* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
+#include <cstdio>
#include <sstream>
#include <string>
#include "base/inet.hh"
using namespace std;
+namespace Net {
+
+EthAddr::EthAddr()
+{
+ memset(data, 0, ETH_ADDR_LEN);
+}
+
+EthAddr::EthAddr(const uint8_t ea[ETH_ADDR_LEN])
+{
+ *data = *ea;
+}
+
+EthAddr::EthAddr(const eth_addr &ea)
+{
+ *data = *ea.data;
+}
+
+EthAddr::EthAddr(const std::string &addr)
+{
+ parse(addr);
+}
+
+const EthAddr &
+EthAddr::operator=(const eth_addr &ea)
+{
+ *data = *ea.data;
+ return *this;
+}
+
+const EthAddr &
+EthAddr::operator=(const std::string &addr)
+{
+ parse(addr);
+ return *this;
+}
+
+void
+EthAddr::parse(const std::string &addr)
+{
+ // the hack below is to make sure that ETH_ADDR_LEN is 6 otherwise
+ // the sscanf function won't work.
+ int bytes[ETH_ADDR_LEN == 6 ? ETH_ADDR_LEN : -1];
+ if (sscanf(addr.c_str(), "%x:%x:%x:%x:%x:%x", &bytes[0], &bytes[1],
+ &bytes[2], &bytes[3], &bytes[4], &bytes[5]) != ETH_ADDR_LEN) {
+ memset(data, 0xff, ETH_ADDR_LEN);
+ return;
+ }
+
+ for (int i = 0; i < ETH_ADDR_LEN; ++i) {
+ if (bytes[i] & ~0xff) {
+ memset(data, 0xff, ETH_ADDR_LEN);
+ return;
+ }
+
+ data[i] = bytes[i];
+ }
+}
+
string
-eaddr_string(const uint8_t a[6])
+EthAddr::string() const
{
stringstream stream;
+ stream << *this;
+ return stream.str();
+}
+
+bool
+operator==(const EthAddr &left, const EthAddr &right)
+{
+ return memcmp(left.bytes(), right.bytes(), ETH_ADDR_LEN);
+}
+
+ostream &
+operator<<(ostream &stream, const EthAddr &ea)
+{
+ const uint8_t *a = ea.addr();
ccprintf(stream, "%x:%x:%x:%x:%x:%x", a[0], a[1], a[2], a[3], a[4], a[5]);
+ return stream;
+}
- return stream.str();
+uint16_t
+cksum(const IpPtr &ptr)
+{
+ int sum = ip_cksum_add(ptr->bytes(), ptr->hlen(), 0);
+ return ip_cksum_carry(sum);
}
uint16_t
-IpHdr::ip_cksum() const
+__tu_cksum(const IpPtr &ip)
{
- int sum = ip_cksum_add(this, hlen(), 0);
- sum = ip_cksum_carry(sum);
- return sum;
+ int tcplen = ip->len() - ip->hlen();
+ int sum = ip_cksum_add(ip->payload(), tcplen, 0);
+ sum = ip_cksum_add(&ip->ip_src, 8, sum); // source and destination
+ sum += htons(ip->ip_p + tcplen);
+ return ip_cksum_carry(sum);
}
uint16_t
-IpHdr::tu_cksum() const
+cksum(const TcpPtr &tcp)
+{ return __tu_cksum(IpPtr(tcp.packet())); }
+
+uint16_t
+cksum(const UdpPtr &udp)
+{ return __tu_cksum(IpPtr(udp.packet())); }
+
+bool
+IpHdr::options(vector<const IpOpt *> &vec) const
{
- int sum = ip_cksum_add(payload(), len() - hlen(), 0);
- sum = ip_cksum_add(&ip_src, 8, sum); // source and destination
- sum += htons(ip_p + len() - hlen());
- sum = ip_cksum_carry(sum);
- return sum;
+ vec.clear();
+
+ const uint8_t *data = bytes() + sizeof(struct ip_hdr);
+ int all = hlen() - sizeof(struct ip_hdr);
+ while (all > 0) {
+ const IpOpt *opt = (const IpOpt *)data;
+ int len = opt->len();
+ if (all < len)
+ return false;
+
+ vec.push_back(opt);
+ all -= len;
+ data += len;
+ }
+
