/* * Common data handling layer for ser_gigaset and usb_gigaset * * Copyright (c) 2005 by Tilman Schmidt , * Hansjoerg Lipp , * Stefan Eilers . * * ===================================================================== * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 of * the License, or (at your option) any later version. * ===================================================================== * ToDo: ... * ===================================================================== * Version: $Id: asyncdata.c,v 1.2.2.7 2005/11/13 23:05:18 hjlipp Exp $ * ===================================================================== */ #include "gigaset.h" #include //#define GIG_M10x_STUFF_VOICE_DATA /* check if byte must be stuffed/escaped * I'm not sure which data should be encoded. * Therefore I will go the hard way and decode every value * less than 0x20, the flag sequence and the control escape char. */ static inline int muststuff(unsigned char c) { if (c < PPP_TRANS) return 1; if (c == PPP_FLAG) return 1; if (c == PPP_ESCAPE) return 1; /* other possible candidates: */ /* 0x91: XON with parity set */ /* 0x93: XOFF with parity set */ return 0; } /* == data input =========================================================== */ /* process a block of received bytes in command mode (modem response) * Return value: * number of processed bytes */ static inline int cmd_loop(unsigned char c, unsigned char *src, int numbytes, struct inbuf_t *inbuf) { struct cardstate *cs = inbuf->cs; unsigned cbytes = cs->cbytes; int inputstate = inbuf->inputstate; int startbytes = numbytes; for (;;) { cs->respdata[cbytes] = c; if (c == 10 || c == 13) { dbg(DEBUG_TRANSCMD, "%s: End of Command (%d Bytes)", __func__, cbytes); cs->cbytes = cbytes; gigaset_handle_modem_response(cs); /* can change cs->dle */ cbytes = 0; if (cs->dle && !(inputstate & INS_DLE_command)) { inputstate &= ~INS_command; break; } } else { /* advance in line buffer, checking for overflow */ if (cbytes < MAX_RESP_SIZE - 1) cbytes++; else warn("response too large"); } if (!numbytes) break; c = *src++; --numbytes; if (c == DLE_FLAG && (cs->dle || inputstate & INS_DLE_command)) { inputstate |= INS_DLE_char; break; } } cs->cbytes = cbytes; inbuf->inputstate = inputstate; return startbytes - numbytes; } /* process a block of received bytes in lock mode (tty i/f) * Return value: * number of processed bytes */ static inline int lock_loop(unsigned char *src, int numbytes, struct inbuf_t *inbuf) { struct cardstate *cs = inbuf->cs; gigaset_dbg_buffer(DEBUG_LOCKCMD, "received response", numbytes, src, 0); gigaset_if_receive(cs, src, numbytes); return numbytes; } /* process a block of received bytes in HDLC data mode * Collect HDLC frames, undoing byte stuffing and watching for DLE escapes. * When a frame is complete, check the FCS and pass valid frames to the LL. * If DLE is encountered, return immediately to let the caller handle it. * Return value: * number of processed bytes * numbytes (all bytes processed) on error --FIXME */ static inline int hdlc_loop(unsigned char c, unsigned char *src, int numbytes, struct inbuf_t *inbuf) { struct cardstate *cs = inbuf->cs; struct bc_state *bcs = inbuf->bcs; int inputstate; __u16 fcs; struct sk_buff *skb; unsigned char error; struct sk_buff *compskb; int startbytes = numbytes; int l; IFNULLRETVAL(bcs, numbytes); inputstate = bcs->inputstate; fcs = bcs->fcs; skb = bcs->skb; IFNULLRETVAL(skb, numbytes); if (unlikely(inputstate & INS_byte_stuff)) { inputstate &= ~INS_byte_stuff; goto