1 && !has_field2) {
+ return true;
+ }
+ if (has_field1 != has_field2) {
+ return false;
+ }
+ SpecificField specific_field;
+ specific_field.field = field;
+ current_parent_fields.push_back(specific_field);
+ return IsMatchInternal(reflection1->GetMessage(message1, field),
+ reflection2->GetMessage(message2, field),
+ current_parent_fields, key_field_path,
+ path_index + 1);
+ }
+ }
+ MessageDifferencer* message_differencer_;
+ std::vector<std::vector<const FieldDescriptor*> > key_field_paths_;
+ GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(MultipleFieldsMapKeyComparator);
+};
+
+// Preserve the order when treating repeated field as SMART_LIST. The current
+// implementation is to find the longest matching sequence from the first
+// element. The optimal solution requires to use //util/diff/lcs.h, which is
+// not open sourced yet. Overwrite this method if you want to have that.
+// TODO(ykzhu): change to use LCS once it is open sourced.
+void MatchIndicesPostProcessorForSmartList(std::vector<int>* match_list1,
+ std::vector<int>* match_list2) {
+ int last_matched_index = -1;
+ for (size_t i = 0; i < match_list1->size(); ++i) {
+ if (match_list1->at(i) < 0) {
+ continue;
+ }
+ if (last_matched_index < 0 || match_list1->at(i) > last_matched_index) {
+ last_matched_index = match_list1->at(i);
+ } else {
+ match_list2->at(match_list1->at(i)) = -1;
+ match_list1->at(i) = -1;
+ }
+ }
+}
+
+void AddSpecificIndex(
+ google::protobuf::util::MessageDifferencer::SpecificField* specific_field,
+ const Message& message, const FieldDescriptor* field, int index) {
+ if (field->is_map()) {
+ const Reflection* reflection = message.GetReflection();
+ specific_field->map_entry1 =
+ &reflection->GetRepeatedMessage(message, field, index);
+ }
+ specific_field->index = index;
+}
+
+void AddSpecificNewIndex(
+ google::protobuf::util::MessageDifferencer::SpecificField* specific_field,
+ const Message& message, const FieldDescriptor* field, int index) {
+ if (field->is_map()) {
+ const Reflection* reflection = message.GetReflection();
+ specific_field->map_entry2 =
+ &reflection->GetRepeatedMessage(message, field, index);
+ }
+ specific_field->new_index = index;
+}
+
+MessageDifferencer::MapEntryKeyComparator::MapEntryKeyComparator(
+ MessageDifferencer* message_differencer)
+ : message_differencer_(message_differencer) {}
+
+bool MessageDifferencer::MapEntryKeyComparator::IsMatch(
+ const Message& message1, const Message& message2,
+ const std::vector<SpecificField>& parent_fields) const {
+ // Map entry has its key in the field with tag 1. See the comment for
+ // map_entry in MessageOptions.
+ const FieldDescriptor* key = message1.GetDescriptor()->FindFieldByNumber(1);
+ // If key is not present in message1 and we're doing partial comparison or if
+ // map key is explicitly ignored treat the field as set instead,
+ const bool treat_as_set =
+ (message_differencer_->scope() == PARTIAL &&
+ !message1.GetReflection()->HasField(message1, key)) ||
+ message_differencer_->IsIgnored(message1, message2, key, parent_fields);
+
+ std::vector<SpecificField> current_parent_fields(parent_fields);
+ if (treat_as_set) {
+ return message_differencer_->Compare(message1, message2,
+ &current_parent_fields);
+ }
+ return message_differencer_->CompareFieldValueUsingParentFields(
+ message1, message2, key, -1, -1, &current_parent_fields);
+}
+
+bool MessageDifferencer::Equals(const Message& message1,
+ const Message& message2) {
+ MessageDifferencer differencer;
+
+ return differencer.Compare(message1, message2);
+}
+
+bool MessageDifferencer::Equivalent(const Message& message1,
+ const Message& message2) {
+ MessageDifferencer differencer;
+ differencer.set_message_field_comparison(MessageDifferencer::EQUIVALENT);
+
+ return differencer.Compare(message1, message2);
+}
+
+bool MessageDifferencer::ApproximatelyEquals(const Message& message1,
+ const Message& message2) {
+ MessageDifferencer differencer;
+ differencer.set_float_comparison(MessageDifferencer::APPROXIMATE);
+
+ return differencer.Compare(message1, message2);
+}
+
+bool MessageDifferencer::ApproximatelyEquivalent(const Message& message1,
+ const Message& message2) {
+ MessageDifferencer differencer;
+ differencer.set_message_field_comparison(MessageDifferencer::EQUIVALENT);
+ differencer.set_float_comparison(MessageDifferencer::APPROXIMATE);
+
+ return differencer.Compare(message1, message2);
+}
+
+// ===========================================================================
+
+MessageDifferencer::MessageDifferencer()
+ : reporter_(NULL),
+ message_field_comparison_(EQUAL),
+ scope_(FULL),
+ repeated_field_comparison_(AS_LIST),
+ map_entry_key_comparator_(this),
+ report_matches_(false),
+ report_moves_(true),
+ report_ignores_(true),
+ output_string_(nullptr),
+ match_indices_for_smart_list_callback_(
+ MatchIndicesPostProcessorForSmartList) {}
+
+MessageDifferencer::~MessageDifferencer() {
+ for (MapKeyComparator* comparator : owned_key_comparators_) {
+ delete comparator;
+ }
+ for (IgnoreCriteria* criteria : ignore_criteria_) {
+ delete criteria;
+ }
+}
+
+void MessageDifferencer::set_field_comparator(FieldComparator* comparator) {
+ GOOGLE_CHECK(comparator) << "Field comparator can't be NULL.";
+ field_comparator_kind_ = kFCBase;
+ field_comparator_.base = comparator;
+}
+
+#ifdef PROTOBUF_FUTURE_BREAKING_CHANGES
+void MessageDifferencer::set_field_comparator(
+ DefaultFieldComparator* comparator) {
+ GOOGLE_CHECK(comparator) << "Field comparator can't be NULL.";
+ field_comparator_kind_ = kFCDefault;
+ field_comparator_.default_impl = comparator;
+}
+#endif // PROTOBUF_FUTURE_BREAKING_CHANGES
+
+void MessageDifferencer::set_message_field_comparison(
+ MessageFieldComparison comparison) {
+ message_field_comparison_ = comparison;
+}
+
+void MessageDifferencer::set_scope(Scope scope) { scope_ = scope; }
+
+MessageDifferencer::Scope MessageDifferencer::scope() { return scope_; }
+
+void MessageDifferencer::set_float_comparison(FloatComparison comparison) {
+ default_field_comparator_.set_float_comparison(
+ comparison == EXACT ? DefaultFieldComparator::EXACT
+ : DefaultFieldComparator::APPROXIMATE);
+}
+
+void MessageDifferencer::set_repeated_field_comparison(
+ RepeatedFieldComparison comparison) {
+ repeated_field_comparison_ = comparison;
+}
+
+MessageDifferencer::RepeatedFieldComparison
+MessageDifferencer::repeated_field_comparison() {
+ return repeated_field_comparison_;
+}
+
+void MessageDifferencer::CheckRepeatedFieldComparisons(
+ const FieldDescriptor* field,
+ const RepeatedFieldComparison& new_comparison) {
+ GOOGLE_CHECK(field->is_repeated())
+ << "Field must be repeated: " << field->full_name();
+ const MapKeyComparator* key_comparator = GetMapKeyComparator(field);
+ GOOGLE_CHECK(key_comparator == NULL)
+ << "Cannot treat this repeated field as both MAP and " << new_comparison
+ << " for comparison. Field name is: " << field->full_name();
+}
+
+void MessageDifferencer::TreatAsSet(const FieldDescriptor* field) {
+ CheckRepeatedFieldComparisons(field, AS_SET);
+ repeated_field_comparisons_[field] = AS_SET;
+}
+
+void MessageDifferencer::TreatAsSmartSet(const FieldDescriptor* field) {
+ CheckRepeatedFieldComparisons(field, AS_SMART_SET);
+ repeated_field_comparisons_[field] = AS_SMART_SET;
+}
+
+void MessageDifferencer::SetMatchIndicesForSmartListCallback(
+ std::function<void(std::vector<int>*, std::vector<int>*)> callback) {
+ match_indices_for_smart_list_callback_ = callback;
+}
+
+void MessageDifferencer::TreatAsList(const FieldDescriptor* field) {
+ CheckRepeatedFieldComparisons(field, AS_LIST);
+ repeated_field_comparisons_[field] = AS_LIST;
+}
+
+void MessageDifferencer::TreatAsSmartList(const FieldDescriptor* field) {
+ CheckRepeatedFieldComparisons(field, AS_SMART_LIST);
+ repeated_field_comparisons_[field] = AS_SMART_LIST;
+}
+
+void MessageDifferencer::TreatAsMap(const FieldDescriptor* field,
+ const FieldDescriptor* key) {
+ GOOGLE_CHECK_EQ(FieldDescriptor::CPPTYPE_MESSAGE, field->cpp_type())
+ << "Field has to be message type. Field name is: " << field->full_name();
+ GOOGLE_CHECK(key->containing_type() == field->message_type())
+ << key->full_name()
+ << " must be a direct subfield within the repeated field "
+ << field->full_name() << ", not " << key->containing_type()->full_name();
+ GOOGLE_CHECK(repeated_field_comparisons_.find(field) ==
+ repeated_field_comparisons_.end())
+ << "Cannot treat the same field as both "
+ << repeated_field_comparisons_[field]
+ << " and MAP. Field name is: " << field->full_name();
+ MapKeyComparator* key_comparator =
+ new MultipleFieldsMapKeyComparator(this, key);
