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[/] [or1k/] [tags/] [before_ORP/] [uclinux/] [uClinux-2.0.x/] [drivers/] [net/] [soundmodem/] [sm_wss.c] - Rev 1765
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/*****************************************************************************/ /* * sm_wss.c -- soundcard radio modem driver, WSS (half duplex) driver * * Copyright (C) 1996 Thomas Sailer (sailer@ife.ee.ethz.ch) * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. * * Please note that the GPL allows you to use the driver, NOT the radio. * In order to use the radio, you need a license from the communications * authority of your country. * */ #include <linux/ptrace.h> #include <linux/sched.h> #include <linux/interrupt.h> #include <asm/io.h> #include <asm/dma.h> #include <linux/ioport.h> #include <linux/soundmodem.h> #include "sm.h" #include "smdma.h" /* --------------------------------------------------------------------- */ /* * currently this module is supposed to support both module styles, i.e. * the old one present up to about 2.1.9, and the new one functioning * starting with 2.1.21. The reason is I have a kit allowing to compile * this module also under 2.0.x which was requested by several people. * This will go in 2.2 */ #include <linux/version.h> #if LINUX_VERSION_CODE >= 0x20100 #include <asm/uaccess.h> #else #include <asm/segment.h> #include <linux/mm.h> #undef put_user #undef get_user #define put_user(x,ptr) ({ __put_user((unsigned long)(x),(ptr),sizeof(*(ptr))); 0; }) #define get_user(x,ptr) ({ x = ((__typeof__(*(ptr)))__get_user((ptr),sizeof(*(ptr)))); 0; }) extern inline int copy_from_user(void *to, const void *from, unsigned long n) { int i = verify_area(VERIFY_READ, from, n); if (i) return i; memcpy_fromfs(to, from, n); return 0; } extern inline int copy_to_user(void *to, const void *from, unsigned long n) { int i = verify_area(VERIFY_WRITE, to, n); if (i) return i; memcpy_tofs(to, from, n); return 0; } #endif /* --------------------------------------------------------------------- */ struct sc_state_wss { unsigned char revwss, revid, revv, revcid; unsigned char fmt[2]; unsigned char crystal; }; #define SCSTATE ((struct sc_state_wss *)(&sm->hw)) /* --------------------------------------------------------------------- */ #define WSS_CONFIG(iobase) (iobase+0) #define WSS_STATUS(iobase) (iobase+3) #define WSS_CODEC_IA(iobase) (iobase+4) #define WSS_CODEC_ID(iobase) (iobase+5) #define WSS_CODEC_STATUS(iobase) (iobase+6) #define WSS_CODEC_DATA(iobase) (iobase+7) #define WSS_EXTENT 8 #define CS423X_HOTFIX /* --------------------------------------------------------------------- */ static void write_codec(struct device *dev, unsigned char idx, unsigned char data) { int timeout = 900000; /* wait until codec ready */ while (timeout > 0 && inb(WSS_CODEC_IA(dev->base_addr)) & 0x80) timeout--; outb(idx, WSS_CODEC_IA(dev->base_addr)); outb(data, WSS_CODEC_ID(dev->base_addr)); } /* --------------------------------------------------------------------- */ static unsigned char read_codec(struct device *dev, unsigned char idx) { int timeout = 900000; /* wait until codec ready */ while (timeout > 0 && inb(WSS_CODEC_IA(dev->base_addr)) & 0x80) timeout--; outb(idx & 