/* * Driver for the NXP SAA7164 PCIe bridge * * Copyright (c) 2009 Steven Toth * * 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. */ #include #include "saa7164.h" int saa7164_api_transition_port(struct saa7164_tsport *port, u8 mode) { int ret; ret = saa7164_cmd_send(port->dev, port->hwcfg.unitid, SET_CUR, SAA_STATE_CONTROL, sizeof(mode), &mode); if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret = 0x%x\n", __func__, ret); return ret; } int saa7164_api_get_fw_version(struct saa7164_dev *dev, u32 *version) { int ret; ret = saa7164_cmd_send(dev, 0, GET_CUR, GET_FW_VERSION_CONTROL, sizeof(u32), version); if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret = 0x%x\n", __func__, ret); return ret; } int saa7164_api_read_eeprom(struct saa7164_dev *dev, u8 *buf, int buflen) { u8 reg[] = { 0x0f, 0x00 }; if (buflen < 128) return -ENOMEM; /* Assumption: Hauppauge eeprom is at 0xa0 on on bus 0 */ /* TODO: Pull the details from the boards struct */ return saa7164_api_i2c_read(&dev->i2c_bus[0], 0xa0 >> 1, sizeof(reg), ®[0], 128, buf); } #if 0 /* Exercise the i2c interface, saa7164_cmd()/bus() layers: * 1. Read the identity byte from each of the demodulators. * 2. Read the entire register set from the TDA18271. * TODO: This function has no purpose other than to exercise i2c. */ int saa7164_api_test(struct saa7164_dev *dev) { /* TDA10048 identities */ u8 reg[] = { 0x00 }; u8 data[256]; dprintk(DBGLVL_API, "%s()\n", __func__); #if 0 /* Read the identity byte from the TDA10048 demodulators */ saa7164_api_i2c_read(&dev->i2c_bus[1], 0x10 >> 1, sizeof(reg), ®[0], 1, &data[0]); saa7164_api_i2c_read(&dev->i2c_bus[2], 0x10 >> 1, sizeof(reg), ®[0], 1, &data[0]); #endif /* Read all 39 bytes from the TDA18271 tuners */ saa7164_api_i2c_read(&dev->i2c_bus[1], 0xc0 >> 1, 0, ®[0], 39, &data[0]); saa7164_api_i2c_read(&dev->i2c_bus[2], 0xc0 >> 1, 0, ®[0], 39, &data[0]); return 0; } #endif int saa7164_api_configure_port_mpeg2ts(struct saa7164_dev *dev, struct saa7164_tsport *port, tmComResTSFormatDescrHeader_t *tsfmt) { dprintk(DBGLVL_API, " bFormatIndex = 0x%x\n", tsfmt->bFormatIndex); dprintk(DBGLVL_API, " bDataOffset = 0x%x\n", tsfmt->bDataOffset); dprintk(DBGLVL_API, " bPacketLength= 0x%x\n", tsfmt->bPacketLength); dprintk(DBGLVL_API, " bStrideLength= 0x%x\n", tsfmt->bStrideLength); dprintk(DBGLVL_API, " bguid = (....)