Context Navigation

← Previous Change
Next Change →

Changeset aadf01e in mainline for uspace/srv/net/il/ip

Timestamp:

2010-03-07T15:13:28Z (16 years ago)

Author:

Lukas Mejdrech <lukasmejdrech@…>

Branches:

lfn, master, serial, ticket/834-toolchain-update, topic/msim-upgrade, topic/simplify-dev-export

Children:

Parents:

Message:

Coding style (no functional change)

Location:

uspace/srv/net/il/ip

Files:

: 8 edited

ip.c (modified) (44 diffs)
ip.h (modified) (8 diffs)
ip_client.c (modified) (2 diffs)
ip_header.h (modified) (8 diffs)
ip_messages.h (modified) (1 diff)
ip_module.c (modified) (5 diffs)
ip_module.h (modified) (2 diffs)
ip_remote.c (modified) (1 diff)

Legend:

: Unmodified
: Added
: Removed

uspace/srv/net/il/ip/ip.c

-              raa85487
+              raadf01e
 /** IP packet address length.
  */
 #define IP_ADDR                                                 sizeof( struct sockaddr_in6 )
+#define IP_ADDR                                                 sizeof(struct sockaddr_in6)
 /** IP packet prefix length.
  */
 #define IP_PREFIX                                               sizeof( ip_header_t )
+#define IP_PREFIX                                               sizeof(ip_header_t)
 /** IP packet suffix length.
 …
 /** The IP localhost address.
  */
 #define IPV4_LOCALHOST_ADDRESS  htonl(( 127 << 24 ) + 1 )
+#define IPV4_LOCALHOST_ADDRESS  htonl((127 << 24) + 1)
 /** IP global data.
 …
 ip_globals_t    ip_globals;
 DEVICE_MAP_IMPLEMENT( ip_netifs, ip_netif_t )
 INT_MAP_IMPLEMENT( ip_protos, ip_proto_t )
 GENERIC_FIELD_IMPLEMENT( ip_routes, ip_route_t )
+DEVICE_MAP_IMPLEMENT(ip_netifs, ip_netif_t)
+INT_MAP_IMPLEMENT(ip_protos, ip_proto_t)
+GENERIC_FIELD_IMPLEMENT(ip_routes, ip_route_t)
 /** Updates the device content length according to the new MTU value.
 …
  *  @returns ENOENT if device is not found.
  */
 int     ip_mtu_changed_message( device_id_t device_id, size_t mtu );
+int ip_mtu_changed_message(device_id_t device_id, size_t mtu);
 /** Updates the device state.
 …
  *  @returns ENOENT if device is not found.
  */
 int     ip_device_state_message( device_id_t device_id, device_state_t state );
+int ip_device_state_message(device_id_t device_id, device_state_t state);
 /** Returns the device packet dimensions for sending.
 …
  *  @returns EOK on success.
  */
 int     ip_packet_size_message( device_id_t device_id, size_t * addr_len, size_t * prefix, size_t * content, size_t * suffix );
+int ip_packet_size_message(device_id_t device_id, size_t * addr_len, size_t * prefix, size_t * content, size_t * suffix);
 /** Registers the transport layer protocol.
 …
  *  @returns ENOMEM if there is not enough memory left.
  */
 int     ip_register( int protocol, services_t service, int phone, tl_received_msg_t tl_received_msg );
+int ip_register(int protocol, services_t service, int phone, tl_received_msg_t tl_received_msg);
 /** Initializes a new network interface specific data.
 …
  *  @returns Other error codes as defined for the nil_packet_size_req() function.
  */
 int     ip_netif_initialize( ip_netif_ref ip_netif );
+int ip_netif_initialize(ip_netif_ref ip_netif);
 /** Sends the packet or the packet queue via the specified route.
 …
  *  @returns Other error codes as defined for the ip_prepare_packet() function.
  */
 int     ip_send_route( packet_t packet, ip_netif_ref netif, ip_route_ref route, in_addr_t * src, in_addr_t dest, services_t error );
+int ip_send_route(packet_t packet, ip_netif_ref netif, ip_route_ref route, in_addr_t * src, in_addr_t dest, services_t error);
 /** Prepares the outgoing packet or the packet queue.
 …
  *  @returns Other error codes as defined for the packet_set_addr() function.
  */
 int     ip_prepare_packet( in_addr_t * source, in_addr_t dest, packet_t packet, measured_string_ref destination );
+int ip_prepare_packet(in_addr_t * source, in_addr_t dest, packet_t packet, measured_string_ref destination);
 /** Checks the packet queue lengths and fragments the packets if needed.
 …
  *  @returns NULL if there are no packets left.
  */
 packet_t        ip_split_packet( packet_t packet, size_t prefix, size_t content, size_t suffix, socklen_t addr_len, services_t error );
+packet_t ip_split_packet(packet_t packet, size_t prefix, size_t content, size_t suffix, socklen_t addr_len, services_t error);
 /** Checks the packet length and fragments it if needed.
 …
  *  @returns Other error codes as defined for the ip_fragment_packet_data() function.
  */
 int     ip_fragment_packet( packet_t packet, size_t length, size_t prefix, size_t suffix, socklen_t addr_len );
+int ip_fragment_packet(packet_t packet, size_t length, size_t prefix, size_t suffix, socklen_t addr_len);
 /** Fragments the packet from the end.
 …
  *  @returns Other error codes as defined for the pq_insert_after() function.
  */
 int     ip_fragment_packet_data( packet_t packet, packet_t new_packet, ip_header_ref header, ip_header_ref new_header, size_t length, const struct sockaddr * src, const struct sockaddr * dest, socklen_t addrlen );
+int ip_fragment_packet_data(packet_t packet, packet_t new_packet, ip_header_ref header, ip_header_ref new_header, size_t length, const struct sockaddr * src, const struct sockaddr * dest, socklen_t addrlen);
 /** Prefixes a middle fragment header based on the last fragment header to the packet.
 …
  *  @returns NULL on error.
  */
 ip_header_ref   ip_create_middle_header( packet_t packet, ip_header_ref last );
+ip_header_ref ip_create_middle_header(packet_t packet, ip_header_ref last);
 /** Copies the fragment header.
 …
  *  @param[in] first The original header to be copied.
  */
 void ip_create_last_header( ip_header_ref last, ip_header_ref first );
+void ip_create_last_header(ip_header_ref last, ip_header_ref first);
 /** Returns the network interface's IP address.
 …
  *  @returns NULL if no IP address was found.
  */
 in_addr_t *     ip_netif_address( ip_netif_ref netif );
+in_addr_t * ip_netif_address(ip_netif_ref netif);
 /** Searches all network interfaces if there is a suitable route.
 …
  *  @returns NULL if no route was found.
  */
 ip_route_ref    ip_find_route( in_addr_t destination );
+ip_route_ref ip_find_route(in_addr_t destination);
 /** Searches the network interfaces if there is a suitable route.
 …
  *  @returns NULL if no route was found.
  */
 ip_route_ref    ip_netif_find_route( ip_netif_ref netif, in_addr_t destination );
+ip_route_ref ip_netif_find_route(ip_netif_ref netif, in_addr_t destination);
 /** Processes the received IP packet or the packet queue one by one.
 …
  *  @returns ENOMEM if there is not enough memory left.
  */
 int     ip_receive_message( device_id_t device_id, packet_t packet );
+int ip_receive_message(device_id_t device_id, packet_t packet);
 /** Processes the received packet.
 …
  *  @returns ENOENT if the packet is for another host and the routing is disabled.
  */
 int     ip_process_packet( device_id_t device_id, packet_t packet );
+int ip_process_packet(device_id_t device_id, packet_t packet);
 /** Returns the packet destination address from the IP header.
 …
  *  @returns The packet destination address.
  */
 in_addr_t       ip_get_destination( ip_header_ref header );
+in_addr_t ip_get_destination(ip_header_ref header);
 /** Delivers the packet to the local host.
 …
  *  @returns Other error codes as defined for the protocol specific tl_received_msg function.
  */
 int     ip_deliver_local( device_id_t device_id, packet_t packet, ip_header_ref header, services_t error );
+int ip_deliver_local(device_id_t device_id, packet_t packet, ip_header_ref header, services_t error);
 /** Prepares the ICMP notification packet.
 …
  *  @returns EINVAL if the ip_prepare_icmp() fails.
  */
 int     ip_prepare_icmp_and_get_phone( services_t error, packet_t packet, ip_header_ref header );
+int ip_prepare_icmp_and_get_phone(services_t error, packet_t packet, ip_header_ref header);
 /** Returns the ICMP phone.
 …
  *  @returns ENOENT if the ICMP is not registered.
  */
 int     ip_get_icmp_phone( void );
+int ip_get_icmp_phone(void);
 /** Prepares the ICMP notification packet.
 …
  *  @returns Other error codes as defined for the packet_set_addr().
  */
 int     ip_prepare_icmp( packet_t packet, ip_header_ref header );
+int ip_prepare_icmp(packet_t packet, ip_header_ref header);
 /** Releases the packet and returns the result.
 …
  *  @return The result parameter.
  */
 int     ip_release_and_return( packet_t packet, int result );
 int ip_initialize( async_client_conn_t client_connection ){
+int ip_release_and_return(packet_t packet, int result);
+int ip_initialize(async_client_conn_t client_connection){
         ERROR_DECLARE;
         fibril_rwlock_initialize( & ip_globals.lock );
         fibril_rwlock_write_lock( & ip_globals.lock );
         fibril_rwlock_initialize( & ip_globals.protos_lock );
         fibril_rwlock_initialize( & ip_globals.netifs_lock );
+        fibril_rwlock_initialize(&ip_globals.lock);
+        fibril_rwlock_write_lock(&ip_globals.lock);
+        fibril_rwlock_initialize(&ip_globals.protos_lock);
+        fibril_rwlock_initialize(&ip_globals.netifs_lock);
         ip_globals.packet_counter = 0;
         ip_globals.gateway.address.s_addr = 0;
 …
         ip_globals.gateway.gateway.s_addr = 0;
         ip_globals.gateway.netif = NULL;
         ERROR_PROPAGATE( ip_netifs_initialize( & ip_globals.netifs ));
         ERROR_PROPAGATE( ip_protos_initialize( & ip_globals.protos ));
+        ERROR_PROPAGATE(ip_netifs_initialize(&ip_globals.netifs));
+        ERROR_PROPAGATE(ip_protos_initialize(&ip_globals.protos));
         ip_globals.client_connection = client_connection;
         ERROR_PROPAGATE( modules_initialize( & ip_globals.modules ));
         ERROR_PROPAGATE( add_module( NULL, & ip_globals.modules, ARP_NAME, ARP_FILENAME, SERVICE_ARP, arp_task_get_id(), arp_connect_module ));
         fibril_rwlock_write_unlock( & ip_globals.lock );
+        ERROR_PROPAGATE(modules_initialize(&ip_globals.modules));
+        ERROR_PROPAGATE(add_module(NULL, &ip_globals.modules, ARP_NAME, ARP_FILENAME, SERVICE_ARP, arp_task_get_id(), arp_connect_module));
+        fibril_rwlock_write_unlock(&ip_globals.lock);
         return EOK;
+}
 int ip_device_req( int il_phone, device_id_t device_id, services_t netif ){
+int ip_device_req(int il_phone, device_id_t device_id, services_t netif){
         ERROR_DECLARE;
+        ip_netif_ref    ip_netif;
+        ip_route_ref    route;
+        int                             index;
+        char *                  data;
+        ip_netif = ( ip_netif_ref ) malloc( sizeof( ip_netif_t ));
+        if( ! ip_netif ) return ENOMEM;
+        if( ERROR_OCCURRED( ip_routes_initialize( & ip_netif->routes ))){
+                free( ip_netif );
+        ip_netif_ref ip_netif;
+        ip_route_ref route;
+        int index;
+        char * data;
+        ip_netif = (ip_netif_ref) malloc(sizeof(ip_netif_t));
+        if(! ip_netif){
+                return ENOMEM;
+        }
+        if(ERROR_OCCURRED(ip_routes_initialize(&ip_netif->routes))){
+                free(ip_netif);
                 return ERROR_CODE;
+        }
 …
         ip_netif->service = netif;
         ip_netif->state = NETIF_STOPPED;
         fibril_rwlock_write_lock( & ip_globals.netifs_lock );
         if( ERROR_OCCURRED( ip_netif_initialize( ip_netif ))){
                 fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
                 ip_routes_destroy( & ip_netif->routes );
                 free( ip_netif );
+        fibril_rwlock_write_lock(&ip_globals.netifs_lock);
+        if(ERROR_OCCURRED(ip_netif_initialize(ip_netif))){
+                fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
+                ip_routes_destroy(&ip_netif->routes);
+                free(ip_netif);
                 return ERROR_CODE;
+        }
+        if( ip_netif->arp ) ++ ip_netif->arp->usage;
+        if(ip_netif->arp){
+                ++ ip_netif->arp->usage;
+        }
         // print the settings
         printf( "New device registered:\n\tid\t= %d\n\tphone\t= %d\n\tIPV\t= %d\n", ip_netif->device_id, ip_netif->phone, ip_netif->ipv );
         printf( "\tconfiguration\t= %s\n", ip_netif->dhcp ? "dhcp" : "static" );
+        printf("New device registered:\n\tid\t= %d\n\tphone\t= %d\n\tIPV\t= %d\n", ip_netif->device_id, ip_netif->phone, ip_netif->ipv);
+        printf("\tconfiguration\t= %s\n", ip_netif->dhcp ? "dhcp" : "static");
         // TODO ipv6 addresses
         data = ( char * ) malloc( INET_ADDRSTRLEN );
         if( data ){
                 for( index = 0; index < ip_routes_count( & ip_netif->routes ); ++ index ){
                         route = ip_routes_get_index( & ip_netif->routes, index );
                         if( route ){
                                 printf( "\tRouting %d:\n", index );
                                 inet_ntop( AF_INET, ( uint8_t * ) & route->address.s_addr, data, INET_ADDRSTRLEN );
                                 printf( "\t\taddress\t= %s\n", data );
                                 inet_ntop( AF_INET, ( uint8_t * ) & route->netmask.s_addr, data, INET_ADDRSTRLEN );
                                 printf( "\t\tnetmask\t= %s\n", data );
                                 inet_ntop( AF_INET, ( uint8_t * ) & route->gateway.s_addr, data, INET_ADDRSTRLEN );
                                 printf( "\t\tgateway\t= %s\n", data );
+                        }
+                }
                 inet_ntop( AF_INET, ( uint8_t * ) & ip_netif->broadcast.s_addr, data, INET_ADDRSTRLEN );
                 printf( "\t\tbroadcast\t= %s\n", data );
                 free( data );
+        }
         fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+        data = (char *) malloc(INET_ADDRSTRLEN);
+        if(data){
+                for(index = 0; index < ip_routes_count(&ip_netif->routes); ++ index){
+                        route = ip_routes_get_index(&ip_netif->routes, index);
+                        if(route){
+                                printf("\tRouting %d:\n", index);
+                                inet_ntop(AF_INET, (uint8_t *) &route->address.s_addr, data, INET_ADDRSTRLEN);
+                                printf("\t\taddress\t= %s\n", data);
+                                inet_ntop(AF_INET, (uint8_t *) &route->netmask.s_addr, data, INET_ADDRSTRLEN);
+                                printf("\t\tnetmask\t= %s\n", data);
+                                inet_ntop(AF_INET, (uint8_t *) &route->gateway.s_addr, data, INET_ADDRSTRLEN);
+                                printf("\t\tgateway\t= %s\n", data);
+                        }
+                }
+                inet_ntop(AF_INET, (uint8_t *) &ip_netif->broadcast.s_addr, data, INET_ADDRSTRLEN);
+                printf("\t\tbroadcast\t= %s\n", data);
+                free(data);
+        }
+        fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
         return EOK;
+}
 int ip_netif_initialize( ip_netif_ref ip_netif ){
+int ip_netif_initialize(ip_netif_ref ip_netif){
         ERROR_DECLARE;
         measured_string_t       names[] = {{ str_dup("IPV"), 3 }, { str_dup("IP_CONFIG"), 9 }, { str_dup("IP_ADDR"), 7 }, { str_dup("IP_NETMASK"), 10 }, { str_dup("IP_GATEWAY"), 10 }, { str_dup("IP_BROADCAST"), 12 }, { str_dup("ARP"), 3 }, { str_dup("IP_ROUTING"), 10 }};
         measured_string_ref     configuration;
         size_t                          count = sizeof( names ) / sizeof( measured_string_t );
         char *                          data;
         measured_string_t       address;
         int                                     index;
         ip_route_ref            route;
         in_addr_t                       gateway;
+        measured_string_t names[] = {{str_dup("IPV"), 3}, {str_dup("IP_CONFIG"), 9}, {str_dup("IP_ADDR"), 7}, {str_dup("IP_NETMASK"), 10}, {str_dup("IP_GATEWAY"), 10}, {str_dup("IP_BROADCAST"), 12}, {str_dup("ARP"), 3}, {str_dup("IP_ROUTING"), 10}};
+        measured_string_ref configuration;
+        size_t count = sizeof(names) / sizeof(measured_string_t);
+        char * data;
+        measured_string_t address;
+        int index;
+        ip_route_ref route;
+        in_addr_t gateway;
         ip_netif->arp = NULL;
 …
         ip_netif->dhcp = false;
         ip_netif->routing = NET_DEFAULT_IP_ROUTING;
         configuration = & names[ 0 ];
+        configuration = &names[0];
         // get configuration
         ERROR_PROPAGATE( net_get_device_conf_req( ip_globals.net_phone, ip_netif->device_id, & configuration, count, & data ));
         if( configuration ){
                 if( configuration[ 0 ].value ){
                         ip_netif->ipv = strtol( configuration[ 0 ].value, NULL, 0 );
+                }
                 ip_netif->dhcp = ! str_lcmp( configuration[ 1 ].value, "dhcp", configuration[ 1 ].length );
                 if( ip_netif->dhcp ){
+        ERROR_PROPAGATE(net_get_device_conf_req(ip_globals.net_phone, ip_netif->device_id, &configuration, count, &data));
+        if(configuration){
+                if(configuration[0].value){
+                        ip_netif->ipv = strtol(configuration[0].value, NULL, 0);
+                }
+                ip_netif->dhcp = ! str_lcmp(configuration[1].value, "dhcp", configuration[1].length);
+                if(ip_netif->dhcp){
                         // TODO dhcp
                         net_free_settings( configuration, data );
+                        net_free_settings(configuration, data);
                         return ENOTSUP;
                 }else if( ip_netif->ipv == IPV4 ){
