int
shardcache_client_get_async(shardcache_client_t *c,
                            void *key,
                            size_t klen,
                            shardcache_client_get_aync_data_cb data_cb,
                            void *priv)
{
    int fd = -1;
    char *addr = select_node(c, key, klen, &fd);
    if (fd < 0) {
        c->errno = SHARDCACHE_CLIENT_ERROR_NETWORK;
        snprintf(c->errstr, sizeof(c->errstr), "Can't connect to '%s'", addr);
        return -1;
    }

    shardcache_client_get_async_data_arg_t *arg = malloc(sizeof(shardcache_client_get_async_data_arg_t));
    arg->connections = c->connections;
    arg->fd = fd;
    arg->cb = data_cb;
    arg->priv = priv;
    return fetch_from_peer_async(addr,
                                 (char *)c->auth,
                                 SHC_HDR_CSIGNATURE_SIP,
                                 key,
                                 klen,
                                 0,
                                 0,
                                 shardcache_client_get_async_data_helper,
                                 arg,
                                 fd,
                                 NULL);
}
static linked_list_t *
shc_split_buckets(shardcache_client_t *c, shc_multi_item_t **items, int *num_items)
{
    linked_list_t *pools = list_create();
    int i;
    for(i = 0; items[i]; i++) {
        shc_multi_item_t *item = items[i];
        item->idx = i;

        char *addr = select_node(c, item->key, item->klen, NULL);

        tagged_value_t *tval = list_get_tagged_value(pools, addr);
        if (!tval || list_count((linked_list_t *)tval->value) > c->pipeline_max)
        {
            linked_list_t *sublist = list_create();
            tval = list_create_tagged_sublist(addr, sublist);
            // put the new sublist at the beggining of the main tagged list
            // so that in case of multiple lists for the same node this will
            // be the one returned by list_get_tagged_value()
            list_unshift_tagged_value(pools, tval);
        }

        list_push_value((linked_list_t *)tval->value, item);

    }

    if (num_items)
        *num_items = i;

    return pools;
}
static inline int
shardcache_client_set_internal(shardcache_client_t *c, void *key, size_t klen, void *data, size_t dlen, uint32_t expire, int inx)
{
    int fd = -1;
    char *addr = select_node(c, key, klen, &fd);
    if (fd < 0) {
        c->errno = SHARDCACHE_CLIENT_ERROR_NETWORK;
        snprintf(c->errstr, sizeof(c->errstr), "Can't connect to '%s'", addr);
        return -1;
    }

    int rc = -1;
    if (inx)
        rc = add_to_peer(addr, (char *)c->auth, SHC_HDR_SIGNATURE_SIP, key, klen, data, dlen, expire, fd, 1);
    else
        rc = send_to_peer(addr, (char *)c->auth, SHC_HDR_SIGNATURE_SIP, key, klen, data, dlen, expire, fd, 1);

    if (rc == -1) {
        close(fd);
        c->errno = SHARDCACHE_CLIENT_ERROR_NODE;
        snprintf(c->errstr, sizeof(c->errstr), "Can't set new data on node '%s'", addr);
    } else {
        connections_pool_add(c->connections, addr, fd);
        c->errno = SHARDCACHE_CLIENT_OK;
        c->errstr[0] = 0;
    }
    return rc;
}
size_t
shardcache_client_get(shardcache_client_t *c, void *key, size_t klen, void **data)
{
    int fd = -1;
    char *addr = select_node(c, key, klen, &fd);

    if (fd < 0) {
        c->errno = SHARDCACHE_CLIENT_ERROR_NETWORK;
        snprintf(c->errstr, sizeof(c->errstr), "Can't connect to '%s'", addr);
        return 0;
    }

    fbuf_t value = FBUF_STATIC_INITIALIZER;
    int rc = fetch_from_peer(addr, (char *)c->auth, SHC_HDR_SIGNATURE_SIP, key, klen, &value, fd);
    if (rc == 0) {
        size_t size = fbuf_used(&value);
        if (data)
            *data = fbuf_data(&value);
        else
            fbuf_destroy(&value);

        c->errno = SHARDCACHE_CLIENT_OK;
        c->errstr[0] = 0;

