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/* PPP for Linux * * Michael Callahan <callahan@maths.ox.ac.uk> * Al Longyear <longyear@netcom.com> * * Dynamic PPP devices by Jim Freeman <jfree@caldera.com>. * ppp_tty_receive ``noisy-raise-bug'' fixed by Ove Ewerlid <ewerlid@syscon.uu.se> * Fixed (I hope) the wait_queue trashing bug. Alan Cox <alan@redhat.com> * * ==FILEVERSION 980512== * * NOTE TO MAINTAINERS: * If you modify this file at all, please set the number above to the * date of the modification as YYMMDD (year month day). * ppp.c is shipped with a PPP distribution as well as with the kernel; * if everyone increases the FILEVERSION number above, then scripts * can do the right thing when deciding whether to install a new ppp.c * file. Don't change the format of that line otherwise, so the * installation script can recognize it. */ /* Sources: slip.c RFC1331: The Point-to-Point Protocol (PPP) for the Transmission of Multi-protocol Datagrams over Point-to-Point Links RFC1332: IPCP ppp-2.0 Flags for this module (any combination is acceptable for testing.): OPTIMIZE_FLAG_TIME - Number of jiffies to force sending of leading flag character. This is normally set to ((HZ * 3) / 2). This is 1.5 seconds. If zero then the leading flag is always sent. CHECK_CHARACTERS - Enable the checking on all received characters for 8 data bits, no parity. This adds a small amount of processing for each received character. */ #define OPTIMIZE_FLAG_TIME ((HZ * 3)/2) #define CHECK_CHARACTERS 1 #define PPP_COMPRESS 1 #ifndef PPP_MAX_DEV #define PPP_MAX_DEV 256 #endif /* $Id: ppp.c,v 1.1.1.1 2001-09-10 07:44:24 simons Exp $ * Added dynamic allocation of channels to eliminate * compiled-in limits on the number of channels. * * Dynamic channel allocation code Copyright 1995 Caldera, Inc., * released under the GNU General Public License Version 2. */ #include <linux/module.h> #include <linux/kernel.h> #include <linux/sched.h> #include <linux/types.h> #include <linux/fcntl.h> #include <linux/interrupt.h> #include <linux/ptrace.h> #include <linux/ioport.h> #include <linux/in.h> #include <linux/malloc.h> #include <linux/tty.h> #include <linux/errno.h> #include <linux/sched.h> /* to get the struct task_struct */ #include <linux/string.h> /* used in new tty drivers */ #include <linux/signal.h> /* used in new tty drivers */ #include <asm/system.h> #include <asm/bitops.h> #include <asm/segment.h> #include <linux/if.h> #include <linux/if_ether.h> #include <linux/netdevice.h> #include <linux/skbuff.h> #include <linux/inet.h> #include <linux/ioctl.h> typedef struct sk_buff sk_buff; #define skb_data(skb) ((__u8 *) (skb)->data) #include <linux/ip.h> #include <linux/tcp.h> #include <linux/if_arp.h> #include <net/slhc_vj.h> #define fcstab ppp_crc16_table /* Name of the table in the kernel */ #include <linux/ppp_defs.h> #include <linux/socket.h> #include <linux/if_ppp.h> #include <linux/if_pppvar.h> #undef PACKETPTR #define PACKETPTR 1 #include <linux/ppp-comp.h> #undef PACKETPTR #define bsd_decompress (*ppp->sc_rcomp->decompress) #define bsd_compress (*ppp->sc_xcomp->compress) #ifndef PPP_IPX #define PPP_IPX 0x2b /* IPX protocol over PPP */ #endif #ifndef PPP_LQR #define PPP_LQR 0xc025 /* Link Quality Reporting Protocol */ #endif #define QUIET static int ppp_register_compressor (struct compressor *cp); static void ppp_unregister_compressor (struct compressor *cp); /* * Local functions */ static struct compressor *find_compressor (int type); static void ppp_init_ctrl_blk (register struct ppp *); static void ppp_kick_tty (struct ppp *, struct ppp_buffer *bfr); static int ppp_doframe (struct ppp *); static struct ppp *ppp_alloc (void); static struct ppp *ppp_find (int pid_value); static void ppp_print_buffer (const __u8 *, const __u8 *, int); extern inline void ppp_stuff_char (struct ppp *ppp, register struct ppp_buffer *buf, register __u8 chr); extern inline int lock_buffer (register struct ppp_buffer *buf); static int rcv_proto_ip (struct ppp *, __u16, __u8 *, int); static int rcv_proto_ipx (struct ppp *, __u16, __u8 *, int); static int rcv_proto_vjc_comp (struct ppp *, __u16, __u8 *, int); static int rcv_proto_vjc_uncomp (struct ppp *, __u16, __u8 *, int); static int rcv_proto_unknown (struct ppp *, __u16, __u8 *, int); static int rcv_proto_lqr (struct ppp *, __u16, __u8 *, int); static void ppp_doframe_lower (struct ppp *, __u8 *, int); static int ppp_doframe (struct ppp *); extern int ppp_bsd_compressor_init(void); static void ppp_proto_ccp (struct ppp *ppp, __u8 *dp, int len, int rcvd); static int rcv_proto_ccp (struct ppp *, __u16, __u8 *, int); #define ins_char(pbuf,c) (buf_base(pbuf) [(pbuf)->count++] = (__u8)(c)) #ifndef OPTIMIZE_FLAG_TIME #define OPTIMIZE_FLAG_TIME 0 #endif #ifndef PPP_MAX_DEV #define PPP_MAX_DEV 256 #endif /* * Parameters which may be changed via insmod. */ static int flag_time = OPTIMIZE_FLAG_TIME; static int max_dev = PPP_MAX_DEV; /* * The "main" procedure to the ppp device */ int ppp_init (struct device *); /* * Network device driver callback routines */ static int ppp_dev_open (struct device *); static int ppp_dev_ioctl (struct device *dev, struct ifreq *ifr, int cmd); static int ppp_dev_close (struct device *); static int ppp_dev_xmit (sk_buff *, struct device *); static struct enet_statistics *ppp_dev_stats (struct device *); static int ppp_dev_header (sk_buff *, struct device *, __u16, void *, void *, unsigned int); static int ppp_dev_rebuild (void *eth, struct device *dev, unsigned long raddr, struct sk_buff *skb); /* * TTY callbacks */ static int ppp_tty_read (struct tty_struct *, struct file *, __u8 *, unsigned int); static int ppp_tty_write (struct tty_struct *, struct file *, const __u8 *, unsigned int); static int ppp_tty_ioctl (struct tty_struct *, struct file *, unsigned int, unsigned long); static int ppp_tty_select (struct tty_struct *tty, struct inode *inode, struct file *filp, int sel_type, select_table * wait); static int ppp_tty_open (struct tty_struct *); static void ppp_tty_close (struct tty_struct *); static int ppp_tty_room (struct tty_struct *tty); static void ppp_tty_receive (struct tty_struct *tty, const __u8 * cp, char *fp, int count); static void ppp_tty_wakeup (struct tty_struct *tty); #define CHECK_PPP(a) if (!ppp->inuse) { printk (ppp_warning, __LINE__); return a;} #define CHECK_PPP_VOID() if (!ppp->inuse) { printk (ppp_warning, __LINE__); return;} #define in_xmap(ppp,c) (ppp->xmit_async_map[(c) >> 5] & (1 << ((c) & 0x1f))) #define in_rmap(ppp,c) ((((unsigned int) (__u8) (c)) < 0x20) && \ ppp->recv_async_map & (1 << (c))) #define bset(p,b) ((p)[(b) >> 5] |= (1 << ((b) & 0x1f))) #define tty2ppp(tty) ((struct ppp *) (tty->disc_data)) #define dev2ppp(dev) ((struct ppp *) (dev->priv)) #define ppp2tty(ppp) ((struct tty_struct *) ppp->tty) #define ppp2dev(ppp) ((struct device *) ppp->dev) struct ppp_hdr { __u8 address; __u8 control; __u8 protocol[2]; }; #define PPP_HARD_HDR_LEN (sizeof (struct ppp_hdr)) typedef struct ppp_ctrl { struct ppp_ctrl *next; /* Next structure in the list */ char name [8]; /* Name of the device */ struct ppp ppp; /* PPP control table */ struct device dev; /* Device information table */ } ppp_ctrl_t; static ppp_ctrl_t *ppp_list = NULL; #define ctl2ppp(ctl) (struct ppp *) &ctl->ppp #define ctl2dev(ctl) (struct device *) &ctl->dev #undef PPP_NRUNIT /* Buffer types */ #define BUFFER_TYPE_DEV_RD 0 /* ppp read buffer */ #define BUFFER_TYPE_TTY_WR 1 /* tty write buffer */ #define BUFFER_TYPE_DEV_WR 2 /* ppp write buffer */ #define BUFFER_TYPE_TTY_RD 3 /* tty read buffer */ #define BUFFER_TYPE_VJ 4 /* vj compression buffer */ /* Define this string only once for all macro invocations */ static char ppp_warning[] = KERN_WARNING "PPP: ALERT! not INUSE! %d\n"; static char szVersion[] = PPP_VERSION; /* * Information for the protocol decoder */ typedef int (*pfn_proto) (struct ppp *, __u16, __u8 *, int); typedef struct ppp_proto_struct { int proto; pfn_proto func; } ppp_proto_type; static ppp_proto_type proto_list[] = { { PPP_IP, rcv_proto_ip }, { PPP_IPX, rcv_proto_ipx }, { PPP_VJC_COMP, rcv_proto_vjc_comp }, { PPP_VJC_UNCOMP, rcv_proto_vjc_uncomp }, { PPP_LQR, rcv_proto_lqr }, { PPP_CCP, rcv_proto_ccp }, { 0, rcv_proto_unknown } /* !!! MUST BE LAST !!! */ }; __u16 ppp_crc16_table[256] = { 0x0000, 0x1189, 0x2312, 0x329b, 0x4624, 0x57ad, 0x6536, 0x74bf, 0x8c48, 0x9dc1, 0xaf5a, 0xbed3, 0xca6c, 0xdbe5, 0xe97e, 0xf8f7, 0x1081, 0x0108, 0x3393, 0x221a, 0x56a5, 0x472c, 0x75b7, 0x643e, 0x9cc9, 0x8d40, 0xbfdb, 0xae52, 0xdaed, 0xcb64, 0xf9ff, 0xe876, 0x2102, 0x308b, 0x0210, 0x1399, 0x6726, 0x76af, 0x4434, 0x55bd, 0xad4a, 0xbcc3, 0x8e58, 0x9fd1, 0xeb6e, 0xfae7, 0xc87c, 0xd9f5, 0x3183, 0x200a, 0x1291, 0x0318, 0x77a7, 0x662e, 0x54b5, 0x453c, 0xbdcb, 0xac42, 0x9ed9, 0x8f50, 0xfbef, 0xea66, 0xd8fd, 0xc974, 0x4204, 0x538d, 0x6116, 0x709f, 0x0420, 0x15a9, 0x2732, 0x36bb, 0xce4c, 0xdfc5, 0xed5e, 0xfcd7, 0x8868, 0x99e1, 0xab7a, 0xbaf3, 0x5285, 0x430c, 0x7197, 0x601e, 0x14a1, 0x0528, 0x37b3, 0x263a, 0xdecd, 0xcf44, 0xfddf, 0xec56, 0x98e9, 0x8960, 0xbbfb, 0xaa72, 0x6306, 0x728f, 0x4014, 0x519d, 0x2522, 0x34ab, 0x0630, 0x17b9, 0xef4e, 0xfec7, 0xcc5c, 0xddd5, 0xa96a, 0xb8e3, 0x8a78, 0x9bf1, 0x7387, 0x620e, 0x5095, 0x411c, 0x35a3, 0x242a, 0x16b1, 0x0738, 0xffcf, 0xee46, 0xdcdd, 0xcd54, 0xb9eb, 0xa862, 0x9af9, 0x8b70, 0x8408, 0x9581, 0xa71a, 0xb693, 0xc22c, 0xd3a5, 0xe13e, 0xf0b7, 0x0840, 0x19c9, 0x2b52, 0x3adb, 0x4e64, 0x5fed, 0x6d76, 0x7cff, 0x9489, 0x8500, 0xb79b, 0xa612, 0xd2ad, 0xc324, 0xf1bf, 0xe036, 0x18c1, 0x0948, 0x3bd3, 0x2a5a, 0x5ee5, 0x4f6c, 0x7df7, 0x6c7e, 0xa50a, 0xb483, 0x8618, 0x9791, 0xe32e, 0xf2a7, 0xc03c, 0xd1b5, 0x2942, 0x38cb, 0x0a50, 0x1bd9, 0x6f66, 0x7eef, 0x4c74, 0x5dfd, 