Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/if_carp/@/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/if_carp/@/dev/cx/csigma.c |
/*- * Low-level subroutines for Cronyx-Sigma adapter. * * Copyright (C) 1994-2000 Cronyx Engineering. * Author: Serge Vakulenko, <vak@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: csigma.c,v 1.1.2.1 2003/11/12 17:13:41 rik Exp $ * $FreeBSD: release/9.1.0/sys/dev/cx/csigma.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> #define DMA_MASK 0xd4 /* DMA mask register */ #define DMA_MASK_CLEAR 0x04 /* DMA clear mask */ #define DMA_MODE 0xd6 /* DMA mode register */ #define DMA_MODE_MASTER 0xc0 /* DMA master mode */ #define BYTE *(unsigned char*)& static unsigned char irqmask [] = { BCR0_IRQ_DIS, BCR0_IRQ_DIS, BCR0_IRQ_DIS, BCR0_IRQ_3, BCR0_IRQ_DIS, BCR0_IRQ_5, BCR0_IRQ_DIS, BCR0_IRQ_7, BCR0_IRQ_DIS, BCR0_IRQ_DIS, BCR0_IRQ_10, BCR0_IRQ_11, BCR0_IRQ_12, BCR0_IRQ_DIS, BCR0_IRQ_DIS, BCR0_IRQ_15, }; static unsigned char dmamask [] = { BCR0_DMA_DIS, BCR0_DMA_DIS, BCR0_DMA_DIS, BCR0_DMA_DIS, BCR0_DMA_DIS, BCR0_DMA_5, BCR0_DMA_6, BCR0_DMA_7, }; /* standard base port set */ static short porttab [] = { 0x200, 0x220, 0x240, 0x260, 0x280, 0x2a0, 0x2c0, 0x2e0, 0x300, 0x320, 0x340, 0x360, 0x380, 0x3a0, 0x3c0, 0x3e0, 0 }; /* valid IRQs and DRQs */ static short irqtab [] = { 3, 5, 7, 10, 11, 12, 15, 0 }; static short dmatab [] = { 5, 6, 7, 0 }; static int valid (short value, short *list) { while (*list) if (value == *list++) return 1; return 0; } long cx_rxbaud = 9600; /* receiver baud rate */ long cx_txbaud = 9600; /* transmitter baud rate */ int cx_univ_mode = M_HDLC; /* univ. chan. mode: async or sync */ int cx_sync_mode = M_HDLC; /* sync. chan. mode: HDLC, Bisync or X.21 */ int cx_iftype = 0; /* univ. chan. interface: upper/lower */ static int cx_probe_chip (port_t base); static void cx_setup_chip (cx_chan_t *c); /* * Wait for CCR to clear. */ void cx_cmd (port_t base, int cmd) { port_t port = CCR(base); int count; /* Wait 10 msec for the previous command to complete. */ for (count=0; inb(port) && count<20000; ++count) continue; /* Issue the command. */ outb (port, cmd); /* Wait 10 msec for the command to complete. */ for (count=0; inb(port) && count<20000; ++count) continue; } /* * Reset the chip. */ static int cx_reset (port_t port) { int count; /* Wait up to 10 msec for revision code to appear after reset. */ for (count=0; count<20000; ++count) if (inb(GFRCR(port)) != 0) break; cx_cmd (port, CCR_RSTALL); /* Firmware revision code should clear imediately. */ /* Wait up to 10 msec for revision code to appear again. */ for (count=0; count<20000; ++count) if (inb(GFRCR(port)) != 0) return (1); /* Reset failed. */ return (0); } int cx_download (port_t port, const unsigned char *firmware, long bits, const cr_dat_tst_t *tst) { unsigned char cr2, sr; long i, n, maxn = (bits + 7) / 8; int v, b; inb (BDET(port)); for (i=n=0; n<maxn; ++n) { v = ((firmware[n] ^ ' ') << 1) | (firmware[n] >> 7 & 1); for (b=0; b<7; b+=2, i+=2) { if (i >= bits) break; cr2 = 0; if (v >> b & 1) cr2 |= BCR2_TMS; if (v >> b & 2) cr2 |= BCR2_TDI; outb (BCR2(port), cr2); sr = inb (BSR(port)); outb (BCR0(port), BCR0800_TCK); outb (BCR0(port), 0); if (i >= tst->end) ++tst; if (i >= tst->start && (sr & BSR800_LERR)) return (0); } } return (1); } /* * Check if the Sigma-XXX board is present at the given base port. */ static int cx_probe_chained_board (port_t port, int *c0, int *c1) { int rev, i; /* Read and check the board revision code. */ rev = inb (BSR(port)); *c0 = *c1 = 0; switch (rev & BSR_VAR_MASK) { case CRONYX_100: *c0 = 1; break; case CRONYX_400: *c1 = 1; break; case CRONYX_500: *c0 = *c1 = 1; break; case CRONYX_410: *c0 = 1; break; case CRONYX_810: *c0 = *c1 = 1; break; case CRONYX_410s: *c0 = 1; break; case CRONYX_810s: *c0 = *c1 = 1; break; case CRONYX_440: *c0 = 1; break; case CRONYX_840: *c0 = *c1 = 1; break; case CRONYX_401: *c0 = 1; break; case CRONYX_801: *c0 = *c1 = 1; break; case CRONYX_401s: *c0 = 1; break; case CRONYX_801s: *c0 = *c1 = 1; break; case CRONYX_404: *c0 = 1; break; case CRONYX_703: *c0 = *c1 = 1; break; default: return (0); /* invalid variant code */ } switch (rev & BSR_OSC_MASK) { case BSR_OSC_20: /* 20 MHz */ case BSR_OSC_18432: /* 18.432 MHz */ break; default: return (0); /* oscillator frequency does not match */ } for (i=2; i<0x10; i+=2) if ((inb (BSR(port)+i) & BSR_REV_MASK) != (rev & BSR_REV_MASK)) return (0); /* status changed? */ return (1); } /* * Check if the Sigma-800 board is present at the given base port. * Read board status register 1 and check identification bits * which should invert every next read. */ static int cx_probe_800_chained_board (port_t port) { unsigned char det, odet; int i; odet = inb (BDET(port)); if ((odet & (BDET_IB | BDET_IB_NEG)) != BDET_IB && (odet & (BDET_IB | BDET_IB_NEG)) != BDET_IB_NEG) return (0); for (i=0; i<100; ++i) { det = inb (BDET(port)); if (((det ^ odet) & (BDET_IB | BDET_IB_NEG)) != (BDET_IB | BDET_IB_NEG)) return (0); odet = det; } /* Reset the controller. */ outb (BCR0(port), 0); outb (BCR1(port), 0); outb (BCR2(port), 0); return (1); } /* * Check if the Sigma-2x board is present at the given base port. */ static int cx_probe_2x_board (port_t port) { int rev, i; /* Read and check the board revision code. */ rev = inb (BSR(port)); if ((rev & BSR2X_VAR_MASK) != CRONYX_22 && (rev & BSR2X_VAR_MASK) != CRONYX_24) return (0); /* invalid variant code */ for (i=2; i<0x10; i+=2) if ((inb (BSR(port)+i) & BSR2X_REV_MASK) != (rev & BSR2X_REV_MASK)) return (0); /* status changed? */ return (1); } /* * Check if the Cronyx-Sigma board is present at the given base port. */ int cx_probe_board (port_t port, int irq, int dma) { int c0, c1, c2=0, c3=0, result; if (! valid (port, porttab)) return 0; if (irq > 0 && ! valid (irq, irqtab)) return 0; if (dma > 0 && ! valid (dma, dmatab)) return 0; if (cx_probe_800_chained_board (port)) { /* Sigma-800 detected. */ if (! (inb (BSR(port)) & BSR_NOCHAIN)) { /* chained board attached */ if (! cx_probe_800_chained_board (port+0x10)) /* invalid chained board? */ return (0); if (! (inb (BSR(port+0x10)) & BSR_NOCHAIN)) /* invalid chained board flag? */ return (0); } return 1; } if (cx_probe_chained_board (port, &c0, &c1)) { /* Sigma-XXX detected. */ if (! (inb (BSR(port)) & BSR_NOCHAIN)) { /* chained board attached */ if (! cx_probe_chained_board (port+0x10, &c2, &c3)) /* invalid chained board? */ return (0); if (! (inb (BSR(port+0x10)) & BSR_NOCHAIN)) /* invalid chained board flag? */ return (0); } } else if (cx_probe_2x_board (port)) { c0 = 1; /* Sigma-2x detected. */ c1 = 0; } else return (0); /* no board detected */ /* Turn off the reset bit. */ outb (BCR0(port), BCR0_NORESET); if (c2 || c3) outb (BCR0(port + 0x10), BCR0_NORESET); result = 1; if (c0 && ! cx_probe_chip (CS0(port))) result = 0; /* no CD2400 chip here */ else if (c1 && ! cx_probe_chip (CS1A(port)) && ! cx_probe_chip (CS1(port))) result = 0; /* no second CD2400 chip */ else if (c2 && ! cx_probe_chip (CS0(port + 0x10))) result = 0; /* no CD2400 chip on the slave board */ else if (c3 && ! cx_probe_chip (CS1(port + 0x10))) result = 0; /* no second CD2400 chip on the slave board */ /* Reset the controller. */ outb (BCR0(port), 0); if (c2 || c3) outb (BCR0(port + 0x10), 0); /* Yes, we really have valid Sigma board. */ return (result); } /* * Check if the CD2400 chip is present at the given base port. */ static int cx_probe_chip (port_t base) { int rev, newrev, count; /* Wait up to 10 msec for revision code to appear after reset. */ rev = 0; for (count=0; rev==0; ++count) { if (count >= 20000) return (0); /* reset failed */ rev = inb (GFRCR(base)); } /* Read and check the global firmware revision code. */ if (! (rev>=REVCL_MIN && rev<=REVCL_MAX) && ! (rev>=REVCL31_MIN && rev<=REVCL31_MAX)) return (0); /* CD2400/2431 revision does not match */ /* Reset the chip. */ if (! cx_reset (base)) return (0); /* Read and check the new global firmware revision code. */ newrev = inb (GFRCR(base)); if (newrev != rev) return (0); /* revision changed */ /* Yes, we really have CD2400/2431 chip here. */ return (1); } /* * Check