// SPDX-License-Identifier: GPL-2.0-or-later /* * hfcmulti.c low level driver for hfc-4s/hfc-8s/hfc-e1 based cards * * Author Andreas Eversberg (jolly@eversberg.eu) * ported to mqueue mechanism: * Peter Sprenger (sprengermoving-bytes.de) * * inspired by existing hfc-pci driver: * Copyright 1999 by Werner Cornelius (werner@isdn-development.de) * Copyright 2008 by Karsten Keil (kkeil@suse.de) * Copyright 2008 by Andreas Eversberg (jolly@eversberg.eu) * * Thanks to Cologne Chip AG for this great controller! */ /* * module parameters: * type: * By default (0), the card is automatically detected. * Or use the following combinations: * Bit 0-7 = 0x00001 = HFC-E1 (1 port) * or Bit 0-7 = 0x00004 = HFC-4S (4 ports) * or Bit 0-7 = 0x00008 = HFC-8S (8 ports) * Bit 8 = 0x00100 = uLaw (instead of aLaw) * Bit 9 = 0x00200 = Disable DTMF detect on all B-channels via hardware * Bit 10 = spare * Bit 11 = 0x00800 = Force PCM bus into slave mode. (otherwhise auto) * or Bit 12 = 0x01000 = Force PCM bus into master mode. (otherwhise auto) * Bit 13 = spare * Bit 14 = 0x04000 = Use external ram (128K) * Bit 15 = 0x08000 = Use external ram (512K) * Bit 16 = 0x10000 = Use 64 timeslots instead of 32 * or Bit 17 = 0x20000 = Use 128 timeslots instead of anything else * Bit 18 = spare * Bit 19 = 0x80000 = Send the Watchdog a Signal (Dual E1 with Watchdog) * (all other bits are reserved and shall be 0) * example: 0x20204 one HFC-4S with dtmf detection and 128 timeslots on PCM * bus (PCM master) * * port: (optional or required for all ports on all installed cards) * HFC-4S/HFC-8S only bits: * Bit 0 = 0x001 = Use master clock for this S/T interface * (ony once per chip). * Bit 1 = 0x002 = transmitter line setup (non capacitive mode) * Don't use this unless you know what you are doing! * Bit 2 = 0x004 = Disable E-channel. (No E-channel processing) * example: 0x0001,0x0000,0x0000,0x0000 one HFC-4S with master clock * received from port 1 * * HFC-E1 only bits: * Bit 0 = 0x0001 = interface: 0=copper, 1=optical * Bit 1 = 0x0002 = reserved (later for 32 B-channels transparent mode) * Bit 2 = 0x0004 = Report LOS * Bit 3 = 0x0008 = Report AIS * Bit 4 = 0x0010 = Report SLIP * Bit 5 = 0x0020 = Report RDI * Bit 8 = 0x0100 = Turn off CRC-4 Multiframe Mode, use double frame * mode instead. * Bit 9 = 0x0200 = Force get clock from interface, even in NT mode. * or Bit 10 = 0x0400 = Force put clock to interface, even in TE mode. * Bit 11 = 0x0800 = Use direct RX clock for PCM sync rather than PLL. * (E1 only) * Bit 12-13 = 0xX000 = elastic jitter buffer (1-3), Set both bits to 0 * for default. * (all other bits are reserved and shall be 0) * * debug: * NOTE: only one debug value must be given for all cards * enable debugging (see hfc_multi.h for debug options) * * poll: * NOTE: only one poll value must be given for all cards * Give the number of samples for each fifo process. * By default 128 is used. Decrease to reduce delay, increase to * reduce cpu load. If unsure, don't mess with it! * Valid is 8, 16, 32, 64, 128, 256. * * pcm: * NOTE: only one pcm value must be given for every card. * The PCM bus id tells the mISDNdsp module about the connected PCM bus. * By default (0), the PCM bus id is 100 for the card that is PCM master. * If multiple cards are PCM master (because they are not interconnected), * each card with PCM master will have increasing PCM id. * All PCM busses with the same ID are expected to be connected and have * common time slots slots. * Only one chip of the PCM bus must be master, the others slave. * -1 means no support of PCM bus not even. * Omit this value, if all cards are interconnected or none is connected. * If unsure, don't give this parameter. * * dmask and bmask: * NOTE: One dmask value must be given for every HFC-E1 card. * If omitted, the E1 card has D-channel on time slot 16, which is default. * dmask is a 32 bit mask. The bit must be set for an alternate time slot. * If multiple bits are set, multiple virtual card fragments are created. * For each bit set, a bmask value must be given. Each bit on the bmask * value stands for a B-channel. The bmask may not overlap with dmask or * with other bmask values for that card. * Example: dmask=0x00020002 bmask=0x0000fffc,0xfffc0000 * This will create one fragment with D-channel on slot 1 with * B-channels on slots 2..15, and a second fragment with D-channel * on slot 17 with B-channels on slot 18..31. Slot 16 is unused. * If bit 0 is set (dmask=0x00000001) the D-channel is on slot 0 and will * not function. * Example: dmask=0x00000001 bmask=0xfffffffe * This will create a port with all 31 usable timeslots as * B-channels. * If no bits are set on bmask, no B-channel is created for that fragment. * Example: dmask=0xfffffffe bmask=0,0,0,0.... (31 0-values for bmask) * This will create 31 ports with one D-channel only. * If you don't know how to use it, you don't need it! * * iomode: * NOTE: only one mode value must be given for every card. * -> See hfc_multi.h for HFC_IO_MODE_* values * By default, the IO mode is pci memory IO (MEMIO). * Some cards require specific IO mode, so it cannot be changed. * It may be useful to set IO mode to register io (REGIO) to solve * PCI bridge problems. * If unsure, don't give this parameter. * * clockdelay_nt: * NOTE: only one clockdelay_nt value must be given once for all cards. * Give the value of the clock control register (A_ST_CLK_DLY) * of the S/T interfaces in NT mode. * This register is needed for the TBR3 certification, so don't change it. * * clockdelay_te: * NOTE: only one clockdelay_te value must be given once * Give the value of the clock control register (A_ST_CLK_DLY) * of the S/T interfaces in TE mode. * This register is needed for the TBR3 certification, so don't change it. * * clock: * NOTE: only one clock value must be given once * Selects interface with clock source for mISDN and applications. * Set to card number starting with 1. Set to -1 to disable. * By default, the first card is used as clock source. * * hwid: * NOTE: only one hwid value must be given once * Enable special embedded devices with XHFC controllers. */ /* * debug register access (never use this, it will flood your system log) * #define HFC_REGISTER_DEBUG */ #define HFC_MULTI_VERSION "2.03" #include #include #include #include #include #include #include /* #define IRQCOUNT_DEBUG #define IRQ_DEBUG */ #include "hfc_multi.h" #ifdef ECHOPREP #include "gaintab.h" #endif #define MAX_CARDS 8 #define MAX_PORTS (8 * MAX_CARDS) #define MAX_FRAGS (32 * MAX_CARDS) static LIST_HEAD(HFClist); static spinlock_t HFClock; /* global hfc list lock */ static void ph_state_change(struct dchannel *); static struct hfc_multi *syncmaster; static int plxsd_master; /* if we have a master card (yet) */ static spinlock_t plx_lock; /* may not acquire other lock inside */ #define TYP_E1 1 #define TYP_4S 4 #define TYP_8S 8 static int poll_timer = 6; /* default = 128 samples = 16ms */ /* number of POLL_TIMER interrupts for G2 timeout (ca 1s) */ static int nt_t1_count[] = { 3840, 1920, 960, 480, 240, 120, 60, 30 }; #define CLKDEL_TE 0x0f /* CLKDEL in TE mode */ #define CLKDEL_NT 0x6c /* CLKDEL in NT mode (0x60 MUST be included!) */ #define DIP_4S 0x1 /* DIP Switches for Beronet 1S/2S/4S cards */ #define DIP_8S 0x2 /* DIP Switches for Beronet 8S+ cards */ #define DIP_E1 0x3 /* DIP Switches for Beronet E1 cards */ /* * module stuff */ static uint type[MAX_CARDS]; static int pcm[MAX_CARDS]; static uint dmask[MAX_CARDS]; static uint bmask[MAX_FRAGS]; static uint iomode[MAX_CARDS]; static uint port[MAX_PORTS]; static uint debug; static uint poll; static int clock; static uint timer; static uint clockdelay_te = CLKDEL_TE; static uint clockdelay_nt = CLKDEL_NT; #define HWID_NONE 0 #define HWID_MINIP4 1 #define HWID_MINIP8 2 #define HWID_MINIP16 3 static uint hwid = HWID_NONE; static int HFC_cnt, E1_cnt, bmask_cnt, Port_cnt, PCM_cnt = 99; MODULE_AUTHOR("Andreas Eversberg"); MODULE_LICENSE("GPL"); MODULE_VERSION(HFC_MULTI_VERSION); module_param(debug, uint, S_IRUGO | S_IWUSR); module_param(poll, uint, S_IRUGO | S_IWUSR); module_param(clock, int, S_IRUGO | S_IWUSR); module_param(timer, uint, S_IRUGO | S_IWUSR); module_param(clockdelay_te, uint, S_IRUGO | S_IWUSR); module_param(clockdelay_nt, uint, S_IRUGO | S_IWUSR); module_param_array(type, uint, NULL, S_IRUGO | S_IWUSR); module_param_array(pcm, int, NULL, S_IRUGO | S_IWUSR); module_param_array(dmask, uint, NULL, S_IRUGO | S_IWUSR); module_param_array(bmask, uint, NULL, S_IRUGO | S_IWUSR); module_param_array(iomode, uint, NULL, S_IRUGO | S_IWUSR); module_param_array(port, uint, NULL, S_IRUGO | S_IWUSR); module_param(hwid, uint, S_IRUGO | S_IWUSR); /* The hardware ID */ #ifdef HFC_REGISTER_DEBUG #define HFC_outb(hc, reg, val) \ (hc->HFC_outb(hc, reg, val, __func__, __LINE__)) #define HFC_outb_nodebug(hc, reg, val) \ (hc->HFC_outb_nodebug(hc, reg, val, __func__, __LINE__)) #define HFC_inb(hc, reg) \ (hc->HFC_inb(hc, reg, __func__, __LINE__)) #define HFC_inb_nodebug(hc, reg) \ (hc->HFC_inb_nodebug(hc, reg, __func__, __LINE__)) #define HFC_inw(hc, reg) \ (hc->HFC_inw(hc, reg, __func__, __LINE__)) #define HFC_inw_nodebug(hc, reg) \ (hc->HFC_inw_nodebug(hc, reg, __func__, __LINE__)) #define HFC_wait(hc) \ (hc->HFC_wait(hc, __func__, __LINE__)) #define HFC_wait_nodebug(hc) \ (hc->HFC_wait_nodebug(hc, __func__, __LINE__)) #else #define HFC_outb(hc, reg, val) (hc->HFC_outb(hc, reg, val)) #define HFC_outb_nodebug(hc, reg, val) (hc->HFC_outb_nodebug(hc, reg, val)) #define HFC_inb(hc, reg) (hc->HFC_inb(hc, reg)) #define HFC_inb_nodebug(hc, reg) (hc->HFC_inb_nodebug(hc, reg)) #define HFC_inw(hc, reg) (hc->HFC_inw(hc, reg)) #define HFC_inw_nodebug(hc, reg) (hc->HFC_inw_nodebug(hc, reg)) #define HFC_wait(hc) (hc->HFC_wait(hc)) #define HFC_wait_nodebug(hc) (hc->HFC_wait_nodebug(hc)) #endif #ifdef CONFIG_MISDN_HFCMULTI_8xx #include "hfc_multi_8xx.h" #endif /* HFC_IO_MODE_PCIMEM */ static void #ifdef HFC_REGISTER_DEBUG HFC_outb_pcimem(struct hfc_multi *hc, u_char reg, u_char val, const char *function, int line) #else HFC_outb_pcimem(struct hfc_multi *hc, u_char reg, u_char val) #endif { writeb(val, hc->pci_membase + reg); } static u_char #ifdef HFC_REGISTER_DEBUG HFC_inb_pcimem(struct hfc_multi *hc, u_char reg, const char *function, int line) #else HFC_inb_pcimem(struct hfc_multi *hc, u_char reg) #endif { return readb(hc->pci_membase + reg); } static u_short #ifdef HFC_REGISTER_DEBUG HFC_inw_pcimem(struct hfc_multi *hc, u_char reg, const char *function, int line) #else HFC_inw_pcimem(struct hfc_multi *hc, u_char reg) #endif { return readw(hc->pci_membase + reg); } static void #ifdef HFC_REGISTER_DEBUG HFC_wait_pcimem(struct hfc_multi *hc, const char *function, int line) #else HFC_wait_pcimem(struct hfc_multi *hc) #endif { while (readb(hc->pci_membase + R_STATUS) & V_BUSY) cpu_relax(); } /* HFC_IO_MODE_REGIO */ static void #ifdef HFC_REGISTER_DEBUG HFC_outb_regio(struct hfc_multi *hc, u_char reg, u_char val, const char *function, int line) #else HFC_outb_regio(struct hfc_multi *hc, u_char reg, u_char val) #endif { outb(reg, hc->pci_iobase + 4); outb(val, hc->pci_iobase); } static u_char #ifdef HFC_REGISTER_DEBUG HFC_inb_regio(struct hfc_multi *hc, u_char reg, const char *function, int line) #else HFC_inb_regio(struct hfc_multi *hc, u_char reg) #endif { outb(reg, hc->pci_iobase + 4); return inb(hc->pci_iobase); } static u_short #ifdef HFC_REGISTER_DEBUG HFC_inw_regio(struct hfc_multi *hc, u_char reg, const char *function, int line) #else HFC_inw_regio(struct hfc_multi *hc, u_char reg) #endif { outb(reg, hc->pci_iobase + 4); return inw(hc->pci_iobase); } static void #ifdef HFC_REGISTER_DEBUG HFC_wait_regio(struct hfc_multi *hc, const char *function, int line) #else HFC_wait_regio(struct hfc_multi *hc) #endif { outb(R_STATUS, hc->pci_iobase + 4); while (inb(hc->pci_iobase) & V_BUSY) cpu_relax(); } #ifdef HFC_REGISTER_DEBUG static void HFC_outb_debug(struct hfc_multi *hc, u_char reg, u_char val, const char *function, int line) { char regname[256] = "", bits[9] = "xxxxxxxx"; int i; i = -1; while (hfc_register_names[++i].name) { if (hfc_register_names[i].reg == reg) strcat(regname, hfc_register_names[i].name); } if (regname[0] == '\0') strcpy(regname, "register"); bits[7] = '0' + (!!(val & 1)); bits[6] = '0' + (!!(val & 2)); bits[5] = '0' + (!!(val & 4)); bits[4] = '0' + (!!(val & 8)); bits[3] = '0' + (!!(val & 16)); bits[2] = '0' + (!!(val & 32)); bits[1] = '0' + (!!(val & 64)); bits[0] = '0' + (!!(val & 128)); printk(KERN_DEBUG "HFC_outb(chip %d, %02x=%s, 0x%02x=%s); in %s() line %d\n", hc->id, reg, regname, val, bits, function, line); HFC_outb_nodebug(hc, reg, val); } static u_char HFC_inb_debug(struct hfc_multi *hc, u_char reg, const char *function, int line) { char regname[256] = "", bits[9] = "xxxxxxxx"; u_char val = HFC_inb_nodebug(hc, reg); int i; i = 0; while (hfc_register_names[i++].name) ; while (hfc_register_names[++i].name) { if (hfc_register_names[i].reg == reg) strcat(regname, hfc_register_names[i].name); } if (regname[0] == '\0') strcpy(regname, "register"); bits[7] = '0' + (!!(val & 1)); bits[6] = '0' + (!!(val & 2)); bits[5] = '0' + (!!(val & 4)); bits[4] = '0' + (!!(val & 8)); bits[3] = '0' + (!!(val & 16)); bits[2] = '0' + (!!(val & 32)); bits[1] = '0' + (!!(val & 64)); bits[0] = '0' + (!!(val & 128)); printk(KERN_DEBUG "HFC_inb(chip %d, %02x=%s) = 0x%02x=%s; in %s() line %d\n", hc->id, reg, regname, val, bits, function, line); return val; } static u_short HFC_inw_debug(struct hfc_multi *hc, u_char reg, const char *function, int line) { char regname[256] = ""; u_short val = HFC_inw_nodebug(hc, reg); int i; i = 0; while (hfc_register_names[i++].name) ; while (hfc_register_names[++i].name) { if (hfc_register_names[i].reg == reg) strcat(regname, hfc_register_names[i].name); } if (regname[0] == '\0') strcpy(regname, "register"); printk(KERN_DEBUG "HFC_inw(chip %d, %02x=%s) = 0x%04x; in %s() line %d\n", hc->id, reg, regname, val, function, line); return val; } static void HFC_wait_debug(struct hfc_multi *hc, const char *function, int line) { printk(KERN_DEBUG "HFC_wait(chip %d); in %s() line %d\n", hc->id, function, line); HFC_wait_nodebug(hc); } #endif /* write fifo data (REGIO) */ static void write_fifo_regio(struct hfc_multi *hc, u_char *data, int len) { outb(A_FIFO_DATA0, (hc->pci_iobase) + 4); while (len >> 2) { outl(cpu_to_le32(*(u32 *)data), hc->pci_iobase); data += 4; len -= 4; } while (len >> 1) { outw(cpu_to_le16(*(u16 *)data), hc->pci_iobase); data += 2; len -= 2; } while (len) { outb(*data, hc->pci_iobase); data++; len--; } } /* write fifo data (PCIMEM) */ static void write_fifo_pcimem(struct hfc_multi *hc, u_char *data, int len) { while (len >> 2) { writel(cpu_to_le32(*(u32 *)data), hc->pci_membase + A_FIFO_DATA0); data += 4; len -= 4; } while (len >> 1) { writew(cpu_to_le16(*(u16 *)data), hc->pci_membase + A_FIFO_DATA0); data += 2; len -= 2; } while (len) { writeb(*data, hc->pci_membase + A_FIFO_DATA0); data++; len--; } } /* read fifo data (REGIO) */ static void read_fifo_regio(struct hfc_multi *hc, u_char *data, int len) { outb(A_FIFO_DATA0, (hc->pci_iobase) + 4); while (len >> 2) { *(u32 *)data = le32_to_cpu(inl(hc->pci_iobase)); data += 4; len -= 4; } while (len >> 1) { *(u16 *)data = le16_to_cpu(inw(hc->pci_iobase)); data += 2; len -= 2; } while (len) { *data = inb(hc->pci_iobase); data++; len--; } } /* read fifo data (PCIMEM) */ static void read_fifo_pcimem(struct hfc_multi *hc, u_char *data, int len) { while (len >> 2) { *(u32 *)data = le32_to_cpu(readl(hc->pci_membase + A_FIFO_DATA0)); data += 4; len -= 4; } while (len >> 1) { *(u16 *)data = le16_to_cpu(readw(hc->pci_membase + A_FIFO_DATA0)); data += 2; len -= 2; } while (len) { *data = readb(hc->pci_membase + A_FIFO_DATA0); data++; len--; } } static void enable_hwirq(struct hfc_multi *hc) { hc->hw.r_irq_ctrl |= V_GLOB_IRQ_EN; HFC_outb(hc, R_IRQ_CTRL, hc->hw.r_irq_ctrl); } static void disable_hwirq(struct hfc_multi *hc) { hc->hw.r_irq_ctrl &= ~((u_char)V_GLOB_IRQ_EN); HFC_outb(hc, R_IRQ_CTRL, hc->hw.r_irq_ctrl); } #define NUM_EC 2 #define MAX_TDM_CHAN 32 static inline void enablepcibridge(struct hfc_multi *c) { HFC_outb(c, R_BRG_PCM_CFG, (0x0 << 6) | 0x3); /* was _io before */ } static inline void disablepcibridge(struct hfc_multi *c) { HFC_outb(c, R_BRG_PCM_CFG, (0x0 << 6) | 0x2); /* was _io before */ } static inline unsigned char readpcibridge(struct hfc_multi *hc, unsigned char address) { unsigned short cipv; unsigned char data; if (!hc->pci_iobase) return 0; /* slow down a PCI read access by 1 PCI clock cycle */ HFC_outb(hc, R_CTRL, 0x4); /*was _io before*/ if (address == 0) cipv = 0x4000; else cipv = 0x5800; /* select local bridge port address by writing to CIP port */ /* data = HFC_inb(c, cipv); * was _io before */ outw(cipv, hc->pci_iobase + 4); data = inb(hc->pci_iobase); /* restore R_CTRL for normal PCI read cycle speed */ HFC_outb(hc, R_CTRL, 0x0); /* was _io before */ return data; } static inline void writepcibridge(struct hfc_multi *hc, unsigned char address, unsigned char data) { unsigned short cipv; unsigned int datav; if (!hc->pci_iobase) return; if (address == 0) cipv = 0x4000; else cipv = 0x5800; /* select local bridge port address by writing to CIP port */ outw(cipv, hc->pci_iobase + 4); /* define a 32 bit dword with 4 identical bytes for write sequence */ datav = data | ((__u32) data << 8) | ((__u32) data << 16) | ((__u32) data << 24); /* * write this 32 bit dword to the bridge data port * this will initiate a write sequence of up to 4 writes to the same * address on the local bus interface the