v0_1_5/lib/marisa_alpha/trie-inline.h - platform/external/marisa-trie - Git at Google

 #ifndef MARISA_ALPHA_TRIE_INLINE_H_
 #define MARISA_ALPHA_TRIE_INLINE_H_

 #include <stdexcept>

 #include "cell.h"

 namespace marisa_alpha {

 inline std::string Trie::operator[](UInt32 key_id) const {
   std::string key;
   restore(key_id, &key);
   return key;
 }

 inline UInt32 Trie::operator[](const char *str) const {
   return lookup(str);
 }

 inline UInt32 Trie::operator[](const std::string &str) const {
   return lookup(str);
 }

 inline UInt32 Trie::lookup(const std::string &str) const {
   return lookup(str.c_str(), str.length());
 }

 inline std::size_t Trie::find(const std::string &str,
     UInt32 *key_ids, std::size_t *key_lengths,
     std::size_t max_num_results) const {
   return find(str.c_str(), str.length(),
       key_ids, key_lengths, max_num_results);
 }

 inline std::size_t Trie::find(const std::string &str,
     std::vector<UInt32> *key_ids, std::vector<std::size_t> *key_lengths,
     std::size_t max_num_results) const {
   return find(str.c_str(), str.length(),
       key_ids, key_lengths, max_num_results);
 }

 inline UInt32 Trie::find_first(const std::string &str,
     std::size_t *key_length) const {
   return find_first(str.c_str(), str.length(), key_length);
 }

 inline UInt32 Trie::find_last(const std::string &str,
     std::size_t *key_length) const {
   return find_last(str.c_str(), str.length(), key_length);
 }

 template <typename T>
 inline std::size_t Trie::find_callback(const char *str,
     T callback) const {
   MARISA_ALPHA_THROW_IF(empty(), MARISA_ALPHA_STATE_ERROR);
   MARISA_ALPHA_THROW_IF(str == NULL, MARISA_ALPHA_PARAM_ERROR);
   return find_callback_<CQuery>(CQuery(str), callback);
 }

 template <typename T>
 inline std::size_t Trie::find_callback(const char *ptr, std::size_t length,
     T callback) const {
   MARISA_ALPHA_THROW_IF(empty(), MARISA_ALPHA_STATE_ERROR);
   MARISA_ALPHA_THROW_IF((ptr == NULL) && (length != 0),
       MARISA_ALPHA_PARAM_ERROR);
   return find_callback_<const Query &>(Query(ptr, length), callback);
 }

 template <typename T>
 inline std::size_t Trie::find_callback(const std::string &str,
     T callback) const {
   return find_callback(str.c_str(), str.length(), callback);
 }

 inline std::size_t Trie::predict(const std::string &str,
     UInt32 *key_ids, std::string *keys, std::size_t max_num_results) const {
   return predict(str.c_str(), str.length(), key_ids, keys, max_num_results);
 }

 inline std::size_t Trie::predict(const std::string &str,
     std::vector<UInt32> *key_ids, std::vector<std::string> *keys,
     std::size_t max_num_results) const {
   return predict(str.c_str(), str.length(), key_ids, keys, max_num_results);
 }

 inline std::size_t Trie::predict_breadth_first(const std::string &str,
     UInt32 *key_ids, std::string *keys, std::size_t max_num_results) const {
   return predict_breadth_first(str.c_str(), str.length(),
       key_ids, keys, max_num_results);
 }

 inline std::size_t Trie::predict_breadth_first(const std::string &str,
     std::vector<UInt32> *key_ids, std::vector<std::string> *keys,
     std::size_t max_num_results) const {
   return predict_breadth_first(str.c_str(), str.length(),
       key_ids, keys, max_num_results);
 }

 inline std::size_t Trie::predict_depth_first(const std::string &str,
     UInt32 *key_ids, std::string *keys, std::size_t max_num_results) const {
   return predict_depth_first(str.c_str(), str.length(),
       key_ids, keys, max_num_results);
 }

