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mirror of https://github.com/DigitalDevices/dddvb.git synced 2023-10-10 13:37:43 +02:00

Merge branch 'internal'

This commit is contained in:
none 2021-04-09 12:54:23 +02:00
commit 23bdd90595
8 changed files with 435 additions and 23 deletions

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@ -1,4 +1,4 @@
all: cit citin flashprog modt ddtest setmod ddflash setmod2 pls setmod3 all: cit citin flashprog modt ddtest setmod ddflash setmod2 pls setmod3 modconfig
cit: cit.c cit: cit.c
$(CC) -o cit cit.c -lpthread $(CC) -o cit cit.c -lpthread
@ -15,6 +15,9 @@ setmod2: setmod2.c
setmod3: setmod3.c setmod3: setmod3.c
$(CC) -o setmod3 setmod3.c -I../include/ $(CC) -o setmod3 setmod3.c -I../include/
modconfig: modconfig.c
$(CC) -o modconfig modconfig.c -I../include/
%.o: %.c %.o: %.c
$(CC) $(CFLAGS) -o $@ $< $(CC) $(CFLAGS) -o $@ $<

286
apps/modconfig.c Normal file
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@ -0,0 +1,286 @@
#include <stdio.h>
#include <stdint.h>
#include <string.h>
#include <stdlib.h>
#include <unistd.h>
#include <sys/ioctl.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <errno.h>
#include <linux/types.h>
#include <getopt.h>
#include <ctype.h>
typedef uint8_t u8;
typedef uint16_t u16;
typedef int16_t s16;
typedef uint32_t u32;
typedef uint64_t u64;
#include "../ddbridge/ddbridge-mci.h"
#include "../ddbridge/ddbridge-ioctl.h"
struct mconf {
int set_output;
int set_channels;
int fd;
struct mci_command channels;
struct mci_command stream;
struct mci_command output;
};
void strim(char *s)
{
int l = strlen(s);
while (l && isspace(s[l-1]))
l--;
s[l] = 0;
}
void parse(char *fname, char *sec, void *priv, void (*cb)(void *, char *, char *))
{
char line[256], csec[80], par[80], val[80], *p;
FILE *f;
if ((f = fopen(fname, "r")) == NULL)
return;
while ((p = fgets(line, sizeof(line), f))) {
if (*p == '\r' || *p == '\n' || *p == '#')
continue;
if (*p == '[') {
if ((p = strtok(line + 1, "]")) == NULL)
continue;
strncpy(csec, p, sizeof(csec));
if (!strcmp(sec, csec) && cb)
cb(priv, NULL, NULL);
continue;
}
if (!(p = strtok(line, "=")))
continue;
while (isspace(*p))
p++;
strncpy(par, p, sizeof(par));
strim(par);
if (!(p = strtok(NULL, "=")))
continue;
while (isspace(*p))
p++;
strncpy (val, p, sizeof(val));
strim(val);
if (!strcmp(sec, csec) && cb)
cb(priv, par, val);
}
if (!strcmp(sec, csec) && cb)
cb(priv, NULL, NULL);
fclose(f);
}
int mci_cmd(int dev, struct mci_command *cmd)
{
int ret;
struct ddb_mci_msg msg;
uint8_t status;
msg.link = 0;
memcpy(&msg.cmd, cmd, sizeof(msg.cmd));
ret = ioctl(dev, IOCTL_DDB_MCI_CMD, &msg);
if (ret < 0) {
dprintf(2, "mci_cmd error %d\n", errno);
return ret;
}
status = msg.res.status;
if (status == MCI_STATUS_OK)
return ret;
if (status == MCI_STATUS_UNSUPPORTED) {
dprintf(2, "Unsupported MCI command\n");
return ret;
}
if (status == MCI_STATUS_INVALID_PARAMETER) {
dprintf(2, "Invalid MCI parameters\n");
return ret;