number of write accesses * is undefined but >=1 and depends on the next PCI transaction * during write sequence on the local bus */ outl(datav, hc->pci_iobase); } static inline void cpld_set_reg(struct hfc_multi *hc, unsigned char reg) { /* Do data pin read low byte */ HFC_outb(hc, R_GPIO_OUT1, reg); } static inline void cpld_write_reg(struct hfc_multi *hc, unsigned char reg, unsigned char val) { cpld_set_reg(hc, reg); enablepcibridge(hc); writepcibridge(hc, 1, val); disablepcibridge(hc); return; } static inline unsigned char cpld_read_reg(struct hfc_multi *hc, unsigned char reg) { unsigned char bytein; cpld_set_reg(hc, reg); /* Do data pin read low byte */ HFC_outb(hc, R_GPIO_OUT1, reg); enablepcibridge(hc); bytein = readpcibridge(hc, 1); disablepcibridge(hc); return bytein; } static inline void vpm_write_address(struct hfc_multi *hc, unsigned short addr) { cpld_write_reg(hc, 0, 0xff & addr); cpld_write_reg(hc, 1, 0x01 & (addr >> 8)); } static inline unsigned short vpm_read_address(struct hfc_multi *c) { unsigned short addr; unsigned short highbit; addr = cpld_read_reg(c, 0); highbit = cpld_read_reg(c, 1); addr = addr | (highbit << 8); return addr & 0x1ff; } static inline unsigned char vpm_in(struct hfc_multi *c, int which, unsigned short addr) { unsigned char res; vpm_write_address(c, addr); if (!which) cpld_set_reg(c, 2); else cpld_set_reg(c, 3); enablepcibridge(c); res = readpcibridge(c, 1); disablepcibridge(c); cpld_set_reg(c, 0); return res; } static inline void vpm_out(struct hfc_multi *c, int which, unsigned short addr, unsigned char data) { vpm_write_address(c, addr); enablepcibridge(c); if (!which) cpld_set_reg(c, 2); else cpld_set_reg(c, 3); writepcibridge(c, 1, data); cpld_set_reg(c, 0); disablepcibridge(c); { unsigned char regin; regin = vpm_in(c, which, addr); if (regin != data) printk(KERN_DEBUG "Wrote 0x%x to register 0x%x but got back " "0x%x\n", data, addr, regin); } } static void vpm_init(struct hfc_multi *wc) { unsigned char reg; unsigned int mask; unsigned int i, x, y; unsigned int ver; for (x = 0; x < NUM_EC; x++) { /* Setup GPIO's */ if (!x) { ver = vpm_in(wc, x, 0x1a0); printk(KERN_DEBUG "VPM: Chip %d: ver %02x\n", x, ver); } for (y = 0; y < 4; y++) { vpm_out(wc, x, 0x1a8 + y, 0x00); /* GPIO out */ vpm_out(wc, x, 0x1ac + y, 0x00); /* GPIO dir */ vpm_out(wc, x, 0x1b0 + y, 0x00); /* GPIO sel */ } /* Setup TDM path - sets fsync and tdm_clk as inputs */ reg = vpm_in(wc, x, 0x1a3); /* misc_con */ vpm_out(wc, x, 0x1a3, reg & ~2); /* Setup Echo length (256 taps) */ vpm_out(wc, x, 0x022, 1); vpm_out(wc, x, 0x023, 0xff); /* Setup timeslots */ vpm_out(wc, x, 0x02f, 0x00); mask = 0x02020202 << (x * 4); /* Setup the tdm channel masks for all chips */ for (i = 0; i < 4; i++) vpm_out(wc, x, 0x33 - i, (mask >> (i << 3)) & 0xff); /* Setup convergence rate */ printk(KERN_DEBUG "VPM: A-law mode\n"); reg = 0x00 | 0x10 | 0x01; vpm_out(wc, x, 0x20, reg); printk(KERN_DEBUG "VPM reg 0x20 is %x\n", reg); /*vpm_out(wc, x, 0x20, (0x00 | 0x08 | 0x20 | 0x10)); */ vpm_out(wc, x, 0x24, 0x02); reg = vpm_in(wc, x, 0x24); printk(KERN_DEBUG "NLP Thresh is set to %d (0x%x)\n", reg, reg); /* Initialize echo cans */ for (i = 0; i < MAX_TDM_CHAN; i++) { if (mask & (0x00000001 << i)) vpm_out(wc, x, i, 0x00); } /* * ARM arch at least disallows a udelay of * more than 2ms... it gives a fake "__bad_udelay" * reference at link-time. * long delays in kernel code are pretty sucky anyway * for now work around it using 5 x 2ms instead of 1 x 10ms */ udelay(2000); udelay(2000); udelay(2000); udelay(2000); udelay(2000); /* Put in bypass mode */ for (i = 0; i < MAX_TDM_CHAN; i++) { if (mask & (0x00000001 << i)) vpm_out(wc, x, i, 0x01); } /* Enable bypass */ for (i = 0; i < MAX_TDM_CHAN; i++) { if (mask & (0x00000001 << i)) vpm_out(wc, x, 0x78 + i, 0x01); } } } #ifdef UNUSED static void vpm_check(struct hfc_multi *hctmp) { unsigned char gpi2; gpi2 = HFC_inb(hctmp, R_GPI_IN2); if ((gpi2 & 0x3) != 0x3) printk(KERN_DEBUG "Got interrupt 0x%x from VPM!\n", gpi2); } #endif /* UNUSED */ /* * Interface to enable/disable the HW Echocan * * these functions are called within a spin_lock_irqsave on * the channel instance lock, so we are not disturbed by irqs * * we can later easily change the interface to make other * things configurable, for now we configure the taps * */ static void vpm_echocan_on(struct hfc_multi *hc, int ch, int taps) { unsigned int timeslot; unsigned int unit; struct bchannel *bch = hc->chan[ch].bch; #ifdef TXADJ int txadj = -4; struct sk_buff *skb; #endif if (hc->chan[ch].protocol != ISDN_P_B_RAW) return; if (!bch) return; #ifdef TXADJ skb = _alloc_mISDN_skb(PH_CONTROL_IND, HFC_VOL_CHANGE_TX, sizeof(int), &txadj, GFP_ATOMIC); if (skb) recv_Bchannel_skb(bch, skb); #endif timeslot = ((ch / 4) * 8) + ((ch % 4) * 4) + 1; unit = ch % 4; printk(KERN_NOTICE "vpm_echocan_on called taps [%d] on timeslot %d\n", taps, timeslot); vpm_out(hc, unit, timeslot, 0x7e); } static void vpm_echocan_off(struct hfc_multi *hc, int ch) { unsigned int timeslot; unsigned int unit; struct bchannel *bch = hc->chan[ch].bch; #ifdef TXADJ int txadj = 0; struct sk_buff *skb; #endif if (hc->chan[ch].protocol != ISDN_P_B_RAW) return; if (!bch) return; #ifdef TXADJ skb = _alloc_mISDN_skb(PH_CONTROL_IND, HFC_VOL_CHANGE_TX, sizeof(int), &txadj, GFP_ATOMIC); if (skb) recv_Bchannel_skb(bch, skb); #endif timeslot = ((ch / 4) * 8) + ((ch % 4) * 4) + 1; unit = ch % 4; printk(KERN_NOTICE "vpm_echocan_off called on timeslot %d\n", timeslot); /* FILLME */ vpm_out(hc, unit, timeslot, 0x01); } /* * Speech Design resync feature * NOTE: This is called sometimes outside interrupt handler. * We must lock irqsave, so no other interrupt (other card) will occur! * Also multiple interrupts may nest, so must lock each access (lists, card)! */ static inline void hfcmulti_resync(struct hfc_multi *locked, struct hfc_multi *newmaster, int rm) { struct hfc_multi *hc, *next, *pcmmaster = NULL; void __iomem *plx_acc_32; u_int pv; u_long flags; spin_lock_irqsave(&HFClock, flags); spin_lock(&plx_lock); /* must be locked inside other locks */ if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "%s: RESYNC(syncmaster=0x%p)\n", __func__, syncmaster); /* select new master */ if (newmaster) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "using provided controller\n"); } else { list_for_each_entry_safe(hc, next, &HFClist, list) { if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { if (hc->syncronized) { newmaster = hc; break; } } } } /* Disable sync of all cards */ list_for_each_entry_safe(hc, next, &HFClist, list) { if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { plx_acc_32 = hc->plx_membase + PLX_GPIOC; pv = readl(plx_acc_32); pv &= ~PLX_SYNC_O_EN; writel(pv, plx_acc_32); if (test_bit(HFC_CHIP_PCM_MASTER, &hc->chip)) { pcmmaster = hc; if (hc->ctype == HFC_TYPE_E1) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "Schedule SYNC_I\n"); hc->e1_resync |= 1; /* get SYNC_I */ } } } } if (newmaster) { hc = newmaster; if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "id=%d (0x%p) = syncronized with " "interface.\n", hc->id, hc); /* Enable new sync master */ plx_acc_32 = hc->plx_membase + PLX_GPIOC; pv = readl(plx_acc_32); pv |= PLX_SYNC_O_EN; writel(pv, plx_acc_32); /* switch to jatt PLL, if not disabled by RX_SYNC */ if (hc->ctype == HFC_TYPE_E1 && !test_bit(HFC_CHIP_RX_SYNC, &hc->chip)) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "Schedule jatt PLL\n"); hc->e1_resync |= 2; /* switch to jatt */ } } else { if (pcmmaster) { hc = pcmmaster; if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "id=%d (0x%p) = PCM master syncronized " "with QUARTZ\n", hc->id, hc); if (hc->ctype == HFC_TYPE_E1) { /* Use the crystal clock for the PCM master card */ if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "Schedule QUARTZ for HFC-E1\n"); hc->e1_resync |= 4; /* switch quartz */ } else { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "QUARTZ is automatically " "enabled by HFC-%dS\n", hc->ctype); } plx_acc_32 = hc->plx_membase + PLX_GPIOC; pv = readl(plx_acc_32); pv |= PLX_SYNC_O_EN; writel(pv, plx_acc_32); } else if (!rm) printk(KERN_ERR "%s no pcm master, this MUST " "not happen!\n", __func__); } syncmaster = newmaster; spin_unlock(&plx_lock); spin_unlock_irqrestore(&HFClock, flags); } /* This must be called AND hc must be locked irqsave!!! */ static inline void plxsd_checksync(struct hfc_multi *hc, int rm) { if (hc->syncronized) { if (syncmaster == NULL) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "%s: GOT sync on card %d" " (id=%d)\n", __func__, hc->id + 1, hc->id); hfcmulti_resync(hc, hc, rm); } } else { if (syncmaster == hc) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "%s: LOST sync on card %d" " (id=%d)\n", __func__, hc->id + 1, hc->id); hfcmulti_resync(hc, NULL, rm); } } } /* * free hardware resources used by driver */ static void release_io_hfcmulti(struct hfc_multi *hc) { void __iomem *plx_acc_32; u_int pv; u_long plx_flags; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: entered\n", __func__); /* soft reset also masks all interrupts */ hc->hw.r_cirm |= V_SRES; HFC_outb(hc, R_CIRM, hc->hw.r_cirm); udelay(1000); hc->hw.r_cirm &= ~V_SRES; HFC_outb(hc, R_CIRM, hc->hw.r_cirm); udelay(1000); /* instead of 'wait' that may cause locking */ /* release Speech Design card, if PLX was initialized */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip) && hc->plx_membase) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "%s: release PLXSD card %d\n", __func__, hc->id + 1); spin_lock_irqsave(&plx_lock, plx_flags); plx_acc_32 = hc->plx_membase + PLX_GPIOC; writel(PLX_GPIOC_INIT, plx_acc_32); pv = readl(plx_acc_32); /* Termination off */ pv &= ~PLX_TERM_ON; /* Disconnect the PCM */ pv |= PLX_SLAVE_EN_N; pv &= ~PLX_MASTER_EN; pv &= ~PLX_SYNC_O_EN; /* Put the DSP in Reset */ pv &= ~PLX_DSP_RES_N; writel(pv, plx_acc_32); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PCM off: PLX_GPIO=%x\n", __func__, pv); spin_unlock_irqrestore(&plx_lock, plx_flags); } /* disable memory mapped ports / io ports */ test_and_clear_bit(HFC_CHIP_PLXSD, &hc->chip); /* prevent resync */ if (hc->pci_dev) pci_write_config_word(hc->pci_dev, PCI_COMMAND, 0); if (hc->pci_membase) iounmap(hc->pci_membase); if (hc->plx_membase) iounmap(hc->plx_membase); if (hc->pci_iobase) release_region(hc->pci_iobase, 8); if (hc->xhfc_membase) iounmap((void *)hc->xhfc_membase); if (hc->pci_dev) { pci_disable_device(hc->pci_dev); pci_set_drvdata(hc->pci_dev, NULL); } if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: done\n", __func__); } /* * function called to reset the HFC chip. A complete software reset of chip * and fifos is done. All configuration of the chip is done. */ static int init_chip(struct hfc_multi *hc) { u_long flags, val, val2 = 0, rev; int i, err = 0; u_char r_conf_en, rval; void __iomem *plx_acc_32; u_int pv; u_long plx_flags, hfc_flags; int plx_count; struct hfc_multi *pos, *next, *plx_last_hc; spin_lock_irqsave(&hc->lock, flags); /* reset all registers */ memset(&hc->hw, 0, sizeof(struct hfcm_hw)); /* revision check */ if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: entered\n", __func__); val = HFC_inb(hc, R_CHIP_ID); if ((val >> 4) != 0x8 && (val >> 4) != 0xc && (val >> 4) != 0xe && (val >> 1) != 0x31) { printk(KERN_INFO "HFC_multi: unknown CHIP_ID:%x\n", (u_int)val); err = -EIO; goto out; } rev = HFC_inb(hc, R_CHIP_RV); printk(KERN_INFO "HFC_multi: detected HFC with chip ID=0x%lx revision=%ld%s\n", val, rev, (rev == 0 && (hc->ctype != HFC_TYPE_XHFC)) ? " (old FIFO handling)" : ""); if (hc->ctype != HFC_TYPE_XHFC && rev == 0) { test_and_set_bit(HFC_CHIP_REVISION0, &hc->chip); printk(KERN_WARNING "HFC_multi: NOTE: Your chip is revision 0, " "ask Cologne Chip for update. Newer chips " "have a better FIFO handling. Old chips " "still work but may have slightly lower " "HDLC transmit performance.\n"); } if (rev > 1) { printk(KERN_WARNING "HFC_multi: WARNING: This driver doesn't " "consider chip revision = %ld. The chip / " "bridge may not work.\n", rev); } /* set s-ram size */ hc->Flen = 0x10; hc->Zmin = 0x80; hc->Zlen = 384; hc->DTMFbase = 0x1000; if (test_bit(HFC_CHIP_EXRAM_128, &hc->chip)) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: changing to 128K external RAM\n", __func__); hc->hw.r_ctrl |= V_EXT_RAM; hc->hw.r_ram_sz = 1; hc->Flen = 0x20; hc->Zmin = 0xc0; hc->Zlen = 1856; hc->DTMFbase = 0x2000; } if (test_bit(HFC_CHIP_EXRAM_512, &hc->chip)) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: changing to 512K external RAM\n", __func__); hc->hw.r_ctrl |= V_EXT_RAM; hc->hw.r_ram_sz = 2; hc->Flen = 0x20; hc->Zmin = 0xc0; hc->Zlen = 8000; hc->DTMFbase = 0x2000; } if (hc->ctype == HFC_TYPE_XHFC) { hc->Flen = 0x8; hc->Zmin = 0x0; hc->Zlen = 64; hc->DTMFbase = 0x0; } hc->max_trans = poll << 1; if (hc->max_trans > hc->Zlen) hc->max_trans = hc->Zlen; /* Speech Design PLX bridge */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "%s: initializing PLXSD card %d\n", __func__, hc->id + 1); spin_lock_irqsave(&plx_lock, plx_flags); plx_acc_32 = hc->plx_membase + PLX_GPIOC; writel(PLX_GPIOC_INIT, plx_acc_32); pv = readl(plx_acc_32); /* The first and the last cards are terminating the PCM bus */ pv |= PLX_TERM_ON; /* hc is currently the last */ /* Disconnect the PCM */ pv |= PLX_SLAVE_EN_N; pv &= ~PLX_MASTER_EN; pv &= ~PLX_SYNC_O_EN; /* Put the DSP in Reset */ pv &= ~PLX_DSP_RES_N; writel(pv, plx_acc_32); spin_unlock_irqrestore(&plx_lock, plx_flags); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: slave/term: PLX_GPIO=%x\n", __func__, pv); /* * If we are the 3rd PLXSD card or higher, we must turn * termination of last PLXSD card off. */ spin_lock_irqsave(&HFClock, hfc_flags); plx_count = 0; plx_last_hc = NULL; list_for_each_entry_safe(pos, next, &HFClist, list) { if (test_bit(HFC_CHIP_PLXSD, &pos->chip)) { plx_count++; if (pos != hc) plx_last_hc = pos; } } if (plx_count >= 3) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "%s: card %d is between, so " "we disable termination\n", __func__, plx_last_hc->id + 1); spin_lock_irqsave(&plx_lock, plx_flags); plx_acc_32 = plx_last_hc->plx_membase + PLX_GPIOC; pv = readl(plx_acc_32); pv &= ~PLX_TERM_ON; writel(pv, plx_acc_32); spin_unlock_irqrestore(&plx_lock, plx_flags); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: term off: PLX_GPIO=%x\n", __func__, pv); } spin_unlock_irqrestore(&HFClock, hfc_flags); hc->hw.r_pcm_md0 = V_F0_LEN; /* shift clock for DSP */ } if (test_bit(HFC_CHIP_EMBSD, &hc->chip)) hc->hw.r_pcm_md0 = V_F0_LEN; /* shift clock for DSP */ /* we only want the real Z2 read-pointer for revision > 0 */ if (!test_bit(HFC_CHIP_REVISION0, &hc->chip)) hc->hw.r_ram_sz |= V_FZ_MD; /* select pcm mode */ if (test_bit(HFC_CHIP_PCM_SLAVE, &hc->chip)) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: setting PCM into slave mode\n", __func__); } else if (test_bit(HFC_CHIP_PCM_MASTER, &hc->chip) && !plxsd_master) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: setting PCM into master mode\n", __func__); hc->hw.r_pcm_md0 |= V_PCM_MD; } else { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: performing PCM auto detect\n", __func__); } /* soft reset */ HFC_outb(hc, R_CTRL, hc->hw.r_ctrl); if (hc->ctype == HFC_TYPE_XHFC) HFC_outb(hc, 0x0C /* R_FIFO_THRES */, 0x11 /* 16 Bytes TX/RX */); else HFC_outb(hc, R_RAM_SZ, hc->hw.r_ram_sz); HFC_outb(hc, R_FIFO_MD, 0); if (hc->ctype == HFC_TYPE_XHFC) hc->hw.r_cirm = V_SRES | V_HFCRES | V_PCMRES | V_STRES; else hc->hw.r_cirm = V_SRES | V_HFCRES | V_PCMRES | V_STRES | V_RLD_EPR; HFC_outb(hc, R_CIRM, hc->hw.r_cirm); udelay(100); hc->hw.r_cirm = 0; HFC_outb(hc, R_CIRM, hc->hw.r_cirm); udelay(100); if (hc->ctype != HFC_TYPE_XHFC) HFC_outb(hc, R_RAM_SZ, hc->hw.r_ram_sz); /* Speech Design PLX bridge pcm and sync mode */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { spin_lock_irqsave(&plx_lock, plx_flags); plx_acc_32 = hc->plx_membase + PLX_GPIOC; pv = readl(plx_acc_32); /* Connect PCM */ if (hc->hw.r_pcm_md0 & V_PCM_MD) { pv |= PLX_MASTER_EN | PLX_SLAVE_EN_N; pv |= PLX_SYNC_O_EN; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: master: PLX_GPIO=%x\n", __func__, pv); } else { pv &= ~(PLX_MASTER_EN | PLX_SLAVE_EN_N); pv &= ~PLX_SYNC_O_EN; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: slave: PLX_GPIO=%x\n", __func__, pv); } writel(pv, plx_acc_32); spin_unlock_irqrestore(&plx_lock, plx_flags); } /* PCM setup */ HFC_outb(hc, R_PCM_MD0, hc->hw.r_pcm_md0 | 0x90); if (hc->slots == 32) HFC_outb(hc, R_PCM_MD1, 0x00); if (hc->slots == 64) HFC_outb(hc, R_PCM_MD1, 0x10); if (hc->slots == 128) HFC_outb(hc, R_PCM_MD1, 0x20); HFC_outb(hc, R_PCM_MD0, hc->hw.r_pcm_md0 | 0xa0); if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) HFC_outb(hc, R_PCM_MD2, V_SYNC_SRC); /* sync via SYNC_I / O */ else if (test_bit(HFC_CHIP_EMBSD, &hc->chip)) HFC_outb(hc, R_PCM_MD2, 0x10); /* V_C2O_EN */ else HFC_outb(hc, R_PCM_MD2, 0x00); /* sync from interface */ HFC_outb(hc, R_PCM_MD0, hc->hw.r_pcm_md0 | 0x00); for (i = 0; i < 256; i++) { HFC_outb_nodebug(hc, R_SLOT, i); HFC_outb_nodebug(hc, A_SL_CFG, 0); if (hc->ctype != HFC_TYPE_XHFC) HFC_outb_nodebug(hc, A_CONF, 0); hc->slot_owner[i] = -1; } /* set clock speed */ if (test_bit(HFC_CHIP_CLOCK2, &hc->chip)) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: setting double clock\n", __func__); HFC_outb(hc, R_BRG_PCM_CFG, V_PCM_CLK); } if (test_bit(HFC_CHIP_EMBSD, &hc->chip)) HFC_outb(hc, 0x02 /* R_CLK_CFG */, 0x40 /* V_CLKO_OFF */); /* B410P GPIO */ if (test_bit(HFC_CHIP_B410P, &hc->chip)) { printk(KERN_NOTICE "Setting GPIOs\n"); HFC_outb(hc, R_GPIO_SEL, 0x30); HFC_outb(hc, R_GPIO_EN1, 0x3); udelay(1000); printk(KERN_NOTICE "calling vpm_init\n"); vpm_init(hc); } /* check if R_F0_CNT counts (8 kHz frame count) */ val = HFC_inb(hc, R_F0_CNTL); val += HFC_inb(hc, R_F0_CNTH) << 8; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "HFC_multi F0_CNT %ld after reset\n", val); spin_unlock_irqrestore(&hc->lock, flags); set_current_state(TASK_UNINTERRUPTIBLE); schedule_timeout((HZ / 100) ? : 1); /* Timeout minimum 10ms */ spin_lock_irqsave(&hc->lock, flags); val2 = HFC_inb(hc, R_F0_CNTL); val2 += HFC_inb(hc, R_F0_CNTH) << 8; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "HFC_multi F0_CNT %ld after 10 ms (1st try)\n", val2); if (val2 >= val + 8) { /* 1 ms */ /* it counts, so we keep the pcm mode */ if (test_bit(HFC_CHIP_PCM_MASTER, &hc->chip)) printk(KERN_INFO "controller is PCM bus MASTER\n"); else if (test_bit(HFC_CHIP_PCM_SLAVE, &hc->chip)) printk(KERN_INFO "controller is PCM bus SLAVE\n"); else { test_and_set_bit(HFC_CHIP_PCM_SLAVE, &hc->chip); printk(KERN_INFO "controller is PCM bus SLAVE " "(auto detected)\n"); } } else { /* does not count */ if (test_bit(HFC_CHIP_PCM_MASTER, &hc->chip)) { controller_fail: printk(KERN_ERR "HFC_multi ERROR, getting no 125us " "pulse. Seems that controller fails.