0xb58b, 0xa402, 0x9699, 0x8710, 0xf3af, 0xe226, 0xd0bd, 0xc134, 0x39c3, 0x284a, 0x1ad1, 0x0b58, 0x7fe7, 0x6e6e, 0x5cf5, 0x4d7c, 0xc60c, 0xd785, 0xe51e, 0xf497, 0x8028, 0x91a1, 0xa33a, 0xb2b3, 0x4a44, 0x5bcd, 0x6956, 0x78df, 0x0c60, 0x1de9, 0x2f72, 0x3efb, 0xd68d, 0xc704, 0xf59f, 0xe416, 0x90a9, 0x8120, 0xb3bb, 0xa232, 0x5ac5, 0x4b4c, 0x79d7, 0x685e, 0x1ce1, 0x0d68, 0x3ff3, 0x2e7a, 0xe70e, 0xf687, 0xc41c, 0xd595, 0xa12a, 0xb0a3, 0x8238, 0x93b1, 0x6b46, 0x7acf, 0x4854, 0x59dd, 0x2d62, 0x3ceb, 0x0e70, 0x1ff9, 0xf78f, 0xe606, 0xd49d, 0xc514, 0xb1ab, 0xa022, 0x92b9, 0x8330, 0x7bc7, 0x6a4e, 0x58d5, 0x495c, 0x3de3, 0x2c6a, 0x1ef1, 0x0f78 }; #ifdef CHECK_CHARACTERS static __u32 paritytab[8] = { 0x96696996, 0x69969669, 0x69969669, 0x96696996, 0x69969669, 0x96696996, 0x96696996, 0x69969669 }; #endif /* local function to store a value into the LQR frame */ extern inline __u8 * store_long (register __u8 *p, register int value) { *p++ = (__u8) (value >> 24); *p++ = (__u8) (value >> 16); *p++ = (__u8) (value >> 8); *p++ = (__u8) value; return p; } /************************************************************* * INITIALIZATION *************************************************************/ /* This procedure is called once and once only to define who we are to * the operating system and the various procedures that it may use in * accessing the ppp protocol. */ static int ppp_first_time (void) { static struct tty_ldisc ppp_ldisc; int status; printk (KERN_INFO "PPP: version %s (dynamic channel allocation)" "\n", szVersion); #ifndef MODULE /* slhc module logic has its own copyright announcement */ printk (KERN_INFO "TCP compression code copyright 1989 Regents of the " "University of California\n"); #endif printk (KERN_INFO "PPP Dynamic channel allocation code copyright 1995 " "Caldera, Inc.\n"); /* * Register the tty discipline */ (void) memset (&ppp_ldisc, 0, sizeof (ppp_ldisc)); ppp_ldisc.magic = TTY_LDISC_MAGIC; ppp_ldisc.open = ppp_tty_open; ppp_ldisc.close = ppp_tty_close; ppp_ldisc.read = ppp_tty_read; ppp_ldisc.write = ppp_tty_write; ppp_ldisc.ioctl = ppp_tty_ioctl; ppp_ldisc.select = ppp_tty_select; ppp_ldisc.receive_room = ppp_tty_room; ppp_ldisc.receive_buf = ppp_tty_receive; ppp_ldisc.write_wakeup = ppp_tty_wakeup; status = tty_register_ldisc (N_PPP, &ppp_ldisc); if (status == 0) printk (KERN_INFO "PPP line discipline registered.\n"); else printk (KERN_ERR "error registering line discipline: %d\n", status); return status; } /************************************************************* * INITIALIZATION *************************************************************/ /* called when the device is actually created */ static int ppp_init_dev (struct device *dev) { int indx; dev->hard_header = ppp_dev_header; dev->rebuild_header = ppp_dev_rebuild; dev->hard_header_len = PPP_HARD_HDR_LEN; /* device INFO */ dev->mtu = PPP_MTU; dev->hard_start_xmit = ppp_dev_xmit; dev->open = ppp_dev_open; dev->stop = ppp_dev_close; dev->get_stats = ppp_dev_stats; dev->do_ioctl = ppp_dev_ioctl; dev->addr_len = 0; dev->tx_queue_len = 10; dev->type = ARPHRD_PPP; for (indx = 0; indx < DEV_NUMBUFFS; indx++) skb_queue_head_init (&dev->buffs[indx]); /* New-style flags */ #ifdef IFF_SOFTHEADERS /* Needed to make SOCK_PACKET work correctly in * memory fussy kernels. */ dev->flags = IFF_POINTOPOINT|IFF_SOFTHEADERS; #else dev->flags = IFF_POINTOPOINT; #endif dev->family = AF_INET; dev->pa_addr = 0; dev->pa_brdaddr = 0; dev->pa_mask = 0; dev->pa_alen = 4; /* sizeof (__u32) */ return 0; } /* * Local procedure to initialize the ppp structure */ static void ppp_init_ctrl_blk (register struct ppp *ppp) { ppp->magic = PPP_MAGIC; ppp->toss = 0xE0; ppp->escape = 0; ppp->flags = 0; ppp->mtu = PPP_MTU; ppp->mru = PPP_MRU; memset (ppp->xmit_async_map, 0, sizeof (ppp->xmit_async_map)); ppp->xmit_async_map[0] = 0xffffffff; ppp->xmit_async_map[3] = 0x60000000; ppp->recv_async_map = 0x00000000; ppp->rbuf = NULL; ppp->wbuf = NULL; ppp->ubuf = NULL; ppp->cbuf = NULL; ppp->slcomp = NULL; #if 0 /* AC - We don't want to initialise this as the wait queue may still be live. Having someone waiting on the old and the new queue is fine the old people will unhook themselves so just set this up in ppp_alloc */ ppp->read_wait = NULL; ppp->write_wait = NULL; #endif ppp->last_xmit = jiffies - flag_time; /* clear statistics */ memset (&ppp->stats, '\0', sizeof (struct pppstat)); /* Reset the demand dial information */ ppp->ddinfo.xmit_idle= /* time since last NP packet sent */ ppp->ddinfo.recv_idle=jiffies; /* time since last NP packet received */ /* PPP compression data */ ppp->sc_xc_state = ppp->sc_rc_state = NULL; } static struct symbol_table ppp_syms = { #include <linux/symtab_begin.h> X(ppp_register_compressor), X(ppp_unregister_compressor), X(ppp_crc16_table), #include <linux/symtab_end.h> }; /* called at boot/load time for each ppp device defined in the kernel */ #ifndef MODULE int ppp_init (struct device *dev) { static int first_time = 1; int answer = 0; if (first_time) { first_time = 0; answer = ppp_first_time(); if (answer == 0) (void) register_symtab (&ppp_syms); } if (answer == 0) answer = -ENODEV; return answer; } #endif /* * Routine to allocate a buffer for later use by the driver. */ static struct ppp_buffer * ppp_alloc_buf (int size, int type) { struct ppp_buffer *buf; buf = (struct ppp_buffer *) kmalloc (size + sizeof (struct ppp_buffer), GFP_ATOMIC); if (buf != NULL) { buf->size = size - 1; /* Mask for the buffer size */ buf->type = type; buf->locked = 0; buf->count = 0; buf->head = 0; buf->tail = 0; buf->fcs = PPP_INITFCS; } return (buf); } /* * Routine to release the allocated buffer. */ static void ppp_free_buf (struct ppp_buffer *ptr) { if (ptr != NULL) kfree (ptr); } /* * Lock the indicated transmit buffer */ extern inline int lock_buffer (register struct ppp_buffer *buf) { register int state; int flags; /* * Save the current state and if free then set it to the "busy" state */ save_flags (flags); cli (); state = buf->locked; if (state == 0) buf->locked = 2; restore_flags (flags); return (state); } /* * MTU has been changed by the IP layer. Unfortunately we are not told * about this, but we spot it ourselves and fix things up. We could be * in an upcall from the tty driver, or in an ip packet queue. */ static int ppp_changedmtu (struct ppp *ppp, int new_mtu, int new_mru) { struct device *dev; struct ppp_buffer *new_rbuf; struct ppp_buffer *new_wbuf; struct ppp_buffer *new_cbuf; struct ppp_buffer *new_tbuf; struct ppp_buffer *old_rbuf; struct ppp_buffer *old_wbuf; struct ppp_buffer *old_cbuf; struct ppp_buffer *old_tbuf; int mtu, mru; /* * Allocate the buffer from the kernel for the data */ dev = ppp2dev (ppp); mru = new_mru; /* allow for possible escaping of every character */ mtu = (new_mtu * 2) + 20; /* RFC 1331, section 7.2 says the minimum value is 1500 bytes */ if (mru < PPP_MRU) mru = PPP_MRU; mru += 10; if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp: channel %s mtu = %d, mru = %d\n", dev->name, new_mtu, new_mru); new_wbuf = ppp_alloc_buf (mtu+PPP_HARD_HDR_LEN, BUFFER_TYPE_DEV_WR); new_tbuf = ppp_alloc_buf ((PPP_MTU * 2) + 24, BUFFER_TYPE_TTY_WR); new_rbuf = ppp_alloc_buf (mru + 84, BUFFER_TYPE_DEV_RD); new_cbuf = ppp_alloc_buf (mru+PPP_HARD_HDR_LEN, BUFFER_TYPE_VJ); /* * If the buffers failed to allocate then complain and release the partial * allocations. */ if (new_wbuf == NULL || new_tbuf == NULL || new_rbuf == NULL || new_cbuf == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp: failed to allocate new buffers\n"); ppp_free_buf (new_wbuf); ppp_free_buf (new_tbuf); ppp_free_buf (new_rbuf); ppp_free_buf (new_cbuf); return 0; } /* * Update the pointers to the new buffer structures. */ cli (); old_wbuf = ppp->wbuf; old_rbuf = ppp->rbuf; old_cbuf = ppp->cbuf; old_tbuf = ppp->tbuf; ppp->wbuf = new_wbuf; ppp->rbuf = new_rbuf; ppp->cbuf = new_cbuf; ppp->tbuf = new_tbuf; ppp->rbuf->size -= 80; /* reserve space for vj header expansion */ dev->mem_start = (unsigned long) buf_base (new_wbuf); dev->mem_end = (unsigned long) (dev->mem_start + mtu); dev->rmem_start = (unsigned long) buf_base (new_rbuf); dev->rmem_end = (unsigned long) (dev->rmem_start + mru); /* * Update the parameters for the new buffer sizes */ ppp->toss = 0xE0; /* To ignore characters until new FLAG */ ppp->escape = 0; /* No pending escape character */ dev->mtu = ppp->mtu = new_mtu; ppp->mru = new_mru; ppp->s1buf = NULL; ppp->s2buf = NULL; ppp->xbuf = NULL; ppp->tty->flags &= ~(1 << TTY_DO_WRITE_WAKEUP); ppp->flags &= ~SC_XMIT_BUSY; sti (); /* * Release old buffer pointers */ ppp_free_buf (old_rbuf); ppp_free_buf (old_wbuf); ppp_free_buf (old_cbuf); ppp_free_buf (old_tbuf); return 1; } /* * CCP is down; free (de)compressor state if necessary. */ static void ppp_ccp_closed (struct ppp *ppp) { if (ppp->sc_xc_state) { (*ppp->sc_xcomp->comp_free) (ppp->sc_xc_state); ppp->sc_xc_state = NULL; } if (ppp->sc_rc_state) { (*ppp->sc_rcomp->decomp_free) (ppp->sc_rc_state); ppp->sc_rc_state = NULL; } } /* * Called to release all of the information in the current PPP structure. * * It is called when the ppp device goes down or if it is unable to go * up. */ static void ppp_release (struct ppp *ppp) { struct tty_struct *tty; struct device *dev; tty = ppp2tty (ppp); dev = ppp2dev (ppp); ppp_ccp_closed (ppp); /* Ensure that the pppd process is not hanging on select() */ wake_up_interruptible (&ppp->read_wait); wake_up_interruptible (&ppp->write_wait); if (tty != NULL && tty->disc_data == ppp) tty->disc_data = NULL; /* Break the tty->ppp link */ if (dev && dev->flags & IFF_UP) { dev_close (dev); /* close the device properly */ dev->flags &= ~IFF_UP; /* prevent recursion */ } ppp_free_buf (ppp->rbuf); ppp_free_buf (ppp->wbuf); ppp_free_buf (ppp->cbuf); ppp_free_buf (ppp->ubuf); ppp_free_buf (ppp->tbuf); ppp->rbuf = ppp->wbuf = ppp->cbuf = ppp->tbuf = ppp->xbuf = ppp->s1buf = ppp->s2buf = ppp->ubuf = NULL; if (ppp->slcomp) { slhc_free (ppp->slcomp); ppp->slcomp = NULL; } ppp->inuse = 0; ppp->tty = NULL; } /* * Device callback. * * Called when the PPP device goes down in response to an ifconfig request. */ static void ppp_tty_close_local (struct tty_struct *tty, int sc_xfer) { struct ppp *ppp = tty2ppp (tty); if (ppp != NULL) { if (ppp->magic != PPP_MAGIC) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp: trying to close unopened tty!