Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/usb/ucom/@/dev/cx/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/usb/ucom/@/dev/cx/cxddk.c |
/*- * Cronyx-Sigma Driver Development Kit. * * Copyright (C) 1998 Cronyx Engineering. * Author: Pavel Novikov, <pavel@inr.net.kiae.su> * * Copyright (C) 1998-2003 Cronyx Engineering. * Author: Roman Kurakin, <rik@cronyx.ru> * * This software is distributed with NO WARRANTIES, not even the implied * warranties for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * * Authors grant any other persons or organisations permission to use * or modify this software as long as this message is kept with the software, * all derivative works or modified versions. * * Cronyx Id: cxddk.c,v 1.1.2.2 2003/11/27 14:24:50 rik Exp $ */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/dev/cx/cxddk.c 139749 2005-01-06 01:43:34Z imp $"); #include <dev/cx/machdep.h> #include <dev/cx/cxddk.h> #include <dev/cx/cxreg.h> #include <dev/cx/cronyxfw.h> #include <dev/cx/csigmafw.h> #define BYTE *(unsigned char*)& /* standard base port set */ static short porttab [] = { 0x200, 0x220, 0x240, 0x260, 0x280, 0x2a0, 0x2c0, 0x2e0, 0x300, 0x320, 0x340, 0x360, 0x380, 0x3a0, 0x3c0, 0x3e0, 0 }; /* * Compute the optimal size of the receive buffer. */ static int cx_compute_buf_len (cx_chan_t *c) { int rbsz; if (c->mode == M_ASYNC) { rbsz = (c->rxbaud + 800 - 1) / 800 * 2; if (rbsz < 4) rbsz = 4; else if (rbsz > DMABUFSZ) rbsz = DMABUFSZ; } else rbsz = DMABUFSZ; return rbsz; } /* * Auto-detect the installed adapters. */ int cx_find (port_t *board_ports) { int i, n; for (i=0, n=0; porttab[i] && n<NBRD; i++) if (cx_probe_board (porttab[i], -1, -1)) board_ports[n++] = porttab[i]; return n; } /* * Initialize the adapter. */ int cx_open_board (cx_board_t *b, int num, port_t port, int irq, int dma) { cx_chan_t *c; if (num >= NBRD || ! cx_probe_board (port, irq, dma)) return 0; /* init callback pointers */ for (c=b->chan; c<b->chan+NCHAN; ++c) { c->call_on_tx = 0; c->call_on_rx = 0; c->call_on_msig = 0; c->call_on_err = 0; } cx_init (b, num, port, irq, dma); /* Loading firmware */ if (! cx_setup_board (b, csigma_fw_data, csigma_fw_len, csigma_fw_tvec)) return 0; return 1; } /* * Shutdown the adapter. */ void cx_close_board (cx_board_t *b) { cx_setup_board (b, 0, 0, 0); /* Reset the controller. */ outb (BCR0(b->port), 0); if (b->chan[8].type || b->chan[12].type) outb (BCR0(b->port+0x10), 0); } /* * Start the channel. */ void cx_start_chan (cx_chan_t *c, cx_buf_t *cb, unsigned long phys) { int command = 0; int mode = 0; int ier = 0; int rbsz; c->overflow = 0; /* Setting up buffers */ if (cb) { c->arbuf = cb->rbuffer[0]; c->brbuf = cb->rbuffer[1]; c->atbuf = cb->tbuffer[0]; c->btbuf = cb->tbuffer[1]; c->arphys = phys + ((char*)c->arbuf - (char*)cb); c->brphys = phys + ((char*)c->brbuf - (char*)cb); c->atphys = phys + ((char*)c->atbuf - (char*)cb); c->btphys = phys + ((char*)c->btbuf - (char*)cb); } /* Set current channel number */ outb (CAR(c->port), c->num & 3); /* set receiver A buffer physical address */ outw (ARBADRU(c->port), (unsigned short) (c->arphys>>16)); outw (ARBADRL(c->port), (unsigned short) c->arphys); /* set receiver B buffer physical address */ outw (BRBADRU(c->port), (unsigned short) (c->brphys>>16)); outw (BRBADRL(c->port), (unsigned short) c->brphys); /* set transmitter A buffer physical address */ outw (ATBADRU(c->port), (unsigned short) (c->atphys>>16)); outw (ATBADRL(c->port), (unsigned short) c->atphys); /* set transmitter B buffer physical address */ outw (BTBADRU(c->port), (unsigned short) (c->btphys>>16)); outw (BTBADRL(c->port), (unsigned short) c->btphys); /* rx */ command |= CCR_ENRX; ier |= IER_RXD; if (c->board->dma) { mode |= CMR_RXDMA; if (c->mode == M_ASYNC) ier |= IER_RET; } /* tx */ command |= CCR_ENTX; ier |= (c->mode == M_ASYNC) ? IER_TXD : (IER_TXD | IER_TXMPTY); if (c->board->dma) mode |= CMR_TXDMA; /* Set mode */ outb (CMR(c->port), mode | (c->mode == M_ASYNC ? CMR_ASYNC : CMR_HDLC)); /* Clear and initialize channel */ cx_cmd (c->port, CCR_CLRCH); cx_cmd (c->port, CCR_INITCH | command); if (c->mode == M_ASYNC) cx_cmd (c->port, CCR_ENTX); /* Start receiver */ rbsz = cx_compute_buf_len(c); outw (ARBCNT(c->port), rbsz); outw (BRBCNT(c->port), rbsz); outw (ARBSTS(c->port), BSTS_OWN24); outw (BRBSTS(c->port), BSTS_OWN24); if (c->mode == M_ASYNC) ier |= IER_MDM; /* Enable interrupts */ outb (IER(c->port), ier); /* Clear DTR and RTS */ cx_set_dtr (c, 0); cx_set_rts (c, 0); } /* * Turn the receiver on/off. */ void cx_enable_receive (cx_chan_t *c, int on) { unsigned char ier; if (cx_receive_enabled(c) && ! on) { outb (CAR(c->port), c->num & 3); if (c->mode == M_ASYNC) { ier = inb (IER(c->port)); outb (IER(c->port), ier & ~ (IER_RXD | IER_RET)); } cx_cmd (c->port, CCR_DISRX); } else if (! cx_receive_enabled(c) && on) { outb (CAR(c->port), c->num & 3); ier = inb (IER(c->port)); if (c->mode == M_ASYNC) outb (IER(c->port), ier | (IER_RXD | IER_RET)); else outb (IER(c->port), ier | IER_RXD); cx_cmd (c->port, CCR_ENRX); } } /* * Turn the transmiter on/off. */ void cx_enable_transmit (cx_chan_t *c, int on) { if (cx_transmit_enabled(c) && ! on) { outb (CAR(c->port), c->num & 3); if (c->mode != M_ASYNC) outb (STCR(c->port), STC_ABORTTX | STC_SNDSPC); cx_cmd (c->port, CCR_DISTX); } else if (! cx_transmit_enabled(c) && on) { outb (CAR(c->port), c->num & 3); cx_cmd (c->port, CCR_ENTX); } } /* * Get channel status. */ int cx_receive_enabled (cx_chan_t *c) { outb (CAR(c->port), c->num & 3); return (inb (CSR(c->port)) & CSRA_RXEN) != 0; } int cx_transmit_enabled (cx_chan_t *c) { outb (CAR(c->port), c->num & 3); return (inb (CSR(c->port)) & CSRA_TXEN) != 0; } unsigned long cx_get_baud (cx_chan_t *c) { return (c->opt.tcor.clk == CLK_EXT) ? 