+ return true;
}
+
+bool
+TcpHdr::options(vector<const TcpOpt *> &vec) const
+{
+ vec.clear();
+
+ const uint8_t *data = bytes() + sizeof(struct tcp_hdr);
+ int all = off() - sizeof(struct tcp_hdr);
+ while (all > 0) {
+ const TcpOpt *opt = (const TcpOpt *)data;
+ int len = opt->len();
+ if (all < len)
+ return false;
+
+ vec.push_back(opt);
+ all -= len;
+ data += len;
+ }
+
+ return true;
+}
+
+bool
+TcpOpt::sack(vector<SackRange> &vec) const
+{
+ vec.clear();
+
+ const uint8_t *data = bytes() + sizeof(struct tcp_hdr);
+ int all = len() - offsetof(tcp_opt, opt_data.sack);
+ while (all > 0) {
+ const uint16_t *sack = (const uint16_t *)data;
+ int len = sizeof(uint16_t) * 2;
+ if (all < len) {
+ vec.clear();
+ return false;
+ }
+
+ vec.push_back(RangeIn(ntohs(sack[0]), ntohs(sack[1])));
+ all -= len;
+ data += len;
+ }
+
+ return false;
+}
+
+/* namespace Net */ }
#ifndef __BASE_INET_HH__
#define __BASE_INET_HH__
+#include <iosfwd>
#include <string>
+#include <utility>
+#include <vector>
-#include "dnet/os.h"
+#include "base/range.hh"
+#include "dev/etherpkt.hh"
+#include "sim/host.hh"
+#include "dnet/os.h"
#include "dnet/eth.h"
#include "dnet/ip.h"
#include "dnet/ip6.h"
#include "dnet/icmp.h"
#include "dnet/tcp.h"
#include "dnet/udp.h"
-
#include "dnet/intf.h"
#include "dnet/route.h"
#include "dnet/fw.h"
-
#include "dnet/blob.h"
#include "dnet/rand.h"
-#include "sim/host.hh"
+namespace Net {
-std::string eaddr_string(const uint8_t a[6]);
+/*
+ * Ethernet Stuff
+ */
+struct EthAddr : protected eth_addr
+{
+ protected:
+ void parse(const std::string &addr);
-struct EthHdr;
-struct IpHdr;
-struct TcpHdr;
-struct UdpHdr;
+ public:
+ EthAddr();
+ EthAddr(const uint8_t ea[ETH_ADDR_LEN]);
+ EthAddr(const eth_addr &ea);
+ EthAddr(const std::string &addr);
+ const EthAddr &operator=(const eth_addr &ea);
+ const EthAddr &operator=(const std::string &addr);
-struct EthHdr : protected eth_hdr
-{
- uint16_t type() const { return ntohs(eth_type); }
+ int size() const { return sizeof(eth_addr); }
- const IpHdr *ip() const
- { return type() == ETH_TYPE_IP ? (const IpHdr *)payload() : 0; }
+ const uint8_t *bytes() const { return &data[0]; }
+ uint8_t *bytes() { return &data[0]; }
- IpHdr *ip()
- { return type() == ETH_TYPE_IP ? (IpHdr *)payload() : 0; }
+ const uint8_t *addr() const { return &data[0]; }
+ bool unicast() const { return data[0] == 0x00; }
+ bool multicast() const { return data[0] == 0x01; }
+ bool broadcast() const { return data[0] == 0xff; }
+ std::string string() const;
+};
+
+std::ostream &operator<<(std::ostream &stream, const EthAddr &ea);
+bool operator==(const EthAddr &left, const EthAddr &right);
+
+struct EthHdr : public eth_hdr
+{
+ uint16_t type() const { return ntohs(eth_type); }
+ const EthAddr &src() const { return *(EthAddr *)ð_src; }
+ const EthAddr &dst() const { return *(EthAddr *)ð_dst; }
- bool unicast() { return eth_dst.data[0] == 0x00; }