byte_stuff; } for (;;) { if (unlikely(c == PPP_ESCAPE)) { if (unlikely(!numbytes)) { inputstate |= INS_byte_stuff; break; } c = *src++; --numbytes; if (unlikely(c == DLE_FLAG && (cs->dle || inbuf->inputstate & INS_DLE_command))) { inbuf->inputstate |= INS_DLE_char; inputstate |= INS_byte_stuff; break; } byte_stuff: c ^= PPP_TRANS; #ifdef CONFIG_GIGASET_DEBUG if (unlikely(!muststuff(c))) dbg(DEBUG_HDLC, "byte stuffed: 0x%02x", c); #endif } else if (unlikely(c == PPP_FLAG)) { if (unlikely(inputstate & INS_skip_frame)) { if (!(inputstate & INS_have_data)) { /* 7E 7E */ //dbg(DEBUG_HDLC, "(7e)7e------------------------"); #ifdef CONFIG_GIGASET_DEBUG ++bcs->emptycount; #endif } else dbg(DEBUG_HDLC, "7e----------------------------"); /* end of frame */ error = 1; gigaset_rcv_error(NULL, cs, bcs); } else if (!(inputstate & INS_have_data)) { /* 7E 7E */ //dbg(DEBUG_HDLC, "(7e)7e------------------------"); #ifdef CONFIG_GIGASET_DEBUG ++bcs->emptycount; #endif break; } else { dbg(DEBUG_HDLC, "7e----------------------------"); /* end of frame */ error = 0; if (unlikely(fcs != PPP_GOODFCS)) { err("Packet checksum at %lu failed, " "packet is corrupted (%u bytes)!", bcs->rcvbytes, skb->len); compskb = NULL; gigaset_rcv_error(compskb, cs, bcs); error = 1; } else { if (likely((l = skb->len) > 2)) { skb->tail -= 2; skb->len -= 2; } else { dev_kfree_skb(skb); skb = NULL; inputstate |= INS_skip_frame; if (l == 1) { err("invalid packet size (1)!"); error = 1; gigaset_rcv_error(NULL, cs, bcs); } } if (likely(!(error || (inputstate & INS_skip_frame)))) { gigaset_rcv_skb(skb, cs, bcs); } } } if (unlikely(error)) if (skb) dev_kfree_skb(skb); fcs = PPP_INITFCS; inputstate &= ~(INS_have_data | INS_skip_frame); if (unlikely(bcs->ignore)) { inputstate |= INS_skip_frame; skb = NULL; } else if (likely((skb = dev_alloc_skb(SBUFSIZE + HW_HDR_LEN)) != NULL)) { skb_reserve(skb, HW_HDR_LEN); } else { warn("could not allocate new skb"); inputstate |= INS_skip_frame; } break; #ifdef CONFIG_GIGASET_DEBUG } else if (unlikely(muststuff(c))) { /* Should not happen. Possible after ZDLE=1. */ dbg(DEBUG_HDLC, "not byte stuffed: 0x%02x", c); #endif } /* add character */ #ifdef CONFIG_GIGASET_DEBUG if (unlikely(!(inputstate & INS_have_data))) { dbg(DEBUG_HDLC, "7e (%d x) ================", bcs->emptycount); bcs->emptycount = 0; } #endif inputstate |= INS_have_data; if (likely(!(inputstate & INS_skip_frame))) { if (unlikely(skb->len == SBUFSIZE)) { warn("received packet too long"); dev_kfree_skb_any(skb); skb = NULL; inputstate |= INS_skip_frame; break; } *gigaset_skb_put_quick(skb, 1) = c; /* *__skb_put (skb, 1) = c; */ fcs = crc_ccitt_byte(fcs, c); } if (unlikely(!numbytes)) break; c = *src++; --numbytes; if (unlikely(c == DLE_FLAG && (cs->dle || inbuf->inputstate & INS_DLE_command))) { inbuf->inputstate |= INS_DLE_char; break; } } bcs->inputstate = inputstate; bcs->fcs = fcs; bcs->skb = skb; return startbytes - numbytes; } /* process a block of received bytes in transparent data mode * Invert bytes, undoing byte stuffing and watching for DLE escapes. * If DLE is encountered, return immediately to let the caller handle it. * Return value: * number of processed bytes * numbytes (all bytes processed) on error --FIXME */ static inline int iraw_loop(unsigned char c, unsigned char *src, int numbytes, struct inbuf_t *inbuf) { struct cardstate *cs = inbuf->cs; struct bc_state *bcs = inbuf->bcs; int inputstate; struct sk_buff *skb; int startbytes = numbytes; IFNULLRETVAL(bcs, numbytes); inputstate = bcs->inputstate; skb = bcs->skb; IFNULLRETVAL(skb, numbytes); for (;;) { /* add character */ inputstate |= INS_have_data; if (likely(!