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mirror of https://github.com/xcat2/xNBA.git synced 2024-12-14 07:11:32 +00:00

Simplify TX datapath.

This commit is contained in:
Michael Brown 2006-06-16 00:19:46 +00:00
parent cce2e47ff4
commit bbd9e28061
9 changed files with 279 additions and 456 deletions

View File

@ -8,11 +8,12 @@
*/
struct net_device;
struct net_header;
struct ll_header;
struct net_protocol;
extern int arp_resolve ( struct net_device *netdev,
const struct net_header *nethdr,
struct ll_header *llhdr );
struct net_protocol *net_protocol,
const void *dest_net_addr,
const void *source_net_addr,
void *dest_ll_addr );
#endif /* _GPXE_ARP_H */

View File

@ -11,4 +11,10 @@ struct net_protocol;
extern struct net_protocol ipv4_protocol;
extern int add_ipv4_address ( struct net_device *netdev,
struct in_addr address, struct in_addr netmask,
struct in_addr gateway );
extern void del_ipv4_address ( struct net_device *netdev );
extern int ipv4_uip_transmit ( struct pk_buff *pkb );
#endif /* _GPXE_IP_H */

View File

@ -86,22 +86,6 @@ struct ll_header {
struct net_protocol {
/** Protocol name */
const char *name;
/**
* Perform network-layer routing
*
* @v pkb Packet buffer
* @v nethdr Generic network-layer header
* @ret rc Return status code
*
* This method should fill in the network header with enough
* information to allow the link layer to route the packet.
*
* For example, in the case of IPv4, this method should fill
* in the IP addresses of the local adapter and the next hop
* destination (e.g. the gateway).
*/
int ( * route ) ( const struct pk_buff *pkb,
struct net_header *nethdr );
/**
* Process received packet
*
@ -141,36 +125,21 @@ struct ll_protocol {
/** Protocol name */
const char *name;
/**
* Perform link-layer routing
* Transmit network-layer packet via network device
*
* @v netdev Network device
* @v nethdr Generic network-layer header
* @ret llhdr Generic link-layer header
* @ret rc Return status code
*
* This method should construct the generic link-layer header
* based on the generic network-layer header.
* @v pkb Packet buffer
* @v netdev Network device
* @v net_protocol Network-layer protocol
* @v ll_dest Link-layer destination address
* @ret rc Return status code
*
* If a link-layer header cannot be constructed (e.g. because
* of a missing ARP cache entry), then this method should
* return an error (after transmitting an ARP request, if
* applicable).
* This method should prepend in the link-layer header
* (e.g. the Ethernet DIX header) and transmit the packet.
*/
int ( * route ) ( struct net_device *netdev,
const struct net_header *nethdr,
struct ll_header *llhdr );
/**
* Fill media-specific link-layer header
*
* @v llhdr Generic link-layer header
* @v pkb Packet buffer
*
* This method should fill in the link-layer header in the
