/*
* Copyright (c) 2009 Lukas Mejdrech
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* - Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* - Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* - The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/** @addtogroup net
* @{
*/
/** @file
*/
#include <async.h>
#include <ctype.h>
#include <errno.h>
#include <malloc.h>
#include <stdio.h>
#include <task.h>
#include <unistd.h>
#include <ipc/ipc.h>
#include <ipc/services.h>
#include "../err.h"
#include "../messages.h"
#include "../modules.h"
//#include "../self_test.h"
#include "../structures/char_map.h"
#include "../structures/generic_char_map.h"
#include "../structures/measured_strings.h"
#include "../structures/packet/packet.h"
#include "../structures/packet/packet_server.h"
#include "../il/ip/ip_messages.h"
#include "../netif/device.h"
#if IP_BUNDLE
#include "../ip/ip_module.h"
#endif
#if TCP_BUNDLE
#include "../tcp/tcp_module.h"
#endif
#define NAME "Networking"
#define LO_NAME "lo"
#define LO_FILENAME "/sbin/lo"
#define DP8390_ISA_NAME "dp8390_isa"
#define DP8390_ISA_FILENAME "/sbin/dp8380_isa"
#define ETHERNET_NAME "ethernet"
#define ETHERNET_FILENAME "/sbin/ethernet"
#define IP_NAME "ip"
#define IP_FILENAME "/sbin/ip"
#define IPC_GET_DEVICE( call ) ( device_id_t ) IPC_GET_ARG1( * call )
#define IPC_GET_COUNT( call ) ( int ) IPC_GET_ARG2( * call )
typedef struct module_struct module_t;
typedef module_t * module_ref;
typedef struct netif netif_t;
typedef netif_t * netif_ref;
typedef struct networking_globals networking_globals_t;
DEVICE_MAP_DECLARE( netifs, netif_t )
GENERIC_CHAR_MAP_DECLARE( measured_strings, measured_string_t )
GENERIC_CHAR_MAP_DECLARE( modules, module_t )
struct module_struct{
task_id_t task_id;
services_t service;
int phone;
int usage;
const char * name;
const char * filename;
};
/** A present network interface device.
*/
struct netif{
/** A system-unique network interface identifier.
*/
device_id_t id;
/** A serving network interface driver module index.
*/
module_ref driver;
/** A serving link layer module index.
*/
module_ref nil;
/** A serving internet layer module index.
*/
module_ref il;
/** A system-unique network interface name.
*/
char * name;
/** Configuration.
*/
measured_strings_t configuration;
};
/** A networking module global variables.
*/
struct networking_globals{
/** Present network interfaces.
*/
netifs_t netifs;
/** Network interface structure indices by names.
*/
char_map_t netif_names;
/** Available modules.
*/
modules_t modules;
/** Global configuration.
*/
measured_strings_t configuration;
};
void networking_print_name( void );
int add_module( module_ref * module, modules_ref modules, const char const * name, const char const * filename, services_t service, task_id_t task_id );
measured_string_ref configuration_find( measured_strings_ref configuration, const char * name );
int networking_start_module( async_client_conn_t client_connection );
int networking_initialize( void );
int networking_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count );
int net_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count );
//int parse_line( measured_strings_ref configuration, char * line );
int add_configuration( measured_strings_ref configuration, const char * name, const char * value );
int read_configuration( void );
task_id_t spawn( const char * fname );
int startup( void );
device_id_t generate_new_device_id( void );
static networking_globals_t networking_globals;
DEVICE_MAP_IMPLEMENT( netifs, netif_t )
GENERIC_CHAR_MAP_IMPLEMENT( measured_strings, measured_string_t )
GENERIC_CHAR_MAP_IMPLEMENT( modules, module_t )
void networking_print_name( void ){
}
int add_module( module_ref * module, modules_ref modules, const char * name, const char * filename, services_t service, task_id_t task_id ){
ERROR_DECLARE;
module_ref tmp_module;
tmp_module
= ( module_ref
) malloc( sizeof( module_t
)); if( ! tmp_module ) return ENOMEM;
tmp_module->task_id = task_id;
tmp_module->phone = 0;
tmp_module->usage = 0;
tmp_module->name = name;
tmp_module->filename = filename;
tmp_module->service = service;
if( ERROR_OCCURRED( modules_add( modules, tmp_module->name, 0, tmp_module ))){
return ERROR_CODE;
}
if( module ) * module = tmp_module;