\n"); /* Cache the hardware configuration in the port */ port->bufcounter = port->hwcfg.BARLocation; port->pitch = port->hwcfg.BARLocation + (2 * sizeof(u32)); port->bufsize = port->hwcfg.BARLocation + (3 * sizeof(u32)); port->bufoffset = port->hwcfg.BARLocation + (4 * sizeof(u32)); port->bufptr32l = port->hwcfg.BARLocation + (4 * sizeof(u32)) + (sizeof(u32) * port->hwcfg.buffercount) + sizeof(u32); port->bufptr32h = port->hwcfg.BARLocation + (4 * sizeof(u32)) + (sizeof(u32) * port->hwcfg.buffercount); port->bufptr64 = port->hwcfg.BARLocation + (4 * sizeof(u32)) + (sizeof(u32) * port->hwcfg.buffercount); dprintk(DBGLVL_API, " = port->hwcfg.BARLocation = 0x%x\n", port->hwcfg.BARLocation); dprintk(DBGLVL_API, " = VS_FORMAT_MPEGTS (becomes dev->ts[%d])\n", port->nr); return 0; } int saa7164_api_dump_subdevs(struct saa7164_dev *dev, u8 *buf, int len) { struct saa7164_tsport *port = 0; u32 idx, next_offset; int i; tmComResDescrHeader_t *hdr, *t; tmComResExtDevDescrHeader_t *exthdr; tmComResPathDescrHeader_t *pathhdr; tmComResAntTermDescrHeader_t *anttermhdr; tmComResTunerDescrHeader_t *tunerunithdr; tmComResDMATermDescrHeader_t *vcoutputtermhdr; tmComResTSFormatDescrHeader_t *tsfmt; u32 currpath = 0; dprintk(DBGLVL_API, "%s(?,?,%d) sizeof(tmComResDescrHeader_t) = %d bytes\n", __func__, len, (u32)sizeof(tmComResDescrHeader_t)); for (idx = 0; idx < (len - sizeof(tmComResDescrHeader_t)); ) { hdr = (tmComResDescrHeader_t *)(buf + idx); if (hdr->type != CS_INTERFACE) return SAA_ERR_NOT_SUPPORTED; dprintk(DBGLVL_API, "@ 0x%x = \n", idx); switch (hdr->subtype) { case GENERAL_REQUEST: dprintk(DBGLVL_API, " GENERAL_REQUEST\n"); break; case VC_TUNER_PATH: dprintk(DBGLVL_API, " VC_TUNER_PATH\n"); pathhdr = (tmComResPathDescrHeader_t *)(buf + idx); dprintk(DBGLVL_API, " pathid = 0x%x\n", pathhdr->pathid); currpath = pathhdr->pathid; break; case VC_INPUT_TERMINAL: dprintk(DBGLVL_API, " VC_INPUT_TERMINAL\n"); anttermhdr = (tmComResAntTermDescrHeader_t *)(buf + idx); dprintk(DBGLVL_API, " terminalid = 0x%x\n", anttermhdr->terminalid); dprintk(DBGLVL_API, " terminaltype = 0x%x\n", anttermhdr->terminaltype); switch (anttermhdr->terminaltype) { case ITT_ANTENNA: dprintk(DBGLVL_API, " = ITT_ANTENNA\n"); break; case LINE_CONNECTOR: dprintk(DBGLVL_API, " = LINE_CONNECTOR\n"); break; case SPDIF_CONNECTOR: dprintk(DBGLVL_API, " = SPDIF_CONNECTOR\n"); break; case COMPOSITE_CONNECTOR: dprintk(DBGLVL_API, " = COMPOSITE_CONNECTOR\n"); break; case SVIDEO_CONNECTOR: dprintk(DBGLVL_API, " = SVIDEO_CONNECTOR\n"); break; case COMPONENT_CONNECTOR: dprintk(DBGLVL_API, " = COMPONENT_CONNECTOR\n"); break; case STANDARD_DMA: dprintk(DBGLVL_API, " = STANDARD_DMA\n"); break; default: dprintk(DBGLVL_API, " = undefined (0x%x)\n", anttermhdr->terminaltype); } dprintk(DBGLVL_API, " assocterminal= 0x%x\n", anttermhdr->assocterminal); dprintk(DBGLVL_API, " iterminal = 0x%x\n", anttermhdr->iterminal); dprintk(DBGLVL_API, " controlsize = 0x%x\n", anttermhdr->controlsize); break; case VC_OUTPUT_TERMINAL: dprintk(DBGLVL_API, " VC_OUTPUT_TERMINAL\n"); vcoutputtermhdr = (tmComResDMATermDescrHeader_t *)(buf + idx); dprintk(DBGLVL_API, " unitid = 0x%x\n", vcoutputtermhdr->unitid); dprintk(DBGLVL_API, " terminaltype = 0x%x\n", vcoutputtermhdr->terminaltype); switch (vcoutputtermhdr->terminaltype) { case ITT_ANTENNA: dprintk(DBGLVL_API, " = ITT_ANTENNA\n"); break; case LINE_CONNECTOR: dprintk(DBGLVL_API, " = LINE_CONNECTOR\n"); break; case SPDIF_CONNECTOR: dprintk(DBGLVL_API, " = SPDIF_CONNECTOR\n"); break; case COMPOSITE_CONNECTOR: dprintk(DBGLVL_API, " = COMPOSITE_CONNECTOR\n"); break; case SVIDEO_CONNECTOR: dprintk(DBGLVL_API, " = SVIDEO_CONNECTOR\n"); break; case COMPONENT_CONNECTOR: dprintk(DBGLVL_API, " = COMPONENT_CONNECTOR\n"); break; case STANDARD_DMA: dprintk(DBGLVL_API, " = STANDARD_DMA\n"); break; default: dprintk(DBGLVL_API, " = undefined (0x%x)\n", vcoutputtermhdr->terminaltype); } dprintk(DBGLVL_API, " assocterminal= 0x%x\n", vcoutputtermhdr->assocterminal); dprintk(DBGLVL_API, " sourceid = 0x%x\n", vcoutputtermhdr->sourceid); dprintk(DBGLVL_API, " iterminal = 0x%x\n", vcoutputtermhdr->iterminal); dprintk(DBGLVL_API, " BARLocation = 0x%x\n", vcoutputtermhdr->BARLocation); dprintk(DBGLVL_API, " flags = 0x%x\n", vcoutputtermhdr->flags); dprintk(DBGLVL_API, " interruptid = 0x%x\n", vcoutputtermhdr->interruptid); dprintk(DBGLVL_API, " buffercount = 0x%x\n", vcoutputtermhdr->buffercount); dprintk(DBGLVL_API, " metadatasize = 0x%x\n", vcoutputtermhdr->metadatasize); dprintk(DBGLVL_API, " controlsize = 0x%x\n", vcoutputtermhdr->controlsize); dprintk(DBGLVL_API, " numformats = 0x%x\n", vcoutputtermhdr->numformats); t = (tmComResDescrHeader_t *) ((tmComResDMATermDescrHeader_t *)(buf + idx)); next_offset = idx + (vcoutputtermhdr->len); for (i = 0; i < vcoutputtermhdr->numformats; i++) { t = (tmComResDescrHeader_t *) (buf + next_offset); switch (t->subtype) { case VS_FORMAT_MPEG2TS: tsfmt = (tmComResTSFormatDescrHeader_t *)t; if (currpath == 1) port = &dev->ts1; else port = &dev->ts2; memcpy(&port->hwcfg, vcoutputtermhdr, sizeof(*vcoutputtermhdr)); saa7164_api_configure_port_mpeg2ts(dev, port, tsfmt); break; case VS_FORMAT_MPEG2PS: dprintk(DBGLVL_API, " = VS_FORMAT_MPEG2PS\n"); break; case VS_FORMAT_VBI: dprintk(DBGLVL_API, " = VS_FORMAT_VBI\n"); break; case VS_FORMAT_RDS: dprintk(DBGLVL_API, " = VS_FORMAT_RDS\n"); break; case VS_FORMAT_UNCOMPRESSED: dprintk(DBGLVL_API, " = VS_FORMAT_UNCOMPRESSED\n"); break; case VS_FORMAT_TYPE: dprintk(DBGLVL_API, " = VS_FORMAT_TYPE\n"); break; default: dprintk(DBGLVL_API, " = undefined (0x%x)\n", t->subtype); } next_offset += t->len; } break; case TUNER_UNIT: dprintk(DBGLVL_API, " TUNER_UNIT\n"); tunerunithdr = (tmComResTunerDescrHeader_t *)(buf + idx); dprintk(DBGLVL_API, " unitid = 