                         route = ( ip_route_ref ) malloc( sizeof( ip_route_t ));
                         if( ! route ){
                                 net_free_settings( configuration, data );
+                }else if(ip_netif->ipv == IPV4){
+                        route = (ip_route_ref) malloc(sizeof(ip_route_t));
+                        if(! route){
+                                net_free_settings(configuration, data);
                                 return ENOMEM;
+                        }
 …
                         route->gateway.s_addr = 0;
                         route->netif = ip_netif;
                         index = ip_routes_add( & ip_netif->routes, route );
                         if( index < 0 ){
                                 net_free_settings( configuration, data );
                                 free( route );
+                        index = ip_routes_add(&ip_netif->routes, route);
+                        if(index < 0){
+                                net_free_settings(configuration, data);
+                                free(route);
                                 return index;
+                        }
                         if( ERROR_OCCURRED( inet_pton( AF_INET, configuration[ 2 ].value, ( uint8_t * ) & route->address.s_addr ))
                         || ERROR_OCCURRED( inet_pton( AF_INET, configuration[ 3 ].value, ( uint8_t * ) & route->netmask.s_addr ))
                         || ( inet_pton( AF_INET, configuration[ 4 ].value, ( uint8_t * ) & gateway.s_addr ) == EINVAL )
                         || ( inet_pton( AF_INET, configuration[ 5 ].value, ( uint8_t * ) & ip_netif->broadcast.s_addr ) == EINVAL )){
                                 net_free_settings( configuration, data );
+                        if(ERROR_OCCURRED(inet_pton(AF_INET, configuration[2].value, (uint8_t *) &route->address.s_addr))
+                                || ERROR_OCCURRED(inet_pton(AF_INET, configuration[3].value, (uint8_t *) &route->netmask.s_addr))
+                                || (inet_pton(AF_INET, configuration[4].value, (uint8_t *) &gateway.s_addr) == EINVAL)
+                                || (inet_pton(AF_INET, configuration[5].value, (uint8_t *) &ip_netif->broadcast.s_addr) == EINVAL)){
+                                net_free_settings(configuration, data);
                                 return EINVAL;
+                        }
                 }else{
                         // TODO ipv6 in separate module
                         net_free_settings( configuration, data );
+                        net_free_settings(configuration, data);
                         return ENOTSUP;
+                }
                 if( configuration[ 6 ].value ){
                         ip_netif->arp = get_running_module( & ip_globals.modules, configuration[ 6 ].value );
                         if( ! ip_netif->arp ){
                                 printf( "Failed to start the arp %s\n", configuration[ 6 ].value );
                                 net_free_settings( configuration, data );
+                if(configuration[6].value){
+                        ip_netif->arp = get_running_module(&ip_globals.modules, configuration[6].value);
+                        if(! ip_netif->arp){
+                                printf("Failed to start the arp %s\n", configuration[6].value);
+                                net_free_settings(configuration, data);
                                 return EINVAL;
+                        }
+                }
                 if( configuration[ 7 ].value ){
                         ip_netif->routing = ( configuration[ 7 ].value[ 0 ] == 'y' );
+                }
                 net_free_settings( configuration, data );
+                if(configuration[7].value){
+                        ip_netif->routing = (configuration[7].value[0] == 'y');
+                }
+                net_free_settings(configuration, data);
+        }
         // binds the netif service which also initializes the device
         ip_netif->phone = nil_bind_service( ip_netif->service, ( ipcarg_t ) ip_netif->device_id, SERVICE_IP, ip_globals.client_connection );
         if( ip_netif->phone < 0 ){
                 printf( "Failed to contact the nil service %d\n", ip_netif->service );
+        ip_netif->phone = nil_bind_service(ip_netif->service, (ipcarg_t) ip_netif->device_id, SERVICE_IP, ip_globals.client_connection);
+        if(ip_netif->phone < 0){
+                printf("Failed to contact the nil service %d\n", ip_netif->service);
                 return ip_netif->phone;
+        }
         // has to be after the device netif module initialization
         if( ip_netif->arp ){
                 if( route ){
                         address.value = ( char * ) & route->address.s_addr;
                         address.length = CONVERT_SIZE( in_addr_t, char, 1 );
                         ERROR_PROPAGATE( arp_device_req( ip_netif->arp->phone, ip_netif->device_id, SERVICE_IP, ip_netif->service, & address ));
+        if(ip_netif->arp){
+                if(route){
+                        address.value = (char *) &route->address.s_addr;
+                        address.length = CONVERT_SIZE(in_addr_t, char, 1);
+                        ERROR_PROPAGATE(arp_device_req(ip_netif->arp->phone, ip_netif->device_id, SERVICE_IP, ip_netif->service, &address));
                 }else{
                         ip_netif->arp = 0;
 …
+        }
         // get packet dimensions
         ERROR_PROPAGATE( nil_packet_size_req( ip_netif->phone, ip_netif->device_id, & ip_netif->packet_dimension ));
         if( ip_netif->packet_dimension.content < IP_MIN_CONTENT ){
                 printf( "Maximum transmission unit %d bytes is too small, at least %d bytes are needed\n", ip_netif->packet_dimension.content, IP_MIN_CONTENT );
+        ERROR_PROPAGATE(nil_packet_size_req(ip_netif->phone, ip_netif->device_id, &ip_netif->packet_dimension));
+        if(ip_netif->packet_dimension.content < IP_MIN_CONTENT){
+                printf("Maximum transmission unit %d bytes is too small, at least %d bytes are needed\n", ip_netif->packet_dimension.content, IP_MIN_CONTENT);
                 ip_netif->packet_dimension.content = IP_MIN_CONTENT;
+        }
+        index = ip_netifs_add( & ip_globals.netifs, ip_netif->device_id, ip_netif );
+        if( index < 0 ) return index;
+        if( gateway.s_addr ){
+        index = ip_netifs_add(&ip_globals.netifs, ip_netif->device_id, ip_netif);
+        if(index < 0){
+                return index;
+        }
+        if(gateway.s_addr){
                 // the default gateway
                 ip_globals.gateway.address.s_addr = 0;
 …
+}
 int ip_mtu_changed_message( device_id_t device_id, size_t mtu ){
         ip_netif_ref    netif;
         fibril_rwlock_write_lock( & ip_globals.netifs_lock );
         netif = ip_netifs_find( & ip_globals.netifs, device_id );
         if( ! netif ){
                 fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+int ip_mtu_changed_message(device_id_t device_id, size_t mtu){
+        ip_netif_ref netif;
+        fibril_rwlock_write_lock(&ip_globals.netifs_lock);
+        netif = ip_netifs_find(&ip_globals.netifs, device_id);
+        if(! netif){
+                fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
                 return ENOENT;
+        }
         netif->packet_dimension.content = mtu;
         printf( "ip - device %d changed mtu to %d\n\n", device_id, mtu );
         fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+        printf("ip - device %d changed mtu to %d\n\n", device_id, mtu);
+        fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
         return EOK;
+}
 int ip_device_state_message( device_id_t device_id, device_state_t state ){
         ip_netif_ref    netif;
         fibril_rwlock_write_lock( & ip_globals.netifs_lock );
+int ip_device_state_message(device_id_t device_id, device_state_t state){
+        ip_netif_ref netif;
+        fibril_rwlock_write_lock(&ip_globals.netifs_lock);
         // find the device
         netif = ip_netifs_find( & ip_globals.netifs, device_id );
         if( ! netif ){
                 fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+        netif = ip_netifs_find(&ip_globals.netifs, device_id);
+        if(! netif){
+                fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
                 return ENOENT;
+        }
         netif->state = state;
         printf( "ip - device %d changed state to %d\n\n", device_id, state );
         fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+        printf("ip - device %d changed state to %d\n\n", device_id, state);
+        fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
         return EOK;
+}
 int ip_connect_module( services_t service ){
+int ip_connect_module(services_t service){
         return EOK;
+}
+int ip_bind_service( services_t service, int protocol, services_t me, async_client_conn_t receiver, tl_received_msg_t received_msg ){
+        return ip_register( protocol, me, 0, received_msg );
+}
+int ip_register( int protocol, services_t service, int phone, tl_received_msg_t received_msg ){
+        ip_proto_ref    proto;
+        int                             index;
+        if( !( protocol && service && (( phone > 0 ) || ( received_msg )))) return EINVAL;
+        proto = ( ip_proto_ref ) malloc( sizeof( ip_protos_t ));
+        if( ! proto ) return ENOMEM;
+int ip_bind_service(services_t service, int protocol, services_t me, async_client_conn_t receiver, tl_received_msg_t received_msg){
+        return ip_register(protocol, me, 0, received_msg);
+}
+int ip_register(int protocol, services_t service, int phone, tl_received_msg_t received_msg){
+        ip_proto_ref proto;
+        int index;
+        if(!(protocol && service && ((phone > 0) || (received_msg)))){
+                return EINVAL;
+        }
+        proto = (ip_proto_ref) malloc(sizeof(ip_protos_t));
+        if(! proto){
+                return ENOMEM;
+        }
         proto->protocol = protocol;
         proto->service = service;
         proto->phone = phone;
         proto->received_msg = received_msg;
         fibril_rwlock_write_lock( & ip_globals.protos_lock );
         index = ip_protos_add( & ip_globals.protos, proto->protocol, proto );
         if( index < 0 ){
                 fibril_rwlock_write_unlock( & ip_globals.protos_lock );
                 free( proto );
+        fibril_rwlock_write_lock(&ip_globals.protos_lock);
+        index = ip_protos_add(&ip_globals.protos, proto->protocol, proto);
+        if(index < 0){
+                fibril_rwlock_write_unlock(&ip_globals.protos_lock);
+                free(proto);
                 return index;
+        }
         printf( "New protocol registered:\n\tprotocol\t= %d\n\tphone\t= %d\n", proto->protocol, proto->phone );
         fibril_rwlock_write_unlock( & ip_globals.protos_lock );
+        printf("New protocol registered:\n\tprotocol\t= %d\n\tphone\t= %d\n", proto->protocol, proto->phone);
+        fibril_rwlock_write_unlock(&ip_globals.protos_lock);
         return EOK;
+}
 int ip_send_msg( int il_phone, device_id_t device_id, packet_t packet, services_t sender, services_t error ){
+int ip_send_msg(int il_phone, device_id_t device_id, packet_t packet, services_t sender, services_t error){
         ERROR_DECLARE;
         int                                     addrlen;
         ip_netif_ref            netif;
         ip_route_ref            route;
         struct sockaddr *               addr;
         struct sockaddr_in *    address_in;
+        int addrlen;
+        ip_netif_ref netif;
+        ip_route_ref route;
+        struct sockaddr * addr;
+        struct sockaddr_in * address_in;
 //      struct sockaddr_in6 *   address_in6;
         in_addr_t *                     dest;
         in_addr_t *                     src;
         int                                     phone;
+        in_addr_t * dest;
+        in_addr_t * src;
+        int phone;
         // addresses in the host byte order
         // should be the next hop address or the target destination address
         addrlen = packet_get_addr( packet, NULL, ( uint8_t ** ) & addr );
         if( addrlen < 0 ){
                 return ip_release_and_return( packet, addrlen );
+        }
         if(( size_t ) addrlen < sizeof( struct sockaddr )){
                 return ip_release_and_return( packet, EINVAL );
+        }
         switch( addr->sa_family ){
+        addrlen = packet_get_addr(packet, NULL, (uint8_t **) &addr);
+        if(addrlen < 0){
+                return ip_release_and_return(packet, addrlen);
+        }
+        if((size_t) addrlen < sizeof(struct sockaddr)){
+                return ip_release_and_return(packet, EINVAL);
+        }
+        switch(addr->sa_family){
                 case AF_INET:
                         if( addrlen != sizeof( struct sockaddr_in )){
                                 return ip_release_and_return( packet, EINVAL );
+                        }
                         address_in = ( struct sockaddr_in * ) addr;
                         dest = & address_in->sin_addr;
                         if( ! dest->s_addr ){
+                        if(addrlen != sizeof(struct sockaddr_in)){
+                                return ip_release_and_return(packet, EINVAL);
+                        }
+                        address_in = (struct sockaddr_in *) addr;
+                        dest = &address_in->sin_addr;
+                        if(! dest->s_addr){
                                 dest->s_addr = IPV4_LOCALHOST_ADDRESS;
+                        }
 …
                 // TODO IPv6
 /*              case AF_INET6:
+                        if( addrlen != sizeof( struct sockaddr_in6 )) return EINVAL;
+                        address_in6 = ( struct sockaddr_in6 * ) dest;
+                        if(addrlen != sizeof(struct sockaddr_in6)){
+                                return EINVAL;
+                        }
+                        address_in6 = (struct sockaddr_in6 *) dest;
                         address_in6.sin6_addr.s6_addr;
                         IPV6_LOCALHOST_ADDRESS;
 */              default:
                         return ip_release_and_return( packet, EAFNOSUPPORT );
+        }
         fibril_rwlock_read_lock( & ip_globals.netifs_lock );
+                        return ip_release_and_return(packet, EAFNOSUPPORT);
+        }
+        fibril_rwlock_read_lock(&ip_globals.netifs_lock);
         // device specified?
         if( device_id > 0 ){
                 netif = ip_netifs_find( & ip_globals.netifs, device_id );
                 route = ip_netif_find_route( netif, * dest );
                 if( netif && ( ! route ) && ( ip_globals.gateway.netif == netif )){
                         route = & ip_globals.gateway;
+        if(device_id > 0){
+                netif = ip_netifs_find(&ip_globals.netifs, device_id);
+                route = ip_netif_find_route(netif, * dest);
+                if(netif && (! route) && (ip_globals.gateway.netif == netif)){
+                        route = &ip_globals.gateway;
+                }
         }else{
                 route = ip_find_route( * dest );
+                route = ip_find_route(*dest);
                 netif = route ? route->netif : NULL;
+        }
         if( !( netif && route )){
                 fibril_rwlock_read_unlock( & ip_globals.netifs_lock );
                 phone = ip_prepare_icmp_and_get_phone( error, packet, NULL );
                 if( phone >= 0 ){
+        if(!(netif && route)){
+                fibril_rwlock_read_unlock(&ip_globals.netifs_lock);
+                phone = ip_prepare_icmp_and_get_phone(error, packet, NULL);
+                if(phone >= 0){
                         // unreachable ICMP if no routing
                         icmp_destination_unreachable_msg( phone, ICMP_NET_UNREACH, 0, packet );
+                        icmp_destination_unreachable_msg(phone, ICMP_NET_UNREACH, 0, packet);
+                }
                 return ENOENT;
+        }
         if( error ){
+        if(error){
                 // do not send for broadcast, anycast packets or network broadcast
                 if(( ! dest->s_addr )
                 || ( !( ~ dest->s_addr ))
                 || ( !( ~(( dest->s_addr & ( ~ route->netmask.s_addr )) | route->netmask.s_addr )))
                 || ( !( dest->s_addr & ( ~ route->netmask.s_addr )))){
                         return ip_release_and_return( packet, EINVAL );
+                }
+        }
         if( route->address.s_addr == dest->s_addr ){
+                if((! dest->s_addr)
+                        || (!(~ dest->s_addr))
+                        || (!(~((dest->s_addr &(~ route->netmask.s_addr)) | route->netmask.s_addr)))
+                        || (!(dest->s_addr &(~ route->netmask.s_addr)))){
+                        return ip_release_and_return(packet, EINVAL);
+                }
+        }
+        if(route->address.s_addr == dest->s_addr){
                 // find the loopback device to deliver
                 dest->s_addr = IPV4_LOCALHOST_ADDRESS;
                 route = ip_find_route( * dest );
+                route = ip_find_route(*dest);
                 netif = route ? route->netif : NULL;
                 if( !( netif && route )){
                         fibril_rwlock_read_unlock( & ip_globals.netifs_lock );
                         phone = ip_prepare_icmp_and_get_phone( error, packet, NULL );
                         if( phone >= 0 ){