\n"); err = -EIO; goto out; } if (test_bit(HFC_CHIP_PCM_SLAVE, &hc->chip)) { printk(KERN_INFO "controller is PCM bus SLAVE " "(ignoring missing PCM clock)\n"); } else { /* only one pcm master */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip) && plxsd_master) { printk(KERN_ERR "HFC_multi ERROR, no clock " "on another Speech Design card found. " "Please be sure to connect PCM cable.\n"); err = -EIO; goto out; } /* retry with master clock */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { spin_lock_irqsave(&plx_lock, plx_flags); plx_acc_32 = hc->plx_membase + PLX_GPIOC; pv = readl(plx_acc_32); pv |= PLX_MASTER_EN | PLX_SLAVE_EN_N; pv |= PLX_SYNC_O_EN; writel(pv, plx_acc_32); spin_unlock_irqrestore(&plx_lock, plx_flags); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: master: " "PLX_GPIO=%x\n", __func__, pv); } hc->hw.r_pcm_md0 |= V_PCM_MD; HFC_outb(hc, R_PCM_MD0, hc->hw.r_pcm_md0 | 0x00); spin_unlock_irqrestore(&hc->lock, flags); set_current_state(TASK_UNINTERRUPTIBLE); schedule_timeout((HZ / 100) ?: 1); /* Timeout min. 10ms */ spin_lock_irqsave(&hc->lock, flags); val2 = HFC_inb(hc, R_F0_CNTL); val2 += HFC_inb(hc, R_F0_CNTH) << 8; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "HFC_multi F0_CNT %ld after " "10 ms (2nd try)\n", val2); if (val2 >= val + 8) { /* 1 ms */ test_and_set_bit(HFC_CHIP_PCM_MASTER, &hc->chip); printk(KERN_INFO "controller is PCM bus MASTER " "(auto detected)\n"); } else goto controller_fail; } } /* Release the DSP Reset */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { if (test_bit(HFC_CHIP_PCM_MASTER, &hc->chip)) plxsd_master = 1; spin_lock_irqsave(&plx_lock, plx_flags); plx_acc_32 = hc->plx_membase + PLX_GPIOC; pv = readl(plx_acc_32); pv |= PLX_DSP_RES_N; writel(pv, plx_acc_32); spin_unlock_irqrestore(&plx_lock, plx_flags); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: reset off: PLX_GPIO=%x\n", __func__, pv); } /* pcm id */ if (hc->pcm) printk(KERN_INFO "controller has given PCM BUS ID %d\n", hc->pcm); else { if (test_bit(HFC_CHIP_PCM_MASTER, &hc->chip) || test_bit(HFC_CHIP_PLXSD, &hc->chip)) { PCM_cnt++; /* SD has proprietary bridging */ } hc->pcm = PCM_cnt; printk(KERN_INFO "controller has PCM BUS ID %d " "(auto selected)\n", hc->pcm); } /* set up timer */ HFC_outb(hc, R_TI_WD, poll_timer); hc->hw.r_irqmsk_misc |= V_TI_IRQMSK; /* set E1 state machine IRQ */ if (hc->ctype == HFC_TYPE_E1) hc->hw.r_irqmsk_misc |= V_STA_IRQMSK; /* set DTMF detection */ if (test_bit(HFC_CHIP_DTMF, &hc->chip)) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: enabling DTMF detection " "for all B-channel\n", __func__); hc->hw.r_dtmf = V_DTMF_EN | V_DTMF_STOP; if (test_bit(HFC_CHIP_ULAW, &hc->chip)) hc->hw.r_dtmf |= V_ULAW_SEL; HFC_outb(hc, R_DTMF_N, 102 - 1); hc->hw.r_irqmsk_misc |= V_DTMF_IRQMSK; } /* conference engine */ if (test_bit(HFC_CHIP_ULAW, &hc->chip)) r_conf_en = V_CONF_EN | V_ULAW; else r_conf_en = V_CONF_EN; if (hc->ctype != HFC_TYPE_XHFC) HFC_outb(hc, R_CONF_EN, r_conf_en); /* setting leds */ switch (hc->leds) { case 1: /* HFC-E1 OEM */ if (test_bit(HFC_CHIP_WATCHDOG, &hc->chip)) HFC_outb(hc, R_GPIO_SEL, 0x32); else HFC_outb(hc, R_GPIO_SEL, 0x30); HFC_outb(hc, R_GPIO_EN1, 0x0f); HFC_outb(hc, R_GPIO_OUT1, 0x00); HFC_outb(hc, R_GPIO_EN0, V_GPIO_EN2 | V_GPIO_EN3); break; case 2: /* HFC-4S OEM */ case 3: HFC_outb(hc, R_GPIO_SEL, 0xf0); HFC_outb(hc, R_GPIO_EN1, 0xff); HFC_outb(hc, R_GPIO_OUT1, 0x00); break; } if (test_bit(HFC_CHIP_EMBSD, &hc->chip)) { hc->hw.r_st_sync = 0x10; /* V_AUTO_SYNCI */ HFC_outb(hc, R_ST_SYNC, hc->hw.r_st_sync); } /* set master clock */ if (hc->masterclk >= 0) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: setting ST master clock " "to port %d (0..%d)\n", __func__, hc->masterclk, hc->ports - 1); hc->hw.r_st_sync |= (hc->masterclk | V_AUTO_SYNC); HFC_outb(hc, R_ST_SYNC, hc->hw.r_st_sync); } /* setting misc irq */ HFC_outb(hc, R_IRQMSK_MISC, hc->hw.r_irqmsk_misc); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "r_irqmsk_misc.2: 0x%x\n", hc->hw.r_irqmsk_misc); /* RAM access test */ HFC_outb(hc, R_RAM_ADDR0, 0); HFC_outb(hc, R_RAM_ADDR1, 0); HFC_outb(hc, R_RAM_ADDR2, 0); for (i = 0; i < 256; i++) { HFC_outb_nodebug(hc, R_RAM_ADDR0, i); HFC_outb_nodebug(hc, R_RAM_DATA, ((i * 3) & 0xff)); } for (i = 0; i < 256; i++) { HFC_outb_nodebug(hc, R_RAM_ADDR0, i); HFC_inb_nodebug(hc, R_RAM_DATA); rval = HFC_inb_nodebug(hc, R_INT_DATA); if (rval != ((i * 3) & 0xff)) { printk(KERN_DEBUG "addr:%x val:%x should:%x\n", i, rval, (i * 3) & 0xff); err++; } } if (err) { printk(KERN_DEBUG "aborting - %d RAM access errors\n", err); err = -EIO; goto out; } if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: done\n", __func__); out: spin_unlock_irqrestore(&hc->lock, flags); return err; } /* * control the watchdog */ static void hfcmulti_watchdog(struct hfc_multi *hc) { hc->wdcount++; if (hc->wdcount > 10) { hc->wdcount = 0; hc->wdbyte = hc->wdbyte == V_GPIO_OUT2 ? V_GPIO_OUT3 : V_GPIO_OUT2; /* printk("Sending Watchdog Kill %x\n",hc->wdbyte); */ HFC_outb(hc, R_GPIO_EN0, V_GPIO_EN2 | V_GPIO_EN3); HFC_outb(hc, R_GPIO_OUT0, hc->wdbyte); } } /* * output leds */ static void hfcmulti_leds(struct hfc_multi *hc) { unsigned long lled; unsigned long leddw; int i, state, active, leds; struct dchannel *dch; int led[4]; switch (hc->leds) { case 1: /* HFC-E1 OEM */ /* 2 red steady: LOS * 1 red steady: L1 not active * 2 green steady: L1 active * 1st green flashing: activity on TX * 2nd green flashing: activity on RX */ led[0] = 0; led[1] = 0; led[2] = 0; led[3] = 0; dch = hc->chan[hc->dnum[0]].dch; if (dch) { if (hc->chan[hc->dnum[0]].los) led[1] = 1; if (hc->e1_state != 1) { led[0] = 1; hc->flash[2] = 0; hc->flash[3] = 0; } else { led[2] = 1; led[3] = 1; if (!hc->flash[2] && hc->activity_tx) hc->flash[2] = poll; if (!hc->flash[3] && hc->activity_rx) hc->flash[3] = poll; if (hc->flash[2] && hc->flash[2] < 1024) led[2] = 0; if (hc->flash[3] && hc->flash[3] < 1024) led[3] = 0; if (hc->flash[2] >= 2048) hc->flash[2] = 0; if (hc->flash[3] >= 2048) hc->flash[3] = 0; if (hc->flash[2]) hc->flash[2] += poll; if (hc->flash[3]) hc->flash[3] += poll; } } leds = (led[0] | (led[1]<<2) | (led[2]<<1) | (led[3]<<3))^0xF; /* leds are inverted */ if (leds != (int)hc->ledstate) { HFC_outb_nodebug(hc, R_GPIO_OUT1, leds); hc->ledstate = leds; } break; case 2: /* HFC-4S OEM */ /* red steady: PH_DEACTIVATE * green steady: PH_ACTIVATE * green flashing: activity on TX */ for (i = 0; i < 4; i++) { state = 0; active = -1; dch = hc->chan[(i << 2) | 2].dch; if (dch) { state = dch->state; if (dch->dev.D.protocol == ISDN_P_NT_S0) active = 3; else active = 7; } if (state) { if (state == active) { led[i] = 1; /* led green */ hc->activity_tx |= hc->activity_rx; if (!hc->flash[i] && (hc->activity_tx & (1 << i))) hc->flash[i] = poll; if (hc->flash[i] && hc->flash[i] < 1024) led[i] = 0; /* led off */ if (hc->flash[i] >= 2048) hc->flash[i] = 0; if (hc->flash[i]) hc->flash[i] += poll; } else { led[i] = 2; /* led red */ hc->flash[i] = 0; } } else led[i] = 0; /* led off */ } if (test_bit(HFC_CHIP_B410P, &hc->chip)) { leds = 0; for (i = 0; i < 4; i++) { if (led[i] == 1) { /*green*/ leds |= (0x2 << (i * 2)); } else if (led[i] == 2) { /*red*/ leds |= (0x1 << (i * 2)); } } if (leds != (int)hc->ledstate) { vpm_out(hc, 0, 0x1a8 + 3, leds); hc->ledstate = leds; } } else { leds = ((led[3] > 0) << 0) | ((led[1] > 0) << 1) | ((led[0] > 0) << 2) | ((led[2] > 0) << 3) | ((led[3] & 1) << 4) | ((led[1] & 1) << 5) | ((led[0] & 1) << 6) | ((led[2] & 1) << 7); if (leds != (int)hc->ledstate) { HFC_outb_nodebug(hc, R_GPIO_EN1, leds & 0x0F); HFC_outb_nodebug(hc, R_GPIO_OUT1, leds >> 4); hc->ledstate = leds; } } break; case 3: /* HFC 1S/2S Beronet */ /* red steady: PH_DEACTIVATE * green steady: PH_ACTIVATE * green flashing: activity on TX */ for (i = 0; i < 2; i++) { state = 0; active = -1; dch = hc->chan[(i << 2) | 2].dch; if (dch) { state = dch->state; if (dch->dev.D.protocol == ISDN_P_NT_S0) active = 3; else active = 7; } if (state) { if (state == active) { led[i] = 1; /* led green */ hc->activity_tx |= hc->activity_rx; if (!hc->flash[i] && (hc->activity_tx & (1 << i))) hc->flash[i] = poll; if (hc->flash[i] < 1024) led[i] = 0; /* led off */ if (hc->flash[i] >= 2048) hc->flash[i] = 0; if (hc->flash[i]) hc->flash[i] += poll; } else { led[i] = 2; /* led red */ hc->flash[i] = 0; } } else led[i] = 0; /* led off */ } leds = (led[0] > 0) | ((led[1] > 0) << 1) | ((led[0]&1) << 2) | ((led[1]&1) << 3); if (leds != (int)hc->ledstate) { HFC_outb_nodebug(hc, R_GPIO_EN1, ((led[0] > 0) << 2) | ((led[1] > 0) << 3)); HFC_outb_nodebug(hc, R_GPIO_OUT1, ((led[0] & 1) << 2) | ((led[1] & 1) << 3)); hc->ledstate = leds; } break; case 8: /* HFC 8S+ Beronet */ /* off: PH_DEACTIVATE * steady: PH_ACTIVATE * flashing: activity on TX */ lled = 0xff; /* leds off */ for (i = 0; i < 8; i++) { state = 0; active = -1; dch = hc->chan[(i << 2) | 2].dch; if (dch) { state = dch->state; if (dch->dev.D.protocol == ISDN_P_NT_S0) active = 3; else active = 7; } if (state) { if (state == active) { lled &= ~(1 << i); /* led on */ hc->activity_tx |= hc->activity_rx; if (!hc->flash[i] && (hc->activity_tx & (1 << i))) hc->flash[i] = poll; if (hc->flash[i] < 1024) lled |= 1 << i; /* led off */ if (hc->flash[i] >= 2048) hc->flash[i] = 0; if (hc->flash[i]) hc->flash[i] += poll; } else hc->flash[i] = 0; } } leddw = lled << 24 | lled << 16 | lled << 8 | lled; if (leddw != hc->ledstate) { /* HFC_outb(hc, R_BRG_PCM_CFG, 1); HFC_outb(c, R_BRG_PCM_CFG, (0x0 << 6) | 0x3); */ /* was _io before */ HFC_outb_nodebug(hc, R_BRG_PCM_CFG, 1 | V_PCM_CLK); outw(0x4000, hc->pci_iobase + 4); outl(leddw, hc->pci_iobase); HFC_outb_nodebug(hc, R_BRG_PCM_CFG, V_PCM_CLK); hc->ledstate = leddw; } break; } hc->activity_tx = 0; hc->activity_rx = 0; } /* * read dtmf coefficients */ static void hfcmulti_dtmf(struct hfc_multi *hc) { s32 *coeff; u_int mantissa; int co, ch; struct bchannel *bch = NULL; u8 exponent; int dtmf = 0; int addr; u16 w_float; struct sk_buff *skb; struct mISDNhead *hh; if (debug & DEBUG_HFCMULTI_DTMF) printk(KERN_DEBUG "%s: dtmf detection irq\n", __func__); for (ch = 0; ch <= 31; ch++) { /* only process enabled B-channels */ bch = hc->chan[ch].bch; if (!bch) continue; if (!hc->created[hc->chan[ch].port]) continue; if (!test_bit(FLG_TRANSPARENT, &bch->Flags)) continue; if (debug & DEBUG_HFCMULTI_DTMF) printk(KERN_DEBUG "%s: dtmf channel %d:", __func__, ch); coeff = &(hc->chan[ch].coeff[hc->chan[ch].coeff_count * 16]); dtmf = 1; for (co = 0; co < 8; co++) { /* read W(n-1) coefficient */ addr = hc->DTMFbase + ((co << 7) | (ch << 2)); HFC_outb_nodebug(hc, R_RAM_ADDR0, addr); HFC_outb_nodebug(hc, R_RAM_ADDR1, addr >> 8); HFC_outb_nodebug(hc, R_RAM_ADDR2, (addr >> 16) | V_ADDR_INC); w_float = HFC_inb_nodebug(hc, R_RAM_DATA); w_float |= (HFC_inb_nodebug(hc, R_RAM_DATA) << 8); if (debug & DEBUG_HFCMULTI_DTMF) printk(" %04x", w_float); /* decode float (see chip doc) */ mantissa = w_float & 0x0fff; if (w_float & 0x8000) mantissa |= 0xfffff000; exponent = (w_float >> 12) & 0x7; if (exponent) { mantissa ^= 0x1000; mantissa <<= (exponent - 1); } /* store coefficient */ coeff[co << 1] = mantissa; /* read W(n) coefficient */ w_float = HFC_inb_nodebug(hc, R_RAM_DATA); w_float |= (HFC_inb_nodebug(hc, R_RAM_DATA) << 8); if (debug & DEBUG_HFCMULTI_DTMF) printk(" %04x", w_float); /* decode float (see chip doc) */ mantissa = w_float & 0x0fff; if (w_float & 0x8000) mantissa |= 0xfffff000; exponent = (w_float >> 12) & 0x7; if (exponent) { mantissa ^= 0x1000; mantissa <<= (exponent - 1); } /* store coefficient */ coeff[(co << 1) | 1] = mantissa; } if (debug & DEBUG_HFCMULTI_DTMF) printk(" DTMF ready %08x %08x %08x %08x " "%08x %08x %08x %08x\n", coeff[0], coeff[1], coeff[2], coeff[3], coeff[4], coeff[5], coeff[6], coeff[7]); hc->chan[ch].coeff_count++; if (hc->chan[ch].coeff_count == 8) { hc->chan[ch].coeff_count = 0; skb = mI_alloc_skb(512, GFP_ATOMIC); if (!skb) { printk(KERN_DEBUG "%s: No memory for skb\n", __func__); continue; } hh = mISDN_HEAD_P(skb); hh->prim = PH_CONTROL_IND; hh->id = DTMF_HFC_COEF; skb_put_data(skb, hc->chan[ch].coeff, 512); recv_Bchannel_skb(bch, skb); } } /* restart DTMF processing */ hc->dtmf = dtmf; if (dtmf) HFC_outb_nodebug(hc, R_DTMF, hc->hw.r_dtmf | V_RST_DTMF); } /* * fill fifo as much as possible */ static void hfcmulti_tx(struct hfc_multi *hc, int ch) { int i, ii, temp, len = 0; int Zspace, z1, z2; /* must be int for calculation */ int Fspace, f1, f2; u_char *d; int *txpending, slot_tx; struct bchannel *bch; struct dchannel *dch; struct sk_buff **sp = NULL; int *idxp; bch = hc->chan[ch].bch; dch = hc->chan[ch].dch; if ((!dch) && (!bch)) return; txpending = &hc->chan[ch].txpending; slot_tx = hc->chan[ch].slot_tx; if (dch) { if (!test_bit(FLG_ACTIVE, &dch->Flags)) return; sp = &dch->tx_skb; idxp = &dch->tx_idx; } else { if (!test_bit(FLG_ACTIVE, &bch->Flags)) return; sp = &bch->tx_skb; idxp = &bch->tx_idx; } if (*sp) len = (*sp)->len; if ((!len) && *txpending != 1) return; /* no data */ if (test_bit(HFC_CHIP_B410P, &hc->chip) && (hc->chan[ch].protocol == ISDN_P_B_RAW) && (hc->chan[ch].slot_rx < 0) && (hc->chan[ch].slot_tx < 0)) HFC_outb_nodebug(hc, R_FIFO, 0x20 | (ch << 1)); else HFC_outb_nodebug(hc, R_FIFO, ch << 1); HFC_wait_nodebug(hc); if (*txpending == 2) { /* reset fifo */ HFC_outb_nodebug(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait_nodebug(hc); HFC_outb(hc, A_SUBCH_CFG, 0); *txpending = 1; } next_frame: if (dch || test_bit(FLG_HDLC, &bch->Flags)) { f1 = HFC_inb_nodebug(hc, A_F1); f2 = HFC_inb_nodebug(hc, A_F2); while (f2 != (temp = HFC_inb_nodebug(hc, A_F2))) { if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): reread f2 because %d!=%d\n", __func__, hc->id + 1, temp, f2); f2 = temp; /* repeat until F2 is equal */ } Fspace = f2 - f1 - 1; if (Fspace < 0) Fspace += hc->Flen; /* * Old FIFO handling doesn't give us the current Z2 read * pointer, so we cannot send the next frame before the fifo * is empty. It makes no difference except for a slightly * lower performance. */ if (test_bit(HFC_CHIP_REVISION0, &hc->chip)) { if (f1 != f2) Fspace = 0; else Fspace = 1; } /* one frame only for ST D-channels, to allow resending */ if (hc->ctype != HFC_TYPE_E1 && dch) { if (f1 != f2) Fspace = 0; } /* F-counter full condition */ if (Fspace == 0) return; } z1 = HFC_inw_nodebug(hc, A_Z1) - hc->Zmin; z2 = HFC_inw_nodebug(hc, A_Z2) - hc->Zmin; while (z2 != (temp = (HFC_inw_nodebug(hc, A_Z2) - hc->Zmin))) { if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): reread z2 because " "%d!=%d\n", __func__, hc->id + 1, temp, z2); z2 = temp; /* repeat unti Z2 is equal */ } hc->chan[ch].Zfill = z1 - z2; if (hc->chan[ch].Zfill < 0) hc->chan[ch].Zfill += hc->Zlen; Zspace = z2 - z1; if (Zspace <= 0) Zspace += hc->Zlen; Zspace -= 4; /* keep not too full, so pointers will not overrun */ /* fill transparent data only to maxinum transparent load (minus 4) */ if (bch && test_bit(FLG_TRANSPARENT, &bch->Flags)) Zspace = Zspace - hc->Zlen + hc->max_trans; if (Zspace <= 0) /* no space of 4 bytes */ return; /* if no data */ if (!len) { if (z1 == z2) { /* empty */ /* if done with FIFO audio data during PCM connection */ if (bch && (!test_bit(FLG_HDLC, &bch->Flags)) && *txpending && slot_tx >= 0) { if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: reconnecting PCM due to no " "more FIFO data: channel %d " "slot_tx %d\n", __func__, ch, slot_tx); /* connect slot */ if (hc->ctype == HFC_TYPE_XHFC) HFC_outb(hc, A_CON_HDLC, 0xc0 | 0x07 << 2 | V_HDLC_TRP | V_IFF); /* Enable FIFO, no interrupt */ else HFC_outb(hc, A_CON_HDLC, 0xc0 | 0x00 | V_HDLC_TRP | V_IFF); HFC_outb_nodebug(hc, R_FIFO, ch << 1 | 1); HFC_wait_nodebug(hc); if (hc->ctype == HFC_TYPE_XHFC) HFC_outb(hc, A_CON_HDLC, 0xc0 | 0x07 << 2 | V_HDLC_TRP | V_IFF); /* Enable FIFO, no interrupt */ else HFC_outb(hc, A_CON_HDLC, 0xc0 | 0x00 | V_HDLC_TRP | V_IFF); HFC_outb_nodebug(hc, R_FIFO, ch << 1); HFC_wait_nodebug(hc); } *txpending = 0; } return; /* no data */ } /* "fill fifo if empty" feature */ if (bch && test_bit(FLG_FILLEMPTY, &bch->Flags) && !test_bit(FLG_HDLC, &bch->Flags) && z2 == z1) { if (debug & DEBUG_HFCMULTI_FILL) printk(KERN_DEBUG "%s: buffer empty, so we have " "underrun\n", __func__); /* fill buffer, to prevent future underrun */ hc->write_fifo(hc, hc->silence_data, poll >> 1); Zspace -= (poll >> 1); } /* if audio data and connected slot */ if (bch && (!test_bit(FLG_HDLC, &bch->Flags)) && (!