0x%x\n", tunerunithdr->unitid); dprintk(DBGLVL_API, " sourceid = 0x%x\n", tunerunithdr->sourceid); dprintk(DBGLVL_API, " iunit = 0x%x\n", tunerunithdr->iunit); dprintk(DBGLVL_API, " tuningstandards = 0x%x\n", tunerunithdr->tuningstandards); dprintk(DBGLVL_API, " controlsize = 0x%x\n", tunerunithdr->controlsize); dprintk(DBGLVL_API, " controls = 0x%x\n", tunerunithdr->controls); break; case VC_SELECTOR_UNIT: dprintk(DBGLVL_API, " VC_SELECTOR_UNIT\n"); break; case VC_PROCESSING_UNIT: dprintk(DBGLVL_API, " VC_PROCESSING_UNIT\n"); break; case FEATURE_UNIT: dprintk(DBGLVL_API, " FEATURE_UNIT\n"); break; case ENCODER_UNIT: dprintk(DBGLVL_API, " ENCODER_UNIT\n"); break; case EXTENSION_UNIT: dprintk(DBGLVL_API, " EXTENSION_UNIT\n"); exthdr = (tmComResExtDevDescrHeader_t *)(buf + idx); dprintk(DBGLVL_API, " unitid = 0x%x\n", exthdr->unitid); dprintk(DBGLVL_API, " deviceid = 0x%x\n", exthdr->deviceid); dprintk(DBGLVL_API, " devicetype = 0x%x\n", exthdr->devicetype); if (exthdr->devicetype & 0x1) dprintk(DBGLVL_API, " = Decoder Device\n"); if (exthdr->devicetype & 0x2) dprintk(DBGLVL_API, " = GPIO Source\n"); if (exthdr->devicetype & 0x4) dprintk(DBGLVL_API, " = Video Decoder\n"); if (exthdr->devicetype & 0x8) dprintk(DBGLVL_API, " = Audio Decoder\n"); if (exthdr->devicetype & 0x20) dprintk(DBGLVL_API, " = Crossbar\n"); if (exthdr->devicetype & 0x40) dprintk(DBGLVL_API, " = Tuner\n"); if (exthdr->devicetype & 0x80) dprintk(DBGLVL_API, " = IF PLL\n"); if (exthdr->devicetype & 0x100) dprintk(DBGLVL_API, " = Demodulator\n"); if (exthdr->devicetype & 0x200) dprintk(DBGLVL_API, " = RDS Decoder\n"); if (exthdr->devicetype & 0x400) dprintk(DBGLVL_API, " = Encoder\n"); if (exthdr->devicetype & 0x800) dprintk(DBGLVL_API, " = IR Decoder\n"); if (exthdr->devicetype & 0x1000) dprintk(DBGLVL_API, " = EEPROM\n"); if (exthdr->devicetype & 0x2000) dprintk(DBGLVL_API, " = VBI Decoder\n"); if (exthdr->devicetype & 0x10000) dprintk(DBGLVL_API, " = Streaming Device\n"); if (exthdr->devicetype & 0x20000) dprintk(DBGLVL_API, " = DRM Device\n"); if (exthdr->devicetype & 0x40000000) dprintk(DBGLVL_API, " = Generic Device\n"); if (exthdr->devicetype & 0x80000000) dprintk(DBGLVL_API, " = Config Space Device\n"); dprintk(DBGLVL_API, " numgpiopins = 0x%x\n", exthdr->numgpiopins); dprintk(DBGLVL_API, " numgpiogroups = 0x%x\n", exthdr->numgpiogroups); dprintk(DBGLVL_API, " controlsize = 0x%x\n", exthdr->controlsize); break; case PVC_INFRARED_UNIT: dprintk(DBGLVL_API, " PVC_INFRARED_UNIT\n"); break; case DRM_UNIT: dprintk(DBGLVL_API, " DRM_UNIT\n"); break; default: dprintk(DBGLVL_API, "default %d\n", hdr->subtype); } dprintk(DBGLVL_API, " 1.%x\n", hdr->len); dprintk(DBGLVL_API, " 2.%x\n", hdr->type); dprintk(DBGLVL_API, " 3.