- bool multicast() { return eth_dst.data[0] == 0x01; }
- bool broadcast() { return eth_dst.data[0] == 0xff; }
+ int size() const { return sizeof(eth_hdr); }
- int size() const { return sizeof(EthHdr); }
const uint8_t *bytes() const { return (const uint8_t *)this; }
const uint8_t *payload() const { return bytes() + size(); }
uint8_t *bytes() { return (uint8_t *)this; }
uint8_t *payload() { return bytes() + size(); }
};
-struct IpHdr : protected ip_hdr
+class EthPtr
+{
+ protected:
+ friend class IpPtr;
+ PacketPtr p;
+
+ public:
+ EthPtr() {}
+ EthPtr(const PacketPtr &ptr) : p(ptr) { }
+
+ EthHdr *operator->() { return (EthHdr *)p->data; }
+ EthHdr &operator*() { return *(EthHdr *)p->data; }
+ operator EthHdr *() { return (EthHdr *)p->data; }
+
+ const EthHdr *operator->() const { return (const EthHdr *)p->data; }
+ const EthHdr &operator*() const { return *(const EthHdr *)p->data; }
+ operator const EthHdr *() const { return (const EthHdr *)p->data; }
+
+ const EthPtr &operator=(const PacketPtr &ptr) { p = ptr; return *this; }
+
+ const PacketPtr packet() const { return p; }
+ PacketPtr packet() { return p; }
+ bool operator!() const { return !p; }
+ operator bool() const { return p; }
+};
+
+/*
+ * IP Stuff
+ */
+struct IpOpt;
+struct IpHdr : public ip_hdr
{
uint8_t version() const { return ip_v; }
uint8_t hlen() const { return ip_hl * 4; }
void sum(uint16_t sum) { ip_sum = sum; }
- uint16_t ip_cksum() const;
- uint16_t tu_cksum() const;
-
- const TcpHdr *tcp() const
- { return proto() == IP_PROTO_TCP ? (const TcpHdr *)payload() : 0; }
- const UdpHdr *udp() const
- { return proto() == IP_PROTO_UDP ? (const UdpHdr *)payload() : 0; }
-
- TcpHdr *tcp()
- { return proto() == IP_PROTO_TCP ? (TcpHdr *)payload() : 0; }
- UdpHdr *udp()
- { return proto() == IP_PROTO_UDP ? (UdpHdr *)payload() : 0; }
-
+ bool options(std::vector<const IpOpt *> &vec) const;
int size() const { return hlen(); }
const uint8_t *bytes() const { return (const uint8_t *)this; }
uint8_t *payload() { return bytes() + size(); }
};
-struct TcpHdr : protected tcp_hdr
+class IpPtr
+{
+ protected:
+ friend class TcpPtr;
+ friend class UdpPtr;
+ PacketPtr p;
+
+ const IpHdr *h() const
+ { return (const IpHdr *)(p->data + sizeof(eth_hdr)); }
+ IpHdr *h() { return (IpHdr *)(p->data + sizeof(eth_hdr)); }
+
+ void set(const PacketPtr &ptr)
+ {
+ EthHdr *eth = (EthHdr *)ptr->data;
+ if (eth->type() == ETH_TYPE_IP)
+ p = ptr;
+ else
+ p = 0;
+ }
+
+ public:
+ IpPtr() {}
+ IpPtr(const PacketPtr &ptr) { set(ptr); }
+ IpPtr(const EthPtr &ptr) { set(ptr.p); }
+ IpPtr(const IpPtr &ptr) : p(ptr.p) { }
+
+ IpHdr *operator->() { return h(); }
+ IpHdr &operator*() { return *h(); }
+ operator IpHdr *() { return h(); }
+
+ const IpHdr *operator->() const { return h(); }
+ const IpHdr &operator*() const { return *h(); }
+ operator const IpHdr *() const { return h(); }
+
+ const IpPtr &operator=(const PacketPtr &ptr) { set(ptr); return *this; }
