cannam@87: /*
cannam@87:   Copyright 2011-2013 David Robillard <http://drobilla.net>
cannam@87: 
cannam@87:   Permission to use, copy, modify, and/or distribute this software for any
cannam@87:   purpose with or without fee is hereby granted, provided that the above
cannam@87:   copyright notice and this permission notice appear in all copies.
cannam@87: 
cannam@87:   THIS SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
cannam@87:   WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
cannam@87:   MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
cannam@87:   ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
cannam@87:   WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
cannam@87:   ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
cannam@87:   OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
cannam@87: */
cannam@87: 
cannam@87: /**
cannam@87:    @file sordmm.hpp
cannam@87:    Public Sord C++ API.
cannam@87: */
cannam@87: 
cannam@87: #ifndef SORD_SORDMM_HPP
cannam@87: #define SORD_SORDMM_HPP
cannam@87: 
cannam@87: #include <cassert>
cannam@87: #include <cstring>
cannam@87: #include <cstdlib>
cannam@87: #include <iostream>
cannam@87: #include <set>
cannam@87: #include <string>
cannam@87: #include <sstream>
cannam@87: 
cannam@87: #include "serd/serd.h"
cannam@87: #include "sord/sord.h"
cannam@87: 
cannam@87: #define SORD_NS_XSD "http://www.w3.org/2001/XMLSchema#"
cannam@87: 
cannam@87: namespace Sord {
cannam@87: 
cannam@87: /** Utility base class to prevent copying. */
cannam@87: class Noncopyable {
cannam@87: protected:
cannam@87: 	Noncopyable() {}
cannam@87: 	~Noncopyable() {}
cannam@87: private:
cannam@87: 	Noncopyable(const Noncopyable&);
cannam@87: 	const Noncopyable& operator=(const Noncopyable&);
cannam@87: };
cannam@87: 
cannam@87: /** C++ wrapper for a Sord object. */
cannam@87: template <typename T>
cannam@87: class Wrapper {
cannam@87: public:
cannam@87: 	inline Wrapper(T c_obj = NULL) : _c_obj(c_obj) {}
cannam@87: 
cannam@87: 	inline T       c_obj()       { return _c_obj; }
cannam@87: 	inline const T c_obj() const { return _c_obj; }
cannam@87: 
cannam@87: protected:
cannam@87: 	T _c_obj;
cannam@87: };
cannam@87: 
cannam@87: /** Collection of RDF namespaces with prefixes. */
cannam@87: class Namespaces : public Wrapper<SerdEnv*> {
cannam@87: public:
cannam@87: 	Namespaces() : Wrapper<SerdEnv*>(serd_env_new(NULL)) {}
cannam@87: 	~Namespaces() { serd_env_free(_c_obj); }
cannam@87: 
cannam@87: 	static inline SerdNode string_to_node(SerdType type, const std::string& s) {
cannam@87: 		SerdNode ret = {
cannam@87: 			(const uint8_t*)s.c_str(), s.length(), s.length(), 0, type };
cannam@87: 		return ret;
cannam@87: 	}
cannam@87: 
cannam@87: 	inline void add(const std::string& name,
cannam@87: 	                const std::string& uri) {
cannam@87: 		const SerdNode name_node = string_to_node(SERD_LITERAL, name);
cannam@87: 		const SerdNode uri_node  = string_to_node(SERD_URI,     uri);
cannam@87: 		serd_env_set_prefix(_c_obj, &name_node, &uri_node);
cannam@87: 	}
cannam@87: 
cannam@87: 	inline std::string qualify(std::string uri) const {
cannam@87: 		const SerdNode uri_node = string_to_node(SERD_URI, uri);
cannam@87: 		SerdNode       prefix;
cannam@87: 		SerdChunk      suffix;
cannam@87: 		if (serd_env_qualify(_c_obj, &uri_node, &prefix, &suffix)) {
cannam@87: 			std::string ret((const char*)prefix.buf, prefix.n_bytes);
cannam@87: 			ret.append(":").append((const char*)suffix.buf, suffix.len);
cannam@87: 			return ret;
cannam@87: 		}
cannam@87: 		return uri;
cannam@87: 	}
cannam@87: 