%x\n", hdr->subtype); dprintk(DBGLVL_API, " 4.%x\n", hdr->unitid); idx += hdr->len; } return 0; } int saa7164_api_enum_subdevs(struct saa7164_dev *dev) { int ret; u32 buflen = 0; u8 *buf; dprintk(DBGLVL_API, "%s()\n", __func__); /* Get the total descriptor length */ ret = saa7164_cmd_send(dev, 0, GET_LEN, GET_DESCRIPTORS_CONTROL, sizeof(buflen), &buflen); if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret = 0x%x\n", __func__, ret); dprintk(DBGLVL_API, "%s() total descriptor size = %d bytes.\n", __func__, buflen); /* Allocate enough storage for all of the descs */ buf = kzalloc(buflen, GFP_KERNEL); if (buf == NULL) return SAA_ERR_NO_RESOURCES; /* Retrieve them */ ret = saa7164_cmd_send(dev, 0, GET_CUR, GET_DESCRIPTORS_CONTROL, buflen, buf); if (ret != SAA_OK) { printk(KERN_ERR "%s() error, ret = 0x%x\n", __func__, ret); goto out; } if (debug & DBGLVL_API) saa7164_dumphex16(dev, buf, (buflen/16)*16); saa7164_api_dump_subdevs(dev, buf, buflen); out: kfree(buf); return ret; } int saa7164_api_i2c_read(struct saa7164_i2c *bus, u8 addr, u32 reglen, u8 *reg, u32 datalen, u8 *data) { struct saa7164_dev *dev = bus->dev; u16 len = 0; int unitid; u32 regval; u8 buf[256]; int ret; dprintk(DBGLVL_API, "%s()\n", __func__); if (reglen > 4) return -EIO; if (reglen == 1) regval = *(reg); else if (reglen == 2) regval = ((*(reg) << 8) || *(reg+1)); else if (reglen == 3) regval = ((*(reg) << 16) | (*(reg+1) << 8) | *(reg+2)); else if (reglen == 4) regval = ((*(reg) << 24) | (*(reg+1) << 16) | (*(reg+2) << 8) | *(reg+3)); /* Prepare the send buffer */ /* Bytes 00-03 source register length * 04-07 source bytes to read * 08... register address */ memset(buf, 0, sizeof(buf)); memcpy((buf + 2 * sizeof(u32) + 0), reg, reglen); *((u32 *)(buf + 0 * sizeof(u32))) = reglen; *((u32 *)(buf + 1 * sizeof(u32))) = datalen; unitid = saa7164_i2caddr_to_unitid(bus, addr); if (unitid < 0) { printk(KERN_ERR "%s() error, cannot translate regaddr 0x%x to unitid\n", __func__, addr); return -EIO; } ret = saa7164_cmd_send(bus->dev, unitid, GET_LEN, EXU_REGISTER_ACCESS_CONTROL, sizeof(len), &len); if (ret != SAA_OK) { printk(KERN_ERR "%s() error, ret(1) = 0x%x\n", __func__, ret); return -EIO; } dprintk(DBGLVL_API, "%s() len = %d bytes\n", __func__, len); if (debug & DBGLVL_I2C) saa7164_dumphex16(dev, buf, 2 * 16); ret = saa7164_cmd_send(bus->dev, unitid, GET_CUR, EXU_REGISTER_ACCESS_CONTROL, len, &buf); if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret(2) = 0x%x\n", __func__, ret); else { if (debug & DBGLVL_I2C) saa7164_dumphex16(dev, buf, sizeof(buf)); memcpy(data, (buf + 2 * sizeof(u32) + reglen), datalen); } return ret == SAA_OK ? 