that the irq is functional. * irq>0 - activate the interrupt from the adapter (irq=on) * irq<0 - deactivate the interrupt (irq=off) * irq==0 - free the interrupt line (irq=tri-state) * Return the interrupt mask _before_ activating irq. */ int cx_probe_irq (cx_board_t *b, int irq) { int mask, rev; port_t port; rev = inb (BSR(b->port)); port = ((rev & BSR_VAR_MASK) != CRONYX_400) ? CS0(b->port) : CS1(b->port); outb (0x20, 0x0a); mask = inb (0x20); outb (0xa0, 0x0a); mask |= inb (0xa0) << 8; if (irq > 0) { outb (BCR0(b->port), BCR0_NORESET | irqmask[irq]); outb (CAR(port), 0); cx_cmd (port, CCR_CLRCH); outb (CMR(port), CMR_HDLC); outb (TCOR(port), 0); outb (TBPR(port), 1); cx_cmd (port, CCR_INITCH | CCR_ENTX); outb (IER(port), IER_TXMPTY); } else if (irq < 0) { cx_reset (port); if (-irq > 7) { outb (0xa0, 0x60 | ((-irq) & 7)); outb (0x20, 0x62); } else outb (0x20, 0x60 | (-irq)); } else outb (BCR0(b->port), 0); return mask; } static int cx_chip_revision (port_t port, int rev) { int count; /* Model 400 has no first chip. */ port = ((rev & BSR_VAR_MASK) != CRONYX_400) ? CS0(port) : CS1(port); /* Wait up to 10 msec for revision code to appear after reset. */ for (count=0; inb(GFRCR(port))==0; ++count) if (count >= 20000) return (0); /* reset failed */ return inb (GFRCR (port)); } /* * Probe and initialize the board structure. */ void cx_init (cx_board_t *b, int num, port_t port, int irq, int dma) { int gfrcr, rev, chain, mod = 0, rev2 = 0, mod2 = 0; rev = inb (BSR(port)); chain = ! (rev & BSR_NOCHAIN); if (cx_probe_800_chained_board (port)) { cx_init_800 (b, num, port, irq, dma, chain); return; } if ((rev & BSR2X_VAR_MASK) == CRONYX_22 || (rev & BSR2X_VAR_MASK) == CRONYX_24) { cx_init_2x (b, num, port, irq, dma, (rev & BSR2X_VAR_MASK), (rev & BSR2X_OSC_33)); return; } outb (BCR0(port), BCR0_NORESET); if (chain) outb (BCR0(port+0x10), BCR0_NORESET); gfrcr = cx_chip_revision (port, rev); if (gfrcr >= REVCL31_MIN && gfrcr <= REVCL31_MAX) mod = 1; if (chain) { rev2 = inb (BSR(port+0x10)); gfrcr = cx_chip_revision (port+0x10, rev2); if (gfrcr >= REVCL31_MIN && gfrcr <= REVCL31_MAX) mod2 = 1; outb (BCR0(port+0x10), 0); } outb (BCR0(port), 0); cx_init_board (b, num, port, irq, dma, chain, (rev & BSR_VAR_MASK), (rev & BSR_OSC_MASK), mod, (rev2 & BSR_VAR_MASK), (rev2 & BSR_OSC_MASK), mod2); } /* * Initialize the board structure, given the type of the board. */ void cx_init_board (cx_board_t *b, int num, port_t port, int irq, int dma, int chain, int rev, int osc, int mod, int rev2, int osc2, int mod2) { cx_chan_t *c; char *type; int i; /* Initialize board structure. */ b->port = port; b->num = num; b->irq = irq; b->dma = dma; b->opt = board_opt_dflt; b->type = B_SIGMA_XXX; b->if0type = b->if8type = cx_iftype; /* Set channels 0 and 8 mode, set DMA and IRQ. */ b->bcr0 = b->bcr0b = BCR0_NORESET | dmamask[b->dma] | irqmask[b->irq]; /* Clear DTR[0..3] and DTR[8..12]. */ b->bcr1 = b->bcr1b = 0; /*------------------ Master board -------------------*/ /* Read and check the board revision code. */ strcpy (b->name, mod ? "m" : ""); switch (rev) { default: type = ""; break; case CRONYX_100: type = "100"; break; case CRONYX_400: type = "400"; break; case CRONYX_500: type = "500"; break; case CRONYX_410: type = "410"; break; case CRONYX_810: type = "810"; break; case CRONYX_410s: type = "410s"; break; case CRONYX_810s: type = "810s"; break; case CRONYX_440: type = "440"; break; case CRONYX_840: type = "840"; break; case CRONYX_401: type = "401"; break; case CRONYX_801: type = "801"; break; case CRONYX_401s: type = "401s"; break; case CRONYX_801s: type = "801s"; break; case CRONYX_404: type = "404"; break; case CRONYX_703: type = "703"; break; } strcat (b->name, type); switch (osc) { default: case BSR_OSC_20: /* 20 MHz */ b->chan[0].oscfreq = b->chan[1].oscfreq = b->chan[2].oscfreq = b->chan[3].oscfreq = b->chan[4].oscfreq = b->chan[5].oscfreq = b->chan[6].oscfreq = b->chan[7].oscfreq = mod ? 