+ owned_key_comparators_.push_back(key_comparator);
+ map_field_key_comparator_[field] = key_comparator;
+}
+
+void MessageDifferencer::TreatAsMapWithMultipleFieldsAsKey(
+ const FieldDescriptor* field,
+ const std::vector<const FieldDescriptor*>& key_fields) {
+ std::vector<std::vector<const FieldDescriptor*> > key_field_paths;
+ for (const FieldDescriptor* key_filed : key_fields) {
+ std::vector<const FieldDescriptor*> key_field_path;
+ key_field_path.push_back(key_filed);
+ key_field_paths.push_back(key_field_path);
+ }
+ TreatAsMapWithMultipleFieldPathsAsKey(field, key_field_paths);
+}
+
+void MessageDifferencer::TreatAsMapWithMultipleFieldPathsAsKey(
+ const FieldDescriptor* field,
+ const std::vector<std::vector<const FieldDescriptor*> >& key_field_paths) {
+ GOOGLE_CHECK(field->is_repeated())
+ << "Field must be repeated: " << field->full_name();
+ GOOGLE_CHECK_EQ(FieldDescriptor::CPPTYPE_MESSAGE, field->cpp_type())
+ << "Field has to be message type. Field name is: " << field->full_name();
+ for (const auto& key_field_path : key_field_paths) {
+ for (size_t j = 0; j < key_field_path.size(); ++j) {
+ const FieldDescriptor* parent_field =
+ j == 0 ? field : key_field_path[j - 1];
+ const FieldDescriptor* child_field = key_field_path[j];
+ GOOGLE_CHECK(child_field->containing_type() == parent_field->message_type())
+ << child_field->full_name()
+ << " must be a direct subfield within the field: "
+ << parent_field->full_name();
+ if (j != 0) {
+ GOOGLE_CHECK_EQ(FieldDescriptor::CPPTYPE_MESSAGE, parent_field->cpp_type())
+ << parent_field->full_name() << " has to be of type message.";
+ GOOGLE_CHECK(!parent_field->is_repeated())
+ << parent_field->full_name() << " cannot be a repeated field.";
+ }
+ }
+ }
+ GOOGLE_CHECK(repeated_field_comparisons_.find(field) ==
+ repeated_field_comparisons_.end())
+ << "Cannot treat the same field as both "
+ << repeated_field_comparisons_[field]
+ << " and MAP. Field name is: " << field->full_name();
+ MapKeyComparator* key_comparator =
+ new MultipleFieldsMapKeyComparator(this, key_field_paths);
+ owned_key_comparators_.push_back(key_comparator);
+ map_field_key_comparator_[field] = key_comparator;
+}
+
+void MessageDifferencer::TreatAsMapUsingKeyComparator(
+ const FieldDescriptor* field, const MapKeyComparator* key_comparator) {
+ GOOGLE_CHECK(field->is_repeated())
+ << "Field must be repeated: " << field->full_name();
+ GOOGLE_CHECK(repeated_field_comparisons_.find(field) ==
+ repeated_field_comparisons_.end())
+ << "Cannot treat the same field as both "
+ << repeated_field_comparisons_[field]
+ << " and MAP. Field name is: " << field->full_name();
+ map_field_key_comparator_[field] = key_comparator;
+}
+
+void MessageDifferencer::AddIgnoreCriteria(IgnoreCriteria* ignore_criteria) {
+ ignore_criteria_.push_back(ignore_criteria);
+}
+
+void MessageDifferencer::IgnoreField(const FieldDescriptor* field) {
+ ignored_fields_.insert(field);
+}
+
+void MessageDifferencer::SetFractionAndMargin(const FieldDescriptor* field,
+ double fraction, double margin) {
+ default_field_comparator_.SetFractionAndMargin(field, fraction, margin);
+}
+
+void MessageDifferencer::ReportDifferencesToString(std::string* output) {
+ GOOGLE_DCHECK(output) << "Specified output string was NULL";
+
+ output_string_ = output;
+ output_string_->clear();
+}
+
+void MessageDifferencer::ReportDifferencesTo(Reporter* reporter) {
+ // If an output string is set, clear it to prevent
+ // it superseding the specified reporter.
+ if (output_string_) {
+ output_string_ = NULL;
+ }
+
+ reporter_ = reporter;
+}
+
+bool MessageDifferencer::FieldBefore(const FieldDescriptor* field1,
+ const FieldDescriptor* field2) {
+ // Handle sentinel values (i.e. make sure NULLs are always ordered
+ // at the end of the list).
+ if (field1 == NULL) {
+ return false;
+ }
+
+ if (field2 == NULL) {
+ return true;
+ }
+
+ // Always order fields by their tag number
+ return (field1->number() < field2->number());
+}
+
+bool MessageDifferencer::Compare(const Message& message1,
+ const Message& message2) {
+ std::vector<SpecificField> parent_fields;
+
+ bool result = false;
+ // Setup the internal reporter if need be.
+ if (output_string_) {
+ io::StringOutputStream output_stream(output_string_);
+ StreamReporter reporter(&output_stream);
+ reporter.SetMessages(message1, message2);
+ reporter_ = &reporter;
+ result = Compare(message1, message2, &parent_fields);
+ reporter_ = NULL;
+ } else {
+ result = Compare(message1, message2, &parent_fields);
+ }
+ return result;
+}
+
+bool MessageDifferencer::CompareWithFields(
+ const Message& message1, const Message& message2,
+ const std::vector<const FieldDescriptor*>& message1_fields_arg,
+ const std::vector<const FieldDescriptor*>& message2_fields_arg) {
+ if (message1.GetDescriptor() != message2.GetDescriptor()) {
+ GOOGLE_LOG(DFATAL) << "Comparison between two messages with different "
+ << "descriptors.";
+ return false;
+ }
+
+ std::vector<SpecificField> parent_fields;
+
+ bool result = false;
+
+ FieldDescriptorArray message1_fields(message1_fields_arg.size() + 1);
+ FieldDescriptorArray message2_fields(message2_fields_arg.size() + 1);
+
+ std::copy(message1_fields_arg.cbegin(), message1_fields_arg.cend(),
+ message1_fields.begin());
+ std::copy(message2_fields_arg.cbegin(), message2_fields_arg.cend(),
+ message2_fields.begin());
+
+ // Append sentinel values.
+ message1_fields[message1_fields_arg.size()] = nullptr;
+ message2_fields[message2_fields_arg.size()] = nullptr;
+
+ std::sort(message1_fields.begin(), message1_fields.end(), FieldBefore);
+ std::sort(message2_fields.begin(), message2_fields.end(), FieldBefore);
+
+ // Setup the internal reporter if need be.
+ if (output_string_) {
+ io::StringOutputStream output_stream(output_string_);
+ StreamReporter reporter(&output_stream);
+ reporter_ = &reporter;
+ result = CompareRequestedFieldsUsingSettings(
+ message1, message2, message1_fields, message2_fields, &parent_fields);
+ reporter_ = NULL;
+ } else {
+ result = CompareRequestedFieldsUsingSettings(
+ message1, message2, message1_fields, message2_fields, &parent_fields);
+ }
+
+ return result;
+}
+
+bool MessageDifferencer::Compare(const Message& message1,
+ const Message& message2,
+ std::vector<SpecificField>* parent_fields) {
+ const Descriptor* descriptor1 = message1.GetDescriptor();
+ const Descriptor* descriptor2 = message2.GetDescriptor();
+ if (descriptor1 != descriptor2) {
+ GOOGLE_LOG(DFATAL) << "Comparison between two messages with different "
+ << "descriptors. " << descriptor1->full_name() << " vs "
+ << descriptor2->full_name();
+ return false;
+ }
+
+ // Expand google.protobuf.Any payload if possible.
+ if (descriptor1->full_name() == internal::kAnyFullTypeName) {
+ std::unique_ptr<Message> data1;
+ std::unique_ptr<Message> data2;
+ if (unpack_any_field_.UnpackAny(message1, &data1) &&
+ unpack_any_field_.UnpackAny(message2, &data2)) {
+ // Avoid DFATAL for different descriptors in google.protobuf.Any payloads.
+ if (data1->GetDescriptor() != data2->GetDescriptor()) {
+ return false;
+ }
+ return Compare(*data1, *data2, parent_fields);
+ }
+ }
+ const Reflection* reflection1 = message1.GetReflection();
+ const Reflection* reflection2 = message2.GetReflection();
+
+ bool unknown_compare_result = true;
+ // Ignore unknown fields in EQUIVALENT mode
+ if (message_field_comparison_ != EQUIVALENT) {
+ const UnknownFieldSet& unknown_field_set1 =
+ reflection1->GetUnknownFields(message1);
+ const UnknownFieldSet& unknown_field_set2 =
+ reflection2->GetUnknownFields(message2);
+ if (!CompareUnknownFields(message1, message2, unknown_field_set1,
+ unknown_field_set2, parent_fields)) {
+ if (reporter_ == NULL) {
+ return false;
+ }
+ unknown_compare_result = false;
+ }
+ }
+
+ FieldDescriptorArray message1_fields = RetrieveFields(message1, true);
+ FieldDescriptorArray message2_fields = RetrieveFields(message2, false);
+
+ return CompareRequestedFieldsUsingSettings(message1, message2,
+ message1_fields, message2_fields,
+ parent_fields) &&
+ unknown_compare_result;
+}
+
+FieldDescriptorArray MessageDifferencer::RetrieveFields(const Message& message,
+ bool base_message) {
+ const Descriptor* descriptor = message.GetDescriptor();
+
+ tmp_message_fields_.clear();
+ tmp_message_fields_.reserve(descriptor->field_count() + 1);
+
+ const Reflection* reflection = message.GetReflection();
+ if (descriptor->options().map_entry()) {
+ if (this->scope_ == PARTIAL && base_message) {
+ reflection->ListFields(message, &tmp_message_fields_);
+ } else {
+ // Map entry fields are always considered present.