cannam@87: 	inline std::string expand(const std::string& curie) const {
cannam@87: 		assert(curie.find(":") != std::string::npos);
cannam@87: 		SerdNode  curie_node = string_to_node(SERD_CURIE, curie);
cannam@87: 		SerdChunk uri_prefix;
cannam@87: 		SerdChunk uri_suffix;
cannam@87: 		if (!serd_env_expand(_c_obj, &curie_node, &uri_prefix, &uri_suffix)) {
cannam@87: 			std::string ret((const char*)uri_prefix.buf, uri_prefix.len);
cannam@87: 			ret.append((const char*)uri_suffix.buf, uri_suffix.len);
cannam@87: 			return ret;
cannam@87: 		}
cannam@87: 		std::cerr << "CURIE `" << curie << "' has unknown prefix." << std::endl;
cannam@87: 		return curie;
cannam@87: 	}
cannam@87: };
cannam@87: 
cannam@87: /** Sord library state. */
cannam@87: class World : public Noncopyable, public Wrapper<SordWorld*> {
cannam@87: public:
cannam@87: 	inline World()
cannam@87: 		: _next_blank_id(0)
cannam@87: 	{
cannam@87: 		_c_obj = sord_world_new();
cannam@87: 	}
cannam@87: 
cannam@87: 	inline ~World() {
cannam@87: 		sord_world_free(_c_obj);
cannam@87: 	}
cannam@87: 
cannam@87: 	inline uint64_t blank_id() { return _next_blank_id++; }
cannam@87: 
cannam@87: 	inline void add_prefix(const std::string& prefix, const std::string& uri) {
cannam@87: 		_prefixes.add(prefix, uri);
cannam@87: 	}
cannam@87: 
cannam@87: 	inline const Namespaces& prefixes() const { return _prefixes; }
cannam@87: 	inline SordWorld*        world()          { return _c_obj; }
cannam@87: 
cannam@87: private:
cannam@87: 	Namespaces            _prefixes;
cannam@87: 	std::set<std::string> _blank_ids;
cannam@87: 	uint64_t              _next_blank_id;
cannam@87: };
cannam@87: 
cannam@87: /** An RDF Node (resource, literal, etc)
cannam@87:  */
cannam@87: class Node : public Wrapper<SordNode*> {
cannam@87: public:
cannam@87: 	enum Type {
cannam@87: 		UNKNOWN  = 0,
cannam@87: 		URI      = SORD_URI,
cannam@87: 		BLANK    = SORD_BLANK,
cannam@87: 		LITERAL  = SORD_LITERAL
cannam@87: 	};
cannam@87: 
cannam@87: 	inline Node() : Wrapper<SordNode*>(NULL), _world(NULL) {}
cannam@87: 
cannam@87: 	inline Node(World& world, Type t, const std::string& s);
cannam@87: 	inline Node(World& world);
cannam@87: 	inline Node(World& world, const SordNode* node);
cannam@87: 	inline Node(World& world, SordNode* node, bool copy=false);
cannam@87: 	inline Node(const Node& other);
cannam@87: 	inline ~Node();
cannam@87: 
cannam@87: 	inline Type type() const {
cannam@87: 		return _c_obj ? (Type)sord_node_get_type(_c_obj) : UNKNOWN;
cannam@87: 	}
cannam@87: 
cannam@87: 	inline const SordNode* get_node() const { return _c_obj; }
cannam@87: 	inline SordNode*       get_node()       { return _c_obj; }
cannam@87: 
cannam@87: 	const SerdNode* to_serd_node() {
cannam@87: 		return sord_node_to_serd_node(_c_obj);
cannam@87: 	}
cannam@87: 
cannam@87: 	inline bool is_valid() const { return type() != UNKNOWN; }
cannam@87: 
cannam@87: 	inline bool operator<(const Node& other) const {
cannam@87: 		if (type() != other.type()) {
cannam@87: 			return type() < other.type();
cannam@87: 		} else {
cannam@87: 			return to_string() < other.to_string();
cannam@87: 		}
cannam@87: 	}
cannam@87: 
cannam@87: 	Node& operator=(const Node& other) {
cannam@87: 		if (&other != this) {
cannam@87: 			if (_c_obj) {
cannam@87: 				sord_node_free(_world->c_obj(), _c_obj);
cannam@87: 			}
cannam@87: 			_world = other._world;
cannam@87: 			_c_obj = other._c_obj ? sord_node_copy(other._c_obj) : NULL;
cannam@87: 		}
cannam@87: 		return *this;
cannam@87: 	}
cannam@87: 
cannam@87: 	inline bool operator==(const Node& other) const {