33000000L : 20000000L; strcat (b->name, "a"); break; case BSR_OSC_18432: /* 18.432 MHz */ b->chan[0].oscfreq = b->chan[1].oscfreq = b->chan[2].oscfreq = b->chan[3].oscfreq = b->chan[4].oscfreq = b->chan[5].oscfreq = b->chan[6].oscfreq = b->chan[7].oscfreq = mod ? 20000000L : 18432000L; strcat (b->name, "b"); break; } /*------------------ Slave board -------------------*/ if (chain) { /* Read and check the board revision code. */ strcat (b->name, mod2 ? "/m" : "/"); switch (rev2) { default: type = ""; break; case CRONYX_100: type = "100"; break; case CRONYX_400: type = "400"; break; case CRONYX_500: type = "500"; break; case CRONYX_410: type = "410"; break; case CRONYX_810: type = "810"; break; case CRONYX_410s: type = "410s"; break; case CRONYX_810s: type = "810s"; break; case CRONYX_440: type = "440"; break; case CRONYX_840: type = "840"; break; case CRONYX_401: type = "401"; break; case CRONYX_801: type = "801"; break; case CRONYX_401s: type = "401s"; break; case CRONYX_801s: type = "801s"; break; case CRONYX_404: type = "404"; break; case CRONYX_703: type = "703"; break; } strcat (b->name, type); switch (osc2) { default: case BSR_OSC_20: /* 20 MHz */ b->chan[8].oscfreq = b->chan[9].oscfreq = b->chan[10].oscfreq = b->chan[11].oscfreq = b->chan[12].oscfreq = b->chan[13].oscfreq = b->chan[14].oscfreq = b->chan[15].oscfreq = mod2 ? 33000000L : 20000000L; strcat (b->name, "a"); break; case BSR_OSC_18432: /* 18.432 MHz */ b->chan[8].oscfreq = b->chan[9].oscfreq = b->chan[10].oscfreq = b->chan[11].oscfreq = b->chan[12].oscfreq = b->chan[13].oscfreq = b->chan[14].oscfreq = b->chan[15].oscfreq = mod2 ? 20000000L : 18432000L; strcat (b->name, "b"); break; } } /* Initialize channel structures. */ for (i=0; i<4; ++i) { b->chan[i+0].port = CS0(port); b->chan[i+4].port = cx_probe_chip (CS1A(port)) ? CS1A(port) : CS1(port); b->chan[i+8].port = CS0(port+0x10); b->chan[i+12].port = CS1(port+0x10); } for (c=b->chan; c<b->chan+NCHAN; ++c) { c->board = b; c->num = c - b->chan; c->type = T_NONE; } /*------------------ Master board -------------------*/ switch (rev) { case CRONYX_400: for (i=4; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_100: b->chan[0].type = T_UNIV_RS232; break; case CRONYX_500: b->chan[0].type = T_UNIV_RS232; for (i=4; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_410: b->chan[0].type = T_UNIV_V35; for (i=1; i<4; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_810: b->chan[0].type = T_UNIV_V35; for (i=1; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_410s: b->chan[0].type = T_UNIV_V35; for (i=1; i<4; ++i) b->chan[i].type = T_SYNC_RS232; break; case CRONYX_810s: b->chan[0].type = T_UNIV_V35; for (i=1; i<4; ++i) b->chan[i].type = T_SYNC_RS232; for (i=4; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_440: b->chan[0].type = T_UNIV_V35; for (i=1; i<4; ++i) b->chan[i].type = T_SYNC_V35; break; case CRONYX_840: b->chan[0].type = T_UNIV_V35; for (i=1; i<4; ++i) b->chan[i].type = T_SYNC_V35; for (i=4; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_401: b->chan[0].type = T_UNIV_RS449; for (i=1; i<4; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_801: b->chan[0].type = T_UNIV_RS449; for (i=1; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_401s: b->chan[0].type = T_UNIV_RS449; for (i=1; i<4; ++i) b->chan[i].type = T_SYNC_RS232; break; case CRONYX_801s: b->chan[0].type = T_UNIV_RS449; for (i=1; i<4; ++i) b->chan[i].type = T_SYNC_RS232; for (i=4; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_404: b->chan[0].type = T_UNIV_RS449; for (i=1; i<4; ++i) b->chan[i].type = T_SYNC_RS449; break; case CRONYX_703: b->chan[0].type = T_UNIV_RS449; for (i=1; i<3; ++i) b->chan[i].type = T_SYNC_RS449; for (i=4; i<8; ++i) b->chan[i].type = T_UNIV_RS232; break; } /*------------------ Slave board -------------------*/ if (chain) { switch (rev2) { case CRONYX_400: break; case CRONYX_100: b->chan[8].type = T_UNIV_RS232; break; case CRONYX_500: b->chan[8].type = T_UNIV_RS232; for (i=12; i<16; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_410: b->chan[8].type = T_UNIV_V35; for (i=9; i<12; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_810: b->chan[8].type = T_UNIV_V35; for (i=9; i<16; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_410s: b->chan[8].type = T_UNIV_V35; for (i=9; i<12; ++i) b->chan[i].type = T_SYNC_RS232; break; case CRONYX_810s: b->chan[8].type = T_UNIV_V35; for (i=9; i<12; ++i) b->chan[i].type = T_SYNC_RS232; for (i=12; i<16; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_440: b->chan[8].type = T_UNIV_V35; for (i=9; i<12; ++i) b->chan[i].type = T_SYNC_V35; break; case CRONYX_840: b->chan[8].type = T_UNIV_V35; for (i=9; i<12; ++i) b->chan[i].type = T_SYNC_V35; for (i=12; i<16; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_401: b->chan[8].type = T_UNIV_RS449; for (i=9; i<12; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_801: b->chan[8].type = T_UNIV_RS449; for (i=9; i<16; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_401s: b->chan[8].type = T_UNIV_RS449; for (i=9; i<12; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_801s: b->chan[8].type = T_UNIV_RS449; for (i=9; i<12; ++i) b->chan[i].type = T_SYNC_RS232; for (i=12; i<16; ++i) b->chan[i].type = T_UNIV_RS232; break; case CRONYX_404: b->chan[8].type = T_UNIV_RS449; for (i=9; i<12; ++i) b->chan[i].type = T_SYNC_RS449; break; case CRONYX_703: b->chan[8].type = T_UNIV_RS449; for (i=9; i<11; ++i) b->chan[i].type = T_SYNC_RS449; for (i=12; i<16; ++i) b->chan[i].type = T_UNIV_RS232; break; } } b->nuniv = b->nsync = b->nasync = 0; for (c=b->chan; c<b->chan+NCHAN; ++c) switch (c->type) { case T_ASYNC: ++b->nasync; break; case T_UNIV: case T_UNIV_RS232: case T_UNIV_RS449: case T_UNIV_V35: ++b->nuniv; break; case T_SYNC_RS232: case T_SYNC_V35: case T_SYNC_RS449: ++b->nsync; break; } cx_reinit_board (b); } /* * Initialize the Sigma-800 board structure. */ void cx_init_800 (cx_board_t *b, int num, port_t port, int irq, int dma, int chain) { cx_chan_t *c; int i; /* Initialize board structure. */ b->port = port; b->num = num; b->irq = irq; b->dma = dma; b->opt = board_opt_dflt; b->type = B_SIGMA_800; /* Set channels 0 and 8 mode, set DMA and IRQ. */ b->bcr0 = b->bcr0b = dmamask[b->dma] | irqmask[b->irq]; /* Clear DTR[0..7] and DTR[8..15]. */ b->bcr1 = b->bcr1b = 0; strcpy (b->name, "800"); if (chain) strcat (b->name, "/800"); /* Initialize channel structures. */ for (i=0; i<4; ++i) { b->chan[i+0].port = CS0(port); b->chan[i+4].port = cx_probe_chip (CS1A(port)) ? CS1A(port) : CS1(port); b->chan[i+8].port = CS0(port+0x10); b->chan[i+12].port = CS1(port+0x10); } for (c=b->chan; c<b->chan+NCHAN; ++c) { c->board = b; c->num = c - b->chan; c->oscfreq = 33000000L; c->type = (c->num < 8 || chain) ? T_UNIV_RS232 : T_NONE; } b->nuniv = b->nsync = b->nasync = 0; for (c=b->chan; c<b->chan+NCHAN; ++c) switch (c->type) { case T_ASYNC: ++b->nasync; break; case T_UNIV: case T_UNIV_RS232: case T_UNIV_RS449: case T_UNIV_V35: ++b->nuniv; break; case T_SYNC_RS232: case T_SYNC_V35: case T_SYNC_RS449: ++b->nsync; break; } cx_reinit_board (b); } /* * Initialize the Sigma-2x board structure. */ void cx_init_2x (cx_board_t *b, int num, port_t port, int irq, int dma, int rev, int osc) { cx_chan_t *c; int i; /* Initialize board structure. */ b->port = port; b->num = num; b->irq = irq; b->dma = dma; b->opt = board_opt_dflt; b->type = B_SIGMA_2X; /* Set channels 0 and 8 mode, set DMA and IRQ. */ b->bcr0 = BCR0_NORESET | dmamask[b->dma] | irqmask[b->irq]; if (b->type == B_SIGMA_2X && b->opt.fast) b->bcr0 |= BCR02X_FAST; /* Clear DTR[0..3] and DTR[8..12]. */ b->bcr1 = 0; /* Initialize channel structures. */ for (i=0; i<4; ++i) { b->chan[i+0].port = CS0(port); b->chan[i+4].port = CS1(port); b->chan[i+8].port = CS0(port+0x10); b->chan[i+12].port = CS1(port+0x10); } for (c=b->chan; c<b->chan+NCHAN; ++c) { c->board = b; c->num = c - b->chan; c->type = T_NONE; c->oscfreq = (osc & BSR2X_OSC_33) ? 