+ for (int i = 0; i < descriptor->field_count(); i++) {
+ tmp_message_fields_.push_back(descriptor->field(i));
+ }
+ }
+ } else {
+ reflection->ListFields(message, &tmp_message_fields_);
+ }
+ // Add sentinel values to deal with the
+ // case where the number of the fields in
+ // each list are different.
+ tmp_message_fields_.push_back(nullptr);
+
+ FieldDescriptorArray message_fields(tmp_message_fields_.begin(),
+ tmp_message_fields_.end());
+
+ return message_fields;
+}
+
+bool MessageDifferencer::CompareRequestedFieldsUsingSettings(
+ const Message& message1, const Message& message2,
+ const FieldDescriptorArray& message1_fields,
+ const FieldDescriptorArray& message2_fields,
+ std::vector<SpecificField>* parent_fields) {
+ if (scope_ == FULL) {
+ if (message_field_comparison_ == EQUIVALENT) {
+ // We need to merge the field lists of both messages (i.e.
+ // we are merely checking for a difference in field values,
+ // rather than the addition or deletion of fields).
+ FieldDescriptorArray fields_union =
+ CombineFields(message1_fields, FULL, message2_fields, FULL);
+ return CompareWithFieldsInternal(message1, message2, fields_union,
+ fields_union, parent_fields);
+ } else {
+ // Simple equality comparison, use the unaltered field lists.
+ return CompareWithFieldsInternal(message1, message2, message1_fields,
+ message2_fields, parent_fields);
+ }
+ } else {
+ if (message_field_comparison_ == EQUIVALENT) {
+ // We use the list of fields for message1 for both messages when
+ // comparing. This way, extra fields in message2 are ignored,
+ // and missing fields in message2 use their default value.
+ return CompareWithFieldsInternal(message1, message2, message1_fields,
+ message1_fields, parent_fields);
+ } else {
+ // We need to consider the full list of fields for message1
+ // but only the intersection for message2. This way, any fields
+ // only present in message2 will be ignored, but any fields only
+ // present in message1 will be marked as a difference.
+ FieldDescriptorArray fields_intersection =
+ CombineFields(message1_fields, PARTIAL, message2_fields, PARTIAL);
+ return CompareWithFieldsInternal(message1, message2, message1_fields,
+ fields_intersection, parent_fields);
+ }
+ }
+}
+
+FieldDescriptorArray MessageDifferencer::CombineFields(
+ const FieldDescriptorArray& fields1, Scope fields1_scope,
+ const FieldDescriptorArray& fields2, Scope fields2_scope) {
+ size_t index1 = 0;
+ size_t index2 = 0;
+
+ tmp_message_fields_.clear();
+
+ while (index1 < fields1.size() && index2 < fields2.size()) {
+ const FieldDescriptor* field1 = fields1[index1];
+ const FieldDescriptor* field2 = fields2[index2];
+
+ if (FieldBefore(field1, field2)) {
+ if (fields1_scope == FULL) {
+ tmp_message_fields_.push_back(fields1[index1]);
+ }
+ ++index1;
+ } else if (FieldBefore(field2, field1)) {
+ if (fields2_scope == FULL) {
+ tmp_message_fields_.push_back(fields2[index2]);
+ }
+ ++index2;
+ } else {
+ tmp_message_fields_.push_back(fields1[index1]);
+ ++index1;
+ ++index2;
+ }
+ }
+
+ tmp_message_fields_.push_back(nullptr);
+
+ FieldDescriptorArray combined_fields(tmp_message_fields_.begin(),
+ tmp_message_fields_.end());
+
+ return combined_fields;
+}
+
+bool MessageDifferencer::CompareWithFieldsInternal(
+ const Message& message1, const Message& message2,
+ const FieldDescriptorArray& message1_fields,
+ const FieldDescriptorArray& message2_fields,
+ std::vector<SpecificField>* parent_fields) {
+ bool isDifferent = false;
+ int field_index1 = 0;
+ int field_index2 = 0;
+
+ const Reflection* reflection1 = message1.GetReflection();
+ const Reflection* reflection2 = message2.GetReflection();
+
+ while (true) {
+ const FieldDescriptor* field1 = message1_fields[field_index1];
+ const FieldDescriptor* field2 = message2_fields[field_index2];
+
+ // Once we have reached sentinel values, we are done the comparison.
+ if (field1 == NULL && field2 == NULL) {
+ break;
+ }
+
+ // Check for differences in the field itself.
+ if (FieldBefore(field1, field2)) {
+ // Field 1 is not in the field list for message 2.
+ if (IsIgnored(message1, message2, field1, *parent_fields)) {
+ // We are ignoring field1. Report the ignore and move on to
+ // the next field in message1_fields.
+ if (reporter_ != NULL) {
+ SpecificField specific_field;
+ specific_field.field = field1;
+ parent_fields->push_back(specific_field);
+ if (report_ignores_) {
+ reporter_->ReportIgnored(message1, message2, *parent_fields);
+ }
+ parent_fields->pop_back();
+ }
+ ++field_index1;
+ continue;
+ }
+
+ if (reporter_ != NULL) {
+ assert(field1 != NULL);
+ int count = field1->is_repeated()
+ ? reflection1->FieldSize(message1, field1)
+ : 1;
+
+ for (int i = 0; i < count; ++i) {
+ SpecificField specific_field;
+ specific_field.field = field1;
+ if (field1->is_repeated()) {
+ AddSpecificIndex(&specific_field, message1, field1, i);
+ } else {
+ specific_field.index = -1;
+ }
+
+ parent_fields->push_back(specific_field);
+ reporter_->ReportDeleted(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ }
+
+ isDifferent = true;
+ } else {
+ return false;
+ }
+
+ ++field_index1;
+ continue;
+ } else if (FieldBefore(field2, field1)) {
+ // Field 2 is not in the field list for message 1.
+ if (IsIgnored(message1, message2, field2, *parent_fields)) {
+ // We are ignoring field2. Report the ignore and move on to
+ // the next field in message2_fields.
+ if (reporter_ != NULL) {
+ SpecificField specific_field;
+ specific_field.field = field2;
+ parent_fields->push_back(specific_field);
+ if (report_ignores_) {
+ reporter_->ReportIgnored(message1, message2, *parent_fields);
+ }
+ parent_fields->pop_back();
+ }
+ ++field_index2;
+ continue;
+ }
+
+ if (reporter_ != NULL) {
+ int count = field2->is_repeated()
+ ? reflection2->FieldSize(message2, field2)
+ : 1;
+
+ for (int i = 0; i < count; ++i) {
+ SpecificField specific_field;
+ specific_field.field = field2;
+ if (field2->is_repeated()) {
+ specific_field.index = i;
+ AddSpecificNewIndex(&specific_field, message2, field2, i);
+ } else {
+ specific_field.index = -1;
+ specific_field.new_index = -1;
+ }
+
+ parent_fields->push_back(specific_field);
+ reporter_->ReportAdded(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ }
+
+ isDifferent = true;
+ } else {
+ return false;
+ }
+
+ ++field_index2;
+ continue;
+ }
+
+ // By this point, field1 and field2 are guaranteed to point to the same
+ // field, so we can now compare the values.
+ if (IsIgnored(message1, message2, field1, *parent_fields)) {
+ // Ignore this field. Report and move on.
+ if (reporter_ != NULL) {
+ SpecificField specific_field;
+ specific_field.field = field1;
+ parent_fields->push_back(specific_field);
+ if (report_ignores_) {
+ reporter_->ReportIgnored(message1, message2, *parent_fields);
+ }
+ parent_fields->pop_back();
+ }
+
+ ++field_index1;
+ ++field_index2;
+ continue;
+ }
+
+ bool fieldDifferent = false;
+ assert(field1 != NULL);
+ if (field1->is_map()) {
+ fieldDifferent =
+ !CompareMapField(message1, message2, field1, parent_fields);
+ } else if (field1->is_repeated()) {
+ fieldDifferent =
+ !CompareRepeatedField(message1, message2, field1, parent_fields);
+ } else {
+ fieldDifferent = !CompareFieldValueUsingParentFields(
+ message1, message2, field1, -1, -1, parent_fields);
+
+ if (reporter_ != nullptr) {
+ SpecificField specific_field;
+ specific_field.field = field1;
+ parent_fields->push_back(specific_field);
+ if (fieldDifferent) {
+ reporter_->ReportModified(message1, message2, *parent_fields);
+ isDifferent = true;
+ } else if (report_matches_) {
+ reporter_->ReportMatched(message1, message2, *parent_fields);
+ }
+ parent_fields->pop_back();
+ }
+ }
+ if (fieldDifferent) {
+ if (reporter_ == nullptr) return false;
+ isDifferent = true;
+ }
+ // Increment the field indices.
+ ++field_index1;
+ ++field_index2;
+ }
+
+ return !isDifferent;
+}
+
+bool MessageDifferencer::IsMatch(
+ const FieldDescriptor* repeated_field,
+ const MapKeyComparator* key_comparator, const Message* message1,
+ const Message* message2, const std::vector<SpecificField>& parent_fields,
+ Reporter* reporter, int index1, int index2) {
+ std::vector<SpecificField> current_parent_fields(parent_fields);
+ if (repeated_field->cpp_type() != FieldDescriptor::CPPTYPE_MESSAGE) {
+ return CompareFieldValueUsingParentFields(*message1, *message2,
+ repeated_field, index1, index2,
+ &current_parent_fields);
+ }
+ // Back up the Reporter and output_string_. They will be reset in the
+ // following code.