cannam@87: 		return sord_node_equals(_c_obj, other._c_obj);
cannam@87: 	}
cannam@87: 
cannam@87: 	inline const uint8_t* to_u_string() const;
cannam@87: 	inline const char*    to_c_string() const;
cannam@87: 	inline std::string    to_string() const;
cannam@87: 
cannam@87: 	inline bool is_literal_type(const char* type_uri) const;
cannam@87: 
cannam@87: 	inline bool is_uri()   const { return _c_obj && type() == URI; }
cannam@87: 	inline bool is_blank() const { return _c_obj && type() == BLANK; }
cannam@87: 	inline bool is_int()   const { return is_literal_type(SORD_NS_XSD "integer"); }
cannam@87: 	inline bool is_float() const { return is_literal_type(SORD_NS_XSD "decimal"); }
cannam@87: 	inline bool is_bool()  const { return is_literal_type(SORD_NS_XSD "boolean"); }
cannam@87: 
cannam@87: 	inline int   to_int()   const;
cannam@87: 	inline float to_float() const;
cannam@87: 	inline bool  to_bool()  const;
cannam@87: 
cannam@87: 	inline static Node blank_id(World& world, const std::string base="b") {
cannam@87: 		const uint64_t num = world.blank_id();
cannam@87: 		std::ostringstream ss;
cannam@87: 		ss << base << num;
cannam@87: 		return Node(world, Node::BLANK, ss.str());
cannam@87: 	}
cannam@87: 
cannam@87: private:
cannam@87: 	World* _world;
cannam@87: };
cannam@87: 
cannam@87: inline std::ostream&
cannam@87: operator<<(std::ostream& os, const Node& node)
cannam@87: {
cannam@87: 	return os << node.to_string();
cannam@87: }
cannam@87: 
cannam@87: class URI : public Node {
cannam@87: public:
cannam@87: 	inline URI(World& world, const std::string& s)
cannam@87: 		: Node(world, Node::URI, s) {}
cannam@87: 	inline URI(World& world, const std::string& s, const std::string& base)
cannam@87: 		: Node(world, sord_new_relative_uri(world.world(),
cannam@87: 		                                    (const uint8_t*)s.c_str(),
cannam@87: 		                                    (const uint8_t*)base.c_str()))
cannam@87: 	{}
cannam@87: };
cannam@87: 
cannam@87: class Curie : public Node {
cannam@87: public:
cannam@87: 	inline Curie(World& world, const std::string& s)
cannam@87: 		: Node(world, Node::URI, world.prefixes().expand(s)) {}
cannam@87: };
cannam@87: 
cannam@87: class Literal : public Node {
cannam@87: public:
cannam@87: 	inline Literal(World& world, const std::string& s)
cannam@87: 		: Node(world, Node::LITERAL, s) {}
cannam@87: 
cannam@87: 	static inline Node decimal(World& world, double d, unsigned frac_digits) {
cannam@87: 		const SerdNode val  = serd_node_new_decimal(d, 7);
cannam@87: 		const SerdNode type = serd_node_from_string(
cannam@87: 			SERD_URI, (const uint8_t*)SORD_NS_XSD "decimal");
cannam@87: 
cannam@87: 		return Node(
cannam@87: 			world,
cannam@87: 			sord_node_from_serd_node(
cannam@87: 				world.c_obj(), world.prefixes().c_obj(), &val, &type, NULL),
cannam@87: 			false);
cannam@87: 	}
cannam@87: 
cannam@87: 	static inline Node integer(World& world, int64_t i) {
cannam@87: 		const SerdNode val  = serd_node_new_integer(i);
cannam@87: 		const SerdNode type = serd_node_from_string(
cannam@87: 			SERD_URI, (const uint8_t*)SORD_NS_XSD "integer");
cannam@87: 
cannam@87: 		return Node(
cannam@87: 			world,
cannam@87: 			sord_node_from_serd_node(
cannam@87: 				world.c_obj(), world.prefixes().c_obj(), &val, &type, NULL),
cannam@87: 			false);
cannam@87: 	}
cannam@87: };
cannam@87: 
cannam@87: inline
cannam@87: Node::Node(World& world, Type type, const std::string& s)
cannam@87: 	: _world(&world)
cannam@87: {
cannam@87: 	switch (type) {
cannam@87: 	case URI:
cannam@87: 		_c_obj = sord_new_uri(
cannam@87: 			world.world(), (const unsigned char*)s.c_str());