\n"); } else { CHECK_PPP_VOID(); ppp->sc_xfer = sc_xfer; if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp: channel %s closing.\n", ppp2dev(ppp) -> name); ppp_release (ppp); MOD_DEC_USE_COUNT; } } } static void ppp_tty_close (struct tty_struct *tty) { ppp_tty_close_local (tty, 0); } /* * TTY callback. * * Called when the tty discipline is switched to PPP. */ static int ppp_tty_open (struct tty_struct *tty) { struct ppp *ppp = tty2ppp (tty); int indx; /* * There should not be an existing table for this slot. */ if (ppp) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_tty_open: gack! tty already associated to %s!\n", ppp->magic == PPP_MAGIC ? ppp2dev(ppp)->name : "unknown"); return -EEXIST; } /* * Allocate the structure from the system */ ppp = ppp_find(current->pid); if (ppp == NULL) { ppp = ppp_find(0); if (ppp == NULL) ppp = ppp_alloc(); } if (ppp == NULL) { printk (KERN_WARNING "ppp_tty_open: couldn't allocate ppp channel\n"); return -ENFILE; } /* * Initialize the control block */ ppp_init_ctrl_blk (ppp); ppp->tty = tty; tty->disc_data = ppp; /* * Flush any pending characters in the driver and discipline. */ if (tty->ldisc.flush_buffer) tty->ldisc.flush_buffer (tty); if (tty->driver.flush_buffer) tty->driver.flush_buffer (tty); /* * Allocate space for the default VJ header compression slots */ ppp->slcomp = slhc_init (16, 16); if (ppp->slcomp == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_tty_open: no space for compression buffers!\n"); ppp_release (ppp); return -ENOMEM; } /* * Allocate space for the MTU and MRU buffers */ if (ppp_changedmtu (ppp, ppp2dev(ppp)->mtu, ppp->mru) == 0) { ppp_release (ppp); return -ENOMEM; } /* * Allocate space for a user level buffer */ ppp->ubuf = ppp_alloc_buf (RBUFSIZE, BUFFER_TYPE_TTY_RD); if (ppp->ubuf == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_tty_open: no space for user receive buffer\n"); ppp_release (ppp); return -ENOMEM; } if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp: channel %s open\n", ppp2dev(ppp)->name); for (indx = 0; indx < NUM_NP; ++indx) ppp->sc_npmode[indx] = NPMODE_PASS; MOD_INC_USE_COUNT; return (ppp->line); } /* * Local function to send the next portion of the buffer. * * Called by the tty driver's tty_wakeup function should it be entered * because the partial buffer was transmitted. * * Called by kick_tty to send the initial portion of the buffer. * * Completion processing of the buffer transmission is handled here. */ static void ppp_tty_wakeup_code (struct ppp *ppp, struct tty_struct *tty, struct ppp_buffer *xbuf) { register int count, actual; /* * Prevent re-entrancy by ensuring that this routine is called only once. */ cli (); if (ppp->flags & SC_XMIT_BUSY) { sti (); return; } ppp->flags |= SC_XMIT_BUSY; sti (); /* * Send the next block of data to the modem */ count = xbuf->count - xbuf->tail; actual = tty->driver.write (tty, 0, buf_base (xbuf) + xbuf->tail, count); /* * Terminate transmission of any block which may have an error. * This could occur should the carrier drop. */ if (actual < 0) { ppp->stats.ppp_oerrors++; actual = count; } else ppp->bytes_sent += actual; /* * If the buffer has been transmitted then clear the indicators. */ xbuf->tail += actual; if (actual == count) { xbuf = NULL; ppp->flags &= ~SC_XMIT_BUSY; /* * Complete the transmission on the current buffer. */ xbuf = ppp->xbuf; if (xbuf != NULL) { tty->flags &= ~(1 << TTY_DO_WRITE_WAKEUP); xbuf->locked = 0; ppp->xbuf = NULL; /* * If the completed buffer came from the device write, then complete the * transmission block. */ if (ppp2dev (ppp) -> flags & IFF_UP) { if (xbuf->type == BUFFER_TYPE_DEV_WR) ppp2dev (ppp)->tbusy = 0; mark_bh (NET_BH); } /* * Wake up the transmission queue for all completion events. */ wake_up_interruptible (&ppp->write_wait); /* * Look at the priorities. Choose a daemon write over the device driver. */ cli(); xbuf = ppp->s1buf; ppp->s1buf = NULL; if (xbuf == NULL) { xbuf = ppp->s2buf; ppp->s2buf = NULL; } sti(); /* * If there is a pending buffer then transmit it now. */ if (xbuf != NULL) { ppp->flags &= ~SC_XMIT_BUSY; ppp_kick_tty (ppp, xbuf); return; } } } /* * Clear the re-entry flag */ ppp->flags &= ~SC_XMIT_BUSY; } /* * This function is called by the tty driver when the transmit buffer has * additional space. It is used by the ppp code to continue to transmit * the current buffer should the buffer have been partially sent. * * In addition, it is used to send the first part of the buffer since the * logic and the inter-locking would be identical. */ static void ppp_tty_wakeup (struct tty_struct *tty) { struct ppp_buffer *xbuf; struct ppp *ppp = tty2ppp (tty); if (!ppp) return; if (ppp->magic != PPP_MAGIC) return; /* * Ensure that there is a transmission pending. Clear the re-entry flag if * there is no pending buffer. Otherwise, send the buffer. */ xbuf = ppp->xbuf; if (xbuf == NULL) tty->flags &= ~(1 << TTY_DO_WRITE_WAKEUP); else ppp_tty_wakeup_code (ppp, tty, xbuf); } /* * This function is called to transmit a buffer to the remote. The buffer * is placed on the pending queue if there is presently a buffer being * sent or it is transmitted with the aid of ppp_tty_wakeup. */ static void ppp_kick_tty (struct ppp *ppp, struct ppp_buffer *xbuf) { register int flags; /* * Hold interrupts. */ save_flags (flags); cli (); /* * Control the flags which are best performed with the interrupts masked. */ xbuf->locked = 1; xbuf->tail = 0; /* * If the transmitter is busy then place the buffer on the appropriate * priority queue. */ if (ppp->xbuf != NULL) { if (xbuf->type == BUFFER_TYPE_TTY_WR) ppp->s1buf = xbuf; else ppp->s2buf = xbuf; restore_flags (flags); return; } /* * If the transmitter is not busy then this is the highest priority frame */ ppp->flags &= ~SC_XMIT_BUSY; ppp->tty->flags |= (1 << TTY_DO_WRITE_WAKEUP); ppp->xbuf = xbuf; restore_flags (flags); /* * Do the "tty wakeup_code" to actually send this buffer. */ ppp_tty_wakeup_code (ppp, ppp2tty (ppp), xbuf); } /************************************************************* * TTY INPUT * The following functions handle input that arrives from * the TTY. It recognizes PPP frames and either hands them * to the network layer or queues them for delivery to a * user process reading this TTY. *************************************************************/ /* * Callback function from tty driver. Return the amount of space left * in the receiver's buffer to decide if remote transmitter is to be * throttled. */ static int ppp_tty_room (struct tty_struct *tty) { return 65536; /* We can handle an infinite amount of data. :-) */ } /* * Callback function when data is available at the tty driver. */ static void ppp_tty_receive (struct tty_struct *tty, const __u8 * data, char *flags, int count) { register struct ppp *ppp = tty2ppp (tty); register struct ppp_buffer *buf = NULL; __u8 chr; /* * Fetch the pointer to the buffer. Be careful about race conditions. */ if (ppp != NULL) buf = ppp->rbuf; if (buf == NULL) return; /* * Verify the table pointer and ensure that the line is * still in PPP discipline. */ if (ppp->magic != PPP_MAGIC) { if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "PPP: handler called but couldn't find " "PPP struct.\n"); return; } CHECK_PPP_VOID (); /* * Print the buffer if desired */ if (ppp->flags & SC_LOG_RAWIN) ppp_print_buffer ("receive buffer", data, count); /* * Collect the character and error condition for the character. Set the toss * flag for the first character error. */ while (count-- > 0) { ppp->bytes_rcvd++; chr = *data++; if (flags) { if (*flags && ppp->toss == 0) ppp->toss = *flags; ++flags; } /* * Set the flags for 8 data bits and no parity. * * Actually, it sets the flags for d7 being 0/1 and parity being even/odd * so that the normal processing would have all flags set at the end of the * session. A missing flag bit would denote an error condition. */ #ifdef CHECK_CHARACTERS if (chr & 0x80) ppp->flags |= SC_RCV_B7_1; else ppp->flags |= SC_RCV_B7_0; if (paritytab[chr >> 5] & (1 << (chr & 0x1F))) ppp->flags |= SC_RCV_ODDP; else ppp->flags |= SC_RCV_EVNP; #endif /* * Branch on the character. Process the escape character. The sequence ESC ESC * is defined to be ESC. */ switch (chr) { case PPP_ESCAPE: /* PPP_ESCAPE: invert bit in next character */ ppp->escape = PPP_TRANS; break; /* * FLAG. This is the end of the block. If the block terminated by ESC FLAG, * then the block is to be ignored. In addition, characters before the very * first FLAG are also tossed by this procedure. */ case PPP_FLAG: /* PPP_FLAG: end of frame */ ppp->stats.ppp_ibytes += ppp->rbuf->count; if (ppp->escape) ppp->toss |= 0x80; /* * Process frames which are not to be ignored. If the processing failed, * then clean up the VJ tables. */ if ((ppp->toss & 0x80) != 0 || ppp_doframe (ppp) == 0) { slhc_toss (ppp->slcomp); } /* * Reset all indicators for the new frame to follow. */ buf->count = 0; buf->fcs = PPP_INITFCS; ppp->escape = 0; ppp->toss = 0; break; /* * All other characters in the data come here. If the character is in the * receive mask then ignore the character. */ default: if (in_rmap (ppp, chr)) break; /* * Adjust the character and if the frame is to be discarded then simply * ignore the character until the ending FLAG is received. */ chr ^= ppp->escape; ppp->escape = 0; if (ppp->toss != 0) break; /* * If the count sent is within reason then store the character, bump the * count, and update the FCS for the character. */ if (buf->count < buf->size) { buf_base (buf)[buf->count++] = chr; buf->fcs = PPP_FCS (buf->fcs, chr); break; } /* * The peer sent too much data. Set the flags to discard the current frame * and wait for the re-synchronization FLAG to be sent. */ ppp->stats.ppp_ierrors++; ppp->toss |= 0xC0; break; } } } /* * Put the input frame into the networking system for the indicated protocol */ static int ppp_rcv_rx (struct ppp *ppp, __u16 proto, __u8 * data, int count) { sk_buff *skb = dev_alloc_skb (count); /* * Generate a skb buffer for the new frame. */ if (skb == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_do_ip: packet dropped on %s (no memory)!