}
return ret;
}
struct mci_command msg_channels = {
.mod_command = MOD_SETUP_CHANNELS,
.mod_channel = 0,
.mod_stream = 0,
.mod_setup_channels[0] = {
.flags = MOD_SETUP_FLAG_FIRST|MOD_SETUP_FLAG_LAST|MOD_SETUP_FLAG_VALID,
.standard = MOD_STANDARD_DVBT_8,
.num_channels = 25,
.frequency = 474000000,
},
};
struct mci_command msg_stream = {
.mod_command = MOD_SETUP_STREAM,
.mod_channel = 1,
.mod_stream = 0,
.mod_setup_stream = {
.standard = MOD_STANDARD_DVBT_8,
.fft_size = 1,
.guard_interval = 0,
},
};
struct mci_command msg_output = {
.mod_command = MOD_SETUP_OUTPUT,
.mod_channel = 0,
.mod_stream = 0,
.mod_setup_output = {
.connector = MOD_CONNECTOR_F,
.num_channels = 16,
.unit = MOD_UNIT_DBUV,
.channel_power = 5000,
},
};
void output_cb(void *priv, char *par, char *val)
{
struct mconf *mc = (struct mconf *) priv;
if (!par && !val) {
mc->set_output = 1;
return;
}
if (!strcasecmp(par, "connector")) {
if (!strcasecmp(val, "F")) {
mc->output.mod_setup_output.connector = MOD_CONNECTOR_F;
} else if (!strcasecmp(val, "SMA")) {
mc->output.mod_setup_output.connector = MOD_CONNECTOR_SMA;
} else if (!strcasecmp(val, "OFF")) {
mc->output.mod_setup_output.connector = MOD_CONNECTOR_OFF;
} else
printf("invalid connector\n");
} else if (!strcasecmp(par, "power")) {
mc->output.mod_setup_output.channel_power = (uint32_t) (strtod(val, NULL) * 100.0);
} else if (!strcasecmp(par, "channels")) {
mc->output.mod_setup_output.num_channels = strtol(val, NULL, 10);
}else if (!strcasecmp(par, "unit")) {
if (!strcasecmp(val, "DBUV")) {
mc->output.mod_setup_output.unit = MOD_UNIT_DBUV;
} else if (!strcasecmp(val, "DBM")) {
mc->output.mod_setup_output.unit = MOD_UNIT_DBM;
} else
printf("invalid unit\n");
} else
printf("invalid output parameter: %s\n", par);
}
void channels_cb(void *priv, char *par, char *val)
{
struct mconf *mc = (struct mconf *) priv;
if (!par && !val) {
mc->set_channels = 1;
return;
}
if (!strcasecmp(par, "frequency")) {
mc->channels.mod_setup_channels[0].frequency = (uint32_t) (strtod(val, NULL) * 1000000.0);
printf("frequency = %u\n", mc->channels.mod_setup_channels[0].frequency);
} else if (!strcasecmp(par, "channels")) {
mc->channels.mod_setup_channels[0].num_channels = strtol(val, NULL, 10);
} else if (!strcasecmp(par, "standard")) {
mc->channels.mod_setup_channels[0].standard = strtol(val, NULL, 10);
} else if (!strcasecmp(par, "offset")) {
mc->channels.mod_setup_channels[0].offset = (uint32_t) (strtod(val, NULL) * 1000000.0);
} else if (!strcasecmp(par, "bandwidth")) {
mc->channels.mod_setup_channels[0].bandwidth = (uint32_t) (strtod(val, NULL) * 1000000.0);
mc->channels.mod_setup_channels[0].offset =
mc->channels.mod_setup_channels[0].bandwidth / 2;
} else
printf("invalid channels parameter: %s\n", par);
}
void streams_cb(void *priv, char *par, char *val)
{
struct mconf *mc = (struct mconf *) priv;
if (!par && !val) {
return;
}
if (!strcasecmp(par, "fft_size")) {
mc->stream.mod_setup_stream.fft_size = strtol(val, NULL, 10);
