native/actions/regex-actions.cc - platform/external/libtextclassifier - Git at Google

 /*
  * Copyright (C) 2018 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "actions/regex-actions.h"

 #include "actions/utils.h"
 #include "utils/base/logging.h"
 #include "utils/regex-match.h"
 #include "utils/utf8/unicodetext.h"
 #include "utils/zlib/zlib_regex.h"

 namespace libtextclassifier3 {
 namespace {

 // Creates an annotation from a regex capturing group.
 bool FillAnnotationFromMatchGroup(
     const UniLib::RegexMatcher* matcher,
     const RulesModel_::RuleActionSpec_::RuleCapturingGroup* group,
     const std::string& group_match_text, const int message_index,
     ActionSuggestionAnnotation* annotation) {
   if (group->annotation_name() != nullptr ||
       group->annotation_type() != nullptr) {
     int status = UniLib::RegexMatcher::kNoError;
     const CodepointSpan span = {matcher->Start(group->group_id(), &status),
                                 matcher->End(group->group_id(), &status)};
     if (status != UniLib::RegexMatcher::kNoError) {
       TC3_LOG(ERROR) << "Could not extract span from rule capturing group.";
       return false;
     }
     return FillAnnotationFromCapturingMatch(span, group, message_index,
                                             group_match_text, annotation);
   }
   return true;
 }

 }  // namespace

 bool RegexActions::InitializeRules(
     const RulesModel* rules, const RulesModel* low_confidence_rules,
     const TriggeringPreconditions* triggering_preconditions_overlay,
     ZlibDecompressor* decompressor) {
   if (rules != nullptr) {
     if (!InitializeRulesModel(rules, decompressor, &rules_)) {
       TC3_LOG(ERROR) << "Could not initialize action rules.";
       return false;
     }
   }

   if (low_confidence_rules != nullptr) {
     if (!InitializeRulesModel(low_confidence_rules, decompressor,
                               &low_confidence_rules_)) {
       TC3_LOG(ERROR) << "Could not initialize low confidence rules.";
       return false;
     }
   }

   // Extend by rules provided by the overwrite.
   // NOTE: The rules from the original models are *not* cleared.
   if (triggering_preconditions_overlay != nullptr &&
       triggering_preconditions_overlay->low_confidence_rules() != nullptr) {
     // These rules are optionally compressed, but separately.
     std::unique_ptr<ZlibDecompressor> overwrite_decompressor =
         ZlibDecompressor::Instance();
     if (overwrite_decompressor == nullptr) {
       TC3_LOG(ERROR) << "Could not initialze decompressor for overwrite rules.";
       return false;
     }
     if (!InitializeRulesModel(
             triggering_preconditions_overlay->low_confidence_rules(),
             overwrite_decompressor.get(), &low_confidence_rules_)) {
       TC3_LOG(ERROR)
           << "Could not initialize low confidence rules from overwrite.";
       return false;
     }
   }

   return true;
 }

 bool RegexActions::InitializeRulesModel(
     const RulesModel* rules, ZlibDecompressor* decompressor,
     std::vector<CompiledRule>* compiled_rules) const {
   if (rules->regex_rule() == nullptr) {
     return true;
   }
   for (const RulesModel_::RegexRule* rule : *rules->regex_rule()) {
     std::unique_ptr<UniLib::RegexPattern> compiled_pattern =
         UncompressMakeRegexPattern(
             unilib_, rule->pattern(), rule->compressed_pattern(),
             rules->lazy_regex_compilation(), decompressor);
     if (compiled_pattern == nullptr) {
       TC3_LOG(ERROR) << "Failed to load rule pattern.";
       return false;
     }

     // Check whether there is a check on the output.
     std::unique_ptr<UniLib::RegexPattern> compiled_output_pattern;
     if (rule->output_pattern() != nullptr ||
         rule->compressed_output_pattern() != nullptr) {
       compiled_output_pattern = UncompressMakeRegexPattern(
           unilib_, rule->output_pattern(), rule->compressed_output_pattern(),
           rules->lazy_regex_compilation(), decompressor);
       if (compiled_output_pattern == nullptr) {
         TC3_LOG(ERROR) << "Failed to load rule output pattern.";
         return false;
       }
     }

     compiled_rules->emplace_back(rule, std::move(compiled_pattern),
                                  std::move(compiled_output_pattern));
   }

