/* * This file is part of DOS-libpcap * Ported to DOS/DOSX by G. Vanem <giva@bgnett.no> * * pcap-dos.c: Interface to PKTDRVR, NDIS2 and 32-bit pmode * network drivers. * * @(#) $Header: /tcpdump/master/libpcap/pcap-dos.c,v 1.1.2.1 2005/05/03 18:54:35 guy Exp $ (LBL) */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <signal.h> #include <float.h> #include <fcntl.h> #include <io.h> #if defined(USE_32BIT_DRIVERS) #include "msdos/pm_drvr/pmdrvr.h" #include "msdos/pm_drvr/pci.h" #include "msdos/pm_drvr/bios32.h" #include "msdos/pm_drvr/module.h" #include "msdos/pm_drvr/3c501.h" #include "msdos/pm_drvr/3c503.h" #include "msdos/pm_drvr/3c509.h" #include "msdos/pm_drvr/3c59x.h" #include "msdos/pm_drvr/3c515.h" #include "msdos/pm_drvr/3c90x.h" #include "msdos/pm_drvr/3c575_cb.h" #include "msdos/pm_drvr/ne.h" #include "msdos/pm_drvr/wd.h" #include "msdos/pm_drvr/accton.h" #include "msdos/pm_drvr/cs89x0.h" #include "msdos/pm_drvr/rtl8139.h" #include "msdos/pm_drvr/ne2k-pci.h" #endif #include "pcap.h" #include "pcap-dos.h" #include "pcap-int.h" #include "msdos/pktdrvr.h" #ifdef USE_NDIS2 #include "msdos/ndis2.h" #endif #include <arpa/inet.h> #include <net/if.h> #include <net/if_arp.h> #include <net/if_ether.h> #include <net/if_packe.h> #include <tcp.h> #if defined(USE_32BIT_DRIVERS) #define FLUSHK() do { _printk_safe = 1; _printk_flush(); } while (0) #define NDIS_NEXT_DEV &rtl8139_dev static char *rx_pool = NULL; static void init_32bit (void); static int pktq_init (struct rx_ringbuf *q, int size, int num, char *pool); static int pktq_check (struct rx_ringbuf *q); static int pktq_inc_out (struct rx_ringbuf *q); static int pktq_in_index (struct rx_ringbuf *q) LOCKED_FUNC; static void pktq_clear (struct rx_ringbuf *q) LOCKED_FUNC; static struct rx_elem *pktq_in_elem (struct rx_ringbuf *q) LOCKED_FUNC; static struct rx_elem *pktq_out_elem (struct rx_ringbuf *q); #else #define FLUSHK() ((void)0) #define NDIS_NEXT_DEV NULL #endif /* * Internal variables/functions in Watt-32 */ extern WORD _pktdevclass; extern BOOL _eth_is_init; extern int _w32_dynamic_host; extern int _watt_do_exit; extern int _watt_is_init; extern int _w32__bootp_on, _w32__dhcp_on, _w32__rarp_on, _w32__do_mask_req; extern void (*_w32_usr_post_init) (void); extern void (*_w32_print_hook)(); extern void dbug_write (const char *); /* Watt-32 lib, pcdbug.c */ extern int pkt_get_mtu (void); static int ref_count = 0; static u_long mac_count = 0; static u_long filter_count = 0; static volatile BOOL exc_occured = 0; static struct device *handle_to_device [20]; static int pcap_read_dos (pcap_t *p, int cnt, pcap_handler callback, u_char *data); static void pcap_close_dos (pcap_t *p); static int pcap_stats_dos (pcap_t *p, struct pcap_stat *ps); static int pcap_sendpacket_dos (pcap_t *p, const void *buf, size_t len); static int pcap_setfilter_dos (pcap_t *p, struct bpf_program *fp); static int ndis_probe (struct device *dev); static int pkt_probe (struct device *dev); static void close_driver (void); static int init_watt32 (struct pcap *pcap, const char *dev_name, char *err_buf); static int first_init (const char *name, char *ebuf, int promisc); static void watt32_recv_hook (u_char *dummy, const struct pcap_pkthdr *pcap, const u_char *buf); /* * These are the device we always support */ static struct device ndis_dev = { "ndis", "NDIS2 LanManager", 0, 0,0,0,0,0,0, NDIS_NEXT_DEV, /* NULL or a 32-bit device */ ndis_probe }; static struct device pkt_dev = { "pkt", "Packet-Driver", 0, 0,0,0,0,0,0, &ndis_dev, pkt_probe }; static struct device *get_device (int fd) { if (fd <= 0 || fd >= sizeof(handle_to_device)/sizeof(handle_to_device[0])) return (NULL); return handle_to_device [fd-1]; } /* * Open MAC-driver