0 : c->txbaud; } int cx_get_loop (cx_chan_t *c) { return c->opt.tcor.llm ? 1 : 0; } int cx_get_nrzi (cx_chan_t *c) { return c->opt.rcor.encod == ENCOD_NRZI; } int cx_get_dpll (cx_chan_t *c) { return c->opt.rcor.dpll ? 1 : 0; } void cx_set_baud (cx_chan_t *c, unsigned long bps) { int clock, period; c->txbaud = c->rxbaud = bps; /* Set current channel number */ outb (CAR(c->port), c->num & 3); if (bps) { if (c->mode == M_ASYNC || c->opt.rcor.dpll || c->opt.tcor.llm) { /* Receive baud - internal */ cx_clock (c->oscfreq, c->rxbaud, &clock, &period); c->opt.rcor.clk = clock; outb (RCOR(c->port), BYTE c->opt.rcor); outb (RBPR(c->port), period); } else { /* Receive baud - external */ c->opt.rcor.clk = CLK_EXT; outb (RCOR(c->port), BYTE c->opt.rcor); outb (RBPR(c->port), 1); } /* Transmit baud - internal */ cx_clock (c->oscfreq, c->txbaud, &clock, &period); c->opt.tcor.clk = clock; c->opt.tcor.ext1x = 0; outb (TBPR(c->port), period); } else if (c->mode != M_ASYNC) { /* External clock - disable local loopback and DPLL */ c->opt.tcor.llm = 0; c->opt.rcor.dpll = 0; /* Transmit baud - external */ c->opt.tcor.ext1x = 1; c->opt.tcor.clk = CLK_EXT; outb (TBPR(c->port), 1); /* Receive baud - external */ c->opt.rcor.clk = CLK_EXT; outb (RCOR(c->port), BYTE c->opt.rcor); outb (RBPR(c->port), 1); } if (c->opt.tcor.llm) outb (COR2(c->port), (BYTE c->hopt.cor2) & ~3); else outb (COR2(c->port), BYTE c->hopt.cor2); outb (TCOR(c->port), BYTE c->opt.tcor); } void cx_set_loop (cx_chan_t *c, int on) { if (! c->txbaud) return; c->opt.tcor.llm = on ? 1 : 0; cx_set_baud (c, c->txbaud); } void cx_set_dpll (cx_chan_t *c, int on) { if (! c->txbaud) return; c->opt.rcor.dpll = on ? 1 : 0; cx_set_baud (c, c->txbaud); } void cx_set_nrzi (cx_chan_t *c, int nrzi) { c->opt.rcor.encod = (nrzi ? ENCOD_NRZI : ENCOD_NRZ); outb (CAR(c->port), c->num & 3); outb (RCOR(c->port), BYTE c->opt.rcor); } static int cx_send (cx_chan_t *c, char *data, int len, void *attachment) { unsigned char *buf; port_t cnt_port, sts_port; void **attp; /* Set the current channel number. */ outb (CAR(c->port), c->num & 3); /* Determine the buffer order. */ if (inb (DMABSTS(c->port)) & DMABSTS_NTBUF) { if (inb (BTBSTS(c->port)) & BSTS_OWN24) { buf = c->atbuf; cnt_port = ATBCNT(c->port); sts_port = ATBSTS(c->port); attp = &c->attach[0]; } else { buf = c->btbuf; cnt_port = BTBCNT(c->port); sts_port = BTBSTS(c->port); attp = &c->attach[1]; } } else { if (inb (ATBSTS(c->port)) & BSTS_OWN24) { buf = c->btbuf; cnt_port = BTBCNT(c->port); sts_port = BTBSTS(c->port); attp = &c->attach[1]; } else { buf = c->atbuf; cnt_port = ATBCNT(c->port); sts_port = ATBSTS(c->port); attp = &c->attach[0]; } } /* Is it busy? */ if (inb (sts_port) & BSTS_OWN24) return -1; memcpy (buf, data, len); *attp = attachment; /* Start transmitter. */ outw (cnt_port, len); outb (sts_port, BSTS_EOFR | BSTS_INTR | BSTS_OWN24); /* Enable TXMPTY interrupt, * to catch the case when the second buffer is empty. */ if (c->mode != M_ASYNC) { if ((inb(ATBSTS(c->port)) & BSTS_OWN24) && (inb(BTBSTS(c->port)) & BSTS_OWN24)) { outb (IER(c->port), IER_RXD | IER_TXD | IER_TXMPTY); } else outb (IER(c->port), IER_RXD | IER_TXD); } return 0; } /* * Number of free buffs */ int cx_buf_free (cx_chan_t *c) { return ! (inb (ATBSTS(c->port)) & BSTS_OWN24) + ! (inb (BTBSTS(c->port)) & BSTS_OWN24); } /* * Send the data packet. */ int cx_send_packet (cx_chan_t *c, char *data, int len, void *attachment) { if (len >= DMABUFSZ) return -2; if (c->mode == M_ASYNC) { static char buf [DMABUFSZ]; char *p, *t = buf; /* Async -- double all nulls. */ for (p=data; p < data+len && t < buf+DMABUFSZ-1; ++p) if ((*t++ = *p) == 0) *t++ = 0; return cx_send (c, buf, t-buf, attachment); } return cx_send (c, data, len, attachment); } static int cx_receive_interrupt (cx_chan_t *c) { unsigned short risr; int len = 0, rbsz; ++c->rintr; risr = inw (RISR(c->port)); /* Compute optimal receiver buffer length */ rbsz = cx_compute_buf_len(c); if (c->mode == M_ASYNC && (risr & RISA_TIMEOUT)) { unsigned long rcbadr = (unsigned short) inw (RCBADRL(c->port)) | (long) inw (RCBADRU(c->port)) << 16; unsigned char *buf = 0; port_t cnt_port = 0, sts_port = 0; if (rcbadr >= c->brphys && rcbadr < c->brphys+DMABUFSZ) { buf = c->brbuf; len = rcbadr - c->brphys; cnt_port = BRBCNT(c->port); sts_port = BRBSTS(c->port); } else if (rcbadr >= c->arphys && rcbadr < c->arphys+DMABUFSZ) { buf = c->arbuf; len = rcbadr - c->arphys; cnt_port = ARBCNT(c->port); sts_port = ARBSTS(c->port); } if (len) { c->ibytes += len; c->received_data = buf; c->received_len = len; /* Restart receiver. */ outw (cnt_port, rbsz); outb (sts_port, BSTS_OWN24); } return (REOI_TERMBUFF); } /* Receive errors. */ if (risr & RIS_OVERRUN) { ++c->ierrs; if (c->call_on_err) c->call_on_err (c, CX_OVERRUN); } else if (c->mode != M_ASYNC && (risr & RISH_CRCERR)) { ++c->ierrs; if (c->call_on_err) c->call_on_err (c, CX_CRC); } else if (c->mode != M_ASYNC && (risr & (RISH_RXABORT | RISH_RESIND))) { ++c->ierrs; if (c->call_on_err) c->call_on_err (c, CX_FRAME); } else if (c->mode == M_ASYNC && (risr & RISA_PARERR)) { ++c->ierrs; if (c->call_on_err) c->call_on_err (c, CX_CRC); } else if (c->mode == M_ASYNC && (risr & RISA_FRERR)) { ++c->ierrs; if (c->call_on_err) c->call_on_err (c, CX_FRAME); } else if (c->mode == M_ASYNC && (risr & RISA_BREAK)) { if (c->call_on_err) c->call_on_err (c, CX_BREAK); } else if (! (risr & RIS_EOBUF)) { ++c->ierrs; } else { /* Handle received data. */ len = (risr & RIS_BB) ? inw(BRBCNT(c->port)) : inw(ARBCNT(c->port)); if (len > DMABUFSZ) { /* Fatal error: actual DMA transfer size * exceeds our buffer size. It could be caused * by incorrectly programmed DMA register or * hardware fault. Possibly, should panic