   return true;
 }

 bool RegexActions::IsLowConfidenceInput(
     const Conversation& conversation, const int num_messages,
     std::vector<const UniLib::RegexPattern*>* post_check_rules) const {
   for (int i = 1; i <= num_messages; i++) {
     const std::string& message =
         conversation.messages[conversation.messages.size() - i].text;
     const UnicodeText message_unicode(
         UTF8ToUnicodeText(message, /*do_copy=*/false));
     for (int low_confidence_rule = 0;
          low_confidence_rule < low_confidence_rules_.size();
          low_confidence_rule++) {
       const CompiledRule& rule = low_confidence_rules_[low_confidence_rule];
       const std::unique_ptr<UniLib::RegexMatcher> matcher =
           rule.pattern->Matcher(message_unicode);
       int status = UniLib::RegexMatcher::kNoError;
       if (matcher->Find(&status) && status == UniLib::RegexMatcher::kNoError) {
         // Rule only applies to input-output pairs, so defer the check.
         if (rule.output_pattern != nullptr) {
           post_check_rules->push_back(rule.output_pattern.get());
           continue;
         }
         return true;
       }
     }
   }
   return false;
 }

 bool RegexActions::FilterConfidenceOutput(
     const std::vector<const UniLib::RegexPattern*>& post_check_rules,
     std::vector<ActionSuggestion>* actions) const {
   if (post_check_rules.empty() || actions->empty()) {
     return true;
   }
   std::vector<ActionSuggestion> filtered_text_replies;
   for (const ActionSuggestion& action : *actions) {
     if (action.response_text.empty()) {
       filtered_text_replies.push_back(action);
       continue;
     }
     bool passes_post_check = true;
     const UnicodeText text_reply_unicode(
         UTF8ToUnicodeText(action.response_text, /*do_copy=*/false));
     for (const UniLib::RegexPattern* post_check_rule : post_check_rules) {
       const std::unique_ptr<UniLib::RegexMatcher> matcher =
           post_check_rule->Matcher(text_reply_unicode);
       if (matcher == nullptr) {
         TC3_LOG(ERROR) << "Could not create matcher for post check rule.";
         return false;
       }
       int status = UniLib::RegexMatcher::kNoError;
       if (matcher->Find(&status) || status != UniLib::RegexMatcher::kNoError) {
         passes_post_check = false;
         break;
       }
     }
     if (passes_post_check) {
       filtered_text_replies.push_back(action);
     }
   }
   *actions = std::move(filtered_text_replies);
   return true;
 }

 bool RegexActions::SuggestActions(
     const Conversation& conversation,
     const MutableFlatbufferBuilder* entity_data_builder,
     std::vector<ActionSuggestion>* actions) const {
   // Create actions based on rules checking the last message.
   const int message_index = conversation.messages.size() - 1;
   const std::string& message = conversation.messages.back().text;
   const UnicodeText message_unicode(
       UTF8ToUnicodeText(message, /*do_copy=*/false));
   for (const CompiledRule& rule : rules_) {
     const std::unique_ptr<UniLib::RegexMatcher> matcher =
         rule.pattern->Matcher(message_unicode);
     int status = UniLib::RegexMatcher::kNoError;
     while (matcher->Find(&status) && status == UniLib::RegexMatcher::kNoError) {
       for (const RulesModel_::RuleActionSpec* rule_action :
            *rule.rule->actions()) {
         const ActionSuggestionSpec* action = rule_action->action();
         std::vector<ActionSuggestionAnnotation> annotations;

         std::unique_ptr<MutableFlatbuffer> entity_data =
             entity_data_builder != nullptr ? entity_data_builder->NewRoot()
                                            : nullptr;

         // Add entity data from rule capturing groups.
         if (rule_action->capturing_group() != nullptr) {
           for (const RulesModel_::RuleActionSpec_::RuleCapturingGroup* group :
                *rule_action->capturing_group()) {
             Optional<std::string> group_match_text =
                 GetCapturingGroupText(matcher.get(), group->group_id());
             if (!group_match_text.has_value()) {
               // The group was not part of the match, ignore and continue.
               continue;
             }

             UnicodeText normalized_group_match_text =
                 NormalizeMatchText(unilib_, group, group_match_text.value());

             if (!MergeEntityDataFromCapturingMatch(
                     group, normalized_group_match_text.ToUTF8String(),
                     entity_data.get())) {
               TC3_LOG(ERROR)
                   << "Could not merge entity data from a capturing match.";
               return false;
             }

             // Create a text annotation for the group span.
             ActionSuggestionAnnotation annotation;
             if (FillAnnotationFromMatchGroup(matcher.get(), group,
                                              group_match_text.value(),
                                              message_index, &annotation)) {
               annotations.push_back(annotation);
             }

             // Create text reply.
             SuggestTextRepliesFromCapturingMatch(
                 entity_data_builder, group, normalized_group_match_text,
                 smart_reply_action_type_, actions);
           }
         }

         if (action != nullptr) {
           ActionSuggestion suggestion;
           suggestion.annotations = annotations;
           FillSuggestionFromSpec(action, entity_data.get(), &suggestion);
           actions->push_back(suggestion);
         }
       }
     }
   }
   return true;
 }