*txpending) && slot_tx >= 0) { if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: disconnecting PCM due to " "FIFO data: channel %d slot_tx %d\n", __func__, ch, slot_tx); /* disconnect slot */ if (hc->ctype == HFC_TYPE_XHFC) HFC_outb(hc, A_CON_HDLC, 0x80 | 0x07 << 2 | V_HDLC_TRP | V_IFF); /* Enable FIFO, no interrupt */ else HFC_outb(hc, A_CON_HDLC, 0x80 | 0x00 | V_HDLC_TRP | V_IFF); HFC_outb_nodebug(hc, R_FIFO, ch << 1 | 1); HFC_wait_nodebug(hc); if (hc->ctype == HFC_TYPE_XHFC) HFC_outb(hc, A_CON_HDLC, 0x80 | 0x07 << 2 | V_HDLC_TRP | V_IFF); /* Enable FIFO, no interrupt */ else HFC_outb(hc, A_CON_HDLC, 0x80 | 0x00 | V_HDLC_TRP | V_IFF); HFC_outb_nodebug(hc, R_FIFO, ch << 1); HFC_wait_nodebug(hc); } *txpending = 1; /* show activity */ if (dch) hc->activity_tx |= 1 << hc->chan[ch].port; /* fill fifo to what we have left */ ii = len; if (dch || test_bit(FLG_HDLC, &bch->Flags)) temp = 1; else temp = 0; i = *idxp; d = (*sp)->data + i; if (ii - i > Zspace) ii = Zspace + i; if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): fifo(%d) has %d bytes space " "left (z1=%04x, z2=%04x) sending %d of %d bytes %s\n", __func__, hc->id + 1, ch, Zspace, z1, z2, ii-i, len-i, temp ? "HDLC" : "TRANS"); /* Have to prep the audio data */ hc->write_fifo(hc, d, ii - i); hc->chan[ch].Zfill += ii - i; *idxp = ii; /* if not all data has been written */ if (ii != len) { /* NOTE: fifo is started by the calling function */ return; } /* if all data has been written, terminate frame */ if (dch || test_bit(FLG_HDLC, &bch->Flags)) { /* increment f-counter */ HFC_outb_nodebug(hc, R_INC_RES_FIFO, V_INC_F); HFC_wait_nodebug(hc); } dev_kfree_skb(*sp); /* check for next frame */ if (bch && get_next_bframe(bch)) { len = (*sp)->len; goto next_frame; } if (dch && get_next_dframe(dch)) { len = (*sp)->len; goto next_frame; } /* * now we have no more data, so in case of transparent, * we set the last byte in fifo to 'silence' in case we will get * no more data at all. this prevents sending an undefined value. */ if (bch && test_bit(FLG_TRANSPARENT, &bch->Flags)) HFC_outb_nodebug(hc, A_FIFO_DATA0_NOINC, hc->silence); } /* NOTE: only called if E1 card is in active state */ static void hfcmulti_rx(struct hfc_multi *hc, int ch) { int temp; int Zsize, z1, z2 = 0; /* = 0, to make GCC happy */ int f1 = 0, f2 = 0; /* = 0, to make GCC happy */ int again = 0; struct bchannel *bch; struct dchannel *dch = NULL; struct sk_buff *skb, **sp = NULL; int maxlen; bch = hc->chan[ch].bch; if (bch) { if (!test_bit(FLG_ACTIVE, &bch->Flags)) return; } else if (hc->chan[ch].dch) { dch = hc->chan[ch].dch; if (!test_bit(FLG_ACTIVE, &dch->Flags)) return; } else { return; } next_frame: /* on first AND before getting next valid frame, R_FIFO must be written to. */ if (test_bit(HFC_CHIP_B410P, &hc->chip) && (hc->chan[ch].protocol == ISDN_P_B_RAW) && (hc->chan[ch].slot_rx < 0) && (hc->chan[ch].slot_tx < 0)) HFC_outb_nodebug(hc, R_FIFO, 0x20 | (ch << 1) | 1); else HFC_outb_nodebug(hc, R_FIFO, (ch << 1) | 1); HFC_wait_nodebug(hc); /* ignore if rx is off BUT change fifo (above) to start pending TX */ if (hc->chan[ch].rx_off) { if (bch) bch->dropcnt += poll; /* not exact but fair enough */ return; } if (dch || test_bit(FLG_HDLC, &bch->Flags)) { f1 = HFC_inb_nodebug(hc, A_F1); while (f1 != (temp = HFC_inb_nodebug(hc, A_F1))) { if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): reread f1 because %d!=%d\n", __func__, hc->id + 1, temp, f1); f1 = temp; /* repeat until F1 is equal */ } f2 = HFC_inb_nodebug(hc, A_F2); } z1 = HFC_inw_nodebug(hc, A_Z1) - hc->Zmin; while (z1 != (temp = (HFC_inw_nodebug(hc, A_Z1) - hc->Zmin))) { if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): reread z2 because " "%d!=%d\n", __func__, hc->id + 1, temp, z2); z1 = temp; /* repeat until Z1 is equal */ } z2 = HFC_inw_nodebug(hc, A_Z2) - hc->Zmin; Zsize = z1 - z2; if ((dch || test_bit(FLG_HDLC, &bch->Flags)) && f1 != f2) /* complete hdlc frame */ Zsize++; if (Zsize < 0) Zsize += hc->Zlen; /* if buffer is empty */ if (Zsize <= 0) return; if (bch) { maxlen = bchannel_get_rxbuf(bch, Zsize); if (maxlen < 0) { pr_warn("card%d.B%d: No bufferspace for %d bytes\n", hc->id + 1, bch->nr, Zsize); return; } sp = &bch->rx_skb; maxlen = bch->maxlen; } else { /* Dchannel */ sp = &dch->rx_skb; maxlen = dch->maxlen + 3; if (*sp == NULL) { *sp = mI_alloc_skb(maxlen, GFP_ATOMIC); if (*sp == NULL) { pr_warn("card%d: No mem for dch rx_skb\n", hc->id + 1); return; } } } /* show activity */ if (dch) hc->activity_rx |= 1 << hc->chan[ch].port; /* empty fifo with what we have */ if (dch || test_bit(FLG_HDLC, &bch->Flags)) { if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): fifo(%d) reading %d " "bytes (z1=%04x, z2=%04x) HDLC %s (f1=%d, f2=%d) " "got=%d (again %d)\n", __func__, hc->id + 1, ch, Zsize, z1, z2, (f1 == f2) ? "fragment" : "COMPLETE", f1, f2, Zsize + (*sp)->len, again); /* HDLC */ if ((Zsize + (*sp)->len) > maxlen) { if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): hdlc-frame too large.\n", __func__, hc->id + 1); skb_trim(*sp, 0); HFC_outb_nodebug(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait_nodebug(hc); return; } hc->read_fifo(hc, skb_put(*sp, Zsize), Zsize); if (f1 != f2) { /* increment Z2,F2-counter */ HFC_outb_nodebug(hc, R_INC_RES_FIFO, V_INC_F); HFC_wait_nodebug(hc); /* check size */ if ((*sp)->len < 4) { if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): Frame below minimum " "size\n", __func__, hc->id + 1); skb_trim(*sp, 0); goto next_frame; } /* there is at least one complete frame, check crc */ if ((*sp)->data[(*sp)->len - 1]) { if (debug & DEBUG_HFCMULTI_CRC) printk(KERN_DEBUG "%s: CRC-error\n", __func__); skb_trim(*sp, 0); goto next_frame; } skb_trim(*sp, (*sp)->len - 3); if ((*sp)->len < MISDN_COPY_SIZE) { skb = *sp; *sp = mI_alloc_skb(skb->len, GFP_ATOMIC); if (*sp) { skb_put_data(*sp, skb->data, skb->len); skb_trim(skb, 0); } else { printk(KERN_DEBUG "%s: No mem\n", __func__); *sp = skb; skb = NULL; } } else { skb = NULL; } if (debug & DEBUG_HFCMULTI_FIFO) { printk(KERN_DEBUG "%s(card %d):", __func__, hc->id + 1); temp = 0; while (temp < (*sp)->len) printk(" %02x", (*sp)->data[temp++]); printk("\n"); } if (dch) recv_Dchannel(dch); else recv_Bchannel(bch, MISDN_ID_ANY, false); *sp = skb; again++; goto next_frame; } /* there is an incomplete frame */ } else { /* transparent */ hc->read_fifo(hc, skb_put(*sp, Zsize), Zsize); if (debug & DEBUG_HFCMULTI_FIFO) printk(KERN_DEBUG "%s(card %d): fifo(%d) reading %d bytes " "(z1=%04x, z2=%04x) TRANS\n", __func__, hc->id + 1, ch, Zsize, z1, z2); /* only bch is transparent */ recv_Bchannel(bch, hc->chan[ch].Zfill, false); } } /* * Interrupt handler */ static void signal_state_up(struct dchannel *dch, int info, char *msg) { struct sk_buff *skb; int id, data = info; if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: %s\n", __func__, msg); id = TEI_SAPI | (GROUP_TEI << 8); /* manager address */ skb = _alloc_mISDN_skb(MPH_INFORMATION_IND, id, sizeof(data), &data, GFP_ATOMIC); if (!skb) return; recv_Dchannel_skb(dch, skb); } static inline void handle_timer_irq(struct hfc_multi *hc) { int ch, temp; struct dchannel *dch; u_long flags; /* process queued resync jobs */ if (hc->e1_resync) { /* lock, so e1_resync gets not changed */ spin_lock_irqsave(&HFClock, flags); if (hc->e1_resync & 1) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "Enable SYNC_I\n"); HFC_outb(hc, R_SYNC_CTRL, V_EXT_CLK_SYNC); /* disable JATT, if RX_SYNC is set */ if (test_bit(HFC_CHIP_RX_SYNC, &hc->chip)) HFC_outb(hc, R_SYNC_OUT, V_SYNC_E1_RX); } if (hc->e1_resync & 2) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "Enable jatt PLL\n"); HFC_outb(hc, R_SYNC_CTRL, V_SYNC_OFFS); } if (hc->e1_resync & 4) { if (debug & DEBUG_HFCMULTI_PLXSD) printk(KERN_DEBUG "Enable QUARTZ for HFC-E1\n"); /* set jatt to quartz */ HFC_outb(hc, R_SYNC_CTRL, V_EXT_CLK_SYNC | V_JATT_OFF); /* switch to JATT, in case it is not already */ HFC_outb(hc, R_SYNC_OUT, 0); } hc->e1_resync = 0; spin_unlock_irqrestore(&HFClock, flags); } if (hc->ctype != HFC_TYPE_E1 || hc->e1_state == 1) for (ch = 0; ch <= 31; ch++) { if (hc->created[hc->chan[ch].port]) { hfcmulti_tx(hc, ch); /* fifo is started when switching to rx-fifo */ hfcmulti_rx(hc, ch); if (hc->chan[ch].dch && hc->chan[ch].nt_timer > -1) { dch = hc->chan[ch].dch; if (!(--hc->chan[ch].nt_timer)) { schedule_event(dch, FLG_PHCHANGE); if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: nt_timer at " "state %x\n", __func__, dch->state); } } } } if (hc->ctype == HFC_TYPE_E1 && hc->created[0]) { dch = hc->chan[hc->dnum[0]].dch; /* LOS */ temp = HFC_inb_nodebug(hc, R_SYNC_STA) & V_SIG_LOS; hc->chan[hc->dnum[0]].los = temp; if (test_bit(HFC_CFG_REPORT_LOS, &hc->chan[hc->dnum[0]].cfg)) { if (!temp && hc->chan[hc->dnum[0]].los) signal_state_up(dch, L1_SIGNAL_LOS_ON, "LOS detected"); if (temp && !hc->chan[hc->dnum[0]].los) signal_state_up(dch, L1_SIGNAL_LOS_OFF, "LOS gone"); } if (test_bit(HFC_CFG_REPORT_AIS, &hc->chan[hc->dnum[0]].cfg)) { /* AIS */ temp = HFC_inb_nodebug(hc, R_SYNC_STA) & V_AIS; if (!temp && hc->chan[hc->dnum[0]].ais) signal_state_up(dch, L1_SIGNAL_AIS_ON, "AIS detected"); if (temp && !hc->chan[hc->dnum[0]].ais) signal_state_up(dch, L1_SIGNAL_AIS_OFF, "AIS gone"); hc->chan[hc->dnum[0]].ais = temp; } if (test_bit(HFC_CFG_REPORT_SLIP, &hc->chan[hc->dnum[0]].cfg)) { /* SLIP */ temp = HFC_inb_nodebug(hc, R_SLIP) & V_FOSLIP_RX; if (!temp && hc->chan[hc->dnum[0]].slip_rx) signal_state_up(dch, L1_SIGNAL_SLIP_RX, " bit SLIP detected RX"); hc->chan[hc->dnum[0]].slip_rx = temp; temp = HFC_inb_nodebug(hc, R_SLIP) & V_FOSLIP_TX; if (!temp && hc->chan[hc->dnum[0]].slip_tx) signal_state_up(dch, L1_SIGNAL_SLIP_TX, " bit SLIP detected TX"); hc->chan[hc->dnum[0]].slip_tx = temp; } if (test_bit(HFC_CFG_REPORT_RDI, &hc->chan[hc->dnum[0]].cfg)) { /* RDI */ temp = HFC_inb_nodebug(hc, R_RX_SL0_0) & V_A; if (!temp && hc->chan[hc->dnum[0]].rdi) signal_state_up(dch, L1_SIGNAL_RDI_ON, "RDI detected"); if (temp && !hc->chan[hc->dnum[0]].rdi) signal_state_up(dch, L1_SIGNAL_RDI_OFF, "RDI gone"); hc->chan[hc->dnum[0]].rdi = temp; } temp = HFC_inb_nodebug(hc, R_JATT_DIR); switch (hc->chan[hc->dnum[0]].sync) { case 0: if ((temp & 0x60) == 0x60) { if (debug & DEBUG_HFCMULTI_SYNC) printk(KERN_DEBUG "%s: (id=%d) E1 now " "in clock sync\n", __func__, hc->id); HFC_outb(hc, R_RX_OFF, hc->chan[hc->dnum[0]].jitter | V_RX_INIT); HFC_outb(hc, R_TX_OFF, hc->chan[hc->dnum[0]].jitter | V_RX_INIT); hc->chan[hc->dnum[0]].sync = 1; goto check_framesync; } break; case 1: if ((temp & 0x60) != 0x60) { if (debug & DEBUG_HFCMULTI_SYNC) printk(KERN_DEBUG "%s: (id=%d) E1 " "lost clock sync\n", __func__, hc->id); hc->chan[hc->dnum[0]].sync = 0; break; } check_framesync: temp = HFC_inb_nodebug(hc, R_SYNC_STA); if (temp == 0x27) { if (debug & DEBUG_HFCMULTI_SYNC) printk(KERN_DEBUG "%s: (id=%d) E1 " "now in frame sync\n", __func__, hc->id); hc->chan[hc->dnum[0]].sync = 2; } break; case 2: if ((temp & 0x60) != 0x60) { if (debug & DEBUG_HFCMULTI_SYNC) printk(KERN_DEBUG "%s: (id=%d) E1 lost " "clock & frame sync\n", __func__, hc->id); hc->chan[hc->dnum[0]].sync = 0; break; } temp = HFC_inb_nodebug(hc, R_SYNC_STA); if (temp != 0x27) { if (debug & DEBUG_HFCMULTI_SYNC) printk(KERN_DEBUG "%s: (id=%d) E1 " "lost frame sync\n", __func__, hc->id); hc->chan[hc->dnum[0]].sync = 1; } break; } } if (test_bit(HFC_CHIP_WATCHDOG, &hc->chip)) hfcmulti_watchdog(hc); if (hc->leds) hfcmulti_leds(hc); } static void ph_state_irq(struct hfc_multi *hc, u_char r_irq_statech) { struct dchannel *dch; int ch; int active; u_char st_status, temp; /* state machine */ for (ch = 0; ch <= 31; ch++) { if (hc->chan[ch].dch) { dch = hc->chan[ch].dch; if (r_irq_statech & 1) { HFC_outb_nodebug(hc, R_ST_SEL, hc->chan[ch].port); /* undocumented: delay after R_ST_SEL */ udelay(1); /* undocumented: status changes during read */ st_status = HFC_inb_nodebug(hc, A_ST_RD_STATE); while (st_status != (temp = HFC_inb_nodebug(hc, A_ST_RD_STATE))) { if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: reread " "STATE because %d!=%d\n", __func__, temp, st_status); st_status = temp; /* repeat */ } /* Speech Design TE-sync indication */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip) && dch->dev.D.protocol == ISDN_P_TE_S0) { if (st_status & V_FR_SYNC_ST) hc->syncronized |= (1 << hc->chan[ch].port); else hc->syncronized &= ~(1 << hc->chan[ch].port); } dch->state = st_status & 0x0f; if (dch->dev.D.protocol == ISDN_P_NT_S0) active = 3; else active = 7; if (dch->state == active) { HFC_outb_nodebug(hc, R_FIFO, (ch << 1) | 1); HFC_wait_nodebug(hc); HFC_outb_nodebug(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait_nodebug(hc); dch->tx_idx = 0; } schedule_event(dch, FLG_PHCHANGE); if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: S/T newstate %x port %d\n", __func__, dch->state, hc->chan[ch].port); } r_irq_statech >>= 1; } } if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) plxsd_checksync(hc, 0); } static void fifo_irq(struct hfc_multi *hc, int block) { int ch, j; struct dchannel *dch; struct bchannel *bch; u_char r_irq_fifo_bl; r_irq_fifo_bl = HFC_inb_nodebug(hc, R_IRQ_FIFO_BL0 + block); j = 0; while (j < 8) { ch = (block << 2) + (j >> 1); dch = hc->chan[ch].dch; bch = hc->chan[ch].bch; if (((!dch) && (!bch)) || (!hc->created[hc->chan[ch].port])) { j += 2; continue; } if (dch && (r_irq_fifo_bl & (1 << j)) && test_bit(FLG_ACTIVE, &dch->Flags)) { hfcmulti_tx(hc, ch); /* start fifo */ HFC_outb_nodebug(hc, R_FIFO, 0); HFC_wait_nodebug(hc); } if (bch && (r_irq_fifo_bl & (1 << j)) && test_bit(FLG_ACTIVE, &bch->Flags)) { hfcmulti_tx(hc, ch); /* start fifo */ HFC_outb_nodebug(hc, R_FIFO, 0); HFC_wait_nodebug(hc); } j++; if (dch && (r_irq_fifo_bl & (1 << j)) && test_bit(FLG_ACTIVE, &dch->Flags)) { hfcmulti_rx(hc, ch); } if (bch && (r_irq_fifo_bl & (1 << j)) && test_bit(FLG_ACTIVE, &bch->Flags)) { hfcmulti_rx(hc, ch); } j++; } } #ifdef IRQ_DEBUG int irqsem; #endif static irqreturn_t hfcmulti_interrupt(int intno, void *dev_id) { #ifdef IRQCOUNT_DEBUG static int iq1 = 0, iq2 = 0, iq3 = 0, iq4 = 0, iq5 = 0, iq6 = 0, iqcnt = 0; #endif struct hfc_multi *hc = dev_id; struct dchannel *dch; u_char r_irq_statech, status, r_irq_misc, r_irq_oview; int i; void __iomem *plx_acc; u_short wval; u_char e1_syncsta, temp, temp2; u_long flags; if (!hc) { printk(KERN_ERR "HFC-multi: Spurious interrupt!\n"); return IRQ_NONE; } spin_lock(&hc->lock); #ifdef IRQ_DEBUG if (irqsem) printk(KERN_ERR "irq for card %d during irq from " "card %d, this is no bug.\n", hc->id + 1, irqsem); irqsem = hc->id + 1; #endif #ifdef CONFIG_MISDN_HFCMULTI_8xx if (hc->immap->im_cpm.cp_pbdat & hc->pb_irqmsk) goto irq_notforus; #endif if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { spin_lock_irqsave(&plx_lock, flags); plx_acc = hc->plx_membase + PLX_INTCSR; wval = readw(plx_acc); spin_unlock_irqrestore(&plx_lock, flags); if (!(wval & PLX_INTCSR_LINTI1_STATUS)) goto irq_notforus; } status = HFC_inb_nodebug(hc, R_STATUS); r_irq_statech = HFC_inb_nodebug(hc, R_IRQ_STATECH); #ifdef IRQCOUNT_DEBUG if (r_irq_statech) iq1++; if (status & V_DTMF_STA) iq2++; if (status & V_LOST_STA) iq3++; if (status & V_EXT_IRQSTA) iq4++; if (status & V_MISC_IRQSTA) iq5++; if (status & V_FR_IRQSTA) iq6++; if (iqcnt++ > 5000) { printk(KERN_ERR "iq1:%x iq2:%x iq3:%x iq4:%x iq5:%x iq6:%x\n", iq1, iq2, iq3, iq4, iq5, iq6); iqcnt = 0; } #endif if (!r_irq_statech && !(status & (V_DTMF_STA | V_LOST_STA | V_EXT_IRQSTA | V_MISC_IRQSTA | V_FR_IRQSTA))) { /* irq is not for us */ goto irq_notforus; } hc->irqcnt++; if (r_irq_statech) { if (hc->ctype != HFC_TYPE_E1) ph_state_irq(hc, r_irq_statech); } if (status & V_EXT_IRQSTA) ; /* external IRQ */ if (status & V_LOST_STA) { /* LOST IRQ */ HFC_outb(hc, R_INC_RES_FIFO, V_RES_LOST); /* clear irq! */ } if (status & V_MISC_IRQSTA) { /* misc IRQ */ r_irq_misc = HFC_inb_nodebug(hc, R_IRQ_MISC); r_irq_misc &= hc->hw.r_irqmsk_misc; /* ignore disabled irqs */ if (r_irq_misc & V_STA_IRQ) { if (hc->ctype == HFC_TYPE_E1) { /* state machine */ dch = hc->chan[hc->dnum[0]].dch; e1_syncsta = HFC_inb_nodebug(hc, R_SYNC_STA); if (test_bit(HFC_CHIP_PLXSD, &hc->chip) && hc->e1_getclock) { if (e1_syncsta & V_FR_SYNC_E1) hc->syncronized = 1; else hc->syncronized = 0; } /* undocumented: status changes during read */ temp = HFC_inb_nodebug(hc, R_E1_RD_STA); while (temp != (temp2 = HFC_inb_nodebug(hc, R_E1_RD_STA))) { if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: reread " "STATE because %d!