* packet buffer based on information in the generic
* link-layer header.
*/
void ( * fill_llh ) ( const struct ll_header *llhdr,
struct pk_buff *pkb );
int ( * transmit ) ( struct pk_buff *pkb, struct net_device *netdev,
struct net_protocol *net_protocol,
const void *ll_dest );
/**
* Parse media-specific link-layer header
*
@ -204,8 +173,8 @@ struct ll_protocol {
uint16_t ll_proto;
/** Link-layer address length */
uint8_t ll_addr_len;
/** Link-layer header length */
uint8_t ll_header_len;
/** Link-layer broadcast address */
const uint8_t *ll_broadcast;
};
/**
@ -288,31 +257,6 @@ extern struct net_device static_single_netdev;
static_single_netdev.priv = priv_data; \
&static_single_netdev; } )
/**
* Register network device
*
* @v netdev Network device
* @ret rc Return status code
*
* Adds the network device to the list of network devices.
*/
static inline int
register_netdev ( struct net_device *netdev __attribute__ (( unused )) ) {
return 0;
}
/**
* Unregister network device
*
* @v netdev Network device
*
* Removes the network device from the list of network devices.
*/
static inline void
unregister_netdev ( struct net_device *netdev __attribute__ (( unused )) ) {
/* Nothing to do */
}
/**
* Free network device
*
@ -339,6 +283,27 @@ static inline int netdev_transmit ( struct net_device *netdev,
return netdev->transmit ( netdev, pkb );
}
/**
* Transmit network-layer packet
*
* @v pkb Packet buffer
* @v netdev Network device
* @v net_protocol Network-layer protocol
* @v ll_dest Destination link-layer address
* @ret rc Return status code
*
* Prepends link-layer headers to the packet buffer and transmits the
* packet via the specified network device. This function takes
* ownership of the packet buffer.
*/
static inline int net_transmit ( struct pk_buff *pkb,
struct net_device *netdev,
struct net_protocol *net_protocol,
const void *ll_dest ) {
return netdev->ll_protocol->transmit ( pkb, netdev, net_protocol,
ll_dest );
}
/**
* Register a link-layer protocol
*
@ -363,14 +328,14 @@ static inline int netdev_transmit ( struct net_device *netdev,
#define STATIC_SINGLE_NETDEV_ADDRESS( address ) \
struct net_address address __table ( sgl_netdev_addresses, 01 )
extern int register_netdev ( struct net_device *netdev );
extern void unregister_netdev ( struct net_device *netdev );
extern void netdev_rx ( struct net_device *netdev, struct pk_buff *pkb );
extern struct net_protocol *find_net_protocol ( uint16_t net_proto );
extern struct net_device *
find_netdev_by_net_addr ( struct net_protocol *net_protocol, void *net_addr );
extern int net_transmit_via ( struct pk_buff *pkb, struct net_device *netdev );
extern int net_transmit ( struct pk_buff *pkb );
extern int net_poll ( void );
extern struct pk_buff * net_rx_dequeue ( void );
extern int net_rx_process ( struct pk_buff *pkb );