+ Reporter* backup_reporter = reporter_;
+ std::string* output_string = output_string_;
+ reporter_ = reporter;
+ output_string_ = NULL;
+ bool match;
+
+ if (key_comparator == NULL) {
+ match = CompareFieldValueUsingParentFields(*message1, *message2,
+ repeated_field, index1, index2,
+ &current_parent_fields);
+ } else {
+ const Reflection* reflection1 = message1->GetReflection();
+ const Reflection* reflection2 = message2->GetReflection();
+ const Message& m1 =
+ reflection1->GetRepeatedMessage(*message1, repeated_field, index1);
+ const Message& m2 =
+ reflection2->GetRepeatedMessage(*message2, repeated_field, index2);
+ SpecificField specific_field;
+ specific_field.field = repeated_field;
+ if (repeated_field->is_map()) {
+ specific_field.map_entry1 = &m1;
+ specific_field.map_entry2 = &m2;
+ }
+ specific_field.index = index1;
+ specific_field.new_index = index2;
+ current_parent_fields.push_back(specific_field);
+ match = key_comparator->IsMatch(m1, m2, current_parent_fields);
+ }
+
+ reporter_ = backup_reporter;
+ output_string_ = output_string;
+ return match;
+}
+
+bool MessageDifferencer::CompareMapFieldByMapReflection(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* map_field, std::vector<SpecificField>* parent_fields,
+ DefaultFieldComparator* comparator) {
+ GOOGLE_DCHECK_EQ(nullptr, reporter_);
+ GOOGLE_DCHECK(map_field->is_map());
+ GOOGLE_DCHECK(map_field_key_comparator_.find(map_field) ==
+ map_field_key_comparator_.end());
+ GOOGLE_DCHECK_EQ(repeated_field_comparison_, AS_LIST);
+ const Reflection* reflection1 = message1.GetReflection();
+ const Reflection* reflection2 = message2.GetReflection();
+ const int count1 = reflection1->MapSize(message1, map_field);
+ const int count2 = reflection2->MapSize(message2, map_field);
+ const bool treated_as_subset = IsTreatedAsSubset(map_field);
+ if (count1 != count2 && !treated_as_subset) {
+ return false;
+ }
+ if (count1 > count2) {
+ return false;
+ }
+
+ // First pass: check whether the same keys are present.
+ for (MapIterator it = reflection1->MapBegin(const_cast<Message*>(&message1),
+ map_field),
+ it_end = reflection1->MapEnd(const_cast<Message*>(&message1),
+ map_field);
+ it != it_end; ++it) {
+ if (!reflection2->ContainsMapKey(message2, map_field, it.GetKey())) {
+ return false;
+ }
+ }
+
+ // Second pass: compare values for matching keys.
+ const FieldDescriptor* val_des = map_field->message_type()->map_value();
+ switch (val_des->cpp_type()) {
+#define HANDLE_TYPE(CPPTYPE, METHOD, COMPAREMETHOD) \
+ case FieldDescriptor::CPPTYPE_##CPPTYPE: { \
+ for (MapIterator it = reflection1->MapBegin( \
+ const_cast<Message*>(&message1), map_field), \
+ it_end = reflection1->MapEnd( \
+ const_cast<Message*>(&message1), map_field); \
+ it != it_end; ++it) { \
+ MapValueConstRef value2; \
+ reflection2->LookupMapValue(message2, map_field, it.GetKey(), &value2); \
+ if (!comparator->Compare##COMPAREMETHOD(*val_des, \
+ it.GetValueRef().Get##METHOD(), \
+ value2.Get##METHOD())) { \
+ return false; \
+ } \
+ } \
+ break; \
+ }
+ HANDLE_TYPE(INT32, Int32Value, Int32);
+ HANDLE_TYPE(INT64, Int64Value, Int64);
+ HANDLE_TYPE(UINT32, UInt32Value, UInt32);
+ HANDLE_TYPE(UINT64, UInt64Value, UInt64);
+ HANDLE_TYPE(DOUBLE, DoubleValue, Double);
+ HANDLE_TYPE(FLOAT, FloatValue, Float);
+ HANDLE_TYPE(BOOL, BoolValue, Bool);
+ HANDLE_TYPE(STRING, StringValue, String);
+ HANDLE_TYPE(ENUM, EnumValue, Int32);
+#undef HANDLE_TYPE
+ case FieldDescriptor::CPPTYPE_MESSAGE: {
+ for (MapIterator it = reflection1->MapBegin(
+ const_cast<Message*>(&message1), map_field);
+ it !=
+ reflection1->MapEnd(const_cast<Message*>(&message1), map_field);
+ ++it) {
+ if (!reflection2->ContainsMapKey(message2, map_field, it.GetKey())) {
+ return false;
+ }
+ bool compare_result;
+ MapValueConstRef value2;
+ reflection2->LookupMapValue(message2, map_field, it.GetKey(), &value2);
+ // Append currently compared field to the end of parent_fields.
+ SpecificField specific_value_field;
+ specific_value_field.field = val_des;
+ parent_fields->push_back(specific_value_field);
+ compare_result = Compare(it.GetValueRef().GetMessageValue(),
+ value2.GetMessageValue(), parent_fields);
+ parent_fields->pop_back();
+ if (!compare_result) {
+ return false;
+ }
+ }
+ break;
+ }
+ }
+ return true;
+}
+
+bool MessageDifferencer::CompareMapField(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* repeated_field,
+ std::vector<SpecificField>* parent_fields) {
+ GOOGLE_DCHECK(repeated_field->is_map());
+
+ // the input FieldDescriptor is guaranteed to be repeated field.
+ const Reflection* reflection1 = message1.GetReflection();
+ const Reflection* reflection2 = message2.GetReflection();
+
+ // When both map fields are on map, do not sync to repeated field.
+ if (reflection1->GetMapData(message1, repeated_field)->IsMapValid() &&
+ reflection2->GetMapData(message2, repeated_field)->IsMapValid() &&
+ // TODO(jieluo): Add support for reporter
+ reporter_ == nullptr &&
+ // Users didn't set custom map field key comparator
+ map_field_key_comparator_.find(repeated_field) ==
+ map_field_key_comparator_.end() &&
+ // Users didn't set repeated field comparison
+ repeated_field_comparison_ == AS_LIST &&
+ // Users didn't set their own FieldComparator implementation
+ field_comparator_kind_ == kFCDefault) {
+ const FieldDescriptor* key_des = repeated_field->message_type()->map_key();
+ const FieldDescriptor* val_des =
+ repeated_field->message_type()->map_value();
+ std::vector<SpecificField> current_parent_fields(*parent_fields);
+ SpecificField specific_field;
+ specific_field.field = repeated_field;
+ current_parent_fields.push_back(specific_field);
+ if (!IsIgnored(message1, message2, key_des, current_parent_fields) &&
+ !IsIgnored(message1, message2, val_des, current_parent_fields)) {
+ return CompareMapFieldByMapReflection(message1, message2, repeated_field,
+ &current_parent_fields,
+ field_comparator_.default_impl);
+ }
+ }
+
+ return CompareRepeatedRep(message1, message2, repeated_field, parent_fields);
+}
+
+bool MessageDifferencer::CompareRepeatedField(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* repeated_field,
+ std::vector<SpecificField>* parent_fields) {
+ GOOGLE_DCHECK(!repeated_field->is_map());
+ return CompareRepeatedRep(message1, message2, repeated_field, parent_fields);
+}
+
+bool MessageDifferencer::CompareRepeatedRep(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* repeated_field,
+ std::vector<SpecificField>* parent_fields) {
+ // the input FieldDescriptor is guaranteed to be repeated field.
+ GOOGLE_DCHECK(repeated_field->is_repeated());
+ const Reflection* reflection1 = message1.GetReflection();
+ const Reflection* reflection2 = message2.GetReflection();
+
+ const int count1 = reflection1->FieldSize(message1, repeated_field);
+ const int count2 = reflection2->FieldSize(message2, repeated_field);
+ const bool treated_as_subset = IsTreatedAsSubset(repeated_field);
+
+ // If the field is not treated as subset and no detailed reports is needed,
+ // we do a quick check on the number of the elements to avoid unnecessary
+ // comparison.
+ if (count1 != count2 && reporter_ == NULL && !treated_as_subset) {
+ return false;
+ }
+ // A match can never be found if message1 has more items than message2.
+ if (count1 > count2 && reporter_ == NULL) {
+ return false;
+ }
+
+ // These two list are used for store the index of the correspondent
+ // element in peer repeated field.
+ std::vector<int> match_list1;
+ std::vector<int> match_list2;
+
+ const MapKeyComparator* key_comparator = GetMapKeyComparator(repeated_field);
+ bool smart_list = IsTreatedAsSmartList(repeated_field);
+ bool simple_list = key_comparator == nullptr &&
+ !IsTreatedAsSet(repeated_field) &&
+ !IsTreatedAsSmartSet(repeated_field) && !smart_list;
+
+ // For simple lists, we avoid matching repeated field indices, saving the
+ // memory allocations that would otherwise be needed for match_list1 and
+ // match_list2.
+ if (!simple_list) {
+ // Try to match indices of the repeated fields. Return false if match fails.
+ if (!MatchRepeatedFieldIndices(message1, message2, repeated_field,
+ key_comparator, *parent_fields, &match_list1,
+ &match_list2) &&
+ reporter_ == nullptr) {
+ return false;
+ }
+ }
+
+ bool fieldDifferent = false;
+ SpecificField specific_field;
+ specific_field.field = repeated_field;
+
+ // At this point, we have already matched pairs of fields (with the reporting
+ // to be done later). Now to check if the paired elements are different.
+ int next_unmatched_index = 0;
+ for (int i = 0; i < count1; i++) {
+ if (simple_list && i >= count2) {
+ break;
+ }
+ if (!simple_list && match_list1[i] == -1) {
+ if (smart_list) {
+ if (reporter_ == nullptr) return false;
+ AddSpecificIndex(&specific_field, message1, repeated_field, i);
+ parent_fields->push_back(specific_field);
+ reporter_->ReportDeleted(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ fieldDifferent = true;
+ // Use -2 to mark this element has been reported.
+ match_list1[i] = -2;
+ }
+ continue;
+ }
+ if (smart_list) {
+ for (int j = next_unmatched_index; j < match_list1[i]; ++j) {
+ GOOGLE_CHECK_LE(0, j);
+ if (reporter_ == nullptr) return false;
+ specific_field.index = j;
+ AddSpecificNewIndex(&specific_field, message2, repeated_field, j);
+ parent_fields->push_back(specific_field);
+ reporter_->ReportAdded(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ fieldDifferent = true;
+ // Use -2 to mark this element has been reported.