=%d\n", __func__, temp, temp2); temp = temp2; /* repeat */ } /* broadcast state change to all fragments */ if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: E1 (id=%d) newstate %x\n", __func__, hc->id, temp & 0x7); for (i = 0; i < hc->ports; i++) { dch = hc->chan[hc->dnum[i]].dch; dch->state = temp & 0x7; schedule_event(dch, FLG_PHCHANGE); } if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) plxsd_checksync(hc, 0); } } if (r_irq_misc & V_TI_IRQ) { if (hc->iclock_on) mISDN_clock_update(hc->iclock, poll, NULL); handle_timer_irq(hc); } if (r_irq_misc & V_DTMF_IRQ) hfcmulti_dtmf(hc); if (r_irq_misc & V_IRQ_PROC) { static int irq_proc_cnt; if (!irq_proc_cnt++) printk(KERN_DEBUG "%s: got V_IRQ_PROC -" " this should not happen\n", __func__); } } if (status & V_FR_IRQSTA) { /* FIFO IRQ */ r_irq_oview = HFC_inb_nodebug(hc, R_IRQ_OVIEW); for (i = 0; i < 8; i++) { if (r_irq_oview & (1 << i)) fifo_irq(hc, i); } } #ifdef IRQ_DEBUG irqsem = 0; #endif spin_unlock(&hc->lock); return IRQ_HANDLED; irq_notforus: #ifdef IRQ_DEBUG irqsem = 0; #endif spin_unlock(&hc->lock); return IRQ_NONE; } /* * timer callback for D-chan busy resolution. Currently no function */ static void hfcmulti_dbusy_timer(struct timer_list *t) { } /* * activate/deactivate hardware for selected channels and mode * * configure B-channel with the given protocol * ch eqals to the HFC-channel (0-31) * ch is the number of channel (0-4,4-7,8-11,12-15,16-19,20-23,24-27,28-31 * for S/T, 1-31 for E1) * the hdlc interrupts will be set/unset */ static int mode_hfcmulti(struct hfc_multi *hc, int ch, int protocol, int slot_tx, int bank_tx, int slot_rx, int bank_rx) { int flow_tx = 0, flow_rx = 0, routing = 0; int oslot_tx, oslot_rx; int conf; if (ch < 0 || ch > 31) return -EINVAL; oslot_tx = hc->chan[ch].slot_tx; oslot_rx = hc->chan[ch].slot_rx; conf = hc->chan[ch].conf; if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: card %d channel %d protocol %x slot old=%d new=%d " "bank new=%d (TX) slot old=%d new=%d bank new=%d (RX)\n", __func__, hc->id, ch, protocol, oslot_tx, slot_tx, bank_tx, oslot_rx, slot_rx, bank_rx); if (oslot_tx >= 0 && slot_tx != oslot_tx) { /* remove from slot */ if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: remove from slot %d (TX)\n", __func__, oslot_tx); if (hc->slot_owner[oslot_tx << 1] == ch) { HFC_outb(hc, R_SLOT, oslot_tx << 1); HFC_outb(hc, A_SL_CFG, 0); if (hc->ctype != HFC_TYPE_XHFC) HFC_outb(hc, A_CONF, 0); hc->slot_owner[oslot_tx << 1] = -1; } else { if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: we are not owner of this tx slot " "anymore, channel %d is.\n", __func__, hc->slot_owner[oslot_tx << 1]); } } if (oslot_rx >= 0 && slot_rx != oslot_rx) { /* remove from slot */ if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: remove from slot %d (RX)\n", __func__, oslot_rx); if (hc->slot_owner[(oslot_rx << 1) | 1] == ch) { HFC_outb(hc, R_SLOT, (oslot_rx << 1) | V_SL_DIR); HFC_outb(hc, A_SL_CFG, 0); hc->slot_owner[(oslot_rx << 1) | 1] = -1; } else { if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: we are not owner of this rx slot " "anymore, channel %d is.\n", __func__, hc->slot_owner[(oslot_rx << 1) | 1]); } } if (slot_tx < 0) { flow_tx = 0x80; /* FIFO->ST */ /* disable pcm slot */ hc->chan[ch].slot_tx = -1; hc->chan[ch].bank_tx = 0; } else { /* set pcm slot */ if (hc->chan[ch].txpending) flow_tx = 0x80; /* FIFO->ST */ else flow_tx = 0xc0; /* PCM->ST */ /* put on slot */ routing = bank_tx ? 0xc0 : 0x80; if (conf >= 0 || bank_tx > 1) routing = 0x40; /* loop */ if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: put channel %d to slot %d bank" " %d flow %02x routing %02x conf %d (TX)\n", __func__, ch, slot_tx, bank_tx, flow_tx, routing, conf); HFC_outb(hc, R_SLOT, slot_tx << 1); HFC_outb(hc, A_SL_CFG, (ch << 1) | routing); if (hc->ctype != HFC_TYPE_XHFC) HFC_outb(hc, A_CONF, (conf < 0) ? 0 : (conf | V_CONF_SL)); hc->slot_owner[slot_tx << 1] = ch; hc->chan[ch].slot_tx = slot_tx; hc->chan[ch].bank_tx = bank_tx; } if (slot_rx < 0) { /* disable pcm slot */ flow_rx = 0x80; /* ST->FIFO */ hc->chan[ch].slot_rx = -1; hc->chan[ch].bank_rx = 0; } else { /* set pcm slot */ if (hc->chan[ch].txpending) flow_rx = 0x80; /* ST->FIFO */ else flow_rx = 0xc0; /* ST->(FIFO,PCM) */ /* put on slot */ routing = bank_rx ? 0x80 : 0xc0; /* reversed */ if (conf >= 0 || bank_rx > 1) routing = 0x40; /* loop */ if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: put channel %d to slot %d bank" " %d flow %02x routing %02x conf %d (RX)\n", __func__, ch, slot_rx, bank_rx, flow_rx, routing, conf); HFC_outb(hc, R_SLOT, (slot_rx << 1) | V_SL_DIR); HFC_outb(hc, A_SL_CFG, (ch << 1) | V_CH_DIR | routing); hc->slot_owner[(slot_rx << 1) | 1] = ch; hc->chan[ch].slot_rx = slot_rx; hc->chan[ch].bank_rx = bank_rx; } switch (protocol) { case (ISDN_P_NONE): /* disable TX fifo */ HFC_outb(hc, R_FIFO, ch << 1); HFC_wait(hc); HFC_outb(hc, A_CON_HDLC, flow_tx | 0x00 | V_IFF); HFC_outb(hc, A_SUBCH_CFG, 0); HFC_outb(hc, A_IRQ_MSK, 0); HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); /* disable RX fifo */ HFC_outb(hc, R_FIFO, (ch << 1) | 1); HFC_wait(hc); HFC_outb(hc, A_CON_HDLC, flow_rx | 0x00); HFC_outb(hc, A_SUBCH_CFG, 0); HFC_outb(hc, A_IRQ_MSK, 0); HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); if (hc->chan[ch].bch && hc->ctype != HFC_TYPE_E1) { hc->hw.a_st_ctrl0[hc->chan[ch].port] &= ((ch & 0x3) == 0) ? ~V_B1_EN : ~V_B2_EN; HFC_outb(hc, R_ST_SEL, hc->chan[ch].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_CTRL0, hc->hw.a_st_ctrl0[hc->chan[ch].port]); } if (hc->chan[ch].bch) { test_and_clear_bit(FLG_HDLC, &hc->chan[ch].bch->Flags); test_and_clear_bit(FLG_TRANSPARENT, &hc->chan[ch].bch->Flags); } break; case (ISDN_P_B_RAW): /* B-channel */ if (test_bit(HFC_CHIP_B410P, &hc->chip) && (hc->chan[ch].slot_rx < 0) && (hc->chan[ch].slot_tx < 0)) { printk(KERN_DEBUG "Setting B-channel %d to echo cancelable " "state on PCM slot %d\n", ch, ((ch / 4) * 8) + ((ch % 4) * 4) + 1); printk(KERN_DEBUG "Enabling pass through for channel\n"); vpm_out(hc, ch, ((ch / 4) * 8) + ((ch % 4) * 4) + 1, 0x01); /* rx path */ /* S/T -> PCM */ HFC_outb(hc, R_FIFO, (ch << 1)); HFC_wait(hc); HFC_outb(hc, A_CON_HDLC, 0xc0 | V_HDLC_TRP | V_IFF); HFC_outb(hc, R_SLOT, (((ch / 4) * 8) + ((ch % 4) * 4) + 1) << 1); HFC_outb(hc, A_SL_CFG, 0x80 | (ch << 1)); /* PCM -> FIFO */ HFC_outb(hc, R_FIFO, 0x20 | (ch << 1) | 1); HFC_wait(hc); HFC_outb(hc, A_CON_HDLC, 0x20 | V_HDLC_TRP | V_IFF); HFC_outb(hc, A_SUBCH_CFG, 0); HFC_outb(hc, A_IRQ_MSK, 0); if (hc->chan[ch].protocol != protocol) { HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); } HFC_outb(hc, R_SLOT, ((((ch / 4) * 8) + ((ch % 4) * 4) + 1) << 1) | 1); HFC_outb(hc, A_SL_CFG, 0x80 | 0x20 | (ch << 1) | 1); /* tx path */ /* PCM -> S/T */ HFC_outb(hc, R_FIFO, (ch << 1) | 1); HFC_wait(hc); HFC_outb(hc, A_CON_HDLC, 0xc0 | V_HDLC_TRP | V_IFF); HFC_outb(hc, R_SLOT, ((((ch / 4) * 8) + ((ch % 4) * 4)) << 1) | 1); HFC_outb(hc, A_SL_CFG, 0x80 | 0x40 | (ch << 1) | 1); /* FIFO -> PCM */ HFC_outb(hc, R_FIFO, 0x20 | (ch << 1)); HFC_wait(hc); HFC_outb(hc, A_CON_HDLC, 0x20 | V_HDLC_TRP | V_IFF); HFC_outb(hc, A_SUBCH_CFG, 0); HFC_outb(hc, A_IRQ_MSK, 0); if (hc->chan[ch].protocol != protocol) { HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); } /* tx silence */ HFC_outb_nodebug(hc, A_FIFO_DATA0_NOINC, hc->silence); HFC_outb(hc, R_SLOT, (((ch / 4) * 8) + ((ch % 4) * 4)) << 1); HFC_outb(hc, A_SL_CFG, 0x80 | 0x20 | (ch << 1)); } else { /* enable TX fifo */ HFC_outb(hc, R_FIFO, ch << 1); HFC_wait(hc); if (hc->ctype == HFC_TYPE_XHFC) HFC_outb(hc, A_CON_HDLC, flow_tx | 0x07 << 2 | V_HDLC_TRP | V_IFF); /* Enable FIFO, no interrupt */ else HFC_outb(hc, A_CON_HDLC, flow_tx | 0x00 | V_HDLC_TRP | V_IFF); HFC_outb(hc, A_SUBCH_CFG, 0); HFC_outb(hc, A_IRQ_MSK, 0); if (hc->chan[ch].protocol != protocol) { HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); } /* tx silence */ HFC_outb_nodebug(hc, A_FIFO_DATA0_NOINC, hc->silence); /* enable RX fifo */ HFC_outb(hc, R_FIFO, (ch << 1) | 1); HFC_wait(hc); if (hc->ctype == HFC_TYPE_XHFC) HFC_outb(hc, A_CON_HDLC, flow_rx | 0x07 << 2 | V_HDLC_TRP); /* Enable FIFO, no interrupt*/ else HFC_outb(hc, A_CON_HDLC, flow_rx | 0x00 | V_HDLC_TRP); HFC_outb(hc, A_SUBCH_CFG, 0); HFC_outb(hc, A_IRQ_MSK, 0); if (hc->chan[ch].protocol != protocol) { HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); } } if (hc->ctype != HFC_TYPE_E1) { hc->hw.a_st_ctrl0[hc->chan[ch].port] |= ((ch & 0x3) == 0) ? V_B1_EN : V_B2_EN; HFC_outb(hc, R_ST_SEL, hc->chan[ch].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_CTRL0, hc->hw.a_st_ctrl0[hc->chan[ch].port]); } if (hc->chan[ch].bch) test_and_set_bit(FLG_TRANSPARENT, &hc->chan[ch].bch->Flags); break; case (ISDN_P_B_HDLC): /* B-channel */ case (ISDN_P_TE_S0): /* D-channel */ case (ISDN_P_NT_S0): case (ISDN_P_TE_E1): case (ISDN_P_NT_E1): /* enable TX fifo */ HFC_outb(hc, R_FIFO, ch << 1); HFC_wait(hc); if (hc->ctype == HFC_TYPE_E1 || hc->chan[ch].bch) { /* E1 or B-channel */ HFC_outb(hc, A_CON_HDLC, flow_tx | 0x04); HFC_outb(hc, A_SUBCH_CFG, 0); } else { /* D-Channel without HDLC fill flags */ HFC_outb(hc, A_CON_HDLC, flow_tx | 0x04 | V_IFF); HFC_outb(hc, A_SUBCH_CFG, 2); } HFC_outb(hc, A_IRQ_MSK, V_IRQ); HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); /* enable RX fifo */ HFC_outb(hc, R_FIFO, (ch << 1) | 1); HFC_wait(hc); HFC_outb(hc, A_CON_HDLC, flow_rx | 0x04); if (hc->ctype == HFC_TYPE_E1 || hc->chan[ch].bch) HFC_outb(hc, A_SUBCH_CFG, 0); /* full 8 bits */ else HFC_outb(hc, A_SUBCH_CFG, 2); /* 2 bits dchannel */ HFC_outb(hc, A_IRQ_MSK, V_IRQ); HFC_outb(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait(hc); if (hc->chan[ch].bch) { test_and_set_bit(FLG_HDLC, &hc->chan[ch].bch->Flags); if (hc->ctype != HFC_TYPE_E1) { hc->hw.a_st_ctrl0[hc->chan[ch].port] |= ((ch & 0x3) == 0) ? V_B1_EN : V_B2_EN; HFC_outb(hc, R_ST_SEL, hc->chan[ch].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_CTRL0, hc->hw.a_st_ctrl0[hc->chan[ch].port]); } } break; default: printk(KERN_DEBUG "%s: protocol not known %x\n", __func__, protocol); hc->chan[ch].protocol = ISDN_P_NONE; return -ENOPROTOOPT; } hc->chan[ch].protocol = protocol; return 0; } /* * connect/disconnect PCM */ static void hfcmulti_pcm(struct hfc_multi *hc, int ch, int slot_tx, int bank_tx, int slot_rx, int bank_rx) { if (slot_tx < 0 || slot_rx < 0 || bank_tx < 0 || bank_rx < 0) { /* disable PCM */ mode_hfcmulti(hc, ch, hc->chan[ch].protocol, -1, 0, -1, 0); return; } /* enable pcm */ mode_hfcmulti(hc, ch, hc->chan[ch].protocol, slot_tx, bank_tx, slot_rx, bank_rx); } /* * set/disable conference */ static void hfcmulti_conf(struct hfc_multi *hc, int ch, int num) { if (num >= 0 && num <= 7) hc->chan[ch].conf = num; else hc->chan[ch].conf = -1; mode_hfcmulti(hc, ch, hc->chan[ch].protocol, hc->chan[ch].slot_tx, hc->chan[ch].bank_tx, hc->chan[ch].slot_rx, hc->chan[ch].bank_rx); } /* * set/disable sample loop */ /* NOTE: this function is experimental and therefore disabled */ /* * Layer 1 callback function */ static int hfcm_l1callback(struct dchannel *dch, u_int cmd) { struct hfc_multi *hc = dch->hw; struct sk_buff_head free_queue; u_long flags; switch (cmd) { case INFO3_P8: case INFO3_P10: break; case HW_RESET_REQ: /* start activation */ spin_lock_irqsave(&hc->lock, flags); if (hc->ctype == HFC_TYPE_E1) { if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HW_RESET_REQ no BRI\n", __func__); } else { HFC_outb(hc, R_ST_SEL, hc->chan[dch->slot].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_WR_STATE, V_ST_LD_STA | 3); /* F3 */ udelay(6); /* wait at least 5,21us */ HFC_outb(hc, A_ST_WR_STATE, 3); HFC_outb(hc, A_ST_WR_STATE, 3 | (V_ST_ACT * 3)); /* activate */ } spin_unlock_irqrestore(&hc->lock, flags); l1_event(dch->l1, HW_POWERUP_IND); break; case HW_DEACT_REQ: __skb_queue_head_init(&free_queue); /* start deactivation */ spin_lock_irqsave(&hc->lock, flags); if (hc->ctype == HFC_TYPE_E1) { if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HW_DEACT_REQ no BRI\n", __func__); } else { HFC_outb(hc, R_ST_SEL, hc->chan[dch->slot].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_WR_STATE, V_ST_ACT * 2); /* deactivate */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { hc->syncronized &= ~(1 << hc->chan[dch->slot].port); plxsd_checksync(hc, 0); } } skb_queue_splice_init(&dch->squeue, &free_queue); if (dch->tx_skb) { __skb_queue_tail(&free_queue, dch->tx_skb); dch->tx_skb = NULL; } dch->tx_idx = 0; if (dch->rx_skb) { __skb_queue_tail(&free_queue, dch->rx_skb); dch->rx_skb = NULL; } test_and_clear_bit(FLG_TX_BUSY, &dch->Flags); if (test_and_clear_bit(FLG_BUSY_TIMER, &dch->Flags)) del_timer(&dch->timer); spin_unlock_irqrestore(&hc->lock, flags); __skb_queue_purge(&free_queue); break; case HW_POWERUP_REQ: spin_lock_irqsave(&hc->lock, flags); if (hc->ctype == HFC_TYPE_E1) { if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HW_POWERUP_REQ no BRI\n", __func__); } else { HFC_outb(hc, R_ST_SEL, hc->chan[dch->slot].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_WR_STATE, 3 | 0x10); /* activate */ udelay(6); /* wait at least 5,21us */ HFC_outb(hc, A_ST_WR_STATE, 3); /* activate */ } spin_unlock_irqrestore(&hc->lock, flags); break; case PH_ACTIVATE_IND: test_and_set_bit(FLG_ACTIVE, &dch->Flags); _queue_data(&dch->dev.D, cmd, MISDN_ID_ANY, 0, NULL, GFP_ATOMIC); break; case PH_DEACTIVATE_IND: test_and_clear_bit(FLG_ACTIVE, &dch->Flags); _queue_data(&dch->dev.D, cmd, MISDN_ID_ANY, 0, NULL, GFP_ATOMIC); break; default: if (dch->debug & DEBUG_HW) printk(KERN_DEBUG "%s: unknown command %x\n", __func__, cmd); return -1; } return 0; } /* * Layer2 -> Layer 1 Transfer */ static int handle_dmsg(struct mISDNchannel *ch, struct sk_buff *skb) { struct mISDNdevice *dev = container_of(ch, struct mISDNdevice, D); struct dchannel *dch = container_of(dev, struct dchannel, dev); struct hfc_multi *hc = dch->hw; struct mISDNhead *hh = mISDN_HEAD_P(skb); int ret = -EINVAL; unsigned int id; u_long flags; switch (hh->prim) { case PH_DATA_REQ: if (skb->len < 1) break; spin_lock_irqsave(&hc->lock, flags); ret = dchannel_senddata(dch, skb); if (ret > 0) { /* direct TX */ id = hh->id; /* skb can be freed */ hfcmulti_tx(hc, dch->slot); ret = 0; /* start fifo */ HFC_outb(hc, R_FIFO, 0); HFC_wait(hc); spin_unlock_irqrestore(&hc->lock, flags); queue_ch_frame(ch, PH_DATA_CNF, id, NULL); } else spin_unlock_irqrestore(&hc->lock, flags); return ret; case PH_ACTIVATE_REQ: if (dch->dev.D.protocol != ISDN_P_TE_S0) { spin_lock_irqsave(&hc->lock, flags); ret = 0; if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: PH_ACTIVATE port %d (0..%d)\n", __func__, hc->chan[dch->slot].port, hc->ports - 1); /* start activation */ if (hc->ctype == HFC_TYPE_E1) { ph_state_change(dch); if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: E1 report state %x \n", __func__, dch->state); } else { HFC_outb(hc, R_ST_SEL, hc->chan[dch->slot].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_WR_STATE, V_ST_LD_STA | 1); /* G1 */ udelay(6); /* wait at least 5,21us */ HFC_outb(hc, A_ST_WR_STATE, 1); HFC_outb(hc, A_ST_WR_STATE, 1 | (V_ST_ACT * 3)); /* activate */ dch->state = 1; } spin_unlock_irqrestore(&hc->lock, flags); } else ret = l1_event(dch->l1, hh->prim); break; case PH_DEACTIVATE_REQ: test_and_clear_bit(FLG_L2_ACTIVATED, &dch->Flags); if (dch->dev.D.protocol != ISDN_P_TE_S0) { struct sk_buff_head free_queue; __skb_queue_head_init(&free_queue); spin_lock_irqsave(&hc->lock, flags); if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: PH_DEACTIVATE port %d (0..%d)\n", __func__, hc->chan[dch->slot].port, hc->ports - 1); /* start deactivation */ if (hc->ctype == HFC_TYPE_E1) { if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: PH_DEACTIVATE no BRI\n", __func__); } else { HFC_outb(hc, R_ST_SEL, hc->chan[dch->slot].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_WR_STATE, V_ST_ACT * 2); /* deactivate */ dch->state = 1; } skb_queue_splice_init(&dch->squeue, &free_queue); if (dch->tx_skb) { __skb_queue_tail(&free_queue, dch->tx_skb); dch->tx_skb = NULL; } dch->tx_idx = 0; if (dch->rx_skb) { __skb_queue_tail(&free_queue, dch->rx_skb); dch->rx_skb = NULL; } test_and_clear_bit(FLG_TX_BUSY, &dch->Flags); if (test_and_clear_bit(FLG_BUSY_TIMER, &dch->Flags)) del_timer(&dch->timer); #ifdef FIXME if (test_and_clear_bit(FLG_L1_BUSY, &dch->Flags)) dchannel_sched_event(&hc->dch, D_CLEARBUSY); #endif ret = 0; spin_unlock_irqrestore(&hc->lock, flags); __skb_queue_purge(&free_queue); } else ret = l1_event(dch->l1, hh->prim); break; } if (!ret) dev_kfree_skb(skb); return ret; } static void deactivate_bchannel(struct bchannel *bch) { struct hfc_multi *hc = bch->hw; u_long flags; spin_lock_irqsave(&hc->lock, flags); mISDN_clear_bchannel(bch); hc->chan[bch->slot].coeff_count = 0; hc->chan[bch->slot].rx_off = 0; hc->chan[bch->slot].conf = -1; mode_hfcmulti(hc, bch->slot, ISDN_P_NONE, -1, 0, -1, 0); spin_unlock_irqrestore(&hc->lock, flags); } static int handle_bmsg(struct mISDNchannel *ch, struct sk_buff *skb) { struct bchannel *bch = container_of(ch, struct bchannel, ch); struct hfc_multi *hc = bch->hw; int ret = -EINVAL; struct mISDNhead *hh = mISDN_HEAD_P(skb); unsigned long flags; switch (hh->prim) { case PH_DATA_REQ: if (!skb->len) break; spin_lock_irqsave(&hc->lock, flags); ret = bchannel_senddata(bch, skb); if (ret > 0) { /* direct TX */ hfcmulti_tx(hc, bch->slot); ret = 0; /* start fifo */ HFC_outb_nodebug(hc, R_FIFO, 0); HFC_wait_nodebug(hc); } spin_unlock_irqrestore(&hc->lock, flags); return ret; case PH_ACTIVATE_REQ: if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: PH_ACTIVATE ch %d (0..32)\n", __func__, bch->slot); spin_lock_irqsave(&hc->lock, flags); /* activate B-channel if not already activated */ if (!test_and_set_bit(FLG_ACTIVE, &bch->Flags)) { hc->chan[bch->slot].txpending = 0; ret = mode_hfcmulti(hc, bch->slot, ch->protocol, hc->chan[bch->slot].slot_tx, hc->chan[bch->slot].bank_tx, hc->chan[bch->slot].slot_rx, hc->chan[bch->slot].bank_rx); if (!ret) { if (ch->protocol == ISDN_P_B_RAW && !hc->dtmf && test_bit(HFC_CHIP_DTMF, &hc->chip)) { /* start decoder */ hc->dtmf = 1; if (debug & DEBUG_HFCMULTI_DTMF) printk(KERN_DEBUG "%s: start dtmf decoder\n", __func__); HFC_outb(hc, R_DTMF, hc->hw.r_dtmf | V_RST_DTMF); } } } else ret = 0; spin_unlock_irqrestore(&hc->lock, flags); if (!ret) _queue_data(ch, PH_ACTIVATE_IND, MISDN_ID_ANY, 0, NULL, GFP_KERNEL); break; case PH_CONTROL_REQ: spin_lock_irqsave(&hc->lock, flags); switch (hh->id) { case HFC_SPL_LOOP_ON: /* set sample loop */ if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_SPL_LOOP_ON (len = %d)\n", __func__, skb->len); ret = 0; break; case HFC_SPL_LOOP_OFF: /* set silence */ if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_SPL_LOOP_OFF\n", __func__); ret = 0; break; default: printk(KERN_ERR "%s: unknown PH_CONTROL_REQ info %x\n", __func__, hh->id); ret = -EINVAL; } spin_unlock_irqrestore(&hc->lock, flags); break; case PH_DEACTIVATE_REQ: deactivate_bchannel(bch); /* locked there */ _queue_data(ch, PH_DEACTIVATE_IND, MISDN_ID_ANY, 0, NULL, GFP_KERNEL); ret = 0; break; } if (!ret) dev_kfree_skb(skb); return ret; } /* * bchannel control function */ static int channel_bctrl(struct bchannel *bch, struct mISDN_ctrl_req *cq) { int ret = 0; struct dsp_features *features = (struct dsp_features *)(*((u_long *)&cq->p1)); struct hfc_multi *hc = bch->hw; int slot_tx; int bank_tx; int slot_rx; int bank_rx; int num; switch (cq->op) { case MISDN_CTRL_GETOP: ret = mISDN_ctrl_bchannel(bch, cq); cq->op |= MISDN_CTRL_HFC_OP | MISDN_CTRL_HW_FEATURES_OP; break; case MISDN_CTRL_RX_OFF: /* turn off / on rx stream */ ret = mISDN_ctrl_bchannel(bch, cq); hc->chan[bch->slot].rx_off = !!cq->p1; if (!hc->chan[bch->slot].rx_off) { /* reset fifo on rx on */ HFC_outb_nodebug(hc, R_FIFO, (bch->slot << 1) | 1); HFC_wait_nodebug(hc); HFC_outb_nodebug(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait_nodebug(hc); } if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: RX_OFF request (nr=%d off=%d)\n", __func__, bch->nr, hc->chan[bch->slot].rx_off); break; case MISDN_CTRL_FILL_EMPTY: ret = mISDN_ctrl_bchannel(bch, cq); hc->silence = bch->fill[0]; memset(hc->silence_data, hc->silence, sizeof(hc->silence_data)); break; case MISDN_CTRL_HW_FEATURES: /* fill features structure */ if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HW_FEATURE request\n", __func__); /* create confirm */ features->hfc_id = hc->id; if (test_bit(HFC_CHIP_DTMF, &hc->chip)) features->hfc_dtmf = 1; if (test_bit(HFC_CHIP_CONF, &hc->chip)) features->hfc_conf = 1; features->hfc_loops = 0; if (test_bit(HFC_CHIP_B410P, &hc->chip)) { features->hfc_echocanhw = 1; } else { features->pcm_id = hc->pcm; features->pcm_slots = hc->slots; features->pcm_banks = 2; } break; case MISDN_CTRL_HFC_PCM_CONN: /* connect to pcm timeslot (0..N) */ slot_tx = cq->p1 & 0xff; bank_tx = cq->p1 >> 8; slot_rx = cq->p2 & 0xff; bank_rx = cq->p2 >> 8; if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_PCM_CONN slot %d bank %d (TX) " "slot %d bank %d (RX)\n", __func__, slot_tx, bank_tx, slot_rx, bank_rx); if (slot_tx < hc->slots && bank_tx <= 2 && slot_rx < hc->slots && bank_rx <= 2) hfcmulti_pcm(hc, bch->slot, slot_tx, bank_tx, slot_rx, bank_rx); else { printk(KERN_WARNING "%s: HFC_PCM_CONN slot %d bank %d (TX) " "slot %d bank %d (RX) out of range\n", __func__, slot_tx, bank_tx, slot_rx, bank_rx); ret = -EINVAL; } break; case MISDN_CTRL_HFC_PCM_DISC: /* release interface from pcm timeslot */ if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_PCM_DISC\n", __func__); hfcmulti_pcm(hc, bch->slot, -1, 0, -1, 0); break; case MISDN_CTRL_HFC_CONF_JOIN: /* join conference (0..7) */ num = cq->p1 & 0xff; if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_CONF_JOIN conf %d\n", __func__, num); if (num <= 7) hfcmulti_conf(hc, bch->slot, num); else { printk(KERN_WARNING "%s: HW_CONF_JOIN conf %d out of range\n", __func__, num); ret = -EINVAL; } break; case MISDN_CTRL_HFC_CONF_SPLIT: /* split conference */ if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_CONF_SPLIT\n", __func__); hfcmulti_conf(hc, bch->slot, -1); break; case MISDN_CTRL_HFC_ECHOCAN_ON: if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_ECHOCAN_ON\n", __func__); if (test_bit(HFC_CHIP_B410P, &hc->chip)) vpm_echocan_on(hc, bch->slot, cq->p1); else ret = -EINVAL; break; case MISDN_CTRL_HFC_ECHOCAN_OFF: if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: HFC_ECHOCAN_OFF\n", __func__); if (test_bit(HFC_CHIP_B410P, &hc->chip)) vpm_echocan_off(hc, bch->slot); else ret = -EINVAL; break; default: ret = mISDN_ctrl_bchannel(bch, cq); break; } return ret; } static int hfcm_bctrl(struct mISDNchannel *ch, u_int cmd, void *arg) { struct bchannel *bch = container_of(ch, struct bchannel, ch); struct hfc_multi *hc = bch->hw; int err = -EINVAL; u_long flags; if (bch->debug & DEBUG_HW) printk(KERN_DEBUG "%s: cmd:%x %p\n", __func__, cmd, arg); switch (cmd) { case CLOSE_CHANNEL: test_and_clear_bit(FLG_OPEN, &bch->Flags); deactivate_bchannel(bch); /* locked there */ ch->protocol = ISDN_P_NONE; ch->peer = NULL; module_put(THIS_MODULE); err = 0; break; case CONTROL_CHANNEL: spin_lock_irqsave(&hc->lock, flags); err = channel_bctrl(bch, arg); spin_unlock_irqrestore(&hc->lock, flags); break; default: printk(KERN_WARNING "%s: unknown prim(%x)\n", __func__, cmd); } return err; } /* * handle D-channel events * * handle state change event */ static void ph_state_change(struct dchannel *dch) { struct hfc_multi *hc; int ch, i; if (!dch) { printk(KERN_WARNING "%s: ERROR given dch is NULL\n", __func__); return; } hc = dch->hw; ch = dch->slot; if (hc->ctype == HFC_TYPE_E1) { if (dch->dev.D.protocol == ISDN_P_TE_E1) { if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: E1 TE (id=%d) newstate %x\n", __func__, hc->id, dch->state); } else { if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: E1 NT (id=%d) newstate %x\n", __func__, hc->id, dch->state); } switch (dch->state) { case (1): if (hc->e1_state != 1) { for (i = 1; i <= 31; i++) { /* reset fifos on e1 activation */ HFC_outb_nodebug(hc, R_FIFO, (i << 1) | 1); HFC_wait_nodebug(hc); HFC_outb_nodebug(hc, R_INC_RES_FIFO, V_RES_F); HFC_wait_nodebug(hc); } } test_and_set_bit(FLG_ACTIVE, &dch->Flags); _queue_data(&dch->dev.D, PH_ACTIVATE_IND, MISDN_ID_ANY, 0, NULL, GFP_ATOMIC); break; default: if (hc->e1_state != 1) return; test_and_clear_bit(FLG_ACTIVE, &dch->Flags); _queue_data(&dch->dev.D, PH_DEACTIVATE_IND, MISDN_ID_ANY, 0, NULL, GFP_ATOMIC); } hc->e1_state = dch->state; } else { if (dch->dev.D.protocol == ISDN_P_TE_S0) { if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: S/T TE newstate %x\n", __func__, dch->state); switch (dch->state) { case (0): l1_event(dch->l1, HW_RESET_IND); break; case (3): l1_event(dch->l1, HW_DEACT_IND); break; case (5): case (8): l1_event(dch->l1, ANYSIGNAL); break; case (6): l1_event(dch->l1, INFO2); break; case (7): l1_event(dch->l1, INFO4_P8); break; } } else { if (debug & DEBUG_HFCMULTI_STATE) printk(KERN_DEBUG "%s: S/T NT newstate %x\n", __func__, dch->state); switch (dch->state) { case (2): if (hc->chan[ch].nt_timer == 0) { hc->chan[ch].nt_timer = -1; HFC_outb(hc, R_ST_SEL, hc->chan[ch].port); /* undocumented: delay after R_ST_SEL */ udelay(1); HFC_outb(hc, A_ST_WR_STATE, 4 | V_ST_LD_STA); /* G4 */ udelay(6); /* wait at least 5,21us */ HFC_outb(hc, A_ST_WR_STATE, 4); dch->state = 4; } else { /* one extra count for the next event */ hc->chan[ch].nt_timer = nt_t1_count[poll_timer] + 1; HFC_outb(hc, R_ST_SEL, hc->chan[ch].port); /* undocumented: delay after R_ST_SEL */ udelay(1); /* allow G2 -> G3 transition */ HFC_outb(hc, A_ST_WR_STATE, 2 | V_SET_G2_G3); } break; case (1): hc->chan[ch].nt_timer = -1; test_and_clear_bit(FLG_ACTIVE, &dch->Flags); _queue_data(&dch->dev.D, PH_DEACTIVATE_IND, MISDN_ID_ANY, 0, NULL, GFP_ATOMIC); break; case (4): hc->chan[ch].nt_timer = -1; break; case (3): hc->chan[ch].nt_timer = -1; test_and_set_bit(FLG_ACTIVE, &dch->Flags); _queue_data(&dch->dev.D, PH_ACTIVATE_IND, MISDN_ID_ANY, 0, NULL, GFP_ATOMIC); break; } } } } /* * called for card mode init message */ static void hfcmulti_initmode(struct dchannel *dch) { struct hfc_multi *hc = dch->hw; u_char a_st_wr_state, r_e1_wr_sta; int i, pt; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: entered\n", __func__); i = dch->slot; pt = hc->chan[i].port; if (hc->ctype == HFC_TYPE_E1) { /* E1 */ hc->chan[hc->dnum[pt]].slot_tx = -1; hc->chan[hc->dnum[pt]].slot_rx = -1; hc->chan[hc->dnum[pt]].conf = -1; if (hc->dnum[pt]) { mode_hfcmulti(hc, dch->slot, dch->dev.D.protocol, -1, 0, -1, 0); timer_setup(&dch->timer, hfcmulti_dbusy_timer, 0); } for (i = 1; i <= 31; i++) { if (!((1 << i) & hc->bmask[pt])) /* skip unused chan */ continue; hc->chan[i].slot_tx = -1; hc->chan[i].slot_rx = -1; hc->chan[i].conf = -1; mode_hfcmulti(hc, i, ISDN_P_NONE, -1, 0, -1, 0); } } if (hc->ctype == HFC_TYPE_E1 && pt == 0) { /* E1, port 0 */ dch = hc->chan[hc->dnum[0]].dch; if (test_bit(HFC_CFG_REPORT_LOS, &hc->chan[hc->dnum[0]].cfg)) { HFC_outb(hc, R_LOS0, 255); /* 2 ms */ HFC_outb(hc, R_LOS1, 255); /* 512 ms */ } if (test_bit(HFC_CFG_OPTICAL, &hc->chan[hc->dnum[0]].cfg)) { HFC_outb(hc, R_RX0, 0); hc->hw.r_tx0 = 0 | V_OUT_EN; } else { HFC_outb(hc, R_RX0, 1); hc->hw.r_tx0 = 1 | V_OUT_EN; } hc->hw.r_tx1 = V_ATX | V_NTRI; HFC_outb(hc, R_TX0, hc->hw.r_tx0); HFC_outb(hc, R_TX1, hc->hw.r_tx1); HFC_outb(hc, R_TX_FR0, 0x00); HFC_outb(hc, R_TX_FR1, 0xf8); if (test_bit(HFC_CFG_CRC4, &hc->chan[hc->dnum[0]].cfg)) HFC_outb(hc, R_TX_FR2, V_TX_MF | V_TX_E | V_NEG_E); HFC_outb(hc, R_RX_FR0, V_AUTO_RESYNC | V_AUTO_RECO | 0); if (test_bit(HFC_CFG_CRC4, &hc->chan[hc->dnum[0]].cfg)) HFC_outb(hc, R_RX_FR1, V_RX_MF | V_RX_MF_SYNC); if (dch->dev.D.protocol == ISDN_P_NT_E1) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: E1 port is NT-mode\n", __func__); r_e1_wr_sta = 0; /* G0 */ hc->e1_getclock = 0; } else { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: E1 port is TE-mode\n", __func__); r_e1_wr_sta = 0; /* F0 */ hc->e1_getclock = 1; } if (test_bit(HFC_CHIP_RX_SYNC, &hc->chip)) HFC_outb(hc, R_SYNC_OUT, V_SYNC_E1_RX); else HFC_outb(hc, R_SYNC_OUT, 0); if (test_bit(HFC_CHIP_E1CLOCK_GET, &hc->chip)) hc->e1_getclock = 1; if (test_bit(HFC_CHIP_E1CLOCK_PUT, &hc->chip)) hc->e1_getclock = 0; if (test_bit(HFC_CHIP_PCM_SLAVE, &hc->chip)) { /* SLAVE (clock master) */ if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: E1 port is clock master " "(clock from PCM)\n", __func__); HFC_outb(hc, R_SYNC_CTRL, V_EXT_CLK_SYNC | V_PCM_SYNC); } else { if (hc->e1_getclock) { /* MASTER (clock slave) */ if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: E1 port is clock slave " "(clock to PCM)\n", __func__); HFC_outb(hc, R_SYNC_CTRL, V_SYNC_OFFS); } else { /* MASTER (clock master) */ if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: E1 port is " "clock master " "(clock from QUARTZ)\n", __func__); HFC_outb(hc, R_SYNC_CTRL, V_EXT_CLK_SYNC | V_PCM_SYNC | V_JATT_OFF); HFC_outb(hc, R_SYNC_OUT, 0); } } HFC_outb(hc, R_JATT_ATT, 0x9c); /* undoc register */ HFC_outb(hc, R_PWM_MD, V_PWM0_MD); HFC_outb(hc, R_PWM0, 0x50); HFC_outb(hc, R_PWM1, 0xff); /* state machine setup */ HFC_outb(hc, R_E1_WR_STA, r_e1_wr_sta | V_E1_LD_STA); udelay(6); /* wait at least 5,21us */ HFC_outb(hc, R_E1_WR_STA, r_e1_wr_sta); if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { hc->syncronized = 0; plxsd_checksync(hc, 0); } } if (hc->ctype != HFC_TYPE_E1) { /* ST */ hc->chan[i].slot_tx = -1; hc->chan[i].slot_rx = -1; hc->chan[i].conf = -1; mode_hfcmulti(hc, i, dch->dev.D.protocol, -1, 0, -1, 0); timer_setup(&dch->timer, hfcmulti_dbusy_timer, 0); hc->chan[i - 2].slot_tx = -1; hc->chan[i - 2].slot_rx = -1; hc->chan[i - 2].conf = -1; mode_hfcmulti(hc, i - 2, ISDN_P_NONE, -1, 0, -1, 0); hc->chan[i - 1].slot_tx = -1; hc->chan[i - 1].slot_rx = -1; hc->chan[i - 1].conf = -1; mode_hfcmulti(hc, i - 1, ISDN_P_NONE, -1, 0, -1, 0); /* select interface */ HFC_outb(hc, R_ST_SEL, pt); /* undocumented: delay after R_ST_SEL */ udelay(1); if (dch->dev.D.protocol == ISDN_P_NT_S0) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: ST port %d is NT-mode\n", __func__, pt); /* clock delay */ HFC_outb(hc, A_ST_CLK_DLY, clockdelay_nt); a_st_wr_state = 1; /* G1 */ hc->hw.a_st_ctrl0[pt] = V_ST_MD; } else { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: ST port %d is TE-mode\n", __func__, pt); /* clock delay */ HFC_outb(hc, A_ST_CLK_DLY, clockdelay_te); a_st_wr_state = 2; /* F2 */ hc->hw.a_st_ctrl0[pt] = 0; } if (!test_bit(HFC_CFG_NONCAP_TX, &hc->chan[i].cfg)) hc->hw.a_st_ctrl0[pt] |= V_TX_LI; if (hc->ctype == HFC_TYPE_XHFC) { hc->hw.a_st_ctrl0[pt] |= 0x40 /* V_ST_PU_CTRL */; HFC_outb(hc, 0x35 /* A_ST_CTRL3 */, 0x7c << 1 /* V_ST_PULSE */); } /* line setup */ HFC_outb(hc, A_ST_CTRL0, hc->hw.a_st_ctrl0[pt]); /* disable E-channel */ if ((dch->dev.D.protocol == ISDN_P_NT_S0) || test_bit(HFC_CFG_DIS_ECHANNEL, &hc->chan[i].cfg)) HFC_outb(hc, A_ST_CTRL1, V_E_IGNO); else HFC_outb(hc, A_ST_CTRL1, 0); /* enable B-channel receive */ HFC_outb(hc, A_ST_CTRL2, V_B1_RX_EN | V_B2_RX_EN); /* state machine setup */ HFC_outb(hc, A_ST_WR_STATE, a_st_wr_state | V_ST_LD_STA); udelay(6); /* wait at least 5,21us */ HFC_outb(hc, A_ST_WR_STATE, a_st_wr_state); hc->hw.r_sci_msk |= 1 << pt; /* state machine interrupts */ HFC_outb(hc, R_SCI_MSK, hc->hw.r_sci_msk); /* unset sync on port */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { hc->syncronized &= ~(1 << hc->chan[dch->slot].port); plxsd_checksync(hc, 0); } } if (debug & DEBUG_HFCMULTI_INIT) printk("%s: done\n", __func__); } static int open_dchannel(struct hfc_multi *hc, struct dchannel *dch, struct channel_req *rq) { int err = 0; u_long flags; if (debug & DEBUG_HW_OPEN) printk(KERN_DEBUG "%s: dev(%d) open from %p\n", __func__, dch->dev.id, __builtin_return_address(0)); if (rq->protocol == ISDN_P_NONE) return -EINVAL; if ((dch->dev.D.protocol != ISDN_P_NONE) && (dch->dev.D.protocol != rq->protocol)) { if (debug & DEBUG_HFCMULTI_MODE) printk(KERN_DEBUG "%s: change protocol %x to %x\n", __func__, dch->dev.D.protocol, rq->protocol); } if ((dch->dev.D.protocol == ISDN_P_TE_S0) && (rq->protocol != ISDN_P_TE_S0)) l1_event(dch->l1, CLOSE_CHANNEL); if (dch->dev.D.protocol != rq->protocol) { if (rq->protocol == ISDN_P_TE_S0) { err = create_l1(dch, hfcm_l1callback); if (err) return err; } dch->dev.D.protocol = rq->protocol; spin_lock_irqsave(&hc->lock, flags); hfcmulti_initmode(dch); spin_unlock_irqrestore(&hc->lock, flags); } if (test_bit(FLG_ACTIVE, &dch->Flags)) _queue_data(&dch->dev.D, PH_ACTIVATE_IND, MISDN_ID_ANY, 0, NULL, GFP_KERNEL); rq->ch = &dch->dev.D; if (!try_module_get(THIS_MODULE)) printk(KERN_WARNING "%s:cannot get module\n", __func__); return 0; } static int open_bchannel(struct hfc_multi *hc, struct dchannel *dch, struct channel_req *rq) { struct bchannel *bch; int ch; if (!test_channelmap(rq->adr.channel, dch->dev.channelmap)) return -EINVAL; if (rq->protocol == ISDN_P_NONE) return -EINVAL; if (hc->ctype == HFC_TYPE_E1) ch = rq->adr.channel; else ch = (rq->adr.channel - 1) + (dch->slot - 2); bch = hc->chan[ch].bch; if (!bch) { printk(KERN_ERR "%s:internal error ch %d has no bch\n", __func__, ch); return -EINVAL; } if (test_and_set_bit(FLG_OPEN, &bch->Flags)) return -EBUSY; /* b-channel can be only open once */ bch->ch.protocol = rq->protocol; hc->chan[ch].rx_off = 0; rq->ch = &bch->ch; if (!try_module_get(THIS_MODULE)) printk(KERN_WARNING "%s:cannot get module\n", __func__); return 0; } /* * device control function */ static int channel_dctrl(struct dchannel *dch, struct mISDN_ctrl_req *cq) { struct hfc_multi *hc = dch->hw; int ret = 0; int wd_mode, wd_cnt; switch (cq->op) { case MISDN_CTRL_GETOP: cq->op = MISDN_CTRL_HFC_OP | MISDN_CTRL_L1_TIMER3; break; case MISDN_CTRL_HFC_WD_INIT: /* init the watchdog */ wd_cnt = cq->p1 & 0xf; wd_mode = !!(cq->p1 >> 4); if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: MISDN_CTRL_HFC_WD_INIT mode %s" ", counter 0x%x\n", __func__, wd_mode ? "AUTO" : "MANUAL", wd_cnt); /* set the watchdog timer */ HFC_outb(hc, R_TI_WD, poll_timer | (wd_cnt << 4)); hc->hw.r_bert_wd_md = (wd_mode ? V_AUTO_WD_RES : 0); if (hc->ctype == HFC_TYPE_XHFC) hc->hw.r_bert_wd_md |= 0x40 /* V_WD_EN */; /* init the watchdog register and reset the counter */ HFC_outb(hc, R_BERT_WD_MD, hc->hw.r_bert_wd_md | V_WD_RES); if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { /* enable the watchdog output for Speech-Design */ HFC_outb(hc, R_GPIO_SEL, V_GPIO_SEL7); HFC_outb(hc, R_GPIO_EN1, V_GPIO_EN15); HFC_outb(hc, R_GPIO_OUT1, 0); HFC_outb(hc, R_GPIO_OUT1, V_GPIO_OUT15); } break; case MISDN_CTRL_HFC_WD_RESET: /* reset the watchdog counter */ if (debug & DEBUG_HFCMULTI_MSG) printk(KERN_DEBUG "%s: MISDN_CTRL_HFC_WD_RESET\n", __func__); HFC_outb(hc, R_BERT_WD_MD, hc->hw.r_bert_wd_md | V_WD_RES); break; case MISDN_CTRL_L1_TIMER3: ret = l1_event(dch->l1, HW_TIMER3_VALUE | (cq->p1 & 0xff)); break; default: printk(KERN_WARNING "%s: unknown Op %x\n", __func__, cq->op); ret = -EINVAL; break; } return ret; } static int hfcm_dctrl(struct mISDNchannel *ch, u_int cmd, void *arg) { struct mISDNdevice *dev = container_of(ch, struct mISDNdevice, D); struct dchannel *dch = container_of(dev, struct dchannel, dev); struct hfc_multi *hc = dch->hw; struct channel_req *rq; int err = 0; u_long flags; if (dch->debug & DEBUG_HW) printk(KERN_DEBUG "%s: cmd:%x %p\n", __func__, cmd, arg); switch (cmd) { case OPEN_CHANNEL: rq = arg; switch (rq->protocol) { case ISDN_P_TE_S0: case ISDN_P_NT_S0: if (hc->ctype == HFC_TYPE_E1) { err = -EINVAL; break; } err = open_dchannel(hc, dch, rq); /* locked there */ break; case ISDN_P_TE_E1: case ISDN_P_NT_E1: if (hc->ctype != HFC_TYPE_E1) { err = -EINVAL; break; } err = open_dchannel(hc, dch, rq); /* locked there */ break; default: spin_lock_irqsave(&hc->lock, flags); err = open_bchannel(hc, dch, rq); spin_unlock_irqrestore(&hc->lock, flags); } break; case CLOSE_CHANNEL: if (debug & DEBUG_HW_OPEN) printk(KERN_DEBUG "%s: dev(%d) close from %p\n", __func__, dch->dev.id, __builtin_return_address(0)); module_put(THIS_MODULE); break; case CONTROL_CHANNEL: spin_lock_irqsave(&hc->lock, flags); err = channel_dctrl(dch, arg); spin_unlock_irqrestore(&hc->lock, flags); break; default: if (dch->debug & DEBUG_HW) printk(KERN_DEBUG "%s: unknown command %x\n", __func__, cmd); err = -EINVAL; } return err; } static int clockctl(void *priv, int enable) { struct hfc_multi *hc = priv; hc->iclock_on = enable; return 0; } /* * initialize the card */ /* * start timer irq, wait some time and check if we have interrupts. * if not, reset chip and try again. */ static int init_card(struct hfc_multi *hc) { int err = -EIO; u_long flags; void __iomem *plx_acc; u_long plx_flags; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: entered\n", __func__); spin_lock_irqsave(&hc->lock, flags); /* set interrupts but leave global interrupt disabled */ hc->hw.r_irq_ctrl = V_FIFO_IRQ; disable_hwirq(hc); spin_unlock_irqrestore(&hc->lock, flags); if (request_irq(hc->irq, hfcmulti_interrupt, IRQF_SHARED, "HFC-multi", hc)) { printk(KERN_WARNING "mISDN: Could not get interrupt %d.