View File

@ -24,6 +24,7 @@
#include <byteswap.h>
#include <gpxe/list.h>
#include <gpxe/if_ether.h>
#include <gpxe/ethernet.h>
#include <gpxe/pkbuff.h>
#include <gpxe/uaccess.h>
#include <gpxe/ata.h>
@ -116,7 +117,7 @@ static int aoe_send_command ( struct aoe_session *aoe ) {
/* Send packet */
start_timer ( &aoe->timer );
return net_transmit_via ( pkb, aoe->netdev );
return net_transmit ( pkb, aoe->netdev, &aoe_protocol, aoe->target );
}
/**
@ -251,38 +252,11 @@ static int aoe_rx ( struct pk_buff *pkb ) {
return rc;
}
/**
* Perform AoE network-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 aoe_route ( const struct pk_buff *pkb __unused,
struct net_header *nethdr ) {
struct aoehdr *aoehdr = pkb->data;
struct aoe_session *aoe;
list_for_each_entry ( aoe, &aoe_sessions, list ) {
if ( ( ntohs ( aoehdr->major ) == aoe->major ) &&
( aoehdr->minor == aoe->minor ) ) {
nethdr->flags = PKT_FL_RAW_ADDR;
memcpy ( nethdr->dest_net_addr, aoe->target,
sizeof ( aoe->target ) );
return 0;
}
}
return -EHOSTUNREACH;
}
/** AoE protocol */
struct net_protocol aoe_protocol = {
.name = "AoE",
.net_proto = htons ( ETH_P_AOE ),
.rx_process = aoe_rx,
.route = aoe_route,
};
NET_PROTOCOL ( aoe_protocol );
@ -293,7 +267,8 @@ NET_PROTOCOL ( aoe_protocol );
* @v aoe AoE session
*/
void aoe_open ( struct aoe_session *aoe ) {
memset ( aoe->target, 0xff, sizeof ( aoe->target ) );
memcpy ( aoe->target, ethernet_protocol.ll_broadcast,
sizeof ( aoe->target ) );
aoe->tag = AOE_TAG_MAGIC;
aoe->timer.expired = aoe_timer_expired;
list_add ( &aoe->list, &aoe_sessions );