 inline std::size_t Trie::predict_depth_first(const std::string &str,
     std::vector<UInt32> *key_ids, std::vector<std::string> *keys,
     std::size_t max_num_results) const {
   return predict_depth_first(str.c_str(), str.length(),
       key_ids, keys, max_num_results);
 }

 template <typename T>
 inline std::size_t Trie::predict_callback(
     const char *str, T callback) const {
   return predict_callback_<CQuery>(CQuery(str), callback);
 }

 template <typename T>
 inline std::size_t Trie::predict_callback(
     const char *ptr, std::size_t length,
     T callback) const {
   return predict_callback_<const Query &>(Query(ptr, length), callback);
 }

 template <typename T>
 inline std::size_t Trie::predict_callback(
     const std::string &str, T callback) const {
   return predict_callback(str.c_str(), str.length(), callback);
 }

 inline bool Trie::empty() const {
   return louds_.empty();
 }

 inline std::size_t Trie::num_keys() const {
   return num_keys_;
 }

 inline UInt32 Trie::notfound() {
   return MARISA_ALPHA_NOT_FOUND;
 }

 inline std::size_t Trie::mismatch() {
   return MARISA_ALPHA_MISMATCH;
 }

 template <typename T>
 inline bool Trie::find_child(UInt32 &node, T query,
     std::size_t &pos) const {
   UInt32 louds_pos = get_child(node);
   if (!louds_[louds_pos]) {
     return false;
   }
   node = louds_pos_to_node(louds_pos, node);
   UInt32 link_id = MARISA_ALPHA_UINT32_MAX;
   do {
     if (has_link(node)) {
       if (link_id == MARISA_ALPHA_UINT32_MAX) {
         link_id = get_link_id(node);
       } else {
         ++link_id;
       }
       std::size_t next_pos = has_trie() ?
           trie_->trie_match<T>(get_link(node, link_id), query, pos) :
           tail_match<T>(node, link_id, query, pos);
       if (next_pos == mismatch()) {
         return false;
       } else if (next_pos != pos) {
         pos = next_pos;
         return true;
       }
     } else if (labels_[node] == query[pos]) {
       ++pos;
       return true;
     }
     ++node;
     ++louds_pos;
   } while (louds_[louds_pos]);
   return false;
 }

 template <typename T, typename U>
 std::size_t Trie::find_callback_(T query, U callback) const try {
   std::size_t count = 0;
   UInt32 node = 0;
   std::size_t pos = 0;
   do {
     if (terminal_flags_[node]) {
       ++count;
       if (!callback(node_to_key_id(node), pos)) {
         return count;
       }
     }
   } while (!query.ends_at(pos) && find_child<T>(node, query, pos));
   return count;
 } catch (const std::bad_alloc &) {
   MARISA_ALPHA_THROW(MARISA_ALPHA_MEMORY_ERROR);
 } catch (const std::length_error &) {
   MARISA_ALPHA_THROW(MARISA_ALPHA_SIZE_ERROR);
 }

 template <typename T>
 inline bool Trie::predict_child(UInt32 &node, T query, std::size_t &pos,
     std::string *key) const {
   UInt32 louds_pos = get_child(node);
   if (!louds_[louds_pos]) {
     return false;
   }
   node = louds_pos_to_node(louds_pos, node);
   UInt32 link_id = MARISA_ALPHA_UINT32_MAX;
   do {
     if (has_link(node)) {
       if (link_id == MARISA_ALPHA_UINT32_MAX) {
         link_id = get_link_id(node);
       } else {
         ++link_id;
       }
       std::size_t next_pos = has_trie() ?
           trie_->trie_prefix_match<T>(
               get_link(node, link_id), query, pos, key) :
           tail_prefix_match<T>(node, link_id, query, pos, key);
       if (next_pos == mismatch()) {
         return false;
       } else if (next_pos != pos) {
         pos = next_pos;
         return true;
       }
     } else if (labels_[node] == query[pos]) {
       ++pos;
       return true;
     }
     ++node;
     ++louds_pos;
   } while (louds_[louds_pos]);
   return false;
 }