with name 'device_name' for live capture of * network packets. */ pcap_t *pcap_open_live (const char *device_name, int snaplen, int promisc, int timeout_ms, char *errbuf) { struct pcap *pcap; if (snaplen < ETH_MIN) snaplen = ETH_MIN; if (snaplen > ETH_MAX) /* silently accept and truncate large MTUs */ snaplen = ETH_MAX; pcap = calloc (sizeof(*pcap), 1); if (!pcap) { strcpy (errbuf, "Not enough memory (pcap)"); return (NULL); } pcap->snapshot = max (ETH_MIN+8, snaplen); pcap->linktype = DLT_EN10MB; /* !! */ pcap->inter_packet_wait = timeout_ms; pcap->close_op = pcap_close_dos; pcap->read_op = pcap_read_dos; pcap->stats_op = pcap_stats_dos; pcap->inject_op = pcap_sendpacket_dos; pcap->setfilter_op = pcap_setfilter_dos; pcap->setdirection_op = NULL; /* Not implemented.*/ pcap->fd = ++ref_count; if (pcap->fd == 1) /* first time we're called */ { if (!init_watt32(pcap, device_name, errbuf) || !first_init(device_name, errbuf, promisc)) { free (pcap); return (NULL); } atexit (close_driver); } else if (stricmp(active_dev->name,device_name)) { snprintf (errbuf, PCAP_ERRBUF_SIZE, "Cannot use different devices simultaneously " "(`%s' vs. `%s')", active_dev->name, device_name); free (pcap); pcap = NULL; } handle_to_device [pcap->fd-1] = active_dev; return (pcap); } /* * Poll the receiver queue and call the pcap callback-handler * with the packet. */ static int pcap_read_one (pcap_t *p, pcap_handler callback, u_char *data) { struct pcap_pkthdr pcap; struct bpf_insn *fcode = p->fcode.bf_insns; struct timeval now, expiry; BYTE *rx_buf; int rx_len = 0; if (p->inter_packet_wait > 0) { gettimeofday2 (&now, NULL); expiry.tv_usec = now.tv_usec + 1000UL * p->inter_packet_wait; expiry.tv_sec = now.tv_sec; while (expiry.tv_usec >= 1000000L) { expiry.tv_usec -= 1000000L; expiry.tv_sec++; } } while (!exc_occured) { volatile struct device *dev; /* might be reset by sig_handler */ dev = get_device (p->fd); if (!dev) break; PCAP_ASSERT (dev->copy_rx_buf || dev->peek_rx_buf); FLUSHK(); /* If driver has a zero-copy receive facility, peek at the queue, * filter it, do the callback and release the buffer. */ if (dev->peek_rx_buf) { PCAP_ASSERT (dev->release_rx_buf); rx_len = (*dev->peek_rx_buf) (&rx_buf); } else { BYTE buf [ETH_MAX+100]; /* add some margin */ rx_len = (*dev->copy_rx_buf) (buf, p->snapshot); rx_buf = buf; } if (rx_len > 0) /* got a packet */ { mac_count++; FLUSHK(); pcap.caplen = min (rx_len, p->snapshot); pcap.len = rx_len; if (callback && (!fcode || bpf_filter(fcode, rx_buf, pcap.len, pcap.caplen))) { filter_count++; /* Fix-me!! Should be time of arrival. Not time of * capture. */ gettimeofday2 (&pcap.ts, NULL); (*callback) (data, &pcap, rx_buf); } if (dev->release_rx_buf) (*dev->release_rx_buf) (rx_buf); if (pcap_pkt_debug > 0) { if (callback == watt32_recv_hook) dbug_write ("pcap_recv_hook\n"); else dbug_write ("pcap_read_op\n"); } FLUSHK(); return (1); } /* If not to wait for a packet or pcap_close() called from * e.g. SIGINT handler, exit loop now. */ if (p->inter_packet_wait <= 0 || (volatile int)p->fd <= 0) break; gettimeofday2 (&now, NULL); if (timercmp(&now, &expiry, >)) break; #ifndef DJGPP kbhit(); /* a real CPU hog */ #endif if (p->wait_proc) (*p->wait_proc)(); /* call yield func */ } if (rx_len < 0) /* receive error */ { p->md.stat.ps_drop++; #ifdef USE_32BIT_DRIVERS if (pcap_pkt_debug > 1) printk ("pkt-err %s\n", pktInfo.error); #endif return (-1); } return (0); } static int pcap_read_dos (pcap_t *p, int cnt, pcap_handler callback, u_char *data) { int rc, num = 0; while (num <= cnt || (cnt < 0)) { if (p->fd <= 0) return (-1); rc = pcap_read_one (p, callback, data); if (rc > 0) num++; if (rc < 0) break; _w32_os_yield(); /* allow SIGINT