return EOK;
}
int networking_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count ){
#ifdef NETWORKING_module
//TODO map to *_message
if( IS_NET_IL_MESSAGE( call ) || IS_NET_IP_MESSAGE( call )){
return ip_message( callid, call, answer, answer_count );
/* }else if( IS_NET_ARP_MESSAGE( call )){
return arp_message( callid, call, answer, answer_count );
*//* }else if( IS_NET_RARP_MESSAGE( call )){
return rarp_message( callid, call, answer, answer_count );
*//* }else if( IS_NET_ICMP_MESSAGE( call )){
return icmp_message( callid, call, answer, answer_count );
*//* }else if( IS_NET_UDP_MESSAGE( call )){
return udp_message( callid, call, answer, answer_count );
*/ }else if( IS_NET_TCP_MESSAGE( call )){
return tcp_message( callid, call, answer, answer_count );
/* }else if( IS_NET_SOCKET_MESSAGE( call )){
return socket_message( callid, call, answer, answer_count );
*//* }else if( IS_NET_NIL_MESSAGE( call ) || IS_NET_ETHERNET_MESSAGE( call )){
return ethernet_message( callid, call, answer, answer_count );
*/ }else{
#endif
if( IS_NET_PACKET_MESSAGE( call )){
return packet_server_message( callid, call, answer, answer_count );
}else{
return net_message( callid, call, answer, answer_count );
}
#ifdef NETWORKING_module
}
#endif
}
int networking_start_module( async_client_conn_t client_connection ){
ERROR_DECLARE;
ipcarg_t phonehash;
async_set_client_connection( client_connection );
ERROR_PROPAGATE( pm_init());
if( ERROR_OCCURRED( networking_initialize())
|| ERROR_OCCURRED( REGISTER_ME( SERVICE_NETWORKING, & phonehash ))){
pm_destroy();
return ERROR_CODE;
}
async_manager();
pm_destroy();
return EOK;
}
int networking_initialize( void ){
ERROR_DECLARE;
task_id_t task_id;
netifs_initialize( & networking_globals.netifs );
char_map_initialize( & networking_globals.netif_names );
modules_initialize( & networking_globals.modules );
measured_strings_initialize( & networking_globals.configuration );
// run self tests
// ERROR_PROPAGATE( self_test());
ERROR_PROPAGATE( add_module( NULL, & networking_globals.modules, LO_NAME, LO_FILENAME, SERVICE_LO, 0 ));
ERROR_PROPAGATE( add_module( NULL, & networking_globals.modules, DP8390_ISA_NAME, DP8390_ISA_FILENAME, SERVICE_DP8390_ISA, 0 ));
ERROR_PROPAGATE( add_module( NULL, & networking_globals.modules, ETHERNET_NAME, ETHERNET_FILENAME, SERVICE_ETHERNET, 0 ));
#ifdef NETWORKING_modular
task_id = spawn( "/sbin/ip" );
if( ! task_id ) return EINVAL;
ERROR_PROPAGATE( add_module( NULL, & networking_globals.modules, IP_NAME, IP_FILENAME, SERVICE_IP, task_id ));
// if( ! spawn( "/sbin/udp" )) return EINVAL;
if( ! spawn( "/sbin/tcp" )) return EINVAL;
// if( ! spawn( "/sbin/socket" )) return EINVAL;
// not always necesssary
// if( ! spawn( "/sbin/arp" )) return EINVAL;
// if( ! spawn( "/sbin/rarp" )) return EINVAL;
// if( ! spawn( "/sbin/icmp" )) return EINVAL;
#else
#ifdef NETWORKING_module
ipcarg_t phonehash;
ERROR_PROPAGATE( REGISTER_ME( SERVICE_IP, & phonehash ));
ERROR_PROPAGATE( add_module( NULL, & networking_globals.modules, IP_NAME, IP_FILENAME, SERVICE_IP, task_get_id()));
ERROR_PROPAGATE( ip_initialize());
// ERROR_PROPAGATE( REGISTER_ME( SERVICE_ARP, & phonehash ));
// ERROR_PROPAGATE( arp_initialize());
// ERROR_PROPAGATE( REGISTER_ME( SERVICE_RARP, & phonehash ));
// ERROR_PROPAGATE( rarp_initialize());
// ERROR_PROPAGATE( REGISTER_ME( SERVICE_ICMP, & phonehash ));
// ERROR_PROPAGATE( icmp_initialize());
// ERROR_PROPAGATE( REGISTER_ME( SERVICE_UDP, & phonehash ));
// ERROR_PROPAGATE( udp_initialize());
ERROR_PROPAGATE( REGISTER_ME( SERVICE_TCP, & phonehash ));
ERROR_PROPAGATE( tcp_initialize());
// ERROR_PROPAGATE( REGISTER_ME( SERVICE_SOCKET, & phonehash ));
// ERROR_PROPAGATE( socket_initialize());
// ERROR_PROPAGATE( REGISTER_ME( SERVICE_ETHERNET, & phonehash ));
// ERROR_PROPAGATE( ethernet_initialize());
#endif
#endif
return EOK;
}
//TODO as ip.c
int net_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count ){
ERROR_DECLARE;
measured_string_ref strings;
char * data;
int index;
measured_string_ref setting;
measured_strings_ref configuration;
netif_ref netif;
* answer_count = 0;
switch( IPC_GET_METHOD( * call )){
case IPC_M_PHONE_HUNGUP:
return EOK;
case NET_NET_DEVICE:
// TODO configure, register
printf( "\nNetworking: new netif %d", IPC_GET_DEVICE