0x1f, WSS_CODEC_IA(dev->base_addr)); return inb(WSS_CODEC_ID(dev->base_addr)); } /* --------------------------------------------------------------------- */ extern void inline wss_ack_int(struct device *dev) { outb(0, WSS_CODEC_STATUS(dev->base_addr)); } /* --------------------------------------------------------------------- */ static int wss_srate_tab[16] = { 8000, 5510, 16000, 11025, 27420, 18900, 32000, 22050, -1, 37800, -1, 44100, 48000, 33075, 9600, 6620 }; static int wss_srate_index(int srate) { int i; for (i = 0; i < (sizeof(wss_srate_tab)/sizeof(wss_srate_tab[0])); i++) if (srate == wss_srate_tab[i] && wss_srate_tab[i] > 0) return i; return -1; } /* --------------------------------------------------------------------- */ static int wss_set_codec_fmt(struct device *dev, struct sm_state *sm, unsigned char fmt, unsigned char fmt2, char fdx, char fullcalib) { unsigned long time; unsigned long flags; save_flags(flags); cli(); /* Clock and data format register */ write_codec(dev, 0x48, fmt); if (SCSTATE->crystal) { write_codec(dev, 0x5c, fmt2 & 0xf0); /* MCE and interface config reg */ write_codec(dev, 0x49, (fdx ? 0 : 0x4) | (fullcalib ? 0x18 : 0)); } else /* MCE and interface config reg */ write_codec(dev, 0x49, fdx ? 0x8 : 0xc); outb(0xb, WSS_CODEC_IA(dev->base_addr)); /* leave MCE */ if (SCSTATE->crystal && !fullcalib) return 0; /* * wait for ACI start */ time = 1000; while (!(read_codec(dev, 0x0b) & 0x20)) if (!(--time)) { printk(KERN_WARNING "%s: ad1848 auto calibration timed out (1)\n", sm_drvname); restore_flags(flags); return -1; } /* * wait for ACI end */ sti(); time = jiffies + HZ/4; while ((read_codec(dev, 0x0b) & 0x20) && ((signed)(jiffies - time) < 0)); restore_flags(flags); if ((signed)(jiffies - time) >= 0) { printk(KERN_WARNING "%s: ad1848 auto calibration timed out (2)\n", sm_drvname); return -1; } return 0; } /* --------------------------------------------------------------------- */ static int wss_init_codec(struct device *dev, struct sm_state *sm, char fdx, unsigned char src_l, unsigned char src_r, int igain_l, int igain_r, int ogain_l, int ogain_r) { unsigned char tmp, reg0, reg1, reg6, reg7; static const signed char irqtab[16] = { -1, -1, 0x10, -1, -1, -1, -1, 0x08, -1, 0x10, 0x18, 0x20, -1, -1, -1, -1 }; static const signed char dmatab[4] = { 1, 2, -1, 3 }; tmp = inb(WSS_STATUS(dev->base_addr)); if ((tmp & 0x3f) != 0x04 && (tmp & 0x3f) != 0x00 && (tmp & 0x3f) != 0x0f) { printk(KERN_WARNING "sm: WSS card id register not found, " "address 0x%lx, ID register 0x%02x\n", dev->base_addr, (int)tmp); /* return -1; */ SCSTATE->revwss = 0; } else { if ((tmp & 0x80) && ((dev->dma == 0) || ((dev->irq >= 8) && (dev->irq != 9)))) { printk(KERN_ERR "%s: WSS: DMA0 and/or IRQ8..IRQ15 " "(except IRQ9) cannot be used on an 8bit " "card\n", sm_drvname); return -1; } if (dev->irq > 15 || irqtab[dev->irq] == -1) { printk(KERN_ERR "%s: WSS: invalid interrupt %d\n", sm_drvname, (int)dev->irq); return -1; } if (dev->dma > 3 || dmatab[dev->dma] == -1) { printk(KERN_ERR "%s: WSS: invalid dma channel %d\n", sm_drvname, (int)dev->dma); return -1; } tmp = irqtab[dev->irq] | dmatab[dev->dma]; /* irq probe */ outb((tmp & 0x38) | 0x40, WSS_CONFIG(dev->base_addr)); if (!