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/*

 * 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 eth

 *  @{

 */

/** @file

 *  Ethernet module implementation.

 *  @see eth.h

 */

#include <async.h>

#include <malloc.h>

#include <stdio.h>

#include <string.h>

#include <ipc/ipc.h>

#include <ipc/services.h>

#include "../../err.h"

#include "../../messages.h"

#include "../../modules.h"

#include "../../include/byteorder.h"

#include "../../include/crc.h"

#include "../../include/ethernet_lsap.h"

#include "../../include/ethernet_protocols.h"

#include "../../include/protocol_map.h"

#include "../../netif/device.h"

#include "../../structures/measured_strings.h"

#include "../../structures/packet/packet.h"

#include "../../structures/packet/packet_client.h"

#include "eth.h"

#include "eth_header.h"

//#include "eth_messages.h"

#include "eth_module.h"

#define ETH_PREFIX		( sizeof( eth_header_t ) + sizeof( eth_header_lsap_t ) + sizeof( eth_header_snap_t ))

#define ETH_SUFFIX		sizeof( eth_fcs_t )

#define ETH_MAX_CONTENT 1500

#define ETH_MIN_CONTENT 46

/** Returns the device identifier message parameter.

 */

#define IPC_GET_DEVICE( call )		( device_id_t ) IPC_GET_ARG1( * call )

/** Returns the packet identifier message parameter.

 */

#define IPC_GET_PACKET( call )		( packet_id_t ) IPC_GET_ARG2( * call )

/** Returns the protocol service message parameter.

 */

#define IPC_GET_PROTO( call )		( services_t ) IPC_GET_ARG1( * call )

/** Returns the device driver service message parameter.

 */

#define IPC_GET_SERVICE( call )		( services_t ) IPC_GET_ARG2( * call )

#define IPC_GET_MTU( call )			( size_t ) IPC_GET_ARG3( * call )

#define IPC_GET_PHONE( call )		( int ) IPC_GET_ARG5( * call )

#define IPC_SET_ADDR( answer )		(( size_t * ) & IPC_GET_ARG1( * answer ))

#define IPC_SET_PREFIX( answer )	(( size_t * ) & IPC_GET_ARG2( * answer ))

#define IPC_SET_CONTENT( answer )	(( size_t * ) & IPC_GET_ARG3( * answer ))

#define IPC_SET_SUFFIX( answer )	(( size_t * ) & IPC_GET_ARG4( * answer ))

typedef enum eth_addr_type	eth_addr_type_t;

typedef eth_addr_type_t *	eth_addr_type_ref;

enum eth_addr_type{

	ETH_LOCAL_ADDR,

	ETH_BROADCAST_ADDR

};

/** Ethernet global data.

 */

eth_globals_t	eth_globals;

/** Processes IPC messages from the registered device driver modules in an infinite loop.

 *  @param iid The message identifier. Input parameter.

 *  @param icall The message parameters. Input/output parameter.

 */

void	eth_receiver( ipc_callid_t iid, ipc_call_t * icall );

DEVICE_MAP_IMPLEMENT( eth_devices, eth_device_t )

INT_MAP_IMPLEMENT( eth_protos, eth_proto_t )

int	eth_device_message( device_id_t device_id, services_t service, size_t mtu );

int	eth_receive_message( device_id_t device_id, packet_t packet );

int	eth_packet_space_message( device_id_t device_id, size_t * addr_len, size_t * prefix, size_t * content, size_t * suffix );

int	eth_addr_message( device_id_t device_id, eth_addr_type_t type, measured_string_ref * address );

int	eth_register_message( services_t service, int phone );

int	eth_send_message( device_id_t device_id, packet_t packet, services_t sender );

int	eth_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count );

void	eth_receiver( ipc_callid_t iid, ipc_call_t * icall );

eth_proto_ref	eth_proccess_packet( int dummy, packet_t packet );

int	eth_prepare_packet( int dummy, packet_t packet, uint8_t * src_addr, int ethertype );