 template <typename T, typename U>
 std::size_t Trie::predict_callback_(T query, U callback) const try {
   std::string key;
   UInt32 node = 0;
   std::size_t pos = 0;
   while (!query.ends_at(pos)) {
     if (!predict_child<T>(node, query, pos, &key)) {
       return 0;
     }
   }
   query.insert(&key);
   std::size_t count = 0;
   if (terminal_flags_[node]) {
     ++count;
     if (!callback(node_to_key_id(node), key)) {
       return count;
     }
   }
   Cell cell;
   cell.set_louds_pos(get_child(node));
   if (!louds_[cell.louds_pos()]) {
     return count;
   }
   cell.set_node(louds_pos_to_node(cell.louds_pos(), node));
   cell.set_key_id(node_to_key_id(cell.node()));
   cell.set_length(key.length());
   Vector<Cell> stack;
   stack.push_back(cell);
   std::size_t stack_pos = 1;
   while (stack_pos != 0) {
     Cell &cur = stack[stack_pos - 1];
     if (!louds_[cur.louds_pos()]) {
       cur.set_louds_pos(cur.louds_pos() + 1);
       --stack_pos;
       continue;
     }
     cur.set_louds_pos(cur.louds_pos() + 1);
     key.resize(cur.length());
     if (has_link(cur.node())) {
       if (has_trie()) {
         trie_->trie_restore(get_link(cur.node()), &key);
       } else {
         tail_restore(cur.node(), &key);
       }
     } else {
       key += labels_[cur.node()];
     }
     if (terminal_flags_[cur.node()]) {
       ++count;
       if (!callback(cur.key_id(), key)) {
         return count;
       }
       cur.set_key_id(cur.key_id() + 1);
     }
     if (stack_pos == stack.size()) {
       cell.set_louds_pos(get_child(cur.node()));
       cell.set_node(louds_pos_to_node(cell.louds_pos(), cur.node()));
       cell.set_key_id(node_to_key_id(cell.node()));
       stack.push_back(cell);
     }
     stack[stack_pos].set_length(key.length());
     stack[stack_pos - 1].set_node(stack[stack_pos - 1].node() + 1);
     ++stack_pos;
   }
   return count;
 } catch (const std::bad_alloc &) {
   MARISA_ALPHA_THROW(MARISA_ALPHA_MEMORY_ERROR);
 } catch (const std::length_error &) {
   MARISA_ALPHA_THROW(MARISA_ALPHA_SIZE_ERROR);
 }

 inline UInt32 Trie::key_id_to_node(UInt32 key_id) const {
   return terminal_flags_.select1(key_id);
 }

 inline UInt32 Trie::node_to_key_id(UInt32 node) const {
   return terminal_flags_.rank1(node);
 }

 inline UInt32 Trie::louds_pos_to_node(UInt32 louds_pos,
     UInt32 parent_node) const {
   return louds_pos - parent_node - 1;
 }

 inline UInt32 Trie::get_child(UInt32 node) const {
   return louds_.select0(node) + 1;
 }

 inline UInt32 Trie::get_parent(UInt32 node) const {
   return (node > num_first_branches_) ? (louds_.select1(node) - node - 1) : 0;
 }

 inline bool Trie::has_link(UInt32 node) const {
   return (link_flags_.empty()) ? false : link_flags_[node];
 }

 inline UInt32 Trie::get_link_id(UInt32 node) const {
   return link_flags_.rank1(node);
 }

 inline UInt32 Trie::get_link(UInt32 node) const {
   return get_link(node, get_link_id(node));
 }

 inline UInt32 Trie::get_link(UInt32 node, UInt32 link_id) const {
   return (links_[link_id] * 256) + labels_[node];
 }

 inline bool Trie::has_link() const {
   return !link_flags_.empty();
 }

 inline bool Trie::has_trie() const {
   return trie_.get() != NULL;
 }

 inline bool Trie::has_tail() const {
   return !tail_.empty();
 }

 }  // namespace marisa_alpha

 #endif  // MARISA_ALPHA_TRIE_INLINE_H_
	#ifndef MARISA_ALPHA_TRIE_INLINE_H_
	#define MARISA_ALPHA_TRIE_INLINE_H_

	#include <stdexcept>

	#include "cell.h"

	namespace marisa_alpha {

	inline std::string Trie::operator[](UInt32 key_id) const {
	std::string key;
	restore(key_id, &key);
	return key;
	}

	inline UInt32 Trie::operator[](const char *str) const {
	return lookup(str);
	}

	inline UInt32 Trie::operator[](const std::string &str) const {
	return lookup(str);
	}

	inline UInt32 Trie::lookup(const std::string &str) const {
	return lookup(str.c_str(), str.length());
	}

	inline std::size_t Trie::find(const std::string &str,
	UInt32 key_ids, std::size_t key_lengths,
	std::size_t max_num_results) const {
	return find(str.c_str(), str.length(),
	key_ids, key_lengths, max_num_results);
	}

	inline std::size_t Trie::find(const std::string &str,
	std::vector<UInt32> key_ids, std::vector<std::size_t> key_lengths,
	std::size_t max_num_results) const {
	return find(str.c_str(), str.length(),
	key_ids, key_lengths, max_num_results);
	}

	inline UInt32 Trie::find_first(const std::string &str,
	std::size_t *key_length) const {
	return find_first(str.c_str(), str.length(), key_length);
	}

	inline UInt32 Trie::find_last(const std::string &str,
	std::size_t *key_length) const {
	return find_last(str.c_str(), str.length(), key_length);
	}

	template <typename T>
	inline std::size_t Trie::find_callback(const char *str,
	T callback) const {
	MARISA_ALPHA_THROW_IF(empty(), MARISA_ALPHA_STATE_ERROR);
	MARISA_ALPHA_THROW_IF(str == NULL, MARISA_ALPHA_PARAM_ERROR);
	return find_callback_<CQuery>(CQuery(str), callback);
	}

	template <typename T>
	inline std::size_t Trie::find_callback(const char *ptr, std::size_t length,
	T callback) const {
	MARISA_ALPHA_THROW_IF(empty(), MARISA_ALPHA_STATE_ERROR);
	MARISA_ALPHA_THROW_IF((ptr == NULL) && (length != 0),
	MARISA_ALPHA_PARAM_ERROR);
	return find_callback_<const Query &>(Query(ptr, length), callback);
	}

	template <typename T>
	inline std::size_t Trie::find_callback(const std::string &str,
	T callback) const {
	return find_callback(str.c_str(), str.length(), callback);
	}

	inline std::size_t Trie::predict(const std::string &str,
	UInt32 key_ids, std::string keys, std::size_t max_num_results) const {
	return predict(str.c_str(), str.length(), key_ids, keys, max_num_results);
	}

	inline std::size_t Trie::predict(const std::string &str,
	std::vector<UInt32> key_ids, std::vector<std::string> keys,
	std::size_t max_num_results) const {
	return predict(str.c_str(), str.length(), key_ids, keys, max_num_results);
	}

	inline std::size_t Trie::predict_breadth_first(const std::string &str,
	UInt32 key_ids, std::string keys, std::size_t max_num_results) const {
	return predict_breadth_first(str.c_str(), str.length(),
	key_ids, keys, max_num_results);
	}

	inline std::size_t Trie::predict_breadth_first(const std::string &str,
	std::vector<UInt32> key_ids, std::vector<std::string> keys,
	std::size_t max_num_results) const {
	return predict_breadth_first(str.c_str(), str.length(),
	key_ids, keys, max_num_results);
	}

	inline std::size_t Trie::predict_depth_first(const std::string &str,
	UInt32 key_ids, std::string keys, std::size_t max_num_results) const {
	return predict_depth_first(str.c_str(), str.length(),
	key_ids, keys, max_num_results);
	}

	inline std::size_t Trie::predict_depth_first(const std::string &str,
	std::vector<UInt32> key_ids, std::vector<std::string> keys,
	std::size_t max_num_results) const {
	return predict_depth_first(str.c_str(), str.length(),
	key_ids, keys, max_num_results);
	}

	template <typename T>
	inline std::size_t Trie::predict_callback(
	const char *str, T callback) const {
	return predict_callback_<CQuery>(CQuery(str), callback);
	}

	template <typename T>
	inline std::size_t Trie::predict_callback(
	const char *ptr, std::size_t length,
	T callback) const {
	return predict_callback_<const Query &>(Query(ptr, length), callback);
	}

	template <typename T>
	inline std::size_t Trie::predict_callback(
	const std::string &str, T callback) const {
	return predict_callback(str.c_str(), str.length(), callback);
	}

	inline bool Trie::empty() const {
	return louds_.empty();
	}

	inline std::size_t Trie::num_keys() const {
	return num_keys_;
	}

	inline UInt32 Trie::notfound() {
	return MARISA_ALPHA_NOT_FOUND;
	}

	inline std::size_t Trie::mismatch() {
	return MARISA_ALPHA_MISMATCH;
	}

	template <typename T>
	inline bool Trie::find_child(UInt32 &node, T query,
	std::size_t &pos) const {
	UInt32 louds_pos = get_child(node);
	if (!louds_[louds_pos]) {
	return false;
	}
	node = louds_pos_to_node(louds_pos, node);
	UInt32 link_id = MARISA_ALPHA_UINT32_MAX;
	do {
	if (has_link(node)) {
	if (link_id == MARISA_ALPHA_UINT32_MAX) {
	link_id = get_link_id(node);
	} else {
	++link_id;
	}
	std::size_t next_pos = has_trie() ?
	trie_->trie_match<T>(get_link(node, link_id), query, pos) :
	tail_match<T>(node, link_id, query, pos);
	if (next_pos == mismatch()) {
	return false;
	} else if (next_pos != pos) {
	pos = next_pos;
	return true;
	}
	} else if (labels_[node] == query[pos]) {
	++pos;
	return true;
	}
	++node;
	++louds_pos;
	} while (louds_[louds_pos]);
	return false;
	}

	template <typename T, typename U>
	std::size_t Trie::find_callback_(T query, U callback) const try {
	std::size_t count = 0;
	UInt32 node = 0;
	std::size_t pos = 0;
	do {
	if (terminal_flags_[node]) {
	++count;
	if (!callback(node_to_key_id(node), pos)) {
	return count;
	}
	}
	} while (!query.ends_at(pos) && find_child<T>(node, query, pos));
	return count;
	} catch (const std::bad_alloc &) {
	MARISA_ALPHA_THROW(MARISA_ALPHA_MEMORY_ERROR);
	} catch (const std::length_error &) {
	MARISA_ALPHA_THROW(MARISA_ALPHA_SIZE_ERROR);
	}

	template <typename T>
	inline bool Trie::predict_child(UInt32 &node, T query, std::size_t &pos,
	std::string *key) const {
	UInt32 louds_pos = get_child(node);
	if (!louds_[louds_pos]) {
	return false;
	}
	node = louds_pos_to_node(louds_pos, node);
	UInt32 link_id = MARISA_ALPHA_UINT32_MAX;
	do {
	if (has_link(node)) {
	if (link_id == MARISA_ALPHA_UINT32_MAX) {
	link_id = get_link_id(node);
	} else {
	++link_id;
	}
	std::size_t next_pos = has_trie() ?
	trie_->trie_prefix_match<T>(
	get_link(node, link_id), query, pos, key) :
	tail_prefix_match<T>(node, link_id, query, pos, key);
	if (next_pos == mismatch()) {
	return false;
	} else if (next_pos != pos) {
	pos = next_pos;
	return true;
	}
	} else if (labels_[node] == query[pos]) {
	++pos;
	return true;
	}
	++node;
	++louds_pos;
	} while (louds_[louds_pos]);
	return false;
	}