generation, yield to Win95/NT */ } return (num); } /* * Return network statistics */ static int pcap_stats_dos (pcap_t *p, struct pcap_stat *ps) { struct net_device_stats *stats; struct device *dev = p ? get_device(p->fd) : NULL; if (!dev) { strcpy (p->errbuf, "illegal pcap handle"); return (-1); } if (!dev->get_stats || (stats = (*dev->get_stats)(dev)) == NULL) { strcpy (p->errbuf, "device statistics not available"); return (-1); } FLUSHK(); p->md.stat.ps_recv = stats->rx_packets; p->md.stat.ps_drop += stats->rx_missed_errors; p->md.stat.ps_ifdrop = stats->rx_dropped + /* queue full */ stats->rx_errors; /* HW errors */ if (ps) *ps = p->md.stat; return (0); } /* * Return detailed network/device statistics. * May be called after 'dev->close' is called. */ int pcap_stats_ex (pcap_t *p, struct pcap_stat_ex *se) { struct device *dev = p ? get_device (p->fd) : NULL; if (!dev || !dev->get_stats) { strlcpy (p->errbuf, "detailed device statistics not available", PCAP_ERRBUF_SIZE); return (-1); } if (!strnicmp(dev->name,"pkt",3)) { strlcpy (p->errbuf, "pktdrvr doesn't have detailed statistics", PCAP_ERRBUF_SIZE); return (-1); } memcpy (se, (*dev->get_stats)(dev), sizeof(*se)); return (0); } /* * Simply store the filter-code for the pcap_read_dos() callback * Some day the filter-code could be handed down to the active * device (pkt_rx1.s or 32-bit device interrupt handler). */ static int pcap_setfilter_dos (pcap_t *p, struct bpf_program *fp) { if (!p) return (-1); p->fcode = *fp; return (0); } /* * Return # of packets received in pcap_read_dos() */ u_long pcap_mac_packets (void) { return (mac_count); } /* * Return # of packets passed through filter in pcap_read_dos() */ u_long pcap_filter_packets (void) { return (filter_count); } /* * Close pcap device. Not called for offline captures. */ static void pcap_close_dos (pcap_t *p) { if (p && !exc_occured) { if (pcap_stats(p,NULL) < 0) p->md.stat.ps_drop = 0; if (!get_device(p->fd)) return; handle_to_device [p->fd-1] = NULL; p->fd = 0; if (ref_count > 0) ref_count--; if (ref_count > 0) return; } close_driver(); } /* * Return the name of the 1st network interface, * or NULL if none can be found. */ char *pcap_lookupdev (char *ebuf) { struct device *dev; #ifdef USE_32BIT_DRIVERS init_32bit(); #endif for (dev = (struct device*)dev_base; dev; dev = dev->next) { PCAP_ASSERT (dev->probe); if ((*dev->probe)(dev)) { FLUSHK(); probed_dev = (struct device*) dev; /* remember last probed device */ return (char*) dev->name; } } if (ebuf) strcpy (ebuf, "No driver found"); return (NULL); } /* * Gets localnet & netmask from Watt-32. */ int pcap_lookupnet (const char *device, bpf_u_int32 *localnet, bpf_u_int32 *netmask, char *errbuf) { if (!_watt_is_init) { strcpy (errbuf, "pcap_open_offline() or pcap_open_live() must be " "called first"); return (-1); } *netmask = _w32_sin_mask; *localnet = my_ip_addr & *netmask; if (*localnet == 0) { if (IN_CLASSA(*netmask)) *localnet = IN_CLASSA_NET; else if (IN_CLASSB(*netmask)) *localnet = IN_CLASSB_NET; else if (IN_CLASSC(*netmask)) *localnet = IN_CLASSC_NET; else { sprintf (errbuf, "inet class for 0x%lx unknown", *netmask); return (-1); } } ARGSUSED (device); return (0); } /* * Get a list of all interfaces that are present and that we probe okay. * Returns -1 on error, 0 otherwise. * The list, as returned through "alldevsp", may be null if no interfaces * were up and could be opened. */ int pcap_findalldevs (pcap_if_t **alldevsp, char *errbuf) { struct device *dev; struct sockaddr_ll sa_ll_1, sa_ll_2; struct sockaddr *addr, *netmask, *broadaddr, *dstaddr; pcap_if_t *devlist = NULL; int ret = 0; size_t addr_size = sizeof(struct sockaddr_ll); for (dev = (struct device*)dev_base; dev; dev = dev->next) { PCAP_ASSERT (dev->probe); if (!