\n", ppp2dev (ppp)->name); return 0; } /* * Move the received data from the input buffer to the skb buffer. */ skb->dev = ppp2dev (ppp); /* We are the device */ skb->protocol = proto; skb->mac.raw = skb_data(skb); memcpy (skb_put(skb,count), data, count); /* move data */ /* * Tag the frame and kick it to the proper receive routine */ skb->free = 1; ppp->ddinfo.recv_idle = jiffies; netif_rx (skb); return 1; } /* * Process the receipt of an IP frame */ static int rcv_proto_ip (struct ppp *ppp, __u16 proto, __u8 * data, int count) { if ((ppp2dev (ppp)->flags & IFF_UP) && (count > 0)) if (ppp->sc_npmode[NP_IP] == NPMODE_PASS) return ppp_rcv_rx (ppp, htons (ETH_P_IP), data, count); return 0; } /* * Process the receipt of an IPX frame */ static int rcv_proto_ipx (struct ppp *ppp, __u16 proto, __u8 * data, int count) { if (((ppp2dev (ppp)->flags & IFF_UP) != 0) && (count > 0)) return ppp_rcv_rx (ppp, htons (ETH_P_IPX), data, count); return 0; } /* * Process the receipt of an VJ Compressed frame */ static int rcv_proto_vjc_comp (struct ppp *ppp, __u16 proto, __u8 *data, int count) { if ((ppp->flags & SC_REJ_COMP_TCP) == 0) { int new_count = slhc_uncompress (ppp->slcomp, data, count); if (new_count >= 0) { return rcv_proto_ip (ppp, PPP_IP, data, new_count); } if (ppp->flags & SC_DEBUG) printk (KERN_NOTICE "ppp: error in VJ decompression\n"); } return 0; } /* * Process the receipt of an VJ Un-compressed frame */ static int rcv_proto_vjc_uncomp (struct ppp *ppp, __u16 proto, __u8 *data, int count) { if ((ppp->flags & SC_REJ_COMP_TCP) == 0) { if (slhc_remember (ppp->slcomp, data, count) > 0) { return rcv_proto_ip (ppp, PPP_IP, data, count); } if (ppp->flags & SC_DEBUG) printk (KERN_NOTICE "ppp: error in VJ memorizing\n"); } return 0; } /* * Receive all unclassified protocols. */ static int rcv_proto_unknown (struct ppp *ppp, __u16 proto, __u8 *data, int len) { int totlen; register int current_idx; #define PUTC(c) \ { \ buf_base (ppp->ubuf) [current_idx++] = (__u8) (c); \ current_idx &= ppp->ubuf->size; \ if (current_idx == ppp->ubuf->tail) \ goto failure; \ } /* * The total length includes the protocol data. * Lock the user information buffer. */ if (set_bit (0, &ppp->ubuf->locked)) { if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_us_queue: can't get lock\n"); } else { current_idx = ppp->ubuf->head; /* * Insert the buffer length (not counted), the protocol, and the data */ totlen = len + 2; PUTC (totlen >> 8); PUTC (totlen); PUTC (proto >> 8); PUTC (proto); totlen -= 2; while (totlen-- > 0) { PUTC (*data++); } #undef PUTC /* * The frame is complete. Update the head pointer and wakeup the pppd * process. */ ppp->ubuf->head = current_idx; clear_bit (0, &ppp->ubuf->locked); wake_up_interruptible (&ppp->read_wait); if (ppp->tty->fasync != NULL) kill_fasync (ppp->tty->fasync, SIGIO); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp: successfully queued %d bytes, flags = %x\n", len + 2, ppp->flags); return 1; /* * The buffer is full. Unlock the header */ failure: clear_bit (0, &ppp->ubuf->locked); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_us_queue: ran out of buffer space.\n"); } /* * Discard the frame. There are no takers for this protocol. */ if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp: dropping packet on the floor.\n"); slhc_toss (ppp->slcomp); return 0; } /* * Handle a CCP packet. * * The CCP packet is passed along to the pppd process just like any * other PPP frame. The difference is that some processing needs to be * immediate or the compressors will become confused on the peer. */ static void ppp_proto_ccp (struct ppp *ppp, __u8 *dp, int len, int rcvd) { int slen = CCP_LENGTH(dp); __u8 *opt = dp + CCP_HDRLEN; int opt_len = slen - CCP_HDRLEN; if (slen > len) return; switch (CCP_CODE(dp)) { case CCP_CONFREQ: case CCP_TERMREQ: case CCP_TERMACK: /* * CCP must be going down - disable compression */ if (ppp->flags & SC_CCP_UP) { ppp->flags &= ~(SC_CCP_UP | SC_COMP_RUN | SC_DECOMP_RUN); } break; case CCP_CONFACK: if ((ppp->flags & SC_CCP_OPEN) == 0) break; if (ppp->flags & SC_CCP_UP) break; if (slen < (CCP_HDRLEN + CCP_OPT_MINLEN)) break; if (slen < (CCP_OPT_LENGTH (opt) + CCP_HDRLEN)) break; /* * we're agreeing to send compressed packets. */ if (!rcvd) { if (ppp->sc_xc_state == NULL) break; if ((*ppp->sc_xcomp->comp_init) (ppp->sc_xc_state, opt, opt_len, ppp2dev (ppp)->base_addr, 0, ppp->flags)) ppp->flags |= SC_COMP_RUN; break; } /* * peer is agreeing to send compressed packets. */ if (ppp->sc_rc_state == NULL) break; if ((*ppp->sc_rcomp->decomp_init) (ppp->sc_rc_state, opt, opt_len, ppp2dev (ppp)->base_addr, 0, ppp->mru, ppp->flags)) { ppp->flags |= SC_DECOMP_RUN; ppp->flags &= ~(SC_DC_ERROR | SC_DC_FERROR); } break; /* * The protocol sequence is complete at this end */ case CCP_RESETACK: if ((ppp->flags & SC_CCP_UP) == 0) break; if (!rcvd) { if (ppp->sc_xc_state && (ppp->flags & SC_COMP_RUN)) (*ppp->sc_xcomp->comp_reset)(ppp->sc_xc_state); } else { if (ppp->sc_rc_state && (ppp->flags & SC_DECOMP_RUN)) { (*ppp->sc_rcomp->decomp_reset)(ppp->sc_rc_state); ppp->flags &= ~SC_DC_ERROR; } } break; } } static int rcv_proto_ccp (struct ppp *ppp, __u16 proto, __u8 *dp, int len) { ppp_proto_ccp (ppp, dp, len, 1); return rcv_proto_unknown (ppp, proto, dp, len); } /* * Handle a LQR packet. */ static int rcv_proto_lqr (struct ppp *ppp, __u16 proto, __u8 * data, int len) { return rcv_proto_unknown (ppp, proto, data, len); } /* on entry, a received frame is in ppp->rbuf.bufr check it and dispose as appropriate */ static void ppp_doframe_lower (struct ppp *ppp, __u8 *data, int count) { __u16 proto = PPP_PROTOCOL (data); ppp_proto_type *proto_ptr; /* * Ignore empty frames */ if (count <= 4) return; /* * Count the frame and print it */ ++ppp->stats.ppp_ipackets; if (ppp->flags & SC_LOG_INPKT) ppp_print_buffer ("receive frame", data, count); /* * Find the procedure to handle this protocol. The last one is marked * as a protocol 0 which is the 'catch-all' to feed it to the pppd daemon. */ proto_ptr = proto_list; while (proto_ptr->proto != 0 && proto_ptr->proto != proto) ++proto_ptr; /* * Update the appropriate statistic counter. */ if ((*proto_ptr->func) (ppp, proto, &data[PPP_HARD_HDR_LEN], count - PPP_HARD_HDR_LEN)) ppp->stats.ppp_ioctects += count; else ++ppp->stats.ppp_discards; } /* on entry, a received frame is in ppp->rbuf.bufr check it and dispose as appropriate */ static int ppp_doframe (struct ppp *ppp) { __u8 *data = buf_base (ppp->rbuf); int count = ppp->rbuf->count; int addr, ctrl, proto; int new_count; __u8 *new_data; /* * If there is a pending error from the receiver then log it and discard * the damaged frame. */ if (ppp->toss) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_toss: tossing frame, reason = %d\n", ppp->toss); ppp->stats.ppp_ierrors++; return 0; } /* * An empty frame is ignored. This occurs if the FLAG sequence precedes and * follows each frame. */ if (count == 0) return 1; /* * Generate an error if the frame is too small. */ if (count < PPP_HARD_HDR_LEN) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp: got runt ppp frame, %d chars\n", count); slhc_toss (ppp->slcomp); ppp->stats.ppp_ierrors++; return 1; } /* * Verify the CRC of the frame and discard the CRC characters from the * end of the buffer. */ if (ppp->rbuf->fcs != PPP_GOODFCS) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp: frame with bad fcs, excess = %x\n", ppp->rbuf->fcs ^ PPP_GOODFCS); ppp->stats.ppp_ierrors++; return 0; } count -= 2; /* ignore the fcs characters */ /* * Ignore the leading ADDRESS and CONTROL fields in the frame. */ addr = PPP_ALLSTATIONS; ctrl = PPP_UI; if ((data[0] == PPP_ALLSTATIONS) && (data[1] == PPP_UI)) { data += 2; count -= 2; } /* * Obtain the protocol from the frame */ proto = (__u16) *data++; if ((proto & 1) == 0) { proto = (proto << 8) | (__u16) *data++; --count; } /* * Rewrite the header with the full information. This may encroach upon * the 'filler' area in the buffer header. This is the purpose for the * filler. */ *(--data) = proto; *(--data) = proto >> 8; *(--data) = ctrl; *(--data) = addr; count += 3; /* * Process the active decompressor. */ if ((ppp->sc_rc_state != (void *) 0) && (ppp->flags & SC_DECOMP_RUN) && ((ppp->flags & (SC_DC_FERROR | SC_DC_ERROR)) == 0)) { if (proto == PPP_COMP) { /* * If the frame is compressed then decompress it. */ new_data = kmalloc (ppp->mru + 4, GFP_ATOMIC); if (new_data == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_doframe: no memory\n"); slhc_toss (ppp->slcomp); (*ppp->sc_rcomp->incomp) (ppp->sc_rc_state, data, count); return 1; } /* * Decompress the frame */ new_count = bsd_decompress (ppp->sc_rc_state, data, count, new_data, ppp->mru + 4); switch (new_count) { default: ppp_doframe_lower (ppp, new_data, new_count); kfree (new_data); return 1; case DECOMP_OK: break; case DECOMP_ERROR: ppp->flags |= SC_DC_ERROR; break; case DECOMP_FATALERROR: ppp->flags |= SC_DC_FERROR; break; } /* * Log the error condition and discard the frame. */ if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_proto_comp: " "decompress err %d\n", new_count); kfree (new_data); slhc_toss (ppp->slcomp); return 1; } /* * The frame is not special. Pass it through the compressor without * actually compressing the data */ (*ppp->sc_rcomp->incomp) (ppp->sc_rc_state, data, count); } /* * Process the uncompressed frame. */ ppp_doframe_lower (ppp, data, count); return 1; } /************************************************************* * LINE DISCIPLINE SUPPORT * The following functions form support user programs * which read and write data on a TTY with the PPP line * discipline. Reading is done from a circular queue, * filled by the lower TTY levels. *************************************************************/ /* read a PPP frame from the us_rbuff circular buffer, waiting if necessary */ static int ppp_tty_read (struct tty_struct *tty, struct file *file, __u8 * buf, unsigned int nr) { struct ppp *ppp = tty2ppp (tty); __u8 c; int len, indx; #define GETC(c) \ { \ c = buf_base (ppp->ubuf) [ppp->ubuf->tail++]; \ ppp->ubuf->tail &= ppp->ubuf->size; \ } /* * Validate the pointers */ if (!ppp) return -EIO; if (ppp->magic != PPP_MAGIC) return -EIO; CHECK_PPP (-ENXIO); if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_read: called buf=%p nr=%u\n", buf, nr); /* * Acquire the read lock. */ for (;;) { ppp = tty2ppp (tty); if (!ppp || ppp->magic != PPP_MAGIC || !ppp->inuse) return 0; if (set_bit (0, &ppp->ubuf->locked) != 0) { if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_read: sleeping(ubuf)\n"); current->timeout = 0; current->state = TASK_INTERRUPTIBLE; schedule (); if (current->signal & ~current->blocked) return -EINTR; continue; } /* * Before we attempt to write the frame to the user, ensure that the * user has access to the pages for the total buffer length. */ indx = verify_area (VERIFY_WRITE, buf, nr); if (indx != 0) return (indx); /* * Fetch the length of the buffer from the first two bytes. */ if (ppp->ubuf->head == ppp->ubuf->tail) len = 0; else { GETC (c); len = c << 8; GETC (c); len += c; } /* * If there is no length then wait for the data to arrive. */ if (len == 0) { /* no data */ clear_bit (0, &ppp->ubuf->locked); if (file->f_flags & O_NONBLOCK) { if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_read: no data " "(EAGAIN)\n"); return -EAGAIN; } current->timeout = 0; if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_read: sleeping(read_wait)\n"); interruptible_sleep_on (&ppp->read_wait); if (current->signal & ~current->blocked) return -EINTR; continue; } /* * Reset the time of the last read operation. */ if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_read: len = %d\n", len); /* * Ensure that the frame will fit within the caller's buffer. If not, then * discard the frame from the input buffer. */ if (len + 2 > nr) { /* Can't copy it, update us_rbuff_head */ if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp: read of %u bytes too small for %d " "frame\n", nr, len + 2); ppp->ubuf->tail += len; ppp->ubuf->tail &= ppp->ubuf->size; clear_bit (0, &ppp->ubuf->locked); ppp->stats.ppp_ierrors++; return -EOVERFLOW; } /* * Before we attempt to write the frame to the user, ensure that the * page tables are proper. */ indx = verify_area (VERIFY_WRITE, buf, len + 2); if (indx != 0) { ppp->ubuf->tail += len; ppp->ubuf->tail &= ppp->ubuf->size; clear_bit (0, &ppp->ubuf->locked); return (indx); } /* * Fake the insertion of the ADDRESS and CONTROL information because these * were not saved in the buffer. */ put_user (PPP_ALLSTATIONS, buf++); put_user (PPP_UI, buf++); indx = len; /* * Copy the received data from the buffer to the caller's area. */ while (indx-- > 0) { GETC (c); put_user (c, buf); ++buf; } clear_bit (0, &ppp->ubuf->locked); len += 2; /* Account for ADDRESS and CONTROL bytes */ if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_read: passing %d bytes up\n", len); return len; } #undef GETC } /* stuff a character into the transmit buffer, using PPP's way of escaping special characters. also, update fcs to take account of new character */ extern inline void ppp_stuff_char (struct ppp *ppp, register struct ppp_buffer *buf, register __u8 chr) { /* * The buffer should not be full. */ if (ppp->flags & SC_DEBUG) { if ((buf->count < 0) || (buf->count > 3000)) printk (KERN_DEBUG "ppp_stuff_char: %x %d\n", (unsigned int) buf->count, (unsigned int) chr); } /* * Update the FCS and if the character needs to be escaped, do it. */ buf->fcs = PPP_FCS (buf->fcs, chr); if (in_xmap (ppp, chr)) { chr ^= PPP_TRANS; ins_char (buf, PPP_ESCAPE); } /* * Add the character to the buffer. */ ins_char (buf, chr); } /* * Procedure to encode the data with the proper escaping and send the * data to the remote system. */ static void ppp_dev_xmit_lower (struct ppp *ppp, struct ppp_buffer *buf, __u8 *data, int count, int non_ip) { __u16 write_fcs; int address, control; int proto; /* * Insert the leading FLAG character */ buf->count = 0; if (non_ip || flag_time == 0) ins_char (buf, PPP_FLAG); else { if (jiffies - ppp->last_xmit > flag_time) ins_char (buf, PPP_FLAG); } ppp->last_xmit = jiffies; buf->fcs = PPP_INITFCS; /* * Emit the address/control information if needed */ address = PPP_ADDRESS (data); control = PPP_CONTROL (data); proto = PPP_PROTOCOL (data); if (address != PPP_ALLSTATIONS || control != PPP_UI || (ppp->flags & SC_COMP_AC) == 0) { ppp_stuff_char (ppp, buf, address); ppp_stuff_char (ppp, buf, control); } /* * Emit the protocol (compressed if possible) */ if ((ppp->flags & SC_COMP_PROT) == 0 || (proto & 0xFF00)) ppp_stuff_char (ppp, buf, proto >> 8); ppp_stuff_char (ppp, buf, proto); /* * Insert the data */ data += 4; count -= 4; while (count-- > 0) ppp_stuff_char (ppp, buf, *data++); /* * Add the trailing CRC and the final flag character */ write_fcs = buf->fcs ^ 0xFFFF; ppp_stuff_char (ppp, buf, write_fcs); ppp_stuff_char (ppp, buf, write_fcs >> 8); if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_dev_xmit_lower: fcs is %hx\n", write_fcs); /* * Add the trailing flag character */ ins_char (buf, PPP_FLAG); /* * Print the buffer */ if (ppp->flags & SC_LOG_FLUSH) ppp_print_buffer ("ppp flush", buf_base (buf), buf->count); else { if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_dev_xmit: writing %d chars\n", buf->count); } /* * Send the block to the tty driver. */ ppp->stats.ppp_obytes += buf->count; ppp_kick_tty (ppp, buf); } /* * Send an frame to the remote with the proper bsd compression. * * Return 0 if frame was queued for transmission. * 1 if frame must be re-queued for later driver support. */ static int ppp_dev_xmit_frame (struct ppp *ppp, struct ppp_buffer *buf, __u8 *data, int count) { int proto; int address, control; __u8 *new_data; int new_count; /* * Print the buffer */ if (ppp->flags & SC_LOG_OUTPKT) ppp_print_buffer ("write frame", data, count); /* * Determine if the frame may be compressed. Attempt to compress the * frame if possible. */ proto = PPP_PROTOCOL (data); address = PPP_ADDRESS (data); control = PPP_CONTROL (data); if (((ppp->flags & SC_COMP_RUN) != 0) && (ppp->sc_xc_state != (void *) 0) && (address == PPP_ALLSTATIONS) && (control == PPP_UI) && (proto != PPP_LCP) && (proto != PPP_CCP)) { new_data = kmalloc (count, GFP_ATOMIC); if (new_data == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_dev_xmit_frame: no memory\n"); return 1; } new_count = bsd_compress (ppp->sc_xc_state, data, new_data, count, count); if (new_count > 0) { ++ppp->stats.ppp_opackets; ppp->stats.ppp_ooctects += new_count; ppp_dev_xmit_lower (ppp, buf, new_data, new_count, 0); kfree (new_data); return 0; } /* * The frame could not be compressed. */ kfree (new_data); } /* * The frame may not be compressed. Update the statistics before the * count field is destroyed. The frame will be transmitted. */ ++ppp->stats.ppp_opackets; ppp->stats.ppp_ooctects += count; /* * Go to the escape encoding */ ppp_dev_xmit_lower (ppp, buf, data, count, !!