} else if (!strcasecmp(par, "guard_interval")) {
mc->stream.mod_setup_stream.guard_interval = strtol(val, NULL, 10);
} else if (!strcasecmp(par, "standard")) {
mc->stream.mod_setup_stream.standard = strtol(val, NULL, 10);
} else if (!strcasecmp(par, "stream_format")) {
mc->stream.mod_setup_stream.stream_format = strtol(val, NULL, 10);
} else if (!strcasecmp(par, "symbol_rate")) {
mc->stream.mod_setup_stream.symbol_rate = (uint32_t) (strtod(val, NULL) * 1000000.0);
} else if (!strcasecmp(par, "stream")) {
mc->stream.mod_stream = strtol(val, NULL, 10);
printf("set stream %u to channel %u\n", mc->stream.mod_stream, mc->stream.mod_channel);
mci_cmd(mc->fd, &mc->stream);
} else if (!strcasecmp(par, "channel")) {
mc->stream.mod_channel = strtol(val, NULL, 10);
} else
printf("invalid streams parameter: %s\n", par);
}
int main(int argc, char*argv[])
{
int fd = -1;
char fn[128];
uint32_t device = 0;
uint32_t frequency = 0;
char *configname = "modulator.conf";
struct mconf mc;
memset(&mc, 0, sizeof(mc));
mc.channels = msg_channels;
mc.stream = msg_stream;
mc.output = msg_output;
while (1) {
int cur_optind = optind ? optind : 1;
int option_index = 0;
int c;
static struct option long_options[] = {
{"device", required_argument, 0, 'd'},
{"config", required_argument, 0, 'c'},
{"help", no_argument, 0, 'h'},
{0, 0, 0, 0}
};
c = getopt_long(argc, argv, "d:c:",
long_options, &option_index);
if (c == -1)
break;
switch (c) {
case 'd':
device = strtoul(optarg, NULL, 0);
break;
case 'c':
configname = optarg;
break;
case 'h':
dprintf(2, "modconfig [-d device_number] [-c config_file]\n");
break;
default:
break;
}
}
if (optind < argc) {
printf("too many arguments\n");
exit(1);
}
snprintf(fn, 127, "/dev/ddbridge/card%u", device);
fd = open(fn, O_RDWR);
if (fd < 0) {
dprintf(2, "Could not open %s\n", fn);
return -1;
}
mc.fd = fd;
parse(configname, "output", (void *) &mc, output_cb);
if (mc.set_output)
mci_cmd(fd, &mc.output);
parse(configname, "channels", (void *) &mc, channels_cb);
if (mc.set_channels)
mci_cmd(fd, &mc.channels);
parse(configname, "streams", (void *) &mc, streams_cb);
}

51
apps/modulator.conf Normal file
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@ -0,0 +1,51 @@
[output]
# connector = OFF, SMA or F
connector = F
# number of total channels to be used at the same time
# use lower number to have fewer channels but stronger signal per channel
channels = 16
# unit of power in DBUV or DBM
unit = DBUV
# power output in units of above unit
power = 50.0
# define channels:
# channels are frequency slots to which a stream (mod0, mod1 ...) can be assigned
[channels]
# standard: 0 = generic, 1 = DVB-T 8MHz, 2 = DVB-T 7 MHz, 3 = DVB-T 6 MHz
standard = 1
# numbers of channels to allocate, starting from frequency below
# this defines 25 channels at 474, 474+8, 474+16, etc. Mhz
channels = 25
# frequency of channel 0, following channels are spaced according to set standard
frequency = 474.0
[streams]