(inb(WSS_STATUS(dev->base_addr)) & 0x40)) { outb(0, WSS_CONFIG(dev->base_addr)); printk(KERN_ERR "%s: WSS: IRQ%d is not free!\n", sm_drvname, dev->irq); } outb(tmp, WSS_CONFIG(dev->base_addr)); SCSTATE->revwss = inb(WSS_STATUS(dev->base_addr)) & 0x3f; } /* * initialize the codec */ if (igain_l < 0) igain_l = 0; if (igain_r < 0) igain_r = 0; if (ogain_l > 0) ogain_l = 0; if (ogain_r > 0) ogain_r = 0; reg0 = (src_l << 6) & 0xc0; reg1 = (src_r << 6) & 0xc0; if (reg0 == 0x80 && igain_l >= 20) { reg0 |= 0x20; igain_l -= 20; } if (reg1 == 0x80 && igain_r >= 20) { reg1 |= 0x20; igain_r -= 20; } if (igain_l > 23) igain_l = 23; if (igain_r > 23) igain_r = 23; reg0 |= igain_l * 2 / 3; reg1 |= igain_r * 2 / 3; reg6 = (ogain_l < -95) ? 0x80 : (ogain_l * (-2) / 3); reg7 = (ogain_r < -95) ? 0x80 : (ogain_r * (-2) / 3); write_codec(dev, 9, 0); write_codec(dev, 0, 0x45); if (read_codec(dev, 0) != 0x45) goto codec_err; write_codec(dev, 0, 0xaa); if (read_codec(dev, 0) != 0xaa) goto codec_err; write_codec(dev, 12, 0x40); /* enable MODE2 */ write_codec(dev, 16, 0); write_codec(dev, 0, 0x45); SCSTATE->crystal = (read_codec(dev, 16) != 0x45); write_codec(dev, 0, 0xaa); SCSTATE->crystal &= (read_codec(dev, 16) != 0xaa); if (SCSTATE->crystal) { SCSTATE->revcid = read_codec(dev, 0x19); SCSTATE->revv = (SCSTATE->revcid >> 5) & 7; SCSTATE->revcid &= 7; write_codec(dev, 0x10, 0x80); /* maximum output level */ write_codec(dev, 0x11, 0x02); /* xtal enable and no HPF */ write_codec(dev, 0x12, 0x80); /* left line input control */ write_codec(dev, 0x13, 0x80); /* right line input control */ write_codec(dev, 0x16, 0); /* disable alternative freq sel */ write_codec(dev, 0x1a, 0xe0); /* mono IO disable */ write_codec(dev, 0x1b, 0x00); /* left out no att */ write_codec(dev, 0x1d, 0x00); /* right out no att */ } if (wss_set_codec_fmt(dev, sm, SCSTATE->fmt[0], SCSTATE->fmt[0], fdx, 1)) goto codec_err; write_codec(dev, 0, reg0); /* left input control */ write_codec(dev, 1, reg1); /* right input control */ write_codec(dev, 2, 0x80); /* left aux#1 input control */ write_codec(dev, 3, 0x80); /* right aux#1 input control */ write_codec(dev, 4, 0x80); /* left aux#2 input control */ write_codec(dev, 5, 0x80); /* right aux#2 input control */ write_codec(dev, 6, reg6); /* left dac control */ write_codec(dev, 7, reg7); /* right dac control */ write_codec(dev, 0xa, 0x2); /* pin control register */ write_codec(dev, 0xd, 0x0); /* digital mix control */ SCSTATE->revid = read_codec(dev, 0xc) & 0xf; /* * print revisions */ if (SCSTATE->crystal) printk(KERN_INFO "%s: Crystal CODEC ID %d, Chip revision %d, " " Chip ID %d\n", sm_drvname, (int)SCSTATE->revid, (int)SCSTATE->revv, (int)SCSTATE->revcid); else printk(KERN_INFO "%s: WSS revision %d, CODEC revision %d\n", sm_drvname, (int)SCSTATE->revwss, (int)SCSTATE->revid); return 0; codec_err: outb(0, WSS_CONFIG(dev->base_addr)); printk(KERN_ERR "%s: no WSS soundcard found at address 0x%lx\n", sm_drvname, dev->base_addr); return -1; } /* --------------------------------------------------------------------- */ static void setup_dma_wss(struct device *dev, struct sm_state *sm, int send) { unsigned long flags; static const unsigned char codecmode[2] = { 0x0e, 0x0d }; unsigned char oldcodecmode; long abrt; unsigned char fmt; unsigned int numsamps; send = !!send; fmt = SCSTATE->fmt[send]; save_flags(flags); cli(); /* * perform the final DMA sequence to disable the codec request */ oldcodecmode = read_codec(dev, 9); write_codec(dev, 9, 0xc); /* disable codec */ wss_ack_int(dev); if (read_codec(dev, 11) & 0x10) { dma_setup(sm, oldcodecmode & 1, dev->dma); abrt = 0; while ((read_codec(dev, 11) & 0x10) || ((++abrt) >= 0x10000)); } #ifdef CS423X_HOTFIX if (read_codec(dev, 0x8) != fmt || SCSTATE->crystal) wss_set_codec_fmt(dev, sm, fmt, fmt, 0, 0); #else /* CS423X_HOTFIX */ if (read_codec(dev, 0x8) != fmt) wss_set_codec_fmt(dev, sm, fmt, fmt, 0, 0); #endif /* CS423X_HOTFIX */ numsamps = dma_setup(sm, send, dev->dma) - 1; write_codec(dev, 15, numsamps & 0xff); write_codec(dev, 14, numsamps >> 8); write_codec(dev, 9, codecmode[send]); restore_flags(flags); } /* --------------------------------------------------------------------- */ static void wss_interrupt(int irq, void *dev_id, struct pt_regs *regs) { struct device *dev = (struct device *)dev_id; struct sm_state *sm = (struct sm_state *)dev->priv; unsigned int curfrag; unsigned int nums; if (!dev || !sm || !sm->mode_rx || !sm->mode_tx || sm->hdrv.magic != HDLCDRV_MAGIC) return; cli(); wss_ack_int(dev); disable_dma(dev->dma); clear_dma_ff(dev->dma); nums = dma_ptr(sm, sm->dma.ptt_cnt > 0, dev->dma, &curfrag) - 1; write_codec(dev, 15, nums & 0xff); write_codec(dev, 14, nums >> 8); enable_dma(dev->dma); sm_int_freq(sm); sti(); if (sm->dma.ptt_cnt <= 0) { dma_receive(sm, curfrag); hdlcdrv_arbitrate(dev, &sm->hdrv); if (hdlcdrv_ptt(&sm->hdrv)) { /* starting to transmit */ disable_dma(dev->dma); hdlcdrv_transmitter(dev, &sm->hdrv); /* prefill HDLC buffer */ dma_start_transmit(sm); setup_dma_wss(dev, sm, 1); dma_transmit(sm); } } else if (dma_end_transmit(sm, curfrag)) { /* stopping transmission */ disable_dma(dev->dma); dma_init_receive(sm); setup_dma_wss(dev, sm, 0); } else dma_transmit(sm); sm_output_status(sm); hdlcdrv_transmitter(dev, &sm->hdrv); hdlcdrv_receiver(dev, &sm->hdrv); } /* --------------------------------------------------------------------- */ static int wss_open(struct device *dev, struct sm_state *sm) { unsigned int dmasz, u; if (sizeof(sm->m) < sizeof(struct sc_state_wss)) { printk(KERN_ERR "sm wss: wss state too big: %d > %d\n", sizeof(struct sc_state_wss), sizeof(sm->m)); return -ENODEV; } if (!dev || !sm || !sm->mode_rx || !sm->mode_tx) return -ENXIO; if (dev->base_addr <= 0 || dev->base_addr > 0x1000-WSS_EXTENT || dev->irq < 2 || dev->irq > 15 || dev->dma > 3) return -ENXIO; if (check_region(dev->base_addr, WSS_EXTENT)) return -EACCES; /* * check if a card is available */ if (wss_init_codec(dev, sm, 0, 1, 1, 0, 0, -45, -45)) return -ENODEV; /* * initialize some variables */ dma_init_receive(sm); dmasz = (NUM_FRAGMENTS + 1) * sm->dma.ifragsz; u = NUM_FRAGMENTS * sm->dma.ofragsz; if (u > dmasz) dmasz = u; if (!