 }  // namespace libtextclassifier3
	/*
	* Copyright (C) 2018 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "actions/regex-actions.h"

	#include "actions/utils.h"
	#include "utils/base/logging.h"
	#include "utils/regex-match.h"
	#include "utils/utf8/unicodetext.h"
	#include "utils/zlib/zlib_regex.h"

	namespace libtextclassifier3 {
	namespace {

	// Creates an annotation from a regex capturing group.
	bool FillAnnotationFromMatchGroup(
	const UniLib::RegexMatcher* matcher,
	const RulesModel_::RuleActionSpec_::RuleCapturingGroup* group,
	const std::string& group_match_text, const int message_index,
	ActionSuggestionAnnotation* annotation) {
	if (group->annotation_name() != nullptr \|\|
	group->annotation_type() != nullptr) {
	int status = UniLib::RegexMatcher::kNoError;
	const CodepointSpan span = {matcher->Start(group->group_id(), &status),
	matcher->End(group->group_id(), &status)};
	if (status != UniLib::RegexMatcher::kNoError) {
	TC3_LOG(ERROR) << "Could not extract span from rule capturing group.";
	return false;
	}
	return FillAnnotationFromCapturingMatch(span, group, message_index,
	group_match_text, annotation);
	}
	return true;
	}

	} // namespace

	bool RegexActions::InitializeRules(
	const RulesModel* rules, const RulesModel* low_confidence_rules,
	const TriggeringPreconditions* triggering_preconditions_overlay,
	ZlibDecompressor* decompressor) {
	if (rules != nullptr) {
	if (!InitializeRulesModel(rules, decompressor, &rules_)) {
	TC3_LOG(ERROR) << "Could not initialize action rules.";
	return false;
	}
	}

	if (low_confidence_rules != nullptr) {
	if (!InitializeRulesModel(low_confidence_rules, decompressor,
	&low_confidence_rules_)) {
	TC3_LOG(ERROR) << "Could not initialize low confidence rules.";
	return false;
	}
	}

	// Extend by rules provided by the overwrite.
	// NOTE: The rules from the original models are not cleared.
	if (triggering_preconditions_overlay != nullptr &&
	triggering_preconditions_overlay->low_confidence_rules() != nullptr) {
	// These rules are optionally compressed, but separately.
	std::unique_ptr<ZlibDecompressor> overwrite_decompressor =
	ZlibDecompressor::Instance();
	if (overwrite_decompressor == nullptr) {
	TC3_LOG(ERROR) << "Could not initialze decompressor for overwrite rules.";
	return false;
	}
	if (!InitializeRulesModel(
	triggering_preconditions_overlay->low_confidence_rules(),
	overwrite_decompressor.get(), &low_confidence_rules_)) {
	TC3_LOG(ERROR)
	<< "Could not initialize low confidence rules from overwrite.";
	return false;
	}
	}

	return true;
	}

	bool RegexActions::InitializeRulesModel(
	const RulesModel* rules, ZlibDecompressor* decompressor,
	std::vector<CompiledRule>* compiled_rules) const {
	if (rules->regex_rule() == nullptr) {
	return true;
	}
	for (const RulesModel_::RegexRule* rule : *rules->regex_rule()) {
	std::unique_ptr<UniLib::RegexPattern> compiled_pattern =
	UncompressMakeRegexPattern(
	unilib_, rule->pattern(), rule->compressed_pattern(),
	rules->lazy_regex_compilation(), decompressor);
	if (compiled_pattern == nullptr) {
	TC3_LOG(ERROR) << "Failed to load rule pattern.";
	return false;
	}

	// Check whether there is a check on the output.
	std::unique_ptr<UniLib::RegexPattern> compiled_output_pattern;
	if (rule->output_pattern() != nullptr \|\|
	rule->compressed_output_pattern() != nullptr) {
	compiled_output_pattern = UncompressMakeRegexPattern(
	unilib_, rule->output_pattern(), rule->compressed_output_pattern(),
	rules->lazy_regex_compilation(), decompressor);
	if (compiled_output_pattern == nullptr) {
	TC3_LOG(ERROR) << "Failed to load rule output pattern.";
	return false;
	}
	}

	compiled_rules->emplace_back(rule, std::move(compiled_pattern),
	std::move(compiled_output_pattern));
	}