# number of streams depends on the card hardware
# streams correspond to devices mod0, mod1, ...
# channels are defined above in channels section
# 0 = 1/32, 1 = 1/16, 2 = 1/8, 3 = 1/4
guard_interval = 0
# 0 = 2K, 1 = 8K (2K not yet supported)
fft_size = 1
# all following streams will be set according to the last set other parameters
# example:
# this would set mod 1 to 474 MHz and mod0 to 482 MHz (474 + 8 MHz)
# both with guard interval 1/32 and 8K FFT
# and mod2 to 490MHz, guard interval 1/16 and 8K FFT
channel = 1
stream = 0
#
channel = 0
stream = 1
#
guard_interval = 1
channel = 2
stream = 2

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@ -312,6 +312,7 @@ static int __devinit ddb_probe(struct pci_dev *pdev,
dev->link[0].ids.subvendor = id->subvendor; dev->link[0].ids.subvendor = id->subvendor;
dev->link[0].ids.subdevice = pdev->subsystem_device; dev->link[0].ids.subdevice = pdev->subsystem_device;
dev->link[0].ids.devid = (id->device << 16) | id->vendor; dev->link[0].ids.devid = (id->device << 16) | id->vendor;
dev->link[0].ids.revision = pdev->revision;
dev->link[0].dev = dev; dev->link[0].dev = dev;
dev->link[0].info = get_ddb_info(id->vendor, id->device, dev->link[0].info = get_ddb_info(id->vendor, id->device,

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@ -34,10 +34,16 @@ static int mci_reset(struct ddb_link *link)
u32 control; u32 control;
u32 status = 0; u32 status = 0;
u32 timeout = 40; u32 timeout = 40;
union {
u32 u[4];
char s[16];
} version;
u32 vaddr;
if (!regmap || ! regmap->mci) if (!regmap || !regmap->mci)
return -EINVAL; return -EINVAL;
control = regmap->mci->base; control = regmap->mci->base;
vaddr = regmap->mci_buf->base + 0xf0;
if ((link->info->type == DDB_OCTOPUS_MCI) && if ((link->info->type == DDB_OCTOPUS_MCI) &&
(ddblreadl(link, control) & MCI_CONTROL_START_COMMAND)) { (ddblreadl(link, control) & MCI_CONTROL_START_COMMAND)) {
@ -55,11 +61,17 @@ static int mci_reset(struct ddb_link *link)
msleep(50); msleep(50);
} }
dev_info(link->dev->dev, "MCI control port @ %08x\n", control); dev_info(link->dev->dev, "MCI control port @ %08x\n", control);
if ((status & MCI_CONTROL_READY) == 0) { if ((status & MCI_CONTROL_READY) == 0) {
dev_err(link->dev->dev, "MCI init failed!\n"); dev_err(link->dev->dev, "MCI init failed!\n");
return -1; return -1;
} }
version.u[0] = ddblreadl(link, vaddr);
version.u[1] = ddblreadl(link, vaddr + 4);
version.u[2] = ddblreadl(link, vaddr + 8);
version.u[3] = ddblreadl(link, vaddr + 12);
dev_info(link->dev->dev, "MCI port OK, init time %u msecs\n", (40 - timeout) * 50); dev_info(link->dev->dev, "MCI port OK, init time %u msecs\n", (40 - timeout) * 50);
dev_info(link->dev->dev, "MCI firmware version %s.%d\n", version.s, version.s[15]);
return 0; return 0;
} }
@ -108,6 +120,7 @@ static int ddb_mci_cmd_raw_unlocked(struct ddb_link *link,
0xffffff, INTERRUPT_ACK); 0xffffff, INTERRUPT_ACK);
} }
} }
//print_hex_dump(KERN_INFO, "MCI", DUMP_PREFIX_OFFSET, 16, 1, cmd, cmd_len, false);
if (res && res_len) if (res && res_len)
for (i = 0; i < res_len; i++) for (i = 0; i < res_len; i++)
res[i] = ddblreadl(link, result + i * 4); res[i] = ddblreadl(link, result + i * 4);
@ -166,17 +179,10 @@ int mci_init(struct ddb_link *link)