(sm->dma.ibuf = sm->dma.obuf = kmalloc(dmasz, GFP_KERNEL | GFP_DMA))) return -ENOMEM; dma_init_transmit(sm); dma_init_receive(sm); memset(&sm->m, 0, sizeof(sm->m)); memset(&sm->d, 0, sizeof(sm->d)); if (sm->mode_tx->init) sm->mode_tx->init(sm); if (sm->mode_rx->init) sm->mode_rx->init(sm); if (request_dma(dev->dma, sm->hwdrv->hw_name)) { kfree_s(sm->dma.obuf, dmasz); return -EBUSY; } if (request_irq(dev->irq, wss_interrupt, SA_INTERRUPT, sm->hwdrv->hw_name, dev)) { free_dma(dev->dma); kfree_s(sm->dma.obuf, dmasz); return -EBUSY; } request_region(dev->base_addr, WSS_EXTENT, sm->hwdrv->hw_name); setup_dma_wss(dev, sm, 0); return 0; } /* --------------------------------------------------------------------- */ static int wss_close(struct device *dev, struct sm_state *sm) { if (!dev || !sm) return -EINVAL; /* * disable interrupts */ disable_dma(dev->dma); write_codec(dev, 9, 0xc); /* disable codec */ free_irq(dev->irq, dev); free_dma(dev->dma); release_region(dev->base_addr, WSS_EXTENT); kfree(sm->dma.obuf); return 0; } /* --------------------------------------------------------------------- */ static int wss_sethw(struct device *dev, struct sm_state *sm, char *mode) { char *cp = strchr(mode, '.'); const struct modem_tx_info **mtp = sm_modem_tx_table; const struct modem_rx_info **mrp; int i, j; if (!strcmp(mode, "off")) { sm->mode_tx = NULL; sm->mode_rx = NULL; return 0; } if (cp) *cp++ = '\0'; else cp = mode; for (; *mtp; mtp++) { if ((*mtp)->loc_storage > sizeof(sm->m)) { printk(KERN_ERR "%s: insufficient storage for modulator %s (%d)\n", sm_drvname, (*mtp)->name, (*mtp)->loc_storage); continue; } if (!(*mtp)->name || strcmp((*mtp)->name, mode)) continue; if ((i = wss_srate_index((*mtp)->srate)) < 0) continue; for (mrp = sm_modem_rx_table; *mrp; mrp++) { if ((*mrp)->loc_storage > sizeof(sm->d)) { printk(KERN_ERR "%s: insufficient storage for demodulator %s (%d)\n", sm_drvname, (*mrp)->name, (*mrp)->loc_storage); continue; } if ((*mrp)->name && !strcmp((*mrp)->name, cp) && ((j = wss_srate_index((*mrp)->srate)) >= 0)) { sm->mode_tx = *mtp; sm->mode_rx = *mrp; SCSTATE->fmt[0] = j; SCSTATE->fmt[1] = i; sm->dma.ifragsz = (sm->mode_rx->srate + 50)/100; sm->dma.ofragsz = (sm->mode_tx->srate + 50)/100; if (sm->dma.ifragsz < sm->mode_rx->overlap) sm->dma.ifragsz = sm->mode_rx->overlap; /* prefer same data format if possible to minimize switching times */ sm->dma.i16bit = sm->dma.o16bit = 2; if (sm->mode_rx->srate == sm->mode_tx->srate) { if (sm->mode_rx->demodulator_s16 && sm->mode_tx->modulator_s16) sm->dma.i16bit = sm->dma.o16bit = 1; else if (sm->mode_rx->demodulator_u8 && sm->mode_tx->modulator_u8) sm->dma.i16bit = sm->dma.o16bit = 0; } if (sm->dma.i16bit == 2) { if (sm->mode_rx->demodulator_s16) sm->dma.i16bit = 1; else if (sm->mode_rx->demodulator_u8) sm->dma.i16bit = 0; } if (sm->dma.o16bit == 2) { if (sm->mode_tx->modulator_s16) sm->dma.o16bit = 1; else if (sm->mode_tx->modulator_u8) sm->dma.o16bit = 0; } if (sm->dma.i16bit == 2 || sm->dma.o16bit == 2) { printk(KERN_INFO "%s: mode %s or %s unusable\n", sm_drvname, sm->mode_rx->name, sm->mode_tx->name); sm->mode_tx = NULL; sm->mode_rx = NULL; return -EINVAL; } #ifdef __BIG_ENDIAN /* big endian 16bit only works on crystal cards... */ if (sm->dma.i16bit) { SCSTATE->fmt[0] |= 0xc0; sm->dma.ifragsz <<= 1; } if (sm->dma.o16bit) { SCSTATE->fmt[1] |= 0xc0; sm->dma.ofragsz <<= 1; } #else /* __BIG_ENDIAN */ if (sm->dma.i16bit) { SCSTATE->fmt[0] |= 0x40; sm->dma.ifragsz <<= 1; } if (sm->dma.o16bit) { SCSTATE->fmt[1] |= 0x40; sm->dma.ofragsz <<= 1; } #endif /* __BIG_ENDIAN */ return 0; } } } return -EINVAL; } /* --------------------------------------------------------------------- */ static int wss_ioctl(struct device *dev, struct sm_state *sm, struct ifreq *ifr, struct hdlcdrv_ioctl *hi, int cmd) { struct sm_ioctl bi; int i; if (cmd != SIOCDEVPRIVATE) return -ENOIOCTLCMD; if (hi->cmd == HDLCDRVCTL_MODEMPARMASK) return HDLCDRV_PARMASK_IOBASE | HDLCDRV_PARMASK_IRQ | HDLCDRV_PARMASK_DMA | HDLCDRV_PARMASK_SERIOBASE | HDLCDRV_PARMASK_PARIOBASE | HDLCDRV_PARMASK_MIDIIOBASE; if (copy_from_user(&bi, ifr->ifr_data, sizeof(bi))) return -EFAULT; switch (bi.cmd) { default: return -ENOIOCTLCMD; case SMCTL_GETMIXER: i = 0; bi.data.mix.sample_rate = sm->mode_rx->srate; bi.data.mix.bit_rate = sm->hdrv.par.bitrate; bi.data.mix.mixer_type = SCSTATE->crystal ? SM_MIXER_CRYSTAL : SM_MIXER_AD1848; if (((SCSTATE->crystal ? 0x2c0c20fflu: 0x20fflu) >> bi.data.mix.reg) & 1) { bi.data.mix.data = read_codec(dev, bi.data.mix.reg); i = 1; } if (copy_to_user(ifr->ifr_data, &bi, sizeof(bi))) return -EFAULT; return i; case SMCTL_SETMIXER: if (!suser()) return -EACCES; if ((bi.data.mix.mixer_type != SM_MIXER_CRYSTAL || !SCSTATE->crystal) && (bi.data.mix.mixer_type != SM_MIXER_AD1848 || bi.data.mix.reg >= 0x10)) return -EINVAL; if (!((0x2c0c20fflu >> bi.data.mix.reg) & 1)) return -EACCES; write_codec(dev, bi.data.mix.reg, bi.data.mix.data); return 0; } if (copy_to_user(ifr->ifr_data, &bi, sizeof(bi))) return -EFAULT; return 0; } /* --------------------------------------------------------------------- */ const struct hardware_info sm_hw_wss = { "wss", sizeof(struct sc_state_wss), wss_open, wss_close, wss_ioctl, wss_sethw }; /* --------------------------------------------------------------------- */ static void setup_fdx_dma_wss(struct device *dev, struct sm_state *sm) { unsigned long flags; unsigned char oldcodecmode, codecdma; long abrt; unsigned int osamps, isamps; save_flags(flags); cli(); /* * perform the final DMA sequence to disable the codec request */ oldcodecmode = read_codec(dev, 9); write_codec(dev, 9, 0); /* disable codec DMA */ wss_ack_int(dev); if ((codecdma = read_codec(dev, 11)) & 0x10) { dma_setup(sm, 1, dev->dma); dma_setup(sm, 0, sm->hdrv.ptt_out.dma2); abrt = 0; while (((codecdma = read_codec(dev, 11)) & 0x10) || ((++abrt) >= 0x10000)); } wss_set_codec_fmt(dev, sm, SCSTATE->fmt[1], SCSTATE->fmt[0], 1, 1); osamps = dma_setup(sm, 1, dev->dma) - 1; isamps = dma_setup(sm, 0, sm->hdrv.ptt_out.dma2) - 1; write_codec(dev, 15, osamps & 0xff); write_codec(dev, 14, osamps >> 8); if (SCSTATE->crystal) { write_codec(dev, 31, isamps & 0xff); write_codec(dev, 30, isamps >> 8); } write_codec(dev, 9, 3); restore_flags(flags); } /* --------------------------------------------------------------------- */ static void wssfdx_interrupt(int irq, void *dev_id, struct pt_regs *regs) { struct device *dev = (struct device *)dev_id; struct sm_state *sm = (struct sm_state *)dev->priv; unsigned long flags; unsigned char cry_int_src; unsigned icfrag, ocfrag, isamps, osamps; if (!dev || !sm || !sm->mode_rx || !sm->mode_tx || sm->hdrv.magic != HDLCDRV_MAGIC) return; save_flags(flags); cli(); if (SCSTATE->crystal) { /* Crystal has an essentially different interrupt handler! */ cry_int_src = read_codec(dev, 0x18); wss_ack_int(dev); if (cry_int_src & 0x10) { /* playback interrupt */ disable_dma(dev->dma); clear_dma_ff(dev->dma); osamps = dma_ptr(sm, 1, dev->dma, &ocfrag)-1; write_codec(dev, 15, osamps & 0xff); write_codec(dev, 14, osamps >> 8); enable_dma(dev->dma); } if (cry_int_src & 0x20) { /* capture interrupt */ disable_dma(sm->hdrv.ptt_out.dma2); clear_dma_ff(sm->hdrv.ptt_out.dma2); isamps = dma_ptr(sm, 0, sm->hdrv.ptt_out.dma2, &icfrag)-1; write_codec(dev, 31, isamps & 0xff); write_codec(dev, 30, isamps >> 8); enable_dma(sm->hdrv.ptt_out.dma2); } restore_flags(flags); sm_int_freq(sm); sti(); if (cry_int_src & 0x10) { if (dma_end_transmit(sm, ocfrag)) dma_clear_transmit(sm); dma_transmit(sm); } if (cry_int_src & 0x20) { dma_receive(sm, icfrag); hdlcdrv_arbitrate(dev, &sm->hdrv); } sm_output_status(sm); hdlcdrv_transmitter(dev, &sm->hdrv); hdlcdrv_receiver(dev, &sm->hdrv); return; } wss_ack_int(dev); disable_dma(dev->dma); disable_dma(sm->hdrv.ptt_out.dma2); clear_dma_ff(dev->dma); clear_dma_ff(sm->hdrv.ptt_out.dma2); osamps = dma_ptr(sm, 1, dev->dma, &ocfrag)-1; isamps = dma_ptr(sm, 0, sm->hdrv.ptt_out.dma2, &icfrag)-1; write_codec(dev, 15, osamps & 0xff); write_codec(dev, 14, osamps >> 8); if (SCSTATE->crystal) { write_codec(dev, 31, isamps & 0xff); write_codec(dev, 30, isamps >> 8); } enable_dma(dev->dma); enable_dma(sm->hdrv.ptt_out.dma2); restore_flags(flags); sm_int_freq(sm); sti(); if (dma_end_transmit(sm, ocfrag)) dma_clear_transmit(sm); dma_transmit(sm); dma_receive(sm, icfrag); hdlcdrv_arbitrate(dev, &sm->hdrv); sm_output_status(sm); hdlcdrv_transmitter(dev, &sm->hdrv); hdlcdrv_receiver(dev, &sm->hdrv); } /* --------------------------------------------------------------------- */ static int wssfdx_open(struct device *dev, struct sm_state *sm) { if (!dev || !sm || !sm->mode_rx || !sm->mode_tx) return -ENXIO; if (dev->base_addr <= 0 || dev->base_addr > 0x1000-WSS_EXTENT || dev->irq < 2 || dev->irq > 15 || dev->dma > 3) return -ENXIO; if (check_region(dev->base_addr, WSS_EXTENT)) return -EACCES; /* * check if a card is available */ if (wss_init_codec(dev, sm, 1, 1, 1, 0, 0, -45, -45)) return -ENODEV; /* * initialize some variables */ if (!(sm->dma.ibuf = kmalloc(sm->dma.ifragsz * (NUM_FRAGMENTS+1), GFP_KERNEL | GFP_DMA))) return -ENOMEM; if (!(sm->dma.obuf = kmalloc(sm->dma.ofragsz * NUM_FRAGMENTS, GFP_KERNEL | GFP_DMA))) { kfree(sm->dma.ibuf); return -ENOMEM; } dma_init_transmit(sm); dma_init_receive(sm); memset(&sm->m, 0, sizeof(sm->m)); memset(&sm->d, 0, sizeof(sm->d)); if (sm->mode_tx->init) sm->mode_tx->init(sm); if (sm->mode_rx->init) sm->mode_rx->init(sm); if (request_dma(dev->dma, sm->hwdrv->hw_name)) { kfree(sm->dma.ibuf); kfree(sm->dma.obuf); return -EBUSY; } if (request_dma(sm->hdrv.ptt_out.dma2, sm->hwdrv->hw_name)) { kfree(sm->dma.ibuf); kfree(sm->dma.obuf); free_dma(dev->dma); return -EBUSY; } if (request_irq(dev->irq, wssfdx_interrupt, SA_INTERRUPT, sm->hwdrv->hw_name, dev)) { kfree(sm->dma.ibuf); kfree(sm->dma.obuf); free_dma(dev->dma); free_dma(sm->hdrv.ptt_out.dma2); return -EBUSY; } request_region(dev->base_addr, WSS_EXTENT, sm->hwdrv->hw_name); setup_fdx_dma_wss(dev, sm); return 0; } /* --------------------------------------------------------------------- */ static int wssfdx_close(struct device *dev, struct sm_state *sm) { if (!dev || !sm) return -EINVAL; /* * disable