(proto & 0xFF00)); return 0; } /* * Revise the tty frame for specific protocols. */ static int send_revise_frame (register struct ppp *ppp, __u8 *data, int len) { __u8 *p; switch (PPP_PROTOCOL (data)) { /* * Update the LQR frame with the current MIB information. This saves having * the daemon read old MIB data from the driver. */ case PPP_LQR: len = 48; /* total size of this frame */ p = (__u8 *) &data [40]; /* Point to last two items. */ p = store_long (p, ppp->stats.ppp_opackets + 1); p = store_long (p, ppp->stats.ppp_ooctects + len); break; /* * Outbound compression frames */ case PPP_CCP: ppp_proto_ccp (ppp, data + PPP_HARD_HDR_LEN, len - PPP_HARD_HDR_LEN, 0); break; default: break; } return len; } /* * write a frame with NR chars from BUF to TTY * we have to put the FCS field on ourselves */ static int ppp_tty_write (struct tty_struct *tty, struct file *file, const __u8 * data, unsigned int count) { struct ppp *ppp = tty2ppp (tty); __u8 *new_data; int status; /* * Verify the pointers. */ if (!ppp) return -EIO; if (ppp->magic != PPP_MAGIC) return -EIO; CHECK_PPP (-ENXIO); /* * Ensure that the caller does not wish to send too much. */ if (count > PPP_MTU) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_tty_write: truncating user packet " "from %u to mtu %d\n", count, PPP_MTU); count = PPP_MTU; } /* * Allocate a buffer for the data and fetch it from the user space. */ new_data = kmalloc (count, GFP_KERNEL); if (new_data == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_tty_write: no memory\n"); return 0; } /* * lock this PPP unit so we will be the only writer; * sleep if necessary */ while (lock_buffer (ppp->tbuf) != 0) { current->timeout = 0; if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_write: sleeping\n"); interruptible_sleep_on (&ppp->write_wait); ppp = tty2ppp (tty); if (!ppp || ppp->magic != PPP_MAGIC || !ppp->inuse) { kfree (new_data); return 0; } if (current->signal & ~current->blocked) { kfree (new_data); return -EINTR; } } /* * Ensure that the caller's buffer is valid. */ status = verify_area (VERIFY_READ, data, count); if (status != 0) { kfree (new_data); ppp->tbuf->locked = 0; return status; } memcpy_fromfs (new_data, data, count); /* * Change the LQR frame */ count = send_revise_frame (ppp, new_data, count); /* * Send the data */ ppp_dev_xmit_frame (ppp, ppp->tbuf, new_data, count); kfree (new_data); return (int) count; } /* * Process the BSD compression IOCTL event for the tty device. */ static int ppp_set_compression (struct ppp *ppp, struct ppp_option_data *odp) { struct compressor *cp; struct ppp_option_data data; int error; int nb; __u8 *ptr; __u8 ccp_option[CCP_MAX_OPTION_LENGTH]; /* * Fetch the compression parameters */ error = verify_area (VERIFY_READ, odp, sizeof (data)); if (error == 0) { memcpy_fromfs (&data, odp, sizeof (data)); nb = data.length; ptr = data.ptr; if ((__u32) nb >= (__u32)CCP_MAX_OPTION_LENGTH) nb = CCP_MAX_OPTION_LENGTH; error = verify_area (VERIFY_READ, ptr, nb); } if (error != 0) return error; memcpy_fromfs (ccp_option, ptr, nb); if (ccp_option[1] < 2) /* preliminary check on the length byte */ return (-EINVAL); cp = find_compressor ((int) (unsigned int) (__u8) ccp_option[0]); if (cp != (struct compressor *) 0) { /* * Found a handler for the protocol - try to allocate * a compressor or decompressor. */ error = 0; if (data.transmit) { if (ppp->sc_xc_state != NULL) (*ppp->sc_xcomp->comp_free)(ppp->sc_xc_state); ppp->sc_xcomp = cp; ppp->sc_xc_state = cp->comp_alloc(ccp_option, nb); if (ppp->sc_xc_state == NULL) { if (ppp->flags & SC_DEBUG) printk("ppp%ld: comp_alloc failed\n", ppp2dev (ppp)->base_addr); error = -ENOBUFS; } ppp->flags &= ~SC_COMP_RUN; } else { if (ppp->sc_rc_state != NULL) (*ppp->sc_rcomp->decomp_free)(ppp->sc_rc_state); ppp->sc_rcomp = cp; ppp->sc_rc_state = cp->decomp_alloc(ccp_option, nb); if (ppp->sc_rc_state == NULL) { if (ppp->flags & SC_DEBUG) printk("ppp%ld: decomp_alloc failed\n", ppp2dev (ppp)->base_addr); error = ENOBUFS; } ppp->flags &= ~SC_DECOMP_RUN; } return (error); } if (ppp->flags & SC_DEBUG) printk(KERN_DEBUG "ppp%ld: no compressor for [%x %x %x], %x\n", ppp2dev (ppp)->base_addr, ccp_option[0], ccp_option[1], ccp_option[2], nb); return (-EINVAL); /* no handler found */ } /* * Process the IOCTL event for the tty device. */ static int ppp_tty_ioctl (struct tty_struct *tty, struct file * file, unsigned int param2, unsigned long param3) { struct ppp *ppp = tty2ppp (tty); register int temp_i = 0; int error = 0; /* * Verify the status of the PPP device. */ if (!ppp) return -EBADF; if (ppp->magic != PPP_MAGIC) return -EBADF; CHECK_PPP (-ENXIO); /* * The user must have an euid of root to do these requests. */ if (!suser ()) return -EPERM; /* * Set the MRU value */ switch (param2) { case PPPIOCSMRU: error = verify_area (VERIFY_READ, (void *) param3, sizeof (temp_i)); if (error == 0) { temp_i = get_user ((int *) param3); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: set mru to %x\n", temp_i); if (ppp->mru != temp_i) ppp_changedmtu (ppp, ppp2dev (ppp)->mtu, temp_i); } break; /* * Fetch the flags */ case PPPIOCGFLAGS: error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (temp_i)); if (error == 0) { temp_i = (ppp->flags & SC_MASK); #ifndef CHECK_CHARACTERS /* Don't generate errors if we don't check chars. */ temp_i |= SC_RCV_B7_1 | SC_RCV_B7_0 | SC_RCV_ODDP | SC_RCV_EVNP; #endif put_user (temp_i, (int *) param3); if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_tty_ioctl: get flags: addr %lx flags " "%x\n", param3, temp_i); } break; /* * Set the flags for the various options */ case PPPIOCSFLAGS: error = verify_area (VERIFY_READ, (void *) param3, sizeof (temp_i)); if (error == 0) { temp_i = get_user ((int *) param3) & SC_MASK; temp_i |= (ppp->flags & ~SC_MASK); if ((ppp->flags & SC_CCP_OPEN) && (temp_i & SC_CCP_OPEN) == 0) ppp_ccp_closed (ppp); if ((ppp->flags | temp_i) & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: set flags to %x\n", temp_i); ppp->flags = temp_i; } break; /* * Set the compression mode */ case PPPIOCSCOMPRESS: error = ppp_set_compression (ppp, (struct ppp_option_data *) param3); break; /* * Retrieve the transmit async map */ case PPPIOCGASYNCMAP: error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (temp_i)); if (error == 0) { put_user (ppp->xmit_async_map[0], (int *) param3); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: get asyncmap: addr " "%lx asyncmap %x\n", param3, ppp->xmit_async_map[0]); } break; /* * Set the transmit async map */ case PPPIOCSASYNCMAP: error = verify_area (VERIFY_READ, (void *) param3, sizeof (temp_i)); if (error == 0) { ppp->xmit_async_map[0] = get_user ((int *) param3); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: set xmit asyncmap %x\n", ppp->xmit_async_map[0]); } break; /* * Set the receive async map */ case PPPIOCSRASYNCMAP: error = verify_area (VERIFY_READ, (void *) param3, sizeof (temp_i)); if (error == 0) { ppp->recv_async_map = get_user ((int *) param3); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: set rcv asyncmap %x\n", ppp->recv_async_map); } break; /* * Obtain the unit number for this device. */ case PPPIOCGUNIT: error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (temp_i)); if (error == 0) { put_user (ppp2dev (ppp)->base_addr, (int *) param3); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: get unit: %ld", ppp2dev (ppp)->base_addr); } break; /* * Set the debug level */ case PPPIOCSDEBUG: error = verify_area (VERIFY_READ, (void *) param3, sizeof (temp_i)); if (error == 0) { temp_i = (get_user ((int *) param3) & 0x1F) << 16; temp_i |= (ppp->flags & ~0x1F0000); if ((ppp->flags | temp_i) & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: set flags to %x\n", temp_i); ppp->flags = temp_i; } break; /* * Get the debug level */ case PPPIOCGDEBUG: error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (temp_i)); if (error == 0) { temp_i = (ppp->flags >> 16) & 0x1F; put_user (temp_i, (int *) param3); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: get debug level %d\n", temp_i); } break; /* * Get the times since the last send/receive frame operation */ case PPPIOCGIDLE: error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (struct ppp_idle)); if (error == 0) { struct ppp_idle cur_ddinfo; __u32 cur_jiffies = jiffies; /* change absolute times to relative times. */ cur_ddinfo.xmit_idle = (cur_jiffies - ppp->ddinfo.xmit_idle) / HZ; cur_ddinfo.recv_idle = (cur_jiffies - ppp->ddinfo.recv_idle) / HZ; memcpy_tofs ((void *) param3, &cur_ddinfo, sizeof (cur_ddinfo)); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: read demand dial info\n"); } break; /* * Retrieve the extended async map */ case PPPIOCGXASYNCMAP: error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (ppp->xmit_async_map)); if (error == 0) { memcpy_tofs ((void *) param3, ppp->xmit_async_map, sizeof (ppp->xmit_async_map)); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: get xasyncmap: addr %lx\n", param3); } break; /* * Set the async extended map */ case PPPIOCSXASYNCMAP: error = verify_area (VERIFY_READ, (void *) param3, sizeof (ppp->xmit_async_map)); if (error == 0) { __u32 temp_tbl[8]; memcpy_fromfs (temp_tbl, (void *) param3, sizeof (ppp->xmit_async_map)); temp_tbl[1] = 0x00000000; temp_tbl[2] &= ~0x40000000; temp_tbl[3] |= 0x60000000; if ((temp_tbl[2] & temp_tbl[3]) != 0 || (temp_tbl[4] & temp_tbl[5]) != 0 || (temp_tbl[6] & temp_tbl[7]) != 0) error = -EINVAL; else { memcpy (ppp->xmit_async_map, temp_tbl, sizeof (ppp->xmit_async_map)); if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: set xasyncmap\n"); } } break; /* * Set the maximum VJ header compression slot number. */ case PPPIOCSMAXCID: error = verify_area (VERIFY_READ, (void *) param3, sizeof (temp_i)); if (error == 0) { temp_i = get_user ((int *) param3) + 1; if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_tty_ioctl: set maxcid to %d\n", temp_i); if (ppp->slcomp != NULL) slhc_free (ppp->slcomp); ppp->slcomp = slhc_init (16, temp_i); if (ppp->slcomp == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp: no space for compression buffers!