(*dev->probe)(dev)) continue; PCAP_ASSERT (dev->close); /* set by probe routine */ FLUSHK(); (*dev->close) (dev); memset (&sa_ll_1, 0, sizeof(sa_ll_1)); memset (&sa_ll_2, 0, sizeof(sa_ll_2)); sa_ll_1.sll_family = AF_PACKET; sa_ll_2.sll_family = AF_PACKET; addr = (struct sockaddr*) &sa_ll_1; netmask = (struct sockaddr*) &sa_ll_1; dstaddr = (struct sockaddr*) &sa_ll_1; broadaddr = (struct sockaddr*) &sa_ll_2; memset (&sa_ll_2.sll_addr, 0xFF, sizeof(sa_ll_2.sll_addr)); if (pcap_add_if(&devlist, dev->name, dev->flags, dev->long_name, errbuf) < 0) { ret = -1; break; } if (add_addr_to_iflist(&devlist,dev->name, dev->flags, addr, addr_size, netmask, addr_size, broadaddr, addr_size, dstaddr, addr_size, errbuf) < 0) { ret = -1; break; } } if (devlist && ret < 0) { pcap_freealldevs (devlist); devlist = NULL; } else if (!devlist) strcpy (errbuf, "No drivers found"); *alldevsp = devlist; return (ret); } /* * pcap_assert() is mainly used for debugging */ void pcap_assert (const char *what, const char *file, unsigned line) { FLUSHK(); fprintf (stderr, "%s (%u): Assertion \"%s\" failed\n", file, line, what); close_driver(); _exit (-1); } /* * For pcap_offline_read(): wait and yield between printing packets * to simulate the pace packets where actually recorded. */ void pcap_set_wait (pcap_t *p, void (*yield)(void), int wait) { if (p) { p->wait_proc = yield; p->inter_packet_wait = wait; } } /* * Initialise a named network device. */ static struct device * open_driver (const char *dev_name, char *ebuf, int promisc) { struct device *dev; for (dev = (struct device*)dev_base; dev; dev = dev->next) { PCAP_ASSERT (dev->name); if (strcmp (dev_name,dev->name)) continue; if (!probed_dev) /* user didn't call pcap_lookupdev() first */ { PCAP_ASSERT (dev->probe); if (!(*dev->probe)(dev)) /* call the xx_probe() function */ { sprintf (ebuf, "failed to detect device `%s'", dev_name); return (NULL); } probed_dev = dev; /* device is probed okay and may be used */ } else if (dev != probed_dev) { goto not_probed; } FLUSHK(); /* Select what traffic to receive */ if (promisc) dev->flags |= (IFF_ALLMULTI | IFF_PROMISC); else dev->flags &= ~(IFF_ALLMULTI | IFF_PROMISC); PCAP_ASSERT (dev->open); if (!(*dev->open)(dev)) { sprintf (ebuf, "failed to activate device `%s'", dev_name); if (pktInfo.error && !strncmp(dev->name,"pkt",3)) { strcat (ebuf, ": "); strcat (ebuf, pktInfo.error); } return (NULL); } /* Some devices need this to operate in promiscous mode */ if (promisc && dev->set_multicast_list) (*dev->set_multicast_list) (dev); active_dev = dev; /* remember our active device */ break; } /* 'dev_name' not matched in 'dev_base' list. */ if (!dev) { sprintf (ebuf, "device `%s' not supported", dev_name); return (NULL); } not_probed: if (!probed_dev) { sprintf (ebuf, "device `%s' not probed", dev_name); return (NULL); } return (dev); } /* * Deinitialise MAC driver. * Set receive mode back to default mode. */ static void close_driver (void) { /* !!todo: loop over all 'handle_to_device[]' ? */ struct device *dev = active_dev; if (dev && dev->close) { (*dev->close) (dev); FLUSHK(); } active_dev = NULL; #ifdef USE_32BIT_DRIVERS if (rx_pool) { k_free (rx_pool); rx_pool = NULL; } if (dev) pcibios_exit(); #endif } #ifdef __DJGPP__ static void setup_signals (void (*handler)(int)) { signal (SIGSEGV,handler); signal (SIGILL, handler); signal (SIGFPE, handler); } static void exc_handler (int sig) { #ifdef USE_32BIT_DRIVERS if (active_dev->irq > 0) /* excludes IRQ 0 */ { disable_irq (active_dev->irq); irq_eoi_cmd (active_dev->irq); _printk_safe = 1; } #endif switch (sig) { case SIGSEGV: fputs ("Catching SIGSEGV.\n", stderr); break; case SIGILL: fputs ("Catching SIGILL.