int eth_initialize( void ){

	ERROR_DECLARE;

	rwlock_initialize( & eth_globals.devices_lock );

	rwlock_initialize( & eth_globals.protos_lock );

	rwlock_write_lock( & eth_globals.devices_lock );

	rwlock_write_lock( & eth_globals.protos_lock );

	eth_globals.broadcast_addr = measured_string_create_bulk( "\xFF\xFF\xFF\xFF\xFF\xFF", CONVERT_SIZE( uint8_t, char, ETH_ADDR ));

	if( ! eth_globals.broadcast_addr ) return ENOMEM;

	ERROR_PROPAGATE( eth_devices_initialize( & eth_globals.devices ));

	if( ERROR_OCCURRED( eth_protos_initialize( & eth_globals.protos ))){

		eth_devices_destroy( & eth_globals.devices );

		return ERROR_CODE;

	}

	rwlock_write_unlock( & eth_globals.protos_lock );

	rwlock_write_unlock( & eth_globals.devices_lock );

	return EOK;

}

int eth_device_message( device_id_t device_id, services_t service, size_t mtu ){

	ERROR_DECLARE;

	aid_t			message;

	ipc_call_t		answer;

	eth_device_ref	device;

	int				result;

	rwlock_write_lock( & eth_globals.devices_lock );

	// an existing device?

	device = eth_devices_find( & eth_globals.devices, device_id );

	if( device ){

		if( device->service == service ){

			// update mtu

			device->mtu = mtu;

			rwlock_write_unlock( & eth_globals.devices_lock );

			return EOK;

		}else{

			rwlock_write_unlock( & eth_globals.devices_lock );

			return EEXIST;

		}

	}else{

		// create a new device

		device = ( eth_device_ref ) malloc( sizeof( eth_device_t ));

		if( ! device ) return ENOMEM;

		device->device_id = device_id;

		device->service = service;

		device->mtu = mtu;

		// TODO get dummy setting

		device->dummy = 0;

		// bind the device driver

		device->phone = bind_service( device->service, device->device_id, SERVICE_ETHERNET, 0, eth_receiver );

		// get hardware address

		message = async_send_1( device->phone, NET_NETIF_GET_ADDR, device->device_id, & answer );

		if( ERROR_OCCURRED( measured_strings_return( device->phone, & device->addr, & device->addr_data, 1 ))){

			rwlock_write_unlock( & eth_globals.devices_lock );

			free( device );

			async_wait_for( message, NULL );

			return ERROR_CODE;

		}

		async_wait_for( message, ( ipcarg_t * ) & result );

		if( ERROR_OCCURRED( result )){

			rwlock_write_unlock( & eth_globals.devices_lock );

			free( device->addr );

			free( device->addr_data );

			free( device );

			return ERROR_CODE;

		}

		// add to the cache

		if( ERROR_OCCURRED( eth_devices_add( & eth_globals.devices, device->device_id, device ))){

			rwlock_write_unlock( & eth_globals.devices_lock );

			free( device->addr );

			free( device->addr_data );

			free( device );

			return ERROR_CODE;

		}

	}

	rwlock_write_unlock( & eth_globals.devices_lock );

	return EOK;

}

eth_proto_ref eth_proccess_packet( int dummy, packet_t packet ){

	ERROR_DECLARE;

	eth_header_ex_ref	header;

	size_t				length;

	int					type;

	size_t				prefix;

	size_t				suffix;

	eth_fcs_ref			fcs;

	length = packet_get_data_length( packet );

	if( dummy ){

		packet_trim( packet, sizeof( eth_preamble_t ), 0 );

	}

	if( length <= sizeof( eth_header_t ) + ETH_MIN_CONTENT + ETH_SUFFIX ) return NULL;

	header = ( eth_header_ex_ref ) packet_get_data( packet );

	type = ntohs( header->header.ethertype );

	if( type >= ETH_MIN_PROTO ){

		// DIX Ethernet

		prefix = sizeof( eth_header_t );

		suffix = sizeof( eth_fcs_t );

		fcs = (( void * ) header ) + length - suffix;

