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[/] [or1k/] [trunk/] [rc203soc/] [sw/] [uClinux/] [drivers/] [isdn/] [hisax/] [avm_pci.c] - Rev 1772
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/* $Id: avm_pci.c,v 1.1 2005-12-20 10:17:01 jcastillo Exp $ * avm_pci.c low level stuff for AVM Fritz!PCI and ISA PnP isdn cards * Thanks to AVM, Berlin for informations * * Author Karsten Keil (keil@isdn4linux.de) * * * $Log: not supported by cvs2svn $ * Revision 1.1.1.1 2001/09/10 07:44:18 simons * Initial import * * Revision 1.1.1.1 2001/07/02 17:58:32 simons * Initial revision * * Revision 1.1.2.8 1998/11/05 21:11:12 keil * AVM PnP support * * Revision 1.1.2.7 1998/11/03 00:05:48 keil * certification related changes * fixed logging for smaller stack use * * Revision 1.1.2.6 1998/10/16 12:46:03 keil * fix pci detection for more as one card * * Revision 1.1.2.5 1998/10/13 18:38:50 keil * Fix PCI detection * * Revision 1.1.2.4 1998/10/04 23:03:41 keil * PCI has 255 device entries * * Revision 1.1.2.3 1998/09/27 23:52:57 keil * Fix error handling * * Revision 1.1.2.2 1998/09/27 13:03:16 keil * Fix segfaults on connect * * Revision 1.1.2.1 1998/08/25 14:01:24 calle * Ported driver for AVM Fritz!Card PCI from the 2.1 tree. * I could not test it. * * Revision 1.1 1998/08/20 13:47:30 keil * first version * * * */ #define __NO_VERSION__ #include <linux/config.h> #include "hisax.h" #include "isac.h" #include "isdnl1.h" #include <linux/pci.h> #include <linux/bios32.h> #include <linux/interrupt.h> extern const char *CardType[]; static const char *avm_pci_rev = "$Revision: 1.1 $"; #define AVM_FRITZ_PCI 1 #define AVM_FRITZ_PNP 2 #define PCI_VENDOR_AVM 0x1244 #define PCI_FRITZPCI_ID 0xa00 #define HDLC_FIFO 0x0 #define HDLC_STATUS 0x4 #define AVM_HDLC_1 0x00 #define AVM_HDLC_2 0x01 #define AVM_ISAC_FIFO 0x02 #define AVM_ISAC_REG_LOW 0x04 #define AVM_ISAC_REG_HIGH 0x06 #define AVM_STATUS0_IRQ_ISAC 0x01 #define AVM_STATUS0_IRQ_HDLC 0x02 #define AVM_STATUS0_IRQ_TIMER 0x04 #define AVM_STATUS0_IRQ_MASK 0x07 #define AVM_STATUS0_RESET 0x01 #define AVM_STATUS0_DIS_TIMER 0x02 #define AVM_STATUS0_RES_TIMER 0x04 #define AVM_STATUS0_ENA_IRQ 0x08 #define AVM_STATUS0_TESTBIT 0x10 #define AVM_STATUS1_INT_SEL 0x0f #define AVM_STATUS1_ENA_IOM 0x80 #define HDLC_MODE_ITF_FLG 0x01 #define HDLC_MODE_TRANS 0x02 #define HDLC_MODE_CCR_7 0x04 #define HDLC_MODE_CCR_16 0x08 #define HDLC_MODE_TESTLOOP 0x80 #define HDLC_INT_XPR 0x80 #define HDLC_INT_XDU 0x40 #define HDLC_INT_RPR 0x20 #define HDLC_INT_MASK 0xE0 #define HDLC_STAT_RME 0x01 #define HDLC_STAT_RDO 0x10 #define HDLC_STAT_CRCVFRRAB 0x0E #define HDLC_STAT_CRCVFR 0x06 #define HDLC_STAT_RML_MASK 0x3f00 #define HDLC_CMD_XRS 0x80 #define HDLC_CMD_XME 0x01 #define HDLC_CMD_RRS 0x20 #define HDLC_CMD_XML_MASK 0x3f00 /* Interface functions */ static u_char ReadISAC(struct IsdnCardState *cs, u_char offset) { register u_char idx = (offset > 0x2f) ? AVM_ISAC_REG_HIGH : AVM_ISAC_REG_LOW; register u_char val; register long flags; save_flags(flags); cli(); outb(idx, cs->hw.avm.cfg_reg + 4); val = inb(cs->hw.avm.isac + (offset & 0xf)); restore_flags(flags); return (val); } static void WriteISAC(struct IsdnCardState *cs, u_char offset, u_char value) { register u_char idx = (offset > 0x2f) ? AVM_ISAC_REG_HIGH : AVM_ISAC_REG_LOW; register long flags; save_flags(flags); cli(); outb(idx, cs->hw.avm.cfg_reg + 4); outb(value, cs->hw.avm.isac + (offset & 0xf)); restore_flags(flags); } static void ReadISACfifo(struct IsdnCardState *cs, u_char * data, int size) { outb(AVM_ISAC_FIFO, cs->hw.avm.cfg_reg + 4); insb(cs->hw.avm.isac, data, size); } static void WriteISACfifo(struct IsdnCardState *cs, u_char * data, int size) { outb(AVM_ISAC_FIFO, cs->hw.avm.cfg_reg + 4); outsb(cs->hw.avm.isac, data, size); } static inline u_int ReadHDLCPCI(struct IsdnCardState *cs, int chan, u_char offset) { register u_int idx = chan ? AVM_HDLC_2 : AVM_HDLC_1; register u_int val; register long flags; save_flags(flags); cli(); outl(idx, cs->hw.avm.cfg_reg + 4); val = inl(cs->hw.avm.isac + offset); restore_flags(flags); return (val); } static inline void WriteHDLCPCI(struct IsdnCardState *cs, int chan, u_char offset, u_int value) { register u_int idx = chan ? AVM_HDLC_2 : AVM_HDLC_1; register long flags; save_flags(flags); cli(); outl(idx, cs->hw.avm.cfg_reg + 4); outl(value, cs->hw.avm.isac + offset); restore_flags(flags); } static inline u_char ReadHDLCPnP(struct IsdnCardState *cs, int chan, u_char offset) { register u_char idx = chan ? AVM_HDLC_2 : AVM_HDLC_1; register u_char val; register long flags; save_flags(flags); cli(); outb(idx, cs->hw.avm.cfg_reg + 4); val = inb(cs->hw.avm.isac + offset); restore_flags(flags); return (val); } static inline void WriteHDLCPnP(struct IsdnCardState *cs, int chan, u_char offset, u_char value) { register u_char idx = chan ? AVM_HDLC_2 : AVM_HDLC_1; register long flags; save_flags(flags); cli(); outb(idx, cs->hw.avm.cfg_reg + 4); outb(value, cs->hw.avm.isac + offset); restore_flags(flags); } static u_char ReadHDLC_s(struct IsdnCardState *cs, int chan, u_char offset) { return(0xff & ReadHDLCPCI(cs, chan, offset)); } static void WriteHDLC_s(struct IsdnCardState *cs, int chan, u_char offset, u_char value) { WriteHDLCPCI(cs, chan, offset, value); } static inline struct BCState *Sel_BCS(struct IsdnCardState *cs, int channel) { if (cs->bcs[0].mode && (cs->bcs[0].channel == channel)) return(&cs->bcs[0]); else if (cs->bcs[1].mode && (cs->bcs[1].channel == channel)) return(&cs->bcs[1]); else return(NULL); } void inline hdlc_sched_event(struct BCState *bcs, int event) { bcs->event |= 1 << event; queue_task(&bcs->tqueue, &tq_immediate); mark_bh(IMMEDIATE_BH); } void write_ctrl(struct BCState *bcs, int which) { if (bcs->cs->debug & L1_DEB_HSCX) debugl1(bcs->cs, "hdlc %c wr%x ctrl %x", 'A' + bcs->channel, which, bcs->hw.hdlc.ctrl.ctrl); if (bcs->cs->subtyp == AVM_FRITZ_PCI) { WriteHDLCPCI(bcs->cs, bcs->channel, HDLC_STATUS, bcs->hw.hdlc.ctrl.ctrl); } else { if (which & 4) WriteHDLCPnP(bcs->cs, bcs->channel, HDLC_STATUS + 2, bcs->hw.hdlc.ctrl.sr.mode); if (which & 2) WriteHDLCPnP(bcs->cs, bcs->channel, HDLC_STATUS + 1, bcs->hw.hdlc.ctrl.sr.xml); if (which & 1) WriteHDLCPnP(bcs->cs, bcs->channel, HDLC_STATUS, bcs->hw.hdlc.ctrl.sr.cmd); } } void modehdlc(struct BCState *bcs, int mode, int bc) { struct IsdnCardState *cs = bcs->cs; int hdlc = bcs->channel; if (cs->debug & L1_DEB_HSCX) debugl1(cs, "hdlc %c mode %d ichan %d", 'A' + hdlc, mode, bc); bcs->mode = mode; bcs->channel = bc; bcs->hw.hdlc.ctrl.ctrl = 0; switch (mode) { case (L1_MODE_NULL): bcs->hw.hdlc.ctrl.sr.cmd = HDLC_CMD_XRS | HDLC_CMD_RRS; bcs->hw.hdlc.ctrl.sr.mode = HDLC_MODE_TRANS; write_ctrl(bcs, 5); break; case (L1_MODE_TRANS): bcs->hw.hdlc.ctrl.sr.cmd = HDLC_CMD_XRS | HDLC_CMD_RRS; bcs->hw.hdlc.ctrl.sr.mode = HDLC_MODE_TRANS; write_ctrl(bcs, 5); bcs->hw.hdlc.ctrl.sr.cmd = HDLC_CMD_XRS; write_ctrl(bcs, 1); bcs->hw.hdlc.ctrl.sr.cmd = 0; hdlc_sched_event(bcs, B_XMTBUFREADY); break; case (L1_MODE_HDLC): bcs->hw.hdlc.ctrl.sr.cmd = HDLC_CMD_XRS | HDLC_CMD_RRS; bcs->hw.hdlc.ctrl.sr.mode = HDLC_MODE_ITF_FLG; write_ctrl(bcs, 5); bcs->hw.hdlc.ctrl.sr.cmd = HDLC_CMD_XRS; write_ctrl(bcs, 1); bcs->hw.hdlc.ctrl.sr.cmd = 0; hdlc_sched_event(bcs, B_XMTBUFREADY); break; } } static inline void hdlc_empty_fifo(struct BCState *bcs, int count) { register u_int *ptr; u_char *p; u_char idx = bcs->channel ? AVM_HDLC_2 : AVM_HDLC_1; int cnt=0; struct IsdnCardState *cs = bcs->cs; if ((cs->debug & L1_DEB_HSCX) && !(cs->debug & L1_DEB_HSCX_FIFO)) debugl1(cs, "hdlc_empty_fifo %d", count); if (bcs->hw.hdlc.rcvidx + count > HSCX_BUFMAX) { if (cs->debug & L1_DEB_WARN) debugl1(cs, "hdlc_empty_fifo: incoming packet too large"); return; } ptr = (u_int *) p = bcs->hw.hdlc.rcvbuf + bcs->hw.hdlc.rcvidx; bcs->hw.hdlc.rcvidx += count; if (cs->subtyp == AVM_FRITZ_PCI) { outl(idx, cs->hw.avm.cfg_reg + 4); while (cnt < count) { *ptr++ = inl(cs->hw.avm.isac); cnt += 4; } } else { outb(idx, cs->hw.avm.cfg_reg + 4); while (cnt < count) { *p++ = inb(cs->hw.avm.isac); cnt++; } } if (cs->debug & L1_DEB_HSCX_FIFO) { char *t = bcs->blog; if (cs->subtyp == AVM_FRITZ_PNP) p = (u_char *) ptr; t += sprintf(t, "hdlc_empty_fifo %c cnt %d", bcs->channel ? 