+ const IpPtr &operator=(const EthPtr &ptr) { set(ptr.p); return *this; }
+ const IpPtr &operator=(const IpPtr &ptr) { p = ptr.p; return *this; }
+
+ const PacketPtr packet() const { return p; }
+ PacketPtr packet() { return p; }
+ bool operator!() const { return !p; }
+ operator bool() const { return p; }
+ operator bool() { return p; }
+};
+
+uint16_t cksum(const IpPtr &ptr);
+
+struct IpOpt : public ip_opt
+{
+ uint8_t type() const { return opt_type; }
+ uint8_t typeNumber() const { return IP_OPT_NUMBER(opt_type); }
+ uint8_t typeClass() const { return IP_OPT_CLASS(opt_type); }
+ uint8_t typeCopied() const { return IP_OPT_COPIED(opt_type); }
+ uint8_t len() const { return IP_OPT_TYPEONLY(type()) ? 1 : opt_len; }
+
+ bool isNumber(int num) const { return typeNumber() == IP_OPT_NUMBER(num); }
+ bool isClass(int cls) const { return typeClass() == IP_OPT_CLASS(cls); }
+ bool isCopied(int cpy) const { return typeCopied() == IP_OPT_COPIED(cpy); }
+
+ const uint8_t *data() const { return opt_data.data8; }
+ void sec(ip_opt_data_sec &sec) const;
+ void lsrr(ip_opt_data_rr &rr) const;
+ void ssrr(ip_opt_data_rr &rr) const;
+ void ts(ip_opt_data_ts &ts) const;
+ uint16_t satid() const { return ntohs(opt_data.satid); }
+ uint16_t mtup() const { return ntohs(opt_data.mtu); }
+ uint16_t mtur() const { return ntohs(opt_data.mtu); }
+ void tr(ip_opt_data_tr &tr) const;
+ const uint32_t *addext() const { return &opt_data.addext[0]; }
+ uint16_t rtralt() const { return ntohs(opt_data.rtralt); }
+ void sdb(std::vector<uint32_t> &vec) const;
+};
+
+/*
+ * TCP Stuff
+ */
+struct TcpOpt;
+struct TcpHdr : public tcp_hdr
{
uint16_t sport() const { return ntohs(th_sport); }
uint16_t dport() const { return ntohs(th_dport); }
void sum(uint16_t sum) { th_sum = sum; }
+ bool options(std::vector<const TcpOpt *> &vec) const;
+
int size() const { return off(); }
const uint8_t *bytes() const { return (const uint8_t *)this; }
const uint8_t *payload() const { return bytes() + size(); }
uint8_t *payload() { return bytes() + size(); }
};
-struct UdpHdr : protected udp_hdr
+class TcpPtr
+{
+ protected:
+ PacketPtr p;
+ int off;
+
+ const TcpHdr *h() const { return (const TcpHdr *)(p->data + off); }
+ TcpHdr *h() { return (TcpHdr *)(p->data + off); }
+
+ void set(const PacketPtr &ptr, int offset) { p = ptr; off = offset; }
+ void set(const IpPtr &ptr)
+ {
+ if (ptr->proto() == IP_PROTO_TCP)
+ set(ptr.p, sizeof(eth_hdr) + ptr->hlen());
+ else
+ set(0, 0);
+ }
+
+ public:
+ TcpPtr() {}
+ TcpPtr(const IpPtr &ptr) { set(ptr); }
+ TcpPtr(const TcpPtr &ptr) : p(ptr.p), off(ptr.off) {}
+
+ TcpHdr *operator->() { return h(); }
+ TcpHdr &operator*() { return *h(); }
+ operator TcpHdr *() { return h(); }
+
+ const TcpHdr *operator->() const { return h(); }
+ const TcpHdr &operator*() const { return *h(); }
+ operator const TcpHdr *() const { return h(); }
+
+ const TcpPtr &operator=(const IpPtr &i) { set(i); return *this; }