here. */ len = DMABUFSZ; } else if (c->mode != M_ASYNC && ! (risr & RIS_EOFR)) { /* The received frame does not fit in the DMA buffer. * It could be caused by serial lie noise, * or if the peer has too big MTU. */ if (! c->overflow) { if (c->call_on_err) c->call_on_err (c, CX_OVERFLOW); c->overflow = 1; ++c->ierrs; } } else if (! c->overflow) { if (risr & RIS_BB) { c->received_data = c->brbuf; c->received_len = len; } else { c->received_data = c->arbuf; c->received_len = len; } if (c->mode != M_ASYNC) ++c->ipkts; c->ibytes += len; } else c->overflow = 0; } /* Restart receiver. */ if (! (inb (ARBSTS(c->port)) & BSTS_OWN24)) { outw (ARBCNT(c->port), rbsz); outb (ARBSTS(c->port), BSTS_OWN24); } if (! (inb (BRBSTS(c->port)) & BSTS_OWN24)) { outw (BRBCNT(c->port), rbsz); outb (BRBSTS(c->port), BSTS_OWN24); } /* Discard exception characters. */ if ((risr & RISA_SCMASK) && c->aopt.cor2.ixon) return (REOI_DISCEXC); else return (0); } static void cx_transmit_interrupt (cx_chan_t *c) { unsigned char tisr; int len = 0; ++c->tintr; tisr = inb (TISR(c->port)); if (tisr & TIS_UNDERRUN) { /* Transmit underrun error */ if (c->call_on_err) c->call_on_err (c, CX_UNDERRUN); ++c->oerrs; } else if (tisr & (TIS_EOBUF | TIS_TXEMPTY | TIS_TXDATA)) { /* Call processing function */ if (tisr & TIS_BB) { len = inw(BTBCNT(c->port)); if (c->call_on_tx) c->call_on_tx (c, c->attach[1], len); } else { len = inw(ATBCNT(c->port)); if (c->call_on_tx) c->call_on_tx (c, c->attach[0], len); } if (c->mode != M_ASYNC && len != 0) ++c->opkts; c->obytes += len; } /* Enable TXMPTY interrupt, * to catch the case when the second buffer is empty. */ if (c->mode != M_ASYNC) { if ((inb (ATBSTS(c->port)) & BSTS_OWN24) && (inb (BTBSTS(c->port)) & BSTS_OWN24)) { outb (IER(c->port), IER_RXD | IER_TXD | IER_TXMPTY); } else outb (IER(c->port), IER_RXD | IER_TXD); } } void cx_int_handler (cx_board_t *b) { unsigned char livr; cx_chan_t *c; while (! (inw (BSR(b->port)) & BSR_NOINTR)) { /* Enter the interrupt context, using IACK bus cycle. Read the local interrupt vector register. */ livr = inb (IACK(b->port, BRD_INTR_LEVEL)); c = b->chan + (livr>>2 & 0xf); if (c->type == T_NONE) continue; switch (livr & 3) { case LIV_MODEM: /* modem interrupt */ ++c->mintr; if (c->call_on_msig) c->call_on_msig (c); outb (MEOIR(c->port), 0); break; case LIV_EXCEP: /* receive exception */ case LIV_RXDATA: /* receive interrupt */ outb (REOIR(c->port), cx_receive_interrupt (c)); if (c->call_on_rx && c->received_data) { c->call_on_rx (c, c->received_data, c->received_len); c->received_data = 0; } break; case LIV_TXDATA: /* transmit interrupt */ cx_transmit_interrupt (c); outb (TEOIR(c->port), 0); break; } } } /* * Register event processing functions */ void cx_register_transmit (cx_chan_t *c, void (*func) (cx_chan_t *c, void *attachment, int len)) { c->call_on_tx = func; } void cx_register_receive (cx_chan_t *c, void (*func) (cx_chan_t *c, char *data, int len)) { c->call_on_rx = func; } void cx_register_modem (cx_chan_t *c, void (*func) (cx_chan_t *c)) { c->call_on_msig = func; } void cx_register_error (cx_chan_t *c, void (*func) (cx_chan_t *c, int data)) { c->call_on_err = func; } /* * Async protocol functions. */ /* * Enable/disable transmitter. */ void cx_transmitter_ctl (cx_chan_t *c,int start) { outb (CAR(c->port), c->num & 3); cx_cmd (c->port, start ? CCR_ENTX : CCR_DISTX); } /* * Discard all data queued in transmitter. */ void cx_flush_transmit (cx_chan_t *c) { outb (CAR(c->port), c->num & 3); cx_cmd (c->port, CCR_CLRTX); } /* * Send the XON/XOFF flow control symbol. */ void cx_xflow_ctl (cx_chan_t *c, int on) { outb (CAR(c->port), c->num & 3); outb (STCR(c->port), STC_SNDSPC | (on ? STC_SSPC_1 : STC_SSPC_2)); } /* * Send the break signal for a given number of milliseconds. */ void cx_send_break (cx_chan_t *c, int msec) { static unsigned char buf [128]; unsigned char *p; p = buf; *p++ = 0; /* extended transmit command */ *p++ = 0x81; /* send break */ if (msec > 10000) /* max 10 seconds */ msec = 10000; if (msec < 10) /* min 10 msec */ msec = 10; while (msec > 0) { int ms = 250; /* 250 msec */ if (ms > msec) ms = msec; msec -= ms; *p++ = 0; /* extended transmit command */ *p++ = 0x82; /* insert delay */ *p++ = ms; } *p++ = 0; /* extended transmit command */ *p++ = 0x83; /* stop break */ cx_send (c, buf, p-buf, 0); } /* * Set async parameters. */ void cx_set_async_param (cx_chan_t *c, int baud, int bits, int parity, int stop2, int ignpar, int rtscts, int ixon, int ixany, int symstart, int symstop) { int clock, period; cx_cor1_async_t cor1; /* Set character length and parity mode. */ BYTE cor1 = 0; cor1.charlen = bits - 1; cor1.parmode = parity ? PARM_NORMAL : PARM_NOPAR; cor1.parity = parity==1 ? PAR_ODD : PAR_EVEN; cor1.ignpar = ignpar ? 1 : 0; /* Enable/disable hardware CTS. */ c->aopt.cor2.ctsae = rtscts ? 1 : 0; /* Enable extended transmit command mode. * Unfortunately, there is no other method for sending break. */ c->aopt.cor2.etc = 1; /* Enable/disable hardware XON/XOFF. */ c->aopt.cor2.ixon = ixon ? 1 : 0; c->aopt.cor2.ixany = ixany ? 1 : 0; /* Set the number of stop bits. */ if (stop2) c->aopt.cor3.stopb = STOPB_2; else c->aopt.cor3.stopb = STOPB_1; /* Disable/enable passing XON/XOFF chars to the host. */ c->aopt.cor3.scde = ixon ? 1 : 0; c->aopt.cor3.flowct = ixon ? FLOWCC_NOTPASS : FLOWCC_PASS; c->aopt.schr1 = symstart; /* XON */ c->aopt.schr2 = symstop; /* XOFF */ /* Set current channel number. */ outb (CAR(c->port), c->num & 3); /* Set up clock values. */ if (baud) { c->rxbaud = c->txbaud = baud; /* Receiver. */ cx_clock (c->oscfreq, c->rxbaud, &clock, &period); c->opt.rcor.clk = clock; outb (RCOR(c->port), BYTE c->opt.rcor); outb (RBPR(c->port), period); /* Transmitter. */ cx_clock (c->oscfreq, c->txbaud, &clock, &period); c->opt.tcor.clk = clock; c->opt.tcor.ext1x = 0; outb (TCOR(c->port), BYTE c->opt.tcor); outb (TBPR(c->port), period); } outb (COR2(c->port), BYTE c->aopt.cor2); outb (COR3(c->port), BYTE c->aopt.cor3); outb (SCHR1(c->port), c->aopt.schr1); outb (SCHR2(c->port), c->aopt.schr2); if (BYTE c->aopt.cor1 != BYTE cor1) { BYTE c->aopt.cor1 = BYTE cor1; outb (COR1(c->port), BYTE c->aopt.cor1); /* Any change to COR1 require reinitialization. */ /* Unfortunately, it may cause transmitter glitches... */ cx_cmd (c->port, CCR_INITCH); } } /* * Set mode: M_ASYNC or M_HDLC. * Both receiver and transmitter are disabled. */ int cx_set_mode (cx_chan_t *c, int mode) { if (mode == M_HDLC) { if (c->type == T_ASYNC) return -1; if (c->mode == M_HDLC) return 0; c->mode = M_HDLC; } else if (mode == M_ASYNC) { if (c->type == T_SYNC_RS232 || c->type == T_SYNC_V35 || c->type == T_SYNC_RS449) return -1; if (c->mode == M_ASYNC) return 0; c->mode = M_ASYNC; c->opt.tcor.ext1x = 0; c->opt.tcor.llm = 0; c->opt.rcor.dpll = 0; c->opt.rcor.encod = ENCOD_NRZ; if (! c->txbaud || ! c->rxbaud) c->txbaud = c->rxbaud = 9600; } else return -1; cx_setup_chan (c); cx_start_chan (c, 0, 0); cx_enable_receive (c, 0); cx_enable_transmit (c, 0); return 0; } /* * Set port type for old models of Sigma */ void cx_set_port (cx_chan_t *c, int iftype) { if (c->board->type == B_SIGMA_XXX) { switch (c->num) { case 0: if ((c->board->if0type != 0) == (iftype != 0)) return; c->board->if0type = iftype; c->board->bcr0 &= ~BCR0_UMASK; if (c->board->if0type && (c->type==T_UNIV_RS449 || c->type==T_UNIV_V35)) c->board->bcr0 |= BCR0_UI_RS449; outb (BCR0(c->board->port), c->board->bcr0); break; case 8: if ((c->board->if8type != 0) == (iftype != 0)) return; c->board->if8type = iftype; c->board->bcr0b &= ~BCR0_UMASK; if (c->board->if8type && (c->type==T_UNIV_RS449 || c->type==T_UNIV_V35)) c->board->bcr0b |= BCR0_UI_RS449; outb (BCR0(c->board->port+0x10), c->board->bcr0b); break; } } } /* * Get port type for old models of Sigma * -1 Fixed port type or auto detect * 0 RS232 * 1 V35 * 2 RS449 */ int cx_get_port (cx_chan_t *c) { int iftype; if (c->board->type == B_SIGMA_XXX) { switch (c->num) { case 0: iftype = c->board->if0type; break; case 8: iftype = c->board->if8type; break; default: return -1; } if (iftype) switch (c->type) { case T_UNIV_V35: return 1; break; case T_UNIV_RS449: return 2; break; default: return -1; break; } else return 0; } else return -1; } void cx_intr_off (cx_board_t *b) { outb (BCR0(b->port), b->bcr0 & ~BCR0_IRQ_MASK); if (b->chan[8].port || b->chan[12].port) outb (BCR0(b->port+0x10), b->bcr0b & ~BCR0_IRQ_MASK); } void cx_intr_on (cx_board_t *b) { outb (BCR0(b->port), b->bcr0); if (b->chan[8].port || b->chan[12].port) outb (BCR0(b->port+0x10), b->bcr0b); } int cx_checkintr (cx_board_t *b) { return (!(inw (BSR(b->port)) & BSR_NOINTR)); }