( call
)); return EOK;
case NET_NET_GET_DEVICE_CONF:
ERROR_PROPAGATE( measured_strings_receive( & strings, & data, IPC_GET_COUNT( call )));
netif = netifs_find( & networking_globals.netifs, IPC_GET_DEVICE( call ));
if( netif ){
configuration = & netif->configuration;
}else{
configuration = NULL;
}
for( index = 0; index < IPC_GET_COUNT( call ); ++ index ){
setting = measured_strings_find( configuration, strings[ index ].value, 0 );
if( ! setting ){
setting = measured_strings_find( & networking_globals.configuration, strings[ index ].value, 0 );
}
if( setting ){
strings[ index ].length = setting->length;
strings[ index ].value = setting->value;
}else{
strings[ index ].length = 0;
strings[ index ].value = NULL;
}
}
// strings should not contain received data anymore
ERROR_CODE = measured_strings_reply( strings, IPC_GET_COUNT( call ));
return ERROR_CODE;
case NET_NET_GET_CONF:
// arg1 = count
ERROR_PROPAGATE( measured_strings_receive( & strings, & data, IPC_GET_COUNT( call )));
for( index = 0; index < IPC_GET_COUNT( call ); ++ index ){
setting = measured_strings_find( & networking_globals.configuration, strings[ index ].value, 0 );
if( setting ){
strings[ index ].length = setting->length;
strings[ index ].value = setting->value;
}else{
strings[ index ].length = 0;
strings[ index ].value = NULL;
}
}
// strings should not contain received data anymore
ERROR_CODE = measured_strings_reply( strings, IPC_GET_COUNT( call ));
return ERROR_CODE;
case NET_NET_STARTUP:
return startup();
}
return ENOTSUP;
}
/*
int parse_line( measured_strings_ref configuration, char * line ){
ERROR_DECLARE;
measured_string_ref setting;
char * name;
char * value;
// from the beginning
name = line;
// skip spaces
while( isspace( * name )) ++ name;
// remember the name start
value = name;
// skip the name
while( isalnum( * value ) || ( * value == '_' )){
// make uppercase
// * value = toupper( * value );
++ value;
}
if( * value == '=' ){
// terminate the name
* value = '\0';
}else{
// terminate the name
* value = '\0';
// skip until '='
++ value;
while(( * value ) && ( * value != '=' )) ++ value;
// not found?
if( * value != '=' ) return EINVAL;
}
++ value;
// skip spaces
while( isspace( * value )) ++ value;
// create a bulk measured string till the end
setting = measured_string_create_bulk( value, -1 );
if( ! setting ) return ENOMEM;
// add the configuration setting
if( ERROR_OCCURRED( measured_strings_add( configuration, name, 0, setting ))){
free( setting );
return ERROR_CODE;
}
return EOK;
}
*/
int add_configuration( measured_strings_ref configuration, const char * name, const char * value ){
ERROR_DECLARE;
measured_string_ref setting;
setting = measured_string_create_bulk( value, 0 );
if( ! setting ) return ENOMEM;
// add the configuration setting
if( ERROR_OCCURRED( measured_strings_add( configuration, name, 0, setting ))){
return ERROR_CODE;
}
return EOK;
}
device_id_t generate_new_device_id( void ){
return netifs_count( & networking_globals.netifs ) + 1;
}
int read_configuration( void ){
ERROR_DECLARE;
netif_ref netif;
measured_string_ref setting;
services_t internet_service;
int index;
// read general configuration
ERROR_PROPAGATE( add_configuration( & networking_globals.configuration, "IPV", "4" ));
// read network interfaces configuration
// static loopback initialization
// printf( "\nloopback initialization" );
netif
= ( netif_ref
) malloc( sizeof( netif_t
)); if( ! netif ) return ENOMEM;
netif->id = generate_new_device_id();
ERROR_PROPAGATE( measured_strings_initialize( & netif->configuration ));
if( ERROR_OCCURRED( add_configuration( & netif->configuration, "NAME", LO_NAME ))
|| ERROR_OCCURRED( add_configuration( & netif->configuration, "NETIF", LO_NAME ))
|| ERROR_OCCURRED( add_configuration( & netif->configuration, "IL", IP_NAME ))
|| ERROR_OCCURRED( add_configuration( & netif->configuration, "MTU", "1500" ))
|| ERROR_OCCURRED( add_configuration( & netif->configuration, "IP_CONFIG", "STATIC" ))
|| ERROR_OCCURRED( add_configuration( & netif->configuration, "IP_ADDR", "127.0.0.1" ))
|| ERROR_OCCURRED( add_configuration( & netif->configuration, "NETMASK", "255.0.0.0" ))){
measured_strings_destroy( & netif->configuration );
return ERROR_CODE;
}
// mandatory name