+ match_list2[j] = -2;
+ }
+ }
+ AddSpecificIndex(&specific_field, message1, repeated_field, i);
+ if (simple_list) {
+ AddSpecificNewIndex(&specific_field, message2, repeated_field, i);
+ } else {
+ AddSpecificNewIndex(&specific_field, message2, repeated_field,
+ match_list1[i]);
+ next_unmatched_index = match_list1[i] + 1;
+ }
+
+ const bool result = CompareFieldValueUsingParentFields(
+ message1, message2, repeated_field, i, specific_field.new_index,
+ parent_fields);
+
+ // If we have found differences, either report them or terminate if
+ // no reporter is present. Note that ReportModified, ReportMoved, and
+ // ReportMatched are all mutually exclusive.
+ if (!result) {
+ if (reporter_ == NULL) return false;
+ parent_fields->push_back(specific_field);
+ reporter_->ReportModified(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ fieldDifferent = true;
+ } else if (reporter_ != NULL &&
+ specific_field.index != specific_field.new_index &&
+ !specific_field.field->is_map() && report_moves_) {
+ parent_fields->push_back(specific_field);
+ reporter_->ReportMoved(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ } else if (report_matches_ && reporter_ != NULL) {
+ parent_fields->push_back(specific_field);
+ reporter_->ReportMatched(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ }
+ }
+
+ // Report any remaining additions or deletions.
+ for (int i = 0; i < count2; ++i) {
+ if (!simple_list && match_list2[i] != -1) continue;
+ if (simple_list && i < count1) continue;
+ if (!treated_as_subset) {
+ fieldDifferent = true;
+ }
+
+ if (reporter_ == NULL) continue;
+ specific_field.index = i;
+ AddSpecificNewIndex(&specific_field, message2, repeated_field, i);
+ parent_fields->push_back(specific_field);
+ reporter_->ReportAdded(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ }
+
+ for (int i = 0; i < count1; ++i) {
+ if (!simple_list && match_list1[i] != -1) continue;
+ if (simple_list && i < count2) continue;
+ assert(reporter_ != NULL);
+ AddSpecificIndex(&specific_field, message1, repeated_field, i);
+ parent_fields->push_back(specific_field);
+ reporter_->ReportDeleted(message1, message2, *parent_fields);
+ parent_fields->pop_back();
+ fieldDifferent = true;
+ }
+ return !fieldDifferent;
+}
+
+bool MessageDifferencer::CompareFieldValue(const Message& message1,
+ const Message& message2,
+ const FieldDescriptor* field,
+ int index1, int index2) {
+ return CompareFieldValueUsingParentFields(message1, message2, field, index1,
+ index2, NULL);
+}
+
+bool MessageDifferencer::CompareFieldValueUsingParentFields(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* field, int index1, int index2,
+ std::vector<SpecificField>* parent_fields) {
+ FieldContext field_context(parent_fields);
+ FieldComparator::ComparisonResult result = GetFieldComparisonResult(
+ message1, message2, field, index1, index2, &field_context);
+
+ if (field->cpp_type() == FieldDescriptor::CPPTYPE_MESSAGE &&
+ result == FieldComparator::RECURSE) {
+ // Get the nested messages and compare them using one of the Compare
+ // methods.
+ const Reflection* reflection1 = message1.GetReflection();
+ const Reflection* reflection2 = message2.GetReflection();
+ const Message& m1 =
+ field->is_repeated()
+ ? reflection1->GetRepeatedMessage(message1, field, index1)
+ : reflection1->GetMessage(message1, field);
+ const Message& m2 =
+ field->is_repeated()
+ ? reflection2->GetRepeatedMessage(message2, field, index2)
+ : reflection2->GetMessage(message2, field);
+
+ // parent_fields is used in calls to Reporter methods.
+ if (parent_fields != NULL) {
+ // Append currently compared field to the end of parent_fields.
+ SpecificField specific_field;
+ specific_field.field = field;
+ AddSpecificIndex(&specific_field, message1, field, index1);
+ AddSpecificNewIndex(&specific_field, message2, field, index2);
+ parent_fields->push_back(specific_field);
+ const bool compare_result = Compare(m1, m2, parent_fields);
+ parent_fields->pop_back();
+ return compare_result;
+ } else {
+ // Recreates parent_fields as if m1 and m2 had no parents.
+ return Compare(m1, m2);
+ }
+ } else {
+ return (result == FieldComparator::SAME);
+ }
+}
+
+bool MessageDifferencer::CheckPathChanged(
+ const std::vector<SpecificField>& field_path) {
+ for (const SpecificField& specific_field : field_path) {
+ // Don't check indexes for map entries -- maps are unordered.
+ if (specific_field.field != nullptr && specific_field.field->is_map())
+ continue;
+ if (specific_field.index != specific_field.new_index) return true;
+ }
+ return false;
+}
+
+bool MessageDifferencer::IsTreatedAsSet(const FieldDescriptor* field) {
+ if (!field->is_repeated()) return false;
+ if (repeated_field_comparisons_.find(field) !=
+ repeated_field_comparisons_.end()) {
+ return repeated_field_comparisons_[field] == AS_SET;
+ }
+ return GetMapKeyComparator(field) == nullptr &&
+ repeated_field_comparison_ == AS_SET;
+}
+
+bool MessageDifferencer::IsTreatedAsSmartSet(const FieldDescriptor* field) {
+ if (!field->is_repeated()) return false;
+ if (repeated_field_comparisons_.find(field) !=
+ repeated_field_comparisons_.end()) {
+ return repeated_field_comparisons_[field] == AS_SMART_SET;
+ }
+ return GetMapKeyComparator(field) == nullptr &&
+ repeated_field_comparison_ == AS_SMART_SET;
+}
+
+bool MessageDifferencer::IsTreatedAsSmartList(const FieldDescriptor* field) {
+ if (!field->is_repeated()) return false;
+ if (repeated_field_comparisons_.find(field) !=
+ repeated_field_comparisons_.end()) {
+ return repeated_field_comparisons_[field] == AS_SMART_LIST;
+ }
+ return GetMapKeyComparator(field) == nullptr &&
+ repeated_field_comparison_ == AS_SMART_LIST;
+}
+
+bool MessageDifferencer::IsTreatedAsSubset(const FieldDescriptor* field) {
+ return scope_ == PARTIAL &&
+ (IsTreatedAsSet(field) || GetMapKeyComparator(field) != NULL);
+}
+
+bool MessageDifferencer::IsIgnored(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* field,
+ const std::vector<SpecificField>& parent_fields) {
+ if (ignored_fields_.find(field) != ignored_fields_.end()) {
+ return true;
+ }
+ for (IgnoreCriteria* criteria : ignore_criteria_) {
+ if (criteria->IsIgnored(message1, message2, field, parent_fields)) {
+ return true;
+ }
+ }
+ return false;
+}
+
+bool MessageDifferencer::IsUnknownFieldIgnored(
+ const Message& message1, const Message& message2,
+ const SpecificField& field,
+ const std::vector<SpecificField>& parent_fields) {
+ for (IgnoreCriteria* criteria : ignore_criteria_) {
+ if (criteria->IsUnknownFieldIgnored(message1, message2, field,
+ parent_fields)) {
+ return true;
+ }
+ }
+ return false;
+}
+
+const MessageDifferencer::MapKeyComparator*
+MessageDifferencer ::GetMapKeyComparator(const FieldDescriptor* field) const {
+ if (!field->is_repeated()) return NULL;
+ FieldKeyComparatorMap::const_iterator it =
+ map_field_key_comparator_.find(field);
+ if (it != map_field_key_comparator_.end()) {
+ return it->second;
+ }
+ if (field->is_map()) {
+ // field cannot already be treated as list or set since TreatAsList() and
+ // TreatAsSet() call GetMapKeyComparator() and fail if it returns non-NULL.
+ return &map_entry_key_comparator_;
+ }
+ return NULL;
+}
+
+namespace {
+
+typedef std::pair<int, const UnknownField*> IndexUnknownFieldPair;
+
+struct UnknownFieldOrdering {
+ inline bool operator()(const IndexUnknownFieldPair& a,
+ const IndexUnknownFieldPair& b) const {
+ if (a.second->number() < b.second->number()) return true;
+ if (a.second->number() > b.second->number()) return false;
+ return a.second->type() < b.second->type();
+ }
+};
+
+} // namespace
+
+bool MessageDifferencer::UnpackAnyField::UnpackAny(
+ const Message& any, std::unique_ptr<Message>* data) {
+ const Reflection* reflection = any.GetReflection();
+ const FieldDescriptor* type_url_field;
+ const FieldDescriptor* value_field;
+ if (!internal::GetAnyFieldDescriptors(any, &type_url_field, &value_field)) {
+ return false;
+ }
+ const std::string& type_url = reflection->GetString(any, type_url_field);
+ std::string full_type_name;
+ if (!internal::ParseAnyTypeUrl(type_url, &full_type_name)) {
+ return false;
+ }
+
+ const Descriptor* desc =
+ any.GetDescriptor()->file()->pool()->FindMessageTypeByName(
+ full_type_name);
+ if (desc == NULL) {
+ GOOGLE_LOG(INFO) << "Proto type '" << full_type_name << "' not found";
+ return false;
+ }
+
+ if (dynamic_message_factory_ == NULL) {
+ dynamic_message_factory_.reset(new DynamicMessageFactory());
+ }
+ data->reset(dynamic_message_factory_->GetPrototype(desc)->New());
+ std::string serialized_value = reflection->GetString(any, value_field);
+ if (!(*data)->ParsePartialFromString(serialized_value)) {
+ GOOGLE_DLOG(ERROR) << "Failed to parse value for " << full_type_name;
+ return false;
+ }
+ return true;
+}
+
+bool MessageDifferencer::CompareUnknownFields(
+ const Message& message1, const Message& message2,
+ const UnknownFieldSet& unknown_field_set1,
+ const UnknownFieldSet& unknown_field_set2,
+ std::vector<SpecificField>* parent_field) {
+ // Ignore unknown fields in EQUIVALENT mode.