+                if(!(netif && route)){
+                        fibril_rwlock_read_unlock(&ip_globals.netifs_lock);
+                        phone = ip_prepare_icmp_and_get_phone(error, packet, NULL);
+                        if(phone >= 0){
                                 // unreachable ICMP if no routing
                                 icmp_destination_unreachable_msg( phone, ICMP_HOST_UNREACH, 0, packet );
+                                icmp_destination_unreachable_msg(phone, ICMP_HOST_UNREACH, 0, packet);
+                        }
                         return ENOENT;
+                }
+        }
         src = ip_netif_address( netif );
         if( ! src ){
                 fibril_rwlock_read_unlock( & ip_globals.netifs_lock );
                 return ip_release_and_return( packet, ENOENT );
+        }
         ERROR_CODE = ip_send_route( packet, netif, route, src, * dest, error );
         fibril_rwlock_read_unlock( & ip_globals.netifs_lock );
+        src = ip_netif_address(netif);
+        if(! src){
+                fibril_rwlock_read_unlock(&ip_globals.netifs_lock);
+                return ip_release_and_return(packet, ENOENT);
+        }
+        ERROR_CODE = ip_send_route(packet, netif, route, src, * dest, error);
+        fibril_rwlock_read_unlock(&ip_globals.netifs_lock);
         return ERROR_CODE;
+}
 in_addr_t * ip_netif_address( ip_netif_ref netif ){
         ip_route_ref    route;
         route = ip_routes_get_index( & netif->routes, 0 );
         return route ? & route->address : NULL;
+}
 int ip_send_route( packet_t packet, ip_netif_ref netif, ip_route_ref route, in_addr_t * src, in_addr_t dest, services_t error ){
+in_addr_t * ip_netif_address(ip_netif_ref netif){
+        ip_route_ref route;
+        route = ip_routes_get_index(&netif->routes, 0);
+        return route ? &route->address : NULL;
+}
+int ip_send_route(packet_t packet, ip_netif_ref netif, ip_route_ref route, in_addr_t * src, in_addr_t dest, services_t error){
         ERROR_DECLARE;
         measured_string_t       destination;
         measured_string_ref     translation;
         char *                          data;
         int                                     phone;
+        measured_string_t destination;
+        measured_string_ref translation;
+        char * data;
+        int phone;
         // get destination hardware address
         if( netif->arp && ( route->address.s_addr != dest.s_addr )){
                 destination.value = route->gateway.s_addr ? ( char * ) & route->gateway.s_addr : ( char * ) & dest.s_addr;
                 destination.length = CONVERT_SIZE( dest.s_addr, char, 1 );
                 if( ERROR_OCCURRED( arp_translate_req( netif->arp->phone, netif->device_id, SERVICE_IP, & destination, & translation, & data ))){
 //                      sleep( 1 );
 //                      ERROR_PROPAGATE( arp_translate_req( netif->arp->phone, netif->device_id, SERVICE_IP, & destination, & translation, & data ));
                         pq_release( ip_globals.net_phone, packet_get_id( packet ));
+        if(netif->arp && (route->address.s_addr != dest.s_addr)){
+                destination.value = route->gateway.s_addr ? (char *) &route->gateway.s_addr : (char *) &dest.s_addr;
+                destination.length = CONVERT_SIZE(dest.s_addr, char, 1);
+                if(ERROR_OCCURRED(arp_translate_req(netif->arp->phone, netif->device_id, SERVICE_IP, &destination, &translation, &data))){
+//                      sleep(1);
+//                      ERROR_PROPAGATE(arp_translate_req(netif->arp->phone, netif->device_id, SERVICE_IP, &destination, &translation, &data));
+                        pq_release(ip_globals.net_phone, packet_get_id(packet));
                         return ERROR_CODE;
+                }
                 if( !( translation && translation->value )){
                         if( translation ){
                                 free( translation );
                                 free( data );
+                        }
                         phone = ip_prepare_icmp_and_get_phone( error, packet, NULL );
                         if( phone >= 0 ){
+                if(!(translation && translation->value)){
+                        if(translation){
+                                free(translation);
+                                free(data);
+                        }
+                        phone = ip_prepare_icmp_and_get_phone(error, packet, NULL);
+                        if(phone >= 0){
                                 // unreachable ICMP if no routing
                                 icmp_destination_unreachable_msg( phone, ICMP_HOST_UNREACH, 0, packet );
+                                icmp_destination_unreachable_msg(phone, ICMP_HOST_UNREACH, 0, packet);
+                        }
                         return EINVAL;
+                }
         }else translation = NULL;
         if( ERROR_OCCURRED( ip_prepare_packet( src, dest, packet, translation ))){
                 pq_release( ip_globals.net_phone, packet_get_id( packet ));
+        if(ERROR_OCCURRED(ip_prepare_packet(src, dest, packet, translation))){
+                pq_release(ip_globals.net_phone, packet_get_id(packet));
         }else{
                 packet = ip_split_packet( packet, netif->packet_dimension.prefix, netif->packet_dimension.content, netif->packet_dimension.suffix, netif->packet_dimension.addr_len, error );
                 if( packet ){
                         nil_send_msg( netif->phone, netif->device_id, packet, SERVICE_IP );
+                }
+        }
         if( translation ){
                 free( translation );
                 free( data );
+                packet = ip_split_packet(packet, netif->packet_dimension.prefix, netif->packet_dimension.content, netif->packet_dimension.suffix, netif->packet_dimension.addr_len, error);
+                if(packet){
+                        nil_send_msg(netif->phone, netif->device_id, packet, SERVICE_IP);
+                }
+        }
+        if(translation){
+                free(translation);
+                free(data);
+        }
         return ERROR_CODE;
+}
 int ip_prepare_packet( in_addr_t * source, in_addr_t dest, packet_t packet, measured_string_ref destination ){
+int ip_prepare_packet(in_addr_t * source, in_addr_t dest, packet_t packet, measured_string_ref destination){
         ERROR_DECLARE;
+        size_t                          length;
+        ip_header_ref           header;
+        ip_header_ref           last_header;
+        ip_header_ref           middle_header;
+        packet_t                        next;
+        length = packet_get_data_length( packet );
+        if(( length < sizeof( ip_header_t )) || ( length > IP_MAX_CONTENT )) return EINVAL;
+        header = ( ip_header_ref ) packet_get_data( packet );
+        if( destination ){
+                ERROR_PROPAGATE( packet_set_addr( packet, NULL, ( uint8_t * ) destination->value, CONVERT_SIZE( char, uint8_t, destination->length )));
+        size_t length;
+        ip_header_ref header;
+        ip_header_ref last_header;
+        ip_header_ref middle_header;
+        packet_t next;
+        length = packet_get_data_length(packet);
+        if((length < sizeof(ip_header_t)) || (length > IP_MAX_CONTENT)){
+                return EINVAL;
+        }
+        header = (ip_header_ref) packet_get_data(packet);
+        if(destination){
+                ERROR_PROPAGATE(packet_set_addr(packet, NULL, (uint8_t *) destination->value, CONVERT_SIZE(char, uint8_t, destination->length)));
         }else{
                 ERROR_PROPAGATE( packet_set_addr( packet, NULL, NULL, 0 ));
+                ERROR_PROPAGATE(packet_set_addr(packet, NULL, NULL, 0));
+        }
         header->version = IPV4;
 …
         header->fragment_offset_low = 0;
         header->header_checksum = 0;
+        if( source ) header->source_address = source->s_addr;
+        if(source){
+                header->source_address = source->s_addr;
+        }
         header->destination_address = dest.s_addr;
         fibril_rwlock_write_lock( & ip_globals.lock );
+        fibril_rwlock_write_lock(&ip_globals.lock);
         ++ ip_globals.packet_counter;
+        header->identification = htons( ip_globals.packet_counter );
+        fibril_rwlock_write_unlock( & ip_globals.lock );
+//      length = packet_get_data_length( packet );
+        if( pq_next( packet )){
+                last_header = ( ip_header_ref ) malloc( IP_HEADER_LENGTH( header ));
+                if( ! last_header ) return ENOMEM;
+                ip_create_last_header( last_header, header );
+                next = pq_next( packet );
+                while( pq_next( next )){
+                        middle_header = ( ip_header_ref ) packet_prefix( next, IP_HEADER_LENGTH( last_header ));
+                        if( ! middle_header ) return ENOMEM;
+                        memcpy( middle_header, last_header, IP_HEADER_LENGTH( last_header ));
+        header->identification = htons(ip_globals.packet_counter);
+        fibril_rwlock_write_unlock(&ip_globals.lock);
+//      length = packet_get_data_length(packet);
+        if(pq_next(packet)){
+                last_header = (ip_header_ref) malloc(IP_HEADER_LENGTH(header));
+                if(! last_header){
+                        return ENOMEM;
+                }
+                ip_create_last_header(last_header, header);
+                next = pq_next(packet);
+                while(pq_next(next)){
+                        middle_header = (ip_header_ref) packet_prefix(next, IP_HEADER_LENGTH(last_header));
+                        if(! middle_header){
+                                return ENOMEM;
+                        }
+                        memcpy(middle_header, last_header, IP_HEADER_LENGTH(last_header));
                         header->flags |= IPFLAG_MORE_FRAGMENTS;
+                        middle_header->total_length = htons( packet_get_data_length( next ));
+                        middle_header->fragment_offset_high = IP_COMPUTE_FRAGMENT_OFFSET_HIGH( length );
+                        middle_header->fragment_offset_low = IP_COMPUTE_FRAGMENT_OFFSET_LOW( length );
+                        middle_header->header_checksum = IP_HEADER_CHECKSUM( middle_header );
+                        if( destination ){
+                                ERROR_PROPAGATE( packet_set_addr( next, NULL, ( uint8_t * ) destination->value, CONVERT_SIZE( char, uint8_t, destination->length )));
+                        }
+                        length += packet_get_data_length( next );
+                        next = pq_next( next );
+                }
+                middle_header = ( ip_header_ref ) packet_prefix( next, IP_HEADER_LENGTH( last_header ));
+                if( ! middle_header ) return ENOMEM;
+                memcpy( middle_header, last_header, IP_HEADER_LENGTH( last_header ));
+                middle_header->total_length = htons( packet_get_data_length( next ));
+                middle_header->fragment_offset_high = IP_COMPUTE_FRAGMENT_OFFSET_HIGH( length );
+                middle_header->fragment_offset_low = IP_COMPUTE_FRAGMENT_OFFSET_LOW( length );
+                middle_header->header_checksum = IP_HEADER_CHECKSUM( middle_header );
+                if( destination ){
+                        ERROR_PROPAGATE( packet_set_addr( next, NULL, ( uint8_t * ) destination->value, CONVERT_SIZE( char, uint8_t, destination->length )));
+                }
+                length += packet_get_data_length( next );
+                free( last_header );
+                        middle_header->total_length = htons(packet_get_data_length(next));
+                        middle_header->fragment_offset_high = IP_COMPUTE_FRAGMENT_OFFSET_HIGH(length);
+                        middle_header->fragment_offset_low = IP_COMPUTE_FRAGMENT_OFFSET_LOW(length);
+                        middle_header->header_checksum = IP_HEADER_CHECKSUM(middle_header);
+                        if(destination){
+                                ERROR_PROPAGATE(packet_set_addr(next, NULL, (uint8_t *) destination->value, CONVERT_SIZE(char, uint8_t, destination->length)));
+                        }
+                        length += packet_get_data_length(next);
+                        next = pq_next(next);
+                }
+                middle_header = (ip_header_ref) packet_prefix(next, IP_HEADER_LENGTH(last_header));
+                if(! middle_header){
+                        return ENOMEM;
+                }
+                memcpy(middle_header, last_header, IP_HEADER_LENGTH(last_header));
+                middle_header->total_length = htons(packet_get_data_length(next));
+                middle_header->fragment_offset_high = IP_COMPUTE_FRAGMENT_OFFSET_HIGH(length);
+                middle_header->fragment_offset_low = IP_COMPUTE_FRAGMENT_OFFSET_LOW(length);
+                middle_header->header_checksum = IP_HEADER_CHECKSUM(middle_header);
+                if(destination){
+                        ERROR_PROPAGATE(packet_set_addr(next, NULL, (uint8_t *) destination->value, CONVERT_SIZE(char, uint8_t, destination->length)));
+                }
+                length += packet_get_data_length(next);
+                free(last_header);
                 header->flags |= IPFLAG_MORE_FRAGMENTS;
+        }
         header->total_length = htons( length );
+        header->total_length = htons(length);
         // unnecessary for all protocols
         header->header_checksum = IP_HEADER_CHECKSUM( header );
+        header->header_checksum = IP_HEADER_CHECKSUM(header);
         return EOK;
+}
 int ip_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count ){
+int ip_message(ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count){
         ERROR_DECLARE;
         packet_t                                packet;
         struct sockaddr *               addr;
         size_t                                  addrlen;
         ip_pseudo_header_ref    header;
         size_t                                  headerlen;
         * answer_count = 0;
         switch( IPC_GET_METHOD( * call )){
+        packet_t packet;
+        struct sockaddr * addr;
+        size_t addrlen;
+        ip_pseudo_header_ref header;
+        size_t headerlen;
+        *answer_count = 0;
+        switch(IPC_GET_METHOD(*call)){
                 case IPC_M_PHONE_HUNGUP:
                         return EOK;
                 case NET_IL_DEVICE:
                         return ip_device_req( 0, IPC_GET_DEVICE( call ), IPC_GET_SERVICE( call ));
+                        return ip_device_req(0, IPC_GET_DEVICE(call), IPC_GET_SERVICE(call));
                 case IPC_M_CONNECT_TO_ME:
                         return ip_register( IL_GET_PROTO( call ), IL_GET_SERVICE( call ), IPC_GET_PHONE( call ), NULL );
+                        return ip_register(IL_GET_PROTO(call), IL_GET_SERVICE(call), IPC_GET_PHONE(call), NULL);
                 case NET_IL_SEND:
                         ERROR_PROPAGATE( packet_translate( ip_globals.net_phone, & packet, IPC_GET_PACKET( call )));
                         return ip_send_msg( 0, IPC_GET_DEVICE( call ), packet, 0, IPC_GET_ERROR( call ));
+                        ERROR_PROPAGATE(packet_translate(ip_globals.net_phone, &packet, IPC_GET_PACKET(call)));
+                        return ip_send_msg(0, IPC_GET_DEVICE(call), packet, 0, IPC_GET_ERROR(call));
                 case NET_IL_DEVICE_STATE:
                         return ip_device_state_message( IPC_GET_DEVICE( call ), IPC_GET_STATE( call ));
+                        return ip_device_state_message(IPC_GET_DEVICE(call), IPC_GET_STATE(call));
                 case NET_IL_RECEIVED:
                         ERROR_PROPAGATE( packet_translate( ip_globals.net_phone, & packet, IPC_GET_PACKET( call )));
                         return ip_receive_message( IPC_GET_DEVICE( call ), packet );
+                        ERROR_PROPAGATE(packet_translate(ip_globals.net_phone, &packet, IPC_GET_PACKET(call)));
+                        return ip_receive_message(IPC_GET_DEVICE(call), packet);
                 case NET_IP_RECEIVED_ERROR:
                         ERROR_PROPAGATE( packet_translate( ip_globals.net_phone, & packet, IPC_GET_PACKET( call )));
                         return ip_received_error_msg( 0, IPC_GET_DEVICE( call ), packet, IPC_GET_TARGET( call ), IPC_GET_ERROR( call ));
+                        ERROR_PROPAGATE(packet_translate(ip_globals.net_phone, &packet, IPC_GET_PACKET(call)));
+                        return ip_received_error_msg(0, IPC_GET_DEVICE(call), packet, IPC_GET_TARGET(call), IPC_GET_ERROR(call));
                 case NET_IP_ADD_ROUTE:
                         return ip_add_route_req( 0, IPC_GET_DEVICE( call ), IP_GET_ADDRESS( call ), IP_GET_NETMASK( call ), IP_GET_GATEWAY( call ));
+                        return ip_add_route_req(0, IPC_GET_DEVICE(call), IP_GET_ADDRESS(call), IP_GET_NETMASK(call), IP_GET_GATEWAY(call));
                 case NET_IP_SET_GATEWAY:
                         return ip_set_gateway_req( 0, IPC_GET_DEVICE( call ), IP_GET_GATEWAY( call ));
+                        return ip_set_gateway_req(0, IPC_GET_DEVICE(call), IP_GET_GATEWAY(call));
                 case NET_IP_GET_ROUTE:
                         ERROR_PROPAGATE( data_receive(( void ** ) & addr, & addrlen ));
                         ERROR_PROPAGATE( ip_get_route_req( 0, IP_GET_PROTOCOL( call ), addr, ( socklen_t ) addrlen, IPC_SET_DEVICE( answer ), & header, & headerlen ));
                         * IP_SET_HEADERLEN( answer ) = headerlen;
                         * answer_count = 2;