View File

@ -92,42 +92,42 @@ arp_find_entry ( struct ll_protocol *ll_protocol,
* Look up media-specific link-layer address in the ARP cache
*
* @v netdev Network device
* @v nethdr Generic network-layer header
* @ret llhdr Generic link-layer header
* @v net_protocol Network-layer protocol
* @v dest_net_addr Destination network-layer address
* @v source_net_addr Source network-layer address
* @ret dest_ll_addr Destination link layer address
* @ret rc Return status code
*
* This function will use the ARP cache to look up the link-layer
* address for the link-layer protocol specified in @c llhdr and the
* network-layer protocol and address as specified in @c nethdr. If
* address for the link-layer protocol associated with the network
* device and the given network-layer protocol and addresses. If
* found, the destination link-layer address will be filled in in @c
* llhdr.
* dest_ll_addr.
*
* If no address is found in the ARP cache, an ARP request will be
* transmitted on the specified network device and -ENOENT will be
* returned.
*/
int arp_resolve ( struct net_device *netdev, const struct net_header *nethdr,
struct ll_header *llhdr ) {
struct net_protocol *net_protocol = nethdr->net_protocol;
struct ll_protocol *ll_protocol = llhdr->ll_protocol;
int arp_resolve ( struct net_device *netdev, struct net_protocol *net_protocol,
const void *dest_net_addr, const void *source_net_addr,
void *dest_ll_addr ) {
struct ll_protocol *ll_protocol = netdev->ll_protocol;
const struct arp_entry *arp;
struct pk_buff *pkb;
struct arphdr *arphdr;
int rc;
/* Look for existing entry in ARP table */
arp = arp_find_entry ( ll_protocol, net_protocol,
nethdr->dest_net_addr );
arp = arp_find_entry ( ll_protocol, net_protocol, dest_net_addr );
if ( arp ) {
DBG ( "ARP cache hit: %s %s => %s %s\n",
net_protocol->name, net_protocol->ntoa ( arp->net_addr ),
ll_protocol->name, ll_protocol->ntoa ( arp->ll_addr ) );
memcpy ( llhdr->dest_ll_addr, arp->ll_addr,
sizeof ( llhdr->dest_ll_addr ) );
memcpy ( dest_ll_addr, arp->ll_addr, ll_protocol->ll_addr_len);
return 0;
}
DBG ( "ARP cache miss: %s %s\n", net_protocol->name,
net_protocol->ntoa ( nethdr->dest_net_addr ) );
net_protocol->ntoa ( dest_net_addr ) );
/* Allocate ARP packet */
pkb = alloc_pkb ( MAX_LL_HEADER_LEN + sizeof ( *arphdr ) +
@ -145,16 +145,17 @@ int arp_resolve ( struct net_device *netdev, const struct net_header *nethdr,
arphdr->ar_pln = net_protocol->net_addr_len;
arphdr->ar_op = htons ( ARPOP_REQUEST );
memcpy ( pkb_put ( pkb, ll_protocol->ll_addr_len ),
llhdr->source_ll_addr, ll_protocol->ll_addr_len );
netdev->ll_addr, ll_protocol->ll_addr_len );
memcpy ( pkb_put ( pkb, net_protocol->net_addr_len ),
nethdr->source_net_addr, net_protocol->net_addr_len );
source_net_addr, net_protocol->net_addr_len );
memset ( pkb_put ( pkb, ll_protocol->ll_addr_len ),
0, ll_protocol->ll_addr_len );
memcpy ( pkb_put ( pkb, net_protocol->net_addr_len ),
nethdr->dest_net_addr, net_protocol->net_addr_len );
dest_net_addr, net_protocol->net_addr_len );
/* Transmit ARP request */
if ( ( rc = net_transmit_via ( pkb, netdev ) ) != 0 )
if ( ( rc = net_transmit ( pkb, netdev, &arp_protocol,
ll_protocol->ll_broadcast ) ) != 0 )
return rc;
return -ENOENT;
@ -235,10 +236,10 @@ static int arp_rx ( struct pk_buff *pkb ) {
arphdr->ar_op = htons ( ARPOP_REPLY );
memswap ( arp_sender_ha ( arphdr ), arp_target_ha ( arphdr ),
arphdr->ar_hln + arphdr->ar_pln );
memcpy ( arp_target_ha ( arphdr ), netdev->ll_addr, arphdr->ar_hln );
memcpy ( arp_sender_ha ( arphdr ), netdev->ll_addr, arphdr->ar_hln );
/* Send reply */
net_transmit_via ( pkb, netdev );
net_transmit ( pkb, netdev, &arp_protocol, arp_target_ha (arphdr ) );
pkb = NULL;
done:
@ -246,29 +247,6 @@ static int arp_rx ( struct pk_buff *pkb ) {
return 0;
}
/**
* Perform ARP network-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 arp_route ( const struct pk_buff *pkb,
struct net_header *nethdr ) {
struct arphdr *arphdr = pkb->data;
memcpy ( nethdr->source_net_addr, arp_sender_ha ( arphdr ),
arphdr->ar_hln );
memcpy ( nethdr->dest_net_addr, arp_target_ha ( arphdr ),
arphdr->ar_hln );
nethdr->flags = PKT_FL_RAW_ADDR;
if ( arphdr->ar_op == htons ( ARPOP_REQUEST ) )
nethdr->flags |= PKT_FL_BROADCAST;
return 0;
}
/**
* Transcribe ARP address
*
@ -287,7 +265,6 @@ struct net_protocol arp_protocol = {
.name = "ARP",
.net_proto = htons ( ETH_P_ARP ),
.rx_process = arp_rx,
.route = arp_route,
.ntoa = arp_ntoa,
};