+ const TcpPtr &operator=(const TcpPtr &t) { set(t.p, t.off); return *this; }
+
+ const PacketPtr packet() const { return p; }
+ PacketPtr packet() { return p; }
+ bool operator!() const { return !p; }
+ operator bool() const { return p; }
+ operator bool() { return p; }
+};
+
+uint16_t cksum(const TcpPtr &ptr);
+
+typedef Range<uint16_t> SackRange;
+
+struct TcpOpt : public tcp_opt
+{
+ uint8_t type() const { return opt_type; }
+ uint8_t len() const { return TCP_OPT_TYPEONLY(type()) ? 1 : opt_len; }
+
+ bool isopt(int opt) const { return type() == opt; }
+
+ const uint8_t *data() const { return opt_data.data8; }
+
+ uint16_t mss() const { return ntohs(opt_data.mss); }
+ uint8_t wscale() const { return opt_data.wscale; }
+ bool sack(std::vector<SackRange> &vec) const;
+ uint32_t echo() const { return ntohl(opt_data.echo); }
+ uint32_t tsval() const { return ntohl(opt_data.timestamp[0]); }
+ uint32_t tsecr() const { return ntohl(opt_data.timestamp[1]); }
+ uint32_t cc() const { return ntohl(opt_data.cc); }
+ uint8_t cksum() const{ return opt_data.cksum; }
+ const uint8_t *md5() const { return opt_data.md5; }
+
+ int size() const { return len(); }
+ const uint8_t *bytes() const { return (const uint8_t *)this; }
+ const uint8_t *payload() const { return bytes() + size(); }
+ uint8_t *bytes() { return (uint8_t *)this; }
+ uint8_t *payload() { return bytes() + size(); }
+};
+
+/*
+ * UDP Stuff
+ */
+struct UdpHdr : public udp_hdr
{
uint16_t sport() const { return ntohs(uh_sport); }
uint16_t dport() const { return ntohs(uh_dport); }
void sum(uint16_t sum) { uh_sum = htons(sum); }
- int size() const { return sizeof(UdpHdr); }
+ int size() const { return sizeof(udp_hdr); }
const uint8_t *bytes() const { return (const uint8_t *)this; }
const uint8_t *payload() const { return bytes() + size(); }
uint8_t *bytes() { return (uint8_t *)this; }
uint8_t *payload() { return bytes() + size(); }
};
+class UdpPtr
+{
+ protected:
+ PacketPtr p;
+ int off;
+
+ const UdpHdr *h() const { return (const UdpHdr *)(p->data + off); }
+ UdpHdr *h() { return (UdpHdr *)(p->data + off); }
+
+ void set(const PacketPtr &ptr, int offset) { p = ptr; off = offset; }
+ void set(const IpPtr &ptr)
+ {
+ if (ptr->proto() == IP_PROTO_UDP)
+ set(ptr.p, sizeof(eth_hdr) + ptr->hlen());
+ else
+ set(0, 0);
+ }
+
+ public:
+ UdpPtr() {}
+ UdpPtr(const IpPtr &ptr) { set(ptr); }
+ UdpPtr(const UdpPtr &ptr) : p(ptr.p), off(ptr.off) {}
+
+ UdpHdr *operator->() { return h(); }
+ UdpHdr &operator*() { return *h(); }
+ operator UdpHdr *() { return h(); }
+
+ const UdpHdr *operator->() const { return h(); }
+ const UdpHdr &operator*() const { return *h(); }
+ operator const UdpHdr *() const { return h(); }
+
+ const UdpPtr &operator=(const IpPtr &i) { set(i); return *this; }
+ const UdpPtr &operator=(const UdpPtr &t) { set(t.p, t.off); return *this; }
+
+ const PacketPtr packet() const { return p; }
+ PacketPtr packet() { return p; }