        connections_pool_add(c->connections, addr, fd);
        return size;
    } else {
        close(fd);
        c->errno = SHARDCACHE_CLIENT_ERROR_NODE;
        snprintf(c->errstr, sizeof(c->errstr), "Can't fetch data from node '%s'", addr);
        return 0;
    }
    return 0;
}
size_t
shardcache_client_offset(shardcache_client_t *c, void *key, size_t klen, uint32_t offset, void *data, uint32_t dlen)
{
    int fd = -1;
    char *addr = select_node(c, key, klen, &fd);
    if (fd < 0) {
        c->errno = SHARDCACHE_CLIENT_ERROR_NETWORK;
        snprintf(c->errstr, sizeof(c->errstr), "Can't connect to '%s'", addr);
        return 0;
    }

    fbuf_t value = FBUF_STATIC_INITIALIZER;
    int rc = offset_from_peer(addr, (char *)c->auth, SHC_HDR_SIGNATURE_SIP, key, klen, offset, dlen, &value, fd);
    if (rc == 0) {
        uint32_t to_copy = dlen > fbuf_used(&value) ? fbuf_used(&value) : dlen;
        if (data)
            memcpy(data, fbuf_data(&value), to_copy);

        c->errno = SHARDCACHE_CLIENT_OK;
        c->errstr[0] = 0;

        connections_pool_add(c->connections, addr, fd);
        fbuf_destroy(&value);
        return to_copy;
    } else {
        close(fd);
        c->errno = SHARDCACHE_CLIENT_ERROR_NODE;
        snprintf(c->errstr, sizeof(c->errstr), "Can't fetch data from node '%s'", addr);
    }
    fbuf_destroy(&value);
    return 0;
}
Beispiel #6
0
void SJView::select_single_node(CPoint point) 
{
	SJPoint* p_point = select_node(point);
	if(p_point) mp_sg->mp_mesh->select_point(p_point);


}
Beispiel #7
0
	std::string DomNode::select_string(const DomString &xpath_expression) const
	{
		DomNode node = select_node(xpath_expression);
		if (node.is_element())
			return node.to_element().get_text();
		else
			return node.get_node_value();
	}
Beispiel #8
0
  void unselect_node(){
    if(seek_port.port_type == NO_PORT && seek_port.node_viewer != NULL){
      Node * nd = find_node_from_nodeview(seek_port.node_viewer);
      saved_text.erase(curser_pos,1);
      if(text_changed == true){
	replace_node_with_line(saved_text,nd);
      }
    }
    
     select_node({NULL,NO_PORT,0});
  }
Beispiel #9
0
void test()
{
	char* ss[] = {"abc", "dfg", "hjk"};
	char* s = select(ss, "abc");
	printf("%s",s);
	node node1;
	node1.name="abc"; 
	node1.age=1;
	node* nodes[] = {&node1};
	node*  selected_node = select_node(nodes, "abc");
	printf("node:{name:%s,age:%d}",selected_node->name, selected_node->age);
}
Beispiel #10
0
void SJView::select_element_node(CPoint point) 
{
	SJPoint* p_point = select_node(point);

//	TRACE("SJView::select_element_node %i\n", p_point);

	if(p_point == NULL) return;

	ml_elgens.add_tail(p_point);
	if(ml_elgens.get_count() == 4) 
	{
		mp_sg->mp_mesh->add_block(ml_elgens);
		ml_elgens.delete_list_nodes();
		mp_sg->mp_mesh->unselect_nodes();
	}
	else p_point->m_selection = 1;

}
int
shardcache_client_del(shardcache_client_t *c, void *key, size_t klen)
{
    int fd = -1;
    char *addr = select_node(c, key, klen, &fd);
    if (fd < 0) {
        c->errno = SHARDCACHE_CLIENT_ERROR_NETWORK;
        snprintf(c->errstr, sizeof(c->errstr), "Can't connect to '%s'", addr);
        return -1;
    }
    int rc = delete_from_peer(addr, (char *)c->auth, SHC_HDR_SIGNATURE_SIP, key, klen, fd, 1);
    if (rc != 0) {
        close(fd);
        c->errno = SHARDCACHE_CLIENT_ERROR_NODE;
        snprintf(c->errstr, sizeof(c->errstr), "Can't delete data from node '%s'", addr);
    } else {
        connections_pool_add(c->connections, addr, fd);
        c->errno = SHARDCACHE_CLIENT_OK;
        c->errstr[0] = 0;
    }
    return rc;
}
Beispiel #12
0
/* 候補手の評価値を算出 */
int book_alphabeta(BooksNode *book_header, int depth, int alpha, int beta, int color)
{
	if(book_header->child == NULL)
	{
		if(color == WHITE)
		{
			return -book_header->eval;
		}
		return book_header->eval;
	}