(inputstate & INS_skip_frame))) { if (unlikely(skb->len == SBUFSIZE)) { //FIXME just pass skb up and allocate a new one warn("received packet too long"); dev_kfree_skb_any(skb); skb = NULL; inputstate |= INS_skip_frame; break; } *gigaset_skb_put_quick(skb, 1) = gigaset_invtab[c]; } if (unlikely(!numbytes)) break; c = *src++; --numbytes; if (unlikely(c == DLE_FLAG && (cs->dle || inbuf->inputstate & INS_DLE_command))) { inbuf->inputstate |= INS_DLE_char; break; } } /* pass data up */ if (likely(inputstate & INS_have_data)) { if (likely(!(inputstate & INS_skip_frame))) { gigaset_rcv_skb(skb, cs, bcs); } inputstate &= ~(INS_have_data | INS_skip_frame); if (unlikely(bcs->ignore)) { inputstate |= INS_skip_frame; skb = NULL; } else if (likely((skb = dev_alloc_skb(SBUFSIZE + HW_HDR_LEN)) != NULL)) { skb_reserve(skb, HW_HDR_LEN); } else { warn("could not allocate new skb"); inputstate |= INS_skip_frame; } } bcs->inputstate = inputstate; bcs->skb = skb; return startbytes - numbytes; } /* process a block of data received from the device */ void gigaset_m10x_input(struct inbuf_t *inbuf) { struct cardstate *cs; unsigned tail, head, numbytes; unsigned char *src, c; int procbytes; head = atomic_read(&inbuf->head); tail = atomic_read(&inbuf->tail); dbg(DEBUG_INTR, "buffer state: %u -> %u", head, tail); if (head != tail) { cs = inbuf->cs; src = inbuf->data + head; numbytes = (head > tail ? RBUFSIZE : tail) - head; dbg(DEBUG_INTR, "processing %u bytes", numbytes); while (numbytes) { if (atomic_read(&cs->mstate) == MS_LOCKED) { procbytes = lock_loop(src, numbytes, inbuf); src += procbytes; numbytes -= procbytes; } else { c = *src++; --numbytes; if (c == DLE_FLAG && (cs->dle || inbuf->inputstate & INS_DLE_command)) { if (!(inbuf->inputstate & INS_DLE_char)) { inbuf->inputstate |= INS_DLE_char; goto nextbyte; } /* => in data stream */ inbuf->inputstate &= ~INS_DLE_char; } if (!(inbuf->inputstate & INS_DLE_char)) { /* FIXME Einfach je nach Modus Funktionszeiger in cs setzen [hier+hdlc_loop]? */ /* FIXME Spart folgendes "if" und ermoeglicht andere Protokolle */ if (inbuf->inputstate & INS_command) procbytes = cmd_loop(c, src, numbytes, inbuf); else if (inbuf->bcs->proto2 == ISDN_PROTO_L2_HDLC) procbytes = hdlc_loop(c, src, numbytes, inbuf); else procbytes = iraw_loop(c, src, numbytes, inbuf); src += procbytes; numbytes -= procbytes; } else { /* DLE-char */ inbuf->inputstate &= ~INS_DLE_char; switch (c) { case 'X': /*begin of command*/ #ifdef CONFIG_GIGASET_DEBUG if (inbuf->inputstate & INS_command) err("received 'X' in command mode"); #endif inbuf->inputstate |= INS_command | INS_DLE_command; break; case '.': /*end of command*/ #ifdef CONFIG_GIGASET_DEBUG if (!(inbuf->inputstate & INS_command)) err("received '.' in hdlc mode"); #endif inbuf->inputstate &= cs->dle ? ~(INS_DLE_command|INS_command) : ~INS_DLE_command; break; //case DLE_FLAG: /*DLE_FLAG in data stream*/ /* schon oben behandelt! */ default: err("received 0x10 0x%02x!", (int) c); /* FIXME: reset driver?? */ } } } nextbyte: if (!numbytes) { /* end of buffer, check for wrap */ if (head > tail) { head = 0; src = inbuf->data; numbytes = tail; } else { head = tail; break; } } } dbg(DEBUG_INTR, "setting head to %u", head); atomic_set(&inbuf->head, head); } } /* == data output ========================================================== */ /* Encoding of a PPP packet into an octet stuffed HDLC frame * with FCS, opening and closing flags. * parameters: * skb skb containing original packet (freed upon return) * head number of headroom bytes to allocate in result skb * tail number of tailroom bytes to allocate in result skb * Return value: * pointer to newly allocated skb containing the result frame */ static struct sk_buff *HDLC_Encode(struct sk_buff *skb, int head, int tail) { struct sk_buff *hdlc_skb; __u16 fcs; unsigned char c; unsigned char *cp; int len; unsigned int stuf_cnt; stuf_cnt = 0; fcs = PPP_INITFCS; cp = skb->data; len = skb->len; while (len--) { if (muststuff(*cp)) stuf_cnt++; fcs = crc_ccitt_byte(fcs, *cp++); } fcs ^= 0xffff; /* complement */ /* size of new buffer: original size + number of stuffing bytes * + 2 bytes FCS + 2 stuffing bytes for FCS (if needed) + 2 flag bytes */ hdlc_skb = dev_alloc_skb(skb->len + stuf_cnt + 6 + tail + head); if (!hdlc_skb) { err("unable to allocate memory for HDLC encoding!"); dev_kfree_skb(skb); return NULL; } skb_reserve(hdlc_skb, head); /* Copy acknowledge request into new skb */ memcpy(hdlc_skb->head, skb->head, 2); /* Add flag sequence in front of everything.. */ *(skb_put(hdlc_skb, 1)) = PPP_FLAG; /* Perform byte stuffing while copying data. */ while (skb->len--) { if (muststuff(*skb->data)) { *(skb_put(hdlc_skb, 1)) = PPP_ESCAPE; *(skb_put(hdlc_skb, 1)) = (*skb->data++) ^ PPP_TRANS; } else *(skb_put(hdlc_skb, 1)) = *skb->data++; } /* Finally add FCS (byte stuffed) and flag sequence */ c = (fcs & 0x00ff); /* least significant byte first */ if (muststuff(c)) { *(skb_put(hdlc_skb, 1)) = PPP_ESCAPE; c ^= PPP_TRANS; } *(skb_put(hdlc_skb, 1)) = c; c = ((fcs >> 8) & 0x00ff); if (muststuff(c)) { *(skb_put(hdlc_skb, 1)) = PPP_ESCAPE; c ^= PPP_TRANS; } *(skb_put(hdlc_skb, 1)) = c; *(skb_put(hdlc_skb, 1)) = PPP_FLAG; dev_kfree_skb(skb); return hdlc_skb; } /* Encoding of a raw packet into an octet stuffed bit inverted frame * parameters: * skb skb containing original packet (freed upon return) * head number of headroom bytes to allocate in result skb * tail number of tailroom bytes to allocate in result skb * Return value: * pointer to newly allocated skb containing the result frame */ static struct sk_buff *iraw_encode(struct sk_buff *skb, int head, int tail) { struct sk_buff *iraw_skb; unsigned char c; unsigned char *cp; int len; /* worst case: every byte must be stuffed */ iraw_skb = dev_alloc_skb(2*skb->len + tail + head); if (!iraw_skb) { err("unable to allocate memory for HDLC encoding!"); dev_kfree_skb(skb); return NULL; } skb_reserve(iraw_skb, head); cp = skb->data; len = skb->len; while (len--) { c = gigaset_invtab[*cp++]; if (c == DLE_FLAG) *(skb_put(iraw_skb, 1)) = c; *(skb_put(iraw_skb, 1)) = c; } dev_kfree_skb(skb); return iraw_skb; } /* gigaset_send_skb * called by common.c to queue an skb for sending * and start transmission if necessary * parameters: * B Channel control structure * skb * Return value: * number of bytes accepted for sending * (skb->len if ok, 0 if out of buffer space) * or error code (< 0, eg. -EINVAL) */ int gigaset_m10x_send_skb(struct bc_state *bcs, struct sk_buff *skb) { unsigned len; IFNULLRETVAL(bcs, -EFAULT); IFNULLRETVAL(skb, -EFAULT); len = skb->len; if (bcs->proto2 == ISDN_PROTO_L2_HDLC) skb = HDLC_Encode(skb, HW_HDR_LEN, 0); else skb = iraw_encode(skb, HW_HDR_LEN, 0); if (!skb) return -ENOMEM; skb_queue_tail(&bcs->squeue, skb); tasklet_schedule(&bcs->cs->write_tasklet); return len; /* ok so far */ }