xNBA/src/net/ipv4.c

#include <string.h>
#include <stdint.h>
#include <byteswap.h>
#include <gpxe/in.h>


#include <ip.h>


#include <gpxe/if_ether.h>
#include <gpxe/pkbuff.h>
#include <gpxe/netdevice.h>
#include "../proto/uip/uip.h"

/** @file
 *
 * IPv4 protocol
 *
 * The gPXE IP stack is currently implemented on top of the uIP
 * protocol stack.  This file provides wrappers around uIP so that
 * higher-level protocol implementations do not need to talk directly
 * to uIP (which has a somewhat baroque API).
 *
 */

/** An IPv4 routing table entry */
struct ipv4_route {
	/** Network address */
	struct in_addr network;
	/** Subnet mask */
	struct in_addr netmask;
	/** Gateway address */
	struct in_addr gateway;
	/** Gateway device */
	struct in_addr gatewaydev;
};

enum {
	STATIC_SINGLE_NETDEV_ROUTE = 0,
	DEFAULT_ROUTE,
	NUM_ROUTES
};

/** IPv4 routing table */
static struct ipv4_route routing_table[NUM_ROUTES];

#define routing_table_end ( routing_table + NUM_ROUTES )

#if 0
/**
 * Set IP address
 *
 */
void set_ipaddr ( struct in_addr address ) {
	union {
		struct in_addr address;
		uint16_t uip_address[2];
	} u;

	u.address = address;
	uip_sethostaddr ( u.uip_address );
}

/**
 * Set netmask
 *
 */
void set_netmask ( struct in_addr address ) {
	union {
		struct in_addr address;
		uint16_t uip_address[2];
	} u;

	u.address = address;
	uip_setnetmask ( u.uip_address );
}

/**
 * Set default gateway
 *
 */
void set_gateway ( struct in_addr address ) {
	union {
		struct in_addr address;
		uint16_t uip_address[2];
	} u;

	u.address = address;
	uip_setdraddr ( u.uip_address );
}

/**
 * Run the TCP/IP stack
 *
 * Call this function in a loop in order to allow TCP/IP processing to
 * take place.  This call takes the stack through a single iteration;
 * it will typically be used in a loop such as
 *
 * @code
 *
 * struct tcp_connection *my_connection;
 * ...
 * tcp_connect ( my_connection );
 * while ( ! my_connection->finished ) {
 *   run_tcpip();
 * }
 *
 * @endcode
 *
 * where @c my_connection->finished is set by one of the connection's
 * #tcp_operations methods to indicate completion.
 */
void run_tcpip ( void ) {
	void *data;
	size_t len;
	uint16_t type;
	int i;
	
	if ( netdev_poll ( 1, &data, &len ) ) {
		/* We have data */
		memcpy ( uip_buf, data, len );
		uip_len = len;
		type = ntohs ( *( ( uint16_t * ) ( uip_buf + 12 ) ) );
		if ( type == UIP_ETHTYPE_ARP ) {
			uip_arp_arpin();
		} else {
			uip_arp_ipin();
			uip_input();
		}
		if ( uip_len > 0 )
			uip_transmit();
	} else {
		for ( i = 0 ; i < UIP_CONNS ; i++ ) {
			uip_periodic ( i );
			if ( uip_len > 0 )
				uip_transmit();
		}
	}
}
#endif

/**
 * Process incoming IP packets
 *
 * @v pkb		Packet buffer
 * @ret rc		Return status code
 *
 * This handles IP packets by handing them off to the uIP protocol
 * stack.
 */
static int ipv4_rx ( struct pk_buff *pkb ) {

	/* Transfer to uIP buffer.  Horrendously space-inefficient,
	 * but will do as a proof-of-concept for now.
	 */
	memcpy ( uip_buf, pkb->data, pkb_len ( pkb ) );

	/* Hand to uIP for processing */
	uip_input ();
	if ( uip_len > 0 ) {
		pkb_empty ( pkb );
		pkb_put ( pkb, uip_len );
		memcpy ( pkb->data, uip_buf, uip_len );
		if ( net_transmit ( pkb ) != 0 )
			free_pkb ( pkb );
	} else {
		free_pkb ( pkb );
	}
	return 0;
}

/**
 * Perform IP layer routing
 *
 * @v pkb	Packet buffer
 * @ret source	Network-layer source address
 * @ret dest	Network-layer destination address
 * @ret rc	Return status code
 */
static int ipv4_route ( const struct pk_buff *pkb,
			struct net_header *nethdr ) {
	struct iphdr *iphdr = pkb->data;
	struct in_addr *source = ( struct in_addr * ) nethdr->source_net_addr;
	struct in_addr *dest = ( struct in_addr * ) nethdr->dest_net_addr;
	struct ipv4_route *route;

	/* Route IP packet according to routing table */
	source->s_addr = INADDR_NONE;
	dest->s_addr = iphdr->dest.s_addr;
	for ( route = routing_table ; route < routing_table_end ; route++ ) {
		if ( ( dest->s_addr & route->netmask.s_addr )
		     == route->network.s_addr ) {
			source->s_addr = route->gatewaydev.s_addr;
			if ( route->gateway.s_addr )
				dest->s_addr = route->gateway.s_addr;
			break;
		}
	}

	/* Set broadcast and multicast flags as applicable */
	nethdr->dest_flags = 0;
	if ( dest->s_addr == htonl ( INADDR_BROADCAST ) ) {
		nethdr->dest_flags = NETADDR_FL_BROADCAST;
	} else if ( IN_MULTICAST ( dest->s_addr ) ) {
		nethdr->dest_flags = NETADDR_FL_MULTICAST;
	}

	return 0;
}

/** IPv4 protocol */
struct net_protocol ipv4_protocol = {
	.net_proto = ETH_P_IP,
	.net_addr_len = sizeof ( struct in_addr ),
	.rx = ipv4_rx,
	.route = ipv4_route,
};

NET_PROTOCOL ( ipv4_protocol );

/** IPv4 address for the static single net device */
struct net_address static_single_ipv4_address = {
	.net_protocol = &ipv4_protocol,
};

STATIC_SINGLE_NETDEV_ADDRESS ( static_single_ipv4_address );
Network API now allows for multiple network devices (although the implementation allows for only one, and does so without compromising on the efficiency of static allocation). Link-layer protocols are cleanly separated from the device drivers. Network-layer protocols are cleanly separated from individual network devices. Link-layer and network-layer protocols are cleanly separated from each other. 2006-04-24 15:38:53 +00:00			`#include <string.h>`
			`#include <stdint.h>`
			`#include <byteswap.h>`
			`#include <gpxe/in.h>`


			`#include <ip.h>`


			`#include <gpxe/if_ether.h>`
			`#include <gpxe/pkbuff.h>`
			`#include <gpxe/netdevice.h>`
			`#include "../proto/uip/uip.h"`

			`/** @file`
			`*`
			`* IPv4 protocol`
			`*`
			`* The gPXE IP stack is currently implemented on top of the uIP`
			`* protocol stack. This file provides wrappers around uIP so that`
			`* higher-level protocol implementations do not need to talk directly`
			`* to uIP (which has a somewhat baroque API).`
			`*`
			`*/`

			`/** An IPv4 routing table entry */`
			`struct ipv4_route {`
			`/** Network address */`
			`struct in_addr network;`
			`/** Subnet mask */`
			`struct in_addr netmask;`
			`/** Gateway address */`
			`struct in_addr gateway;`
			`/** Gateway device */`
			`struct in_addr gatewaydev;`
			`};`

			`enum {`
			`STATIC_SINGLE_NETDEV_ROUTE = 0,`
			`DEFAULT_ROUTE,`
			`NUM_ROUTES`
			`};`

			`/** IPv4 routing table */`
			`static struct ipv4_route routing_table[NUM_ROUTES];`

			`#define routing_table_end ( routing_table + NUM_ROUTES )`

			`#if 0`
			`/**`
			`* Set IP address`
			`*`
			`*/`
			`void set_ipaddr ( struct in_addr address ) {`
			`union {`
			`struct in_addr address;`
			`uint16_t uip_address[2];`
			`} u;`

			`u.address = address;`
			`uip_sethostaddr ( u.uip_address );`
			`}`

			`/**`
			`* Set netmask`
			`*`
			`*/`
			`void set_netmask ( struct in_addr address ) {`
			`union {`
			`struct in_addr address;`
			`uint16_t uip_address[2];`
			`} u;`

			`u.address = address;`
			`uip_setnetmask ( u.uip_address );`
			`}`

			`/**`
			`* Set default gateway`
			`*`
			`*/`
			`void set_gateway ( struct in_addr address ) {`
			`union {`
			`struct in_addr address;`
			`uint16_t uip_address[2];`
			`} u;`

			`u.address = address;`
			`uip_setdraddr ( u.uip_address );`
			`}`

			`/**`
			`* Run the TCP/IP stack`
			`*`
			`* Call this function in a loop in order to allow TCP/IP processing to`
			`* take place. This call takes the stack through a single iteration;`
			`* it will typically be used in a loop such as`
			`*`
			`* @code`
			`*`
			`* struct tcp_connection *my_connection;`
			`* ...`
			`* tcp_connect ( my_connection );`
			`* while ( ! my_connection->finished ) {`
			`* run_tcpip();`
			`* }`
			`*`
			`* @endcode`
			`*`
			`* where @c my_connection->finished is set by one of the connection's`
			`* #tcp_operations methods to indicate completion.`
			`*/`
			`void run_tcpip ( void ) {`
			`void *data;`
			`size_t len;`
			`uint16_t type;`
			`int i;`

			`if ( netdev_poll ( 1, &data, &len ) ) {`
			`/* We have data */`
			`memcpy ( uip_buf, data, len );`
			`uip_len = len;`
			`type = ntohs ( ( ( uint16_t ) ( uip_buf + 12 ) ) );`
			`if ( type == UIP_ETHTYPE_ARP ) {`
			`uip_arp_arpin();`
			`} else {`
			`uip_arp_ipin();`
			`uip_input();`
			`}`
			`if ( uip_len > 0 )`
			`uip_transmit();`
			`} else {`
			`for ( i = 0 ; i < UIP_CONNS ; i++ ) {`
			`uip_periodic ( i );`
			`if ( uip_len > 0 )`
			`uip_transmit();`
			`}`
			`}`
			`}`
			`#endif`

			`/**`
			`* Process incoming IP packets`
			`*`
			`* @v pkb Packet buffer`
			`* @ret rc Return status code`
			`*`
			`* This handles IP packets by handing them off to the uIP protocol`
			`* stack.`
			`*/`
			`static int ipv4_rx ( struct pk_buff *pkb ) {`

			`/* Transfer to uIP buffer. Horrendously space-inefficient,`
			`* but will do as a proof-of-concept for now.`
			`*/`
			`memcpy ( uip_buf, pkb->data, pkb_len ( pkb ) );`

			`/* Hand to uIP for processing */`
			`uip_input ();`
			`if ( uip_len > 0 ) {`
			`pkb_empty ( pkb );`
			`pkb_put ( pkb, uip_len );`
			`memcpy ( pkb->data, uip_buf, uip_len );`
			`if ( net_transmit ( pkb ) != 0 )`
			`free_pkb ( pkb );`
			`} else {`
			`free_pkb ( pkb );`
			`}`
			`return 0;`
			`}`

			`/**`
			`* Perform IP layer routing`
			`*`
			`* @v pkb Packet buffer`
			`* @ret source Network-layer source address`
			`* @ret dest Network-layer destination address`
			`* @ret rc Return status code`
			`*/`
			`static int ipv4_route ( const struct pk_buff *pkb,`
			`struct net_header *nethdr ) {`
			`struct iphdr *iphdr = pkb->data;`
			`struct in_addr source = ( struct in_addr ) nethdr->source_net_addr;`
			`struct in_addr dest = ( struct in_addr ) nethdr->dest_net_addr;`
			`struct ipv4_route *route;`

			`/* Route IP packet according to routing table */`
			`source->s_addr = INADDR_NONE;`
			`dest->s_addr = iphdr->dest.s_addr;`
			`for ( route = routing_table ; route < routing_table_end ; route++ ) {`
			`if ( ( dest->s_addr & route->netmask.s_addr )`
			`== route->network.s_addr ) {`
			`source->s_addr = route->gatewaydev.s_addr;`
			`if ( route->gateway.s_addr )`
			`dest->s_addr = route->gateway.s_addr;`
			`break;`
			`}`
			`}`

			`/* Set broadcast and multicast flags as applicable */`
			`nethdr->dest_flags = 0;`
			`if ( dest->s_addr == htonl ( INADDR_BROADCAST ) ) {`
			`nethdr->dest_flags = NETADDR_FL_BROADCAST;`
			`} else if ( IN_MULTICAST ( dest->s_addr ) ) {`
			`nethdr->dest_flags = NETADDR_FL_MULTICAST;`
			`}`

			`return 0;`
			`}`

			`/** IPv4 protocol */`
			`struct net_protocol ipv4_protocol = {`
			`.net_proto = ETH_P_IP,`
			`.net_addr_len = sizeof ( struct in_addr ),`
			`.rx = ipv4_rx,`
			`.route = ipv4_route,`
			`};`

			`NET_PROTOCOL ( ipv4_protocol );`

			`/** IPv4 address for the static single net device */`
			`struct net_address static_single_ipv4_address = {`
			`.net_protocol = &ipv4_protocol,`
			`};`

			`STATIC_SINGLE_NETDEV_ADDRESS ( static_single_ipv4_address );`