\n", stderr); break; case SIGFPE: _fpreset(); fputs ("Catching SIGFPE.\n", stderr); break; default: fprintf (stderr, "Catching signal %d.\n", sig); } exc_occured = 1; pcap_close_dos (NULL); } #endif /* __DJGPP__ */ /* * Open the pcap device for the first client calling pcap_open_live() */ static int first_init (const char *name, char *ebuf, int promisc) { struct device *dev; #ifdef USE_32BIT_DRIVERS rx_pool = k_calloc (RECEIVE_BUF_SIZE, RECEIVE_QUEUE_SIZE); if (!rx_pool) { strcpy (ebuf, "Not enough memory (Rx pool)"); return (0); } #endif #ifdef __DJGPP__ setup_signals (exc_handler); #endif #ifdef USE_32BIT_DRIVERS init_32bit(); #endif dev = open_driver (name, ebuf, promisc); if (!dev) { #ifdef USE_32BIT_DRIVERS k_free (rx_pool); rx_pool = NULL; #endif #ifdef __DJGPP__ setup_signals (SIG_DFL); #endif return (0); } #ifdef USE_32BIT_DRIVERS /* * If driver is NOT a 16-bit "pkt/ndis" driver (having a 'copy_rx_buf' * set in it's probe handler), initialise near-memory ring-buffer for * the 32-bit device. */ if (dev->copy_rx_buf == NULL) { dev->get_rx_buf = get_rxbuf; dev->peek_rx_buf = peek_rxbuf; dev->release_rx_buf = release_rxbuf; pktq_init (&dev->queue, RECEIVE_BUF_SIZE, RECEIVE_QUEUE_SIZE, rx_pool); } #endif return (1); } #ifdef USE_32BIT_DRIVERS static void init_32bit (void) { static int init_pci = 0; if (!_printk_file) _printk_init (64*1024, NULL); /* calls atexit(printk_exit) */ if (!init_pci) (void)pci_init(); /* init BIOS32+PCI interface */ init_pci = 1; } #endif /* * Hook functions for using Watt-32 together with pcap */ static char rxbuf [ETH_MAX+100]; /* rx-buffer with some margin */ static WORD etype; static pcap_t pcap_save; static void watt32_recv_hook (u_char *dummy, const struct pcap_pkthdr *pcap, const u_char *buf) { /* Fix me: assumes Ethernet II only */ struct ether_header *ep = (struct ether_header*) buf; memcpy (rxbuf, buf, pcap->caplen); etype = ep->ether_type; ARGSUSED (dummy); } #if (WATTCP_VER >= 0x0224) /* * This function is used by Watt-32 to poll for a packet. * i.e. it's set to bypass _eth_arrived() */ static void *pcap_recv_hook (WORD *type) { int len = pcap_read_dos (&pcap_save, 1, watt32_recv_hook, NULL); if (len < 0) return (NULL); *type = etype; return (void*) &rxbuf; } /* * This function is called by Watt-32 (via _eth_xmit_hook). * If dbug_init() was called, we should trace packets sent. */ static int pcap_xmit_hook (const void *buf, unsigned len) { int rc = 0; if (pcap_pkt_debug > 0) dbug_write ("pcap_xmit_hook: "); if (active_dev && active_dev->xmit) if ((*active_dev->xmit) (active_dev, buf, len) > 0) rc = len; if (pcap_pkt_debug > 0) dbug_write (rc ? "ok\n" : "fail\n"); return (rc); } #endif static int pcap_sendpacket_dos (pcap_t *p, const void *buf, size_t len) { struct device *dev = p ? get_device(p->fd) : NULL; if (!dev || !dev->xmit) return (-1); return (*dev->xmit) (dev, buf, len); } /* * This function is called by Watt-32 in tcp_post_init(). * We should prevent Watt-32 from using BOOTP/DHCP/RARP etc. */ static void (*prev_post_hook) (void); static void pcap_init_hook (void) { _w32__bootp_on = _w32__dhcp_on = _w32__rarp_on = 0; _w32__do_mask_req = 0; _w32_dynamic_host = 0; if (prev_post_hook) (*prev_post_hook)(); } /* * Supress PRINT message from Watt-32's sock_init() */ static void null_print (void) {} /* * To use features of Watt-32 (netdb functions and socket etc.) * we must call sock_init(). But we set various hooks to prevent * using normal PKTDRVR functions in pcpkt.c. This should hopefully * make Watt-32 and pcap co-operate. */ static int init_watt32 (struct pcap *pcap, const char *dev_name, char *err_buf) { char *env; int rc, MTU, has_ip_addr; int using_pktdrv = 1; /* If user