int mci_cmd_val(struct ddb_link *link, uint32_t cmd, uint32_t val) int mci_cmd_val(struct ddb_link *link, uint32_t cmd, uint32_t val)
{ {
struct mci_result result; struct mci_result result;
#if 0
struct mci_command command = {
.command_word = cmd,
.params = { val },
};
#else
struct mci_command command; struct mci_command command;
command.command_word = cmd; command.command_word = cmd;
command.params[0] = val; command.params[0] = val;
#endif
return ddb_mci_cmd_link(link, &command, &result); return ddb_mci_cmd_link(link, &command, &result);
} }

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@ -185,6 +185,60 @@
#define MCI_SUCCESS(status) ((status & MCI_STATUS_UNSUPPORTED) == 0) #define MCI_SUCCESS(status) ((status & MCI_STATUS_UNSUPPORTED) == 0)
/********************************************************/
#define MOD_SETUP_CHANNELS (0x60)
#define MOD_SETUP_OUTPUT (0x61)
#define MOD_SETUP_STREAM (0x62)
#define MOD_SETUP_FLAG_FIRST (0x01)
#define MOD_SETUP_FLAG_LAST (0x02)
#define MOD_SETUP_FLAG_VALID (0x80)
#define MOD_STANDARD_GENERIC (0x00)
#define MOD_STANDARD_DVBT_8 (0x01)
#define MOD_STANDARD_DVBT_7 (0x02)
#define MOD_STANDARD_DVBT_6 (0x03)
#define MOD_CONNECTOR_OFF (0x00)
#define MOD_CONNECTOR_F (0x01)
#define MOD_CONNECTOR_SMA (0x02)
#define MOD_UNIT_DBUV (0x00)
#define MOD_UNIT_DBM (0x01)
#define MOD_FORMAT_DEFAULT (0x00)
#define MOD_FORMAT_IQ16 (0x01)
#define MOD_FORMAT_IQ8 (0x02)
#define MOD_FORMAT_IDX8 (0x03)
#define MOD_FORMAT_TS (0x04)
struct mod_setup_channels {
u8 flags;
u8 standard;
u8 num_channels;
u8 rsvd;
u32 frequency;
u32 offset; /* used only when Standard == 0 */
u32 bandwidth; /* used only when Standard == 0 */
};
struct mod_setup_stream {
u8 standard;
u8 stream_format;
u8 rsvd[2];
u32 symbol_rate; /* only used when Standard doesn't define a fixed symbol rate */
u8 fft_size; /* 0 = 2K, 1 = 8K (2K yet supported) */
u8 guard_interval; /* 0 = 1/32, 1 = 1/16, 2 = 1/8, 3 = 1/4 (DVB-T Encoding) */
};
struct mod_setup_output {
u8 connector; /* 0 = OFF, 1 = F, 2 = SMA */
u8 num_channels; /* max active channels, determines max power for each channel. */
u8 unit; /* 0 = dBµV, 1 = dBm, */
u8 rsvd;
s16 channel_power;
};
/********************************************************/ /********************************************************/
@ -197,6 +251,12 @@ struct mci_command {
u8 demod; u8 demod;
u8 output; u8 output;
}; };
struct {
u8 mod_command;
u8 mod_channel;
u8 mod_stream;
u8 mod_rsvd1;
};
}; };
union { union {
u32 params[31]; u32 params[31];
@ -307,27 +367,27 @@ struct mci_command {
} get_iq_symbol; } get_iq_symbol;
struct { struct {
uint8_t flags; /* Bit 0 : 0 = VTM/SDR, 1 = SCAN, u8 flags; /* Bit 0 : 0 = VTM/SDR, 1 = SCAN,
Bit 1: 1 = Disable AGC, Bit 1: 1 = Disable AGC,
Bit 2: 1 = Set Gain. */ Bit 2: 1 = Set Gain. */
uint8_t roll_off; u8 roll_off;
uint8_t rsvd1; u8 rsvd1;
uint8_t rsvd2; u8 rsvd2;
uint32_t frequency; u32 frequency;
uint32_t symbol_rate; /* Only in VTM/SDR mode, SCAN Mode uses exactly 1550/24 MSymbols/s.*/ u32 symbol_rate; /* Only in VTM/SDR mode, SCAN Mode uses exactly 1550/24 MSymbols/s.*/
uint8_t gain; /* Gain in 0.25 dB Steps */ u8 gain; /* Gain in 0.25 dB Steps */
/* Frequency, symbolrate and gain can be schanged while running */ /* Frequency, symbolrate and gain can be schanged while running */