'B' : 'A', count); QuickHex(t, p, count); debugl1(cs, bcs->blog); } } static inline void hdlc_fill_fifo(struct BCState *bcs) { struct IsdnCardState *cs = bcs->cs; int count, cnt =0; int fifo_size = 32; u_char *p; u_int *ptr; if ((cs->debug & L1_DEB_HSCX) && !(cs->debug & L1_DEB_HSCX_FIFO)) debugl1(cs, "hdlc_fill_fifo"); if (!bcs->tx_skb) return; if (bcs->tx_skb->len <= 0) return; bcs->hw.hdlc.ctrl.sr.cmd &= ~HDLC_CMD_XME; if (bcs->tx_skb->len > fifo_size) { count = fifo_size; } else { count = bcs->tx_skb->len; if (bcs->mode != L1_MODE_TRANS) bcs->hw.hdlc.ctrl.sr.cmd |= HDLC_CMD_XME; } if ((cs->debug & L1_DEB_HSCX) && !(cs->debug & L1_DEB_HSCX_FIFO)) debugl1(cs, "hdlc_fill_fifo %d/%ld", count, bcs->tx_skb->len); ptr = (u_int *) p = bcs->tx_skb->data; skb_pull(bcs->tx_skb, count); bcs->tx_cnt -= count; bcs->hw.hdlc.count += count; bcs->hw.hdlc.ctrl.sr.xml = ((count == fifo_size) ? 0 : count); write_ctrl(bcs, 3); /* sets the correct index too */ if (cs->subtyp == AVM_FRITZ_PCI) { while (cnt<count) { outl(*ptr++, cs->hw.avm.isac); cnt += 4; } } else { while (cnt<count) { outb(*p++, cs->hw.avm.isac); cnt++; } } if (cs->debug & L1_DEB_HSCX_FIFO) { char *t = bcs->blog; if (cs->subtyp == AVM_FRITZ_PNP) p = (u_char *) ptr; t += sprintf(t, "hdlc_fill_fifo %c cnt %d", bcs->channel ? 'B' : 'A', count); QuickHex(t, p, count); debugl1(cs, bcs->blog); } } static void fill_hdlc(struct BCState *bcs) { long flags; save_flags(flags); cli(); hdlc_fill_fifo(bcs); restore_flags(flags); } static inline void HDLC_irq(struct BCState *bcs, u_int stat) { int len; struct sk_buff *skb; if (bcs->cs->debug & L1_DEB_HSCX) debugl1(bcs->cs, "ch%d stat %#x", bcs->channel, stat); if (stat & HDLC_INT_RPR) { if (stat & HDLC_STAT_RDO) { if (bcs->cs->debug & L1_DEB_HSCX) debugl1(bcs->cs, "RDO"); else debugl1(bcs->cs, "ch%d stat %#x", bcs->channel, stat); bcs->hw.hdlc.ctrl.sr.xml = 0; bcs->hw.hdlc.ctrl.sr.cmd |= HDLC_CMD_RRS; write_ctrl(bcs, 1); bcs->hw.hdlc.ctrl.sr.cmd &= ~HDLC_CMD_RRS; write_ctrl(bcs, 1); bcs->hw.hdlc.rcvidx = 0; } else { if (!(len = (stat & HDLC_STAT_RML_MASK)>>8)) len = 32; hdlc_empty_fifo(bcs, len); if ((stat & HDLC_STAT_RME) || (bcs->mode == L1_MODE_TRANS)) { if (((stat & HDLC_STAT_CRCVFRRAB)==HDLC_STAT_CRCVFR) || (bcs->mode == L1_MODE_TRANS)) { if (!(skb = dev_alloc_skb(bcs->hw.hdlc.rcvidx))) printk(KERN_WARNING "HDLC: receive out of memory\n"); else { memcpy(skb_put(skb, bcs->hw.hdlc.rcvidx), bcs->hw.hdlc.rcvbuf, bcs->hw.hdlc.rcvidx); skb_queue_tail(&bcs->rqueue, skb); } bcs->hw.hdlc.rcvidx = 0; hdlc_sched_event(bcs, B_RCVBUFREADY); } else { if (bcs->cs->debug & L1_DEB_HSCX) debugl1(bcs->cs, "invalid frame"); else debugl1(bcs->cs, "ch%d invalid frame %#x", bcs->channel, stat); bcs->hw.hdlc.rcvidx = 0; } } } } if (stat & HDLC_INT_XDU) { /* Here we lost an TX interrupt, so * restart transmitting the whole frame. */ if (bcs->tx_skb) { skb_push(bcs->tx_skb, bcs->hw.hdlc.count); bcs->tx_cnt += bcs->hw.hdlc.count; bcs->hw.hdlc.count = 0; // hdlc_sched_event(bcs, B_XMTBUFREADY); if (bcs->cs->debug & L1_DEB_WARN) debugl1(bcs->cs, "ch%d XDU", bcs->channel); } else if (bcs->cs->debug & L1_DEB_WARN) debugl1(bcs->cs, "ch%d XDU without skb", bcs->channel); bcs->hw.hdlc.ctrl.sr.xml = 0; bcs->hw.hdlc.ctrl.sr.cmd |= HDLC_CMD_XRS; write_ctrl(bcs, 1); bcs->hw.hdlc.ctrl.sr.cmd &= ~HDLC_CMD_XRS; write_ctrl(bcs, 1); hdlc_fill_fifo(bcs); } else if (stat & HDLC_INT_XPR) { if (bcs->tx_skb) { if (bcs->tx_skb->len) { hdlc_fill_fifo(bcs); return; } else { if (bcs->st->lli.l1writewakeup && (PACKET_NOACK != bcs->tx_skb->pkt_type)) bcs->st->lli.l1writewakeup(bcs->st, bcs->hw.hdlc.count); dev_kfree_skb(bcs->tx_skb, FREE_WRITE); bcs->hw.hdlc.count = 0; bcs->tx_skb = NULL; } } if ((bcs->tx_skb = skb_dequeue(&bcs->squeue))) { bcs->hw.hdlc.count = 0; test_and_set_bit(BC_FLG_BUSY, &bcs->Flag); hdlc_fill_fifo(bcs); } else { test_and_clear_bit(BC_FLG_BUSY, &bcs->Flag); hdlc_sched_event(bcs, B_XMTBUFREADY); } } } inline void HDLC_irq_main(struct IsdnCardState *cs) { u_int stat; long flags; struct BCState *bcs; save_flags(flags); cli(); if (cs->subtyp == AVM_FRITZ_PCI) { stat = ReadHDLCPCI(cs, 0, HDLC_STATUS); } else { stat = ReadHDLCPnP(cs, 0, HDLC_STATUS); if (stat & HDLC_INT_RPR) stat |= (ReadHDLCPnP(cs, 0, HDLC_STATUS+1))<<8; } if (stat & HDLC_INT_MASK) { if (!(bcs = Sel_BCS(cs, 0))) { if (cs->debug) debugl1(cs, "hdlc spurious channel 0 IRQ"); } else HDLC_irq(bcs, stat); } if (cs->subtyp == AVM_FRITZ_PCI) { stat = ReadHDLCPCI(cs, 1, HDLC_STATUS); } else { stat = ReadHDLCPnP(cs, 1, HDLC_STATUS); if (stat & HDLC_INT_RPR) stat |= (ReadHDLCPnP(cs, 1, HDLC_STATUS+1))<<8; } if (stat & HDLC_INT_MASK) { if (!(bcs = Sel_BCS(cs, 1))) { if (cs->debug) debugl1(cs, "hdlc spurious channel 1 IRQ"); } else HDLC_irq(bcs, stat); } restore_flags(flags); } void hdlc_l2l1(struct PStack *st, int pr, void *arg) { struct sk_buff *skb = arg; long flags; switch (pr) { case (PH_DATA | REQUEST): save_flags(flags); cli(); if (st->l1.bcs->tx_skb) { skb_queue_tail(&st->l1.bcs->squeue, skb); restore_flags(flags); } else { st->l1.bcs->tx_skb = skb; test_and_set_bit(BC_FLG_BUSY, &st->l1.bcs->Flag); st->l1.bcs->hw.hdlc.count = 0; restore_flags(flags); st->l1.bcs->cs->BC_Send_Data(st->l1.bcs); } break; case (PH_PULL | INDICATION): if (st->l1.bcs->tx_skb) { printk(KERN_WARNING "hdlc_l2l1: this shouldn't happen\n"); break; } test_and_set_bit(BC_FLG_BUSY, &st->l1.bcs->Flag); st->l1.bcs->tx_skb = skb; st->l1.bcs->hw.hdlc.count = 0; st->l1.bcs->cs->BC_Send_Data(st->l1.bcs); break; case (PH_PULL | REQUEST): if (!st->l1.bcs->tx_skb) { test_and_clear_bit(FLG_L1_PULL_REQ, &st->l1.Flags); st->l1.l1l2(st, PH_PULL | CONFIRM, NULL); } else test_and_set_bit(FLG_L1_PULL_REQ, &st->l1.Flags); break; case (PH_ACTIVATE | REQUEST): test_and_set_bit(BC_FLG_ACTIV, &st->l1.bcs->Flag); modehdlc(st->l1.bcs, st->l1.mode, st->l1.bc); l1_msg_b(st, pr, arg); break; case (PH_DEACTIVATE | REQUEST): l1_msg_b(st, pr, arg); break; case (PH_DEACTIVATE | CONFIRM): test_and_clear_bit(BC_FLG_ACTIV, &st->l1.bcs->Flag); test_and_clear_bit(BC_FLG_BUSY, &st->l1.bcs->Flag); modehdlc(st->l1.bcs, 0, st->l1.bc); st->l1.l1l2(st, PH_DEACTIVATE | CONFIRM, NULL); break; } } void close_hdlcstate(struct BCState *bcs) { modehdlc(bcs, 0, 0); if (test_and_clear_bit(BC_FLG_INIT, &bcs->Flag)) { if (bcs->hw.hdlc.rcvbuf) { kfree(bcs->hw.hdlc.rcvbuf); bcs->hw.hdlc.rcvbuf = NULL; } if (bcs->blog) { kfree(bcs->blog); bcs->blog = NULL; } discard_queue(&bcs->rqueue); discard_queue(&bcs->squeue); if (bcs->tx_skb) { dev_kfree_skb(bcs->tx_skb, FREE_WRITE); bcs->tx_skb = NULL; test_and_clear_bit(BC_FLG_BUSY, &bcs->Flag); } } } int open_hdlcstate(struct IsdnCardState *cs, struct BCState *bcs) { if (!test_and_set_bit(BC_FLG_INIT, &bcs->Flag)) { if (!(bcs->hw.hdlc.rcvbuf = kmalloc(HSCX_BUFMAX, GFP_ATOMIC))) { printk(KERN_WARNING "HiSax: No memory for hdlc.rcvbuf\n"); return (1); } if (!(bcs->blog = kmalloc(MAX_BLOG_SPACE, GFP_ATOMIC))) { printk(KERN_WARNING "HiSax: No memory for bcs->blog\n"); test_and_clear_bit(BC_FLG_INIT, &bcs->Flag); kfree(bcs->hw.hdlc.rcvbuf); bcs->hw.hdlc.rcvbuf = NULL; return (2); } skb_queue_head_init(&bcs->rqueue); skb_queue_head_init(&bcs->squeue); } bcs->tx_skb = NULL; test_and_clear_bit(BC_FLG_BUSY, &bcs->Flag); bcs->event = 0; bcs->hw.hdlc.rcvidx = 0; bcs->tx_cnt = 0; return (0); } int setstack_hdlc(struct PStack *st, struct BCState *bcs) { bcs->channel = st->l1.bc; if (open_hdlcstate(st->l1.hardware, bcs)) return (-1); st->l1.bcs = bcs; st->l2.l2l1 = hdlc_l2l1; setstack_manager(st); bcs->st = st; setstack_l1_B(st); return (0); } HISAX_INITFUNC(void clear_pending_hdlc_ints(struct IsdnCardState *cs)) { u_int val; if (cs->subtyp == AVM_FRITZ_PCI) { val = ReadHDLCPCI(cs, 0, HDLC_STATUS); debugl1(cs, "HDLC 1 STA %x", val); val = ReadHDLCPCI(cs, 1, HDLC_STATUS); debugl1(cs, "HDLC 2 STA %x", val); } else { val = ReadHDLCPnP(cs, 0, HDLC_STATUS); debugl1(cs, "HDLC 1 STA %x", val); val = ReadHDLCPnP(cs, 0, HDLC_STATUS + 1); debugl1(cs, "HDLC 1 RML %x", val); val = ReadHDLCPnP(cs, 0, HDLC_STATUS + 2); debugl1(cs, "HDLC 1 MODE %x", val); val = ReadHDLCPnP(cs, 0, HDLC_STATUS + 3); debugl1(cs, "HDLC 1 VIN %x", val); val = ReadHDLCPnP(cs, 1, HDLC_STATUS); debugl1(cs, "HDLC 2 STA %x", val); val = ReadHDLCPnP(cs, 1, HDLC_STATUS + 1); debugl1(cs, "HDLC 2 RML %x", val); val = ReadHDLCPnP(cs, 1, HDLC_STATUS + 2); debugl1(cs, "HDLC 2 MODE %x", val); val = ReadHDLCPnP(cs, 1, HDLC_STATUS + 3); debugl1(cs, "HDLC 2 VIN %x", val); } } HISAX_INITFUNC(void inithdlc(struct IsdnCardState *cs)) { cs->bcs[0].BC_SetStack = setstack_hdlc; cs->bcs[1].BC_SetStack = setstack_hdlc; cs->bcs[0].BC_Close = close_hdlcstate; cs->bcs[1].BC_Close = close_hdlcstate; modehdlc(cs->bcs, 0, 0); modehdlc(cs->bcs + 1, 0, 0); } static void avm_pcipnp_interrupt(int intno, void *dev_id, struct pt_regs *regs) { struct IsdnCardState *cs = dev_id; u_char val, stat = 0; u_char sval; if (!cs) { printk(KERN_WARNING "AVM PCI: Spurious interrupt!\n"); return; } sval = inb(cs->hw.avm.cfg_reg + 2); if ((sval & AVM_STATUS0_IRQ_MASK) == AVM_STATUS0_IRQ_MASK) /* possible a shared IRQ reqest */ return; if (!(sval & AVM_STATUS0_IRQ_ISAC)) { val = ReadISAC(cs, ISAC_ISTA); isac_interrupt(cs, val); stat |= 2; } if (!(sval & AVM_STATUS0_IRQ_HDLC)) { HDLC_irq_main(cs); } if (stat & 2) { WriteISAC(cs, ISAC_MASK, 0xFF); WriteISAC(cs, ISAC_MASK, 0x0); } } static void reset_avmpcipnp(struct IsdnCardState *cs) { long flags; printk(KERN_INFO "AVM PCI/PnP: reset\n"); save_flags(flags); sti(); outb(AVM_STATUS0_RESET | AVM_STATUS0_DIS_TIMER, cs->hw.avm.cfg_reg + 2); current->state = TASK_INTERRUPTIBLE; current->timeout = jiffies + (10 * HZ) / 1000; /* Timeout 10ms */ schedule(); outb(AVM_STATUS0_DIS_TIMER | AVM_STATUS0_RES_TIMER | AVM_STATUS0_ENA_IRQ, cs->hw.avm.cfg_reg + 2); outb(AVM_STATUS1_ENA_IOM | cs->irq, cs->hw.avm.cfg_reg + 3); current->state = TASK_INTERRUPTIBLE; current->timeout = jiffies + (10 * HZ) / 1000; /* Timeout 10ms */ schedule(); printk(KERN_INFO "AVM PCI/PnP: S1 %x\n", inb(cs->hw.avm.cfg_reg + 3)); } static int AVM_card_msg(struct IsdnCardState *cs, int mt, void *arg) { u_int irq_flag; switch (mt) { case CARD_RESET: reset_avmpcipnp(cs); return(0); case CARD_RELEASE: outb(0, cs->hw.avm.cfg_reg + 2); release_region(cs->hw.avm.cfg_reg, 32); return(0); case CARD_SETIRQ: if (cs->subtyp == AVM_FRITZ_PCI) irq_flag = I4L_IRQ_FLAG | SA_SHIRQ; else irq_flag = I4L_IRQ_FLAG; return(request_irq(cs->irq, &avm_pcipnp_interrupt, irq_flag, "HiSax", cs)); case CARD_INIT: clear_pending_isac_ints(cs); initisac(cs); clear_pending_hdlc_ints(cs); inithdlc(cs); outb(AVM_STATUS0_DIS_TIMER | AVM_STATUS0_RES_TIMER, cs->hw.avm.cfg_reg + 2); WriteISAC(cs, ISAC_MASK, 0); outb(AVM_STATUS0_DIS_TIMER | AVM_STATUS0_RES_TIMER | AVM_STATUS0_ENA_IRQ, cs->hw.avm.cfg_reg + 2); /* RESET Receiver and Transmitter */ WriteISAC(cs, ISAC_CMDR, 0x41); return(0); case CARD_TEST: return(0); } return(0); } static int pci_index __initdata = 0; __initfunc(int setup_avm_pcipnp(struct IsdnCard *card)) { u_int val, ver; struct IsdnCardState *cs = card->cs; char tmp[64]; strcpy(tmp, avm_pci_rev); printk(KERN_INFO "HiSax: AVM PCI/ISAPnP driver Rev. %s\n", HiSax_getrev(tmp)); if (cs->typ != ISDN_CTYPE_FRITZPCI) return (0); if (card->para[1]) { cs->hw.avm.cfg_reg = card->para[1]; cs->irq = card->para[0]; cs->subtyp = AVM_FRITZ_PNP; } else { #if CONFIG_PCI for (; pci_index < 255; pci_index++) { unsigned char pci_bus, pci_device_fn; unsigned int ioaddr; unsigned char irq; if (pcibios_find_device (PCI_VENDOR_AVM, PCI_FRITZPCI_ID, pci_index, &pci_bus, &pci_device_fn) != 0) { continue; } pcibios_read_config_byte(pci_bus, pci_device_fn, PCI_INTERRUPT_LINE, &irq); pcibios_read_config_dword(pci_bus, pci_device_fn, PCI_BASE_ADDRESS_1, &ioaddr); cs->irq = irq; cs->hw.avm.cfg_reg = ioaddr & PCI_BASE_ADDRESS_IO_MASK; if (!cs->hw.avm.cfg_reg) { printk(KERN_WARNING "FritzPCI: No IO-Adr for PCI card found\n"); return(0); } cs->subtyp = AVM_FRITZ_PCI; break; } if (pci_index == 255) { printk(KERN_WARNING "FritzPCI: No PCI card found\n"); return(0); } pci_index++; #else printk(KERN_WARNING "FritzPCI: NO_PCI_BIOS\n"); return (0); #endif /* CONFIG_PCI */ } cs->hw.avm.isac = cs->hw.avm.cfg_reg + 0x10; if (check_region((cs->hw.avm.cfg_reg), 32)) { printk(KERN_WARNING "HiSax: %s config port %x-%x already in use\n", CardType[card->typ], cs->hw.avm.cfg_reg, cs->hw.avm.cfg_reg + 31); return (0); } else { request_region(cs->hw.avm.cfg_reg, 32, (cs->subtyp == AVM_FRITZ_PCI) ? "avm PCI" : "avm PnP"); } switch (cs->subtyp) { case AVM_FRITZ_PCI: val = inl(cs->hw.avm.cfg_reg); printk(KERN_INFO "AVM PCI: stat %#x\n", val); printk(KERN_INFO "AVM PCI: Class %X Rev %d\n", val & 0xff, (val>>8) & 0xff); cs->BC_Read_Reg = &ReadHDLC_s; cs->BC_Write_Reg = &WriteHDLC_s; break; case AVM_FRITZ_PNP: val = inb(cs->hw.avm.cfg_reg); ver = inb(cs->hw.avm.cfg_reg + 1); printk(KERN_INFO "AVM PnP: Class %X Rev %d\n", val, ver); reset_avmpcipnp(cs); cs->BC_Read_Reg = &ReadHDLCPnP; cs->BC_Write_Reg = &WriteHDLCPnP; break; default: printk(KERN_WARNING "AVM unknown subtype %d\n", cs->subtyp); return(0); } printk(KERN_INFO "HiSax: %s config irq:%d base:0x%X\n", (cs->subtyp == AVM_FRITZ_PCI) ? "AVM Fritz!PCI" : "AVM Fritz!PnP", cs->irq, cs->hw.avm.cfg_reg); cs->readisac = &ReadISAC; cs->writeisac = &WriteISAC; cs->readisacfifo = &ReadISACfifo; cs->writeisacfifo = &WriteISACfifo; cs->BC_Send_Data = &fill_hdlc; cs->cardmsg = &AVM_card_msg; ISACVersion(cs, (cs->subtyp == AVM_FRITZ_PCI) ? "AVM PCI:" : "AVM PnP:"); return (1); }
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