called sock_init() first, we need to reinit in * order to open debug/trace-file properly */ if (_watt_is_init) sock_exit(); env = getenv ("PCAP_DEBUG"); if (env && atoi(env) > 0 && pcap_pkt_debug < 0) /* if not already set */ { dbug_init(); pcap_pkt_debug = atoi (env); } _watt_do_exit = 0; /* prevent sock_init() calling exit() */ prev_post_hook = _w32_usr_post_init; _w32_usr_post_init = pcap_init_hook; _w32_print_hook = null_print; if (dev_name && strncmp(dev_name,"pkt",3)) using_pktdrv = FALSE; rc = sock_init(); has_ip_addr = (rc != 8); /* IP-address assignment failed */ /* if pcap is using a 32-bit driver w/o a pktdrvr loaded, we * just pretend Watt-32 is initialised okay. * * !! fix-me: The Watt-32 config isn't done if no pktdrvr * was found. In that case my_ip_addr + sin_mask * have default values. Should be taken from another * ini-file/environment in any case (ref. tcpdump.ini) */ _watt_is_init = 1; if (!using_pktdrv || !has_ip_addr) /* for now .... */ { static const char myip[] = "192.168.0.1"; static const char mask[] = "255.255.255.0"; printf ("Just guessing, using IP %s and netmask %s\n", myip, mask); my_ip_addr = aton (myip); _w32_sin_mask = aton (mask); } else if (rc && using_pktdrv) { sprintf (err_buf, "sock_init() failed, code %d", rc); return (0); } /* Set recv-hook for peeking in _eth_arrived(). */ #if (WATTCP_VER >= 0x0224) _eth_recv_hook = pcap_recv_hook; _eth_xmit_hook = pcap_xmit_hook; #endif /* Free the pkt-drvr handle allocated in pkt_init(). * The above hooks should thus use the handle reopened in open_driver() */ if (using_pktdrv) { _eth_release(); /* _eth_is_init = 1; */ /* hack to get Rx/Tx-hooks in Watt-32 working */ } memcpy (&pcap_save, pcap, sizeof(pcap_save)); MTU = pkt_get_mtu(); pcap_save.fcode.bf_insns = NULL; pcap_save.linktype = _eth_get_hwtype (NULL, NULL); pcap_save.snapshot = MTU > 0 ? MTU : ETH_MAX; /* assume 1514 */ #if 1 /* prevent use of resolve() and resolve_ip() */ last_nameserver = 0; #endif return (1); } int EISA_bus = 0; /* Where is natural place for this? */ /* * Application config hooks to set various driver parameters. */ static struct config_table debug_tab[] = { { "PKT.DEBUG", ARG_ATOI, &pcap_pkt_debug }, { "PKT.VECTOR", ARG_ATOX_W, NULL }, { "NDIS.DEBUG", ARG_ATOI, NULL }, #ifdef USE_32BIT_DRIVERS { "3C503.DEBUG", ARG_ATOI, &ei_debug }, { "3C503.IO_BASE", ARG_ATOX_W, &el2_dev.base_addr }, { "3C503.MEMORY", ARG_ATOX_W, &el2_dev.mem_start }, { "3C503.IRQ", ARG_ATOI, &el2_dev.irq }, { "3C505.DEBUG", ARG_ATOI, NULL }, { "3C505.BASE", ARG_ATOX_W, NULL }, { "3C507.DEBUG", ARG_ATOI, NULL }, { "3C509.DEBUG", ARG_ATOI, &el3_debug }, { "3C509.ILOOP", ARG_ATOI, &el3_max_loop }, { "3C529.DEBUG", ARG_ATOI, NULL }, { "3C575.DEBUG", ARG_ATOI, &debug_3c575 }, { "3C59X.DEBUG", ARG_ATOI, &vortex_debug }, { "3C59X.IFACE0", ARG_ATOI, &vortex_options[0] }, { "3C59X.IFACE1", ARG_ATOI, &vortex_options[1] }, { "3C59X.IFACE2", ARG_ATOI, &vortex_options[2] }, { "3C59X.IFACE3", ARG_ATOI, &vortex_options[3] }, { "3C90X.DEBUG", ARG_ATOX_W, &tc90xbc_debug }, { "ACCT.DEBUG", ARG_ATOI, ðpk_debug }, { "CS89.DEBUG", ARG_ATOI, &cs89_debug }, { "RTL8139.DEBUG", ARG_ATOI, &rtl8139_debug }, /* { "RTL8139.FDUPLEX", ARG_ATOI, &rtl8139_options }, */ { "SMC.DEBUG", ARG_ATOI, &ei_debug }, /* { "E100.DEBUG", ARG_ATOI, &e100_debug }, */ { "PCI.DEBUG", ARG_ATOI, &pci_debug }, { "BIOS32.DEBUG", ARG_ATOI, &bios32_debug }, { "IRQ.DEBUG", ARG_ATOI, &irq_debug }, { "TIMER.IRQ", ARG_ATOI, &timer_irq }, #endif { NULL } }; /* * pcap_config_hook() is an extension to application's config * handling. Uses Watt-32's config-table function. */ int pcap_config_hook (const char *name, const char *value) { return parse_config_table (debug_tab, NULL, name, value); } /* * Linked list of supported devices */ struct device *active_dev = NULL; /* the device we have opened */ struct device *probed_dev = NULL; /* the device we have probed */ const struct device *dev_base = &pkt_dev; /* list of network devices */ /* * PKTDRVR device functions */ int pcap_pkt_debug = -1; static void pkt_close (struct device *dev) { BOOL okay = PktExitDriver(); if (pcap_pkt_debug > 1) fprintf (stderr, "pkt_close(): %d\n", okay); if (dev->priv) free (dev->priv); dev->priv = NULL; } static int pkt_open (struct device *dev) { PKT_RX_MODE mode; if (dev->flags & IFF_PROMISC) mode = PDRX_ALL_PACKETS; else mode = PDRX_BROADCAST; if (!PktInitDriver(mode)) return (0); PktResetStatistics (pktInfo.handle); PktQueueBusy (FALSE); return (1); } static int pkt_xmit (struct device *dev, const void *buf, int len) { struct net_device_stats *stats = (struct net_device_stats*) dev->priv; if (pcap_pkt_debug > 0) dbug_write ("pcap_xmit\n"); if (!PktTransmit(buf,len)) { stats->tx_errors++; return (0); } return (len); } static void *pkt_stats (struct device *dev) { struct net_device_stats *stats = (struct net_device_stats*) dev->priv; if (!stats || !PktSessStatistics(pktInfo.handle)) return (NULL); stats->rx_packets = pktStat.inPackets; stats->rx_errors = pktStat.lost; stats->rx_missed_errors = PktRxDropped(); return (stats); } static int pkt_probe (struct device *dev) { if (!PktSearchDriver()) return (0); dev->open = pkt_open; dev->xmit = pkt_xmit; dev->close = pkt_close; dev->get_stats = pkt_stats; dev->copy_rx_buf = PktReceive; /* farmem peek and copy routine */ dev->get_rx_buf = NULL; dev->peek_rx_buf = NULL; dev->release_rx_buf = NULL; dev->priv = calloc (sizeof(struct net_device_stats), 1); if (!dev->priv) return (0); return (1); } /* * NDIS device functions */ static void ndis_close (struct device *dev) { #ifdef USE_NDIS2 NdisShutdown(); #endif ARGSUSED (dev); } static int ndis_open (struct device *dev) { int promis = (dev->flags & IFF_PROMISC); #ifdef USE_NDIS2 if (!NdisInit(promis)) return (0); return (1); #else ARGSUSED (promis); return (0); #endif } static void *ndis_stats (struct device *dev) { static struct net_device_stats stats; /* to-do */ ARGSUSED (dev); return (&stats); } static int ndis_probe (struct device *dev) { #ifdef USE_NDIS2 if (!NdisOpen()) return (0); #endif dev->open = ndis_open; dev->xmit = NULL; dev->close = ndis_close; dev->get_stats = ndis_stats; dev->copy_rx_buf = NULL; /* to-do */ dev->get_rx_buf = NULL; /* upcall is from rmode driver */ dev->peek_rx_buf = NULL; dev->release_rx_buf = NULL; return (0); } /* * Search & probe for supported 32-bit (pmode) pcap devices */ #if defined(USE_32BIT_DRIVERS) struct device el2_dev LOCKED_VAR = { "3c503", "EtherLink II", 0, 0,0,0,0,0,0, NULL, el2_probe }; struct device el3_dev LOCKED_VAR = { "3c509", "EtherLink III", 0, 0,0,0,0,0,0, &el2_dev, el3_probe }; struct device tc515_dev LOCKED_VAR = { "3c515", "EtherLink PCI", 0, 0,0,0,0,0,0, &el3_dev, tc515_probe }; struct device tc59_dev LOCKED_VAR = { "3c59x", "EtherLink PCI", 0, 0,0,0,0,0,0, &tc515_dev, tc59x_probe }; struct device tc90xbc_dev LOCKED_VAR = { "3c90x", "EtherLink 90X", 0, 0,0,0,0,0,0, &tc59_dev, tc90xbc_probe }; struct device wd_dev LOCKED_VAR = { "wd", "Westen Digital", 0, 0,0,0,0,0,0, &tc90xbc_dev, wd_probe }; struct device ne_dev LOCKED_VAR = { "ne", "NEx000", 0, 0,0,0,0,0,0, &wd_dev, ne_probe }; struct device acct_dev LOCKED_VAR = { "acct", "Accton EtherPocket", 0, 0,0,0,0,0,0, &ne_dev, ethpk_probe }; struct device cs89_dev LOCKED_VAR = { "cs89", "Crystal Semiconductor", 0, 0,0,0,0,0,0, &acct_dev, cs89x0_probe }; struct device rtl8139_dev LOCKED_VAR = { "rtl8139", "RealTek PCI", 0, 