\n", hc->irq); hc->irq = 0; return -EIO; } if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { spin_lock_irqsave(&plx_lock, plx_flags); plx_acc = hc->plx_membase + PLX_INTCSR; writew((PLX_INTCSR_PCIINT_ENABLE | PLX_INTCSR_LINTI1_ENABLE), plx_acc); /* enable PCI & LINT1 irq */ spin_unlock_irqrestore(&plx_lock, plx_flags); } if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: IRQ %d count %d\n", __func__, hc->irq, hc->irqcnt); err = init_chip(hc); if (err) goto error; /* * Finally enable IRQ output * this is only allowed, if an IRQ routine is already * established for this HFC, so don't do that earlier */ spin_lock_irqsave(&hc->lock, flags); enable_hwirq(hc); spin_unlock_irqrestore(&hc->lock, flags); /* printk(KERN_DEBUG "no master irq set!!!\n"); */ set_current_state(TASK_UNINTERRUPTIBLE); schedule_timeout((100 * HZ) / 1000); /* Timeout 100ms */ /* turn IRQ off until chip is completely initialized */ spin_lock_irqsave(&hc->lock, flags); disable_hwirq(hc); spin_unlock_irqrestore(&hc->lock, flags); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: IRQ %d count %d\n", __func__, hc->irq, hc->irqcnt); if (hc->irqcnt) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: done\n", __func__); return 0; } if (test_bit(HFC_CHIP_PCM_SLAVE, &hc->chip)) { printk(KERN_INFO "ignoring missing interrupts\n"); return 0; } printk(KERN_ERR "HFC PCI: IRQ(%d) getting no interrupts during init.\n", hc->irq); err = -EIO; error: if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { spin_lock_irqsave(&plx_lock, plx_flags); plx_acc = hc->plx_membase + PLX_INTCSR; writew(0x00, plx_acc); /*disable IRQs*/ spin_unlock_irqrestore(&plx_lock, plx_flags); } if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: free irq %d\n", __func__, hc->irq); if (hc->irq) { free_irq(hc->irq, hc); hc->irq = 0; } if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: done (err=%d)\n", __func__, err); return err; } /* * find pci device and set it up */ static int setup_pci(struct hfc_multi *hc, struct pci_dev *pdev, const struct pci_device_id *ent) { struct hm_map *m = (struct hm_map *)ent->driver_data; printk(KERN_INFO "HFC-multi: card manufacturer: '%s' card name: '%s' clock: %s\n", m->vendor_name, m->card_name, m->clock2 ? "double" : "normal"); hc->pci_dev = pdev; if (m->clock2) test_and_set_bit(HFC_CHIP_CLOCK2, &hc->chip); if (ent->vendor == PCI_VENDOR_ID_DIGIUM && ent->device == PCI_DEVICE_ID_DIGIUM_HFC4S) { test_and_set_bit(HFC_CHIP_B410P, &hc->chip); test_and_set_bit(HFC_CHIP_PCM_MASTER, &hc->chip); test_and_clear_bit(HFC_CHIP_PCM_SLAVE, &hc->chip); hc->slots = 32; } if (hc->pci_dev->irq <= 0) { printk(KERN_WARNING "HFC-multi: No IRQ for PCI card found.\n"); return -EIO; } if (pci_enable_device(hc->pci_dev)) { printk(KERN_WARNING "HFC-multi: Error enabling PCI card.\n"); return -EIO; } hc->leds = m->leds; hc->ledstate = 0xAFFEAFFE; hc->opticalsupport = m->opticalsupport; hc->pci_iobase = 0; hc->pci_membase = NULL; hc->plx_membase = NULL; /* set memory access methods */ if (m->io_mode) /* use mode from card config */ hc->io_mode = m->io_mode; switch (hc->io_mode) { case HFC_IO_MODE_PLXSD: test_and_set_bit(HFC_CHIP_PLXSD, &hc->chip); hc->slots = 128; /* required */ hc->HFC_outb = HFC_outb_pcimem; hc->HFC_inb = HFC_inb_pcimem; hc->HFC_inw = HFC_inw_pcimem; hc->HFC_wait = HFC_wait_pcimem; hc->read_fifo = read_fifo_pcimem; hc->write_fifo = write_fifo_pcimem; hc->plx_origmembase = hc->pci_dev->resource[0].start; /* MEMBASE 1 is PLX PCI Bridge */ if (!hc->plx_origmembase) { printk(KERN_WARNING "HFC-multi: No IO-Memory for PCI PLX bridge found\n"); pci_disable_device(hc->pci_dev); return -EIO; } hc->plx_membase = ioremap(hc->plx_origmembase, 0x80); if (!hc->plx_membase) { printk(KERN_WARNING "HFC-multi: failed to remap plx address space. " "(internal error)\n"); pci_disable_device(hc->pci_dev); return -EIO; } printk(KERN_INFO "HFC-multi: plx_membase:%#lx plx_origmembase:%#lx\n", (u_long)hc->plx_membase, hc->plx_origmembase); hc->pci_origmembase = hc->pci_dev->resource[2].start; /* MEMBASE 1 is PLX PCI Bridge */ if (!hc->pci_origmembase) { printk(KERN_WARNING "HFC-multi: No IO-Memory for PCI card found\n"); pci_disable_device(hc->pci_dev); return -EIO; } hc->pci_membase = ioremap(hc->pci_origmembase, 0x400); if (!hc->pci_membase) { printk(KERN_WARNING "HFC-multi: failed to remap io " "address space. (internal error)\n"); pci_disable_device(hc->pci_dev); return -EIO; } printk(KERN_INFO "card %d: defined at MEMBASE %#lx (%#lx) IRQ %d HZ %d " "leds-type %d\n", hc->id, (u_long)hc->pci_membase, hc->pci_origmembase, hc->pci_dev->irq, HZ, hc->leds); pci_write_config_word(hc->pci_dev, PCI_COMMAND, PCI_ENA_MEMIO); break; case HFC_IO_MODE_PCIMEM: hc->HFC_outb = HFC_outb_pcimem; hc->HFC_inb = HFC_inb_pcimem; hc->HFC_inw = HFC_inw_pcimem; hc->HFC_wait = HFC_wait_pcimem; hc->read_fifo = read_fifo_pcimem; hc->write_fifo = write_fifo_pcimem; hc->pci_origmembase = hc->pci_dev->resource[1].start; if (!hc->pci_origmembase) { printk(KERN_WARNING "HFC-multi: No IO-Memory for PCI card found\n"); pci_disable_device(hc->pci_dev); return -EIO; } hc->pci_membase = ioremap(hc->pci_origmembase, 256); if (!hc->pci_membase) { printk(KERN_WARNING "HFC-multi: failed to remap io address space. " "(internal error)\n"); pci_disable_device(hc->pci_dev); return -EIO; } printk(KERN_INFO "card %d: defined at MEMBASE %#lx (%#lx) IRQ " "%d HZ %d leds-type %d\n", hc->id, (u_long)hc->pci_membase, hc->pci_origmembase, hc->pci_dev->irq, HZ, hc->leds); pci_write_config_word(hc->pci_dev, PCI_COMMAND, PCI_ENA_MEMIO); break; case HFC_IO_MODE_REGIO: hc->HFC_outb = HFC_outb_regio; hc->HFC_inb = HFC_inb_regio; hc->HFC_inw = HFC_inw_regio; hc->HFC_wait = HFC_wait_regio; hc->read_fifo = read_fifo_regio; hc->write_fifo = write_fifo_regio; hc->pci_iobase = (u_int) hc->pci_dev->resource[0].start; if (!hc->pci_iobase) { printk(KERN_WARNING "HFC-multi: No IO for PCI card found\n"); pci_disable_device(hc->pci_dev); return -EIO; } if (!request_region(hc->pci_iobase, 8, "hfcmulti")) { printk(KERN_WARNING "HFC-multi: failed to request " "address space at 0x%08lx (internal error)\n", hc->pci_iobase); pci_disable_device(hc->pci_dev); return -EIO; } printk(KERN_INFO "%s %s: defined at IOBASE %#x IRQ %d HZ %d leds-type %d\n", m->vendor_name, m->card_name, (u_int) hc->pci_iobase, hc->pci_dev->irq, HZ, hc->leds); pci_write_config_word(hc->pci_dev, PCI_COMMAND, PCI_ENA_REGIO); break; default: printk(KERN_WARNING "HFC-multi: Invalid IO mode.\n"); pci_disable_device(hc->pci_dev); return -EIO; } pci_set_drvdata(hc->pci_dev, hc); /* At this point the needed PCI config is done */ /* fifos are still not enabled */ return 0; } /* * remove port */ static void release_port(struct hfc_multi *hc, struct dchannel *dch) { int pt, ci, i = 0; u_long flags; struct bchannel *pb; ci = dch->slot; pt = hc->chan[ci].port; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: entered for port %d\n", __func__, pt + 1); if (pt >= hc->ports) { printk(KERN_WARNING "%s: ERROR port out of range (%d).\n", __func__, pt + 1); return; } if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: releasing port=%d\n", __func__, pt + 1); if (dch->dev.D.protocol == ISDN_P_TE_S0) l1_event(dch->l1, CLOSE_CHANNEL); hc->chan[ci].dch = NULL; if (hc->created[pt]) { hc->created[pt] = 0; mISDN_unregister_device(&dch->dev); } spin_lock_irqsave(&hc->lock, flags); if (dch->timer.function) { del_timer(&dch->timer); dch->timer.function = NULL; } if (hc->ctype == HFC_TYPE_E1) { /* E1 */ /* remove sync */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { hc->syncronized = 0; plxsd_checksync(hc, 1); } /* free channels */ for (i = 0; i <= 31; i++) { if (!((1 << i) & hc->bmask[pt])) /* skip unused chan */ continue; if (hc->chan[i].bch) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: free port %d channel %d\n", __func__, hc->chan[i].port + 1, i); pb = hc->chan[i].bch; hc->chan[i].bch = NULL; spin_unlock_irqrestore(&hc->lock, flags); mISDN_freebchannel(pb); kfree(pb); kfree(hc->chan[i].coeff); spin_lock_irqsave(&hc->lock, flags); } } } else { /* remove sync */ if (test_bit(HFC_CHIP_PLXSD, &hc->chip)) { hc->syncronized &= ~(1 << hc->chan[ci].port); plxsd_checksync(hc, 1); } /* free channels */ if (hc->chan[ci - 2].bch) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: free port %d channel %d\n", __func__, hc->chan[ci - 2].port + 1, ci - 2); pb = hc->chan[ci - 2].bch; hc->chan[ci - 2].bch = NULL; spin_unlock_irqrestore(&hc->lock, flags); mISDN_freebchannel(pb); kfree(pb); kfree(hc->chan[ci - 2].coeff); spin_lock_irqsave(&hc->lock, flags); } if (hc->chan[ci - 1].bch) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: free port %d channel %d\n", __func__, hc->chan[ci - 1].port + 1, ci - 1); pb = hc->chan[ci - 1].bch; hc->chan[ci - 1].bch = NULL; spin_unlock_irqrestore(&hc->lock, flags); mISDN_freebchannel(pb); kfree(pb); kfree(hc->chan[ci - 1].coeff); spin_lock_irqsave(&hc->lock, flags); } } spin_unlock_irqrestore(&hc->lock, flags); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: free port %d channel D(%d)\n", __func__, pt+1, ci); mISDN_freedchannel(dch); kfree(dch); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: done!\n", __func__); } static void release_card(struct hfc_multi *hc) { u_long flags; int ch; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: release card (%d) entered\n", __func__, hc->id); /* unregister clock source */ if (hc->iclock) mISDN_unregister_clock(hc->iclock); /* disable and free irq */ spin_lock_irqsave(&hc->lock, flags); disable_hwirq(hc); spin_unlock_irqrestore(&hc->lock, flags); udelay(1000); if (hc->irq) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: free irq %d (hc=%p)\n", __func__, hc->irq, hc); free_irq(hc->irq, hc); hc->irq = 0; } /* disable D-channels & B-channels */ if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: disable all channels (d and b)\n", __func__); for (ch = 0; ch <= 31; ch++) { if (hc->chan[ch].dch) release_port(hc, hc->chan[ch].dch); } /* dimm leds */ if (hc->leds) hfcmulti_leds(hc); /* release hardware */ release_io_hfcmulti(hc); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: remove instance from list\n", __func__); list_del(&hc->list); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: delete instance\n", __func__); if (hc == syncmaster) syncmaster = NULL; kfree(hc); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: card successfully removed\n", __func__); } static void init_e1_port_hw(struct hfc_multi *hc, struct hm_map *m) { /* set optical line type */ if (port[Port_cnt] & 0x001) { if (!m->opticalsupport) { printk(KERN_INFO "This board has no optical " "support\n"); } else { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT set optical " "interfacs: card(%d) " "port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CFG_OPTICAL, &hc->chan[hc->dnum[0]].cfg); } } /* set LOS report */ if (port[Port_cnt] & 0x004) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT set " "LOS report: card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CFG_REPORT_LOS, &hc->chan[hc->dnum[0]].cfg); } /* set AIS report */ if (port[Port_cnt] & 0x008) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT set " "AIS report: card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CFG_REPORT_AIS, &hc->chan[hc->dnum[0]].cfg); } /* set SLIP report */ if (port[Port_cnt] & 0x010) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT set SLIP report: " "card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CFG_REPORT_SLIP, &hc->chan[hc->dnum[0]].cfg); } /* set RDI report */ if (port[Port_cnt] & 0x020) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT set RDI report: " "card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CFG_REPORT_RDI, &hc->chan[hc->dnum[0]].cfg); } /* set CRC-4 Mode */ if (!(port[Port_cnt] & 0x100)) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT turn on CRC4 report:" " card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CFG_CRC4, &hc->chan[hc->dnum[0]].cfg); } else { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT turn off CRC4" " report: card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); } /* set forced clock */ if (port[Port_cnt] & 0x0200) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT force getting clock from " "E1: card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CHIP_E1CLOCK_GET, &hc->chip); } else if (port[Port_cnt] & 0x0400) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT force putting clock to " "E1: card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CHIP_E1CLOCK_PUT, &hc->chip); } /* set JATT PLL */ if (port[Port_cnt] & 0x0800) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT disable JATT PLL on " "E1: card(%d) port(%d)\n", __func__, HFC_cnt + 1, 1); test_and_set_bit(HFC_CHIP_RX_SYNC, &hc->chip); } /* set elastic jitter buffer */ if (port[Port_cnt] & 0x3000) { hc->chan[hc->dnum[0]].jitter = (port[Port_cnt]>>12) & 0x3; if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PORT set elastic " "buffer to %d: card(%d) port(%d)\n", __func__, hc->chan[hc->dnum[0]].jitter, HFC_cnt + 1, 1); } else hc->chan[hc->dnum[0]].jitter = 2; /* default */ } static int init_e1_port(struct hfc_multi *hc, struct hm_map *m, int pt) { struct dchannel *dch; struct bchannel *bch; int ch, ret = 0; char name[MISDN_MAX_IDLEN]; int bcount = 0; dch = kzalloc(sizeof(struct dchannel), GFP_KERNEL); if (!dch) return -ENOMEM; dch->debug = debug; mISDN_initdchannel(dch, MAX_DFRAME_LEN_L1, ph_state_change); dch->hw = hc; dch->dev.Dprotocols = (1 << ISDN_P_TE_E1) | (1 << ISDN_P_NT_E1); dch->dev.Bprotocols = (1 << (ISDN_P_B_RAW & ISDN_P_B_MASK)) | (1 << (ISDN_P_B_HDLC & ISDN_P_B_MASK)); dch->dev.D.send = handle_dmsg; dch->dev.D.ctrl = hfcm_dctrl; dch->slot = hc->dnum[pt]; hc->chan[hc->dnum[pt]].dch = dch; hc->chan[hc->dnum[pt]].port = pt; hc->chan[hc->dnum[pt]].nt_timer = -1; for (ch = 1; ch <= 31; ch++) { if (!((1 << ch) & hc->bmask[pt])) /* skip unused channel */ continue; bch = kzalloc(sizeof(struct bchannel), GFP_KERNEL); if (!bch) { printk(KERN_ERR "%s: no memory for bchannel\n", __func__); ret = -ENOMEM; goto free_chan; } hc->chan[ch].coeff = kzalloc(512, GFP_KERNEL); if (!hc->chan[ch].coeff) { printk(KERN_ERR "%s: no memory for coeffs\n", __func__); ret = -ENOMEM; kfree(bch); goto free_chan; } bch->nr = ch; bch->slot = ch; bch->debug = debug; mISDN_initbchannel(bch, MAX_DATA_MEM, poll >> 1); bch->hw = hc; bch->ch.send = handle_bmsg; bch->ch.ctrl = hfcm_bctrl; bch->ch.nr = ch; list_add(&bch->ch.list, &dch->dev.bchannels); hc->chan[ch].bch = bch; hc->chan[ch].port = pt; set_channelmap(bch->nr, dch->dev.channelmap); bcount++; } dch->dev.nrbchan = bcount; if (pt == 0) init_e1_port_hw(hc, m); if (hc->ports > 1) snprintf(name, MISDN_MAX_IDLEN - 1, "hfc-e1.%d-%d", HFC_cnt + 1, pt+1); else snprintf(name, MISDN_MAX_IDLEN - 1, "hfc-e1.%d", HFC_cnt + 1); ret = mISDN_register_device(&dch->dev, &hc->pci_dev->dev, name); if (ret) goto free_chan; hc->created[pt] = 1; return ret; free_chan: release_port(hc, dch); return ret; } static int init_multi_port(struct hfc_multi *hc, int pt) { struct dchannel *dch; struct bchannel *bch; int ch, i, ret = 0; char name[MISDN_MAX_IDLEN]; dch = kzalloc(sizeof(struct dchannel), GFP_KERNEL); if (!dch) return -ENOMEM; dch->debug = debug; mISDN_initdchannel(dch, MAX_DFRAME_LEN_L1, ph_state_change); dch->hw = hc; dch->dev.Dprotocols = (1 << ISDN_P_TE_S0) | (1 << ISDN_P_NT_S0); dch->dev.Bprotocols = (1 << (ISDN_P_B_RAW & ISDN_P_B_MASK)) | (1 << (ISDN_P_B_HDLC & ISDN_P_B_MASK)); dch->dev.D.send = handle_dmsg; dch->dev.D.ctrl = hfcm_dctrl; dch->dev.nrbchan = 2; i = pt << 2; dch->slot = i + 2; hc->chan[i + 2].dch = dch; hc->chan[i + 2].port = pt; hc->chan[i + 2].nt_timer = -1; for (ch = 0; ch < dch->dev.nrbchan; ch++) { bch = kzalloc(sizeof(struct bchannel), GFP_KERNEL); if (!bch) { printk(KERN_ERR "%s: no memory for bchannel\n", __func__); ret = -ENOMEM; goto free_chan; } hc->chan[i + ch].coeff = kzalloc(512, GFP_KERNEL); if (!hc->chan[i + ch].coeff) { printk(KERN_ERR "%s: no memory for coeffs\n", __func__); ret = -ENOMEM; kfree(bch); goto free_chan; } bch->nr = ch + 1; bch->slot = i + ch; bch->debug = debug; mISDN_initbchannel(bch, MAX_DATA_MEM, poll >> 1); bch->hw = hc; bch->ch.send = handle_bmsg; bch->ch.ctrl = hfcm_bctrl; bch->ch.nr = ch + 1; list_add(&bch->ch.list, &dch->dev.bchannels); hc->chan[i + ch].bch = bch; hc->chan[i + ch].port = pt; set_channelmap(bch->nr, dch->dev.channelmap); } /* set master clock */ if (port[Port_cnt] & 0x001) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PROTOCOL set master clock: " "card(%d) port(%d)\n", __func__, HFC_cnt + 1, pt + 1); if (dch->dev.D.protocol != ISDN_P_TE_S0) { printk(KERN_ERR "Error: Master clock " "for port(%d) of card(%d) is only" " possible with TE-mode\n", pt + 1, HFC_cnt + 1); ret = -EINVAL; goto free_chan; } if (hc->masterclk >= 0) { printk(KERN_ERR "Error: Master clock " "for port(%d) of card(%d) already " "defined for port(%d)\n", pt + 1, HFC_cnt + 1, hc->masterclk + 1); ret = -EINVAL; goto free_chan; } hc->masterclk = pt; } /* set transmitter line to non capacitive */ if (port[Port_cnt] & 0x002) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PROTOCOL set non capacitive " "transmitter: card(%d) port(%d)\n", __func__, HFC_cnt + 1, pt + 1); test_and_set_bit(HFC_CFG_NONCAP_TX, &hc->chan[i + 2].cfg); } /* disable E-channel */ if (port[Port_cnt] & 0x004) { if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: PROTOCOL disable E-channel: " "card(%d) port(%d)\n", __func__, HFC_cnt + 1, pt + 1); test_and_set_bit(HFC_CFG_DIS_ECHANNEL, &hc->chan[i + 2].cfg); } if (hc->ctype == HFC_TYPE_XHFC) { snprintf(name, MISDN_MAX_IDLEN - 1, "xhfc.