\n"); ppp_release (ppp); error = -ENOMEM; } } break; case PPPIOCXFERUNIT: ppp_tty_close_local (tty, current->pid); break; case PPPIOCGNPMODE: case PPPIOCSNPMODE: error = verify_area (VERIFY_READ, (void *) param3, sizeof (struct npioctl)); if (error == 0) { struct npioctl npi; memcpy_fromfs (&npi, (void *) param3, sizeof (npi)); switch (npi.protocol) { case PPP_IP: npi.protocol = NP_IP; break; default: error = -EINVAL; } if (error != 0) break; if (param2 == PPPIOCGNPMODE) { npi.mode = ppp->sc_npmode[npi.protocol]; error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (npi)); if (error != 0) break; memcpy_tofs ((void *) param3, &npi, sizeof (npi)); break; } if (npi.mode != ppp->sc_npmode[npi.protocol]) { ppp->sc_npmode[npi.protocol] = npi.mode; if (npi.mode != NPMODE_QUEUE) { /* ppp_requeue(ppp); maybe needed */ ppp_tty_wakeup (ppp2tty(ppp)); } } } break; /* * Allow users to read, but not set, the serial port parameters */ case TCGETS: case TCGETA: error = n_tty_ioctl (tty, file, param2, param3); break; case FIONREAD: error = verify_area (VERIFY_WRITE, (void *) param3, sizeof (int)); if (error == 0) { int count = ppp->ubuf->tail - ppp->ubuf->head; if (count < 0) count += (ppp->ubuf->size + 1); put_user (count, (int *) param3); } break; /* * All other ioctl() events will come here. */ default: if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_tty_ioctl: invalid ioctl: %x, addr %lx\n", param2, param3); error = -ENOIOCTLCMD; break; } return error; } /* * TTY callback. * * Process the select() statement for the PPP device. */ static int ppp_tty_select (struct tty_struct *tty, struct inode *inode, struct file *filp, int sel_type, select_table * wait) { struct ppp *ppp = tty2ppp (tty); int result = 1; /* * Verify the status of the PPP device. */ if (!ppp) return -EBADF; if (ppp->magic != PPP_MAGIC) return -EBADF; CHECK_PPP (0); /* * Branch on the type of select mode. A read request must lock the user * buffer area. */ switch (sel_type) { case SEL_IN: if (set_bit (0, &ppp->ubuf->locked) == 0) { /* Test for the presence of data in the queue */ if (ppp->ubuf->head != ppp->ubuf->tail) { clear_bit (0, &ppp->ubuf->locked); break; } clear_bit (0, &ppp->ubuf->locked); } /* fall through */ /* * Exceptions or read errors. */ case SEL_EX: /* Is this a pty link and the remote disconnected? */ if (tty->flags & (1 << TTY_OTHER_CLOSED)) break; /* Is this a local link and the modem disconnected? */ if (tty_hung_up_p (filp)) break; select_wait (&ppp->read_wait, wait); result = 0; break; /* * Write mode. A write is allowed if there is no current transmission. */ case SEL_OUT: if (ppp->tbuf->locked != 0) { select_wait (&ppp->write_wait, wait); result = 0; } break; } return result; } /************************************************************* * NETWORK OUTPUT * This routine accepts requests from the network layer * and attempts to deliver the packets. * It also includes various routines we are compelled to * have to make the network layer work (arp, etc...). *************************************************************/ /* * Callback from the network layer when the device goes up. */ static int ppp_dev_open (struct device *dev) { struct ppp *ppp = dev2ppp (dev); /* reset POINTOPOINT every time, since dev_close zaps it! */ dev->flags |= IFF_POINTOPOINT; if (ppp2tty (ppp) == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp: %s not connected to a TTY! can't go open!\n", dev->name); return -ENXIO; } if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp: channel %s going up for IP packets!\n", dev->name); CHECK_PPP (-ENXIO); return 0; } /* * Callback from the network layer when the ppp device goes down. */ static int ppp_dev_close (struct device *dev) { struct ppp *ppp = dev2ppp (dev); if (ppp2tty (ppp) == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp: %s not connected to a TTY! can't go down!\n", dev->name); return -ENXIO; } /* * We don't do anything about the device going down. It is not important * for us. */ if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp: channel %s going down for IP packets!\n", dev->name); CHECK_PPP (-ENXIO); return 0; } /* * IOCTL operation to read the version of the driver. */ static int ppp_dev_ioctl_version (struct ppp *ppp, struct ifreq *ifr) { int error; int len; char *result; /* * Must have write access to the buffer. */ result = (char *) ifr->ifr_ifru.ifru_data; len = strlen (szVersion) + 1; error = verify_area (VERIFY_WRITE, result, len); /* * Move the version data */ if (error == 0) memcpy_tofs (result, szVersion, len); return error; } /* * IOCTL to read the statistics for the pppstats program. */ static int ppp_dev_ioctl_stats (struct ppp *ppp, struct ifreq *ifr, struct device *dev) { struct ppp_stats *result, temp; int error; /* * Must have write access to the buffer. */ result = (struct ppp_stats *) ifr->ifr_ifru.ifru_data; error = verify_area (VERIFY_WRITE, result, sizeof (temp)); /* * Supply the information for the caller. First move the version data * then move the ppp stats; and finally the vj stats. */ memset (&temp, 0, sizeof(temp)); if (error == 0 && dev->flags & IFF_UP) { memcpy (&temp.p, &ppp->stats, sizeof (struct pppstat)); if (ppp->slcomp != NULL) { temp.vj.vjs_packets = ppp->slcomp->sls_o_compressed+ ppp->slcomp->sls_o_uncompressed; temp.vj.vjs_compressed = ppp->slcomp->sls_o_compressed; temp.vj.vjs_searches = ppp->slcomp->sls_o_searches; temp.vj.vjs_misses = ppp->slcomp->sls_o_misses; temp.vj.vjs_errorin = ppp->slcomp->sls_i_error; temp.vj.vjs_tossed = ppp->slcomp->sls_i_tossed; temp.vj.vjs_uncompressedin = ppp->slcomp->sls_i_uncompressed; temp.vj.vjs_compressedin = ppp->slcomp->sls_i_compressed; } } if (error == 0) memcpy_tofs (result, &temp, sizeof (temp)); return error; } /* * IOCTL to read the compression statistics for the pppstats program. */ static int ppp_dev_ioctl_comp_stats (struct ppp *ppp, struct ifreq *ifr, struct device *dev) { struct ppp_comp_stats *result, temp; int error; /* * Must have write access to the buffer. */ result = (struct ppp_comp_stats *) ifr->ifr_ifru.ifru_data; error = verify_area (VERIFY_WRITE, result, sizeof (temp)); /* * Supply the information for the caller. */ memset (&temp, 0, sizeof(temp)); if (error == 0 && dev->flags & IFF_UP) { if (ppp->sc_xc_state != NULL) (*ppp->sc_xcomp->comp_stat) (ppp->sc_xc_state, &temp.c); if (ppp->sc_rc_state != NULL) (*ppp->sc_rcomp->decomp_stat) (ppp->sc_rc_state, &temp.d); } /* * Move the data to the caller's buffer */ if (error == 0) memcpy_tofs (result, &temp, sizeof (temp)); return error; } /* * Callback from the network layer to process the sockioctl functions. */ static int ppp_dev_ioctl (struct device *dev, struct ifreq *ifr, int cmd) { struct ppp *ppp = dev2ppp (dev); int error; /* * Process the requests */ switch (cmd) { case SIOCGPPPSTATS: error = ppp_dev_ioctl_stats (ppp, ifr, dev); break; case SIOCGPPPCSTATS: error = ppp_dev_ioctl_comp_stats (ppp, ifr, dev); break; case SIOCGPPPVER: error = ppp_dev_ioctl_version (ppp, ifr); break; default: error = -EINVAL; break; } return error; } /* * Send an IP frame to the remote with vj header compression. * * Return 0 if frame was queued for transmission. * 1 if frame must be re-queued for later driver support. */ static int ppp_dev_xmit_ip (struct device *dev, struct ppp *ppp, __u8 *data) { int proto = PPP_IP; int len; struct ppp_hdr *hdr; struct tty_struct *tty = ppp2tty (ppp); /* * Obtain the length from the IP header. */ len = ((struct iphdr *)data) -> tot_len; len = ntohs (len); /* * Validate the tty interface */ if (tty == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_dev_xmit: %s not connected to a TTY!\n", dev->name); return 0; } /* * Ensure that the PPP device is still up */ if (!(dev->flags & IFF_UP)) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_dev_xmit: packet sent on interface %s," " which is down for IP\n", dev->name); return 0; } /* * Branch on the type of processing for the IP frame. */ switch (ppp->sc_npmode[NP_IP]) { case NPMODE_PASS: break; case NPMODE_ERROR: if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_dev_xmit: npmode = NPMODE_ERROR on %s\n", dev->name); return 0; case NPMODE_DROP: if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_dev_xmit: npmode = NPMODE_DROP on %s\n", dev->name); return 0; case NPMODE_QUEUE: break; default: if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_dev_xmit: unknown npmode %d on %s\n", ppp->sc_npmode[NP_IP], dev->name); return 0; } /* * Detect a change in the transfer size */ if (ppp->mtu != ppp2dev (ppp)->mtu) { ppp_changedmtu (ppp, ppp2dev (ppp)->mtu, ppp->mru); } /* * Acquire the lock on the transmission buffer. If the buffer was busy then * mark the device as busy. */ if (lock_buffer (ppp->wbuf) != 0) { dev->tbusy = 1; return 1; } /* * Print the frame being sent */ if (ppp->flags & SC_LOG_OUTPKT) ppp_print_buffer ("ppp outpkt", data, len); /* * At this point, the buffer will be transmitted. There is no other exit. * * Try to compress the header. */ if (ppp->flags & SC_COMP_TCP) { len = slhc_compress (ppp->slcomp, data, len, buf_base (ppp->cbuf) + PPP_HARD_HDR_LEN, &data, (ppp->flags & SC_NO_TCP_CCID) == 0); if (data[0] & SL_TYPE_COMPRESSED_TCP) { proto = PPP_VJC_COMP; data[0] ^= SL_TYPE_COMPRESSED_TCP; } else { if (data[0] >= SL_TYPE_UNCOMPRESSED_TCP) proto = PPP_VJC_UNCOMP; data[0] = (data[0] & 0x0f) | 0x40; } } /* * Send the frame */ len += PPP_HARD_HDR_LEN; hdr = &((struct ppp_hdr *) data)[-1]; hdr->address = PPP_ALLSTATIONS; hdr->control = PPP_UI; hdr->protocol[0] = 0; hdr->protocol[1] = proto; return ppp_dev_xmit_frame (ppp, ppp->wbuf, (__u8 *) hdr, len); } /* * Send an IPX (or any other non-IP) frame to the remote. * * Return 0 if frame was queued for transmission. * 1 if frame must be re-queued for later driver support. */ static int ppp_dev_xmit_ipx (struct device *dev, struct ppp *ppp, __u8 *data, int len, int proto) { struct tty_struct *tty = ppp2tty (ppp); struct ppp_hdr *hdr; /* * Validate the tty interface */ if (tty == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_dev_xmit: %s not connected to a TTY!\n", dev->name); return 0; } /* * Ensure that the PPP device is still up */ if (!