+ if (message_field_comparison_ == EQUIVALENT) return true;
+
+ if (unknown_field_set1.empty() && unknown_field_set2.empty()) {
+ return true;
+ }
+
+ bool is_different = false;
+
+ // We first sort the unknown fields by field number and type (in other words,
+ // in tag order), making sure to preserve ordering of values with the same
+ // tag. This allows us to report only meaningful differences between the
+ // two sets -- that is, differing values for the same tag. We use
+ // IndexUnknownFieldPairs to keep track of the field's original index for
+ // reporting purposes.
+ std::vector<IndexUnknownFieldPair> fields1; // unknown_field_set1, sorted
+ std::vector<IndexUnknownFieldPair> fields2; // unknown_field_set2, sorted
+ fields1.reserve(unknown_field_set1.field_count());
+ fields2.reserve(unknown_field_set2.field_count());
+
+ for (int i = 0; i < unknown_field_set1.field_count(); i++) {
+ fields1.push_back(std::make_pair(i, &unknown_field_set1.field(i)));
+ }
+ for (int i = 0; i < unknown_field_set2.field_count(); i++) {
+ fields2.push_back(std::make_pair(i, &unknown_field_set2.field(i)));
+ }
+
+ UnknownFieldOrdering is_before;
+ std::stable_sort(fields1.begin(), fields1.end(), is_before);
+ std::stable_sort(fields2.begin(), fields2.end(), is_before);
+
+ // In order to fill in SpecificField::index, we have to keep track of how
+ // many values we've seen with the same field number and type.
+ // current_repeated points at the first field in this range, and
+ // current_repeated_start{1,2} are the indexes of the first field in the
+ // range within fields1 and fields2.
+ const UnknownField* current_repeated = NULL;
+ int current_repeated_start1 = 0;
+ int current_repeated_start2 = 0;
+
+ // Now that we have two sorted lists, we can detect fields which appear only
+ // in one list or the other by traversing them simultaneously.
+ size_t index1 = 0;
+ size_t index2 = 0;
+ while (index1 < fields1.size() || index2 < fields2.size()) {
+ enum {
+ ADDITION,
+ DELETION,
+ MODIFICATION,
+ COMPARE_GROUPS,
+ NO_CHANGE
+ } change_type;
+
+ // focus_field is the field we're currently reporting on. (In the case
+ // of a modification, it's the field on the left side.)
+ const UnknownField* focus_field;
+ bool match = false;
+
+ if (index2 == fields2.size() ||
+ (index1 < fields1.size() &&
+ is_before(fields1[index1], fields2[index2]))) {
+ // fields1[index1] is not present in fields2.
+ change_type = DELETION;
+ focus_field = fields1[index1].second;
+ } else if (index1 == fields1.size() ||
+ is_before(fields2[index2], fields1[index1])) {
+ // fields2[index2] is not present in fields1.
+ if (scope_ == PARTIAL) {
+ // Ignore.
+ ++index2;
+ continue;
+ }
+ change_type = ADDITION;
+ focus_field = fields2[index2].second;
+ } else {
+ // Field type and number are the same. See if the values differ.
+ change_type = MODIFICATION;
+ focus_field = fields1[index1].second;
+
+ switch (focus_field->type()) {
+ case UnknownField::TYPE_VARINT:
+ match = fields1[index1].second->varint() ==
+ fields2[index2].second->varint();
+ break;
+ case UnknownField::TYPE_FIXED32:
+ match = fields1[index1].second->fixed32() ==
+ fields2[index2].second->fixed32();
+ break;
+ case UnknownField::TYPE_FIXED64:
+ match = fields1[index1].second->fixed64() ==
+ fields2[index2].second->fixed64();
+ break;
+ case UnknownField::TYPE_LENGTH_DELIMITED:
+ match = fields1[index1].second->length_delimited() ==
+ fields2[index2].second->length_delimited();
+ break;
+ case UnknownField::TYPE_GROUP:
+ // We must deal with this later, after building the SpecificField.
+ change_type = COMPARE_GROUPS;
+ break;
+ }
+ if (match && change_type != COMPARE_GROUPS) {
+ change_type = NO_CHANGE;
+ }
+ }
+
+ if (current_repeated == NULL ||
+ focus_field->number() != current_repeated->number() ||
+ focus_field->type() != current_repeated->type()) {
+ // We've started a new repeated field.
+ current_repeated = focus_field;
+ current_repeated_start1 = index1;
+ current_repeated_start2 = index2;
+ }
+
+ if (change_type == NO_CHANGE && reporter_ == NULL) {
+ // Fields were already compared and matched and we have no reporter.
+ ++index1;
+ ++index2;
+ continue;
+ }
+
+ // Build the SpecificField. This is slightly complicated.
+ SpecificField specific_field;
+ specific_field.unknown_field_number = focus_field->number();
+ specific_field.unknown_field_type = focus_field->type();
+
+ specific_field.unknown_field_set1 = &unknown_field_set1;
+ specific_field.unknown_field_set2 = &unknown_field_set2;
+
+ if (change_type != ADDITION) {
+ specific_field.unknown_field_index1 = fields1[index1].first;
+ }
+ if (change_type != DELETION) {
+ specific_field.unknown_field_index2 = fields2[index2].first;
+ }
+
+ // Calculate the field index.
+ if (change_type == ADDITION) {
+ specific_field.index = index2 - current_repeated_start2;
+ specific_field.new_index = index2 - current_repeated_start2;
+ } else {
+ specific_field.index = index1 - current_repeated_start1;
+ specific_field.new_index = index2 - current_repeated_start2;
+ }
+
+ if (IsUnknownFieldIgnored(message1, message2, specific_field,
+ *parent_field)) {
+ if (report_ignores_ && reporter_ != NULL) {
+ parent_field->push_back(specific_field);
+ reporter_->ReportUnknownFieldIgnored(message1, message2, *parent_field);
+ parent_field->pop_back();
+ }
+ if (change_type != ADDITION) ++index1;
+ if (change_type != DELETION) ++index2;
+ continue;
+ }
+
+ if (change_type == ADDITION || change_type == DELETION ||
+ change_type == MODIFICATION) {
+ if (reporter_ == NULL) {
+ // We found a difference and we have no reporter.
+ return false;
+ }
+ is_different = true;
+ }
+
+ parent_field->push_back(specific_field);
+
+ switch (change_type) {
+ case ADDITION:
+ reporter_->ReportAdded(message1, message2, *parent_field);
+ ++index2;
+ break;
+ case DELETION:
+ reporter_->ReportDeleted(message1, message2, *parent_field);
+ ++index1;
+ break;
+ case MODIFICATION:
+ reporter_->ReportModified(message1, message2, *parent_field);
+ ++index1;
+ ++index2;
+ break;
+ case COMPARE_GROUPS:
+ if (!CompareUnknownFields(
+ message1, message2, fields1[index1].second->group(),
+ fields2[index2].second->group(), parent_field)) {
+ if (reporter_ == NULL) return false;
+ is_different = true;
+ reporter_->ReportModified(message1, message2, *parent_field);
+ }
+ ++index1;
+ ++index2;
+ break;
+ case NO_CHANGE:
+ ++index1;
+ ++index2;
+ if (report_matches_) {
+ reporter_->ReportMatched(message1, message2, *parent_field);
+ }
+ }
+
+ parent_field->pop_back();
+ }
+
+ return !is_different;
+}
+
+namespace {
+
+// Find maximum bipartite matching using the argumenting path algorithm.
+class MaximumMatcher {
+ public:
+ typedef std::function<bool(int, int)> NodeMatchCallback;
+ // MaximumMatcher takes ownership of the passed in callback and uses it to
+ // determine whether a node on the left side of the bipartial graph matches
+ // a node on the right side. count1 is the number of nodes on the left side
+ // of the graph and count2 to is the number of nodes on the right side.
+ // Every node is referred to using 0-based indices.
+ // If a maximum match is found, the result will be stored in match_list1 and
+ // match_list2. match_list1[i] == j means the i-th node on the left side is
+ // matched to the j-th node on the right side and match_list2[x] == y means
+ // the x-th node on the right side is matched to y-th node on the left side.
+ // match_list1[i] == -1 means the node is not matched. Same with match_list2.
+ MaximumMatcher(int count1, int count2, NodeMatchCallback callback,
+ std::vector<int>* match_list1, std::vector<int>* match_list2);
+ // Find a maximum match and return the number of matched node pairs.
+ // If early_return is true, this method will return 0 immediately when it
+ // finds that not all nodes on the left side can be matched.
+ int FindMaximumMatch(bool early_return);
+
+ private:
+ // Determines whether the node on the left side of the bipartial graph
+ // matches the one on the right side.
+ bool Match(int left, int right);
+ // Find an argumenting path starting from the node v on the left side. If a
+ // path can be found, update match_list2_ to reflect the path and return
+ // true.
+ bool FindArgumentPathDFS(int v, std::vector<bool>* visited);
+
+ int count1_;
+ int count2_;
+ NodeMatchCallback match_callback_;
+ std::map<std::pair<int, int>, bool> cached_match_results_;
+ std::vector<int>* match_list1_;
+ std::vector<int>* match_list2_;
+ GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(MaximumMatcher);
+};
+
+MaximumMatcher::MaximumMatcher(int count1, int count2,
+ NodeMatchCallback callback,
+ std::vector<int>* match_list1,
+ std::vector<int>* match_list2)
+ : count1_(count1),
+ count2_(count2),
+ match_callback_(std::move(callback)),
+ match_list1_(match_list1),
+ match_list2_(match_list2) {
+ match_list1_->assign(count1, -1);
+ match_list2_->assign(count2, -1);
+}
+
+int MaximumMatcher::FindMaximumMatch(bool early_return) {
+ int result = 0;
+ for (int i = 0; i < count1_; ++i) {
+ std::vector<bool> visited(count1_);
+ if (FindArgumentPathDFS(i, &visited)) {
+ ++result;
+ } else if (early_return) {
+ return 0;
+ }
+ }
+ // Backfill match_list1_ as we only filled match_list2_ when finding
+ // argumenting paths.