                         if( ! ERROR_OCCURRED( data_reply( & headerlen, sizeof( headerlen )))){
                                 ERROR_CODE = data_reply( header, headerlen );
+                        }
                         free( header );
+                        ERROR_PROPAGATE(data_receive((void **) &addr, &addrlen));
+                        ERROR_PROPAGATE(ip_get_route_req(0, IP_GET_PROTOCOL(call), addr, (socklen_t) addrlen, IPC_SET_DEVICE(answer), &header, &headerlen));
+                        *IP_SET_HEADERLEN(answer) = headerlen;
+                        *answer_count = 2;
+                        if(! ERROR_OCCURRED(data_reply(&headerlen, sizeof(headerlen)))){
+                                ERROR_CODE = data_reply(header, headerlen);
+                        }
+                        free(header);
                         return ERROR_CODE;
                 case NET_IL_PACKET_SPACE:
                         ERROR_PROPAGATE( ip_packet_size_message( IPC_GET_DEVICE( call ), IPC_SET_ADDR( answer ), IPC_SET_PREFIX( answer ), IPC_SET_CONTENT( answer ), IPC_SET_SUFFIX( answer )));
                         * answer_count = 3;
+                        ERROR_PROPAGATE(ip_packet_size_message(IPC_GET_DEVICE(call), IPC_SET_ADDR(answer), IPC_SET_PREFIX(answer), IPC_SET_CONTENT(answer), IPC_SET_SUFFIX(answer)));
+                        *answer_count = 3;
                         return EOK;
                 case NET_IL_MTU_CHANGED:
                         return ip_mtu_changed_message( IPC_GET_DEVICE( call ), IPC_GET_MTU( call ));
+                        return ip_mtu_changed_message(IPC_GET_DEVICE(call), IPC_GET_MTU(call));
+        }
         return ENOTSUP;
+}
+int ip_packet_size_req( int ip_phone, device_id_t device_id, packet_dimension_ref packet_dimension ){
+        if( ! packet_dimension ) return EBADMEM;
+        return ip_packet_size_message( device_id, & packet_dimension->addr_len, & packet_dimension->prefix, & packet_dimension->content, & packet_dimension->suffix );
+}
+int ip_packet_size_message( device_id_t device_id, size_t * addr_len, size_t * prefix, size_t * content, size_t * suffix ){
+        ip_netif_ref    netif;
+        int                             index;
+        if( !( addr_len && prefix && content && suffix )) return EBADMEM;
+        * content = IP_MAX_CONTENT - IP_PREFIX;
+        fibril_rwlock_read_lock( & ip_globals.netifs_lock );
+        if( device_id < 0 ){
+                * addr_len = IP_ADDR;
+                * prefix = 0;
+                * suffix = 0;
+                for( index = ip_netifs_count( & ip_globals.netifs ) - 1; index >= 0; -- index ){
+                        netif = ip_netifs_get_index( & ip_globals.netifs, index );
+                        if( netif ){
+                                if( netif->packet_dimension.addr_len > * addr_len ) * addr_len = netif->packet_dimension.addr_len;
+                                if( netif->packet_dimension.prefix > * prefix ) * prefix = netif->packet_dimension.prefix;
+                                if( netif->packet_dimension.suffix > * suffix ) * suffix = netif->packet_dimension.suffix;
+                        }
+                }
+                * prefix = * prefix + IP_PREFIX;
+                * suffix = * suffix + IP_SUFFIX;
+int ip_packet_size_req(int ip_phone, device_id_t device_id, packet_dimension_ref packet_dimension){
+        if(! packet_dimension){
+                return EBADMEM;
+        }
+        return ip_packet_size_message(device_id, &packet_dimension->addr_len, &packet_dimension->prefix, &packet_dimension->content, &packet_dimension->suffix);
+}
+int ip_packet_size_message(device_id_t device_id, size_t * addr_len, size_t * prefix, size_t * content, size_t * suffix){
+        ip_netif_ref netif;
+        int index;
+        if(!(addr_len && prefix && content && suffix)){
+                return EBADMEM;
+        }
+        *content = IP_MAX_CONTENT - IP_PREFIX;
+        fibril_rwlock_read_lock(&ip_globals.netifs_lock);
+        if(device_id < 0){
+                *addr_len = IP_ADDR;
+                *prefix = 0;
+                *suffix = 0;
+                for(index = ip_netifs_count(&ip_globals.netifs) - 1; index >= 0; -- index){
+                        netif = ip_netifs_get_index(&ip_globals.netifs, index);
+                        if(netif){
+                                if(netif->packet_dimension.addr_len > * addr_len){
+                                        *addr_len = netif->packet_dimension.addr_len;
+                                }
+                                if(netif->packet_dimension.prefix > * prefix){
+                                        *prefix = netif->packet_dimension.prefix;
+                                }
+                                if(netif->packet_dimension.suffix > * suffix){
+                                        *suffix = netif->packet_dimension.suffix;
+                                }
+                        }
+                }
+                *prefix = * prefix + IP_PREFIX;
+                *suffix = * suffix + IP_SUFFIX;
         }else{
                 netif = ip_netifs_find( & ip_globals.netifs, device_id );
                 if( ! netif ){
                         fibril_rwlock_read_unlock( & ip_globals.netifs_lock );
+                netif = ip_netifs_find(&ip_globals.netifs, device_id);
+                if(! netif){
+                        fibril_rwlock_read_unlock(&ip_globals.netifs_lock);
                         return ENOENT;
+                }
                 * addr_len = ( netif->packet_dimension.addr_len > IP_ADDR ) ? netif->packet_dimension.addr_len : IP_ADDR;
                 * prefix = netif->packet_dimension.prefix + IP_PREFIX;
                 * suffix = netif->packet_dimension.suffix + IP_SUFFIX;
+        }
         fibril_rwlock_read_unlock( & ip_globals.netifs_lock );
+                *addr_len = (netif->packet_dimension.addr_len > IP_ADDR) ? netif->packet_dimension.addr_len : IP_ADDR;
+                *prefix = netif->packet_dimension.prefix + IP_PREFIX;
+                *suffix = netif->packet_dimension.suffix + IP_SUFFIX;
+        }
+        fibril_rwlock_read_unlock(&ip_globals.netifs_lock);
         return EOK;
+}
 int ip_add_route_req( int ip_phone, device_id_t device_id, in_addr_t address, in_addr_t netmask, in_addr_t gateway ){
         ip_route_ref    route;
         ip_netif_ref    netif;
         int                             index;
         fibril_rwlock_write_lock( & ip_globals.netifs_lock );
         netif = ip_netifs_find( & ip_globals.netifs, device_id );
         if( ! netif ){
                 fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+int ip_add_route_req(int ip_phone, device_id_t device_id, in_addr_t address, in_addr_t netmask, in_addr_t gateway){
+        ip_route_ref route;
+        ip_netif_ref netif;
+        int index;
+        fibril_rwlock_write_lock(&ip_globals.netifs_lock);
+        netif = ip_netifs_find(&ip_globals.netifs, device_id);
+        if(! netif){
+                fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
                 return ENOENT;
+        }
         route = ( ip_route_ref ) malloc( sizeof( ip_route_t ));
         if( ! route ){
                 fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+        route = (ip_route_ref) malloc(sizeof(ip_route_t));
+        if(! route){
+                fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
                 return ENOMEM;
+        }
 …
         route->gateway.s_addr = gateway.s_addr;
         route->netif = netif;
+        index = ip_routes_add( & netif->routes, route );
+        if( index < 0 ) free( route );
+        fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+        index = ip_routes_add(&netif->routes, route);
+        if(index < 0){
+                free(route);
+        }
+        fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
         return index;
+}
 ip_route_ref ip_find_route( in_addr_t destination ){
         int                             index;
         ip_route_ref    route;
         ip_netif_ref    netif;
+ip_route_ref ip_find_route(in_addr_t destination){
+        int index;
+        ip_route_ref route;
+        ip_netif_ref netif;
         // start with the last netif - the newest one
+        index = ip_netifs_count( & ip_globals.netifs ) - 1;
+        while( index >= 0 ){
+                netif = ip_netifs_get_index( & ip_globals.netifs, index );
+                if( netif && ( netif->state == NETIF_ACTIVE )){
+                        route = ip_netif_find_route( netif, destination );
+                        if( route ) return route;
+        index = ip_netifs_count(&ip_globals.netifs) - 1;
+        while(index >= 0){
+                netif = ip_netifs_get_index(&ip_globals.netifs, index);
+                if(netif && (netif->state == NETIF_ACTIVE)){
+                        route = ip_netif_find_route(netif, destination);
+                        if(route){
+                                return route;
+                        }
+                }
                 -- index;
+        }
         return & ip_globals.gateway;
+}
 ip_route_ref ip_netif_find_route( ip_netif_ref netif, in_addr_t destination ){
         int                             index;
         ip_route_ref    route;
         if( netif ){
+        return &ip_globals.gateway;
+}
+ip_route_ref ip_netif_find_route(ip_netif_ref netif, in_addr_t destination){
+        int index;
+        ip_route_ref route;
+        if(netif){
                 // start with the first one - the direct route
                 for( index = 0; index < ip_routes_count( & netif->routes ); ++ index ){
                         route = ip_routes_get_index( & netif->routes, index );
                         if( route && (( route->address.s_addr & route->netmask.s_addr ) == ( destination.s_addr & route->netmask.s_addr ))){
+                for(index = 0; index < ip_routes_count(&netif->routes); ++ index){
+                        route = ip_routes_get_index(&netif->routes, index);
+                        if(route && ((route->address.s_addr &route->netmask.s_addr) == (destination.s_addr &route->netmask.s_addr))){
                                 return route;
+                        }
 …
+}
 int ip_set_gateway_req( int ip_phone, device_id_t device_id, in_addr_t gateway ){
         ip_netif_ref    netif;
         fibril_rwlock_write_lock( & ip_globals.netifs_lock );
         netif = ip_netifs_find( & ip_globals.netifs, device_id );
         if( ! netif ){
                 fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+int ip_set_gateway_req(int ip_phone, device_id_t device_id, in_addr_t gateway){
+        ip_netif_ref netif;
+        fibril_rwlock_write_lock(&ip_globals.netifs_lock);
+        netif = ip_netifs_find(&ip_globals.netifs, device_id);
+        if(! netif){
+                fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
                 return ENOENT;
+        }
 …
         ip_globals.gateway.gateway.s_addr = gateway.s_addr;
         ip_globals.gateway.netif = netif;
         fibril_rwlock_write_unlock( & ip_globals.netifs_lock );
+        fibril_rwlock_write_unlock(&ip_globals.netifs_lock);
         return EOK;
+}
 packet_t ip_split_packet( packet_t packet, size_t prefix, size_t content, size_t suffix, socklen_t addr_len, services_t error ){
         size_t                  length;
         packet_t                next;
         packet_t                new_packet;
         int                             result;
         int                             phone;
+packet_t ip_split_packet(packet_t packet, size_t prefix, size_t content, size_t suffix, socklen_t addr_len, services_t error){
+        size_t length;
+        packet_t next;
+        packet_t new_packet;
+        int result;
+        int phone;
         next = packet;
         // check all packets
         while( next ){
                 length = packet_get_data_length( next );
+        while(next){
+                length = packet_get_data_length(next);
                 // too long?
                 if( length > content ){
                         result = ip_fragment_packet( next, content, prefix, suffix, addr_len );
                         if( result != EOK ){
                                 new_packet = pq_detach( next );
                                 if( next == packet ){
+                if(length > content){
+                        result = ip_fragment_packet(next, content, prefix, suffix, addr_len);
+                        if(result != EOK){
+                                new_packet = pq_detach(next);
+                                if(next == packet){
                                         // the new first packet of the queue
                                         packet = new_packet;
+                                }
                                 // fragmentation needed?
                                 if( result == EPERM ){
                                         phone = ip_prepare_icmp_and_get_phone( error, next, NULL );
                                         if( phone >= 0 ){
+                                if(result == EPERM){
+                                        phone = ip_prepare_icmp_and_get_phone(error, next, NULL);
+                                        if(phone >= 0){
                                                 // fragmentation necessary ICMP
                                                 icmp_destination_unreachable_msg( phone, ICMP_FRAG_NEEDED, content, next );
+                                                icmp_destination_unreachable_msg(phone, ICMP_FRAG_NEEDED, content, next);
+                                        }
                                 }else{
                                         pq_release( ip_globals.net_phone, packet_get_id( next ));
+                                        pq_release(ip_globals.net_phone, packet_get_id(next));
+                                }
                                 next = new_packet;
 …
+                        }
+                }
                 next = pq_next( next );
+                next = pq_next(next);
+        }
         return packet;
+}
 int ip_fragment_packet( packet_t packet, size_t length, size_t prefix, size_t suffix, socklen_t addr_len ){
+int ip_fragment_packet(packet_t packet, size_t length, size_t prefix, size_t suffix, socklen_t addr_len){
         ERROR_DECLARE;
+        packet_t                new_packet;
+        ip_header_ref   header;
+        ip_header_ref   middle_header;
+        ip_header_ref   last_header;
+        struct sockaddr *               src;
+        struct sockaddr *               dest;
+        socklen_t               addrlen;
+        int                             result;
+        result = packet_get_addr( packet, ( uint8_t ** ) & src, ( uint8_t ** ) & dest );
+        if( result <= 0 ) return EINVAL;
+        addrlen = ( socklen_t ) result;
+        if( packet_get_data_length( packet ) <= sizeof( ip_header_t )) return ENOMEM;
+        packet_t new_packet;
+        ip_header_ref header;
+        ip_header_ref middle_header;
+        ip_header_ref last_header;
+        struct sockaddr * src;
+        struct sockaddr * dest;
+        socklen_t addrlen;
+        int result;
+        result = packet_get_addr(packet, (uint8_t **) &src, (uint8_t **) &dest);
+        if(result <= 0){
+                return EINVAL;
+        }
+        addrlen = (socklen_t) result;
+        if(packet_get_data_length(packet) <= sizeof(ip_header_t)){
+                return ENOMEM;
+        }
         // get header
+        header = ( ip_header_ref ) packet_get_data( packet );
+        if( ! header ) return EINVAL;
+        header = (ip_header_ref) packet_get_data(packet);
+        if(! header){
+                return EINVAL;
+        }
         // fragmentation forbidden?
         if( header->flags & IPFLAG_DONT_FRAGMENT ){
+        if(header->flags &IPFLAG_DONT_FRAGMENT){
                 return EPERM;
+        }
         // create the last fragment
+        new_packet = packet_get_4( ip_globals.net_phone, prefix, length, suffix, (( addrlen > addr_len ) ? addrlen : addr_len ));
+        if( ! new_packet ) return ENOMEM;
+        new_packet = packet_get_4(ip_globals.net_phone, prefix, length, suffix, ((addrlen > addr_len) ? addrlen : addr_len));
+        if(! new_packet){
+                return ENOMEM;
+        }
         // allocate as much as originally
         last_header = ( ip_header_ref ) packet_suffix( new_packet, IP_HEADER_LENGTH( header ));
         if( ! last_header ){
                 return ip_release_and_return( packet, ENOMEM );
+        }
         ip_create_last_header( last_header, header );
+        last_header = (ip_header_ref) packet_suffix(new_packet, IP_HEADER_LENGTH(header));
+        if(! last_header){
+                return ip_release_and_return(packet, ENOMEM);
+        }
+        ip_create_last_header(last_header, header);
         // trim the unused space
         if( ERROR_OCCURRED( packet_trim( new_packet, 0, IP_HEADER_LENGTH( header ) - IP_HEADER_LENGTH( last_header )))){
                 return ip_release_and_return( packet, ERROR_CODE );
+        if(ERROR_OCCURRED(packet_trim(new_packet, 0, IP_HEADER_LENGTH(header) - IP_HEADER_LENGTH(last_header)))){
+                return ip_release_and_return(packet, ERROR_CODE);
+        }
         // biggest multiple of 8 lower than content
         // TODO even fragmentation?
         length = length & ( ~ 0x7 );// ( content / 8 ) * 8