cannam@87: 		break;
cannam@87: 	case LITERAL:
cannam@87: 		_c_obj = sord_new_literal(
cannam@87: 			world.world(), NULL, (const unsigned char*)s.c_str(), NULL);
cannam@87: 		break;
cannam@87: 	case BLANK:
cannam@87: 		_c_obj = sord_new_blank(
cannam@87: 			world.world(), (const unsigned char*)s.c_str());
cannam@87: 		break;
cannam@87: 	default:
cannam@87: 		_c_obj = NULL;
cannam@87: 	}
cannam@87: 
cannam@87: 	assert(this->type() == type);
cannam@87: }
cannam@87: 
cannam@87: inline
cannam@87: Node::Node(World& world)
cannam@87: 	: _world(&world)
cannam@87: {
cannam@87: 	Node me = blank_id(world);
cannam@87: 	*this = me;
cannam@87: }
cannam@87: 
cannam@87: inline
cannam@87: Node::Node(World& world, const SordNode* node)
cannam@87: 	: _world(&world)
cannam@87: {
cannam@87: 	_c_obj = sord_node_copy(node);
cannam@87: }
cannam@87: 
cannam@87: inline
cannam@87: Node::Node(World& world, SordNode* node, bool copy)
cannam@87: 	: _world(&world)
cannam@87: {
cannam@87: 	_c_obj = copy ? sord_node_copy(node) : node;
cannam@87: }
cannam@87: 
cannam@87: inline
cannam@87: Node::Node(const Node& other)
cannam@87: 	: Wrapper<SordNode*>()
cannam@87: 	, _world(other._world)
cannam@87: {
cannam@87: 	if (_world) {
cannam@87: 		_c_obj = other._c_obj ? sord_node_copy(other._c_obj) : NULL;
cannam@87: 	}
cannam@87: 
cannam@87: 	assert((!_c_obj && !other._c_obj) || to_string() == other.to_string());
cannam@87: }
cannam@87: 
cannam@87: inline
cannam@87: Node::~Node()
cannam@87: {
cannam@87: 	if (_world) {
cannam@87: 		sord_node_free(_world->c_obj(), _c_obj);
cannam@87: 	}
cannam@87: }
cannam@87: 
cannam@87: inline std::string
cannam@87: Node::to_string() const
cannam@87: {
cannam@87: 	return _c_obj ? (const char*)sord_node_get_string(_c_obj) : "";
cannam@87: }
cannam@87: 
cannam@87: inline const char*
cannam@87: Node::to_c_string() const
cannam@87: {
cannam@87: 	return (const char*)sord_node_get_string(_c_obj);
cannam@87: }
cannam@87: 
cannam@87: inline const uint8_t*
cannam@87: Node::to_u_string() const
cannam@87: {
cannam@87: 	return sord_node_get_string(_c_obj);
cannam@87: }
cannam@87: 
cannam@87: inline bool
cannam@87: Node::is_literal_type(const char* type_uri) const
cannam@87: {
cannam@87: 	if (_c_obj && sord_node_get_type(_c_obj) == SORD_LITERAL) {
cannam@87: 		const SordNode* datatype = sord_node_get_datatype(_c_obj);
cannam@87: 		if (datatype && !strcmp((const char*)sord_node_get_string(datatype),
cannam@87: 		                        type_uri))
cannam@87: 			return true;
cannam@87: 	}
cannam@87: 	return false;
cannam@87: }
cannam@87: 
cannam@87: inline int
cannam@87: Node::to_int() const
cannam@87: {
cannam@87: 	assert(is_int());
cannam@87: 	char* endptr;
cannam@87: 	return strtol((const char*)sord_node_get_string(_c_obj), &endptr, 10);
cannam@87: }
cannam@87: 
cannam@87: inline float
cannam@87: Node::to_float() const
cannam@87: {
cannam@87: 	assert(is_float());
cannam@87: 	char* endptr;
cannam@87: 	return serd_strtod((const char*)sord_node_get_string(_c_obj), &endptr);
cannam@87: }
cannam@87: 
cannam@87: inline bool
cannam@87: Node::to_bool() const
cannam@87: {
cannam@87: 	assert(is_bool());
cannam@87: 	return !strcmp((const char*)sord_node_get_string(_c_obj), "true");
cannam@87: }
cannam@87: 
cannam@87: struct Iter : public Wrapper<SordIter*> {
cannam@87: 	inline Iter(World& world, SordIter* c_obj)
cannam@87: 		: Wrapper<SordIter*>(c_obj), _world(world) {}
cannam@87: 	inline ~Iter() { sord_iter_free(_c_obj); }
cannam@87: 	inline bool end()  const { return sord_iter_end(_c_obj); }
cannam@87: 	inline bool next() const { return sord_iter_next(_c_obj); }
cannam@87: 	inline Iter& operator++() {
cannam@87: 		assert(!end());
cannam@87: 		next();
cannam@87: 		return *this;
cannam@87: 	}
cannam@87: 	inline const Node get_subject() const {
cannam@87: 		SordQuad quad;
cannam@87: 		sord_iter_get(_c_obj, quad);
cannam@87: 		return Node(_world, quad[SORD_SUBJECT]);
cannam@87: 	}
cannam@87: 	inline const Node get_predicate() const {
cannam@87: 		SordQuad quad;
cannam@87: 		sord_iter_get(_c_obj, quad);
cannam@87: 		return Node(_world, quad[SORD_PREDICATE]);
cannam@87: 	}
cannam@87: 	inline const Node get_object() const {
cannam@87: 		SordQuad quad;
cannam@87: 		sord_iter_get(_c_obj, quad);
cannam@87: 		return Node(_world, quad[SORD_OBJECT]);
cannam@87: 	}
cannam@87: 	World& _world;
cannam@87: };
cannam@87: 
cannam@87: /** An RDF Model (collection of triples).
cannam@87:  */
cannam@87: class Model : public Noncopyable, public Wrapper<SordModel*> {
cannam@87: public:
cannam@87: 	inline Model(World&             world,
cannam@87: 	             const std::string& base_uri,
cannam@87: 	             unsigned           indices = (SORD_SPO | SORD_OPS),
cannam@87: 	             bool               graphs  = true);
cannam@87: 
cannam@87: 	inline ~Model();
cannam@87: 
cannam@87: 	inline const Node& base_uri() const { return _base; }
cannam@87: 
cannam@87: 	size_t num_quads() const { return sord_num_quads(_c_obj); }
cannam@87: 
cannam@87: 	inline void load_file(SerdEnv*           env,
cannam@87: 	                      SerdSyntax         syntax,
cannam@87: 	                      const std::string& uri,
cannam@87: 	                      const std::string& base_uri="");
cannam@87: 
cannam@87: 	inline void load_string(SerdEnv*           env,
cannam@87: 	                        SerdSyntax         syntax,
cannam@87: 	                        const char*        str,
cannam@87: 	                        size_t             len,
cannam@87: 	                        const std::string& base_uri);
cannam@87: 
cannam@87: 	inline SerdStatus write_to_file(
cannam@87: 		const std::string& uri,
cannam@87: 		SerdSyntax         syntax = SERD_TURTLE,
cannam@87: 		SerdStyle          style  = (SerdStyle)(SERD_STYLE_ABBREVIATED
cannam@87: 		                                        |SERD_STYLE_CURIED
cannam@87: 		                                        |SERD_STYLE_RESOLVED));
cannam@87: 
cannam@87: 	inline std::string write_to_string(
cannam@87: 		const std::string& base_uri,
cannam@87: 		SerdSyntax         syntax = SERD_TURTLE,
cannam@87: 		SerdStyle          style  = (SerdStyle)(SERD_STYLE_ABBREVIATED
cannam@87: 		                                        |SERD_STYLE_CURIED
cannam@87: 		                                        |SERD_STYLE_RESOLVED));
cannam@87: 
cannam@87: 	inline void add_statement(const Node& subject,
cannam@87: 	                          const Node& predicate,
cannam@87: 	                          const Node& object);
cannam@87: 
cannam@87: 	inline Iter find(const Node& subject,
cannam@87: 	                 const Node& predicate,
cannam@87: 	                 const Node& object);
cannam@87: 
cannam@87: 	inline Node get(const Node& subject,
cannam@87: 	                const Node& predicate,
cannam@87: 	                const Node& object);
cannam@87: 
cannam@87: 	inline World& world() const { return _world; }
cannam@87: 
cannam@87: private:
cannam@87: 	World&      _world;
cannam@87: 	Node        _base;
cannam@87: 	SerdWriter* _writer;
cannam@87: 	size_t      _next_blank_id;
cannam@87: };
cannam@87: 
cannam@87: /** Create an empty in-memory RDF model.