0,0,0,0,0,0, &cs89_dev, rtl8139_probe /* dev->probe routine */ }; /* * Dequeue routine is called by polling. * NOTE: the queue-element is not copied, only a pointer is * returned at '*buf' */ int peek_rxbuf (BYTE **buf) { struct rx_elem *tail, *head; PCAP_ASSERT (pktq_check (&active_dev->queue)); DISABLE(); tail = pktq_out_elem (&active_dev->queue); head = pktq_in_elem (&active_dev->queue); ENABLE(); if (head != tail) { PCAP_ASSERT (tail->size < active_dev->queue.elem_size-4-2); *buf = &tail->data[0]; return (tail->size); } *buf = NULL; return (0); } /* * Release buffer we peeked at above. */ int release_rxbuf (BYTE *buf) { #ifndef NDEBUG struct rx_elem *tail = pktq_out_elem (&active_dev->queue); PCAP_ASSERT (&tail->data[0] == buf); #else ARGSUSED (buf); #endif pktq_inc_out (&active_dev->queue); return (1); } /* * get_rxbuf() routine (in locked code) is called from IRQ handler * to request a buffer. Interrupts are disabled and we have a 32kB stack. */ BYTE *get_rxbuf (int len) { int idx; if (len < ETH_MIN || len > ETH_MAX) return (NULL); idx = pktq_in_index (&active_dev->queue); #ifdef DEBUG { static int fan_idx LOCKED_VAR = 0; writew ("-\\|/"[fan_idx++] | (15 << 8), /* white on black colour */ 0xB8000 + 2*79); /* upper-right corner, 80-col colour screen */ fan_idx &= 3; } /* writew (idx + '0' + 0x0F00, 0xB8000 + 2*78); */ #endif if (idx != active_dev->queue.out_index) { struct rx_elem *head = pktq_in_elem (&active_dev->queue); head->size = len; active_dev->queue.in_index = idx; return (&head->data[0]); } /* !!to-do: drop 25% of the oldest element */ pktq_clear (&active_dev->queue); return (NULL); } /* * Simple ring-buffer queue handler for reception of packets * from network driver. */ #define PKTQ_MARKER 0xDEADBEEF static int pktq_check (struct rx_ringbuf *q) { #ifndef NDEBUG int i; char *buf; #endif if (!q || !q->num_elem || !q->buf_start) return (0); #ifndef NDEBUG buf = q->buf_start; for (i = 0; i < q->num_elem; i++) { buf += q->elem_size; if (*(DWORD*)(buf - sizeof(DWORD)) != PKTQ_MARKER) return (0); } #endif return (1); } static int pktq_init (struct rx_ringbuf *q, int size, int num, char *pool) { int i; q->elem_size = size; q->num_elem = num; q->buf_start = pool; q->in_index = 0; q->out_index = 0; PCAP_ASSERT (size >= sizeof(struct rx_elem) + sizeof(DWORD)); PCAP_ASSERT (num); PCAP_ASSERT (pool); for (i = 0; i < num; i++) { #if 0 struct rx_elem *elem = (struct rx_elem*) pool; /* assert dword aligned elements */ PCAP_ASSERT (((unsigned)(&elem->data[0]) & 3) == 0); #endif pool += size; *(DWORD*) (pool - sizeof(DWORD)) = PKTQ_MARKER; } return (1); } /* * Increment the queue 'out_index' (tail). * Check for wraps. */ static int pktq_inc_out (struct rx_ringbuf *q) { q->out_index++; if (q->out_index >= q->num_elem) q->out_index = 0; return (q->out_index); } /* * Return the queue's next 'in_index' (head). * Check for wraps. */ static int pktq_in_index (struct rx_ringbuf *q) { volatile int index = q->in_index + 1; if (index >= q->num_elem) index = 0; return (index); } /* * Return the queue's head-buffer. */ static struct rx_elem *pktq_in_elem (struct rx_ringbuf *q) { return (struct rx_elem*) (q->buf_start + (q->elem_size * q->in_index)); } /* * Return the queue's tail-buffer. */ static struct rx_elem *pktq_out_elem (struct rx_ringbuf *q) { return (struct rx_elem*) (q->buf_start + (q->elem_size * q->out_index)); } /* * Clear the queue ring-buffer by setting head=tail. */ static void pktq_clear (struct rx_ringbuf *q) { q->in_index = q->out_index; } /* * Symbols that must be linkable for "gcc -O0" */ #undef __IOPORT_H #undef __DMA_H #define extern #define __inline__ #include "msdos/pm_drvr/ioport.h" #include "msdos/pm_drvr/dma.h" #endif /* USE_32BIT_DRIVERS */