+ bool operator!() const { return !p; }
+ operator bool() const { return p; }
+ operator bool() { return p; }
+};
+
+uint16_t cksum(const UdpPtr &ptr);
+
+/* namespace Net */ }
+
#endif // __BASE_INET_HH__
protected:
T *data;
- void copy(T *d) {
+ void copy(T *d)
+ {
data = d;
if (data)
data->incref();
}
- void del() {
+ void del()
+ {
if (data)
data->decref();
}
+ void set(T *d)
+ {
+ if (data == d)
+ return;
+
+ del();
+ copy(d);
+ }
+
public:
RefCountingPtr() : data(NULL) {}
const T &operator*() const { return *data; }
const T *get() const { return data; }
- RefCountingPtr &operator=(T *p) {
- if (data != p) {
- del();
- copy(p);
- }
- return *this;
- }
-
- RefCountingPtr &operator=(const RefCountingPtr &r) {
- if (data != r.data) {
- del();
- copy(r.data);
- }
- return *this;
- }
+ RefCountingPtr &operator=(T *p) { set(p); return *this; }
+ RefCountingPtr &operator=(const RefCountingPtr &r)
+ { return operator=(r.data); }
bool operator!() const { return data == 0; }
operator bool() const { return data != 0; }
#include <assert.h>
#include "base/refcnt.hh"
-#include "base/inet.hh"
#include "sim/host.hh"
/*
: data(d.release()), length(l) { }
~PacketData() { if (data) delete [] data; }
- public:
- const EthHdr *eth() const { return (const EthHdr *)data; }
- const IpHdr *ip() const {const EthHdr *h = eth(); return h ? h->ip() : 0;}
- const TcpHdr *tcp() const {const IpHdr *h = ip(); return h ? h->tcp() : 0;}
- const UdpHdr *udp() const {const IpHdr *h = ip(); return h ? h->udp() : 0;}
-
- EthHdr *eth() { return (EthHdr *)data; }
- IpHdr *ip() { EthHdr *h = eth(); return h ? h->ip() : 0; }
- TcpHdr *tcp() { IpHdr *h = ip(); return h ? h->tcp() : 0; }
- UdpHdr *udp() { IpHdr *h = ip(); return h ? h->udp() : 0; }
-
public:
void serialize(std::ostream &os);
void unserialize(Checkpoint *cp, const std::string §ion);
};
using namespace std;
-
+using namespace Net;
///////////////////////////////////////////////////////////////////////
//
bool dma_data_free, Tick dma_read_delay, Tick dma_write_delay,
Tick dma_read_factor, Tick dma_write_factor, PciConfigAll *cf,
PciConfigData *cd, Tsunami *t, uint32_t bus, uint32_t dev,
- uint32_t func, bool rx_filter, const int eaddr[6],
+ uint32_t func, bool rx_filter, EthAddr eaddr,
uint32_t tx_fifo_size, uint32_t rx_fifo_size)
: PciDev(name, mmu, cf, cd, bus, dev, func), tsunami(t), ioEnable(false),
maxTxFifoSize(tx_fifo_size), maxRxFifoSize(rx_fifo_size),
dmaWriteFactor = dma_write_factor;
regsReset();
- rom.perfectMatch[0] = eaddr[0];
- rom.perfectMatch[1] = eaddr[1];
- rom.perfectMatch[2] = eaddr[2];
- rom.perfectMatch[3] = eaddr[3];
- rom.perfectMatch[4] = eaddr[4];
- rom.perfectMatch[5] = eaddr[5];
+ memcpy(&rom.perfectMatch, eaddr.bytes(), ETH_ADDR_LEN);
}
NSGigE::~NSGigE()
#if TRACING_ON
if (DTRACE(Ethernet)) {
- const IpHdr *ip = rxPacket->ip();
+ IpPtr ip(rxPacket);
if (ip) {
DPRINTF(Ethernet, "ID is %d\n", ip->id());