0 : -EIO; } /* For a given 8 bit i2c address device, write the buffer */ int saa7164_api_i2c_write(struct saa7164_i2c *bus, u8 addr, u32 datalen, u8 *data) { struct saa7164_dev *dev = bus->dev; u16 len = 0; int unitid; int reglen; u8 buf[256]; int ret; dprintk(DBGLVL_API, "%s()\n", __func__); if ((datalen == 0) || (datalen > 232)) return -EIO; memset(buf, 0, sizeof(buf)); unitid = saa7164_i2caddr_to_unitid(bus, addr); if (unitid < 0) { printk(KERN_ERR "%s() error, cannot translate regaddr 0x%x to unitid\n", __func__, addr); return -EIO; } reglen = saa7164_i2caddr_to_reglen(bus, addr); if (unitid < 0) { printk(KERN_ERR "%s() error, cannot translate regaddr to reglen\n", __func__); return -EIO; } ret = saa7164_cmd_send(bus->dev, unitid, GET_LEN, EXU_REGISTER_ACCESS_CONTROL, sizeof(len), &len); if (ret != SAA_OK) { printk(KERN_ERR "%s() error, ret(1) = 0x%x\n", __func__, ret); return -EIO; } dprintk(DBGLVL_API, "%s() len = %d bytes\n", __func__, len); /* Prepare the send buffer */ /* Bytes 00-03 dest register length * 04-07 dest bytes to write * 08... register address */ *((u32 *)(buf + 0 * sizeof(u32))) = reglen; *((u32 *)(buf + 1 * sizeof(u32))) = datalen - reglen; memcpy((buf + 2 * sizeof(u32)), data, datalen); if (debug & DBGLVL_I2C) saa7164_dumphex16(dev, buf, sizeof(buf)); ret = saa7164_cmd_send(bus->dev, unitid, SET_CUR, EXU_REGISTER_ACCESS_CONTROL, len, &buf); if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret(2) = 0x%x\n", __func__, ret); return ret == SAA_OK ? 0 : -EIO; } #if 0 int saa7164_api_dif_write(struct saa7164_i2c *bus, u8 addr, u32 datalen, u8 *data) { struct saa7164_dev *dev = bus->dev; u16 len = 0; int unitid; int reglen; u8 buf[256]; int ret; dprintk(DBGLVL_API, "%s()\n", __func__); if ((datalen == 0) || (datalen > 232)) return -EIO; memset(buf, 0, sizeof(buf)); unitid = saa7164_i2caddr_to_unitid(bus, addr); if (unitid < 0) { printk(KERN_ERR "%s() error, cannot translate regaddr 0x%x to unitid\n", __func__, addr); #if 0 return -EIO; #endif } reglen = saa7164_i2caddr_to_reglen(bus, addr); if (unitid < 0) { printk(KERN_ERR "%s() error, cannot translate regaddr to reglen\n", __func__); #if 0 return -EIO; #endif } #if 0 ret = saa7164_cmd_send(bus->dev, unitid, GET_LEN, EXU_REGISTER_ACCESS_CONTROL, sizeof(len), &len); #else ret = saa7164_cmd_send(bus->dev, 3, GET_LEN, EXU_REGISTER_ACCESS_CONTROL, sizeof(len), &len); #endif if (ret != SAA_OK) { printk(KERN_ERR "%s() error, ret(1) = 0x%x\n", __func__, ret); return -EIO; } dprintk(DBGLVL_API, "%s() len = %d bytes\n", __func__, len); dprintk(32, "%s() len = %d bytes\n", __func__, len); /* Prepare the send buffer */ /* Bytes 00-03 dest register length * 04-07 dest bytes to write * 08... register address */ #if 1 buf[0] = 0x04; buf[1] = 0x00; buf[2] = 0x00; buf[3] = 