(dev->flags & IFF_UP)) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_dev_xmit: packet sent on interface %s," " which is down\n", dev->name); return 0; } /* * Detect a change in the transfer size */ if (ppp->mtu != ppp2dev (ppp)->mtu) { ppp_changedmtu (ppp, ppp2dev (ppp)->mtu, ppp->mru); } /* * Acquire the lock on the transmission buffer. If the buffer was busy then * mark the device as busy. */ if (lock_buffer (ppp->wbuf) != 0) { dev->tbusy = 1; return 1; } /* * Print the frame being sent */ if (ppp->flags & SC_LOG_OUTPKT) ppp_print_buffer ("ppp outpkt", data, len); /* * Send the frame */ len += PPP_HARD_HDR_LEN; hdr = &((struct ppp_hdr *) data)[-1]; hdr->address = PPP_ALLSTATIONS; hdr->control = PPP_UI; hdr->protocol[0] = proto >> 8; hdr->protocol[1] = proto; return ppp_dev_xmit_frame (ppp, ppp->wbuf, (__u8 *) hdr, len); } /* * Send a frame to the remote. */ static int ppp_dev_xmit (sk_buff *skb, struct device *dev) { int answer, len; __u8 *data; struct ppp *ppp = dev2ppp (dev); struct tty_struct *tty = ppp2tty (ppp); /* * just a little sanity check. */ if (skb == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_WARNING "ppp_dev_xmit: null packet!\n"); return 0; } /* * Avoid timing problem should tty hangup while data is queued to be sent */ if (!ppp->inuse) { dev_kfree_skb (skb, FREE_WRITE); dev_close (dev); return 0; } /* * Validate the tty linkage */ if (ppp->flags & SC_DEBUG) printk (KERN_DEBUG "ppp_dev_xmit [%s]: skb %p\n", dev->name, skb); /* * Validate the tty interface */ if (tty == NULL) { if (ppp->flags & SC_DEBUG) printk (KERN_ERR "ppp_dev_xmit: %s not connected to a TTY!\n", dev->name); dev_kfree_skb (skb, FREE_WRITE); return 0; } /* * Fetch the pointer to the data */ len = skb->len; data = skb_data(skb) + PPP_HARD_HDR_LEN; /* * Bug trap for null data. Release the skb and bail out. */ if(data == NULL) { printk("ppp_dev_xmit: data=NULL before ppp_dev_xmit_ip.\n"); dev_kfree_skb (skb, FREE_WRITE); return 0; } /* * Look at the protocol in the skb to determine the difference between * an IP frame and an IPX frame. */ switch (ntohs (skb->protocol)) { case ETH_P_IPX: answer = ppp_dev_xmit_ipx (dev, ppp, data, len, PPP_IPX); break; case ETH_P_IP: answer = ppp_dev_xmit_ip (dev, ppp, data); break; default: /* All others have no support at this time. */ dev_kfree_skb (skb, FREE_WRITE); return 0; } /* * This is the end of the transmission. Release the buffer if it was sent. */ if (answer == 0) { dev_kfree_skb (skb, FREE_WRITE); ppp->ddinfo.xmit_idle = jiffies; } return answer; } /* * Generate the statistic information for the /proc/net/dev listing. */ static struct enet_statistics * ppp_dev_stats (struct device *dev) { struct ppp *ppp = dev2ppp (dev); static struct enet_statistics ppp_stats; ppp_stats.rx_packets = ppp->stats.ppp_ipackets; ppp_stats.rx_errors = ppp->stats.ppp_ierrors; ppp_stats.rx_dropped = ppp->stats.ppp_ierrors; ppp_stats.rx_fifo_errors = 0; ppp_stats.rx_length_errors = 0; ppp_stats.rx_over_errors = 0; ppp_stats.rx_crc_errors = 0; ppp_stats.rx_frame_errors = 0; ppp_stats.tx_packets = ppp->stats.ppp_opackets; ppp_stats.tx_errors = ppp->stats.ppp_oerrors; ppp_stats.tx_dropped = 0; ppp_stats.tx_fifo_errors = 0; ppp_stats.collisions = 0; ppp_stats.tx_carrier_errors = 0; ppp_stats.tx_aborted_errors = 0; ppp_stats.tx_window_errors = 0; ppp_stats.tx_heartbeat_errors = 0; if (ppp->flags & SC_DEBUG) printk (KERN_INFO "ppp_dev_stats called\n"); return &ppp_stats; } static int ppp_dev_header (sk_buff *skb, struct device *dev, __u16 type, void *daddr, void *saddr, unsigned int len) { /* On the PPP device the hard header must be ignored * by the SOCK_PACKET layer. (Backward compatability). */ skb->mac.raw = skb->data; skb_push(skb,PPP_HARD_HDR_LEN); return PPP_HARD_HDR_LEN; } static int ppp_dev_rebuild (void *eth, struct device *dev, unsigned long raddr, struct sk_buff *skb) { return (0); } /************************************************************* * UTILITIES * Miscellany called by various functions above. *************************************************************/ /* Locate the previous instance of the PPP channel */ static struct ppp * ppp_find (int pid_value) { int if_num; ppp_ctrl_t *ctl; struct ppp *ppp; /* try to find the exact same free device which we had before */ ctl = ppp_list; if_num = 0; while (ctl) { ppp = ctl2ppp (ctl); if (!set_bit(0, &ppp->inuse)) { if (ppp->sc_xfer == pid_value) { ppp->sc_xfer = 0; return (ppp); } clear_bit (0, &ppp->inuse); } ctl = ctl->next; if (++if_num == max_dev) break; } return NULL; } /* allocate or create a PPP channel */ static struct ppp * ppp_alloc (void) { int if_num; int status; ppp_ctrl_t *ctl; struct device *dev; struct ppp *ppp; /* try to find an free device */ ctl = ppp_list; if_num = 0; while (ctl) { ppp = ctl2ppp (ctl); if (!set_bit(0, &ppp->inuse)) return (ppp); ctl = ctl->next; if (++if_num == max_dev) return (NULL); } /* * There are no available items. Allocate a device from the system pool */ ctl = (ppp_ctrl_t *) kmalloc (sizeof(ppp_ctrl_t), GFP_KERNEL); if (ctl) { (void) memset(ctl, 0, sizeof(ppp_ctrl_t)); ppp = ctl2ppp (ctl); dev = ctl2dev (ctl); /* initialize channel control data */ set_bit(0, &ppp->inuse); ppp->line = if_num; ppp->tty = NULL; ppp->dev = dev; dev->next = NULL; dev->init = ppp_init_dev; dev->name = ctl->name; dev->base_addr = (__u32) if_num; dev->priv = (void *) ppp; sprintf (dev->name, "ppp%d", if_num); /* link in the new channel */ ctl->next = ppp_list; ppp_list = ctl; /* register device so that we can be ifconfig'd */ /* ppp_init_dev() will be called as a side-effect */ status = register_netdev (dev); if (status == 0) { #ifndef QUIET printk (KERN_INFO "registered device %s\n", dev->name); #endif return (ppp); } printk (KERN_ERR "ppp_alloc - register_netdev(%s) = %d failure.\n", dev->name, status); /* This one will forever be busy as it is not initialized */ } return (NULL); } /* * Utility procedures to print a buffer in hex/ascii */ static void ppp_print_hex (register __u8 * out, const __u8 * in, int count) { register __u8 next_ch; static char hex[] = "0123456789ABCDEF"; while (count-- > 0) { next_ch = *in++; *out++ = hex[(next_ch >> 4) & 0x0F]; *out++ = hex[next_ch & 0x0F]; ++out; } } static void ppp_print_char (register __u8 * out, const __u8 * in, int count) { register __u8 next_ch; while (count-- > 0) { next_ch = *in++; if (next_ch < 0x20 || next_ch > 0x7e) *out++ = '.'; else { *out++ = next_ch; if (next_ch == '%') /* printk/syslogd has a bug !! */ *out++ = '%'; } } *out = '\0'; } static void ppp_print_buffer (const __u8 * name, const __u8 * buf, int count) { __u8 line[44]; if (name != (__u8 *) NULL) printk (KERN_DEBUG "ppp: %s, count = %d\n", name, count); while (count > 8) { memset (line, 32, 44); ppp_print_hex (line, buf, 8); ppp_print_char (&line[8 * 3], buf, 8); printk (KERN_DEBUG "%s\n", line); count -= 8; buf += 8; } if (count > 0) { memset (line, 32, 44); ppp_print_hex (line, buf, count); ppp_print_char (&line[8 * 3], buf, count); printk (KERN_DEBUG "%s\n", line); } } /************************************************************* * Compressor module interface *************************************************************/ struct compressor_link { struct compressor_link *next; struct compressor *comp; }; static struct compressor_link *ppp_compressors = (struct compressor_link *) 0; static struct compressor *find_compressor (int type) { struct compressor_link *lnk; __u32 flags; save_flags(flags); cli(); lnk = ppp_compressors; while (lnk != (struct compressor_link *) 0) { if ((int) (__u8) lnk->comp->compress_proto == type) { restore_flags(flags); return lnk->comp; } lnk = lnk->next; } restore_flags(flags); return (struct compressor *) 0; } static int ppp_register_compressor (struct compressor *cp) { struct compressor_link *new; __u32 flags; new = (struct compressor_link *) kmalloc (sizeof (struct compressor_link), GFP_KERNEL); if (new == (struct compressor_link *) 0) return 1; save_flags(flags); cli(); if (find_compressor (cp->compress_proto)) { restore_flags(flags); kfree (new); return 0; } new->next = ppp_compressors; new->comp = cp; ppp_compressors = new; restore_flags(flags); return 0; } static void ppp_unregister_compressor (struct compressor *cp) { struct compressor_link *prev = (struct compressor_link *) 0; struct compressor_link *lnk; __u32 flags; save_flags(flags); cli(); lnk = ppp_compressors; while (lnk != (struct compressor_link *) 0) { if (lnk->comp == cp) { if (prev) prev->next = lnk->next; else ppp_compressors = lnk->next; kfree (lnk); break; } prev = lnk; lnk = lnk->next; } restore_flags(flags); } /************************************************************* * Module support routines *************************************************************/ #ifdef MODULE int init_module(void) { int status; /* register our line disciplines */ status = ppp_first_time(); if (status != 0) printk (KERN_INFO "PPP: ppp_init() failure %d\n", status); else (void) register_symtab (&ppp_syms); return (status); } void cleanup_module(void) { int status; ppp_ctrl_t *ctl, *next_ctl; struct device *dev; struct ppp *ppp; int busy_flag = 0; /* * Ensure that the devices are not in operation. */ ctl = ppp_list; while (ctl) { ppp = ctl2ppp (ctl); if (ppp->inuse && ppp->tty != NULL) { busy_flag = 1; break; } dev = ctl2dev (ctl); if (dev->start || dev->flags & IFF_UP) { busy_flag = 1; break; } ctl = ctl->next; } /* * Ensure that there are no compressor modules registered */ if (ppp_compressors != NULL) busy_flag = 1; if (busy_flag) { printk (KERN_INFO "PPP: device busy, remove delayed\n"); return; } /* * Release the tty registration of the line discipline so that no new entries * may be created. */ status = tty_register_ldisc (N_PPP, NULL); if (status != 0) printk (KERN_INFO "PPP: Unable to unregister ppp line discipline " "(err = %d)\n", status); else printk (KERN_INFO "PPP: ppp line discipline successfully unregistered\n"); /* * De-register the devices so that there is no problem with them */ next_ctl = ppp_list; while (next_ctl) { ctl = next_ctl; next_ctl = ctl->next; ppp = ctl2ppp (ctl); dev = ctl2dev (ctl); ppp_release (ppp); unregister_netdev (dev); kfree (ctl); } } #endif