- const TcpHdr *tcp = rxPacket->tcp();
+ TcpPtr tcp(ip);
if (tcp) {
DPRINTF(Ethernet, "Src Port=%d, Dest Port=%d\n",
tcp->sport(), tcp->dport());
*/
if (rxFilterEnable) {
rxDescCache.cmdsts &= ~CMDSTS_DEST_MASK;
- EthHdr *eth = rxFifoFront()->eth();
- if (eth->unicast())
+ const EthAddr &dst = rxFifoFront()->dst();
+ if (dst->unicast())
rxDescCache.cmdsts |= CMDSTS_DEST_SELF;
- if (eth->multicast())
+ if (dst->multicast())
rxDescCache.cmdsts |= CMDSTS_DEST_MULTI;
- if (eth->broadcast())
+ if (dst->broadcast())
rxDescCache.cmdsts |= CMDSTS_DEST_MASK;
}
#endif
- if (extstsEnable && rxPacket->ip()) {
+ IpPtr ip(rxPacket);
+ if (extstsEnable && ip) {
rxDescCache.extsts |= EXTSTS_IPPKT;
rxIpChecksums++;
- IpHdr *ip = rxPacket->ip();
- if (ip->ip_cksum() != 0) {
+ if (cksum(ip) != 0) {
DPRINTF(EthernetCksum, "Rx IP Checksum Error\n");
rxDescCache.extsts |= EXTSTS_IPERR;
}
- if (rxPacket->tcp()) {
+ TcpPtr tcp(ip);
+ UdpPtr udp(ip);
+ if (tcp) {
rxDescCache.extsts |= EXTSTS_TCPPKT;
rxTcpChecksums++;
- if (ip->tu_cksum() != 0) {
+ if (cksum(tcp) != 0) {
DPRINTF(EthernetCksum, "Rx TCP Checksum Error\n");
rxDescCache.extsts |= EXTSTS_TCPERR;
}
- } else if (rxPacket->udp()) {
+ } else if (udp) {
rxDescCache.extsts |= EXTSTS_UDPPKT;
rxUdpChecksums++;
- if (ip->tu_cksum() != 0) {
+ if (cksum(udp) != 0) {
DPRINTF(EthernetCksum, "Rx UDP Checksum Error\n");
rxDescCache.extsts |= EXTSTS_UDPERR;
}
if (interface->sendPacket(txFifo.front())) {
#if TRACING_ON
if (DTRACE(Ethernet)) {
- const IpHdr *ip = txFifo.front()->ip();
+ IpPtr ip(txFifo.front());
if (ip) {
DPRINTF(Ethernet, "ID is %d\n", ip->id());
- const TcpHdr *tcp = txFifo.front()->tcp();
+ TcpPtr tcp(ip);
if (tcp) {
DPRINTF(Ethernet, "Src Port=%d, Dest Port=%d\n",
tcp->sport(), tcp->dport());
DPRINTF(EthernetSM, "This packet is done, let's wrap it up\n");
/* deal with the the packet that just finished */
if ((regs.vtcr & VTCR_PPCHK) && extstsEnable) {
- IpHdr *ip = txPacket->ip();
+ IpPtr ip(txPacket);
if (txDescCache.extsts & EXTSTS_UDPPKT) {
- UdpHdr *udp = txPacket->udp();
+ UdpPtr udp(ip);
udp->sum(0);
- udp->sum(ip->tu_cksum());
+ udp->sum(cksum(udp));
txUdpChecksums++;
} else if (txDescCache.extsts & EXTSTS_TCPPKT) {
- TcpHdr *tcp = txPacket->tcp();
+ TcpPtr tcp(ip);
tcp->sum(0);
- tcp->sum(ip->tu_cksum());
+ tcp->sum(cksum(tcp));
txTcpChecksums++;
}
if (txDescCache.extsts & EXTSTS_IPPKT) {
ip->sum(0);
- ip->sum(ip->ip_cksum());
+ ip->sum(cksum(ip));
txIpChecksums++;
}
}
}
bool
-NSGigE::rxFilter(PacketPtr packet)
+NSGigE::rxFilter(PacketPtr &packet)
{
+ EthPtr eth = packet;
bool drop = true;
string type;
- EthHdr *eth = packet->eth();
- if (eth->unicast()) {
+ const EthAddr &dst = eth->dst();
+ if (dst.unicast()) {
// If we're accepting all unicast addresses
if (acceptUnicast)
drop = false;
// If we make a perfect match
- if (acceptPerfect &&
- memcmp(rom.perfectMatch, packet->data, EADDR_LEN) == 0)
+ if (acceptPerfect && dst == rom.perfectMatch)
drop = false;
if (acceptArp && eth->type() == ETH_TYPE_ARP)
drop = false;
- } else if (eth->broadcast()) {
+ } else if (dst.broadcast()) {
// if we're accepting broadcasts
if (acceptBroadcast)
drop = false;
- } else if (eth->multicast()) {
+ } else if (dst.multicast()) {
// if we're accepting all multicasts
if (acceptMulticast)
drop = false;
}
bool
-NSGigE::recvPacket(PacketPtr packet)
+NSGigE::recvPacket(PacketPtr &packet)
{
rxBytes += packet->length;
rxPackets++;
SERIALIZE_SCALAR(regs.taner);
SERIALIZE_SCALAR(regs.tesr);
- SERIALIZE_ARRAY(rom.perfectMatch, EADDR_LEN);
+ SERIALIZE_ARRAY(rom.perfectMatch, ETH_ADDR_LEN);
SERIALIZE_SCALAR(ioEnable);
UNSERIALIZE_SCALAR(regs.taner);
UNSERIALIZE_SCALAR(regs.tesr);
- UNSERIALIZE_ARRAY(rom.perfectMatch, EADDR_LEN);
+ UNSERIALIZE_ARRAY(rom.perfectMatch, ETH_ADDR_LEN);
UNSERIALIZE_SCALAR(ioEnable);
CREATE_SIM_OBJECT(NSGigE)
{
- int eaddr[6];
- sscanf(((string)hardware_address).c_str(), "%x:%x:%x:%x:%x:%x",
- &eaddr[0], &eaddr[1], &eaddr[2], &eaddr[3], &eaddr[4], &eaddr[5]);
-
return new NSGigE(getInstanceName(), intr_ctrl, intr_delay,
physmem, tx_delay, rx_delay, mmu, hier, header_bus,
payload_bus, pio_latency, dma_desc_free, dma_data_free,
dma_read_delay, dma_write_delay, dma_read_factor,
dma_write_factor, configspace, configdata,
- tsunami, pci_bus, pci_dev, pci_func, rx_filter, eaddr,
+ tsunami, pci_bus, pci_dev, pci_func, rx_filter,
+ EthAddr((string)hardware_address),
tx_fifo_size, rx_fifo_size);
}
* DP83820 ethernet controller
*/
-#ifndef __NS_GIGE_HH__
-#define __NS_GIGE_HH__
+#ifndef __DEV_NS_GIGE_HH__
+#define __DEV_NS_GIGE_HH__
+#include "base/inet.hh"
#include "base/statistics.hh"
#include "dev/etherint.hh"
#include "dev/etherpkt.hh"
#include "mem/bus/bus.hh"
#include "sim/eventq.hh"
-/** length of ethernet address in bytes */
-#define EADDR_LEN 6
-
/**
* Ethernet device registers
*/
* for perfect match memory.
* the linux driver doesn't use any other ROM
*/
- uint8_t perfectMatch[EADDR_LEN];
+ uint8_t perfectMatch[ETH_ADDR_LEN];
};
class IntrControl;
* receive address filter
*/
bool rxFilterEnable;
- bool rxFilter(PacketPtr packet);
+ bool rxFilter(PacketPtr &packet);
bool acceptBroadcast;
bool acceptMulticast;
bool acceptUnicast;
bool dma_data_free, Tick dma_read_delay, Tick dma_write_delay,
Tick dma_read_factor, Tick dma_write_factor, PciConfigAll *cf,
PciConfigData *cd, Tsunami *t, uint32_t bus, uint32_t dev,
- uint32_t func, bool rx_filter, const int eaddr[6],
+ uint32_t func, bool rx_filter, Net::EthAddr eaddr,
uint32_t tx_fifo_size, uint32_t rx_fifo_size);
~NSGigE();
bool cpuIntrPending() const;
void cpuIntrAck() { cpuIntrClear(); }
- bool recvPacket(PacketPtr packet);
+ bool recvPacket(PacketPtr &packet);
void transferDone();
void setInterface(NSGigEInt *i) { assert(!interface); interface = i; }
virtual void sendDone() { dev->transferDone(); }
};
-#endif // __NS_GIGE_HH__
+#endif // __DEV_NS_GIGE_HH__