View File

@ -25,7 +25,6 @@
#include <gpxe/if_ether.h>
#include <gpxe/netdevice.h>
#include <gpxe/pkbuff.h>
#include <gpxe/arp.h>
#include <gpxe/ethernet.h>
/** @file
@ -38,70 +37,24 @@
static uint8_t eth_broadcast[ETH_ALEN] = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
/**
* Perform Ethernet routing
* Transmit Ethernet packet
*
* @v nethdr Generic network-layer header
* @ret llhdr Generic link-layer header
* @ret rc Return status code
* @v pkb Packet buffer
* @v netdev Network device
* @v net_protocol Network-layer protocol
* @v ll_dest Link-layer destination address
*
* Constructs the generic link-layer header based on the generic
* network-layer header, i.e. maps network-layer addresses (e.g. IPv4
* addresses) to MAC addresses.
*
* If the destination MAC address cannot be determined, an ARP request
* is sent for the requested network-layer address and -ENOENT is
* returned.
* Prepends the Ethernet link-layer header and transmits the packet.
*/
static int eth_route ( struct net_device *netdev,
const struct net_header *nethdr,
struct ll_header *llhdr ) {
int rc;
static int eth_transmit ( struct pk_buff *pkb, struct net_device *netdev,
struct net_protocol *net_protocol,
const void *ll_dest ) {
struct ethhdr *ethhdr = pkb_push ( pkb, ETH_HLEN );
/* Fill in the easy bits */
llhdr->net_proto = nethdr->net_protocol->net_proto;
memcpy ( llhdr->source_ll_addr, netdev->ll_addr, ETH_ALEN );
/* Work out the destination MAC address */
if ( nethdr->flags & PKT_FL_BROADCAST ) {
memcpy ( llhdr->dest_ll_addr, eth_broadcast, ETH_ALEN );
} else if ( nethdr->flags & PKT_FL_RAW_ADDR ) {
memcpy ( llhdr->dest_ll_addr, nethdr->dest_net_addr, ETH_ALEN);
} else if ( nethdr->flags & PKT_FL_MULTICAST ) {
/* IP multicast is a special case; there exists a
* direct mapping from IP address to MAC address
*/
assert ( nethdr->net_protocol->net_proto == htons(ETH_P_IP) );
llhdr->dest_ll_addr[0] = 0x01;
llhdr->dest_ll_addr[1] = 0x00;
llhdr->dest_ll_addr[2] = 0x5e;
llhdr->dest_ll_addr[3] = nethdr->dest_net_addr[1] & 0x7f;
llhdr->dest_ll_addr[4] = nethdr->dest_net_addr[2];
llhdr->dest_ll_addr[5] = nethdr->dest_net_addr[3];
} else {
/* Otherwise, look up the address using ARP */
if ( ( rc = arp_resolve ( netdev, nethdr, llhdr ) ) != 0 )
return rc;
}
return 0;
}
/**
* Fill in Ethernet link-layer header
*
* @v pkb Packet buffer
* @v llhdr Generic link-layer header
*
* Fills in the Ethernet link-layer header in the packet buffer based
* on information in the generic link-layer header.
*/
static void eth_fill_llh ( const struct ll_header *llhdr,
struct pk_buff *pkb ) {
struct ethhdr *ethhdr = pkb->data;
memcpy ( ethhdr->h_dest, llhdr->dest_ll_addr, ETH_ALEN );
memcpy ( ethhdr->h_source, llhdr->source_ll_addr, ETH_ALEN );
ethhdr->h_protocol = llhdr->net_proto;
memcpy ( ethhdr->h_dest, ll_dest, ETH_ALEN );
memcpy ( ethhdr->h_source, netdev->ll_addr, ETH_ALEN );
ethhdr->h_protocol = net_protocol->net_proto;
return netdev_transmit ( netdev, pkb );
}
/**
@ -138,7 +91,7 @@ static void eth_parse_llh ( const struct pk_buff *pkb,
*/
static const char * eth_ntoa ( const void *ll_addr ) {
static char buf[18]; /* "00:00:00:00:00:00" */
uint8_t *eth_addr = ll_addr;
const uint8_t *eth_addr = ll_addr;
sprintf ( buf, "%02x:%02x:%02x:%02x:%02x:%02x",
eth_addr[0], eth_addr[1], eth_addr[2],
@ -148,14 +101,13 @@ static const char * eth_ntoa ( const void *ll_addr ) {
/** Ethernet protocol */
struct ll_protocol ethernet_protocol = {
.name = "Ethernet",
.ll_proto = htons ( ARPHRD_ETHER ),
.ll_addr_len = ETH_ALEN,
.ll_header_len = ETH_HLEN,
.route = eth_route,
.fill_llh = eth_fill_llh,
.parse_llh = eth_parse_llh,
.ntoa = eth_ntoa,
.name = "Ethernet",
.ll_proto = htons ( ARPHRD_ETHER ),
.ll_addr_len = ETH_ALEN,
.ll_broadcast = eth_broadcast,
.transmit = eth_transmit,
.parse_llh = eth_parse_llh,
.ntoa = eth_ntoa,
};
LL_PROTOCOL ( ethernet_protocol );