// printf( "\n\tname" );
setting = measured_strings_find( & netif->configuration, "NAME", 0 );
if( ! setting ){
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
netif->name = setting->value;
// printf( " %s OK", netif->name );
// mandatory netif
// printf( "\n\tnetif" );
setting = measured_strings_find( & netif->configuration, "NETIF", 0 );
if( ! setting ){
// printf( " unknown" );
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
// printf( " find %s in %d?", setting->value, modules_count( & networking_globals.modules ));
netif->driver = modules_find( & networking_globals.modules, setting->value, 0 );
if( ! netif->driver ){
// printf( " not found" );
// TODO register the unknown one
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
// printf( " found" );
if( ! netif->driver->task_id ){
netif->driver->task_id = spawn( netif->driver->filename );
if( ! netif->driver->task_id ){
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
}
// printf( " OK" );
// optional link layer
// printf( "\n\tlink layer" );
setting = measured_strings_find( & netif->configuration, "NIL", 0 );
if( setting ){
netif->nil = modules_find( & networking_globals.modules, setting->value, 0 );
if( ! netif->nil ){
// TODO register the unknown one
-- netif->driver->usage;
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
if( ! netif->nil->task_id ){
netif->nil->task_id = spawn( netif->nil->filename );
if( ! netif->nil->task_id ){
-- netif->driver->usage;
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
}
}else{
netif->nil = NULL;
}
// mandatory internet layer
// printf( "\n\tinternet layer" );
setting = measured_strings_find( & netif->configuration, "IL", 0 );
if( ! setting ){
-- netif->driver->usage;
-- netif->nil->usage;
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
// printf( " set %s", setting->value );
netif->il = modules_find( & networking_globals.modules, setting->value, 0 );
if( ! netif->il ){
// TODO register the unknown one
-- netif->driver->usage;
-- netif->nil->usage;
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
// printf( " found" );
if( ! netif->il->task_id ){
netif->il->task_id = spawn( netif->il->filename );
if( ! netif->il->task_id ){
-- netif->driver->usage;
-- netif->nil->usage;
measured_strings_destroy( & netif->configuration );
return EINVAL;
}
}
index = netifs_add( & networking_globals.netifs, netif->id, netif );
if( index < 0 ){
return ERROR_CODE;
}
if( ERROR_OCCURRED( char_map_add( & networking_globals.netif_names, netif->name, 0, index ))){
netifs_exclude_index( & networking_globals.netifs, index );
return ERROR_CODE;
}
// printf( "\nloopback OK" );
// end of the static loopback initialization
// startup the loopback interface
if( ! netif->driver->phone ){
// printf( " connect?" );
netif->driver->phone = connect_to_service( netif->driver->service );
}
// printf( " connected" );
// TODO io, irq
ERROR_PROPAGATE( async_req_3_0( netif->driver->phone, NET_NETIF_PROBE, netif->id, 0, 0 ));
++ netif->driver->usage;
if( netif->nil ){
if( ! netif->nil->phone ){
netif->nil->phone = connect_to_service( netif->nil->service );
}
ERROR_PROPAGATE( async_req_2_0( netif->nil->phone, NET_NIL_DEVICE, netif->id, netif->driver->service ));
++ netif->nil->usage;
internet_service = netif->nil->service;
// printf( " OK" );
}else{
internet_service = netif->driver->service;
// printf( " none" );
}
if( ! netif->il->phone ){
// printf( " connect" );
netif->il->phone = connect_to_service( netif->il->service );
}
// TODO IL_BUNDLE
ERROR_PROPAGATE( async_req_2_0( netif->il->phone, NET_IL_DEVICE, netif->id, internet_service ));
++ netif->il->usage;
// TODO startup?
ERROR_PROPAGATE( async_req_1_0( netif->driver->phone, NET_NETIF_START, netif->id ));
// printf( "\n LO OK" );
return EOK;
}
task_id_t spawn( const char * fname ){
const char * argv[ 2 ];
task_id_t res;
// printf( "Spawning %s\n", fname );
argv[ 0 ] = fname;
argv[ 1 ] = NULL;
res = task_spawn( fname, argv );
if( res != 0 ){
/* Success */
usleep( 50000 );
}
return res;
}
int startup( void ){
ERROR_DECLARE;
// read configuration files
if( ERROR_OCCURRED( read_configuration())) return ERROR_CODE;
// start network interfaces and needed modules
// start_device( "/sbin/lo", "/sbin/dummy_link_layer" );
return EOK;
}
/** @}
*/