0x00; buf[4] = 0x04; buf[5] = 0x00; buf[6] = 0x00; buf[7] = 0x00; memcpy((buf + 2 * sizeof(u32)), data, datalen); #else *((u32 *)(buf + 0 * sizeof(u32))) = reglen; *((u32 *)(buf + 1 * sizeof(u32))) = datalen - reglen; memcpy((buf + 2 * sizeof(u32)), data, datalen); #endif if (debug & DBGLVL_I2C) saa7164_dumphex16(dev, buf, sizeof(buf)); #if 0 ret = saa7164_cmd_send(bus->dev, unitid, SET_CUR, EXU_REGISTER_ACCESS_CONTROL, len, &buf); #else ret = saa7164_cmd_send(bus->dev, 3, SET_CUR, EXU_REGISTER_ACCESS_CONTROL, len, &buf); #endif if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret(2) = 0x%x\n", __func__, ret); return ret == SAA_OK ? 0 : -EIO; } #endif int saa7164_api_modify_gpio(struct saa7164_dev *dev, u8 unitid, u8 pin, u8 state) { int ret; tmComResGPIO_t t; dprintk(DBGLVL_API, "%s(0x%x, %d, %d)\n", __func__, unitid, pin, state); if ((pin > 7) || (state > 2)) return SAA_ERR_BAD_PARAMETER; t.pin = pin; t.state = state; ret = saa7164_cmd_send(dev, unitid, SET_CUR, EXU_GPIO_CONTROL, sizeof(t), &t); if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret = 0x%x\n", __func__, ret); return ret; } int saa7164_api_set_gpiobit(struct saa7164_dev *dev, u8 unitid, u8 pin) { return saa7164_api_modify_gpio(dev, unitid, pin, 1); } int saa7164_api_clear_gpiobit(struct saa7164_dev *dev, u8 unitid, u8 pin) { return saa7164_api_modify_gpio(dev, unitid, pin, 0); } #if 0 int saa7164_api_setif(struct saa7164_dev *dev, u8 reg, u8 unitid, u8 val, u8 mas) { u16 len = 0; u8 buf[256]; int ret; dprintk(DBGLVL_API, "%s()\n", __func__); memset(buf, 0, sizeof(buf)); buf[0x00] = 0x04; buf[0x01] = 0x00; buf[0x02] = 0x00; buf[0x03] = 0x00; buf[0x04] = 0x04; buf[0x05] = 0x00; buf[0x06] = 0x00; buf[0x07] = 0x00; buf[0x08] = reg; buf[0x09] = 0x26; buf[0x0a] = mas; buf[0x0b] = 0xb0; buf[0x0c] = val; buf[0x0d] = 0x00; buf[0x0e] = 0x00; buf[0x0f] = 0x00; ret = saa7164_cmd_send(dev, unitid, GET_LEN, EXU_REGISTER_ACCESS_CONTROL, sizeof(len), &len); if (ret != SAA_OK) { printk(KERN_ERR "%s() error, ret(1) = 0x%x\n", __func__, ret); return -EIO; } dprintk(DBGLVL_API, "%s() len = %d bytes\n", __func__, len); ret = saa7164_cmd_send(dev, unitid, SET_CUR, EXU_REGISTER_ACCESS_CONTROL, len, &buf); if (ret != SAA_OK) printk(KERN_ERR "%s() error, ret(2) = 0x%x\n", __func__, ret); saa7164_dumphex16(dev, buf, 16); return ret == SAA_OK ? 0 : -EIO; } #endif #if 0 /* Disable the IF block AGC controls */ int saa7164_api_agc(struct saa7164_dev *dev) { saa7164_api_setif(dev, 0x00, 0x03, 0x02, 0xd0); saa7164_api_setif(dev, 0x48, 0x03, 0xa0, 0xd0); saa7164_api_setif(dev, 0xc0, 0x03, 0x01, 0xd0); saa7164_api_setif(dev, 0x7c, 0x03, 0x04, 0xd0); saa7164_api_setif(dev, 0x04, 0x03, 0x00, 0xd0); return 0; } #endif