	return true;
	}

	bool RegexActions::IsLowConfidenceInput(
	const Conversation& conversation, const int num_messages,
	std::vector<const UniLib::RegexPattern> post_check_rules) const {
	for (int i = 1; i <= num_messages; i++) {
	const std::string& message =
	conversation.messages[conversation.messages.size() - i].text;
	const UnicodeText message_unicode(
	UTF8ToUnicodeText(message, /do_copy=/false));
	for (int low_confidence_rule = 0;
	low_confidence_rule < low_confidence_rules_.size();
	low_confidence_rule++) {
	const CompiledRule& rule = low_confidence_rules_[low_confidence_rule];
	const std::unique_ptr<UniLib::RegexMatcher> matcher =
	rule.pattern->Matcher(message_unicode);
	int status = UniLib::RegexMatcher::kNoError;
	if (matcher->Find(&status) && status == UniLib::RegexMatcher::kNoError) {
	// Rule only applies to input-output pairs, so defer the check.
	if (rule.output_pattern != nullptr) {
	post_check_rules->push_back(rule.output_pattern.get());
	continue;
	}
	return true;
	}
	}
	}
	return false;
	}

	bool RegexActions::FilterConfidenceOutput(
	const std::vector<const UniLib::RegexPattern*>& post_check_rules,
	std::vector<ActionSuggestion>* actions) const {
	if (post_check_rules.empty() \|\| actions->empty()) {
	return true;
	}
	std::vector<ActionSuggestion> filtered_text_replies;
	for (const ActionSuggestion& action : *actions) {
	if (action.response_text.empty()) {
	filtered_text_replies.push_back(action);
	continue;
	}
	bool passes_post_check = true;
	const UnicodeText text_reply_unicode(
	UTF8ToUnicodeText(action.response_text, /do_copy=/false));
	for (const UniLib::RegexPattern* post_check_rule : post_check_rules) {
	const std::unique_ptr<UniLib::RegexMatcher> matcher =
	post_check_rule->Matcher(text_reply_unicode);
	if (matcher == nullptr) {
	TC3_LOG(ERROR) << "Could not create matcher for post check rule.";
	return false;
	}
	int status = UniLib::RegexMatcher::kNoError;
	if (matcher->Find(&status) \|\| status != UniLib::RegexMatcher::kNoError) {
	passes_post_check = false;
	break;
	}
	}
	if (passes_post_check) {
	filtered_text_replies.push_back(action);
	}
	}
	*actions = std::move(filtered_text_replies);
	return true;
	}

	bool RegexActions::SuggestActions(
	const Conversation& conversation,
	const MutableFlatbufferBuilder* entity_data_builder,
	std::vector<ActionSuggestion>* actions) const {
	// Create actions based on rules checking the last message.
	const int message_index = conversation.messages.size() - 1;
	const std::string& message = conversation.messages.back().text;
	const UnicodeText message_unicode(
	UTF8ToUnicodeText(message, /do_copy=/false));
	for (const CompiledRule& rule : rules_) {
	const std::unique_ptr<UniLib::RegexMatcher> matcher =
	rule.pattern->Matcher(message_unicode);
	int status = UniLib::RegexMatcher::kNoError;
	while (matcher->Find(&status) && status == UniLib::RegexMatcher::kNoError) {
	for (const RulesModel_::RuleActionSpec* rule_action :
	*rule.rule->actions()) {
	const ActionSuggestionSpec* action = rule_action->action();
	std::vector<ActionSuggestionAnnotation> annotations;

	std::unique_ptr<MutableFlatbuffer> entity_data =
	entity_data_builder != nullptr ? entity_data_builder->NewRoot()
	: nullptr;

	// Add entity data from rule capturing groups.
	if (rule_action->capturing_group() != nullptr) {
	for (const RulesModel_::RuleActionSpec_::RuleCapturingGroup* group :
	*rule_action->capturing_group()) {
	Optional<std::string> group_match_text =
	GetCapturingGroupText(matcher.get(), group->group_id());
	if (!group_match_text.has_value()) {
	// The group was not part of the match, ignore and continue.
	continue;
	}

	UnicodeText normalized_group_match_text =
	NormalizeMatchText(unilib_, group, group_match_text.value());

	if (!MergeEntityDataFromCapturingMatch(
	group, normalized_group_match_text.ToUTF8String(),
	entity_data.get())) {
	TC3_LOG(ERROR)
	<< "Could not merge entity data from a capturing match.";
	return false;
	}

	// Create a text annotation for the group span.
	ActionSuggestionAnnotation annotation;
	if (FillAnnotationFromMatchGroup(matcher.get(), group,
	group_match_text.value(),
	message_index, &annotation)) {
	annotations.push_back(annotation);
	}

	// Create text reply.
	SuggestTextRepliesFromCapturingMatch(
	entity_data_builder, group, normalized_group_match_text,
	smart_reply_action_type_, actions);
	}
	}

	if (action != nullptr) {
	ActionSuggestion suggestion;
	suggestion.annotations = annotations;
	FillSuggestionFromSpec(action, entity_data.get(), &suggestion);
	actions->push_back(suggestion);
	}
	}
	}
	}
	return true;
	}

	} // namespace libtextclassifier3