+ for (int i = 0; i < count2_; ++i) {
+ if ((*match_list2_)[i] != -1) {
+ (*match_list1_)[(*match_list2_)[i]] = i;
+ }
+ }
+ return result;
+}
+
+bool MaximumMatcher::Match(int left, int right) {
+ std::pair<int, int> p(left, right);
+ std::map<std::pair<int, int>, bool>::iterator it =
+ cached_match_results_.find(p);
+ if (it != cached_match_results_.end()) {
+ return it->second;
+ }
+ cached_match_results_[p] = match_callback_(left, right);
+ return cached_match_results_[p];
+}
+
+bool MaximumMatcher::FindArgumentPathDFS(int v, std::vector<bool>* visited) {
+ (*visited)[v] = true;
+ // We try to match those un-matched nodes on the right side first. This is
+ // the step that the naive greedy matching algorithm uses. In the best cases
+ // where the greedy algorithm can find a maximum matching, we will always
+ // find a match in this step and the performance will be identical to the
+ // greedy algorithm.
+ for (int i = 0; i < count2_; ++i) {
+ int matched = (*match_list2_)[i];
+ if (matched == -1 && Match(v, i)) {
+ (*match_list2_)[i] = v;
+ return true;
+ }
+ }
+ // Then we try those already matched nodes and see if we can find an
+ // alternative match for the node matched to them.
+ // The greedy algorithm will stop before this and fail to produce the
+ // correct result.
+ for (int i = 0; i < count2_; ++i) {
+ int matched = (*match_list2_)[i];
+ if (matched != -1 && Match(v, i)) {
+ if (!(*visited)[matched] && FindArgumentPathDFS(matched, visited)) {
+ (*match_list2_)[i] = v;
+ return true;
+ }
+ }
+ }
+ return false;
+}
+
+} // namespace
+
+bool MessageDifferencer::MatchRepeatedFieldIndices(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* repeated_field,
+ const MapKeyComparator* key_comparator,
+ const std::vector<SpecificField>& parent_fields,
+ std::vector<int>* match_list1, std::vector<int>* match_list2) {
+ const int count1 =
+ message1.GetReflection()->FieldSize(message1, repeated_field);
+ const int count2 =
+ message2.GetReflection()->FieldSize(message2, repeated_field);
+ const bool is_treated_as_smart_set = IsTreatedAsSmartSet(repeated_field);
+
+ match_list1->assign(count1, -1);
+ match_list2->assign(count2, -1);
+ // Ensure that we don't report differences during the matching process. Since
+ // field comparators could potentially use this message differencer object to
+ // perform further comparisons, turn off reporting here and re-enable it
+ // before returning.
+ Reporter* reporter = reporter_;
+ reporter_ = NULL;
+ NumDiffsReporter num_diffs_reporter;
+ std::vector<int32_t> num_diffs_list1;
+ if (is_treated_as_smart_set) {
+ num_diffs_list1.assign(count1, std::numeric_limits<int32_t>::max());
+ }
+
+ bool success = true;
+ // Find potential match if this is a special repeated field.
+ if (scope_ == PARTIAL) {
+ // When partial matching is enabled, Compare(a, b) && Compare(a, c)
+ // doesn't necessarily imply Compare(b, c). Therefore a naive greedy
+ // algorithm will fail to find a maximum matching.
+ // Here we use the augmenting path algorithm.
+ auto callback = [&](int i1, int i2) {
+ return IsMatch(repeated_field, key_comparator, &message1, &message2,
+ parent_fields, nullptr, i1, i2);
+ };
+ MaximumMatcher matcher(count1, count2, std::move(callback), match_list1,
+ match_list2);
+ // If diff info is not needed, we should end the matching process as
+ // soon as possible if not all items can be matched.
+ bool early_return = (reporter == nullptr);
+ int match_count = matcher.FindMaximumMatch(early_return);
+ if (match_count != count1 && early_return) return false;
+ success = success && (match_count == count1);
+ } else {
+ int start_offset = 0;
+ // If the two repeated fields are treated as sets, optimize for the case
+ // where both start with same items stored in the same order.
+ if (IsTreatedAsSet(repeated_field) || is_treated_as_smart_set ||
+ IsTreatedAsSmartList(repeated_field)) {
+ start_offset = std::min(count1, count2);
+ for (int i = 0; i < count1 && i < count2; i++) {
+ if (IsMatch(repeated_field, key_comparator, &message1, &message2,
+ parent_fields, nullptr, i, i)) {
+ match_list1->at(i) = i;
+ match_list2->at(i) = i;
+ } else {
+ start_offset = i;
+ break;
+ }
+ }
+ }
+ for (int i = start_offset; i < count1; ++i) {
+ // Indicates any matched elements for this repeated field.
+ bool match = false;
+ int matched_j = -1;
+
+ for (int j = start_offset; j < count2; j++) {
+ if (match_list2->at(j) != -1) {
+ if (!is_treated_as_smart_set || num_diffs_list1[i] == 0 ||
+ num_diffs_list1[match_list2->at(j)] == 0) {
+ continue;
+ }
+ }
+
+ if (is_treated_as_smart_set) {
+ num_diffs_reporter.Reset();
+ match = IsMatch(repeated_field, key_comparator, &message1, &message2,
+ parent_fields, &num_diffs_reporter, i, j);
+ } else {
+ match = IsMatch(repeated_field, key_comparator, &message1, &message2,
+ parent_fields, nullptr, i, j);
+ }
+
+ if (is_treated_as_smart_set) {
+ if (match) {
+ num_diffs_list1[i] = 0;
+ } else if (repeated_field->cpp_type() ==
+ FieldDescriptor::CPPTYPE_MESSAGE) {
+ // Replace with the one with fewer diffs.
+ const int32_t num_diffs = num_diffs_reporter.GetNumDiffs();
+ if (num_diffs < num_diffs_list1[i]) {
+ // If j has been already matched to some element, ensure the
+ // current num_diffs is smaller.
+ if (match_list2->at(j) == -1 ||
+ num_diffs < num_diffs_list1[match_list2->at(j)]) {
+ num_diffs_list1[i] = num_diffs;
+ match = true;
+ }
+ }
+ }
+ }
+
+ if (match) {
+ matched_j = j;
+ if (!is_treated_as_smart_set || num_diffs_list1[i] == 0) {
+ break;
+ }
+ }
+ }
+
+ match = (matched_j != -1);
+ if (match) {
+ if (is_treated_as_smart_set && match_list2->at(matched_j) != -1) {
+ // This is to revert the previously matched index in list2.
+ match_list1->at(match_list2->at(matched_j)) = -1;
+ match = false;
+ }
+ match_list1->at(i) = matched_j;
+ match_list2->at(matched_j) = i;
+ }
+ if (!match && reporter == nullptr) return false;
+ success = success && match;
+ }
+ }
+
+ if (IsTreatedAsSmartList(repeated_field)) {
+ match_indices_for_smart_list_callback_(match_list1, match_list2);
+ }
+
+ reporter_ = reporter;
+
+ return success;
+}
+
+FieldComparator::ComparisonResult MessageDifferencer::GetFieldComparisonResult(
+ const Message& message1, const Message& message2,
+ const FieldDescriptor* field, int index1, int index2,
+ const FieldContext* field_context) {
+ FieldComparator* comparator = field_comparator_kind_ == kFCBase
+ ? field_comparator_.base
+ : field_comparator_.default_impl;
+ return comparator->Compare(message1, message2, field, index1, index2,
+ field_context);
+}
+
+// ===========================================================================
+
+MessageDifferencer::Reporter::Reporter() {}
+MessageDifferencer::Reporter::~Reporter() {}
+
+// ===========================================================================
+
+MessageDifferencer::MapKeyComparator::MapKeyComparator() {}
+MessageDifferencer::MapKeyComparator::~MapKeyComparator() {}
+
+// ===========================================================================
+
+MessageDifferencer::IgnoreCriteria::IgnoreCriteria() {}
+MessageDifferencer::IgnoreCriteria::~IgnoreCriteria() {}
+
+// ===========================================================================
+
+// Note that the printer's delimiter is not used, because if we are given a
+// printer, we don't know its delimiter.