	if(depth == 0)
	{
		int i = 0, e_list[24] = 
		{
			NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, 
			NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN, NEGAMIN
		};
		int eval, max = NEGAMIN - 1;
		BooksNode *best_node[24] = 
		{
			NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, 
			NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL
		};
		do{
			if(i == 0)
			{
				book_header = book_header->child;
			}
			else
			{
				book_header = book_header->next;
			}
			eval = -book_alphabeta(book_header, depth + 1, -beta, -alpha, color ^ 1);
			e_list[i] = eval;
			best_node[i] = book_header;
			if(eval > max)
			{
				max = eval;
			}
			i++;
		}while(book_header->next != NULL);
		sort_book_node(best_node, e_list, i);
		/* ノード番号を算出 */
		int node_num = select_node(e_list, i);
		BestNode = best_node[node_num];
		return e_list[node_num];
	}
	else
	{
		int i = 0;
		int eval, max = NEGAMIN - 1;
		do{
			if(i == 0)
			{
				book_header = book_header->child;
			}
			else
			{
				book_header = book_header->next;
			}
			eval = -book_alphabeta(book_header, depth + 1, -beta, -alpha, color ^ 1);
			if(eval > max)
			{
				max = eval;
				if(max > alpha)
				{
					alpha = max;   //下限値も更新
					/* アルファカット */
					if(beta <= alpha)
					{
						break;
					}
				}
			}
			i++;
		}while(book_header->next != NULL);
		return max;
	}
}
Beispiel #13
0
CSSSelectResult CSSDocument::select(const DomElement &node, const std::string &pseudo_element)
{
	DomSelectNode select_node(node);
	return select(&select_node, pseudo_element);
}
Beispiel #14
0
int main(){

    /*
    // Linked list de un arreglo de 10 elementos

    struct node_t arr[10];
    printf("PREV: %x %x %x \n", &arr[0], &arr[1], &arr[2]);

    int i;
    for(i=0; i<10; i++){
        arr[i].next = &arr[i+1];
        printf("addr %d :  0x%p == 0x%p \n", i, &arr[i], arr[i].next);
    } // Hasta ahora el arr[9].next tiene basura


    */


    int menu;
    do{
        printf("Menu:\n");
        printf("1) Create Linked List\n");
        printf("2) Display\n");
        printf("3) Select Node\n");
        printf("4) Insert Node\n");
        printf("5) Remove Node\n");
        printf("6) Delete All Nodes\n");
        printf("0) Exit\n");
        printf("> ");
        scanf("%d", &menu);

        // 1) Create Linked List
        if(menu == 1){
            printf(" create \n");
            create_list();
        }
        // 2) Display
        else if(menu == 2){
            printf(" display \n");
            if(display_list()){ // if it returns a 1, it failed.
                printf("Error: List is empty \n");
            }
        }
        // 3) Select Node
        else if(menu == 3){
            printf(" sel \n");
            int selection;
            printf("Select Node [0:N-1]: ");
            scanf("%d", &selection);
            select_node(selection);

        }
        // 4) Insert Node
        else if(menu == 4){
            printf(" insert \n");
            int selection;
            printf("Insert Node [0:N-1]: ");
            scanf("%d", &selection);
            struct node_t *insert  = (struct node_t*)malloc( sizeof(struct node_t) );
            printf("Dato a insertar: ");
            scanf("%d", &(*insert).data );

            insert_node(selection, insert);
        }

        // 5) Remove Node
        else if(menu == 5){
            printf(" remove \n");
            int selection;
            printf("Remove Node [0:N-1]: ");
            scanf("%d", &selection);
            remove_node(selection);
        }

        // 6) Delete All Nodes
        else if(menu == 6){
            printf(" del all \n");
            delete_all();
        }