} sx8_start_iq; } sx8_start_iq;
struct { struct {
uint8_t flags; u8 flags;
/* Bit 0:1 Preamp Mode; 0 = Preamp AGC, 1 == Minimum (~ -17dB) , /* Bit 0:1 Preamp Mode; 0 = Preamp AGC, 1 == Minimum (~ -17dB) ,
2 = Medium, 3 = Maximum gain {~ 15dB} 2 = Medium, 3 = Maximum gain {~ 15dB}
Bit 2: Bypass Input LNA (6 dB less gain) (Note this is after Preamp) Bit 2: Bypass Input LNA (6 dB less gain) (Note this is after Preamp)
Bit 4: Set RF Gain Bit 4: Set RF Gain
Bit 5: Freeze RF Gain (Turn AGC off at current gain, only when already enabled) Bit 5: Freeze RF Gain (Turn AGC off at current gain, only when already enabled)
Bit 7: Optimize RF Gain and freeze for FFT */ Bit 7: Optimize RF Gain and freeze for FFT */
uint8_t rf_gain; /* 0 .. 50 dB */ u8 rf_gain; /* 0 .. 50 dB */
} sx8_input_enable; } sx8_input_enable;
struct { struct {
@ -344,6 +404,10 @@ struct mci_command {
struct { struct {
u8 select; // 0 = Data PLP, 1 = Common PLP, only DVB-T2 and DVB-C2 u8 select; // 0 = Data PLP, 1 = Common PLP, only DVB-T2 and DVB-C2
} get_bb_header; } get_bb_header;
struct mod_setup_channels mod_setup_channels[4];
struct mod_setup_stream mod_setup_stream;
struct mod_setup_output mod_setup_output;
}; };
}; };
@ -800,7 +864,7 @@ int ddb_mci_get_info(struct mci *mci);
int ddb_mci_get_strength(struct dvb_frontend *fe); int ddb_mci_get_strength(struct dvb_frontend *fe);
void ddb_mci_proc_info(struct mci *mci, struct dtv_frontend_properties *p); void ddb_mci_proc_info(struct mci *mci, struct dtv_frontend_properties *p);
int mci_init(struct ddb_link *link); int mci_init(struct ddb_link *link);
int mci_cmd_val(struct ddb_link *link, uint32_t cmd, uint32_t val); int mci_cmd_val(struct ddb_link *link, u32 cmd, u32 val);
extern struct mci_cfg ddb_max_sx8_cfg; extern struct mci_cfg ddb_max_sx8_cfg;
extern struct mci_cfg ddb_max_m4_cfg; extern struct mci_cfg ddb_max_m4_cfg;

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@ -644,7 +644,6 @@ static int mod_set_sdr_attenuator(struct ddb *dev, u32 value)
static int mod_set_sdr_gain(struct ddb *dev, u32 gain) static int mod_set_sdr_gain(struct ddb *dev, u32 gain)
{ {
u32 control = ddbreadl(dev, SDR_CONTROL); u32 control = ddbreadl(dev, SDR_CONTROL);
struct ddb_link *link = &dev->link[0];
if (control & 0x01000000) { if (control & 0x01000000) {
if (gain > 511) if (gain > 511)
@ -659,8 +658,6 @@ static int mod_set_sdr_gain(struct ddb *dev, u32 gain)
return -EINVAL; return -EINVAL;
ddbwritel(dev, gain, SDR_GAIN_F); ddbwritel(dev, gain, SDR_GAIN_F);
} }
if (link->mci_ok)
mci_cmd_val(link, 0xc0, gain);
return 0; return 0;
} }
@ -2032,6 +2029,9 @@ static int mod_init_sdr_iq(struct ddb *dev)
ddbwritel(dev, 0x01, 0x240); ddbwritel(dev, 0x01, 0x240);
if (dev->link[0].ids.revision == 1)
return 0;
//mod3_set_base_frequency(dev, 602000000); //mod3_set_base_frequency(dev, 602000000);
dev->mod_base.frequency = 570000000; dev->mod_base.frequency = 570000000;
for (i = 0; i < streams; i++) { for (i = 0; i < streams; i++) {

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@ -143,6 +143,7 @@ struct ddb_ids {
u32 regmapid; u32 regmapid;
u32 devid; u32 devid;
u32 mac; u32 mac;
u8 revision;
}; };
struct ddb_info { struct ddb_info {