	}else if( type <= ETH_MAX_CONTENT ){

		// translate "LSAP" values

		if(( header->lsap.dsap == ETH_LSAP_GLSAP ) && ( header->lsap.ssap == ETH_LSAP_GLSAP )){

			// raw packet

			// discard

			return NULL;

		}else if(( header->lsap.dsap == ETH_LSAP_SNAP ) && ( header->lsap.ssap == ETH_LSAP_SNAP )){

			// IEEE 802.3 + 802.2 + LSAP + SNAP

			// organization code not supported

			type = ntohs( header->snap.ethertype );

			prefix = sizeof( eth_header_t ) + sizeof( eth_header_lsap_t) + sizeof( eth_header_snap_t);

		}else{

			// IEEE 802.3 + 802.2 LSAP

			type = lsap_map( header->lsap.dsap );

			prefix = sizeof( eth_header_t ) + sizeof( eth_header_lsap_t);

		}

		suffix = ( type < ETH_MIN_CONTENT ) ? ETH_MIN_CONTENT - type : 0;

		fcs = (( void * ) header ) + prefix + type + suffix;

		suffix += length - prefix - type;

	}else{

		// invalid length/type, should not occurr

		return NULL;

	}

	if( dummy ){

		if(( ~ compute_crc32( ~ 0, & header->header.dest, ((( void * ) fcs ) - (( void * ) & header->header.dest )) * 8 )) != ntohl( * fcs )){

			return NULL;

		}

	}

	if( ERROR_OCCURRED( packet_set_addr( packet, header->header.src, header->header.dest, ETH_ADDR ))

	|| ERROR_OCCURRED( packet_trim( packet, prefix, suffix ))){

		return NULL;

	}

	return eth_protos_find( & eth_globals.protos, type );

}

int eth_receive_message( device_id_t device_id, packet_t packet ){

	eth_proto_ref	proto;

	packet_t		next;

	eth_device_ref	device;

	int				dummy;

	rwlock_read_lock( & eth_globals.devices_lock );

	device = eth_devices_find( & eth_globals.devices, device_id );

	if( ! device ){

		rwlock_read_unlock( & eth_globals.devices_lock );

		return ENOENT;

	}

	dummy = device->dummy;

	rwlock_read_unlock( & eth_globals.devices_lock );

	rwlock_read_lock( & eth_globals.protos_lock );

	do{

		next = pq_detach( packet );

		proto = eth_proccess_packet( dummy, packet );

		if( proto ){

			async_msg_2( proto->phone, NET_IL_RECEIVED, device_id, packet_get_id( packet ));

		}else{

			// drop invalid/unknown

			packet_release( eth_globals.networking_phone, packet_get_id( packet ));

		}

		packet = next;

	}while( packet );

	rwlock_read_unlock( & eth_globals.protos_lock );

	return EOK;

}

int eth_packet_space_message( device_id_t device_id, size_t * addr_len, size_t * prefix, size_t * content, size_t * suffix ){

	eth_device_ref	device;

	if( !( addr_len && prefix && content && suffix )) return EINVAL;

	rwlock_write_lock( & eth_globals.devices_lock );

	device = eth_devices_find( & eth_globals.devices, device_id );

	if( ! device ){

		rwlock_write_unlock( & eth_globals.devices_lock );

		return ENOENT;

	}

	* content = (  ETH_MAX_CONTENT > device->mtu ) ? device->mtu : ETH_MAX_CONTENT;

	rwlock_write_unlock( & eth_globals.devices_lock );

	* addr_len = ETH_ADDR;

	* prefix = ETH_PREFIX;

	* suffix = ETH_MIN_CONTENT + ETH_SUFFIX;

	return EOK;