View File

@ -2,9 +2,11 @@
#include <stdint.h>
#include <errno.h>
#include <byteswap.h>
#include <malloc.h>
#include <vsprintf.h>
#include <gpxe/list.h>
#include <gpxe/in.h>
#include <gpxe/arp.h>
#include <ip.h>
@ -13,6 +15,7 @@
#include <gpxe/pkbuff.h>
#include <gpxe/netdevice.h>
#include "uip/uip.h"
#include <gpxe/ip.h>
/** @file
*
@ -27,121 +30,144 @@
struct net_protocol ipv4_protocol;
/** An IPv4 routing table entry */
struct ipv4_route {
/** Network address */
struct in_addr network;
/** An IPv4 address/routing table entry */
struct ipv4_miniroute {
/** List of miniroutes */
struct list_head list;
/** Network device */
struct net_device *netdev;
/** IPv4 address */
struct in_addr address;
/** 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 );
}
/** List of IPv4 miniroutes */
static LIST_HEAD ( miniroutes );
/**
* Set netmask
* Add IPv4 interface
*
* @v netdev Network device
* @v address IPv4 address
* @v netmask Subnet mask
* @v gateway Gateway address (or @c INADDR_NONE for no gateway)
* @ret rc Return status code
*
*/
void set_netmask ( struct in_addr address ) {
union {
struct in_addr address;
uint16_t uip_address[2];
} u;
int add_ipv4_address ( struct net_device *netdev, struct in_addr address,
struct in_addr netmask, struct in_addr gateway ) {
struct ipv4_miniroute *miniroute;
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;
/* Allocate and populate miniroute structure */
miniroute = malloc ( sizeof ( *miniroute ) );
if ( ! miniroute )
return -ENOMEM;
miniroute->netdev = netdev;
miniroute->address = address;
miniroute->netmask = netmask;
miniroute->gateway = gateway;
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();
/* Add to end of list if we have a gateway, otherwise to start
* of list.
*/
if ( gateway.s_addr != INADDR_NONE ) {
list_add_tail ( &miniroute->list, &miniroutes );
} else {
for ( i = 0 ; i < UIP_CONNS ; i++ ) {
uip_periodic ( i );
if ( uip_len > 0 )
uip_transmit();
list_add ( &miniroute->list, &miniroutes );
}
return 0;
}
/**
* Remove IPv4 interface
*
* @v netdev Network device
*/
void del_ipv4_address ( struct net_device *netdev ) {
struct ipv4_miniroute *miniroute;
list_for_each_entry ( miniroute, &miniroutes, list ) {
if ( miniroute->netdev == netdev ) {
list_del ( &miniroute->list );
break;
}
}
}
#endif
/**
* Transmit packet constructed by uIP
*
* @v pkb Packet buffer
* @ret rc Return status code
*
*/
int ipv4_uip_transmit ( struct pk_buff *pkb ) {
struct iphdr *iphdr = pkb->data;
struct ipv4_miniroute *miniroute;
struct net_device *netdev = NULL;
struct in_addr next_hop;
struct in_addr source;
uint8_t ll_dest_buf[MAX_LL_ADDR_LEN];
const uint8_t *ll_dest = ll_dest_buf;
int rc;
/* Use routing table to identify next hop and transmitting netdev */
next_hop = iphdr->dest;
list_for_each_entry ( miniroute, &miniroutes, list ) {
if ( ( ( ( iphdr->dest.s_addr ^ miniroute->address.s_addr ) &
miniroute->netmask.s_addr ) == 0 ) ||
( miniroute->gateway.s_addr != INADDR_NONE ) ) {
netdev = miniroute->netdev;
source = miniroute->address;
if ( miniroute->gateway.s_addr != INADDR_NONE )
next_hop = miniroute->gateway;
break;
}
}
/* Abort if no network device identified */
if ( ! netdev ) {