         if( ERROR_OCCURRED( ip_fragment_packet_data( packet, new_packet, header, last_header, (( IP_HEADER_DATA_LENGTH( header ) - (( length - IP_HEADER_LENGTH( header )) & ( ~ 0x7 ))) % (( length - IP_HEADER_LENGTH( last_header )) & ( ~ 0x7 ))), src, dest, addrlen ))){
                 return ip_release_and_return( packet, ERROR_CODE );
+        length = length &(~ 0x7);// (content / 8) * 8
+        if(ERROR_OCCURRED(ip_fragment_packet_data(packet, new_packet, header, last_header, ((IP_HEADER_DATA_LENGTH(header) - ((length - IP_HEADER_LENGTH(header)) &(~ 0x7))) % ((length - IP_HEADER_LENGTH(last_header)) &(~ 0x7))), src, dest, addrlen))){
+                return ip_release_and_return(packet, ERROR_CODE);
+        }
         // mark the first as fragmented
         header->flags |= IPFLAG_MORE_FRAGMENTS;
         // create middle framgents
+        while( IP_TOTAL_LENGTH( header ) > length ){
+                new_packet = packet_get_4( ip_globals.net_phone, prefix, length, suffix, (( addrlen >= addr_len ) ? addrlen : addr_len ));
+                if( ! new_packet ) return ENOMEM;
+                middle_header = ip_create_middle_header( new_packet, last_header );
+                if( ! middle_header ){
+                        return ip_release_and_return( packet, ENOMEM );
+                }
+                if( ERROR_OCCURRED( ip_fragment_packet_data( packet, new_packet, header, middle_header, ( length - IP_HEADER_LENGTH( middle_header )) & ( ~ 0x7 ), src, dest, addrlen ))){
+                        return ip_release_and_return( packet, ERROR_CODE );
+        while(IP_TOTAL_LENGTH(header) > length){
+                new_packet = packet_get_4(ip_globals.net_phone, prefix, length, suffix, ((addrlen >= addr_len) ? addrlen : addr_len));
+                if(! new_packet){
+                        return ENOMEM;
+                }
+                middle_header = ip_create_middle_header(new_packet, last_header);
+                if(! middle_header){
+                        return ip_release_and_return(packet, ENOMEM);
+                }
+                if(ERROR_OCCURRED(ip_fragment_packet_data(packet, new_packet, header, middle_header, (length - IP_HEADER_LENGTH(middle_header)) &(~ 0x7), src, dest, addrlen))){
+                        return ip_release_and_return(packet, ERROR_CODE);
+                }
+        }
         // finish the first fragment
         header->header_checksum = IP_HEADER_CHECKSUM( header );
+        header->header_checksum = IP_HEADER_CHECKSUM(header);
         return EOK;
+}
 int ip_fragment_packet_data( packet_t packet, packet_t new_packet, ip_header_ref header, ip_header_ref new_header, size_t length, const struct sockaddr * src, const struct sockaddr * dest, socklen_t addrlen ){
+int ip_fragment_packet_data(packet_t packet, packet_t new_packet, ip_header_ref header, ip_header_ref new_header, size_t length, const struct sockaddr * src, const struct sockaddr * dest, socklen_t addrlen){
         ERROR_DECLARE;
+        void *                  data;
+        size_t                  offset;
+        data = packet_suffix( new_packet, length );
+        if( ! data ) return ENOMEM;
+        memcpy( data, (( void * ) header ) + IP_TOTAL_LENGTH( header ) - length, length );
+        ERROR_PROPAGATE( packet_trim( packet, 0, length ));
+        header->total_length = htons( IP_TOTAL_LENGTH( header ) - length );
+        new_header->total_length = htons( IP_HEADER_LENGTH( new_header ) + length );
+        offset = IP_FRAGMENT_OFFSET( header ) + IP_HEADER_DATA_LENGTH( header );
+        new_header->fragment_offset_high = IP_COMPUTE_FRAGMENT_OFFSET_HIGH( offset );
+        new_header->fragment_offset_low = IP_COMPUTE_FRAGMENT_OFFSET_LOW( offset );
+        new_header->header_checksum = IP_HEADER_CHECKSUM( new_header );
+        ERROR_PROPAGATE( packet_set_addr( new_packet, ( const uint8_t * ) src, ( const uint8_t * ) dest, addrlen ));
+        return pq_insert_after( packet, new_packet );
+}
+ip_header_ref ip_create_middle_header( packet_t packet, ip_header_ref last ){
+        ip_header_ref   middle;
+        middle = ( ip_header_ref ) packet_suffix( packet, IP_HEADER_LENGTH( last ));
+        if( ! middle ) return NULL;
+        memcpy( middle, last, IP_HEADER_LENGTH( last ));
+        void * data;
+        size_t offset;
+        data = packet_suffix(new_packet, length);
+        if(! data){
+                return ENOMEM;
+        }
+        memcpy(data, ((void *) header) + IP_TOTAL_LENGTH(header) - length, length);
+        ERROR_PROPAGATE(packet_trim(packet, 0, length));
+        header->total_length = htons(IP_TOTAL_LENGTH(header) - length);
+        new_header->total_length = htons(IP_HEADER_LENGTH(new_header) + length);
+        offset = IP_FRAGMENT_OFFSET(header) + IP_HEADER_DATA_LENGTH(header);
+        new_header->fragment_offset_high = IP_COMPUTE_FRAGMENT_OFFSET_HIGH(offset);
+        new_header->fragment_offset_low = IP_COMPUTE_FRAGMENT_OFFSET_LOW(offset);
+        new_header->header_checksum = IP_HEADER_CHECKSUM(new_header);
+        ERROR_PROPAGATE(packet_set_addr(new_packet, (const uint8_t *) src, (const uint8_t *) dest, addrlen));
+        return pq_insert_after(packet, new_packet);
+}
+ip_header_ref ip_create_middle_header(packet_t packet, ip_header_ref last){
+        ip_header_ref middle;
+        middle = (ip_header_ref) packet_suffix(packet, IP_HEADER_LENGTH(last));
+        if(! middle){
+                return NULL;
+        }
+        memcpy(middle, last, IP_HEADER_LENGTH(last));
         middle->flags |= IPFLAG_MORE_FRAGMENTS;
         return middle;
+}
 void ip_create_last_header( ip_header_ref last, ip_header_ref first ){
         ip_option_ref   option;
         size_t                  next;
         size_t                  length;
+void ip_create_last_header(ip_header_ref last, ip_header_ref first){
+        ip_option_ref option;
+        size_t next;
+        size_t length;
         // copy first itself
         memcpy( last, first, sizeof( ip_header_t ));
         length = sizeof( ip_header_t );
         next = sizeof( ip_header_t );
+        memcpy(last, first, sizeof(ip_header_t));
+        length = sizeof(ip_header_t);
+        next = sizeof(ip_header_t);
         // process all ip options
         while( next < first->header_length ){
                 option = ( ip_option_ref ) ((( uint8_t * ) first ) + next );
+        while(next < first->header_length){
+                option = (ip_option_ref) (((uint8_t *) first) + next);
                 // skip end or noop
                 if(( option->type == IPOPT_END ) || ( option->type == IPOPT_NOOP )){
+                if((option->type == IPOPT_END) || (option->type == IPOPT_NOOP)){
                         ++ next;
                 }else{
                         // copy if said so or skip
                         if( IPOPT_COPIED( option->type )){
                                 memcpy((( uint8_t * ) last ) + length, (( uint8_t * ) first ) + next, option->length );
+                        if(IPOPT_COPIED(option->type)){
+                                memcpy(((uint8_t *) last) + length, ((uint8_t *) first) + next, option->length);
                                 length += option->length;
+                        }
 …
+        }
         // align 4 byte boundary
         if( length % 4 ){
                 bzero((( uint8_t * ) last ) + length, 4 - ( length % 4 ));
+        if(length % 4){
+                bzero(((uint8_t *) last) + length, 4 - (length % 4));
                 last->header_length = length / 4 + 1;
         }else{
 …
+}
 int ip_receive_message( device_id_t device_id, packet_t packet ){
         packet_t                next;
+int ip_receive_message(device_id_t device_id, packet_t packet){
+        packet_t next;
         do{
                 next = pq_detach( packet );
                 ip_process_packet( device_id, packet );
+                next = pq_detach(packet);
+                ip_process_packet(device_id, packet);
                 packet = next;
         }while( packet );
+        }while(packet);
         return EOK;
+}
 int ip_process_packet( device_id_t device_id, packet_t packet ){
+int ip_process_packet(device_id_t device_id, packet_t packet){
         ERROR_DECLARE;
         ip_header_ref   header;
         in_addr_t               dest;
         ip_route_ref    route;
         int                             phone;
         struct sockaddr *       addr;
         struct sockaddr_in      addr_in;
+        ip_header_ref header;
+        in_addr_t dest;
+        ip_route_ref route;
+        int phone;
+        struct sockaddr * addr;
+        struct sockaddr_in addr_in;
 //      struct sockaddr_in      addr_in6;
         socklen_t               addrlen;
         header = ( ip_header_ref ) packet_get_data( packet );
         if( ! header ){
                 return ip_release_and_return( packet, ENOMEM );
+        socklen_t addrlen;
+        header = (ip_header_ref) packet_get_data(packet);
+        if(! header){
+                return ip_release_and_return(packet, ENOMEM);
+        }
         // checksum
         if(( header->header_checksum ) && ( IP_HEADER_CHECKSUM( header ) != IP_CHECKSUM_ZERO )){
                 phone = ip_prepare_icmp_and_get_phone( 0, packet, header );
                 if( phone >= 0 ){
+        if((header->header_checksum) && (IP_HEADER_CHECKSUM(header) != IP_CHECKSUM_ZERO)){
+                phone = ip_prepare_icmp_and_get_phone(0, packet, header);
+                if(phone >= 0){
                         // checksum error ICMP
                         icmp_parameter_problem_msg( phone, ICMP_PARAM_POINTER, (( size_t ) (( void * ) & header->header_checksum )) - (( size_t ) (( void * ) header )), packet );
+                        icmp_parameter_problem_msg(phone, ICMP_PARAM_POINTER, ((size_t) ((void *) &header->header_checksum)) - ((size_t) ((void *) header)), packet);
+                }
                 return EINVAL;
+        }
         if( header->ttl <= 1 ){
                 phone = ip_prepare_icmp_and_get_phone( 0, packet, header );
                 if( phone >= 0 ){
+        if(header->ttl <= 1){
+                phone = ip_prepare_icmp_and_get_phone(0, packet, header);
+                if(phone >= 0){
                         // ttl oxceeded ICMP
                         icmp_time_exceeded_msg( phone, ICMP_EXC_TTL, packet );
+                        icmp_time_exceeded_msg(phone, ICMP_EXC_TTL, packet);
+                }
                 return EINVAL;
+        }
         // process ipopt and get destination
         dest = ip_get_destination( header );
+        dest = ip_get_destination(header);
         // set the addrination address
         switch( header->version ){
+        switch(header->version){
                 case IPVERSION:
                         addrlen = sizeof( addr_in );
                         bzero( & addr_in, addrlen );
+                        addrlen = sizeof(addr_in);
+                        bzero(&addr_in, addrlen);
                         addr_in.sin_family = AF_INET;
                         memcpy( & addr_in.sin_addr.s_addr, & dest, sizeof( dest ));
                         addr = ( struct sockaddr * ) & addr_in;
+                        memcpy(&addr_in.sin_addr.s_addr, &dest, sizeof(dest));
+                        addr = (struct sockaddr *) &addr_in;
                         break;
 /*              case IPv6VERSION:
                         addrlen = sizeof( dest_in6 );
                         bzero( & dest_in6, addrlen );
+                        addrlen = sizeof(dest_in6);
+                        bzero(&dest_in6, addrlen);
                         dest_in6.sin6_family = AF_INET6;
                         memcpy( & dest_in6.sin6_addr.s6_addr, );
                         dest = ( struct sockaddr * ) & dest_in;
+                        memcpy(&dest_in6.sin6_addr.s6_addr,);
+                        dest = (struct sockaddr *) &dest_in;
                         break;
 */              default:
                         return ip_release_and_return( packet, EAFNOSUPPORT );
+        }
         ERROR_PROPAGATE( packet_set_addr( packet, NULL, ( uint8_t * ) & addr, addrlen ));
         route = ip_find_route( dest );
         if( ! route ){
                 phone = ip_prepare_icmp_and_get_phone( 0, packet, header );
                 if( phone >= 0 ){
+                        return ip_release_and_return(packet, EAFNOSUPPORT);
+        }
+        ERROR_PROPAGATE(packet_set_addr(packet, NULL, (uint8_t *) &addr, addrlen));
+        route = ip_find_route(dest);
+        if(! route){
+                phone = ip_prepare_icmp_and_get_phone(0, packet, header);
+                if(phone >= 0){
                         // unreachable ICMP
                         icmp_destination_unreachable_msg( phone, ICMP_HOST_UNREACH, 0, packet );
+                        icmp_destination_unreachable_msg(phone, ICMP_HOST_UNREACH, 0, packet);
+                }
                 return ENOENT;
+        }
         if( route->address.s_addr == dest.s_addr ){
+        if(route->address.s_addr == dest.s_addr){
                 // local delivery
                 return ip_deliver_local( device_id, packet, header, 0 );
+                return ip_deliver_local(device_id, packet, header, 0);
         }else{
                 // only if routing enabled
                 if( route->netif->routing ){
+                if(route->netif->routing){
                         -- header->ttl;
                         return ip_send_route( packet, route->netif, route, NULL, dest, 0 );
+                        return ip_send_route(packet, route->netif, route, NULL, dest, 0);
                 }else{
                         phone = ip_prepare_icmp_and_get_phone( 0, packet, header );
                         if( phone >= 0 ){
+                        phone = ip_prepare_icmp_and_get_phone(0, packet, header);
+                        if(phone >= 0){
                                 // unreachable ICMP if no routing
                                 icmp_destination_unreachable_msg( phone, ICMP_HOST_UNREACH, 0, packet );
+                                icmp_destination_unreachable_msg(phone, ICMP_HOST_UNREACH, 0, packet);
+                        }
                         return ENOENT;
 …
+}
 int ip_received_error_msg( int ip_phone, device_id_t device_id, packet_t packet, services_t target, services_t error ){
         uint8_t *                       data;
         int                                     offset;
         icmp_type_t                     type;
         icmp_code_t                     code;
         ip_netif_ref            netif;
         measured_string_t       address;
         ip_route_ref            route;
         ip_header_ref           header;
         switch( error ){
+int ip_received_error_msg(int ip_phone, device_id_t device_id, packet_t packet, services_t target, services_t error){
+        uint8_t * data;
+        int offset;
+        icmp_type_t type;
+        icmp_code_t code;
+        ip_netif_ref netif;
+        measured_string_t address;
+        ip_route_ref route;
+        ip_header_ref header;
+        switch(error){
                 case SERVICE_ICMP:
                         offset = icmp_client_process_packet( packet, & type, & code, NULL, NULL );
                         if( offset < 0 ){
                                 return ip_release_and_return( packet, ENOMEM );
+                        }
                         data = packet_get_data( packet );
                         header = ( ip_header_ref )( data + offset );
+                        offset = icmp_client_process_packet(packet, &type, &code, NULL, NULL);
+                        if(offset < 0){
+                                return ip_release_and_return(packet, ENOMEM);
+                        }
+                        data = packet_get_data(packet);
+                        header = (ip_header_ref)(data + offset);
                         // destination host unreachable?
                         if(( type == ICMP_DEST_UNREACH ) && ( code == ICMP_HOST_UNREACH )){
                                 fibril_rwlock_read_lock( & ip_globals.netifs_lock );
                                 netif = ip_netifs_find( & ip_globals.netifs, device_id );
                                 if( netif && netif->arp ){
                                         route = ip_routes_get_index( & netif->routes, 0 );
+                        if((type == ICMP_DEST_UNREACH) && (code == ICMP_HOST_UNREACH)){
+                                fibril_rwlock_read_lock(&ip_globals.netifs_lock);
+                                netif = ip_netifs_find(&ip_globals.netifs, device_id);
+                                if(netif && netif->arp){
+                                        route = ip_routes_get_index(&netif->routes, 0);
                                         // from the same network?
                                         if( route && (( route->address.s_addr & route->netmask.s_addr ) == ( header->destination_address & route->netmask.s_addr ))){
+                                        if(route && ((route->address.s_addr &route->netmask.s_addr) == (header->destination_address &route->netmask.s_addr))){
                                                 // clear the ARP mapping if any
                                                 address.value = ( char * ) & header->destination_address;
                                                 address.length = CONVERT_SIZE( uint8_t, char, sizeof( header->destination_address ));
                                                 arp_clear_address_req( netif->arp->phone, netif->device_id, SERVICE_IP, & address );