%d-%d", HFC_cnt + 1, pt + 1); ret = mISDN_register_device(&dch->dev, NULL, name); } else { snprintf(name, MISDN_MAX_IDLEN - 1, "hfc-%ds.%d-%d", hc->ctype, HFC_cnt + 1, pt + 1); ret = mISDN_register_device(&dch->dev, &hc->pci_dev->dev, name); } if (ret) goto free_chan; hc->created[pt] = 1; return ret; free_chan: release_port(hc, dch); return ret; } static int hfcmulti_init(struct hm_map *m, struct pci_dev *pdev, const struct pci_device_id *ent) { int ret_err = 0; int pt; struct hfc_multi *hc; u_long flags; u_char dips = 0, pmj = 0; /* dip settings, port mode Jumpers */ int i, ch; u_int maskcheck; if (HFC_cnt >= MAX_CARDS) { printk(KERN_ERR "too many cards (max=%d).\n", MAX_CARDS); return -EINVAL; } if ((type[HFC_cnt] & 0xff) && (type[HFC_cnt] & 0xff) != m->type) { printk(KERN_WARNING "HFC-MULTI: Card '%s:%s' type %d found but " "type[%d] %d was supplied as module parameter\n", m->vendor_name, m->card_name, m->type, HFC_cnt, type[HFC_cnt] & 0xff); printk(KERN_WARNING "HFC-MULTI: Load module without parameters " "first, to see cards and their types."); return -EINVAL; } if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: Registering %s:%s chip type %d (0x%x)\n", __func__, m->vendor_name, m->card_name, m->type, type[HFC_cnt]); /* allocate card+fifo structure */ hc = kzalloc(sizeof(struct hfc_multi), GFP_KERNEL); if (!hc) { printk(KERN_ERR "No kmem for HFC-Multi card\n"); return -ENOMEM; } spin_lock_init(&hc->lock); hc->mtyp = m; hc->ctype = m->type; hc->ports = m->ports; hc->id = HFC_cnt; hc->pcm = pcm[HFC_cnt]; hc->io_mode = iomode[HFC_cnt]; if (hc->ctype == HFC_TYPE_E1 && dmask[E1_cnt]) { /* fragment card */ pt = 0; maskcheck = 0; for (ch = 0; ch <= 31; ch++) { if (!((1 << ch) & dmask[E1_cnt])) continue; hc->dnum[pt] = ch; hc->bmask[pt] = bmask[bmask_cnt++]; if ((maskcheck & hc->bmask[pt]) || (dmask[E1_cnt] & hc->bmask[pt])) { printk(KERN_INFO "HFC-E1 #%d has overlapping B-channels on fragment #%d\n", E1_cnt + 1, pt); kfree(hc); return -EINVAL; } maskcheck |= hc->bmask[pt]; printk(KERN_INFO "HFC-E1 #%d uses D-channel on slot %d and a B-channel map of 0x%08x\n", E1_cnt + 1, ch, hc->bmask[pt]); pt++; } hc->ports = pt; } if (hc->ctype == HFC_TYPE_E1 && !dmask[E1_cnt]) { /* default card layout */ hc->dnum[0] = 16; hc->bmask[0] = 0xfffefffe; hc->ports = 1; } /* set chip specific features */ hc->masterclk = -1; if (type[HFC_cnt] & 0x100) { test_and_set_bit(HFC_CHIP_ULAW, &hc->chip); hc->silence = 0xff; /* ulaw silence */ } else hc->silence = 0x2a; /* alaw silence */ if ((poll >> 1) > sizeof(hc->silence_data)) { printk(KERN_ERR "HFCMULTI error: silence_data too small, " "please fix\n"); kfree(hc); return -EINVAL; } for (i = 0; i < (poll >> 1); i++) hc->silence_data[i] = hc->silence; if (hc->ctype != HFC_TYPE_XHFC) { if (!(type[HFC_cnt] & 0x200)) test_and_set_bit(HFC_CHIP_DTMF, &hc->chip); test_and_set_bit(HFC_CHIP_CONF, &hc->chip); } if (type[HFC_cnt] & 0x800) test_and_set_bit(HFC_CHIP_PCM_SLAVE, &hc->chip); if (type[HFC_cnt] & 0x1000) { test_and_set_bit(HFC_CHIP_PCM_MASTER, &hc->chip); test_and_clear_bit(HFC_CHIP_PCM_SLAVE, &hc->chip); } if (type[HFC_cnt] & 0x4000) test_and_set_bit(HFC_CHIP_EXRAM_128, &hc->chip); if (type[HFC_cnt] & 0x8000) test_and_set_bit(HFC_CHIP_EXRAM_512, &hc->chip); hc->slots = 32; if (type[HFC_cnt] & 0x10000) hc->slots = 64; if (type[HFC_cnt] & 0x20000) hc->slots = 128; if (type[HFC_cnt] & 0x80000) { test_and_set_bit(HFC_CHIP_WATCHDOG, &hc->chip); hc->wdcount = 0; hc->wdbyte = V_GPIO_OUT2; printk(KERN_NOTICE "Watchdog enabled\n"); } if (pdev && ent) /* setup pci, hc->slots may change due to PLXSD */ ret_err = setup_pci(hc, pdev, ent); else #ifdef CONFIG_MISDN_HFCMULTI_8xx ret_err = setup_embedded(hc, m); #else { printk(KERN_WARNING "Embedded IO Mode not selected\n"); ret_err = -EIO; } #endif if (ret_err) { if (hc == syncmaster) syncmaster = NULL; kfree(hc); return ret_err; } hc->HFC_outb_nodebug = hc->HFC_outb; hc->HFC_inb_nodebug = hc->HFC_inb; hc->HFC_inw_nodebug = hc->HFC_inw; hc->HFC_wait_nodebug = hc->HFC_wait; #ifdef HFC_REGISTER_DEBUG hc->HFC_outb = HFC_outb_debug; hc->HFC_inb = HFC_inb_debug; hc->HFC_inw = HFC_inw_debug; hc->HFC_wait = HFC_wait_debug; #endif /* create channels */ for (pt = 0; pt < hc->ports; pt++) { if (Port_cnt >= MAX_PORTS) { printk(KERN_ERR "too many ports (max=%d).\n", MAX_PORTS); ret_err = -EINVAL; goto free_card; } if (hc->ctype == HFC_TYPE_E1) ret_err = init_e1_port(hc, m, pt); else ret_err = init_multi_port(hc, pt); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: Registering D-channel, card(%d) port(%d) " "result %d\n", __func__, HFC_cnt + 1, pt + 1, ret_err); if (ret_err) { while (pt) { /* release already registered ports */ pt--; if (hc->ctype == HFC_TYPE_E1) release_port(hc, hc->chan[hc->dnum[pt]].dch); else release_port(hc, hc->chan[(pt << 2) + 2].dch); } goto free_card; } if (hc->ctype != HFC_TYPE_E1) Port_cnt++; /* for each S0 port */ } if (hc->ctype == HFC_TYPE_E1) { Port_cnt++; /* for each E1 port */ E1_cnt++; } /* disp switches */ switch (m->dip_type) { case DIP_4S: /* * Get DIP setting for beroNet 1S/2S/4S cards * DIP Setting: (collect GPIO 13/14/15 (R_GPIO_IN1) + * GPI 19/23 (R_GPI_IN2)) */ dips = ((~HFC_inb(hc, R_GPIO_IN1) & 0xE0) >> 5) | ((~HFC_inb(hc, R_GPI_IN2) & 0x80) >> 3) | (~HFC_inb(hc, R_GPI_IN2) & 0x08); /* Port mode (TE/NT) jumpers */ pmj = ((HFC_inb(hc, R_GPI_IN3) >> 4) & 0xf); if (test_bit(HFC_CHIP_B410P, &hc->chip)) pmj = ~pmj & 0xf; printk(KERN_INFO "%s: %s DIPs(0x%x) jumpers(0x%x)\n", m->vendor_name, m->card_name, dips, pmj); break; case DIP_8S: /* * Get DIP Setting for beroNet 8S0+ cards * Enable PCI auxbridge function */ HFC_outb(hc, R_BRG_PCM_CFG, 1 | V_PCM_CLK); /* prepare access to auxport */ outw(0x4000, hc->pci_iobase + 4); /* * some dummy reads are required to * read valid DIP switch data */ dips = inb(hc->pci_iobase); dips = inb(hc->pci_iobase); dips = inb(hc->pci_iobase); dips = ~inb(hc->pci_iobase) & 0x3F; outw(0x0, hc->pci_iobase + 4); /* disable PCI auxbridge function */ HFC_outb(hc, R_BRG_PCM_CFG, V_PCM_CLK); printk(KERN_INFO "%s: %s DIPs(0x%x)\n", m->vendor_name, m->card_name, dips); break; case DIP_E1: /* * get DIP Setting for beroNet E1 cards * DIP Setting: collect GPI 4/5/6/7 (R_GPI_IN0) */ dips = (~HFC_inb(hc, R_GPI_IN0) & 0xF0) >> 4; printk(KERN_INFO "%s: %s DIPs(0x%x)\n", m->vendor_name, m->card_name, dips); break; } /* add to list */ spin_lock_irqsave(&HFClock, flags); list_add_tail(&hc->list, &HFClist); spin_unlock_irqrestore(&HFClock, flags); /* use as clock source */ if (clock == HFC_cnt + 1) hc->iclock = mISDN_register_clock("HFCMulti", 0, clockctl, hc); /* initialize hardware */ hc->irq = (m->irq) ? : hc->pci_dev->irq; ret_err = init_card(hc); if (ret_err) { printk(KERN_ERR "init card returns %d\n", ret_err); release_card(hc); return ret_err; } /* start IRQ and return */ spin_lock_irqsave(&hc->lock, flags); enable_hwirq(hc); spin_unlock_irqrestore(&hc->lock, flags); return 0; free_card: release_io_hfcmulti(hc); if (hc == syncmaster) syncmaster = NULL; kfree(hc); return ret_err; } static void hfc_remove_pci(struct pci_dev *pdev) { struct hfc_multi *card = pci_get_drvdata(pdev); u_long flags; if (debug) printk(KERN_INFO "removing hfc_multi card vendor:%x " "device:%x subvendor:%x subdevice:%x\n", pdev->vendor, pdev->device, pdev->subsystem_vendor, pdev->subsystem_device); if (card) { spin_lock_irqsave(&HFClock, flags); release_card(card); spin_unlock_irqrestore(&HFClock, flags); } else { if (debug) printk(KERN_DEBUG "%s: drvdata already removed\n", __func__); } } #define VENDOR_CCD "Cologne Chip AG" #define VENDOR_BN "beroNet GmbH" #define VENDOR_DIG "Digium Inc." #define VENDOR_JH "Junghanns.NET GmbH" #define VENDOR_PRIM "PrimuX" static const struct hm_map hfcm_map[] = { /*0*/ {VENDOR_BN, "HFC-1S Card (mini PCI)", 4, 1, 1, 3, 0, DIP_4S, 0, 0}, /*1*/ {VENDOR_BN, "HFC-2S Card", 4, 2, 1, 3, 0, DIP_4S, 0, 0}, /*2*/ {VENDOR_BN, "HFC-2S Card (mini PCI)", 4, 2, 1, 3, 0, DIP_4S, 0, 0}, /*3*/ {VENDOR_BN, "HFC-4S Card", 4, 4, 1, 2, 0, DIP_4S, 0, 0}, /*4*/ {VENDOR_BN, "HFC-4S Card (mini PCI)", 4, 4, 1, 2, 0, 0, 0, 0}, /*5*/ {VENDOR_CCD, "HFC-4S Eval (old)", 4, 4, 0, 0, 0, 0, 0, 0}, /*6*/ {VENDOR_CCD, "HFC-4S IOB4ST", 4, 4, 1, 2, 0, DIP_4S, 0, 0}, /*7*/ {VENDOR_CCD, "HFC-4S", 4, 4, 1, 2, 0, 0, 0, 0}, /*8*/ {VENDOR_DIG, "HFC-4S Card", 4, 4, 0, 2, 0, 0, HFC_IO_MODE_REGIO, 0}, /*9*/ {VENDOR_CCD, "HFC-4S Swyx 4xS0 SX2 QuadBri", 4, 4, 1, 2, 0, 0, 0, 0}, /*10*/ {VENDOR_JH, "HFC-4S (junghanns 2.0)", 4, 4, 1, 2, 0, 0, 0, 0}, /*11*/ {VENDOR_PRIM, "HFC-2S Primux Card", 4, 2, 0, 0, 0, 0, 0, 0}, /*12*/ {VENDOR_BN, "HFC-8S Card", 8, 8, 1, 0, 0, 0, 0, 0}, /*13*/ {VENDOR_BN, "HFC-8S Card (+)", 8, 8, 1, 8, 0, DIP_8S, HFC_IO_MODE_REGIO, 0}, /*14*/ {VENDOR_CCD, "HFC-8S Eval (old)", 8, 8, 0, 0, 0, 0, 0, 0}, /*15*/ {VENDOR_CCD, "HFC-8S IOB4ST Recording", 8, 8, 1, 0, 0, 0, 0, 0}, /*16*/ {VENDOR_CCD, "HFC-8S IOB8ST", 8, 8, 1, 0, 0, 0, 0, 0}, /*17*/ {VENDOR_CCD, "HFC-8S", 8, 8, 1, 0, 0, 0, 0, 0}, /*18*/ {VENDOR_CCD, "HFC-8S", 8, 8, 1, 0, 0, 0, 0, 0}, /*19*/ {VENDOR_BN, "HFC-E1 Card", 1, 1, 0, 1, 0, DIP_E1, 0, 0}, /*20*/ {VENDOR_BN, "HFC-E1 Card (mini PCI)", 1, 1, 0, 1, 0, 0, 0, 0}, /*21*/ {VENDOR_BN, "HFC-E1+ Card (Dual)", 1, 1, 0, 1, 0, DIP_E1, 0, 0}, /*22*/ {VENDOR_BN, "HFC-E1 Card (Dual)", 1, 1, 0, 1, 0, DIP_E1, 0, 0}, /*23*/ {VENDOR_CCD, "HFC-E1 Eval (old)", 1, 1, 0, 0, 0, 0, 0, 0}, /*24*/ {VENDOR_CCD, "HFC-E1 IOB1E1", 1, 1, 0, 1, 0, 0, 0, 0}, /*25*/ {VENDOR_CCD, "HFC-E1", 1, 1, 0, 1, 0, 0, 0, 0}, /*26*/ {VENDOR_CCD, "HFC-4S Speech Design", 4, 4, 0, 0, 0, 0, HFC_IO_MODE_PLXSD, 0}, /*27*/ {VENDOR_CCD, "HFC-E1 Speech Design", 1, 1, 0, 0, 0, 0, HFC_IO_MODE_PLXSD, 0}, /*28*/ {VENDOR_CCD, "HFC-4S OpenVox", 4, 4, 1, 0, 0, 0, 0, 0}, /*29*/ {VENDOR_CCD, "HFC-2S OpenVox", 4, 2, 1, 0, 0, 0, 0, 0}, /*30*/ {VENDOR_CCD, "HFC-8S OpenVox", 8, 8, 1, 0, 0, 0, 0, 0}, /*31*/ {VENDOR_CCD, "XHFC-4S Speech Design", 5, 4, 0, 0, 0, 0, HFC_IO_MODE_EMBSD, XHFC_IRQ}, /*32*/ {VENDOR_JH, "HFC-8S (junghanns)", 8, 8, 1, 0, 0, 0, 0, 0}, /*33*/ {VENDOR_BN, "HFC-2S Beronet Card PCIe", 4, 2, 1, 3, 0, DIP_4S, 0, 0}, /*34*/ {VENDOR_BN, "HFC-4S Beronet Card PCIe", 4, 4, 1, 2, 0, DIP_4S, 0, 0}, }; #undef H #define H(x) ((unsigned long)&hfcm_map[x]) static const struct pci_device_id hfmultipci_ids[] = { /* Cards with HFC-4S Chip */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BN1SM, 0, 0, H(0)}, /* BN1S mini PCI */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BN2S, 0, 0, H(1)}, /* BN2S */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BN2SM, 0, 0, H(2)}, /* BN2S mini PCI */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BN4S, 0, 0, H(3)}, /* BN4S */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BN4SM, 0, 0, H(4)}, /* BN4S mini PCI */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, 0, 0, H(5)}, /* Old Eval */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_IOB4ST, 0, 0, H(6)}, /* IOB4ST */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_HFC4S, 0, 0, H(7)}, /* 4S */ { PCI_VENDOR_ID_DIGIUM, PCI_DEVICE_ID_DIGIUM_HFC4S, PCI_VENDOR_ID_DIGIUM, PCI_DEVICE_ID_DIGIUM_HFC4S, 0, 0, H(8)}, { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_SWYX4S, 0, 0, H(9)}, /* 4S Swyx */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_JH4S20, 0, 0, H(10)}, { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_PMX2S, 0, 0, H(11)}, /* Primux */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_OV4S, 0, 0, H(28)}, /* OpenVox 4 */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_OV2S, 0, 0, H(29)}, /* OpenVox 2 */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, 0xb761, 0, 0, H(33)}, /* BN2S PCIe */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC4S, PCI_VENDOR_ID_CCD, 0xb762, 0, 0, H(34)}, /* BN4S PCIe */ /* Cards with HFC-8S Chip */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BN8S, 0, 0, H(12)}, /* BN8S */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BN8SP, 0, 0, H(13)}, /* BN8S+ */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, 0, 0, H(14)}, /* old Eval */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_IOB8STR, 0, 0, H(15)}, /* IOB8ST Recording */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_IOB8ST, 0, 0, H(16)}, /* IOB8ST */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_IOB8ST_1, 0, 0, H(17)}, /* IOB8ST */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_HFC8S, 0, 0, H(18)}, /* 8S */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_OV8S, 0, 0, H(30)}, /* OpenVox 8 */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFC8S, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_JH8S, 0, 0, H(32)}, /* Junganns 8S */ /* Cards with HFC-E1 Chip */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BNE1, 0, 0, H(19)}, /* BNE1 */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BNE1M, 0, 0, H(20)}, /* BNE1 mini PCI */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BNE1DP, 0, 0, H(21)}, /* BNE1 + (Dual) */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_BNE1D, 0, 0, H(22)}, /* BNE1 (Dual) */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, 0, 0, H(23)}, /* Old Eval */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_IOB1E1, 0, 0, H(24)}, /* IOB1E1 */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_HFCE1, 0, 0, H(25)}, /* E1 */ { PCI_VENDOR_ID_PLX, PCI_DEVICE_ID_PLX_9030, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_SPD4S, 0, 0, H(26)}, /* PLX PCI Bridge */ { PCI_VENDOR_ID_PLX, PCI_DEVICE_ID_PLX_9030, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_SPDE1, 0, 0, H(27)}, /* PLX PCI Bridge */ { PCI_VENDOR_ID_CCD, PCI_DEVICE_ID_CCD_HFCE1, PCI_VENDOR_ID_CCD, PCI_SUBDEVICE_ID_CCD_JHSE1, 0, 0, H(25)}, /* Junghanns E1 */ { PCI_VDEVICE(CCD, PCI_DEVICE_ID_CCD_HFC4S), 0 }, { PCI_VDEVICE(CCD, PCI_DEVICE_ID_CCD_HFC8S), 0 }, { PCI_VDEVICE(CCD, PCI_DEVICE_ID_CCD_HFCE1), 0 }, {0, } }; #undef H MODULE_DEVICE_TABLE(pci, hfmultipci_ids); static int hfcmulti_probe(struct pci_dev *pdev, const struct pci_device_id *ent) { struct hm_map *m = (struct hm_map *)ent->driver_data; int ret; if (m == NULL && ent->vendor == PCI_VENDOR_ID_CCD && ( ent->device == PCI_DEVICE_ID_CCD_HFC4S || ent->device == PCI_DEVICE_ID_CCD_HFC8S || ent->device == PCI_DEVICE_ID_CCD_HFCE1)) { printk(KERN_ERR "Unknown HFC multiport controller (vendor:%04x device:%04x " "subvendor:%04x subdevice:%04x)\n", pdev->vendor, pdev->device, pdev->subsystem_vendor, pdev->subsystem_device); printk(KERN_ERR "Please contact the driver maintainer for support.\n"); return -ENODEV; } ret = hfcmulti_init(m, pdev, ent); if (ret) return ret; HFC_cnt++; printk(KERN_INFO "%d devices registered\n", HFC_cnt); return 0; } static struct pci_driver hfcmultipci_driver = { .name = "hfc_multi", .probe = hfcmulti_probe, .remove = hfc_remove_pci, .id_table = hfmultipci_ids, }; static void __exit HFCmulti_cleanup(void) { struct hfc_multi *card, *next; /* get rid of all devices of this driver */ list_for_each_entry_safe(card, next, &HFClist, list) release_card(card); pci_unregister_driver(&hfcmultipci_driver); } static int __init HFCmulti_init(void) { int err; int i, xhfc = 0; struct hm_map m; printk(KERN_INFO "mISDN: HFC-multi driver %s\n", HFC_MULTI_VERSION); #ifdef IRQ_DEBUG printk(KERN_DEBUG "%s: IRQ_DEBUG IS ENABLED!\n", __func__); #endif spin_lock_init(&HFClock); spin_lock_init(&plx_lock); if (debug & DEBUG_HFCMULTI_INIT) printk(KERN_DEBUG "%s: init entered\n", __func__); switch (poll) { case 0: poll_timer = 6; poll = 128; break; case 8: poll_timer = 2; break; case 16: poll_timer = 3; break; case 32: poll_timer = 4; break; case 64: poll_timer = 5; break; case 128: poll_timer = 6; break; case 256: poll_timer = 7; break; default: printk(KERN_ERR "%s: Wrong poll value (%d).\n", __func__, poll); err = -EINVAL; return err; } if (!clock) clock = 1; /* Register the embedded devices. * This should be done before the PCI cards registration */ switch (hwid) { case HWID_MINIP4: xhfc = 1; m = hfcm_map[31]; break; case HWID_MINIP8: xhfc = 2; m = hfcm_map[31]; break; case HWID_MINIP16: xhfc = 4; m = hfcm_map[31]; break; default: xhfc = 0; } for (i = 0; i < xhfc; ++i) { err = hfcmulti_init(&m, NULL, NULL); if (err) { printk(KERN_ERR "error registering embedded driver: " "%x\n", err); return err; } HFC_cnt++; printk(KERN_INFO "%d devices registered\n", HFC_cnt); } /* Register the PCI cards */ err = pci_register_driver(&hfcmultipci_driver); if (err < 0) { printk(KERN_ERR "error registering pci driver: %x\n", err); return err; } return 0; } module_init(HFCmulti_init); module_exit(HFCmulti_cleanup);