33000000L : 20000000L; } /* Check the board revision code. */ strcpy (b->name, "22"); b->chan[0].type = T_UNIV; b->chan[1].type = T_UNIV; b->nsync = b->nasync = 0; b->nuniv = 2; if (rev == CRONYX_24) { strcpy (b->name, "24"); b->chan[2].type = T_UNIV; b->chan[3].type = T_UNIV; b->nuniv += 2; } strcat (b->name, (osc & BSR2X_OSC_33) ? "c" : "a"); cx_reinit_board (b); } /* * Reinitialize all channels, using new options and baud rate. */ void cx_reinit_board (cx_board_t *b) { cx_chan_t *c; b->opt = board_opt_dflt; if (b->type == B_SIGMA_2X) { b->bcr0 &= ~BCR02X_FAST; if (b->opt.fast) b->bcr0 |= BCR02X_FAST; } else b->if0type = b->if8type = cx_iftype; for (c=b->chan; c<b->chan+NCHAN; ++c) { switch (c->type) { default: case T_NONE: continue; case T_UNIV: case T_UNIV_RS232: case T_UNIV_RS449: case T_UNIV_V35: c->mode = (cx_univ_mode == M_ASYNC) ? M_ASYNC : cx_sync_mode; break; case T_SYNC_RS232: case T_SYNC_V35: case T_SYNC_RS449: c->mode = cx_sync_mode; break; case T_ASYNC: c->mode = M_ASYNC; break; } c->rxbaud = cx_rxbaud; c->txbaud = cx_txbaud; c->opt = chan_opt_dflt; c->aopt = opt_async_dflt; c->hopt = opt_hdlc_dflt; } } /* * Set up the board. */ int cx_setup_board (cx_board_t *b, const unsigned char *firmware, long bits, const cr_dat_tst_t *tst) { int i; #ifndef NDIS_MINIPORT_DRIVER /* Disable DMA channel. */ outb (DMA_MASK, (b->dma & 3) | DMA_MASK_CLEAR); #endif /* Reset the controller. */ outb (BCR0(b->port), 0); if (b->chan[8].type || b->chan[12].type) outb (BCR0(b->port+0x10), 0); /* Load the firmware. */ if (b->type == B_SIGMA_800) { /* Reset the controllers. */ outb (BCR2(b->port), BCR2_TMS); if (b->chan[8].type || b->chan[12].type) outb (BCR2(b->port+0x10), BCR2_TMS); outb (BCR2(b->port), 0); if (b->chan[8].type || b->chan[12].type) outb (BCR2(b->port+0x10), 0); if (firmware && (! cx_download (b->port, firmware, bits, tst) || ((b->chan[8].type || b->chan[12].type) && ! cx_download (b->port+0x10, firmware, bits, tst)))) return (0); } /* * Set channels 0 and 8 to RS232 async. mode. * Enable DMA and IRQ. */ outb (BCR0(b->port), b->bcr0); if (b->chan[8].type || b->chan[12].type) outb (BCR0(b->port+0x10), b->bcr0b); /* Clear DTR[0..3] and DTR[8..12]. */ outw (BCR1(b->port), b->bcr1); if (b->chan[8].type || b->chan[12].type) outw (BCR1(b->port+0x10), b->bcr1b); if (b->type == B_SIGMA_800) outb (BCR2(b->port), b->opt.fast & (BCR2_BUS0 | BCR2_BUS1)); /* Initialize all controllers. */ for (i=0; i<NCHAN; i+=4) if (b->chan[i].type != T_NONE) cx_setup_chip (b->chan + i); #ifndef NDIS_MINIPORT_DRIVER /* Set up DMA channel to master mode. */ outb (DMA_MODE, (b->dma & 3) | DMA_MODE_MASTER); /* Enable DMA channel. */ outb (DMA_MASK, b->dma & 3); #endif /* Initialize all channels. */ for (i=0; i<NCHAN; ++i) if (b->chan[i].type != T_NONE) cx_setup_chan (b->chan + i); return (1); } /* * Initialize the board. */ static void cx_setup_chip (cx_chan_t *c) { /* Reset the chip. */ cx_reset (c->port); /* * Set all interrupt level registers to the same value. * This enables the internal CD2400 priority scheme. */ outb (RPILR(c->port), BRD_INTR_LEVEL); outb (TPILR(c->port), BRD_INTR_LEVEL); outb (MPILR(c->port), BRD_INTR_LEVEL); /* Set bus error count to zero. */ outb (BERCNT(c->port), 0); /* Set 16-bit DMA mode. */ outb (DMR(c->port), 0); /* Set timer period register to 1 msec (approximately). */ outb (TPR(c->port), 10); } /* * Initialize the CD2400 channel. */ void cx_update_chan (cx_chan_t *c) { int clock, period; if (c->board->type == B_SIGMA_XXX) switch (c->num) { case 0: c->board->bcr0 &= ~BCR0_UMASK; if (c->mode != M_ASYNC) c->board->bcr0 |= BCR0_UM_SYNC; 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: c->board->bcr0b &= ~BCR0_UMASK; if (c->mode != M_ASYNC) c->board->bcr0b |= BCR0_UM_SYNC; 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; } /* set current channel number */ outb (CAR(c->port), c->num & 3); switch (c->mode) { /* initialize the channel mode */ case M_ASYNC: /* set receiver timeout register */ outw (RTPR(c->port), 10); /* 10 msec, see TPR */ c->opt.rcor.encod = ENCOD_NRZ; outb (CMR(c->port), CMR_RXDMA | CMR_TXDMA | CMR_ASYNC); outb (COR1(c->port), BYTE c->aopt.cor1); outb (COR2(c->port), BYTE c->aopt.cor2); outb (COR3(c->port), BYTE c->aopt.cor3); outb (COR6(c->port), BYTE c->aopt.cor6); outb (COR7(c->port), BYTE c->aopt.cor7); outb (SCHR1(c->port), c->aopt.schr1); outb (SCHR2(c->port), c->aopt.schr2); outb (SCHR3(c->port), c->aopt.schr3); outb (SCHR4(c->port), c->aopt.schr4); outb (SCRL(c->port), c->aopt.scrl); outb (SCRH(c->port), c->aopt.scrh); outb (LNXT(c->port), c->aopt.lnxt); break; case M_HDLC: outb (CMR(c->port), CMR_RXDMA | CMR_TXDMA | CMR_HDLC); outb (COR1(c->port), BYTE c->hopt.cor1); outb (COR2(c->port), BYTE c->hopt.cor2); outb (COR3(c->port), BYTE c->hopt.cor3); outb (RFAR1(c->port), c->hopt.rfar1); outb (RFAR2(c->port), c->hopt.rfar2); outb (RFAR3(c->port), c->hopt.rfar3); outb (RFAR4(c->port), c->hopt.rfar4); outb (CPSR(c->port), c->hopt.cpsr); break; } /* set mode-independent options */ outb (COR4(c->port), BYTE c->opt.cor4); outb (COR5(c->port), BYTE c->opt.cor5); /* set up receiver clock values */ if (c->mode == M_ASYNC || c->opt.rcor.dpll || c->opt.tcor.llm) { cx_clock (c->oscfreq, c->rxbaud, &clock, &period); c->opt.rcor.clk = clock; } else { c->opt.rcor.clk = CLK_EXT; period = 1; } outb (RCOR(c->port), BYTE c->opt.rcor); outb (RBPR(c->port), period); /* set up transmitter clock values */ if (c->mode == M_ASYNC || !c->opt.tcor.ext1x) { unsigned ext1x = c->opt.tcor.ext1x; c->opt.tcor.ext1x = 0; cx_clock (c->oscfreq, c->txbaud, &clock, &period); c->opt.tcor.clk = clock; c->opt.tcor.ext1x = ext1x; } else { c->opt.tcor.clk = CLK_EXT; period = 1; } outb (TCOR(c->port), BYTE c->opt.tcor); outb (TBPR(c->port), period); } /* * Initialize the CD2400 channel. */ void cx_setup_chan (cx_chan_t *c) { /* set current channel number */ outb (CAR(c->port), c->num & 3); /* reset the channel */ cx_cmd (c->port, CCR_CLRCH); /* set LIVR to contain the board and channel numbers */ outb (LIVR(c->port), c->board->num << 6 | c->num << 2); /* clear DTR, RTS, set TXCout/DTR pin */ outb (MSVR_RTS(c->port), 0); outb (MSVR_DTR(c->port), c->mode==M_ASYNC ? 0 : MSV_TXCOUT); /* 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); c->dtr = 0; c->rts = 0; cx_update_chan (c); } /* * Control DTR signal for the channel. * Turn it on/off. */ void cx_set_dtr (cx_chan_t *c, int on) { cx_board_t *b = c->board; c->dtr = on ? 1 : 0; if (b->type == B_SIGMA_2X) { if (on) b->bcr1 |= BCR1_DTR(c->num); else b->bcr1 &= ~BCR1_DTR(c->num); outw (BCR1(b->port), b->bcr1); return; } if (b->type == B_SIGMA_800) { if (c->num >= 8) { if (on) b->bcr1b |= BCR1800_DTR(c->num); else b->bcr1b &= ~BCR1800_DTR(c->num); outb (BCR1(b->port+0x10), b->bcr1b); } else { if (on) b->bcr1 |= BCR1800_DTR(c->num); else b->bcr1 &= ~BCR1800_DTR(c->num); outb (BCR1(b->port), b->bcr1); } return; } if (c->mode == M_ASYNC) { outb (CAR(c->port), c->num & 3); outb (MSVR_DTR(c->port), on ? MSV_DTR : 0); return; } switch (c->num) { default: /* Channels 4..7 and 12..15 in syncronous mode * have no DTR signal. */ break; case 1: case 2: case 3: if (c->type == T_UNIV_RS232) break; case 0: if (on) b->bcr1 |= BCR1_DTR(c->num); else b->bcr1 &= ~BCR1_DTR(c->num); outw (BCR1(b->port), b->bcr1); break; case 9: case 10: case 11: if (c->type == T_UNIV_RS232) break; case 8: if (on) b->bcr1b |= BCR1_DTR(c->num & 3); else b->bcr1b &= ~BCR1_DTR(c->num & 3); outw (BCR1(b->port+0x10), b->bcr1b); break; } } /* * Control RTS signal for the channel. * Turn it on/off. */ void cx_set_rts (cx_chan_t *c, int on) { c->rts = on ? 1 : 0; outb (CAR(c->port), c->num & 3); outb (MSVR_RTS(c->port), on ? MSV_RTS : 0); } /* * Get the state of DSR signal of the channel. */ int cx_get_dsr (cx_chan_t *c) { unsigned char sigval; if (c->board->type == B_SIGMA_2X || c->board->type == B_SIGMA_800 || c->mode == M_ASYNC) { outb (CAR(c->port), c->num & 3); return (inb (MSVR(c->port)) & MSV_DSR ? 1 : 0); } /* * Channels 4..7 and 12..15 don't have DSR signal available. */ switch (c->num) { default: return (1); case 1: case 2: case 3: if (c->type == T_UNIV_RS232) return (1); case 0: sigval = inw (BSR(c->board->port)) >> 8; break; case 9: case 10: case 11: if (c->type == T_UNIV_RS232) return (1); case 8: sigval = inw (BSR(c->board->port+0x10)) >> 8; break; } return (~sigval >> (c->num & 3) & 1); } /* * Get the state of CARRIER signal of the channel. */ int cx_get_cd (cx_chan_t *c) { unsigned char sigval; if (c->board->type == B_SIGMA_2X || c->board->type == B_SIGMA_800 || c->mode == M_ASYNC) { outb (CAR(c->port), c->num & 3); return (inb (MSVR(c->port)) & MSV_CD ? 