    } while(menu != 0);



    /*
    (*ptr_aux).data = (int)N;
    printf("%d", (*ptr_aux).data);
    */


  /*
  // Linked list con selector

    int N;
    struct node_t *head  = (struct node_t*)malloc( sizeof(struct node_t) );
    printf("Dame N: ");
    scanf("%d", &N);

    struct node_t *ptr_aux = head;

    printf("size of struct %d \n", sizeof(struct node_t) );
    printf("head: %p aux: %p \n", head, ptr_aux);


    int i;
    for(i=0; i<N; i++){
        printf("Dato: ");
        scanf("%d", &(*ptr_aux).data );

        printf("Addr: %p  , Data: %d , ", ptr_aux, (int)(*ptr_aux).data);

        (*ptr_aux).next = (struct node_t*)malloc(sizeof(struct node_t));

        printf("Next: %x\n", (*ptr_aux).next );
        ptr_aux = (*ptr_aux).next;
    }

    int sel=0;
    do{
        ptr_aux = head;
        printf("Selecciona un dato por posicion [0:N-1]: ");
        scanf("%d", &sel);

        int j;
        for(j=0; j<N; j++){

            if(j == sel){
                printf("Dato que buscas: %d, addr %p \n ", (int)(*ptr_aux).data, ptr_aux);
                j=N;

            }
            ptr_aux = (*ptr_aux).next;
        }
    }while(sel < N && sel >= 0);

*/
    printf("head: %p \n", head);
    return 0;
}
Beispiel #15
0
  bool handle_event(MouseClick mclick){
    change = true;

    if(mclick.button == 2){
      middle_down = mclick.pressed;
    }

    if(mode == INTERACT_MODE){
      NodeViewer * nv = nvp.node_viewer;
      if(nv == NULL){
	return false;
      }
      if(mclick.button == 0 && mclick.pressed){
	Node * nd = find_node_from_nodeview(nv);
	if(nd != NULL){
	  nd->handle_click(0,0,0);
	}else{
	  std::cout << "Warning. Clicking NULL node\n";
	}
      }


    }


    if(mode == EDIT_MODE){
      if(shift_down){
	remove_connection_at(last_world);
	return false;
      }

      if(ctrl_down && mclick.button == 0 && mclick.pressed){
	Node * nd = create_and_insert_node("",last_world);
	held_node = {node_view[nd],NO_PORT,0};
	return false;
      }

      if(mclick.button == 0 && mclick.pressed){
	
	held_node = nvp;
	
	return false;
      }


      if(mclick.button == 0 && mclick.released){
	if(held_node.node_viewer != NULL){
	  if( seek_port.node_viewer != NULL && seek_port.port_type != NO_PORT){
	    Node * nd1 = find_node_from_nodeview(nvp.node_viewer);
	    int p1 = nvp.port_nr;
	    Node * nd2 = find_node_from_nodeview(seek_port.node_viewer);
	    int p2 = seek_port.port_nr;
	    if(nvp.port_type == IN_PORT && seek_port.port_type == OUT_PORT){
	      backend.connect_nodes(nd2,nd1,p2,p1);
	  
	    }else if(nvp.port_type == OUT_PORT && seek_port.port_type == IN_PORT){
	      backend.connect_nodes(nd1,nd2,p1,p2);	  
	    }
	    seek_port = {NULL,NO_PORT,0};
	  }else{
	    unselect_node();
	    select_node(held_node);
	    held_node = {NULL,NO_PORT,0};
	    return false;
	  }
	  
	}else{
	  unselect_node();
	  seek_port = {NULL,NO_PORT,0};
	}
	
      }
    }
    unselect_node();
    
  }
void CL_GUIComponent::load_css_layout(const CL_String &xml_filename, const CL_String &css_filename)
{
	CL_CSSDocument2 css_document;
	css_document.add_sheet(css_filename);

	CL_File file(xml_filename);
	CL_DomDocument dom(file, false);
	CL_DomNode cur = dom.get_document_element().get_first_child();
	std::vector<CL_CSSLayoutElement> element_stack;