	template <typename T, typename U>
	std::size_t Trie::predict_callback_(T query, U callback) const try {
	std::string key;
	UInt32 node = 0;
	std::size_t pos = 0;
	while (!query.ends_at(pos)) {
	if (!predict_child<T>(node, query, pos, &key)) {
	return 0;
	}
	}
	query.insert(&key);
	std::size_t count = 0;
	if (terminal_flags_[node]) {
	++count;
	if (!callback(node_to_key_id(node), key)) {
	return count;
	}
	}
	Cell cell;
	cell.set_louds_pos(get_child(node));
	if (!louds_[cell.louds_pos()]) {
	return count;
	}
	cell.set_node(louds_pos_to_node(cell.louds_pos(), node));
	cell.set_key_id(node_to_key_id(cell.node()));
	cell.set_length(key.length());
	Vector<Cell> stack;
	stack.push_back(cell);
	std::size_t stack_pos = 1;
	while (stack_pos != 0) {
	Cell &cur = stack[stack_pos - 1];
	if (!louds_[cur.louds_pos()]) {
	cur.set_louds_pos(cur.louds_pos() + 1);
	--stack_pos;
	continue;
	}
	cur.set_louds_pos(cur.louds_pos() + 1);
	key.resize(cur.length());
	if (has_link(cur.node())) {
	if (has_trie()) {
	trie_->trie_restore(get_link(cur.node()), &key);
	} else {
	tail_restore(cur.node(), &key);
	}
	} else {
	key += labels_[cur.node()];
	}
	if (terminal_flags_[cur.node()]) {
	++count;
	if (!callback(cur.key_id(), key)) {
	return count;
	}
	cur.set_key_id(cur.key_id() + 1);
	}
	if (stack_pos == stack.size()) {
	cell.set_louds_pos(get_child(cur.node()));
	cell.set_node(louds_pos_to_node(cell.louds_pos(), cur.node()));
	cell.set_key_id(node_to_key_id(cell.node()));
	stack.push_back(cell);
	}
	stack[stack_pos].set_length(key.length());
	stack[stack_pos - 1].set_node(stack[stack_pos - 1].node() + 1);
	++stack_pos;
	}
	return count;
	} catch (const std::bad_alloc &) {
	MARISA_ALPHA_THROW(MARISA_ALPHA_MEMORY_ERROR);
	} catch (const std::length_error &) {
	MARISA_ALPHA_THROW(MARISA_ALPHA_SIZE_ERROR);
	}

	inline UInt32 Trie::key_id_to_node(UInt32 key_id) const {
	return terminal_flags_.select1(key_id);
	}

	inline UInt32 Trie::node_to_key_id(UInt32 node) const {
	return terminal_flags_.rank1(node);
	}

	inline UInt32 Trie::louds_pos_to_node(UInt32 louds_pos,
	UInt32 parent_node) const {
	return louds_pos - parent_node - 1;
	}

	inline UInt32 Trie::get_child(UInt32 node) const {
	return louds_.select0(node) + 1;
	}

	inline UInt32 Trie::get_parent(UInt32 node) const {
	return (node > num_first_branches_) ? (louds_.select1(node) - node - 1) : 0;
	}

	inline bool Trie::has_link(UInt32 node) const {
	return (link_flags_.empty()) ? false : link_flags_[node];
	}

	inline UInt32 Trie::get_link_id(UInt32 node) const {
	return link_flags_.rank1(node);
	}

	inline UInt32 Trie::get_link(UInt32 node) const {
	return get_link(node, get_link_id(node));
	}

	inline UInt32 Trie::get_link(UInt32 node, UInt32 link_id) const {
	return (links_[link_id] * 256) + labels_[node];
	}

	inline bool Trie::has_link() const {
	return !link_flags_.empty();
	}

	inline bool Trie::has_trie() const {
	return trie_.get() != NULL;
	}

	inline bool Trie::has_tail() const {
	return !tail_.empty();
	}

	} // namespace marisa_alpha

	#endif // MARISA_ALPHA_TRIE_INLINE_H_