cannam@87:  */
cannam@87: inline
cannam@87: Model::Model(World&             world,
cannam@87:              const std::string& base_uri,
cannam@87:              unsigned           indices,
cannam@87:              bool               graphs)
cannam@87: 	: _world(world)
cannam@87: 	, _base(world, Node::URI, base_uri)
cannam@87: 	, _writer(NULL)
cannam@87: {
cannam@87: 	_c_obj = sord_new(_world.world(), indices, graphs);
cannam@87: }
cannam@87: 
cannam@87: inline void
cannam@87: Model::load_string(SerdEnv*           env,
cannam@87:                    SerdSyntax         syntax,
cannam@87:                    const char*        str,
cannam@87:                    size_t             len,
cannam@87:                    const std::string& base_uri)
cannam@87: {
cannam@87: 	SerdReader* reader = sord_new_reader(_c_obj, env, syntax, NULL);
cannam@87: 	serd_reader_read_string(reader, (const uint8_t*)str);
cannam@87: 	serd_reader_free(reader);
cannam@87: }
cannam@87: 
cannam@87: inline Model::~Model()
cannam@87: {
cannam@87: 	sord_free(_c_obj);
cannam@87: }
cannam@87: 
cannam@87: inline void
cannam@87: Model::load_file(SerdEnv*           env,
cannam@87:                  SerdSyntax         syntax,
cannam@87:                  const std::string& data_uri,
cannam@87:                  const std::string& base_uri)
cannam@87: {
cannam@87: 	uint8_t* path = serd_file_uri_parse((const uint8_t*)data_uri.c_str(), NULL);
cannam@87: 	if (!path) {
cannam@87: 		fprintf(stderr, "Failed to parse file URI <%s>\n", data_uri.c_str());
cannam@87: 		return;
cannam@87: 	}
cannam@87: 
cannam@87: 	// FIXME: blank prefix parameter?
cannam@87: 	SerdReader* reader = sord_new_reader(_c_obj, env, syntax, NULL);
cannam@87: 	serd_reader_read_file(reader, path);
cannam@87: 	serd_reader_free(reader);
cannam@87: 	free(path);
cannam@87: }
cannam@87: 
cannam@87: inline SerdStatus
cannam@87: Model::write_to_file(const std::string& uri, SerdSyntax syntax, SerdStyle style)
cannam@87: {
cannam@87: 	uint8_t* path = serd_file_uri_parse((const uint8_t*)uri.c_str(), NULL);
cannam@87: 	if (!path) {
cannam@87: 		fprintf(stderr, "Failed to parse file URI <%s>\n", uri.c_str());
cannam@87: 		return SERD_ERR_BAD_ARG;
cannam@87: 	}
cannam@87: 
cannam@87: 	FILE* const fd = fopen((const char*)path, "w");
cannam@87: 	if (!fd) {
cannam@87: 		fprintf(stderr, "Failed to open file %s\n", path);
cannam@87: 		free(path);
cannam@87: 		return SERD_ERR_UNKNOWN;
cannam@87: 	}
cannam@87: 	free(path);
cannam@87: 
cannam@87: 	SerdURI base_uri = SERD_URI_NULL;
cannam@87: 	if (serd_uri_parse((const uint8_t*)uri.c_str(), &base_uri)) {
cannam@87: 		fprintf(stderr, "Invalid base URI <%s>\n", uri.c_str());
cannam@87: 		fclose(fd);
cannam@87: 		return SERD_ERR_BAD_ARG;
cannam@87: 	}
cannam@87: 
cannam@87: 	SerdWriter* writer = serd_writer_new(syntax,
cannam@87: 	                                     style,
cannam@87: 	                                     _world.prefixes().c_obj(),
cannam@87: 	                                     &base_uri,
cannam@87: 	                                     serd_file_sink,
cannam@87: 	                                     fd);
cannam@87: 
cannam@87: 	serd_env_foreach(_world.prefixes().c_obj(),