	{
		CL_DomSelectNode select_node(dom.get_document_element());
		impl->css_element.apply_properties(css_document.select(&select_node));
		impl->css_element.apply_properties(dom.get_document_element().get_attribute("style"));
		impl->css_element.set_col_span(dom.get_document_element().get_attribute_int("colspan", 1));
		impl->css_element.set_row_span(dom.get_document_element().get_attribute_int("rowspan", 1));
	}

	element_stack.push_back(impl->css_element);
	while (!cur.is_null())
	{
		CL_CSSLayoutElement child_css_element;
		if (cur.is_element())
		{
			CL_DomElement cur_element = cur.to_element();
			CL_DomSelectNode select_node(cur_element);
			child_css_element = element_stack.back().create_element(cur_element.get_tag_name());
			child_css_element.apply_properties(css_document.select(&select_node));
			child_css_element.apply_properties(cur_element.get_attribute("style"));
			child_css_element.set_col_span(cur_element.get_attribute_int("colspan", 1));
			child_css_element.set_row_span(cur_element.get_attribute_int("rowspan", 1));
		}
		else if (cur.is_text())
		{
			CL_DomText cur_text = cur.to_text();
			element_stack.back().create_text(cur_text.get_node_value());
		}

		CL_DomNode next = cur.get_first_child();
		if (next.is_null())
		{
			next = cur.get_next_sibling();
			if (next.is_null())
			{
				next = cur.get_parent_node();
				while (!next.is_null() && next.get_next_sibling().is_null())
					next = next.get_parent_node();
				if (!next.is_null())
					next = next.get_next_sibling();
			}
		}
		else
		{
			element_stack.push_back(child_css_element);
		}
		cur = next;
	}

	CL_GraphicContext gc = get_gc();
	impl->css_layout.layout(gc, get_size());
}
Beispiel #17
0
/***************************************************************************
* Name  : SearchBooks
* Brief : 定石やからCPUの着手を決定する
* Return: 着手可能位置のビット列
****************************************************************************/
INT32 SearchBooks(BooksNode *book_root, UINT64 bk, UINT64 wh,
	UINT32 color, UINT32 change, INT32 turn)
{
	INT32 move = MOVE_NONE;
	ULONG eval = 0;
	BookData *book_data;
	BooksNode *book_header;

	g_booklist_cnt = 0;
	// 変化度設定
	set_book_error(change);

	/* 局面から該当の定石を探す */
	book_header = SearchBookInfo(book_root, book_root, bk, wh, turn);

	if (book_header != NULL)
	{
		/* 評価値により次の手を定石から選ぶ */
		eval = book_alphabeta(book_header, 0, NEGAMIN, NEGAMAX, color);
		book_data = select_node(change);
		g_evaluation = book_data->eval;

		/* 指し手の対称回転変換の場合分け */
		switch (TRANCE_MOVE)
		{
		case 0:
			move = book_data->node->move;
			break;
		case 1:
		{
			UINT64 t_move = rotate_90(1ULL << book_data->node->move);
			move = CountBit((t_move & (-(INT64)t_move)) - 1);
		}
		break;
		case 2:
		{
			UINT64 t_move = rotate_180(1ULL << book_data->node->move);
			move = CountBit((t_move & (-(INT64)t_move)) - 1);
		}
		break;
		case 3:
		{
			UINT64 t_move = rotate_270(1ULL << book_data->node->move);
			move = CountBit((t_move & (-(INT64)t_move)) - 1);
		}
		break;
		case 4:
		{
			UINT64 t_move = symmetry_x(1ULL << book_data->node->move);
			move = CountBit((t_move & (-(INT64)t_move)) - 1);
		}
		break;
		case 5:
		{
			UINT64 t_move = symmetry_y(1ULL << book_data->node->move);
			move = CountBit((t_move & (-(INT64)t_move)) - 1);
		}
		break;
		case 6:
		{
			UINT64 t_move = symmetry_b(1ULL << book_data->node->move);
			move = CountBit((t_move & (-(INT64)t_move)) - 1);
		}
		break;
		case 7:
		{
			UINT64 t_move = symmetry_w(1ULL << book_data->node->move);
			move = CountBit((t_move & (-(INT64)t_move)) - 1);
		}
		break;
		default:
			move = book_data->node->move;
			break;
		}
	}

	return move;
}