}

int eth_addr_message( device_id_t device_id, eth_addr_type_t type, measured_string_ref * address ){

	eth_device_ref	device;

	if( ! address ) return EINVAL;

	if( type == ETH_BROADCAST_ADDR ){

		* address = eth_globals.broadcast_addr;

	}else{

		rwlock_write_lock( & eth_globals.devices_lock );

		device = eth_devices_find( & eth_globals.devices, device_id );

		if( ! device ){

			rwlock_write_unlock( & eth_globals.devices_lock );

			return ENOENT;

		}

		* address = device->addr;

		rwlock_write_unlock( & eth_globals.devices_lock );

	}

	return ( * address ) ? EOK : ENOENT;

}

int eth_register_message( services_t service, int phone ){

	ERROR_DECLARE;

	eth_proto_ref	proto;

	int				protocol;

	protocol = protocol_map( SERVICE_ETHERNET, service );

	if( ! protocol ) return ENOENT;

	rwlock_write_lock( & eth_globals.protos_lock );

	proto = eth_protos_find( & eth_globals.protos, protocol );

	if( proto ){

		proto->phone = phone;

		rwlock_write_unlock( & eth_globals.protos_lock );

		return EOK;

	}else{

		proto = ( eth_proto_ref ) malloc( sizeof( eth_proto_t ));

		if( ! proto ){

			rwlock_write_unlock( & eth_globals.protos_lock );

			return ENOMEM;

		}

		proto->service = service;

		proto->protocol = protocol;

		proto->phone = phone;

		if( ERROR_OCCURRED( eth_protos_add( & eth_globals.protos, protocol, proto ))){

			rwlock_write_unlock( & eth_globals.protos_lock );

			free( proto );

			return ERROR_CODE;

		}

	}

	rwlock_write_unlock( & eth_globals.protos_lock );

	return EOK;

}

int eth_prepare_packet( int dummy, packet_t packet, uint8_t * src_addr, int ethertype ){

	eth_header_ex_ref	header;

	eth_fcs_ref			fcs;

	uint8_t *			src;

	uint8_t *			dest;

	int					length;

	int					i;

	void *				padding;

	eth_preamble_ref	preamble;

	if( dummy ){

		preamble = PACKET_PREFIX( packet, eth_preamble_t );

		if( ! preamble ) return ENOMEM;

		for( i = 0; i < 7; ++ i ) preamble->preamble[ i ] = ETH_PREAMBLE;

		preamble->sfd = ETH_SFD;

	}

	header = PACKET_PREFIX( packet, eth_header_ex_t );

	if( ! header ) return ENOMEM;

	length = packet_get_addr( packet, & src, & dest );

	if( length < 0 ) return length;

	if( length < ETH_ADDR ) return EINVAL;

	memcpy( header->header.src, src_addr, ETH_ADDR );

	memcpy( & header->header.dest, dest, ETH_ADDR );

	length = packet_get_data_length( packet );

	if( length > ETH_MAX_CONTENT ) return EINVAL;

	if( length < ETH_MIN_CONTENT ){

		padding = packet_suffix( packet, ETH_MIN_CONTENT - length );

		if( ! padding ) return ENOMEM;

		memset( padding, 0, ETH_MIN_CONTENT - length );

	}

	header->header.ethertype = htons( length );

	header->lsap.dsap = 0xAA;

	header->lsap.ssap = header->lsap.dsap;

	header->lsap.ctrl = 0;

	for( i = 0; i < 3; ++ i ) header->snap.proto[ i ] = 0;

	header->snap.ethertype = ethertype;

	if( dummy ){

		fcs = PACKET_SUFFIX( packet, eth_fcs_t );

		if( ! fcs ) return ENOMEM;

		* fcs = htonl( ~ compute_crc32( ~ 0, & header->header.dest, ((( void * ) fcs ) - (( void * ) & header->header.dest )) * 8 ));

	}

	return EOK;

}

int eth_send_message( device_id_t device_id, packet_t packet, services_t sender ){

	ERROR_DECLARE;

	eth_device_ref		device;

	packet_t			next;

	packet_t			tmp;

	int					ethertype;

	ethertype = htons( protocol_map( SERVICE_ETHERNET, sender ));

	if( ! ethertype ){

		packet_release( eth_globals.networking_phone, packet_get_id( packet ));

		return EINVAL;

	}

	rwlock_read_lock( & eth_globals.devices_lock );

	device = eth_devices_find( & eth_globals.devices, device_id );

	if( ! device ){

		rwlock_read_unlock( & eth_globals.devices_lock );

		return ENOENT;

	}

	// proccess packet queue

	next = packet;

	do{

		if( ERROR_OCCURRED( eth_prepare_packet( device->dummy, next, ( uint8_t * ) device->addr->value, ethertype ))){

			// release invalid packet

			tmp = pq_detach( next );

			packet_release( eth_globals.networking_phone, packet_get_id( next ));

			next = tmp;

		}else{

			next = pq_next( next );

		}

	}while( next );

	// send packet queue

	async_msg_2( device->phone, NET_NETIF_SEND, device_id, packet_get_id( packet ));

	rwlock_read_unlock( & eth_globals.devices_lock );

	return EOK;

}

int eth_message( ipc_callid_t callid, ipc_call_t * call, ipc_call_t * answer, int * answer_count ){

	ERROR_DECLARE;

	measured_string_ref	address;

	packet_t			packet;

	* answer_count = 0;

	switch( IPC_GET_METHOD( * call )){

		case IPC_M_PHONE_HUNGUP:

			return EOK;

		case NET_NIL_DEVICE:

			return eth_device_message( IPC_GET_DEVICE( call ), IPC_GET_SERVICE( call ), IPC_GET_MTU( call ));

		case NET_NIL_SEND:

			ERROR_PROPAGATE( packet_translate( eth_globals.networking_phone, & packet, IPC_GET_PACKET( call )));

			return eth_send_message( IPC_GET_DEVICE( call ), packet, IPC_GET_SERVICE( call ));

		case NET_NIL_PACKET_SPACE:

			ERROR_PROPAGATE( eth_packet_space_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_NIL_ADDR:

			rwlock_read_lock( & eth_globals.devices_lock );

			if( ! ERROR_OCCURRED( eth_addr_message( IPC_GET_DEVICE( call ), ETH_LOCAL_ADDR, & address ))){

				 ERROR_CODE = measured_strings_reply( address, 1 );

			}

			rwlock_read_unlock( & eth_globals.devices_lock );

			return ERROR_CODE;

		case NET_NIL_BROADCAST_ADDR:

			rwlock_read_lock( & eth_globals.devices_lock );

			if( ! ERROR_OCCURRED( eth_addr_message( IPC_GET_DEVICE( call ), ETH_BROADCAST_ADDR, & address ))){

				 ERROR_CODE = measured_strings_reply( address, 1 );

			}

			rwlock_read_unlock( & eth_globals.devices_lock );

			return ERROR_CODE;

		case IPC_M_CONNECT_TO_ME:

			return eth_register_message( IPC_GET_PROTO( call ), IPC_GET_PHONE( call ));

	}

	return ENOTSUP;

}

void eth_receiver( ipc_callid_t iid, ipc_call_t * icall ){

	ERROR_DECLARE;

	packet_t		packet;

	while( true ){

		switch( IPC_GET_METHOD( * icall )){

			case NET_NIL_DEVICE_STATE:

				//TODO clear device if off?

				break;

			case NET_NIL_RECEIVED:

				if( ! ERROR_OCCURRED( packet_translate( eth_globals.networking_phone, & packet, IPC_GET_PACKET( icall )))){

					ERROR_CODE = eth_receive_message( IPC_GET_DEVICE( icall ), packet );

				}

				ipc_answer_0( iid, ERROR_CODE );

				break;

			default:

				ipc_answer_0( iid, ENOTSUP );

		}

		iid = async_get_call( icall );

	}

}

/** @}

 */