DBG ( "No route to %s\n", inet_ntoa ( iphdr->dest ) );
rc = -EHOSTUNREACH;
goto err;
}
/* Determine link-layer destination address */
if ( next_hop.s_addr == INADDR_BROADCAST ) {
/* Broadcast address */
ll_dest = netdev->ll_protocol->ll_broadcast;
} else if ( IN_MULTICAST ( next_hop.s_addr ) ) {
/* Special case: IPv4 multicast over Ethernet. This
* code may need to be generalised once we find out
* what happens for other link layers.
*/
uint8_t *next_hop_bytes = ( uint8_t * ) &next_hop;
ll_dest_buf[0] = 0x01;
ll_dest_buf[0] = 0x00;
ll_dest_buf[0] = 0x5e;
ll_dest_buf[3] = next_hop_bytes[1] & 0x7f;
ll_dest_buf[4] = next_hop_bytes[2];
ll_dest_buf[5] = next_hop_bytes[3];
} else {
/* Unicast address: resolve via ARP */
if ( ( rc = arp_resolve ( netdev, &ipv4_protocol, &next_hop,
&source, ll_dest_buf ) ) != 0 ) {
DBG ( "No ARP entry for %s\n",
inet_ntoa ( iphdr->dest ) );
goto err;
}
}
/* Hand off to link layer */
return net_transmit ( pkb, netdev, &ipv4_protocol, ll_dest );
err:
free_pkb ( pkb );
return rc;
}
/**
* Process incoming IP packets
@ -167,51 +193,25 @@ static int ipv4_rx ( struct pk_buff *pkb ) {
pkb = alloc_pkb ( MAX_LL_HEADER_LEN + uip_len );
if ( ! pkb )
return -ENOMEM;
pkb->net_protocol = &ipv4_protocol;
pkb_reserve ( pkb, MAX_LL_HEADER_LEN );
memcpy ( pkb_put ( pkb, uip_len ), uip_buf, uip_len );
net_transmit ( pkb );
ipv4_uip_transmit ( pkb );
}
return 0;
}
/**
* Perform IP layer routing
* Convert IPv4 address to dotted-quad notation
*
* @v pkb Packet buffer
* @ret source Network-layer source address
* @ret dest Network-layer destination address
* @ret rc Return status code
* @v in IP address
* @ret string IP address in dotted-quad notation
*/
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->flags = 0;
if ( dest->s_addr == htonl ( INADDR_BROADCAST ) ) {
nethdr->flags = PKT_FL_BROADCAST;
} else if ( IN_MULTICAST ( dest->s_addr ) ) {
nethdr->flags = PKT_FL_MULTICAST;
}
return 0;
char * inet_ntoa ( struct in_addr in ) {
static char buf[16]; /* "xxx.xxx.xxx.xxx" */
uint8_t *bytes = ( uint8_t * ) &in;
sprintf ( buf, "%d.%d.%d.%d", bytes[0], bytes[1], bytes[2], bytes[3] );
return buf;
}
/**
@ -222,12 +222,7 @@ static int ipv4_route ( const struct pk_buff *pkb,
*
*/
static const char * ipv4_ntoa ( const void *net_addr ) {
static char buf[16]; /* "xxx.xxx.xxx.xxx" */
uint8_t *ip_addr = net_addr;
sprintf ( buf, "%d.%d.%d.%d", ip_addr[0], ip_addr[1], ip_addr[2],
ip_addr[3] );
return buf;
return inet_ntoa ( * ( ( struct in_addr * ) net_addr ) );
}
/** IPv4 protocol */
@ -236,7 +231,6 @@ struct net_protocol ipv4_protocol = {
.net_proto = htons ( ETH_P_IP ),
.net_addr_len = sizeof ( struct in_addr ),
.rx_process = ipv4_rx,
.route = ipv4_route,
.ntoa = ipv4_ntoa,
};
@ -251,12 +245,3 @@ struct net_address static_single_ipv4_address = {
};
STATIC_SINGLE_NETDEV_ADDRESS ( static_single_ipv4_address );
#warning "Remove this static-IP hack"
static struct ipv4_route routing_table[NUM_ROUTES] = {
{ { htonl ( 0x0afefe00 ) }, { htonl ( 0xfffffffc ) },
{ htonl ( 0x00000000 ) }, { htonl ( 0x0afefe01 ) } },
{ { htonl ( 0x00000000 ) }, { htonl ( 0x00000000 ) },
{ htonl ( 0x0afefe02 ) }, { htonl ( 0x0afefe01 ) } },
};

