osd-contiki/core/net/rpl/rpl.h

295 lines
9.9 KiB
C

/*
* Copyright (c) 2010, Swedish Institute of Computer Science.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. 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.
* 3. Neither the name of the Institute 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 INSTITUTE 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 INSTITUTE 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.
*
* This file is part of the Contiki operating system.
*
* \file
* Public API declarations for ContikiRPL.
* \author
* Joakim Eriksson <joakime@sics.se> & Nicolas Tsiftes <nvt@sics.se>
*
*/
#ifndef RPL_H
#define RPL_H
#include "rpl-conf.h"
#include "lib/list.h"
#include "net/ip/uip.h"
#include "net/ipv6/uip-ds6.h"
#include "sys/ctimer.h"
/*---------------------------------------------------------------------------*/
typedef uint16_t rpl_rank_t;
typedef uint16_t rpl_ocp_t;
/*---------------------------------------------------------------------------*/
/* DAG Metric Container Object Types, to be confirmed by IANA. */
#define RPL_DAG_MC_NONE 0 /* Local identifier for empty MC */
#define RPL_DAG_MC_NSA 1 /* Node State and Attributes */
#define RPL_DAG_MC_ENERGY 2 /* Node Energy */
#define RPL_DAG_MC_HOPCOUNT 3 /* Hop Count */
#define RPL_DAG_MC_THROUGHPUT 4 /* Throughput */
#define RPL_DAG_MC_LATENCY 5 /* Latency */
#define RPL_DAG_MC_LQL 6 /* Link Quality Level */
#define RPL_DAG_MC_ETX 7 /* Expected Transmission Count */
#define RPL_DAG_MC_LC 8 /* Link Color */
/* DAG Metric Container flags. */
#define RPL_DAG_MC_FLAG_P 0x8
#define RPL_DAG_MC_FLAG_C 0x4
#define RPL_DAG_MC_FLAG_O 0x2
#define RPL_DAG_MC_FLAG_R 0x1
/* DAG Metric Container aggregation mode. */
#define RPL_DAG_MC_AGGR_ADDITIVE 0
#define RPL_DAG_MC_AGGR_MAXIMUM 1
#define RPL_DAG_MC_AGGR_MINIMUM 2
#define RPL_DAG_MC_AGGR_MULTIPLICATIVE 3
/* The bit index within the flags field of
the rpl_metric_object_energy structure. */
#define RPL_DAG_MC_ENERGY_INCLUDED 3
#define RPL_DAG_MC_ENERGY_TYPE 1
#define RPL_DAG_MC_ENERGY_ESTIMATION 0
#define RPL_DAG_MC_ENERGY_TYPE_MAINS 0
#define RPL_DAG_MC_ENERGY_TYPE_BATTERY 1
#define RPL_DAG_MC_ENERGY_TYPE_SCAVENGING 2
struct rpl_metric_object_energy {
uint8_t flags;
uint8_t energy_est;
};
/* Logical representation of a DAG Metric Container. */
struct rpl_metric_container {
uint8_t type;
uint8_t flags;
uint8_t aggr;
uint8_t prec;
uint8_t length;
union metric_object {
struct rpl_metric_object_energy energy;
uint16_t etx;
} obj;
};
typedef struct rpl_metric_container rpl_metric_container_t;
/*---------------------------------------------------------------------------*/
struct rpl_instance;
struct rpl_dag;
/*---------------------------------------------------------------------------*/
#define RPL_PARENT_FLAG_UPDATED 0x1
#define RPL_PARENT_FLAG_LINK_METRIC_VALID 0x2
struct rpl_parent {
struct rpl_dag *dag;
#if RPL_DAG_MC != RPL_DAG_MC_NONE
rpl_metric_container_t mc;
#endif /* RPL_DAG_MC != RPL_DAG_MC_NONE */
rpl_rank_t rank;
clock_time_t last_tx_time;
uint8_t dtsn;
uint8_t flags;
};
typedef struct rpl_parent rpl_parent_t;
/*---------------------------------------------------------------------------*/
/* RPL DIO prefix suboption */
struct rpl_prefix {
uip_ipaddr_t prefix;
uint32_t lifetime;
uint8_t length;
uint8_t flags;
};
typedef struct rpl_prefix rpl_prefix_t;
/*---------------------------------------------------------------------------*/
/* Directed Acyclic Graph */
struct rpl_dag {
uip_ipaddr_t dag_id;
rpl_rank_t min_rank; /* should be reset per DAG iteration! */
uint8_t version;
uint8_t grounded;
uint8_t preference;
uint8_t used;
/* live data for the DAG */
uint8_t joined;
rpl_parent_t *preferred_parent;
rpl_rank_t rank;
struct rpl_instance *instance;
rpl_prefix_t prefix_info;
};
typedef struct rpl_dag rpl_dag_t;
typedef struct rpl_instance rpl_instance_t;
/*---------------------------------------------------------------------------*/
/*
* API for RPL objective functions (OF)
*
* reset(dag)
*
* Resets the objective function state for a specific DAG. This function is
* called when doing a global repair on the DAG.
*
* neighbor_link_callback(parent, known, etx)
*
* Receives link-layer neighbor information. The parameter "known" is set
* either to 0 or 1. The "etx" parameter specifies the current
* ETX(estimated transmissions) for the neighbor.