+MessageDifferencer::StreamReporter::StreamReporter(
+ io::ZeroCopyOutputStream* output)
+ : printer_(new io::Printer(output, '$')),
+ delete_printer_(true),
+ report_modified_aggregates_(false),
+ message1_(nullptr),
+ message2_(nullptr) {}
+
+MessageDifferencer::StreamReporter::StreamReporter(io::Printer* printer)
+ : printer_(printer),
+ delete_printer_(false),
+ report_modified_aggregates_(false),
+ message1_(nullptr),
+ message2_(nullptr) {}
+
+MessageDifferencer::StreamReporter::~StreamReporter() {
+ if (delete_printer_) delete printer_;
+}
+
+void MessageDifferencer::StreamReporter::PrintPath(
+ const std::vector<SpecificField>& field_path, bool left_side) {
+ for (size_t i = 0; i < field_path.size(); ++i) {
+ SpecificField specific_field = field_path[i];
+
+ if (specific_field.field != nullptr &&
+ specific_field.field->name() == "value") {
+ // check to see if this the value label of a map value. If so, skip it
+ // because it isn't meaningful
+ if (i > 0 && field_path[i - 1].field->is_map()) {
+ continue;
+ }
+ }
+ if (i > 0) {
+ printer_->Print(".");
+ }
+ if (specific_field.field != NULL) {
+ if (specific_field.field->is_extension()) {
+ printer_->Print("($name$)", "name", specific_field.field->full_name());
+ } else {
+ printer_->PrintRaw(specific_field.field->name());
+ }
+
+ if (specific_field.field->is_map()) {
+ PrintMapKey(left_side, specific_field);
+ continue;
+ }
+ } else {
+ printer_->PrintRaw(StrCat(specific_field.unknown_field_number));
+ }
+ if (left_side && specific_field.index >= 0) {
+ printer_->Print("[$name$]", "name", StrCat(specific_field.index));
+ }
+ if (!left_side && specific_field.new_index >= 0) {
+ printer_->Print("[$name$]", "name",
+ StrCat(specific_field.new_index));
+ }
+ }
+}
+
+
+void MessageDifferencer::StreamReporter::PrintValue(
+ const Message& message, const std::vector<SpecificField>& field_path,
+ bool left_side) {
+ const SpecificField& specific_field = field_path.back();
+ const FieldDescriptor* field = specific_field.field;
+ if (field != NULL) {
+ std::string output;
+ int index = left_side ? specific_field.index : specific_field.new_index;
+ if (field->cpp_type() == FieldDescriptor::CPPTYPE_MESSAGE) {
+ const Reflection* reflection = message.GetReflection();
+ const Message& field_message =
+ field->is_repeated()
+ ? reflection->GetRepeatedMessage(message, field, index)
+ : reflection->GetMessage(message, field);
+ const FieldDescriptor* fd = nullptr;
+
+ if (field->is_map() && message1_ != nullptr && message2_ != nullptr) {
+ fd = field_message.GetDescriptor()->field(1);
+ if (fd->cpp_type() == FieldDescriptor::CPPTYPE_MESSAGE) {
+ output = field_message.GetReflection()
+ ->GetMessage(field_message, fd)
+ .ShortDebugString();
+ } else {
+ TextFormat::PrintFieldValueToString(field_message, fd, -1, &output);
+ }
+ } else {
+ output = field_message.ShortDebugString();
+ }
+ if (output.empty()) {
+ printer_->Print("{ }");
+ } else {
+ if ((fd != nullptr) &&
+ (fd->cpp_type() != FieldDescriptor::CPPTYPE_MESSAGE)) {
+ printer_->PrintRaw(output);
+ } else {
+ printer_->Print("{ $name$ }", "name", output);
+ }
+ }
+ } else {
+ TextFormat::PrintFieldValueToString(message, field, index, &output);
+ printer_->PrintRaw(output);
+ }
+ } else {
+ const UnknownFieldSet* unknown_fields =
+ (left_side ? specific_field.unknown_field_set1
+ : specific_field.unknown_field_set2);
+ const UnknownField* unknown_field =
+ &unknown_fields->field(left_side ? specific_field.unknown_field_index1
+ : specific_field.unknown_field_index2);
+ PrintUnknownFieldValue(unknown_field);
+ }
+}
+
+void MessageDifferencer::StreamReporter::PrintUnknownFieldValue(
+ const UnknownField* unknown_field) {
+ GOOGLE_CHECK(unknown_field != NULL) << " Cannot print NULL unknown_field.";
+
+ std::string output;
+ switch (unknown_field->type()) {
+ case UnknownField::TYPE_VARINT:
+ output = StrCat(unknown_field->varint());
+ break;
+ case UnknownField::TYPE_FIXED32:
+ output = StrCat(
+ "0x", strings::Hex(unknown_field->fixed32(), strings::ZERO_PAD_8));
+ break;
+ case UnknownField::TYPE_FIXED64:
+ output = StrCat(
+ "0x", strings::Hex(unknown_field->fixed64(), strings::ZERO_PAD_16));
+ break;
+ case UnknownField::TYPE_LENGTH_DELIMITED:
+ output = StringPrintf(
+ "\"%s\"", CEscape(unknown_field->length_delimited()).c_str());
+ break;
+ case UnknownField::TYPE_GROUP:
+ // TODO(kenton): Print the contents of the group like we do for
+ // messages. Requires an equivalent of ShortDebugString() for
+ // UnknownFieldSet.
+ output = "{ ... }";
+ break;
+ }
+ printer_->PrintRaw(output);
+}
+
+void MessageDifferencer::StreamReporter::Print(const std::string& str) {
+ printer_->Print(str.c_str());
+}
+
+void MessageDifferencer::StreamReporter::PrintMapKey(
+ bool left_side, const SpecificField& specific_field) {
+ if (message1_ == nullptr || message2_ == nullptr) {
+ GOOGLE_LOG(INFO) << "PrintPath cannot log map keys; "
+ "use SetMessages to provide the messages "
+ "being compared prior to any processing.";
+ return;
+ }
+
+ const Message* found_message =
+ left_side ? specific_field.map_entry1 : specific_field.map_entry2;
+ std::string key_string = "";
+ if (found_message != nullptr) {
+ // NB: the map key is always the first field
+ const FieldDescriptor* fd = found_message->GetDescriptor()->field(0);
+ if (fd->cpp_type() == FieldDescriptor::CPPTYPE_STRING) {
+ // Not using PrintFieldValueToString for strings to avoid extra
+ // characters
+ key_string = found_message->GetReflection()->GetString(
+ *found_message, found_message->GetDescriptor()->field(0));
+ } else {
+ TextFormat::PrintFieldValueToString(*found_message, fd, -1, &key_string);
+ }
+ if (key_string.empty()) {
+ key_string = "''";
+ }
+ printer_->PrintRaw(StrCat("[", key_string, "]"));
+ }
+}
+
+void MessageDifferencer::StreamReporter::ReportAdded(
+ const Message& /*message1*/, const Message& message2,
+ const std::vector<SpecificField>& field_path) {
+ printer_->Print("added: ");
+ PrintPath(field_path, false);
+ printer_->Print(": ");
+ PrintValue(message2, field_path, false);
+ printer_->Print("\n"); // Print for newlines.
+}
+
+void MessageDifferencer::StreamReporter::ReportDeleted(
+ const Message& message1, const Message& /*message2*/,
+ const std::vector<SpecificField>& field_path) {
+ printer_->Print("deleted: ");
+ PrintPath(field_path, true);
+ printer_->Print(": ");
+ PrintValue(message1, field_path, true);
+ printer_->Print("\n"); // Print for newlines
+}
+
+void MessageDifferencer::StreamReporter::ReportModified(
+ const Message& message1, const Message& message2,
+ const std::vector<SpecificField>& field_path) {
+ if (!report_modified_aggregates_ && field_path.back().field == NULL) {
+ if (field_path.back().unknown_field_type == UnknownField::TYPE_GROUP) {
+ // Any changes to the subfields have already been printed.
+ return;
+ }
+ } else if (!report_modified_aggregates_) {
+ if (field_path.back().field->cpp_type() ==
+ FieldDescriptor::CPPTYPE_MESSAGE) {
+ // Any changes to the subfields have already been printed.
+ return;
+ }
+ }
+
+ printer_->Print("modified: ");
+ PrintPath(field_path, true);
+ if (CheckPathChanged(field_path)) {
+ printer_->Print(" -> ");
+ PrintPath(field_path, false);
+ }
+ printer_->Print(": ");
+ PrintValue(message1, field_path, true);
+ printer_->Print(" -> ");
+ PrintValue(message2, field_path, false);
+ printer_->Print("\n"); // Print for newlines.
+}
+
+void MessageDifferencer::StreamReporter::ReportMoved(
+ const Message& message1, const Message& /*message2*/,
+ const std::vector<SpecificField>& field_path) {
+ printer_->Print("moved: ");
+ PrintPath(field_path, true);
+ printer_->Print(" -> ");
+ PrintPath(field_path, false);
+ printer_->Print(" : ");
+ PrintValue(message1, field_path, true);
+ printer_->Print("\n"); // Print for newlines.
+}
+
+void MessageDifferencer::StreamReporter::ReportMatched(
+ const Message& message1, const Message& /*message2*/,
+ const std::vector<SpecificField>& field_path) {
+ printer_->Print("matched: ");
+ PrintPath(field_path, true);
+ if (CheckPathChanged(field_path)) {
+ printer_->Print(" -> ");
+ PrintPath(field_path, false);
+ }
+ printer_->Print(" : ");
+ PrintValue(message1, field_path, true);
+ printer_->Print("\n"); // Print for newlines.
+}
+
+void MessageDifferencer::StreamReporter::ReportIgnored(
+ const Message& /*message1*/, const Message& /*message2*/,
+ const std::vector<SpecificField>& field_path) {
+ printer_->Print("ignored: ");
+ PrintPath(field_path, true);
+ if (CheckPathChanged(field_path)) {
+ printer_->Print(" -> ");
+ PrintPath(field_path, false);
+ }
+ printer_->Print("\n"); // Print for newlines.
+}
+
+void MessageDifferencer::StreamReporter::SetMessages(const Message& message1,
+ const Message& message2) {
+ message1_ = &message1;
+ message2_ = &message2;
+}
+
+void MessageDifferencer::StreamReporter::ReportUnknownFieldIgnored(
+ const Message& /*message1*/, const Message& /*message2*/,
+ const std::vector<SpecificField>& field_path) {
+ printer_->Print("ignored: ");
+ PrintPath(field_path, true);
+ if (CheckPathChanged(field_path)) {
+ printer_->Print(" -> ");
+ PrintPath(field_path, false);
+ }
+ printer_->Print("\n"); // Print for newlines.
+}
+
+MessageDifferencer::MapKeyComparator*
+MessageDifferencer::CreateMultipleFieldsMapKeyComparator(
+ const std::vector<std::vector<const FieldDescriptor*> >& key_field_paths) {
+ return new MultipleFieldsMapKeyComparator(this, key_field_paths);
+}
+
+} // namespace util
+} // namespace protobuf
+} // namespace google