View File

@ -62,6 +62,50 @@ static struct net_address static_single_netdev_addresses_end[0]
/** Recevied packet queue */
static LIST_HEAD ( rx_queue );
#warning "Remove this static IP address hack"
#include <ip.h>
#include <gpxe/ip.h>
/**
* Register network device
*
* @v netdev Network device
* @ret rc Return status code
*
* Adds the network device to the list of network devices.
*/
int register_netdev ( struct net_device *netdev ) {
#warning "Remove this static IP address hack"
{
const struct in_addr static_address = { htonl ( 0x0afefe01 ) };
const struct in_addr static_netmask = { htonl ( 0xffffff00 ) };
const struct in_addr static_gateway = { INADDR_NONE };
int rc;
if ( ( rc = add_ipv4_address ( netdev, static_address,
static_netmask,
static_gateway ) ) != 0 )
return rc;
}
return 0;
}
/**
* Unregister network device
*
* @v netdev Network device
*
* Removes the network device from the list of network devices.
*/
void unregister_netdev ( struct net_device *netdev ) {
#warning "Remove this static IP address hack"
del_ipv4_address ( netdev );
}
/**
* Add packet to receive queue
*
@ -128,88 +172,6 @@ find_netdev_by_net_addr ( struct net_protocol *net_protocol,
return NULL;
}
/**
* Transmit packet via a network device
*
* @v pkb Packet buffer
* @v netdev Network device, or NULL
* @ret rc Return status code
*
* Transmits the packet via the specified network device. The packet
* must begin with a network-layer header, and the @c net_protocol
* field must have been filled in. If @c netdev is NULL, the network
* device is identified via the packet contents, if possible. This
* function takes ownership of the packet buffer.
*/
int net_transmit_via ( struct pk_buff *pkb, struct net_device *netdev ) {
struct net_protocol *net_protocol;
struct net_header nethdr;
struct ll_protocol *ll_protocol;
struct ll_header llhdr;
int rc;
/* Perform network-layer routing */
net_protocol = pkb->net_protocol;
nethdr.net_protocol = net_protocol;
if ( ( rc = net_protocol->route ( pkb, &nethdr ) ) != 0 ) {
DBG ( "Could not route to %s address %s\n",
net_protocol->name,
net_protocol->ntoa ( nethdr.dest_net_addr ) );
free_pkb ( pkb );
return rc;
}
/* Identify transmitting network device, if not specified */
if ( ! netdev ) {
netdev = find_netdev_by_net_addr ( net_protocol,
nethdr.source_net_addr );
if ( ! netdev ) {
DBG ( "No network device for %s address %s\n",
net_protocol->name,
net_protocol->ntoa ( nethdr.source_net_addr ) );
free_pkb ( pkb );
return -EHOSTUNREACH;
}
}
/* Perform link-layer routing */
ll_protocol = netdev->ll_protocol;
llhdr.ll_protocol = ll_protocol;
if ( ( rc = ll_protocol->route ( netdev, &nethdr, &llhdr ) ) != 0 ) {
DBG ( "No link-layer route to %s address %s\n",
net_protocol->name,
net_protocol->ntoa ( nethdr.dest_net_addr ) );
free_pkb ( pkb );
return rc;
}
/* Prepend link-layer header */
pkb_push ( pkb, ll_protocol->ll_header_len );
ll_protocol->fill_llh ( &llhdr, pkb );
/* Hand off packet to network device */
if ( ( rc = netdev->transmit ( netdev, pkb ) ) != 0 ) {
DBG ( "Device failed to transmit packet\n" );
return rc;
}
DBG ( "Packet transmitted\n" );
return 0;
}
/**
* Transmit packet
*
* @v pkb Packet buffer
* @ret rc Return status code
*
* Transmits the packet via the appropriate network device. This
* function takes ownership of the packet buffer.
*/
int net_transmit ( struct pk_buff *pkb ) {
return net_transmit_via ( pkb, NULL );
}
/**
* Poll for packet on all network devices
*
@ -277,7 +239,8 @@ int net_rx_process ( struct pk_buff *pkb ) {
pkb->net_protocol = net_protocol;
/* Strip off link-layer header */
pkb_pull ( pkb, ll_protocol->ll_header_len );
#warning "Temporary hack"
pkb_pull ( pkb, ETH_HLEN );
/* Hand off to network layer */
if ( ( rc = net_protocol->rx_process ( pkb ) ) != 0 ) {

View File

@ -176,9 +176,8 @@ static void tcp_periodic ( void ) {
pkb_reserve ( pkb, MAX_LL_HEADER_LEN );
pkb_put ( pkb, uip_len );
memcpy ( pkb->data, uip_buf, uip_len );
pkb->net_protocol = &ipv4_protocol;
net_transmit ( pkb );
ipv4_uip_transmit ( pkb );
}
}
}