*
* best_parent(parent1, parent2)
*
* Compares two parents and returns the best one, according to the OF.
*
* best_dag(dag1, dag2)
*
* Compares two DAGs and returns the best one, according to the OF.
*
* calculate_rank(parent, base_rank)
*
* Calculates a rank value using the parent rank and a base rank.
* If "parent" is NULL, the objective function selects a default increment
* that is adds to the "base_rank". Otherwise, the OF uses information known
* about "parent" to select an increment to the "base_rank".
*
* update_metric_container(dag)
*
* Updates the metric container for outgoing DIOs in a certain DAG.
* If the objective function of the DAG does not use metric containers,
* the function should set the object type to RPL_DAG_MC_NONE.
*/
struct rpl_of {
void (*reset)(struct rpl_dag *);
void (*neighbor_link_callback)(rpl_parent_t *, int, int);
rpl_parent_t *(*best_parent)(rpl_parent_t *, rpl_parent_t *);
rpl_dag_t *(*best_dag)(rpl_dag_t *, rpl_dag_t *);
rpl_rank_t (*calculate_rank)(rpl_parent_t *, rpl_rank_t);
void (*update_metric_container)( rpl_instance_t *);
rpl_ocp_t ocp;
};
typedef struct rpl_of rpl_of_t;
/* Declare the selected objective function. */
extern rpl_of_t RPL_OF;
/*---------------------------------------------------------------------------*/
/* Instance */
struct rpl_instance {
/* DAG configuration */
rpl_metric_container_t mc;
rpl_of_t *of;
rpl_dag_t *current_dag;
rpl_dag_t dag_table[RPL_MAX_DAG_PER_INSTANCE];
/* The current default router - used for routing "upwards" */
uip_ds6_defrt_t *def_route;
uint8_t instance_id;
uint8_t used;
uint8_t dtsn_out;
uint8_t mop;
uint8_t dio_intdoubl;
uint8_t dio_intmin;
uint8_t dio_redundancy;
uint8_t default_lifetime;
uint8_t dio_intcurrent;
uint8_t dio_send; /* for keeping track of which mode the timer is in */
uint8_t dio_counter;
rpl_rank_t max_rankinc;
rpl_rank_t min_hoprankinc;
uint16_t lifetime_unit; /* lifetime in seconds = l_u * d_l */
#if RPL_CONF_STATS
uint16_t dio_totint;
uint16_t dio_totsend;
uint16_t dio_totrecv;
#endif /* RPL_CONF_STATS */
clock_time_t dio_next_delay; /* delay for completion of dio interval */
#if RPL_WITH_PROBING
struct ctimer probing_timer;
#endif /* RPL_WITH_PROBING */
struct ctimer dio_timer;
struct ctimer dao_timer;
struct ctimer dao_lifetime_timer;
};
/*---------------------------------------------------------------------------*/
/* Public RPL functions. */
void rpl_init(void);
void uip_rpl_input(void);
rpl_dag_t *rpl_set_root(uint8_t instance_id, uip_ipaddr_t *dag_id);
int rpl_set_prefix(rpl_dag_t *dag, uip_ipaddr_t *prefix, unsigned len);
int rpl_repair_root(uint8_t instance_id);
int rpl_set_default_route(rpl_instance_t *instance, uip_ipaddr_t *from);
rpl_dag_t *rpl_get_any_dag(void);
rpl_instance_t *rpl_get_instance(uint8_t instance_id);
int rpl_update_header_empty(void);
int rpl_update_header_final(uip_ipaddr_t *addr);
int rpl_verify_header(int);
void rpl_insert_header(void);
void rpl_remove_header(void);
uint8_t rpl_invert_header(void);
uip_ipaddr_t *rpl_get_parent_ipaddr(rpl_parent_t *nbr);
rpl_parent_t *rpl_get_parent(uip_lladdr_t *addr);
rpl_rank_t rpl_get_parent_rank(uip_lladdr_t *addr);
uint16_t rpl_get_parent_link_metric(const uip_lladdr_t *addr);
void rpl_dag_init(void);
uip_ds6_nbr_t *rpl_get_nbr(rpl_parent_t *parent);
void rpl_print_neighbor_list();
/* Per-parent RPL information */
NBR_TABLE_DECLARE(rpl_parents);
/**
* RPL modes
*
* The RPL module can be in either of three modes: mesh mode
* (RPL_MODE_MESH), feater mode (RPL_MODE_FEATHER), and leaf mode
* (RPL_MODE_LEAF). In mesh mode, nodes forward data for other nodes,
* and are reachable by others. In feather mode, nodes can forward
* data for other nodes, but are not reachable themselves. In leaf
* mode, nodes do not forward data for others, but are reachable by
* others. */
enum rpl_mode {
RPL_MODE_MESH = 0,
RPL_MODE_FEATHER = 1,
RPL_MODE_LEAF = 2,
};
/**
* Set the RPL mode
*
* \param mode The new RPL mode
* \retval The previous RPL mode
*/
enum rpl_mode rpl_set_mode(enum rpl_mode mode);
/**
* Get the RPL mode
*
* \retval The RPL mode
*/
enum rpl_mode rpl_get_mode(void);
/*---------------------------------------------------------------------------*/
#endif /* RPL_H */