gem5/base/inet.hh
Ali Saidi 8f8d09538f Mostly done with all device models for new memory system. Still need to get timing packets working and get sinic working
after merge from head. Checkpointing may need some work now. Endian-happiness still not complete.

SConscript:
    add all devices back into make file
base/inet.hh:
dev/etherbus.cc:
dev/etherbus.hh:
dev/etherdump.cc:
dev/etherdump.hh:
dev/etherint.hh:
dev/etherlink.cc:
dev/etherlink.hh:
dev/etherpkt.cc:
dev/etherpkt.hh:
dev/ethertap.cc:
dev/ethertap.hh:
dev/pktfifo.cc:
dev/pktfifo.hh:
    rename PacketPtr EthPacketPtr so it doesn't conflict with the PacketPtr type in the memory system
configs/test/fs.py:
    add nics to fs.py
cpu/cpu_exec_context.cc:
    remove this check, as it's not valid. We may want to add something else back in to make sure that no one can delete the
    static virtual ports in the exec context
cpu/simple/cpu.cc:
cpu/simple/cpu.hh:
dev/alpha_console.cc:
dev/ide_ctrl.cc:
    use new methods for accessing packet data
dev/ide_disk.cc:
    add some more dprintfs
dev/io_device.cc:
    delete packets when we are done with them. Update for new packet methods to access data
dev/isa_fake.cc:
dev/pciconfigall.cc:
dev/tsunami_cchip.cc:
dev/tsunami_io.cc:
dev/tsunami_pchip.cc:
dev/uart8250.cc:
dev/uart8250.hh:
mem/physical.cc:
mem/port.cc:
    dUpdate for new packet methods to access data
dev/ns_gige.cc:
    Update for new memory system
dev/ns_gige.hh:
python/m5/objects/Ethernet.py:
    update for new memory system
dev/sinic.cc:
dev/sinic.hh:
    Update for new memory system. Untested as need to merge in head because of kernel driver differences between versions
mem/packet.hh:
    Add methods to access data instead of accessing it directly.

--HG--
extra : convert_revision : 223f43876afd404e68337270cd9a5e44d0bf553e
2006-04-24 19:31:50 -04:00

407 lines
13 KiB
C++

/*
* Copyright (c) 2002-2005 The Regents of The University of Michigan
* 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;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "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 COPYRIGHT
* OWNER OR CONTRIBUTORS 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.
*/
#ifndef __BASE_INET_HH__
#define __BASE_INET_HH__
#include <iosfwd>
#include <string>
#include <utility>
#include <vector>
#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/addr.h"
#include "dnet/arp.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"
namespace Net {
/*
* Ethernet Stuff
*/
struct EthAddr : protected eth_addr
{
protected:
void parse(const std::string &addr);
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);
int size() const { return sizeof(eth_addr); }
const uint8_t *bytes() const { return &data[0]; }
uint8_t *bytes() { return &data[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;
operator uint64_t() const
{
uint64_t reg = 0;
reg |= ((uint64_t)data[0]) << 40;
reg |= ((uint64_t)data[1]) << 32;
reg |= ((uint64_t)data[2]) << 24;
reg |= ((uint64_t)data[3]) << 16;
reg |= ((uint64_t)data[4]) << 8;
reg |= ((uint64_t)data[5]) << 0;
return reg;
}
};
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 *)&eth_src; }
const EthAddr &dst() const { return *(EthAddr *)&eth_dst; }
int size() const { return sizeof(eth_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 EthPtr
{
protected:
friend class IpPtr;
EthPacketPtr p;
public:
EthPtr() {}
EthPtr(const EthPacketPtr &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 EthPacketPtr &ptr) { p = ptr; return *this; }
const EthPacketPtr packet() const { return p; }
EthPacketPtr 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; }
uint8_t tos() const { return ip_tos; }
uint16_t len() const { return ntohs(ip_len); }
uint16_t id() const { return ntohs(ip_id); }
uint16_t frag_flags() const { return ntohs(ip_off) >> 13; }
uint16_t frag_off() const { return ntohs(ip_off) & 0x1fff; }
uint8_t ttl() const { return ip_ttl; }
uint8_t proto() const { return ip_p; }
uint16_t sum() const { return ip_sum; }
uint32_t src() const { return ntohl(ip_src); }
uint32_t dst() const { return ntohl(ip_dst); }
void sum(uint16_t sum) { ip_sum = sum; }
bool options(std::vector<const IpOpt *> &vec) const;
int size() const { return hlen(); }
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 IpPtr
{
protected:
friend class TcpPtr;
friend class UdpPtr;
EthPacketPtr 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 EthPacketPtr &ptr)
{
EthHdr *eth = (EthHdr *)ptr->data;
if (eth->type() == ETH_TYPE_IP)
p = ptr;
else
p = 0;
}
public:
IpPtr() {}
IpPtr(const EthPacketPtr &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 EthPacketPtr &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 EthPacketPtr packet() const { return p; }
EthPacketPtr 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); }
uint32_t seq() const { return ntohl(th_seq); }
uint32_t ack() const { return ntohl(th_ack); }
uint8_t off() const { return th_off; }
uint8_t flags() const { return th_flags & 0x3f; }
uint16_t win() const { return ntohs(th_win); }
uint16_t sum() const { return th_sum; }
uint16_t urp() const { return ntohs(th_urp); }
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 *bytes() { return (uint8_t *)this; }
uint8_t *payload() { return bytes() + size(); }
};
class TcpPtr
{
protected:
EthPacketPtr p;
int off;
const TcpHdr *h() const { return (const TcpHdr *)(p->data + off); }
TcpHdr *h() { return (TcpHdr *)(p->data + off); }
void set(const EthPacketPtr &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 EthPacketPtr packet() const { return p; }
EthPacketPtr 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); }
uint16_t len() const { return ntohs(uh_ulen); }
uint16_t sum() const { return uh_sum; }
void sum(uint16_t sum) { uh_sum = sum; }
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:
EthPacketPtr p;
int off;
const UdpHdr *h() const { return (const UdpHdr *)(p->data + off); }
UdpHdr *h() { return (UdpHdr *)(p->data + off); }
void set(const EthPacketPtr &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 EthPacketPtr packet() const { return p; }
EthPacketPtr 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__