cannam@87: 	                 (SerdPrefixSink)serd_writer_set_prefix,
cannam@87: 	                 writer);
cannam@87: 
cannam@87: 	sord_write(_c_obj, writer, 0);
cannam@87: 	serd_writer_free(writer);
cannam@87: 	fclose(fd);
cannam@87: 
cannam@87: 	return SERD_SUCCESS;
cannam@87: }
cannam@87: 
cannam@87: static size_t
cannam@87: string_sink(const void* buf, size_t len, void* stream)
cannam@87: {
cannam@87: 	std::string* str = (std::string*)stream;
cannam@87: 	str->append((const char*)buf, len);
cannam@87: 	return len;
cannam@87: }
cannam@87: 
cannam@87: inline std::string
cannam@87: Model::write_to_string(const std::string& base_uri_str,
cannam@87:                        SerdSyntax         syntax,
cannam@87:                        SerdStyle          style)
cannam@87: {
cannam@87: 	SerdURI base_uri = SERD_URI_NULL;
cannam@87: 	if (serd_uri_parse((const uint8_t*)base_uri_str.c_str(), &base_uri)) {
cannam@87: 		fprintf(stderr, "Invalid base URI <%s>\n", base_uri_str.c_str());
cannam@87: 		return "";
cannam@87: 	}
cannam@87: 
cannam@87: 	std::string ret;
cannam@87: 
cannam@87: 	SerdWriter* writer = serd_writer_new(syntax,
cannam@87: 	                                     style,
cannam@87: 	                                     _world.prefixes().c_obj(),
cannam@87: 	                                     &base_uri,
cannam@87: 	                                     string_sink,
cannam@87: 	                                     &ret);
cannam@87: 
cannam@87: 	serd_env_foreach(_world.prefixes().c_obj(),
cannam@87: 	                 (SerdPrefixSink)serd_writer_set_prefix,
cannam@87: 	                 writer);
cannam@87: 
cannam@87: 	sord_write(_c_obj, writer, 0);
cannam@87: 
cannam@87: 	serd_writer_free(writer);
cannam@87: 	return ret;
cannam@87: }
cannam@87: 
cannam@87: inline void
cannam@87: Model::add_statement(const Node& subject,
cannam@87:                      const Node& predicate,
cannam@87:                      const Node& object)
cannam@87: {
cannam@87: 	SordQuad quad = { subject.c_obj(),
cannam@87: 	                  predicate.c_obj(),
cannam@87: 	                  object.c_obj(),
cannam@87: 	                  NULL };
cannam@87: 
cannam@87: 	sord_add(_c_obj, quad);
cannam@87: }
cannam@87: 
cannam@87: inline Iter
cannam@87: Model::find(const Node& subject,
cannam@87:             const Node& predicate,
cannam@87:             const Node& object)
cannam@87: {
cannam@87: 	SordQuad quad = { subject.c_obj(),
cannam@87: 	                  predicate.c_obj(),
cannam@87: 	                  object.c_obj(),
cannam@87: 	                  NULL };
cannam@87: 
cannam@87: 	return Iter(_world, sord_find(_c_obj, quad));
cannam@87: }
cannam@87: 
cannam@87: inline Node
cannam@87: Model::get(const Node& subject,
cannam@87:            const Node& predicate,
cannam@87:            const Node& object)
cannam@87: {
cannam@87: 	SordNode* c_node = sord_get(
cannam@87: 		_c_obj, subject.c_obj(), predicate.c_obj(), object.c_obj(), NULL);
cannam@87: 	Node node(_world, c_node);
cannam@87: 	sord_node_free(_world.c_obj(), c_node);
cannam@87: 	return node;
cannam@87: }
cannam@87: 
cannam@87: }  // namespace Sord
cannam@87: 
cannam@87: #endif  // SORD_SORDMM_HPP
cannam@87: