Index: dahdi-linux-2.1.0/drivers/dahdi/zaphfc.c =================================================================== --- /dev/null 1970-01-01 00:00:00.000000000 +0000 +++ dahdi-linux-2.1.0/drivers/dahdi/zaphfc.c 2008-12-10 12:46:14.000000000 +0200 @@ -0,0 +1,1129 @@ +/* + * zaphfc.c - Zaptel driver for HFC-S PCI A based ISDN BRI cards + * + * kernel module inspired by HFC PCI ISDN4Linux and Zaptel drivers + * + * Copyright (C) 2002, 2003, 2004, 2005 Junghanns.NET GmbH + * + * Klaus-Peter Junghanns + * + * This program is free software and may be modified and + * distributed under the terms of the GNU Public License. + * + */ + +#include +#include +#ifdef RTAITIMING +#include +#include +#include +#include +#endif +#include +#include +#include +#include +#include +#include "zaphfc.h" + +#include + +#if CONFIG_PCI + +#define CLKDEL_TE 0x0f /* CLKDEL in TE mode */ +#define CLKDEL_NT 0x6c /* CLKDEL in NT mode */ + +typedef struct { + int vendor_id; + int device_id; + char *vendor_name; + char *card_name; +} PCI_ENTRY; + +static const PCI_ENTRY id_list[] = +{ + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_2BD0, "CCD/Billion/Asuscom", "2BD0"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B000, "Billion", "B000"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B006, "Billion", "B006"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B007, "Billion", "B007"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B008, "Billion", "B008"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B009, "Billion", "B009"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B00A, "Billion", "B00A"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B00B, "Billion", "B00B"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B00C, "Billion", "B00C"}, + {PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_B100, "Seyeon", "B100"}, + {PCI_VENDOR_ID_ABOCOM, PCI_DEVICE_ID_ABOCOM_2BD1, "Abocom/Magitek", "2BD1"}, + {PCI_VENDOR_ID_ASUSTEK, PCI_DEVICE_ID_ASUSTEK_0675, "Asuscom/Askey", "675"}, + {PCI_VENDOR_ID_BERKOM, PCI_DEVICE_ID_BERKOM_T_CONCEPT, "German telekom", "T-Concept"}, + {PCI_VENDOR_ID_BERKOM, PCI_DEVICE_ID_BERKOM_A1T, "German telekom", "A1T"}, + {PCI_VENDOR_ID_ANIGMA, PCI_DEVICE_ID_ANIGMA_MC145575, "Motorola MC145575", "MC145575"}, + {PCI_VENDOR_ID_ZOLTRIX, PCI_DEVICE_ID_ZOLTRIX_2BD0, "Zoltrix", "2BD0"}, + {PCI_VENDOR_ID_DIGI, PCI_DEVICE_ID_DIGI_DF_M_IOM2_E,"Digi International", "Digi DataFire Micro V IOM2 (Europe)"}, + {PCI_VENDOR_ID_DIGI, PCI_DEVICE_ID_DIGI_DF_M_E,"Digi International", "Digi DataFire Micro V (Europe)"}, + {PCI_VENDOR_ID_DIGI, PCI_DEVICE_ID_DIGI_DF_M_IOM2_A,"Digi International", "Digi DataFire Micro V IOM2 (North America)"}, + {PCI_VENDOR_ID_DIGI, PCI_DEVICE_ID_DIGI_DF_M_A,"Digi International", "Digi DataFire Micro V (North America)"}, + {0x182d, 0x3069,"Sitecom","Isdn 128 PCI"}, + {0, 0, NULL, NULL}, +}; + +static struct hfc_card *hfc_dev_list = NULL; +static int hfc_dev_count = 0; +static int modes = 0; // all TE +static int debug = 0; +static struct pci_dev *multi_hfc = NULL; +static spinlock_t registerlock = SPIN_LOCK_UNLOCKED; + +void hfc_shutdownCard(struct hfc_card *hfctmp) { + unsigned long flags; + + if (hfctmp == NULL) { + return; + } + + if (hfctmp->pci_io == NULL) { + return; + } + + spin_lock_irqsave(&hfctmp->lock,flags); + + printk(KERN_INFO "zaphfc: shutting down card at %p.\n",hfctmp->pci_io); + + /* Clear interrupt mask */ + hfctmp->regs.int_m2 = 0; + hfc_outb(hfctmp, hfc_INT_M2, hfctmp->regs.int_m2); + + /* Reset pending interrupts */ + hfc_inb(hfctmp, hfc_INT_S1); + + /* Wait for interrupts that might still be pending */ + spin_unlock_irqrestore(&hfctmp->lock, flags); + set_current_state(TASK_UNINTERRUPTIBLE); + schedule_timeout((30 * HZ) / 1000); // wait 30 ms + spin_lock_irqsave(&hfctmp->lock,flags); + + /* Remove interrupt handler */ + if (hfctmp->irq) { + free_irq(hfctmp->irq, hfctmp); + } + + /* Soft-reset the card */ + hfc_outb(hfctmp, hfc_CIRM, hfc_CIRM_RESET); // softreset on + + spin_unlock_irqrestore(&hfctmp->lock, flags); + set_current_state(TASK_UNINTERRUPTIBLE); + schedule_timeout((30 * HZ) / 1000); // wait 30 ms + spin_lock_irqsave(&hfctmp->lock,flags); + + hfc_outb(hfctmp,hfc_CIRM,0); // softreset off + + pci_write_config_word(hfctmp->pcidev, PCI_COMMAND, 0); // disable memio and bustmaster + + if (hfctmp->fifomem != NULL) { + kfree(hfctmp->fifomem); + } + iounmap((void *) hfctmp->pci_io); + hfctmp->pci_io = NULL; + if (hfctmp->pcidev != NULL) { + pci_disable_device(hfctmp->pcidev); + } + spin_unlock_irqrestore(&hfctmp->lock,flags); + if (hfctmp->ztdev != NULL) { + dahdi_unregister(&hfctmp->ztdev->span); + kfree(hfctmp->ztdev); + printk(KERN_INFO "unregistered from DAHDI.\n"); + } +} + +void hfc_resetCard(struct hfc_card *hfctmp) { + unsigned long flags; + + spin_lock_irqsave(&hfctmp->lock,flags); + pci_write_config_word(hfctmp->pcidev, PCI_COMMAND, PCI_COMMAND_MEMORY); // enable memio + hfctmp->regs.int_m2 = 0; + hfc_outb(hfctmp, hfc_INT_M2, hfctmp->regs.int_m2); + +// printk(KERN_INFO "zaphfc: resetting card.\n"); + pci_set_master(hfctmp->pcidev); + hfc_outb(hfctmp, hfc_CIRM, hfc_CIRM_RESET); // softreset on + spin_unlock_irqrestore(&hfctmp->lock, flags); + + set_current_state(TASK_UNINTERRUPTIBLE); + schedule_timeout((30 * HZ) / 1000); // wait 30 ms + hfc_outb(hfctmp, hfc_CIRM, 0); // softreset off + + set_current_state(TASK_UNINTERRUPTIBLE); + schedule_timeout((20 * HZ) / 1000); // wait 20 ms + if (hfc_inb(hfctmp,hfc_STATUS) & hfc_STATUS_PCI_PROC) { + printk(KERN_WARNING "zaphfc: hfc busy.\n"); + } + +// hfctmp->regs.fifo_en = hfc_FIFOEN_D | hfc_FIFOEN_B1 | hfc_FIFOEN_B2; +// hfctmp->regs.fifo_en = hfc_FIFOEN_D; /* only D fifos enabled */ + hfctmp->regs.fifo_en = 0; /* no fifos enabled */ + hfc_outb(hfctmp, hfc_FIFO_EN, hfctmp->regs.fifo_en); + + hfctmp->regs.trm = 2; + hfc_outb(hfctmp, hfc_TRM, hfctmp->regs.trm); + + if (hfctmp->regs.nt_mode == 1) { + hfc_outb(hfctmp, hfc_CLKDEL, CLKDEL_NT); /* ST-Bit delay for NT-Mode */ + } else { + hfc_outb(hfctmp, hfc_CLKDEL, CLKDEL_TE); /* ST-Bit delay for TE-Mode */ + } + hfctmp->regs.sctrl_e = hfc_SCTRL_E_AUTO_AWAKE; + hfc_outb(hfctmp, hfc_SCTRL_E, hfctmp->regs.sctrl_e); /* S/T Auto awake */ + hfctmp->regs.bswapped = 0; /* no exchange */ + + hfctmp->regs.ctmt = hfc_CTMT_TRANSB1 | hfc_CTMT_TRANSB2; // all bchans are transparent , no freaking hdlc + hfc_outb(hfctmp, hfc_CTMT, hfctmp->regs.ctmt); + + hfctmp->regs.int_m1 = 0; + hfc_outb(hfctmp, hfc_INT_M1, hfctmp->regs.int_m1); + +#ifdef RTAITIMING + hfctmp->regs.int_m2 = 0; +#else + hfctmp->regs.int_m2 = hfc_M2_PROC_TRANS; +#endif + hfc_outb(hfctmp, hfc_INT_M2, hfctmp->regs.int_m2); + + /* Clear already pending ints */ + hfc_inb(hfctmp, hfc_INT_S1); + + if (hfctmp->regs.nt_mode == 1) { + hfctmp->regs.sctrl = 3 | hfc_SCTRL_NONE_CAP | hfc_SCTRL_MODE_NT; /* set tx_lo mode, error in datasheet ! */ + } else { + hfctmp->regs.sctrl = 3 | hfc_SCTRL_NONE_CAP | hfc_SCTRL_MODE_TE; /* set tx_lo mode, error in datasheet ! */ + } + + hfctmp->regs.mst_mode = hfc_MST_MODE_MASTER; /* HFC Master Mode */ + hfc_outb(hfctmp, hfc_MST_MODE, hfctmp->regs.mst_mode); + + hfc_outb(hfctmp, hfc_SCTRL, hfctmp->regs.sctrl); + hfctmp->regs.sctrl_r = 3; + hfc_outb(hfctmp, hfc_SCTRL_R, hfctmp->regs.sctrl_r); + + hfctmp->regs.connect = 0; + hfc_outb(hfctmp, hfc_CONNECT, hfctmp->regs.connect); + + hfc_outb(hfctmp, hfc_CIRM, 0x80 | 0x40); // bit order + + /* Finally enable IRQ output */ +#ifndef RTAITIMING + hfctmp->regs.int_m2 |= hfc_M2_IRQ_ENABLE; + hfc_outb(hfctmp, hfc_INT_M2, hfctmp->regs.int_m2); +#endif + + /* clear pending ints */ + hfc_inb(hfctmp, hfc_INT_S1); + hfc_inb(hfctmp, hfc_INT_S2); +} + +void hfc_registerCard(struct hfc_card *hfccard) { + spin_lock(®isterlock); + if (hfccard != NULL) { + hfccard->cardno = hfc_dev_count++; + hfccard->next = hfc_dev_list; + hfc_dev_list = hfccard; + } + spin_unlock(®isterlock); +} + +static void hfc_btrans(struct hfc_card *hfctmp, char whichB) { + // we are called with irqs disabled from the irq handler + int count, maxlen, total; + unsigned char *f1, *f2; + unsigned short *z1, *z2, newz1; + int freebytes; + + if (whichB == 1) { + f1 = (char *)(hfctmp->fifos + hfc_FIFO_B1TX_F1); + f2 = (char *)(hfctmp->fifos + hfc_FIFO_B1TX_F2); + z1 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B1TX_Z1 + (*f1 * 4)); + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B1TX_Z2 + (*f1 * 4)); + } else { + f1 = (char *)(hfctmp->fifos + hfc_FIFO_B2TX_F1); + f2 = (char *)(hfctmp->fifos + hfc_FIFO_B2TX_F2); + z1 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B2TX_Z1 + (*f1 * 4)); + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B2TX_Z2 + (*f1 * 4)); + } + + freebytes = *z2 - *z1; + if (freebytes <= 0) { + freebytes += hfc_B_FIFO_SIZE; + } + count = DAHDI_CHUNKSIZE; + + total = count; + if (freebytes < count) { + hfctmp->clicks++; + /* only spit out this warning once per second to not make things worse! */ + if (hfctmp->clicks > 100) { + printk(KERN_CRIT "zaphfc: bchan tx fifo full, dropping audio! (z1=%d, z2=%d)\n",*z1,*z2); + hfctmp->clicks = 0; + } + return; + } + + maxlen = (hfc_B_FIFO_SIZE + hfc_B_SUB_VAL) - *z1; + if (maxlen > count) { + maxlen = count; + } + newz1 = *z1 + total; + if (newz1 >= (hfc_B_FIFO_SIZE + hfc_B_SUB_VAL)) { newz1 -= hfc_B_FIFO_SIZE; } + + if (whichB == 1) { + memcpy((char *)(hfctmp->fifos + hfc_FIFO_B1TX_ZOFF + *z1),hfctmp->ztdev->chans[0].writechunk, maxlen); + } else { + memcpy((char *)(hfctmp->fifos + hfc_FIFO_B2TX_ZOFF + *z1),hfctmp->ztdev->chans[1].writechunk, maxlen); + } + + count -= maxlen; + if (count > 0) { + // Buffer wrap + if (whichB == 1) { + memcpy((char *)(hfctmp->fifos + hfc_FIFO_B1TX_ZOFF + hfc_B_SUB_VAL),hfctmp->ztdev->chans[0].writechunk+maxlen, count); + } else { + memcpy((char *)(hfctmp->fifos + hfc_FIFO_B2TX_ZOFF + hfc_B_SUB_VAL),hfctmp->ztdev->chans[1].writechunk+maxlen, count); + } + } + + *z1 = newz1; /* send it now */ + +// if (count > 0) printk(KERN_CRIT "zaphfc: bchan tx fifo (f1=%d, f2=%d, z1=%d, z2=%d)\n",(*f1) & hfc_FMASK,(*f2) & hfc_FMASK, *z1, *z2); + return; +} + +static void hfc_brec(struct hfc_card *hfctmp, char whichB) { + // we are called with irqs disabled from the irq handler + int count, maxlen, drop; + volatile unsigned char *f1, *f2; + volatile unsigned short *z1, *z2, newz2; + int bytes = 0; + + if (whichB == 1) { + f1 = (char *)(hfctmp->fifos + hfc_FIFO_B1RX_F1); + f2 = (char *)(hfctmp->fifos + hfc_FIFO_B1RX_F2); + z1 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B1RX_Z1 + (*f1 * 4)); + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B1RX_Z2 + (*f1 * 4)); + } else { + f1 = (char *)(hfctmp->fifos + hfc_FIFO_B2RX_F1); + f2 = (char *)(hfctmp->fifos + hfc_FIFO_B2RX_F2); + z1 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B2RX_Z1 + (*f1 * 4)); + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B2RX_Z2 + (*f1 * 4)); + } + + bytes = *z1 - *z2; + if (bytes < 0) { + bytes += hfc_B_FIFO_SIZE; + } + count = DAHDI_CHUNKSIZE; + + if (bytes < DAHDI_CHUNKSIZE) { +#ifndef RTAITIMING + printk(KERN_CRIT "zaphfc: bchan rx fifo not enough bytes to receive! (z1=%d, z2=%d, wanted %d got %d), probably a buffer overrun.\n",*z1,*z2,DAHDI_CHUNKSIZE,bytes); +#endif + return; + } + + /* allowing the buffering of hfc_BCHAN_BUFFER bytes of audio data works around irq jitter */ + if (bytes > hfc_BCHAN_BUFFER + DAHDI_CHUNKSIZE) { + /* if the system is too slow to handle it, we will have to drop it all (except 1 DAHDI chunk) */ + drop = bytes - DAHDI_CHUNKSIZE; + hfctmp->clicks++; + /* only spit out this warning once per second to not make things worse! */ + if (hfctmp->clicks > 100) { + printk(KERN_CRIT "zaphfc: dropped audio (z1=%d, z2=%d, wanted %d got %d, dropped %d).\n",*z1,*z2,count,bytes,drop); + hfctmp->clicks = 0; + } + /* hm, we are processing the b chan data tooooo slowly... let's drop the lost audio */ + newz2 = *z2 + drop; + if (newz2 >= (hfc_B_FIFO_SIZE + hfc_B_SUB_VAL)) { + newz2 -= hfc_B_FIFO_SIZE; + } + *z2 = newz2; + } + + + maxlen = (hfc_B_FIFO_SIZE + hfc_B_SUB_VAL) - *z2; + if (maxlen > count) { + maxlen = count; + } + if (whichB == 1) { + memcpy(hfctmp->ztdev->chans[0].readchunk,(char *)(hfctmp->fifos + hfc_FIFO_B1RX_ZOFF + *z2), maxlen); + } else { + memcpy(hfctmp->ztdev->chans[1].readchunk,(char *)(hfctmp->fifos + hfc_FIFO_B2RX_ZOFF + *z2), maxlen); + } + newz2 = *z2 + count; + if (newz2 >= (hfc_B_FIFO_SIZE + hfc_B_SUB_VAL)) { + newz2 -= hfc_B_FIFO_SIZE; + } + *z2 = newz2; + + count -= maxlen; + if (count > 0) { + // Buffer wrap + if (whichB == 1) { + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B1RX_Z2 + (*f1 * 4)); + memcpy(hfctmp->ztdev->chans[0].readchunk + maxlen,(char *)(hfctmp->fifos + hfc_FIFO_B1RX_ZOFF + hfc_B_SUB_VAL), count); + } else { + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_B2RX_Z2 + (*f1 * 4)); + memcpy(hfctmp->ztdev->chans[1].readchunk + maxlen,(char *)(hfctmp->fifos + hfc_FIFO_B2RX_ZOFF + hfc_B_SUB_VAL), count); + } + newz2 = *z2 + count; + if (newz2 >= (hfc_B_FIFO_SIZE + hfc_B_SUB_VAL)) { + newz2 -= hfc_B_FIFO_SIZE; + } + } + + + if (whichB == 1) { + dahdi_ec_chunk(&hfctmp->ztdev->chans[0], hfctmp->ztdev->chans[0].readchunk, hfctmp->ztdev->chans[0].writechunk); + } else { + dahdi_ec_chunk(&hfctmp->ztdev->chans[1], hfctmp->ztdev->chans[1].readchunk, hfctmp->ztdev->chans[1].writechunk); + } + return; +} + + +static void hfc_dtrans(struct hfc_card *hfctmp) { + // we are called with irqs disabled from the irq handler + int x; + int count, maxlen, total; + unsigned char *f1, *f2, newf1; + unsigned short *z1, *z2, newz1; + int frames, freebytes; + + if (hfctmp->ztdev->chans[2].bytes2transmit == 0) { + return; + } + + f1 = (char *)(hfctmp->fifos + hfc_FIFO_DTX_F1); + f2 = (char *)(hfctmp->fifos + hfc_FIFO_DTX_F2); + z1 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_DTX_Z1 + (*f1 * 4)); + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_DTX_Z2 + (*f1 * 4)); + + frames = (*f1 - *f2) & hfc_FMASK; + if (frames < 0) { + frames += hfc_MAX_DFRAMES + 1; + } + + if (frames >= hfc_MAX_DFRAMES) { + printk(KERN_CRIT "zaphfc: dchan tx fifo total number of frames exceeded!\n"); + return; + } + + freebytes = *z2 - *z1; + if (freebytes <= 0) { + freebytes += hfc_D_FIFO_SIZE; + } + count = hfctmp->ztdev->chans[2].bytes2transmit; + + total = count; + if (freebytes < count) { + printk(KERN_CRIT "zaphfc: dchan tx fifo not enough free bytes! (z1=%d, z2=%d)\n",*z1,*z2); + return; + } + + newz1 = (*z1 + count) & hfc_ZMASK; + newf1 = ((*f1 + 1) & hfc_MAX_DFRAMES) | (hfc_MAX_DFRAMES + 1); // next frame + + if (count > 0) { + if (debug) { + printk(KERN_CRIT "zaphfc: card %d TX [ ", hfctmp->cardno); + for (x=0; xdtransbuf[x]); + } + if (hfctmp->ztdev->chans[2].eoftx == 1) { + printk("] %d bytes\n", count); + } else { + printk("..] %d bytes\n", count); + } + } + maxlen = hfc_D_FIFO_SIZE - *z1; + if (maxlen > count) { + maxlen = count; + } + memcpy((char *)(hfctmp->fifos + hfc_FIFO_DTX_ZOFF + *z1),hfctmp->ztdev->chans[2].writechunk, maxlen); + count -= maxlen; + if (count > 0) { + memcpy((char *)(hfctmp->fifos + hfc_FIFO_DTX_ZOFF),(char *)(hfctmp->ztdev->chans[2].writechunk + maxlen), count); + } + } + + *z1 = newz1; + + if (hfctmp->ztdev->chans[2].eoftx == 1) { + *f1 = newf1; + z1 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_DTX_Z1 + (*f1 * 4)); + *z1 = newz1; + hfctmp->ztdev->chans[2].eoftx = 0; + } +// printk(KERN_CRIT "zaphfc: dchan tx fifo (f1=%d, f2=%d, z1=%d, z2=%d)\n",(*f1) & hfc_FMASK,(*f2) & hfc_FMASK, *z1, *z2); + return; +} + +/* receive a complete hdlc frame, skip broken or short frames */ +static void hfc_drec(struct hfc_card *hfctmp) { + int count=0, maxlen=0, framelen=0; + unsigned char *f1, *f2, *crcstat; + unsigned short *z1, *z2, oldz2, newz2; + + hfctmp->ztdev->chans[2].bytes2receive=0; + hfctmp->ztdev->chans[2].eofrx = 0; + + /* put the received data into the DAHDI buffer + we'll call dahdi_receive() later when the timer fires. */ + f1 = (char *)(hfctmp->fifos + hfc_FIFO_DRX_F1); + f2 = (char *)(hfctmp->fifos + hfc_FIFO_DRX_F2); + + if (*f1 == *f2) return; /* nothing received, strange eh? */ + + z1 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_DRX_Z1 + (*f2 * 4)); + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_DRX_Z2 + (*f2 * 4)); + + /* calculate length of frame, including 2 bytes CRC and 1 byte STAT */ + count = *z1 - *z2; + + if (count < 0) { + count += hfc_D_FIFO_SIZE; /* ring buffer wrapped */ + } + count++; + framelen = count; + + crcstat = (char *)(hfctmp->fifos + hfc_FIFO_DRX_ZOFF + *z1); + + if ((framelen < 4) || (*crcstat != 0x0)) { + /* the frame is too short for a valid HDLC frame or the CRC is borked */ + printk(KERN_CRIT "zaphfc: empty HDLC frame or bad CRC received (framelen = %d, stat = %#x, card = %d).\n", framelen, *crcstat, hfctmp->cardno); + oldz2 = *z2; + *f2 = ((*f2 + 1) & hfc_MAX_DFRAMES) | (hfc_MAX_DFRAMES + 1); /* NEXT!!! */ + // recalculate z2, because Z2 is a function of F2 Z2(F2) and we INCed F2!!! + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_DRX_Z2 + (*f2 * 4)); + *z2 = (oldz2 + framelen) & hfc_ZMASK; + hfctmp->drecinframe = 0; + hfctmp->regs.int_drec--; + /* skip short or broken frames */ + hfctmp->ztdev->chans[2].bytes2receive = 0; + return; + } + + count -= 1; /* strip STAT */ + hfctmp->ztdev->chans[2].eofrx = 1; + + if (count + *z2 <= hfc_D_FIFO_SIZE) { + maxlen = count; + } else { + maxlen = hfc_D_FIFO_SIZE - *z2; + } + + /* copy first part */ + memcpy(hfctmp->drecbuf, (char *)(hfctmp->fifos + hfc_FIFO_DRX_ZOFF + *z2), maxlen); + hfctmp->ztdev->chans[2].bytes2receive += maxlen; + + count -= maxlen; + if (count > 0) { + /* ring buffer wrapped, copy rest from start of d fifo */ + memcpy(hfctmp->drecbuf + maxlen, (char *)(hfctmp->fifos + hfc_FIFO_DRX_ZOFF), count); + hfctmp->ztdev->chans[2].bytes2receive += count; + } + + /* frame read */ + oldz2 = *z2; + newz2 = (oldz2 + framelen) & hfc_ZMASK; + *f2 = ((*f2 + 1) & hfc_MAX_DFRAMES) | (hfc_MAX_DFRAMES + 1); /* NEXT!!! */ + /* recalculate z2, because Z2 is a function of F2 Z2(F2) and we INCed F2!!! */ + z2 = (unsigned short *)(hfctmp->fifos + hfc_FIFO_DRX_Z2 + (*f2 * 4)); + *z2 = newz2; + hfctmp->drecinframe = 0; + hfctmp->regs.int_drec--; +} + +#ifndef RTAITIMING +DAHDI_IRQ_HANDLER(hfc_interrupt) { + struct hfc_card *hfctmp = dev_id; + unsigned long flags = 0; + unsigned char stat; +#else +static void hfc_service(struct hfc_card *hfctmp) { +#endif + struct dahdi_hfc *zthfc; + unsigned char s1, s2, l1state; + int x; + + if (!hfctmp) { +#ifndef RTAITIMING + return IRQ_NONE; +#else + /* rtai */ + return; +#endif + } + + if (!hfctmp->pci_io) { + printk(KERN_WARNING "%s: IO-mem disabled, cannot handle interrupt\n", + __FUNCTION__); +#ifndef RTAITIMING + return IRQ_NONE; +#else + /* rtai */ + return; +#endif + } + + /* we assume a few things in this irq handler: + - the hfc-pci will only generate "timer" irqs (proc/non-proc) + - we need to use every 8th IRQ (to generate 1khz timing) + OR + - if we use rtai for timing the hfc-pci will not generate ANY irq, + instead rtai will call this "fake" irq with a 1khz realtime timer. :) + - rtai will directly service the card, not like it used to by triggering + the linux irq + */ + +#ifndef RTAITIMING + spin_lock_irqsave(&hfctmp->lock, flags); + stat = hfc_inb(hfctmp, hfc_STATUS); + + if ((stat & hfc_STATUS_ANYINT) == 0) { + // maybe we are sharing the irq + spin_unlock_irqrestore(&hfctmp->lock,flags); + return IRQ_NONE; + } +#endif + + s1 = hfc_inb(hfctmp, hfc_INT_S1); + s2 = hfc_inb(hfctmp, hfc_INT_S2); + if (s1 != 0) { + if (s1 & hfc_INTS_TIMER) { + // timer (bit 7) + // printk(KERN_CRIT "timer %d %d %d.\n", stat, s1, s2); + } + if (s1 & hfc_INTS_L1STATE) { + // state machine (bit 6) + // printk(KERN_CRIT "zaphfc: layer 1 state machine interrupt\n"); + zthfc = hfctmp->ztdev; + l1state = hfc_inb(hfctmp,hfc_STATES) & hfc_STATES_STATE_MASK; + if (hfctmp->regs.nt_mode == 1) { + if (debug) { + printk(KERN_CRIT "zaphfc: card %d layer 1 state = G%d\n", hfctmp->cardno, l1state); + } + switch (l1state) { + case 3: +#ifdef RTAITIMING + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [NT] layer 1 ACTIVATED (G%d) [realtime]", hfctmp->cardno, l1state); +#else + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [NT] layer 1 ACTIVATED (G%d)", hfctmp->cardno, l1state); +#endif + break; + default: +#ifdef RTAITIMING + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [NT] layer 1 DEACTIVATED (G%d) [realtime]", hfctmp->cardno, l1state); +#else + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [NT] layer 1 DEACTIVATED (G%d)", hfctmp->cardno, l1state); +#endif + } + if (l1state == 2) { + hfc_outb(hfctmp, hfc_STATES, hfc_STATES_ACTIVATE | hfc_STATES_DO_ACTION | hfc_STATES_NT_G2_G3); + } else if (l1state == 3) { + // fix to G3 state (see specs) + hfc_outb(hfctmp, hfc_STATES, hfc_STATES_LOAD_STATE | 3); + } + } else { + if (debug) { + printk(KERN_CRIT "zaphfc: card %d layer 1 state = F%d\n", hfctmp->cardno, l1state); + } + switch (l1state) { + case 7: +#ifdef RTAITIMING + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [TE] layer 1 ACTIVATED (F%d) [realtime]", hfctmp->cardno, l1state); +#else + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [TE] layer 1 ACTIVATED (F%d)", hfctmp->cardno, l1state); +#endif + break; + default: +#ifdef RTAITIMING + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [TE] layer 1 DEACTIVATED (F%d) [realtime]", hfctmp->cardno, l1state); +#else + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [TE] layer 1 DEACTIVATED (F%d)", hfctmp->cardno, l1state); +#endif + } + if (l1state == 3) { + hfc_outb(hfctmp, hfc_STATES, hfc_STATES_DO_ACTION | hfc_STATES_ACTIVATE); + } + } + + } + if (s1 & hfc_INTS_DREC) { + // D chan RX (bit 5) + hfctmp->regs.int_drec++; + // mr. zapata there is something for you! + // printk(KERN_CRIT "d chan rx\n"); + } + if (s1 & hfc_INTS_B2REC) { + // B2 chan RX (bit 4) + } + if (s1 & hfc_INTS_B1REC) { + // B1 chan RX (bit 3) + } + if (s1 & hfc_INTS_DTRANS) { + // D chan TX (bit 2) +// printk(KERN_CRIT "zaphfc: dchan frame transmitted.\n"); + } + if (s1 & hfc_INTS_B2TRANS) { + // B2 chan TX (bit 1) + } + if (s1 & hfc_INTS_B1TRANS) { + // B1 chan TX (bit 0) + } + } +#ifdef RTAITIMING + /* fake an irq */ + s2 |= hfc_M2_PROC_TRANS; +#endif + if (s2 != 0) { + if (s2 & hfc_M2_PMESEL) { + // kaboom irq (bit 7) + printk(KERN_CRIT "zaphfc: sync lost, pci performance too low. you might have some cpu throtteling enabled.\n"); + } + if (s2 & hfc_M2_GCI_MON_REC) { + // RxR monitor channel (bit 2) + } + if (s2 & hfc_M2_GCI_I_CHG) { + // GCI I-change (bit 1) + } + if (s2 & hfc_M2_PROC_TRANS) { + // processing/non-processing transition (bit 0) + hfctmp->ticks++; +#ifndef RTAITIMING + if (hfctmp->ticks > 7) { + // welcome to DAHDI timing :) +#endif + hfctmp->ticks = 0; + + if (hfctmp->ztdev->span.flags & DAHDI_FLAG_RUNNING) { + // clear dchan buffer + hfctmp->ztdev->chans[2].bytes2transmit = 0; + hfctmp->ztdev->chans[2].maxbytes2transmit = hfc_D_FIFO_SIZE; + + dahdi_transmit(&(hfctmp->ztdev->span)); + + hfc_btrans(hfctmp,1); + hfc_btrans(hfctmp,2); + hfc_dtrans(hfctmp); + } + + hfc_brec(hfctmp,1); + hfc_brec(hfctmp,2); + if (hfctmp->regs.int_drec > 0) { + // dchan data to read + hfc_drec(hfctmp); + if (hfctmp->ztdev->chans[2].bytes2receive > 0) { + if (debug) { + printk(KERN_CRIT "zaphfc: card %d RX [ ", hfctmp->cardno); + if (hfctmp->ztdev->chans[2].eofrx) { + /* dont output CRC == less user confusion */ + for (x=0; x < hfctmp->ztdev->chans[2].bytes2receive - 2; x++) { + printk("%#2x ", hfctmp->drecbuf[x]); + } + printk("] %d bytes\n", hfctmp->ztdev->chans[2].bytes2receive - 2); + } else { + for (x=0; x < hfctmp->ztdev->chans[2].bytes2receive; x++) { + printk("%#2x ", hfctmp->drecbuf[x]); + } + printk("..] %d bytes\n", hfctmp->ztdev->chans[2].bytes2receive); + } + } + } + } else { + // hmm....ok, let DAHDI receive nothing + hfctmp->ztdev->chans[2].bytes2receive = 0; + } + if (hfctmp->ztdev->span.flags & DAHDI_FLAG_RUNNING) { + dahdi_receive(&(hfctmp->ztdev->span)); + } + +#ifndef RTAITIMING + } +#endif + } + + } +#ifndef RTAITIMING + spin_unlock_irqrestore(&hfctmp->lock,flags); + return IRQ_RETVAL(1); +#endif +} + + +static int zthfc_open(struct dahdi_chan *chan) { + struct dahdi_hfc *zthfc = chan->pvt; + struct hfc_card *hfctmp = zthfc->card; + + if (!hfctmp) { + return 0; + } + try_module_get(THIS_MODULE); + return 0; +} + +static int zthfc_close(struct dahdi_chan *chan) { + struct dahdi_hfc *zthfc = chan->pvt; + struct hfc_card *hfctmp = zthfc->card; + + if (!hfctmp) { + return 0; + } + + module_put(THIS_MODULE); + return 0; +} + +static int zthfc_rbsbits(struct dahdi_chan *chan, int bits) { + return 0; +} + +static int zthfc_ioctl(struct dahdi_chan *chan, unsigned int cmd, unsigned long data) { + switch(cmd) { + default: + return -ENOTTY; + } + return 0; +} + +static int zthfc_startup(struct dahdi_span *span) { + struct dahdi_hfc *zthfc = span->pvt; + struct hfc_card *hfctmp = zthfc->card; + int alreadyrunning; + + if (hfctmp == NULL) { + printk(KERN_INFO "zaphfc: no card for span at startup!\n"); + } + alreadyrunning = span->flags & DAHDI_FLAG_RUNNING; + + if (!alreadyrunning) { + span->chans[2]->flags &= ~DAHDI_FLAG_HDLC; + span->chans[2]->flags |= DAHDI_FLAG_BRIDCHAN; + + span->flags |= DAHDI_FLAG_RUNNING; + + hfctmp->ticks = -2; + hfctmp->clicks = 0; + hfctmp->regs.fifo_en = hfc_FIFOEN_D | hfc_FIFOEN_B1 | hfc_FIFOEN_B2; + hfc_outb(hfctmp, hfc_FIFO_EN, hfctmp->regs.fifo_en); + } else { + return 0; + } + + // drivers, start engines! + hfc_outb(hfctmp, hfc_STATES, hfc_STATES_DO_ACTION | hfc_STATES_ACTIVATE); + return 0; +} + +static int zthfc_shutdown(struct dahdi_span *span) { + return 0; +} + +static int zthfc_maint(struct dahdi_span *span, int cmd) { + return 0; +} + +static int zthfc_chanconfig(struct dahdi_chan *chan, int sigtype) { +// printk(KERN_CRIT "chan_config sigtype=%d\n", sigtype); + return 0; +} + +static int zthfc_spanconfig(struct dahdi_span *span, struct dahdi_lineconfig *lc) { + span->lineconfig = lc->lineconfig; + return 0; +} + +static int zthfc_initialize(struct dahdi_hfc *zthfc) { + struct hfc_card *hfctmp = zthfc->card; + int i; + + memset(&zthfc->span, 0x0, sizeof(struct dahdi_span)); // you never can tell... + + sprintf(zthfc->span.name, "ZTHFC%d", hfc_dev_count + 1); + if (hfctmp->regs.nt_mode == 1) { +#ifdef RTAITIMING + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [NT] [realtime]", hfc_dev_count + 1); +#else + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [NT]", hfc_dev_count + 1); +#endif + } else { +#ifdef RTAITIMING + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [TE] [realtime]", hfc_dev_count + 1); +#else + sprintf(zthfc->span.desc, "HFC-S PCI A ISDN card %d [TE]", hfc_dev_count + 1); +#endif + } + + zthfc->span.spanconfig = zthfc_spanconfig; + zthfc->span.chanconfig = zthfc_chanconfig; + zthfc->span.startup = zthfc_startup; + zthfc->span.shutdown = zthfc_shutdown; + zthfc->span.maint = zthfc_maint; + zthfc->span.rbsbits = zthfc_rbsbits; + zthfc->span.open = zthfc_open; + zthfc->span.close = zthfc_close; + zthfc->span.ioctl = zthfc_ioctl; + + zthfc->span.channels = 3; + zthfc->span.chans = zthfc->_chans; + for (i = 0; i < zthfc->span.channels; i++) + zthfc->_chans[i] = &zthfc->chans[i]; + + zthfc->span.deflaw = DAHDI_LAW_ALAW; + zthfc->span.linecompat = DAHDI_CONFIG_AMI | DAHDI_CONFIG_CCS; // <--- this is really BS + zthfc->span.offset = 0; + init_waitqueue_head(&zthfc->span.maintq); + zthfc->span.pvt = zthfc; + + for (i = 0; i < zthfc->span.channels; i++) { + memset(&(zthfc->chans[i]), 0x0, sizeof(struct dahdi_chan)); + sprintf(zthfc->chans[i].name, "ZTHFC%d/%d/%d", hfc_dev_count + 1,0,i + 1); + zthfc->chans[i].pvt = zthfc; + zthfc->chans[i].sigcap = DAHDI_SIG_EM | DAHDI_SIG_CLEAR | DAHDI_SIG_FXSLS | DAHDI_SIG_FXSGS | DAHDI_SIG_FXSKS | DAHDI_SIG_FXOLS | DAHDI_SIG_FXOGS | DAHDI_SIG_FXOKS | DAHDI_SIG_CAS | DAHDI_SIG_SF; + zthfc->chans[i].chanpos = i + 1; + } + + if (dahdi_register(&zthfc->span,0)) { + printk(KERN_CRIT "unable to register DAHDI device!\n"); + return -1; + } +// printk(KERN_CRIT "zaphfc: registered DAHDI device!\n"); + return 0; +} + +#ifdef RTAITIMING +#define TICK_PERIOD 1000000 +#define TICK_PERIOD2 1000000000 +#define TASK_PRIORITY 1 +#define STACK_SIZE 10000 + +static RT_TASK rt_task; +static struct hfc_card *rtai_hfc_list[hfc_MAX_CARDS]; +static unsigned char rtai_hfc_counter = 0; + +static void rtai_register_hfc(struct hfc_card *hfctmp) { + rtai_hfc_list[rtai_hfc_counter++] = hfctmp; +} + +static void rtai_loop(int t) { + int i=0; + for (;;) { + for (i=0; i < rtai_hfc_counter; i++) { + if (rtai_hfc_list[i] != NULL) + hfc_service(rtai_hfc_list[i]); + } + rt_task_wait_period(); + } +} +#endif + +int hfc_findCards(int pcivendor, int pcidevice, char *vendor_name, char *card_name) { + struct pci_dev *tmp; + struct hfc_card *hfctmp = NULL; + struct dahdi_hfc *zthfc = NULL; + + tmp = pci_get_device(pcivendor, pcidevice, multi_hfc); + while (tmp != NULL) { + multi_hfc = tmp; // skip this next time. + + if (pci_enable_device(tmp)) { + multi_hfc = NULL; + return -1; + } + pci_set_master(tmp); + + hfctmp = kmalloc(sizeof(struct hfc_card), GFP_KERNEL); + if (!hfctmp) { + printk(KERN_WARNING "zaphfc: unable to kmalloc!\n"); + pci_disable_device(tmp); + multi_hfc = NULL; + return -ENOMEM; + } + memset(hfctmp, 0x0, sizeof(struct hfc_card)); + spin_lock_init(&hfctmp->lock); + + hfctmp->pcidev = tmp; + hfctmp->pcibus = tmp->bus->number; + hfctmp->pcidevfn = tmp->devfn; + + if (!tmp->irq) { + printk(KERN_WARNING "zaphfc: no irq!\n"); + } else { + hfctmp->irq = tmp->irq; + } + + hfctmp->pci_io = (char *) tmp->resource[1].start; + if (!hfctmp->pci_io) { + printk(KERN_WARNING "zaphfc: no iomem!\n"); + kfree(hfctmp); + pci_disable_device(tmp); + multi_hfc = NULL; + return -1; + } + + hfctmp->fifomem = kmalloc(65536, GFP_KERNEL); + if (!hfctmp->fifomem) { + printk(KERN_WARNING "zaphfc: unable to kmalloc fifomem!\n"); + kfree(hfctmp); + pci_disable_device(tmp); + multi_hfc = NULL; + return -ENOMEM; + } else { + memset(hfctmp->fifomem, 0x0, 65536); + hfctmp->fifos = (void *)(((ulong) hfctmp->fifomem) & ~0x7FFF) + 0x8000; + pci_write_config_dword(hfctmp->pcidev, 0x80, (u_int) virt_to_bus(hfctmp->fifos)); + hfctmp->pci_io = ioremap((ulong) hfctmp->pci_io, 256); + } + +#ifdef RTAITIMING + /* we need no stinking irq */ + hfctmp->irq = 0; +#else + if (request_irq(hfctmp->irq, &hfc_interrupt, DAHDI_IRQ_SHARED, "zaphfc", hfctmp)) { + printk(KERN_WARNING "zaphfc: unable to register irq\n"); + kfree(hfctmp->fifomem); + kfree(hfctmp); + iounmap((void *) hfctmp->pci_io); + pci_disable_device(tmp); + multi_hfc = NULL; + return -EIO; + } +#endif + +#ifdef RTAITIMING + rtai_register_hfc(hfctmp); +#endif + printk(KERN_INFO + "zaphfc: %s %s configured at mem %lx fifo %lx(%#x) IRQ %d HZ %d\n", + vendor_name, card_name, + (unsigned long) hfctmp->pci_io, + (unsigned long) hfctmp->fifos, + (u_int) virt_to_bus(hfctmp->fifos), + hfctmp->irq, HZ); + pci_write_config_word(hfctmp->pcidev, PCI_COMMAND, PCI_COMMAND_MEMORY); // enable memio + hfctmp->regs.int_m1 = 0; // no ints + hfctmp->regs.int_m2 = 0; // not at all + hfc_outb(hfctmp,hfc_INT_M1,hfctmp->regs.int_m1); + hfc_outb(hfctmp,hfc_INT_M2,hfctmp->regs.int_m2); + + if ((modes & (1 << hfc_dev_count)) != 0) { + printk(KERN_INFO "zaphfc: Card %d configured for NT mode\n",hfc_dev_count); + hfctmp->regs.nt_mode = 1; + } else { + printk(KERN_INFO "zaphfc: Card %d configured for TE mode\n",hfc_dev_count); + hfctmp->regs.nt_mode = 0; + } + + zthfc = kmalloc(sizeof(struct dahdi_hfc),GFP_KERNEL); + if (!zthfc) { + printk(KERN_CRIT "zaphfc: unable to kmalloc!\n"); + hfc_shutdownCard(hfctmp); + kfree(hfctmp); + multi_hfc = NULL; + return -ENOMEM; + } + memset(zthfc, 0x0, sizeof(struct dahdi_hfc)); + + zthfc->card = hfctmp; + zthfc_initialize(zthfc); + hfctmp->ztdev = zthfc; + + memset(hfctmp->drecbuf, 0x0, sizeof(hfctmp->drecbuf)); + hfctmp->ztdev->chans[2].readchunk = hfctmp->drecbuf; + + memset(hfctmp->dtransbuf, 0x0, sizeof(hfctmp->dtransbuf)); + hfctmp->ztdev->chans[2].writechunk = hfctmp->dtransbuf; + + memset(hfctmp->brecbuf[0], 0x0, sizeof(hfctmp->brecbuf[0])); + hfctmp->ztdev->chans[0].readchunk = hfctmp->brecbuf[0]; + memset(hfctmp->btransbuf[0], 0x0, sizeof(hfctmp->btransbuf[0])); + hfctmp->ztdev->chans[0].writechunk = hfctmp->btransbuf[0]; + + memset(hfctmp->brecbuf[1], 0x0, sizeof(hfctmp->brecbuf[1])); + hfctmp->ztdev->chans[1].readchunk = hfctmp->brecbuf[1]; + memset(hfctmp->btransbuf[1], 0x0, sizeof(hfctmp->btransbuf[1])); + hfctmp->ztdev->chans[1].writechunk = hfctmp->btransbuf[1]; + + + hfc_registerCard(hfctmp); + hfc_resetCard(hfctmp); + tmp = pci_get_device(pcivendor, pcidevice, multi_hfc); + } + return 0; +} + + + +int init_module(void) { + int i = 0; +#ifdef RTAITIMING + RTIME tick_period; + for (i=0; i < hfc_MAX_CARDS; i++) { + rtai_hfc_list[i] = NULL; + } + rt_set_periodic_mode(); +#endif + i = 0; + while (id_list[i].vendor_id) { + multi_hfc = NULL; + hfc_findCards(id_list[i].vendor_id, id_list[i].device_id, id_list[i].vendor_name, id_list[i].card_name); + i++; + } +#ifdef RTAITIMING + for (i=0; i < hfc_MAX_CARDS; i++) { + if (rtai_hfc_list[i]) { + printk(KERN_INFO + "zaphfc: configured %d at mem %#x fifo %#x(%#x) for realtime servicing\n", + rtai_hfc_list[i]->cardno, + (u_int) rtai_hfc_list[i]->pci_io, + (u_int) rtai_hfc_list[i]->fifos, + (u_int) virt_to_bus(rtai_hfc_list[i]->fifos)); + + } + } + rt_task_init(&rt_task, rtai_loop, 1, STACK_SIZE, TASK_PRIORITY, 0, 0); + tick_period = start_rt_timer(nano2count(TICK_PERIOD)); + rt_task_make_periodic(&rt_task, rt_get_time() + tick_period, tick_period); +#endif + printk(KERN_INFO "zaphfc: %d hfc-pci card(s) in this box.\n", hfc_dev_count); + return 0; +} + +void cleanup_module(void) { + struct hfc_card *tmpcard; +#ifdef RTAITIMING + stop_rt_timer(); + rt_task_delete(&rt_task); +#endif + printk(KERN_INFO "zaphfc: stop\n"); +// spin_lock(®isterlock); + while (hfc_dev_list != NULL) { + if (hfc_dev_list == NULL) break; + hfc_shutdownCard(hfc_dev_list); + tmpcard = hfc_dev_list; + hfc_dev_list = hfc_dev_list->next; + if (tmpcard != NULL) { + kfree(tmpcard); + tmpcard = NULL; + printk(KERN_INFO "zaphfc: freed one card.\n"); + } + } +// spin_unlock(®isterlock); +} +#endif + + +module_param(modes, int, 0600); +module_param(debug, int, 0600); + +MODULE_DESCRIPTION("HFC-S PCI A Zaptel Driver"); +MODULE_AUTHOR("Klaus-Peter Junghanns "); +#ifdef MODULE_LICENSE +MODULE_LICENSE("GPL"); +#endif Index: dahdi-linux-2.1.0/drivers/dahdi/zaphfc.h =================================================================== --- /dev/null 1970-01-01 00:00:00.000000000 +0000 +++ dahdi-linux-2.1.0/drivers/dahdi/zaphfc.h 2008-12-10 12:46:14.000000000 +0200 @@ -0,0 +1,290 @@ +/* + * zaphfc.h - Zaptel driver for HFC-S PCI A based ISDN BRI cards + * + * kernel module based on HFC PCI ISDN4Linux and Zaptel drivers + * + * Copyright (C) 2002, 2003, 2004, 2005 Junghanns.NET GmbH + * + * Klaus-Peter Junghanns + * + * This program is free software and may be modified and + * distributed under the terms of the GNU Public License. + * + */ + +/* HFC register addresses - accessed using memory mapped I/O */ +/* For a list, see datasheet section 3.2.1 at page 21 */ + +#define hfc_outb(a,b,c) (writeb((c),(a)->pci_io+(b))) +#define hfc_inb(a,b) (readb((a)->pci_io+(b))) + +/* GCI/IOM bus monitor registers */ + +#define hfc_C_I 0x08 +#define hfc_TRxR 0x0C +#define hfc_MON1_D 0x28 +#define hfc_MON2_D 0x2C + + +/* GCI/IOM bus timeslot registers */ + +#define hfc_B1_SSL 0x80 +#define hfc_B2_SSL 0x84 +#define hfc_AUX1_SSL 0x88 +#define hfc_AUX2_SSL 0x8C +#define hfc_B1_RSL 0x90 +#define hfc_B2_RSL 0x94 +#define hfc_AUX1_RSL 0x98 +#define hfc_AUX2_RSL 0x9C + +/* GCI/IOM bus data registers */ + +#define hfc_B1_D 0xA0 +#define hfc_B2_D 0xA4 +#define hfc_AUX1_D 0xA8 +#define hfc_AUX2_D 0xAC + +/* GCI/IOM bus configuration registers */ + +#define hfc_MST_EMOD 0xB4 +#define hfc_MST_MODE 0xB8 +#define hfc_CONNECT 0xBC + + +/* Interrupt and status registers */ + +#define hfc_FIFO_EN 0x44 +#define hfc_TRM 0x48 +#define hfc_B_MODE 0x4C +#define hfc_CHIP_ID 0x58 +#define hfc_CIRM 0x60 +#define hfc_CTMT 0x64 +#define hfc_INT_M1 0x68 +#define hfc_INT_M2 0x6C +#define hfc_INT_S1 0x78 +#define hfc_INT_S2 0x7C +#define hfc_STATUS 0x70 + +/* S/T section registers */ + +#define hfc_STATES 0xC0 +#define hfc_SCTRL 0xC4 +#define hfc_SCTRL_E 0xC8 +#define hfc_SCTRL_R 0xCC +#define hfc_SQ 0xD0 +#define hfc_CLKDEL 0xDC +#define hfc_B1_REC 0xF0 +#define hfc_B1_SEND 0xF0 +#define hfc_B2_REC 0xF4 +#define hfc_B2_SEND 0xF4 +#define hfc_D_REC 0xF8 +#define hfc_D_SEND 0xF8 +#define hfc_E_REC 0xFC + +/* Bits and values in various HFC PCI registers */ + +/* bits in status register (READ) */ +#define hfc_STATUS_PCI_PROC 0x02 +#define hfc_STATUS_NBUSY 0x04 +#define hfc_STATUS_TIMER_ELAP 0x10 +#define hfc_STATUS_STATINT 0x20 +#define hfc_STATUS_FRAMEINT 0x40 +#define hfc_STATUS_ANYINT 0x80 + +/* bits in CTMT (Write) */ +#define hfc_CTMT_CLTIMER 0x80 +#define hfc_CTMT_TIM3_125 0x04 +#define hfc_CTMT_TIM25 0x10 +#define hfc_CTMT_TIM50 0x14 +#define hfc_CTMT_TIM400 0x18 +#define hfc_CTMT_TIM800 0x1C +#define hfc_CTMT_AUTO_TIMER 0x20 +#define hfc_CTMT_TRANSB2 0x02 +#define hfc_CTMT_TRANSB1 0x01 + +/* bits in CIRM (Write) */ +#define hfc_CIRM_AUX_MSK 0x07 +#define hfc_CIRM_RESET 0x08 +#define hfc_CIRM_B1_REV 0x40 +#define hfc_CIRM_B2_REV 0x80 + +/* bits in INT_M1 and INT_S1 */ +#define hfc_INTS_B1TRANS 0x01 +#define hfc_INTS_B2TRANS 0x02 +#define hfc_INTS_DTRANS 0x04 +#define hfc_INTS_B1REC 0x08 +#define hfc_INTS_B2REC 0x10 +#define hfc_INTS_DREC 0x20 +#define hfc_INTS_L1STATE 0x40 +#define hfc_INTS_TIMER 0x80 + +/* bits in INT_M2 */ +#define hfc_M2_PROC_TRANS 0x01 +#define hfc_M2_GCI_I_CHG 0x02 +#define hfc_M2_GCI_MON_REC 0x04 +#define hfc_M2_IRQ_ENABLE 0x08 +#define hfc_M2_PMESEL 0x80 + +/* bits in STATES */ +#define hfc_STATES_STATE_MASK 0x0F +#define hfc_STATES_LOAD_STATE 0x10 +#define hfc_STATES_ACTIVATE 0x20 +#define hfc_STATES_DO_ACTION 0x40 +#define hfc_STATES_NT_G2_G3 0x80 + +/* bits in HFCD_MST_MODE */ +#define hfc_MST_MODE_MASTER 0x01 +#define hfc_MST_MODE_SLAVE 0x00 +/* remaining bits are for codecs control */ + +/* bits in HFCD_SCTRL */ +#define hfc_SCTRL_B1_ENA 0x01 +#define hfc_SCTRL_B2_ENA 0x02 +#define hfc_SCTRL_MODE_TE 0x00 +#define hfc_SCTRL_MODE_NT 0x04 +#define hfc_SCTRL_LOW_PRIO 0x08 +#define hfc_SCTRL_SQ_ENA 0x10 +#define hfc_SCTRL_TEST 0x20 +#define hfc_SCTRL_NONE_CAP 0x40 +#define hfc_SCTRL_PWR_DOWN 0x80 + +/* bits in SCTRL_E */ +#define hfc_SCTRL_E_AUTO_AWAKE 0x01 +#define hfc_SCTRL_E_DBIT_1 0x04 +#define hfc_SCTRL_E_IGNORE_COL 0x08 +#define hfc_SCTRL_E_CHG_B1_B2 0x80 + +/* bits in FIFO_EN register */ +#define hfc_FIFOEN_B1TX 0x01 +#define hfc_FIFOEN_B1RX 0x02 +#define hfc_FIFOEN_B2TX 0x04 +#define hfc_FIFOEN_B2RX 0x08 +#define hfc_FIFOEN_DTX 0x10 +#define hfc_FIFOEN_DRX 0x20 + +#define hfc_FIFOEN_B1 (hfc_FIFOEN_B1TX|hfc_FIFOEN_B1RX) +#define hfc_FIFOEN_B2 (hfc_FIFOEN_B2TX|hfc_FIFOEN_B2RX) +#define hfc_FIFOEN_D (hfc_FIFOEN_DTX|hfc_FIFOEN_DRX) + +/* bits in the CONNECT register */ +#define hfc_CONNECT_B1_shift 0 +#define hfc_CONNECT_B2_shift 3 + +#define hfc_CONNECT_HFC_from_ST 0x0 +#define hfc_CONNECT_HFC_from_GCI 0x1 +#define hfc_CONNECT_ST_from_HFC 0x0 +#define hfc_CONNECT_ST_from_GCI 0x2 +#define hfc_CONNECT_GCI_from_HFC 0x0 +#define hfc_CONNECT_GCI_from_ST 0x4 + +/* bits in the __SSL and __RSL registers */ +#define hfc_SRSL_STIO 0x40 +#define hfc_SRSL_ENABLE 0x80 +#define hfc_SRCL_SLOT_MASK 0x1f + +/* FIFO memory definitions */ + +#define hfc_FMASK 0x000f +#define hfc_ZMASK 0x01ff +#define hfc_ZMASKB 0x1fff + +#define hfc_D_FIFO_SIZE 0x0200 +#define hfc_B_SUB_VAL 0x0200 +#define hfc_B_FIFO_SIZE 0x1E00 +#define hfc_MAX_DFRAMES 0x000f + +#define hfc_FIFO_DTX_Z1 0x2080 +#define hfc_FIFO_DTX_Z2 0x2082 +#define hfc_FIFO_DTX_F1 0x20a0 +#define hfc_FIFO_DTX_F2 0x20a1 +#define hfc_FIFO_DTX 0x0000 +#define hfc_FIFO_DTX_ZOFF 0x000 + +#define hfc_FIFO_DRX_Z1 0x6080 +#define hfc_FIFO_DRX_Z2 0x6082 +#define hfc_FIFO_DRX_F1 0x60a0 +#define hfc_FIFO_DRX_F2 0x60a1 +#define hfc_FIFO_DRX 0x4000 +#define hfc_FIFO_DRX_ZOFF 0x4000 + +#define hfc_FIFO_B1TX_Z1 0x2000 +#define hfc_FIFO_B1TX_Z2 0x2002 +#define hfc_FIFO_B1RX_Z1 0x6000 +#define hfc_FIFO_B1RX_Z2 0x6002 + +#define hfc_FIFO_B1TX_F1 0x2080 +#define hfc_FIFO_B1TX_F2 0x2081 +#define hfc_FIFO_B1RX_F1 0x6080 +#define hfc_FIFO_B1RX_F2 0x6081 + +#define hfc_FIFO_B1RX_ZOFF 0x4000 +#define hfc_FIFO_B1TX_ZOFF 0x0000 + +#define hfc_FIFO_B2TX_Z1 0x2100 +#define hfc_FIFO_B2TX_Z2 0x2102 +#define hfc_FIFO_B2RX_Z1 0x6100 +#define hfc_FIFO_B2RX_Z2 0x6102 + +#define hfc_FIFO_B2TX_F1 0x2180 +#define hfc_FIFO_B2TX_F2 0x2181 +#define hfc_FIFO_B2RX_F1 0x6180 +#define hfc_FIFO_B2RX_F2 0x6181 + +#define hfc_FIFO_B2RX_ZOFF 0x6000 +#define hfc_FIFO_B2TX_ZOFF 0x2000 + +#define hfc_BTRANS_THRESHOLD 128 +#define hfc_BTRANS_THRESMASK 0x00 + +/* Structures */ + +typedef struct hfc_regs { + unsigned char fifo_en; + unsigned char ctmt; + unsigned char int_m1; + unsigned char int_m2; + unsigned char sctrl; + unsigned char sctrl_e; + unsigned char sctrl_r; + unsigned char connect; + unsigned char trm; + unsigned char mst_mode; + unsigned char bswapped; + unsigned char nt_mode; + unsigned char int_drec; +} hfc_regs; + +typedef struct hfc_card { + spinlock_t lock; + unsigned int irq; + unsigned int iomem; + int ticks; + int clicks; + unsigned char *pci_io; + void *fifomem; // start of the shared mem + volatile void *fifos; // 32k aligned mem for the fifos + struct hfc_regs regs; + unsigned int pcibus; + unsigned int pcidevfn; + struct pci_dev *pcidev; + struct dahdi_hfc *ztdev; + int drecinframe; + unsigned char drecbuf[hfc_D_FIFO_SIZE]; + unsigned char dtransbuf[hfc_D_FIFO_SIZE]; + unsigned char brecbuf[2][DAHDI_CHUNKSIZE]; + unsigned char btransbuf[2][DAHDI_CHUNKSIZE]; + unsigned char cardno; + struct hfc_card *next; +} hfc_card; + +typedef struct dahdi_hfc { + unsigned int usecount; + struct dahdi_span span; + struct dahdi_chan chans[3]; + struct dahdi_chan *_chans[3]; + struct hfc_card *card; +} dahdi_hfc; + +/* tune this */ +#define hfc_BCHAN_BUFFER 8 +#define hfc_MAX_CARDS 8