1 : 0); } /* * Channels 4..7 and 12..15 don't have CD signal available. */ switch (c->num) { default: return (1); case 1: case 2: case 3: if (c->type == T_UNIV_RS232) return (1); case 0: sigval = inw (BSR(c->board->port)) >> 8; break; case 9: case 10: case 11: if (c->type == T_UNIV_RS232) return (1); case 8: sigval = inw (BSR(c->board->port+0x10)) >> 8; break; } return (~sigval >> 4 >> (c->num & 3) & 1); } /* * Get the state of CTS signal of the channel. */ int cx_get_cts (cx_chan_t *c) { outb (CAR(c->port), c->num & 3); return (inb (MSVR(c->port)) & MSV_CTS ? 1 : 0); } /* * Compute CD2400 clock values. */ void cx_clock (long hz, long ba, int *clk, int *div) { static short clocktab[] = { 8, 32, 128, 512, 2048, 0 }; for (*clk=0; clocktab[*clk]; ++*clk) { long c = ba * clocktab[*clk]; if (hz <= c*256) { *div = (2 * hz + c) / (2 * c) - 1; return; } } /* Incorrect baud rate. Return some meaningful values. */ *clk = 0; *div = 255; } /* * Turn LED on/off. */ void cx_led (cx_board_t *b, int on) { switch (b->type) { case B_SIGMA_2X: if (on) b->bcr0 |= BCR02X_LED; else b->bcr0 &= ~BCR02X_LED; outb (BCR0(b->port), b->bcr0); break; } } void cx_disable_dma (cx_board_t *b) { #ifndef NDIS_MINIPORT_DRIVER /* Disable DMA channel. */ outb (DMA_MASK, (b->dma & 3) | DMA_MASK_CLEAR); #endif } cx_board_opt_t board_opt_dflt = { /* board options */ BUS_NORMAL, /* normal bus master timing */ }; cx_chan_opt_t chan_opt_dflt = { /* mode-independent options */ { /* cor4 */ 7, /* FIFO threshold, odd is better */ 0, 0, /* don't detect 1 to 0 on CTS */ 1, /* detect 1 to 0 on CD */ 0, /* detect 1 to 0 on DSR */ }, { /* cor5 */ 0, /* receive flow control FIFO threshold */ 0, 0, /* don't detect 0 to 1 on CTS */ 1, /* detect 0 to 1 on CD */ 0, /* detect 0 to 1 on DSR */ }, { /* rcor */ 0, /* dummy clock source */ ENCOD_NRZ, /* NRZ mode */ 0, /* disable DPLL */ 0, 0, /* transmit line value */ }, { /* tcor */ 0, 0, /* local loopback mode */ 0, 1, /* external 1x clock mode */ 0, 0, /* dummy transmit clock source */ }, }; cx_opt_async_t opt_async_dflt = { /* default async options */ { /* cor1 */ 8-1, /* 8-bit char length */ 0, /* don't ignore parity */ PARM_NOPAR, /* no parity */ PAR_EVEN, /* even parity */ }, { /* cor2 */ 0, /* disable automatic DSR */ 1, /* enable automatic CTS */ 0, /* disable automatic RTS */ 0, /* no remote loopback */ 0, 0, /* disable embedded cmds */ 0, /* disable XON/XOFF */ 0, /* disable XANY */ }, { /* cor3 */ STOPB_1, /* 1 stop bit */ 0, 0, /* disable special char detection */ FLOWCC_PASS, /* pass flow ctl chars to the host */ 0, /* range detect disable */ 0, /* disable extended spec. char detect */ }, { /* cor6 */ PERR_INTR, /* generate exception on parity errors */ BRK_INTR, /* generate exception on break condition */ 0, /* don't translate NL to CR on input */ 0, /* don't translate CR to NL on input */ 0, /* don't discard CR on input */ }, { /* cor7 */ 0, /* don't translate CR to NL on output */ 0, /* don't translate NL to CR on output */ 0, 0, /* don't process flow ctl err chars */ 0, /* disable LNext option */ 0, /* don't strip 8 bit on input */ }, 0, 0, 0, 0, 0, 0, 0, /* clear schr1-4, scrl, scrh, lnxt */ }; cx_opt_hdlc_t opt_hdlc_dflt = { /* default hdlc options */ { /* cor1 */ 2, /* 2 inter-frame flags */ 0, /* no-address mode */ CLRDET_DISABLE, /* disable clear detect */ AFLO_1OCT, /* 1-byte address field length */ }, { /* cor2 */ 0, /* disable automatic DSR */ 0, /* disable automatic CTS */ 0, /* disable automatic RTS */ 0, CRC_INVERT, /* use CRC V.41 */ 0, FCS_NOTPASS, /* don't pass received CRC to the host */ 0, }, { /* cor3 */ 0, /* 0 pad characters sent */ IDLE_FLAG, /* idle in flag */ 0, /* enable FCS */ FCSP_ONES, /* FCS preset to all ones (V.41) */ SYNC_AA, /* use AAh as sync char */ 0, /* disable pad characters */ }, 0, 0, 0, 0, /* clear rfar1-4 */ POLY_V41, /* use V.41 CRC polynomial */ };