interrupts */ disable_dma(dev->dma); disable_dma(sm->hdrv.ptt_out.dma2); write_codec(dev, 9, 0xc); /* disable codec */ free_irq(dev->irq, dev); free_dma(dev->dma); free_dma(sm->hdrv.ptt_out.dma2); release_region(dev->base_addr, WSS_EXTENT); kfree(sm->dma.ibuf); kfree(sm->dma.obuf); return 0; } /* --------------------------------------------------------------------- */ static int wssfdx_sethw(struct device *dev, struct sm_state *sm, char *mode) { char *cp = strchr(mode, '.'); const struct modem_tx_info **mtp = sm_modem_tx_table; const struct modem_rx_info **mrp; int i; if (!strcmp(mode, "off")) { sm->mode_tx = NULL; sm->mode_rx = NULL; return 0; } if (cp) *cp++ = '\0'; else cp = mode; for (; *mtp; mtp++) { if ((*mtp)->loc_storage > sizeof(sm->m)) { printk(KERN_ERR "%s: insufficient storage for modulator %s (%d)\n", sm_drvname, (*mtp)->name, (*mtp)->loc_storage); continue; } if (!(*mtp)->name || strcmp((*mtp)->name, mode)) continue; if ((i = wss_srate_index((*mtp)->srate)) < 0) continue; for (mrp = sm_modem_rx_table; *mrp; mrp++) { if ((*mrp)->loc_storage > sizeof(sm->d)) { printk(KERN_ERR "%s: insufficient storage for demodulator %s (%d)\n", sm_drvname, (*mrp)->name, (*mrp)->loc_storage); continue; } if ((*mrp)->name && !strcmp((*mrp)->name, cp) && (*mtp)->srate == (*mrp)->srate) { sm->mode_tx = *mtp; sm->mode_rx = *mrp; SCSTATE->fmt[0] = SCSTATE->fmt[1] = i; sm->dma.ifragsz = sm->dma.ofragsz = (sm->mode_rx->srate + 50)/100; if (sm->dma.ifragsz < sm->mode_rx->overlap) sm->dma.ifragsz = sm->mode_rx->overlap; sm->dma.i16bit = sm->dma.o16bit = 2; if (sm->mode_rx->demodulator_s16) { sm->dma.i16bit = 1; sm->dma.ifragsz <<= 1; #ifdef __BIG_ENDIAN /* big endian 16bit only works on crystal cards... */ SCSTATE->fmt[0] |= 0xc0; #else /* __BIG_ENDIAN */ SCSTATE->fmt[0] |= 0x40; #endif /* __BIG_ENDIAN */ } else if (sm->mode_rx->demodulator_u8) sm->dma.i16bit = 0; if (sm->mode_tx->modulator_s16) { sm->dma.o16bit = 1; sm->dma.ofragsz <<= 1; #ifdef __BIG_ENDIAN /* big endian 16bit only works on crystal cards... */ SCSTATE->fmt[1] |= 0xc0; #else /* __BIG_ENDIAN */ SCSTATE->fmt[1] |= 0x40; #endif /* __BIG_ENDIAN */ } else if (sm->mode_tx->modulator_u8) sm->dma.o16bit = 0; if (sm->dma.i16bit == 2 || sm->dma.o16bit == 2) { printk(KERN_INFO "%s: mode %s or %s unusable\n", sm_drvname, sm->mode_rx->name, sm->mode_tx->name); sm->mode_tx = NULL; sm->mode_rx = NULL; return -EINVAL; } return 0; } } } return -EINVAL; } /* --------------------------------------------------------------------- */ static int wssfdx_ioctl(struct device *dev, struct sm_state *sm, struct ifreq *ifr, struct hdlcdrv_ioctl *hi, int cmd) { if (cmd != SIOCDEVPRIVATE) return -ENOIOCTLCMD; if (hi->cmd == HDLCDRVCTL_MODEMPARMASK) return HDLCDRV_PARMASK_IOBASE | HDLCDRV_PARMASK_IRQ | HDLCDRV_PARMASK_DMA | HDLCDRV_PARMASK_DMA2 | HDLCDRV_PARMASK_SERIOBASE | HDLCDRV_PARMASK_PARIOBASE | HDLCDRV_PARMASK_MIDIIOBASE; return wss_ioctl(dev, sm, ifr, hi, cmd); } /* --------------------------------------------------------------------- */ const struct hardware_info sm_hw_wssfdx = { "wssfdx", sizeof(struct sc_state_wss), wssfdx_open, wssfdx_close, wssfdx_ioctl, wssfdx_sethw }; /* --------------------------------------------------------------------- */ #undef SCSTATE