+                                                address.value = (char *) &header->destination_address;
+                                                address.length = CONVERT_SIZE(uint8_t, char, sizeof(header->destination_address));
+                                                arp_clear_address_req(netif->arp->phone, netif->device_id, SERVICE_IP, &address);
+                                        }
+                                }
                                 fibril_rwlock_read_unlock( & ip_globals.netifs_lock );
+                                fibril_rwlock_read_unlock(&ip_globals.netifs_lock);
+                        }
                         break;
                 default:
                         return ip_release_and_return( packet, ENOTSUP );
+        }
         return ip_deliver_local( device_id, packet, header, error );
+}
 int ip_deliver_local( device_id_t device_id, packet_t packet, ip_header_ref header, services_t error ){
+                        return ip_release_and_return(packet, ENOTSUP);
+        }
+        return ip_deliver_local(device_id, packet, header, error);
+}
+int ip_deliver_local(device_id_t device_id, packet_t packet, ip_header_ref header, services_t error){
         ERROR_DECLARE;
         ip_proto_ref    proto;
         int                             phone;
         services_t              service;
         tl_received_msg_t       received_msg;
         struct sockaddr *       src;
         struct sockaddr *       dest;
         struct sockaddr_in      src_in;
         struct sockaddr_in      dest_in;
+        ip_proto_ref proto;
+        int phone;
+        services_t service;
+        tl_received_msg_t received_msg;
+        struct sockaddr * src;
+        struct sockaddr * dest;
+        struct sockaddr_in src_in;
+        struct sockaddr_in dest_in;
 //      struct sockaddr_in      src_in6;
 //      struct sockaddr_in      dest_in6;
         socklen_t               addrlen;
         if(( header->flags & IPFLAG_MORE_FRAGMENTS ) || IP_FRAGMENT_OFFSET( header )){
+        socklen_t addrlen;
+        if((header->flags &IPFLAG_MORE_FRAGMENTS) || IP_FRAGMENT_OFFSET(header)){
                 // TODO fragmented
                 return ENOTSUP;
         }else{
                 switch( header->version ){
+                switch(header->version){
                         case IPVERSION:
                                 addrlen = sizeof( src_in );
                                 bzero( & src_in, addrlen );
+                                addrlen = sizeof(src_in);
+                                bzero(&src_in, addrlen);
                                 src_in.sin_family = AF_INET;
                                 memcpy( & dest_in, & src_in, addrlen );
                                 memcpy( & src_in.sin_addr.s_addr, & header->source_address, sizeof( header->source_address ));
                                 memcpy( & dest_in.sin_addr.s_addr, & header->destination_address, sizeof( header->destination_address ));
                                 src = ( struct sockaddr * ) & src_in;
                                 dest = ( struct sockaddr * ) & dest_in;
+                                memcpy(&dest_in, &src_in, addrlen);
+                                memcpy(&src_in.sin_addr.s_addr, &header->source_address, sizeof(header->source_address));
+                                memcpy(&dest_in.sin_addr.s_addr, &header->destination_address, sizeof(header->destination_address));
+                                src = (struct sockaddr *) &src_in;
+                                dest = (struct sockaddr *) &dest_in;
                                 break;
 /*                      case IPv6VERSION:
                                 addrlen = sizeof( src_in6 );
                                 bzero( & src_in6, addrlen );
+                                addrlen = sizeof(src_in6);
+                                bzero(&src_in6, addrlen);
                                 src_in6.sin6_family = AF_INET6;
                                 memcpy( & dest_in6, & src_in6, addrlen );
                                 memcpy( & src_in6.sin6_addr.s6_addr, );
                                 memcpy( & dest_in6.sin6_addr.s6_addr, );
                                 src = ( struct sockaddr * ) & src_in;
                                 dest = ( struct sockaddr * ) & dest_in;
+                                memcpy(&dest_in6, &src_in6, addrlen);
+                                memcpy(&src_in6.sin6_addr.s6_addr,);
+                                memcpy(&dest_in6.sin6_addr.s6_addr,);
+                                src = (struct sockaddr *) &src_in;
+                                dest = (struct sockaddr *) &dest_in;
                                 break;
 */                      default:
                                 return ip_release_and_return( packet, EAFNOSUPPORT );
+                }
                 if( ERROR_OCCURRED( packet_set_addr( packet, ( uint8_t * ) src, ( uint8_t * ) dest, addrlen ))){
                         return ip_release_and_return( packet, ERROR_CODE );
+                                return ip_release_and_return(packet, EAFNOSUPPORT);
+                }
+                if(ERROR_OCCURRED(packet_set_addr(packet, (uint8_t *) src, (uint8_t *) dest, addrlen))){
+                        return ip_release_and_return(packet, ERROR_CODE);
+                }
                 // trim padding if present
                 if(( ! error ) && ( IP_TOTAL_LENGTH( header ) < packet_get_data_length( packet ))){
                         if( ERROR_OCCURRED( packet_trim( packet, 0, packet_get_data_length( packet ) - IP_TOTAL_LENGTH( header )))){
                                 return ip_release_and_return( packet, ERROR_CODE );
+                        }
+                }
                 fibril_rwlock_read_lock( & ip_globals.protos_lock );
                 proto = ip_protos_find( & ip_globals.protos, header->protocol );
                 if( ! proto ){
                         fibril_rwlock_read_unlock( & ip_globals.protos_lock );
                         phone = ip_prepare_icmp_and_get_phone( error, packet, header );
                         if( phone >= 0 ){
+                if((! error) && (IP_TOTAL_LENGTH(header) < packet_get_data_length(packet))){
+                        if(ERROR_OCCURRED(packet_trim(packet, 0, packet_get_data_length(packet) - IP_TOTAL_LENGTH(header)))){
+                                return ip_release_and_return(packet, ERROR_CODE);
+                        }
+                }
+                fibril_rwlock_read_lock(&ip_globals.protos_lock);
+                proto = ip_protos_find(&ip_globals.protos, header->protocol);
+                if(! proto){
+                        fibril_rwlock_read_unlock(&ip_globals.protos_lock);
+                        phone = ip_prepare_icmp_and_get_phone(error, packet, header);
+                        if(phone >= 0){
                                 // unreachable ICMP
                                 icmp_destination_unreachable_msg( phone, ICMP_PROT_UNREACH, 0, packet );
+                                icmp_destination_unreachable_msg(phone, ICMP_PROT_UNREACH, 0, packet);
+                        }
                         return ENOENT;
+                }
                 if( proto->received_msg ){
+                if(proto->received_msg){
                         service = proto->service;
                         received_msg = proto->received_msg;
                         fibril_rwlock_read_unlock( & ip_globals.protos_lock );
                         ERROR_CODE = received_msg( device_id, packet, service, error );
+                        fibril_rwlock_read_unlock(&ip_globals.protos_lock);
+                        ERROR_CODE = received_msg(device_id, packet, service, error);
                 }else{
                         ERROR_CODE = tl_received_msg( proto->phone, device_id, packet, proto->service, error );
                         fibril_rwlock_read_unlock( & ip_globals.protos_lock );
+                        ERROR_CODE = tl_received_msg(proto->phone, device_id, packet, proto->service, error);
+                        fibril_rwlock_read_unlock(&ip_globals.protos_lock);
+                }
                 return ERROR_CODE;
 …
+}
 in_addr_t ip_get_destination( ip_header_ref header ){
         in_addr_t       destination;
+in_addr_t ip_get_destination(ip_header_ref header){
+        in_addr_t destination;
         // TODO search set ipopt route?
 …
+}
 int ip_prepare_icmp( packet_t packet, ip_header_ref header ){
         packet_t        next;
         struct sockaddr *       dest;
         struct sockaddr_in      dest_in;
+int ip_prepare_icmp(packet_t packet, ip_header_ref header){
+        packet_t next;
+        struct sockaddr * dest;
+        struct sockaddr_in dest_in;
 //      struct sockaddr_in      dest_in6;
         socklen_t               addrlen;
+        socklen_t addrlen;
         // detach the first packet and release the others
+        next = pq_detach( packet );
+        if( next ){
+                pq_release( ip_globals.net_phone, packet_get_id( next ));
+        }
+        if( ! header ){
+                if( packet_get_data_length( packet ) <= sizeof( ip_header_t )) return ENOMEM;
+        next = pq_detach(packet);
+        if(next){
+                pq_release(ip_globals.net_phone, packet_get_id(next));
+        }
+        if(! header){
+                if(packet_get_data_length(packet) <= sizeof(ip_header_t)){
+                        return ENOMEM;
+                }
                 // get header
+                header = ( ip_header_ref ) packet_get_data( packet );
+                if( ! header ) return EINVAL;
+                header = (ip_header_ref) packet_get_data(packet);
+                if(! header){
+                        return EINVAL;
+                }
+        }
         // only for the first fragment
+        if( IP_FRAGMENT_OFFSET( header )) return EINVAL;
+        if(IP_FRAGMENT_OFFSET(header)){
+                return EINVAL;
+        }
         // not for the ICMP protocol
         if( header->protocol == IPPROTO_ICMP ){
+        if(header->protocol == IPPROTO_ICMP){
                 return EPERM;
+        }
         // set the destination address
         switch( header->version ){
+        switch(header->version){
                 case IPVERSION:
                         addrlen = sizeof( dest_in );
                         bzero( & dest_in, addrlen );
+                        addrlen = sizeof(dest_in);
+                        bzero(&dest_in, addrlen);
                         dest_in.sin_family = AF_INET;
                         memcpy( & dest_in.sin_addr.s_addr, & header->source_address, sizeof( header->source_address ));
                         dest = ( struct sockaddr * ) & dest_in;
+                        memcpy(&dest_in.sin_addr.s_addr, &header->source_address, sizeof(header->source_address));
+                        dest = (struct sockaddr *) &dest_in;
                         break;
 /*              case IPv6VERSION:
                         addrlen = sizeof( dest_in6 );
                         bzero( & dest_in6, addrlen );
+                        addrlen = sizeof(dest_in6);
+                        bzero(&dest_in6, addrlen);
                         dest_in6.sin6_family = AF_INET6;
                         memcpy( & dest_in6.sin6_addr.s6_addr, );
                         dest = ( struct sockaddr * ) & dest_in;
+                        memcpy(&dest_in6.sin6_addr.s6_addr,);
+                        dest = (struct sockaddr *) &dest_in;
                         break;
 */              default:
                         return EAFNOSUPPORT;
+        }
         return packet_set_addr( packet, NULL, ( uint8_t * ) dest, addrlen );
+}
 int ip_get_icmp_phone( void ){
         ip_proto_ref    proto;
         int                             phone;
         fibril_rwlock_read_lock( & ip_globals.protos_lock );
         proto = ip_protos_find( & ip_globals.protos, IPPROTO_ICMP );
+        return packet_set_addr(packet, NULL, (uint8_t *) dest, addrlen);
+}
+int ip_get_icmp_phone(void){
+        ip_proto_ref proto;
+        int phone;
+        fibril_rwlock_read_lock(&ip_globals.protos_lock);
+        proto = ip_protos_find(&ip_globals.protos, IPPROTO_ICMP);
         phone = proto ? proto->phone : ENOENT;
         fibril_rwlock_read_unlock( & ip_globals.protos_lock );
+        fibril_rwlock_read_unlock(&ip_globals.protos_lock);
         return phone;
+}
 int ip_prepare_icmp_and_get_phone( services_t error, packet_t packet, ip_header_ref header ){
         int     phone;
+int ip_prepare_icmp_and_get_phone(services_t error, packet_t packet, ip_header_ref header){
+        int phone;
         phone = ip_get_icmp_phone();
         if( error || ( phone < 0 ) || ip_prepare_icmp( packet, header )){
                 return ip_release_and_return( packet, EINVAL );
+        if(error || (phone < 0) || ip_prepare_icmp(packet, header)){
+                return ip_release_and_return(packet, EINVAL);
+        }
         return phone;
+}
 int     ip_release_and_return( packet_t packet, int result ){
         pq_release( ip_globals.net_phone, packet_get_id( packet ));
+int ip_release_and_return(packet_t packet, int result){
+        pq_release(ip_globals.net_phone, packet_get_id(packet));
         return result;
+}
 int ip_get_route_req( int ip_phone, ip_protocol_t protocol, const struct sockaddr * destination, socklen_t addrlen, device_id_t * device_id, ip_pseudo_header_ref * header, size_t * headerlen ){
         struct sockaddr_in *    address_in;
+int ip_get_route_req(int ip_phone, ip_protocol_t protocol, const struct sockaddr * destination, socklen_t addrlen, device_id_t * device_id, ip_pseudo_header_ref * header, size_t * headerlen){
+        struct sockaddr_in * address_in;
 //      struct sockaddr_in6 *   address_in6;
+        in_addr_t *                             dest;
+        in_addr_t *                             src;
+        ip_route_ref                    route;
+        ipv4_pseudo_header_ref  header_in;
+        if( !( destination && ( addrlen > 0 ))) return EINVAL;
+        if( !( device_id && header && headerlen )) return EBADMEM;
+        if(( size_t ) addrlen < sizeof( struct sockaddr )){
+        in_addr_t * dest;
+        in_addr_t * src;
+        ip_route_ref route;
+        ipv4_pseudo_header_ref header_in;
+        if(!(destination && (addrlen > 0))){
                 return EINVAL;
+        }
+        switch( destination->sa_family ){
+        if(!(device_id && header && headerlen)){
+                return EBADMEM;
+        }
+        if((size_t) addrlen < sizeof(struct sockaddr)){
+                return EINVAL;
+        }
+        switch(destination->sa_family){
                 case AF_INET:
                         if( addrlen != sizeof( struct sockaddr_in )){
+                        if(addrlen != sizeof(struct sockaddr_in)){
                                 return EINVAL;
+                        }
                         address_in = ( struct sockaddr_in * ) destination;
                         dest = & address_in->sin_addr;
                         if( ! dest->s_addr ){
+                        address_in = (struct sockaddr_in *) destination;
+                        dest = &address_in->sin_addr;
+                        if(! dest->s_addr){
                                 dest->s_addr = IPV4_LOCALHOST_ADDRESS;
+                        }
 …
                 // TODO IPv6
 /*              case AF_INET6:
+                        if( addrlen != sizeof( struct sockaddr_in6 )) return EINVAL;
+                        address_in6 = ( struct sockaddr_in6 * ) dest;
+                        if(addrlen != sizeof(struct sockaddr_in6)){
+                                return EINVAL;
+                        }
+                        address_in6 = (struct sockaddr_in6 *) dest;
                         address_in6.sin6_addr.s6_addr;
 */              default:
                         return EAFNOSUPPORT;
+        }
         fibril_rwlock_read_lock( & ip_globals.lock );
         route = ip_find_route( * dest );
         if( !( route && route->netif )){
                 fibril_rwlock_read_unlock( & ip_globals.lock );
+        fibril_rwlock_read_lock(&ip_globals.lock);
+        route = ip_find_route(*dest);
+        if(!(route && route->netif)){
+                fibril_rwlock_read_unlock(&ip_globals.lock);
                 return ENOENT;
+        }
+        * device_id = route->netif->device_id;
+        src = ip_netif_address( route->netif );
+        fibril_rwlock_read_unlock( & ip_globals.lock );
+        * headerlen = sizeof( * header_in );
+        header_in = ( ipv4_pseudo_header_ref ) malloc( * headerlen );
+        if( ! header_in ) return ENOMEM;
+        bzero( header_in, * headerlen );
+        *device_id = route->netif->device_id;
+        src = ip_netif_address(route->netif);
+        fibril_rwlock_read_unlock(&ip_globals.lock);
+        *headerlen = sizeof(*header_in);
+        header_in = (ipv4_pseudo_header_ref) malloc(*headerlen);
+        if(! header_in){
+                return ENOMEM;
+        }
+        bzero(header_in, * headerlen);
         header_in->destination_address = dest->s_addr;
         header_in->source_address = src->s_addr;
         header_in->protocol = protocol;
         header_in->data_length = 0;
         * header = ( ip_pseudo_header_ref ) header_in;
+        *header = (ip_pseudo_header_ref) header_in;
         return EOK;
+}

uspace/srv/net/il/ip/ip.h

-              raa85487
+              raadf01e
  *  @see device.h
  */
 DEVICE_MAP_DECLARE( ip_netifs, ip_netif_t )
+DEVICE_MAP_DECLARE(ip_netifs, ip_netif_t)
 /** IP registered protocols.
 …
  *  @see int_map.h
  */
 INT_MAP_DECLARE( ip_protos, ip_proto_t )
+INT_MAP_DECLARE(ip_protos, ip_proto_t)
 /** IP routing table.
  *  @see generic_field.h
  */
 GENERIC_FIELD_DECLARE( ip_routes, ip_route_t )
+GENERIC_FIELD_DECLARE(ip_routes, ip_route_t)
 /** IP network interface specific data.
 …
         /** Device identifier.
          */
         device_id_t     device_id;
+        device_id_t device_id;
         /** Netif module service.
          */
         services_t      service;
+        services_t service;
         /** Netif module phone.
          */
         int                     phone;
+        int phone;
         /** ARP module.
          *  Assigned if using ARP.
          */
         module_ref      arp;
+        module_ref arp;
         /** IP version.
          */
         int                     ipv;
+        int ipv;
         /** Indicates whether using DHCP.
          */
         int                     dhcp;
+        int dhcp;
         /** Indicates whether IP routing is enabled.
          */
         int                     routing;
+        int routing;
         /** Device state.
          */
         device_state_t  state;
+        device_state_t state;
         /** Broadcast address.
          */
         in_addr_t       broadcast;
+        in_addr_t broadcast;
         /** Routing table.
          */
         ip_routes_t     routes;
+        ip_routes_t routes;
         /** Packet dimension.
          */
         packet_dimension_t      packet_dimension;
+        packet_dimension_t packet_dimension;
 };
 …
         /** Protocol number.
          */
         int     protocol;
+        int protocol;
         /** Protocol module service.
          */
 …
         /** Protocol module phone.
          */
         int     phone;
+        int phone;
         /** Protocol packet receiving function.
          */
 …
         /** Target address.
          */
         in_addr_t               address;
+        in_addr_t address;
         /** Target network mask.
          */
         in_addr_t               netmask;
+        in_addr_t netmask;
         /** Gateway.
          */
         in_addr_t               gateway;
+        in_addr_t gateway;
         /** Parent netif.
          */
         ip_netif_ref    netif;
+        ip_netif_ref netif;
 };
 …
         /** Networking module phone.
          */
         int                     net_phone;
+        int net_phone;
         /** Registered network interfaces.
          */
         ip_netifs_t     netifs;
+        ip_netifs_t netifs;
         /** Netifs safeyt lock.
          */
         fibril_rwlock_t netifs_lock;
+        fibril_rwlock_t netifs_lock;
         /** Registered protocols.
          */
         ip_protos_t     protos;
+        ip_protos_t protos;
         /** Protocols safety lock.
          */
         fibril_rwlock_t protos_lock;
+        fibril_rwlock_t protos_lock;
         /** Default gateway.
          */
         ip_route_t      gateway;
+        ip_route_t gateway;
         /** Known support modules.
          */
         modules_t       modules;
+        modules_t modules;
         /** Default client connection function for support modules.
          */
 …
         /** Packet counter.
          */
         uint16_t        packet_counter;
+        uint16_t packet_counter;
         /** Safety lock.
          */
         fibril_rwlock_t lock;
+        fibril_rwlock_t lock;
 };

uspace/srv/net/il/ip/ip_client.c

-              raa85487
+              raadf01e
 #include "ip_header.h"
 int ip_client_prepare_packet( packet_t packet, ip_protocol_t protocol, ip_ttl_t ttl, ip_tos_t tos, int dont_fragment, size_t ipopt_length ){
         ip_header_ref   header;
         uint8_t *               data;
         size_t                  padding;
+int ip_client_prepare_packet(packet_t packet, ip_protocol_t protocol, ip_ttl_t ttl, ip_tos_t tos, int dont_fragment, size_t ipopt_length){
+        ip_header_ref header;
+        uint8_t * data;
+        size_t padding;
         padding =  ipopt_length % 4;
         if( padding ){
+        if(padding){
                 padding = 4 - padding;
                 ipopt_length += padding;
+        }
+        data = ( uint8_t * ) packet_prefix( packet, sizeof( ip_header_t ) + padding );
+        if( ! data ) return ENOMEM;
+        while( padding -- ) data[ sizeof( ip_header_t ) + padding ] = IPOPT_NOOP;
+        header = ( ip_header_ref ) data;
+        header->header_length = IP_COMPUTE_HEADER_LENGTH( sizeof( ip_header_t ) + ipopt_length );
+        header->ttl = ( ttl ? ttl : IPDEFTTL ); //((( ttl ) <= MAXTTL ) ? ttl : MAXTTL ) : IPDEFTTL;
+        data = (uint8_t *) packet_prefix(packet, sizeof(ip_header_t) + padding);
+        if(! data){
+                return ENOMEM;
+        }
+        while(padding --){
+                data[sizeof(ip_header_t) + padding] = IPOPT_NOOP;
+        }
+        header = (ip_header_ref) data;
+        header->header_length = IP_COMPUTE_HEADER_LENGTH(sizeof(ip_header_t) + ipopt_length);
+        header->ttl = (ttl ? ttl : IPDEFTTL); //(((ttl) <= MAXTTL) ? ttl : MAXTTL) : IPDEFTTL;
         header->tos = tos;
         header->protocol = protocol;
+        if( dont_fragment ) header->flags = IPFLAG_DONT_FRAGMENT;
+        if(dont_fragment){
+                header->flags = IPFLAG_DONT_FRAGMENT;
+        }
         return EOK;
+}
 int ip_client_process_packet( packet_t packet, ip_protocol_t * protocol, ip_ttl_t * ttl, ip_tos_t * tos, int * dont_fragment, size_t * ipopt_length ){
         ip_header_ref   header;
+int ip_client_process_packet(packet_t packet, ip_protocol_t * protocol, ip_ttl_t * ttl, ip_tos_t * tos, int * dont_fragment, size_t * ipopt_length){
+        ip_header_ref header;
         header = ( ip_header_ref ) packet_get_data( packet );
         if(( ! header )
         || ( packet_get_data_length( packet ) < sizeof( ip_header_t ))){
+        header = (ip_header_ref) packet_get_data(packet);
+        if((! header)
+                || (packet_get_data_length(packet) < sizeof(ip_header_t))){
                 return ENOMEM;
+        }
+        if( protocol ) * protocol = header->protocol;
+        if( ttl ) * ttl = header->ttl;
+        if( tos ) * tos = header->tos;
+        if( dont_fragment ) * dont_fragment = header->flags & IPFLAG_DONT_FRAGMENT;
+        if( ipopt_length ){
+                * ipopt_length = IP_HEADER_LENGTH( header ) - sizeof( ip_header_t );
+                return sizeof( ip_header_t );
+        if(protocol){
+                *protocol = header->protocol;
+        }
+        if(ttl){
+                *ttl = header->ttl;
+        }
+        if(tos){
+                *tos = header->tos;
+        }
+        if(dont_fragment){
+                *dont_fragment = header->flags &IPFLAG_DONT_FRAGMENT;
+        }
+        if(ipopt_length){
+                *ipopt_length = IP_HEADER_LENGTH(header) - sizeof(ip_header_t);
+                return sizeof(ip_header_t);
         }else{
                 return IP_HEADER_LENGTH( header );
+                return IP_HEADER_LENGTH(header);
+        }
+}
 size_t ip_client_header_length( packet_t packet ){
         ip_header_ref   header;
+size_t ip_client_header_length(packet_t packet){
+        ip_header_ref header;
         header = ( ip_header_ref ) packet_get_data( packet );
         if(( ! header )
         || ( packet_get_data_length( packet ) < sizeof( ip_header_t ))){
+        header = (ip_header_ref) packet_get_data(packet);
+        if((! header)
+                || (packet_get_data_length(packet) < sizeof(ip_header_t))){
                 return 0;
+        }
         return IP_HEADER_LENGTH( header );
+        return IP_HEADER_LENGTH(header);
+}
 int ip_client_set_pseudo_header_data_length( ip_pseudo_header_ref header, size_t headerlen, size_t data_length ){
         ipv4_pseudo_header_ref  header_in;
+int ip_client_set_pseudo_header_data_length(ip_pseudo_header_ref header, size_t headerlen, size_t data_length){
+        ipv4_pseudo_header_ref header_in;
+        if( ! header ) return EBADMEM;
+        if( headerlen == sizeof( ipv4_pseudo_header_t )){
+                header_in = ( ipv4_pseudo_header_ref ) header;
+                header_in->data_length = htons( data_length );
+        if(! header){
+                return EBADMEM;
+        }
+        if(headerlen == sizeof(ipv4_pseudo_header_t)){
+                header_in = (ipv4_pseudo_header_ref) header;
+                header_in->data_length = htons(data_length);
                 return EOK;
         }else{
 …
+}
 int ip_client_get_pseudo_header( ip_protocol_t protocol, struct sockaddr * src, socklen_t srclen, struct sockaddr * dest, socklen_t destlen, size_t data_length, ip_pseudo_header_ref * header, size_t * headerlen ){
         ipv4_pseudo_header_ref  header_in;
         struct sockaddr_in *    address_in;
+int ip_client_get_pseudo_header(ip_protocol_t protocol, struct sockaddr * src, socklen_t srclen, struct sockaddr * dest, socklen_t destlen, size_t data_length, ip_pseudo_header_ref * header, size_t * headerlen){
+        ipv4_pseudo_header_ref header_in;
+        struct sockaddr_in * address_in;
+        if( !( header && headerlen )) return EBADMEM;
+        if( !( src && dest && ( srclen > 0 ) && (( size_t ) srclen >= sizeof( struct sockaddr )) && ( srclen == destlen ) && ( src->sa_family == dest->sa_family ))) return EINVAL;
+        switch( src->sa_family ){
+        if(!(header && headerlen)){
+                return EBADMEM;
+        }
+        if(!(src && dest && (srclen > 0) && ((size_t) srclen >= sizeof(struct sockaddr)) && (srclen == destlen) && (src->sa_family == dest->sa_family))){
+                return EINVAL;
+        }
+        switch(src->sa_family){
                 case AF_INET:
+                        if( srclen != sizeof( struct sockaddr_in )) return EINVAL;
+                        * headerlen = sizeof( * header_in );
+                        header_in = ( ipv4_pseudo_header_ref ) malloc( * headerlen );
+                        if( ! header_in ) return ENOMEM;
+                        bzero( header_in, * headerlen );
+                        address_in = ( struct sockaddr_in * ) dest;
+                        if(srclen != sizeof(struct sockaddr_in)){
+                                return EINVAL;
+                        }
+                        *headerlen = sizeof(*header_in);
+                        header_in = (ipv4_pseudo_header_ref) malloc(*headerlen);
+                        if(! header_in){
+                                return ENOMEM;
+                        }
+                        bzero(header_in, * headerlen);
+                        address_in = (struct sockaddr_in *) dest;
                         header_in->destination_address = address_in->sin_addr.s_addr;
                         address_in = ( struct sockaddr_in * ) src;
+                        address_in = (struct sockaddr_in *) src;
                         header_in->source_address = address_in->sin_addr.s_addr;
                         header_in->protocol = protocol;
                         header_in->data_length = htons( data_length );
                         * header = ( ip_pseudo_header_ref ) header_in;
+                        header_in->data_length = htons(data_length);
+                        *header = (ip_pseudo_header_ref) header_in;
                         return EOK;
                 // TODO IPv6
 /*              case AF_INET6:
+                        if( addrlen != sizeof( struct sockaddr_in6 )) return EINVAL;
+                        address_in6 = ( struct sockaddr_in6 * ) addr;
+                        if(addrlen != sizeof(struct sockaddr_in6)){
+                                return EINVAL;
+                        }
+                        address_in6 = (struct sockaddr_in6 *) addr;
                         return EOK;
 */              default:

uspace/srv/net/il/ip/ip_header.h

-              raa85487
+              raadf01e
  *  @param[in] header The IP packet header.
  */
 #define IP_HEADER_LENGTH( header )              (( header )->header_length * 4u )
+#define IP_HEADER_LENGTH(header)                ((header)->header_length * 4u)
 /** Returns the IP header length.
  *  @param[in] length The IP header length in bytes.
  */
 #define IP_COMPUTE_HEADER_LENGTH( length )              (( uint8_t ) (( length ) / 4u ))
+#define IP_COMPUTE_HEADER_LENGTH(length)                ((uint8_t) ((length) / 4u))
 /** Returns the actual IP packet total length.
  *  @param[in] header The IP packet header.
  */
 #define IP_TOTAL_LENGTH( header )               ntohs(( header )->total_length )
+#define IP_TOTAL_LENGTH(header)         ntohs((header)->total_length)
 /** Returns the actual IP packet data length.
  *  @param[in] header The IP packet header.
  */
 #define IP_HEADER_DATA_LENGTH( header ) ( IP_TOTAL_LENGTH( header ) - IP_HEADER_LENGTH( header ))
+#define IP_HEADER_DATA_LENGTH(header)   (IP_TOTAL_LENGTH(header) - IP_HEADER_LENGTH(header))
 /** Returns the IP packet header checksum.
  *  @param[in] header The IP packet header.
  */
 #define IP_HEADER_CHECKSUM( header )    ( htons( ip_checksum(( uint8_t * )( header ), IP_HEADER_LENGTH( header ))))
+#define IP_HEADER_CHECKSUM(header)      (htons(ip_checksum((uint8_t *)(header), IP_HEADER_LENGTH(header))))
 /** Returns the fragment offest.
  *  @param[in] header The IP packet header.
  */
 #define IP_FRAGMENT_OFFSET( header ) (((( header )->fragment_offset_high << 8 ) + ( header )->fragment_offset_low ) * 8u )
+#define IP_FRAGMENT_OFFSET(header) ((((header)->fragment_offset_high << 8) + (header)->fragment_offset_low) * 8u)
 /** Returns the fragment offest high bits.
  *  @param[in] length The prefixed data total length.
  */
 #define IP_COMPUTE_FRAGMENT_OFFSET_HIGH( length ) (((( length ) / 8u ) & 0x1F00 ) >> 8 )
+#define IP_COMPUTE_FRAGMENT_OFFSET_HIGH(length) ((((length) / 8u) &0x1F00) >> 8)
 /** Returns the fragment offest low bits.
  *  @param[in] length The prefixed data total length.
  */
 #define IP_COMPUTE_FRAGMENT_OFFSET_LOW( length ) ((( length ) / 8u ) & 0xFF )
+#define IP_COMPUTE_FRAGMENT_OFFSET_LOW(length) (((length) / 8u) &0xFF)
 /** Type definition of the internet header.
 …
         /** The Version field indicates the format of the internet header.
          */
         uint8_t         version:4;
+        uint8_t version:4;
         /** Internet Header Length is the length of the internet header in 32~bit words, and thus points to the beginning of the data.
          *  Note that the minimum value for a~correct header is~5.
          */
         uint8_t         header_length:4;
+        uint8_t header_length:4;
 #else
         /** Internet Header Length is the length of the internet header in 32~bit words, and thus points to the beginning of the data.
          *  Note that the minimum value for a~correct header is~5.
          */
         uint8_t         header_length:4;
+        uint8_t header_length:4;
         /** The Version field indicates the format of the internet header.
          */
         uint8_t         version:4;
+        uint8_t version:4;
 #endif
         /** The Type of Service provides an indication of the abstract parameters of the quality of service desired.
 …
          *  The major choice is a~three way tradeoff between low-delay, high-reliability, and high-throughput.
          */
         uint8_t         tos;
+        uint8_t tos;
         /** Total Length is the length of the datagram, measured in octets, including internet header and data.
          *  This field allows the length of a~datagram to be up to 65,535~octets.
          */
         uint16_t        total_length;
+        uint16_t total_length;
         /** An identifying value assigned by the sender to aid in assembling the fragments of a~datagram.
          */
         uint16_t        identification;
+        uint16_t identification;
 #ifdef ARCH_IS_BIG_ENDIAN
         /** Various control flags.
          */
         uint8_t flags:3;
+        uint8_t flags:3;
         /** This field indicates where in the datagram this fragment belongs.
          *  High bits.
          */
         uint8_t fragment_offset_high:5;
+        uint8_t fragment_offset_high:5;
 #else
         /** This field indicates where in the datagram this fragment belongs.
          *  High bits.
          */
         uint8_t fragment_offset_high:5;
+        uint8_t fragment_offset_high:5;
         /** Various control flags.
          */
         uint8_t flags:3;
+        uint8_t flags:3;
 #endif
         /** This field indicates where in the datagram this fragment belongs.
          *  Low bits.
          */
         uint8_t fragment_offset_low;
+        uint8_t fragment_offset_low;
         /** This field indicates the maximum time the datagram is allowed to remain in the internet system.
          *  If this field contains the value zero, then the datagram must be destroyed.
 …
          *  The intention is to cause undeliverable datagrams to be discarded, and to bound the maximum datagram lifetime.
          */
         uint8_t         ttl;
+        uint8_t ttl;
         /** This field indicates the next level protocol used in the data portion of the internet datagram.
          */
         uint8_t         protocol;
+        uint8_t protocol;
         /** A checksum of the header only.
          *  Since some header fields change (e.g., time to live), this is recomputed and verified at each point that the internet header is processed.
 …
          *  For purposes of computing the checksum, the value of the checksum field is zero.
          */
         uint16_t        header_checksum;
+        uint16_t header_checksum;
         /** The source address.
          */
         uint32_t        source_address;
+        uint32_t source_address;
         /** The destination address.
          */
         uint32_t        destination_address;
+        uint32_t destination_address;
 } __attribute__ ((packed));
 …
         /** A single octet of option-type.
          */
         uint8_t         type;
+        uint8_t type;
         /** An option length octet.
          */
         uint8_t         length;
+        uint8_t length;
         /** A~pointer.
          */
         uint8_t         pointer;
+        uint8_t pointer;
 #ifdef ARCH_IS_BIG_ENDIAN
         /** The number of IP modules that cannot register timestamps due to lack of space.
          */
         uint8_t overflow:4;
+        uint8_t overflow:4;
         /** Various internet timestamp control flags.
          */
         uint8_t flags:4;
+        uint8_t flags:4;
 #else
         /** Various internet timestamp control flags.
          */
         uint8_t flags:4;
+        uint8_t flags:4;
         /** The number of IP modules that cannot register timestamps due to lack of space.
          */
         uint8_t overflow:4;
+        uint8_t overflow:4;
 #endif
 } __attribute__ ((packed));
 …
  *  Allows the packet fragmentation.
  */
 #define IPFLAG_MAY_FRAGMENT                     ( 0x0 << IPFLAG_FRAGMENT_SHIFT )
+#define IPFLAG_MAY_FRAGMENT                     (0x0 << IPFLAG_FRAGMENT_SHIFT)
 /** Don't fragment flag value.
  *  Permits the packet fragmentation.
  */
 #define IPFLAG_DONT_FRAGMENT            ( 0x1 << IPFLAG_FRAGMENT_SHIFT )
+#define IPFLAG_DONT_FRAGMENT            (0x1 << IPFLAG_FRAGMENT_SHIFT)
 /** Last fragment flag value.
  *  Indicates the last packet fragment.
  */
 #define IPFLAG_LAST_FRAGMENT            ( 0x0 << IPFLAG_FRAGMENTED_SHIFT )
+#define IPFLAG_LAST_FRAGMENT            (0x0 << IPFLAG_FRAGMENTED_SHIFT)
 /** More fragments flag value.
  *  Indicates that more packet fragments follow.
  */
 #define IPFLAG_MORE_FRAGMENTS           ( 0x1 << IPFLAG_FRAGMENTED_SHIFT )
+#define IPFLAG_MORE_FRAGMENTS           (0x1 << IPFLAG_FRAGMENTED_SHIFT)
 /*@}*/
 …
         /** The source address.
          */
         uint32_t        source_address;
+        uint32_t source_address;
         /** The destination address.
          */
         uint32_t        destination_address;
+        uint32_t destination_address;
         /** Reserved byte.
          *  Must be zero.
          */
         uint8_t         reserved;
+        uint8_t reserved;
         /** This field indicates the next level protocol used in the data portion of the internet datagram.
          */
         uint8_t         protocol;
+        uint8_t protocol;
         /** Data length is the length of the datagram, measured in octets.
          */
         uint16_t        data_length;
+        uint16_t data_length;
 } __attribute__ ((packed));

uspace/srv/net/il/ip/ip_messages.h

-              raa85487
+              raadf01e
  *  @param[in] call The message call structure.
  */
 #define IP_GET_GATEWAY( call )          ({ in_addr_t addr; addr.s_addr = IPC_GET_ARG2( * call ); addr; })
+#define IP_GET_GATEWAY(call)            ({in_addr_t addr; addr.s_addr = IPC_GET_ARG2(*call); addr;})
 /** Returns the address message parameter.
  *  @param[in] call The message call structure.
  */
 #define IP_GET_ADDRESS( call )          ({ in_addr_t addr; addr.s_addr = IPC_GET_ARG3( * call ); addr; })
+#define IP_GET_ADDRESS(call)            ({in_addr_t addr; addr.s_addr = IPC_GET_ARG3(*call); addr;})
 /** Returns the network mask message parameter.
  *  @param[in] call The message call structure.
  */
 #define IP_GET_NETMASK( call )          ({ in_addr_t addr; addr.s_addr = IPC_GET_ARG4( * call ); addr; })
+#define IP_GET_NETMASK(call)            ({in_addr_t addr; addr.s_addr = IPC_GET_ARG4(*call); addr;})
 /** Returns the protocol message parameter.
  *  @param[in] call The message call structure.
  */
 #define IP_GET_PROTOCOL( call )         (( ip_protocol_t ) IPC_GET_ARG1( * call ))
+#define IP_GET_PROTOCOL(call)           ((ip_protocol_t) IPC_GET_ARG1(*call))
 /** Sets the header length in the message answer.
  *  @param[out] answer The message answer structure.
  */
 #define IP_SET_HEADERLEN( answer )      (( size_t * ) & IPC_GET_ARG2( * answer ))
+#define IP_SET_HEADERLEN(answer)        ((size_t *) &IPC_GET_ARG2(*answer))
 /*@}*/

uspace/srv/net/il/ip/ip_module.c

-              raa85487
+              raadf01e
  *  @see NAME
  */
 void    module_print_name( void );
+void module_print_name(void);
 /** Starts the IP module.
 …
  *  @returns Other error codes as defined for the REGISTER_ME() macro function.
  */
 int     module_start( async_client_conn_t client_connection );
+int module_start(async_client_conn_t client_connection);
 /** Processes the IP message.
 …
  *  @returns Other error codes as defined for the ip_message() function.
  */
 int     module_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count );
+int module_message(ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count);
 /** IP module global data.
 …
 extern ip_globals_t     ip_globals;
 void module_print_name( void ){
         printf( "%s", NAME );
+void module_print_name(void){
+        printf("%s", NAME);
+}
 int module_start( async_client_conn_t client_connection ){
+int module_start(async_client_conn_t client_connection){
         ERROR_DECLARE;
         ipcarg_t        phonehash;
+        ipcarg_t phonehash;
         async_set_client_connection( client_connection );
         ip_globals.net_phone = net_connect_module( SERVICE_NETWORKING );
         ERROR_PROPAGATE( pm_init());
         if( ERROR_OCCURRED( ip_initialize( client_connection ))
         || ERROR_OCCURRED( REGISTER_ME( SERVICE_IP, & phonehash ))){
+        async_set_client_connection(client_connection);
+        ip_globals.net_phone = net_connect_module(SERVICE_NETWORKING);
+        ERROR_PROPAGATE(pm_init());
+        if(ERROR_OCCURRED(ip_initialize(client_connection))
+                || ERROR_OCCURRED(REGISTER_ME(SERVICE_IP, &phonehash))){
                 pm_destroy();
                 return ERROR_CODE;
 …
+}
 int     module_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count ){
         return ip_message( callid, call, answer, answer_count );
+int module_message(ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count){
+        return ip_message(callid, call, answer, answer_count);
+}

uspace/srv/net/il/ip/ip_module.h

-              raa85487
+              raadf01e
  *  @returns ENOMEM if there is not enough memory left.
  */
 int     ip_initialize( async_client_conn_t client_connection );
+int ip_initialize(async_client_conn_t client_connection);
 /** Processes the IP message.
 …
  *  @see IS_NET_IP_MESSAGE()
  */
 int     ip_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count );
+int ip_message(ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count);
 #endif

uspace/srv/net/il/ip/ip_remote.c

-              raa85487
+              raadf01e
 #include "ip_messages.h"
 int ip_device_req( int ip_phone, device_id_t device_id, services_t service ){
         return generic_device_req( ip_phone, NET_IL_DEVICE, device_id, 0, service );
+int ip_device_req(int ip_phone, device_id_t device_id, services_t service){
+        return generic_device_req(ip_phone, NET_IL_DEVICE, device_id, 0, service);
+}
 int ip_send_msg( int ip_phone, device_id_t device_id, packet_t packet, services_t sender, services_t error ){
         return generic_send_msg( ip_phone, NET_IL_SEND, device_id, packet_get_id( packet ), sender, error );
+int ip_send_msg(int ip_phone, device_id_t device_id, packet_t packet, services_t sender, services_t error){
+        return generic_send_msg(ip_phone, NET_IL_SEND, device_id, packet_get_id(packet), sender, error);
+}
 int ip_connect_module( services_t service ){
         return connect_to_service( SERVICE_IP );
+int ip_connect_module(services_t service){
+        return connect_to_service(SERVICE_IP);
+}
 int ip_add_route_req( int ip_phone, device_id_t device_id, in_addr_t address, in_addr_t netmask, in_addr_t gateway ){
         return ( int ) async_req_4_0( ip_phone, NET_IP_ADD_ROUTE, ( ipcarg_t ) device_id, ( ipcarg_t ) gateway.s_addr, ( ipcarg_t ) address.s_addr, ( ipcarg_t ) netmask.s_addr );
+int ip_add_route_req(int ip_phone, device_id_t device_id, in_addr_t address, in_addr_t netmask, in_addr_t gateway){
+        return (int) async_req_4_0(ip_phone, NET_IP_ADD_ROUTE, (ipcarg_t) device_id, (ipcarg_t) gateway.s_addr, (ipcarg_t) address.s_addr, (ipcarg_t) netmask.s_addr);
+}
 int ip_set_gateway_req( int ip_phone, device_id_t device_id, in_addr_t gateway ){
         return ( int ) async_req_2_0( ip_phone, NET_IP_SET_GATEWAY, ( ipcarg_t ) device_id, ( ipcarg_t ) gateway.s_addr );
+int ip_set_gateway_req(int ip_phone, device_id_t device_id, in_addr_t gateway){
+        return (int) async_req_2_0(ip_phone, NET_IP_SET_GATEWAY, (ipcarg_t) device_id, (ipcarg_t) gateway.s_addr);
+}
 int ip_packet_size_req( int ip_phone, device_id_t device_id, packet_dimension_ref packet_dimension ){
         return generic_packet_size_req( ip_phone, NET_IL_PACKET_SPACE, device_id, packet_dimension );
+int ip_packet_size_req(int ip_phone, device_id_t device_id, packet_dimension_ref packet_dimension){
+        return generic_packet_size_req(ip_phone, NET_IL_PACKET_SPACE, device_id, packet_dimension);
+}
 int ip_bind_service( services_t service, int protocol, services_t me, async_client_conn_t receiver, tl_received_msg_t tl_received_msg ){
         return ( int ) bind_service( service, ( ipcarg_t ) protocol, me, service, receiver );
+int ip_bind_service(services_t service, int protocol, services_t me, async_client_conn_t receiver, tl_received_msg_t tl_received_msg){
+        return (int) bind_service(service, (ipcarg_t) protocol, me, service, receiver);
+}
 int ip_received_error_msg( int ip_phone, device_id_t device_id, packet_t packet, services_t target, services_t error ){
         return generic_received_msg( ip_phone, NET_IP_RECEIVED_ERROR, device_id, packet_get_id( packet ), target, error );
+int ip_received_error_msg(int ip_phone, device_id_t device_id, packet_t packet, services_t target, services_t error){
+        return generic_received_msg(ip_phone, NET_IP_RECEIVED_ERROR, device_id, packet_get_id(packet), target, error);
+}
 int ip_get_route_req( int ip_phone, ip_protocol_t protocol, const struct sockaddr * destination, socklen_t addrlen, device_id_t * device_id, ip_pseudo_header_ref * header, size_t * headerlen ){
         aid_t                   message_id;
         ipcarg_t                result;
         ipc_call_t              answer;
+int ip_get_route_req(int ip_phone, ip_protocol_t protocol, const struct sockaddr * destination, socklen_t addrlen, device_id_t * device_id, ip_pseudo_header_ref * header, size_t * headerlen){
+        aid_t message_id;
+        ipcarg_t result;
+        ipc_call_t answer;
+        if( !( destination && ( addrlen > 0 ))) return EINVAL;
+        if( !( device_id && header && headerlen )) return EBADMEM;
+        * header = NULL;
+        message_id = async_send_1( ip_phone, NET_IP_GET_ROUTE, ( ipcarg_t ) protocol, & answer );
+        if(( async_data_write_start( ip_phone, destination, addrlen ) == EOK )
+        && ( async_data_read_start( ip_phone, headerlen, sizeof( * headerlen )) == EOK )
+        && ( * headerlen > 0 )){
+                * header = ( ip_pseudo_header_ref ) malloc( * headerlen );
+                if( * header ){
+                        if( async_data_read_start( ip_phone, * header, * headerlen ) != EOK ){
+                                free( * header );
+        if(!(destination && (addrlen > 0))){
+                return EINVAL;
+        }
+        if(!(device_id && header && headerlen)){
+                return EBADMEM;
+        }
+        *header = NULL;
+        message_id = async_send_1(ip_phone, NET_IP_GET_ROUTE, (ipcarg_t) protocol, &answer);
+        if((async_data_write_start(ip_phone, destination, addrlen) == EOK)
+                && (async_data_read_start(ip_phone, headerlen, sizeof(*headerlen)) == EOK)
+                && (*headerlen > 0)){
+                *header = (ip_pseudo_header_ref) malloc(*headerlen);
+                if(*header){
+                        if(async_data_read_start(ip_phone, * header, * headerlen) != EOK){
+                                free(*header);
+                        }
+                }
+        }
         async_wait_for( message_id, & result );
         if(( result != EOK ) && ( * header )){
                 free( * header );
+        async_wait_for(message_id, &result);
+        if((result != EOK) && (*header)){
+                free(*header);
         }else{
                 * device_id = IPC_GET_DEVICE( & answer );
+                *device_id = IPC_GET_DEVICE(&answer);
+        }
         return ( int ) result;
+        return (int) result;
+}

Note: See TracChangeset for help on using the changeset viewer.

Download in other formats: