* "all remaining columns", only applicable to the last field), a format
* specifying character ('x' hexadecimal, 'o' octal, 'b' binary, 'l'
* single-bit logic), and an optional bit count (translating to: logic
- * channels communicated in that column). This "column_formats" option
- * is most versatile, other forms of specifying the column layout only
- * exist for backwards compatibility.
+ * channels communicated in that column). The 'a' format marks analog
+ * data, an optionally following number is the digits count (resolution).
+ * The 't' format marks timestamp values, which could help in automatic
+ * determination of the input stream's samplerate. This "column_formats"
+ * option is most versatile, other forms of specifying the column layout
+ * only exist for backwards compatibility, and are rather limited. They
+ * exclusively support logic input data in strictly adjacent columns,
+ * with further constraints on column layout for multi-bit data.
*
* single_column: Specifies the column number which contains the logic data
* for single-column mode. All logic data is taken from several bits
* - ... -I csv:start_line=20:header=yes:...
* Skip the first 19 text lines. Use line 20 to derive channel names.
* Data starts at line 21.
+ * - ... -I csv:column_formats=*a6 ...
+ * Each column contains an analog value with six significant digits
+ * after the decimal period.
+ * - ... -I csv:column_formats=t,2a ...
+ * The first column contains timestamps, the next two columns contain
+ * analog values. The capture's samplerate could get determined from
+ * the timestamp values if not provided by the user by means of the
+ * 'samplerate' option. This assumes a mere number in units of seconds,
+ * and equidistant rows, there is no fancy support for textual unit
+ * suffixes nor gaps in the stream of samples nor other non-linearity,
+ * just '-' ignore the column if the format is not supported).
*/
/*
* TODO
*
- * - Add support for analog input data? (optional)
- * - Extend the set of supported column types. Just grab a double
- * value from floating point format input text.
- * - Optionally get precision ('digits') from the column's format spec?
- * From the position which is "bit count" for logic channels?
+ * - Extend support for analog input data.
+ * - Determine why analog samples of 'double' data type get scrambled
+ * in sigrok-cli screen output. Is analog.encoding->unitsize not
+ * handled properly? A sigrok-cli or libsigrok (src/output) issue?
+ * - Reconsider the channel creation after format processing. Current
+ * logic may "bleed" channel names into the analog group when logic
+ * channels' columns follow analog columns (seen with "-,2a,x8").
+ * Trying to sort it out, a naive change used to map logic channels'
+ * data to incorrect bitmap positions. The whole channel numbering
+ * needs reconsideration. Probably it's easiest to first create _all_
+ * logic channels so that they have adjacent numbers starting at 0
+ * (addressing logic bits), then all analog channels (again adjacent)
+ * to simplify the calculation of their index in the sample set as
+ * well as their sdi channel index from the "analog column index".
* - Optionally get sample rate from timestamp column. Just best-effort
* approach, not necessarily reliable. Users can always specify rates.
* - Add a test suite for input modules in general, and CSV in specific?
* samplerates, etc).
*/
+typedef float csv_analog_t; /* 'double' currently is flawed. */
+
/* Single column formats. */
enum single_col_format {
FORMAT_NONE, /* Ignore this column. */
FORMAT_BIN, /* Bin digits for a set of bits (or just one bit). */
FORMAT_HEX, /* Hex digits for a set of bits. */
FORMAT_OCT, /* Oct digits for a set of bits. */
+ FORMAT_ANALOG, /* Floating point number for an analog channel. */
+ FORMAT_TIME, /* Timestamps. */
};
static const char *col_format_text[] = {
[FORMAT_BIN] = "binary",
[FORMAT_HEX] = "hexadecimal",
[FORMAT_OCT] = "octal",
+ [FORMAT_ANALOG] = "analog",
+ [FORMAT_TIME] = "timestamp",
};
static const char col_format_char[] = {
[FORMAT_BIN] = 'b',
[FORMAT_HEX] = 'x',
[FORMAT_OCT] = 'o',
+ [FORMAT_ANALOG] = 'a',
+ [FORMAT_TIME] = 't',
};
+static gboolean format_is_ignore(enum single_col_format fmt)
+{
+ return fmt == FORMAT_NONE;
+}
+
+static gboolean format_is_logic(enum single_col_format fmt)
+{
+ return fmt >= FORMAT_BIN && fmt <= FORMAT_OCT;
+}
+
+static gboolean format_is_analog(enum single_col_format fmt)
+{
+ return fmt == FORMAT_ANALOG;
+}
+
+static gboolean format_is_timestamp(enum single_col_format fmt)
+{
+ return fmt == FORMAT_TIME;
+}
+
struct column_details {
size_t col_nr;
enum single_col_format text_format;
size_t channel_offset;
size_t channel_count;
+ size_t channel_index;
+ int analog_digits;
};
struct context {
gboolean started;
- /* Current selected samplerate. */
+ /* Current samplerate, optionally determined from input data. */
uint64_t samplerate;
+ double prev_timestamp;
gboolean samplerate_sent;
- /* Number of logic channels. */
+ /* Number of channels. */
size_t logic_channels;
+ size_t analog_channels;
/* Column delimiter (actually separator), comment leader, EOL sequence. */
GString *delimiter;
size_t sample_unit_size; /**!< Byte count for a single sample. */
uint8_t *sample_buffer; /**!< Buffer for a single sample. */
+ csv_analog_t *analog_sample_buffer; /**!< Buffer for one set of analog values. */
uint8_t *datafeed_buffer; /**!< Queue for datafeed submission. */
size_t datafeed_buf_size;
size_t datafeed_buf_fill;
+ /* "Striped" layout, M samples for N channels each. */
+ csv_analog_t *analog_datafeed_buffer; /**!< Queue for analog datafeed. */
+ size_t analog_datafeed_buf_size;
+ size_t analog_datafeed_buf_fill;
+ GSList **analog_datafeed_channels;
+ int *analog_datafeed_digits;
/* Current line number. */
size_t line_number;
* (when it is full, or upon EOF).
*/
+static int flush_samplerate(const struct sr_input *in)
+{
+ struct context *inc;
+ struct sr_datafeed_packet packet;
+ struct sr_datafeed_meta meta;
+ struct sr_config *src;
+
+ inc = in->priv;
+ if (inc->samplerate && !inc->samplerate_sent) {
+ packet.type = SR_DF_META;
+ packet.payload = &meta;
+ src = sr_config_new(SR_CONF_SAMPLERATE, g_variant_new_uint64(inc->samplerate));
+ meta.config = g_slist_append(NULL, src);
+ sr_session_send(in->sdi, &packet);
+ g_slist_free(meta.config);
+ sr_config_free(src);
+ inc->samplerate_sent = TRUE;
+ }
+
+ return SR_OK;
+}
+
static void clear_logic_samples(struct context *inc)
{
+ if (!inc->logic_channels)
+ return;
inc->sample_buffer = &inc->datafeed_buffer[inc->datafeed_buf_fill];
memset(inc->sample_buffer, 0, inc->sample_unit_size);
}
{
struct context *inc;
struct sr_datafeed_packet packet;
- struct sr_datafeed_meta meta;
- struct sr_config *src;
struct sr_datafeed_logic logic;
int rc;
if (!inc->datafeed_buf_fill)
return SR_OK;
- if (inc->samplerate && !inc->samplerate_sent) {
- packet.type = SR_DF_META;
- packet.payload = &meta;
- src = sr_config_new(SR_CONF_SAMPLERATE, g_variant_new_uint64(inc->samplerate));
- meta.config = g_slist_append(NULL, src);
- sr_session_send(in->sdi, &packet);
- g_slist_free(meta.config);
- sr_config_free(src);
- inc->samplerate_sent = TRUE;
- }
+ rc = flush_samplerate(in);
+ if (rc != SR_OK)
+ return rc;
memset(&packet, 0, sizeof(packet));
memset(&logic, 0, sizeof(logic));
return SR_OK;
}
+static void set_analog_value(struct context *inc, size_t ch_idx, csv_analog_t value);
+
+static void clear_analog_samples(struct context *inc)
+{
+ size_t idx;
+
+ if (!inc->analog_channels)
+ return;
+ inc->analog_sample_buffer = &inc->analog_datafeed_buffer[inc->analog_datafeed_buf_fill];
+ for (idx = 0; idx < inc->analog_channels; idx++)
+ set_analog_value(inc, idx, 0.0);
+}
+
+static void set_analog_value(struct context *inc, size_t ch_idx, csv_analog_t value)
+{
+ if (ch_idx >= inc->analog_channels)
+ return;
+ if (!value)
+ return;
+ inc->analog_sample_buffer[ch_idx * inc->analog_datafeed_buf_size] = value;
+}
+
+static int flush_analog_samples(const struct sr_input *in)
+{
+ struct context *inc;
+ struct sr_datafeed_packet packet;
+ struct sr_datafeed_analog analog;
+ struct sr_analog_encoding encoding;
+ struct sr_analog_meaning meaning;
+ struct sr_analog_spec spec;
+ csv_analog_t *samples;
+ size_t ch_idx;
+ int digits;
+ int rc;
+
+ inc = in->priv;
+ if (!inc->analog_datafeed_buf_fill)
+ return SR_OK;
+
+ rc = flush_samplerate(in);
+ if (rc != SR_OK)
+ return rc;
+
+ samples = inc->analog_datafeed_buffer;
+ for (ch_idx = 0; ch_idx < inc->analog_channels; ch_idx++) {
+ digits = inc->analog_datafeed_digits[ch_idx];
+ sr_analog_init(&analog, &encoding, &meaning, &spec, digits);
+ memset(&packet, 0, sizeof(packet));
+ packet.type = SR_DF_ANALOG;
+ packet.payload = &analog;
+ analog.num_samples = inc->analog_datafeed_buf_fill;
+ analog.data = samples;
+ analog.meaning->channels = inc->analog_datafeed_channels[ch_idx];
+ analog.meaning->mq = 0;
+ analog.meaning->mqflags = 0;
+ analog.meaning->unit = 0;
+ analog.encoding->unitsize = sizeof(samples[0]);
+ analog.encoding->is_signed = TRUE;
+ analog.encoding->is_float = TRUE;
+#ifdef WORDS_BIGENDIAN
+ analog.encoding->is_bigendian = TRUE;
+#else
+ analog.encoding->is_bigendian = FALSE;
+#endif
+ analog.encoding->digits = spec.spec_digits;
+ rc = sr_session_send(in->sdi, &packet);
+ if (rc != SR_OK)
+ return rc;
+ samples += inc->analog_datafeed_buf_size;
+ }
+
+ inc->analog_datafeed_buf_fill = 0;
+ return SR_OK;
+}
+
+static int queue_analog_samples(const struct sr_input *in)
+{
+ struct context *inc;
+ int rc;
+
+ inc = in->priv;
+ if (!inc->analog_channels)
+ return SR_OK;
+
+ inc->analog_datafeed_buf_fill++;
+ if (inc->analog_datafeed_buf_fill == inc->analog_datafeed_buf_size) {
+ rc = flush_analog_samples(in);
+ if (rc != SR_OK)
+ return rc;
+ }
+ return SR_OK;
+}
+
/* Helpers for "column processing". */
static int split_column_format(const char *spec,
case 'l':
format_code = FORMAT_BIN;
break;
+ case 'a':
+ format_code = FORMAT_ANALOG;
+ break;
+ case 't':
+ format_code = FORMAT_TIME;
+ break;
default: /* includes NUL */
return SR_ERR_ARG;
}
if (!endp)
return SR_ERR_ARG;
if (endp == spec)
- count = 1;
- if (format_char == '-')
+ count = format_is_analog(format_code) ? 3 : 1;
+ if (format_is_ignore(format_code))
count = 0;
if (format_char == 'l')
count = 1;
{
struct context *inc;
char **formats, *format;
- size_t format_count, column_count, bit_count;
+ size_t format_count, column_count, logic_count, analog_count;
size_t auto_column_count;
- size_t format_idx, c, b, column_idx, channel_idx;
+ size_t format_idx, c, b, column_idx, channel_idx, analog_idx;
enum single_col_format f;
struct column_details *detail;
GString *channel_name;
size_t create_idx;
char *column;
const char *caption;
+ int channel_type, channel_sdi_nr;
int ret;
inc = in->priv;
g_strfreev(formats);
return SR_ERR_ARG;
}
- column_count = bit_count = 0;
+ column_count = logic_count = analog_count = 0;
auto_column_count = 0;
for (format_idx = 0; format_idx < format_count; format_idx++) {
format = formats[format_idx];
c = auto_column_count;
}
column_count += c;
- bit_count += c * b;
+ if (format_is_analog(f))
+ analog_count += c;
+ else if (format_is_logic(f))
+ logic_count += c * b;
}
- sr_dbg("Column format %s -> %zu columns, %zu logic channels.",
- column_format, column_count, bit_count);
+ sr_dbg("Column format %s -> %zu columns, %zu logic, %zu analog channels.",
+ column_format, column_count, logic_count, analog_count);
/* Allocate and fill in "column processing" details. Create channels. */
inc->column_want_count = column_count;
return SR_ERR_ARG;
}
inc->column_details = g_malloc0_n(column_count, sizeof(inc->column_details[0]));
- column_idx = channel_idx = 0;
+ column_idx = channel_idx = analog_idx = 0;
channel_name = g_string_sized_new(64);
for (format_idx = 0; format_idx < format_count; format_idx++) {
/* Process a format field, which can span multiple columns. */
detail = &inc->column_details[column_idx++];
detail->col_nr = column_idx;
detail->text_format = f;
- if (detail->text_format) {
+ if (format_is_analog(detail->text_format)) {
+ detail->channel_offset = analog_idx;
+ detail->channel_count = 1;
+ detail->analog_digits = b;
+ analog_idx += detail->channel_count;
+ } else if (format_is_logic(detail->text_format)) {
detail->channel_offset = channel_idx;
detail->channel_count = b;
- channel_idx += b;
- }
- sr_dbg("detail -> col %zu, fmt %s, ch off/cnt %zu/%zu",
- detail->col_nr, col_format_text[detail->text_format],
- detail->channel_offset, detail->channel_count);
- if (!detail->text_format)
+ channel_idx += detail->channel_count;
+ } else if (format_is_ignore(detail->text_format)) {
+ /* EMPTY */
+ continue;
+ } else {
+ /*
+ * Neither logic nor analog data, nor ignore.
+ * Format was noted. No channel creation involved.
+ */
continue;
+ }
/*
- * Create channels with appropriate names. Optionally
+ * Pick most appropriate channel names. Optionally
* use text from a header line (when requested by the
* user). In the absence of header text, channels are
* assigned rather generic names.
caption = NULL;
if (!caption || !*caption)
caption = NULL;
+ /*
+ * TODO Need we first create _all_ logic channels,
+ * before creating analog channels? Just store the
+ * parameters here (index, type, name) and have the
+ * creation sequence done outside of the format
+ * spec parse loop.
+ */
for (create_idx = 0; create_idx < detail->channel_count; create_idx++) {
if (caption && detail->channel_count == 1) {
g_string_assign(channel_name, caption);
g_string_printf(channel_name, "%zu",
detail->channel_offset + create_idx);
}
- sr_channel_new(in->sdi, detail->channel_offset + create_idx,
- SR_CHANNEL_LOGIC, TRUE, channel_name->str);
+ if (format_is_analog(detail->text_format)) {
+ channel_sdi_nr = logic_count + detail->channel_offset + create_idx;
+ channel_type = SR_CHANNEL_ANALOG;
+ detail->channel_index = g_slist_length(in->sdi->channels);
+ } else if (format_is_logic(detail->text_format)) {
+ channel_sdi_nr = detail->channel_offset + create_idx;
+ channel_type = SR_CHANNEL_LOGIC;
+ } else {
+ continue;
+ }
+ sr_channel_new(in->sdi, channel_sdi_nr,
+ channel_type, TRUE, channel_name->str);
}
}
}
inc->logic_channels = channel_idx;
+ inc->analog_channels = analog_idx;
g_string_free(channel_name, TRUE);
g_strfreev(formats);
ch_rem--;
set_logic_level(inc, ch_idx + 0, bits & (1 << 0));
break;
- case FORMAT_NONE:
+ default:
/* ShouldNotHappen(TM), but silences compiler warning. */
return SR_ERR;
}
return SR_OK;
}
+/**
+ * @brief Parse a floating point text into an analog value.
+ *
+ * @param[in] column The input text, a floating point number.
+ * @param[in] inc The input module's context.
+ * @param[in] details The column processing details.
+ *
+ * @retval SR_OK Success.
+ * @retval SR_ERR Invalid input data (empty, or format error).
+ *
+ * This routine modifies the analog values in the current sample set,
+ * based on the text input and a user provided format spec.
+ */
+static int parse_analog(const char *column, struct context *inc,
+ const struct column_details *details)
+{
+ size_t length;
+ double dvalue; float fvalue;
+ csv_analog_t value;
+ int ret;
+
+ if (!format_is_analog(details->text_format))
+ return SR_ERR_BUG;
+
+ length = strlen(column);
+ if (!length) {
+ sr_err("Column %zu in line %zu is empty.", details->col_nr,
+ inc->line_number);
+ return SR_ERR;
+ }
+ if (sizeof(value) == sizeof(double)) {
+ ret = sr_atod_ascii(column, &dvalue);
+ value = dvalue;
+ } else if (sizeof(value) == sizeof(float)) {
+ ret = sr_atof_ascii(column, &fvalue);
+ value = fvalue;
+ } else {
+ ret = SR_ERR_BUG;
+ }
+ if (ret != SR_OK) {
+ sr_err("Cannot parse analog text %s in column %zu in line %zu.",
+ column, details->col_nr, inc->line_number);
+ return SR_ERR_DATA;
+ }
+ set_analog_value(inc, details->channel_offset, value);
+
+ return SR_OK;
+}
+
+/**
+ * @brief Parse a timestamp text, auto-determine samplerate.
+ *
+ * @param[in] column The input text, a floating point number.
+ * @param[in] inc The input module's context.
+ * @param[in] details The column processing details.
+ *
+ * @retval SR_OK Success.
+ * @retval SR_ERR Invalid input data (empty, or format error).
+ *
+ * This routine attempts to automatically determine the input data's
+ * samplerate from text rows' timestamp values. Only simple formats are
+ * supported, user provided values always take precedence.
+ */
+static int parse_timestamp(const char *column, struct context *inc,
+ const struct column_details *details)
+{
+ double ts, rate;
+ int ret;
+
+ if (!format_is_timestamp(details->text_format))
+ return SR_ERR_BUG;
+
+ /*
+ * Implementor's notes on timestamp interpretation. Use a simple
+ * approach for improved maintainability which covers most cases
+ * of input data. There is not much gain in adding complexity,
+ * users can easily provide the rate when auto-detection fails.
+ * - Bail out if samplerate is known already.
+ * - Try to interpret the timestamp (simple float conversion).
+ * If conversion fails then clear all previous knowledge and
+ * bail out (non-fatal, perhaps warn). Silently ignore values
+ * of zero since those could be silent fails -- assume that
+ * genuine data contains at least two adjacent rows with useful
+ * timestamps for the feature to work reliably. Annoying users
+ * with "failed to detect" messages is acceptable here, since
+ * users expecting the feature to work should provide useful
+ * data, and there are easy ways to disable the detection or
+ * ignore the column.
+ * - If there is no previous timestamp, keep the current value
+ * for later reference and bail out.
+ * - If a previous timestamp was seen, determine the difference
+ * between them, and derive the samplerate. Update internal
+ * state (the value automatically gets sent to the datafeed),
+ * and clear previous knowledge. Subsequent calls will ignore
+ * following input data (see above, rate is known).
+ *
+ * TODO Potential future improvements:
+ * - Prefer rationals over floats for improved precision and
+ * reduced rounding errors which result in odd rates.
+ * - Support other formats ("2 ms" or similar)?
+ */
+ if (inc->samplerate)
+ return SR_OK;
+ ret = sr_atod_ascii(column, &ts);
+ if (ret != SR_OK)
+ ts = 0.0;
+ if (!ts) {
+ sr_warn("Cannot convert timestamp text %s in line %zu (or zero value).",
+ column, inc->line_number);
+ inc->prev_timestamp = 0.0;
+ return SR_OK;
+ }
+ if (!inc->prev_timestamp) {
+ sr_dbg("First timestamp value %g in line %zu.",
+ ts, inc->line_number);
+ inc->prev_timestamp = ts;
+ return SR_OK;
+ }
+ sr_dbg("Second timestamp value %g in line %zu.", ts, inc->line_number);
+ ts -= inc->prev_timestamp;
+ sr_dbg("Timestamp difference %g in line %zu.",
+ ts, inc->line_number);
+ if (!ts) {
+ sr_warn("Zero timestamp difference in line %zu.",
+ inc->line_number);
+ inc->prev_timestamp = ts;
+ return SR_OK;
+ }
+ rate = 1.0 / ts;
+ rate += 0.5;
+ rate = (uint64_t)rate;
+ sr_dbg("Rate from timestamp %g in line %zu.", rate, inc->line_number);
+ inc->samplerate = rate;
+ inc->prev_timestamp = 0.0;
+
+ return SR_OK;
+}
+
/**
* @brief Parse routine which ignores the input text.
*
[FORMAT_BIN] = parse_logic,
[FORMAT_OCT] = parse_logic,
[FORMAT_HEX] = parse_logic,
+ [FORMAT_ANALOG] = parse_analog,
+ [FORMAT_TIME] = parse_timestamp,
};
static int init(struct sr_input *in, GHashTable *options)
* for datafeed submission that is a multiple of the unit size.
* Allocate the larger buffer, the "sample buffer" will point
* to a location within that large buffer later.
+ *
+ * TODO Move channel creation here, and just store required
+ * parameters in the format parser above? Could simplify the
+ * arrangement that logic and analog channels get created in
+ * strict sequence in their respective groups.
*/
- inc->sample_unit_size = (inc->logic_channels + 7) / 8;
- inc->datafeed_buf_size = CHUNK_SIZE;
- inc->datafeed_buf_size *= inc->sample_unit_size;
- inc->datafeed_buffer = g_malloc(inc->datafeed_buf_size);
- inc->datafeed_buf_fill = 0;
+ if (inc->logic_channels) {
+ inc->sample_unit_size = (inc->logic_channels + 7) / 8;
+ inc->datafeed_buf_size = CHUNK_SIZE;
+ inc->datafeed_buf_size *= inc->sample_unit_size;
+ inc->datafeed_buffer = g_malloc(inc->datafeed_buf_size);
+ if (!inc->datafeed_buffer) {
+ sr_err("Cannot allocate datafeed send buffer (logic).");
+ ret = SR_ERR_MALLOC;
+ goto out;
+ }
+ inc->datafeed_buf_fill = 0;
+ }
+
+ if (inc->analog_channels) {
+ size_t sample_size, sample_count;
+ size_t detail_idx;
+ struct column_details *detail;
+ int *digits_item;
+ void *channel;
+ sample_size = sizeof(inc->analog_datafeed_buffer[0]);
+ inc->analog_datafeed_buf_size = CHUNK_SIZE;
+ inc->analog_datafeed_buf_size /= sample_size;
+ inc->analog_datafeed_buf_size /= inc->analog_channels;
+ sample_count = inc->analog_channels * inc->analog_datafeed_buf_size;
+ inc->analog_datafeed_buffer = g_malloc0(sample_count * sample_size);
+ if (!inc->analog_datafeed_buffer) {
+ sr_err("Cannot allocate datafeed send buffer (analog).");
+ ret = SR_ERR_MALLOC;
+ goto out;
+ }
+ inc->analog_datafeed_buf_fill = 0;
+ inc->analog_datafeed_channels = g_malloc0(inc->analog_channels * sizeof(inc->analog_datafeed_channels[0]));
+ inc->analog_datafeed_digits = g_malloc0(inc->analog_channels * sizeof(inc->analog_datafeed_digits[0]));
+ digits_item = inc->analog_datafeed_digits;
+ for (detail_idx = 0; detail_idx < inc->column_want_count; detail_idx++) {
+ detail = &inc->column_details[detail_idx];
+ if (!format_is_analog(detail->text_format))
+ continue;
+ channel = g_slist_nth_data(in->sdi->channels, detail->channel_index);
+ inc->analog_datafeed_channels[detail->channel_offset] = g_slist_append(NULL, channel);
+ *digits_item++ = detail->analog_digits;
+ }
+ }
out:
if (columns)
/* Have the columns of the current text line processed. */
clear_logic_samples(inc);
+ clear_analog_samples(inc);
for (col_idx = 0; col_idx < inc->column_want_count; col_idx++) {
column = columns[col_idx];
col_nr = col_idx + 1;
/* Send sample data to the session bus (buffered). */
ret = queue_logic_samples(in);
+ ret += queue_analog_samples(in);
if (ret != SR_OK) {
sr_err("Sending samples failed.");
g_strfreev(columns);
return ret;
ret = flush_logic_samples(in);
+ ret += flush_analog_samples(in);
if (ret != SR_OK)
return ret;
inc->termination = NULL;
g_free(inc->datafeed_buffer);
inc->datafeed_buffer = NULL;
+ g_free(inc->analog_datafeed_buffer);
+ inc->analog_datafeed_buffer = NULL;
}
static int reset(struct sr_input *in)
OPT_SINGLE_COL,
OPT_FIRST_COL,
OPT_NUM_LOGIC,
- OPT_FORMAT,
- OPT_START,
+ OPT_SINGLE_FMT,
+ OPT_START_LINE,
OPT_HEADER,
- OPT_RATE,
- OPT_DELIM,
+ OPT_SAMPLERATE,
+ OPT_COL_SEP,
OPT_COMMENT,
OPT_MAX,
};
static struct sr_option options[] = {
[OPT_COL_FMTS] = {
"column_formats", "Column format specs",
- "Specifies text columns data types: comma separated list of [<cols>]<fmt>[<bits>], with -/x/o/b/l format specifiers.",
+ "Text columns data types. A comma separated list of [<cols>]<fmt>[<bits>] items. * for all remaining columns. - ignores columns, x/o/b/l logic data, a (and digits) analog data, t timestamps.",
NULL, NULL,
},
[OPT_SINGLE_COL] = {
"single_column", "Single column",
- "Enable single-column mode, exclusively use text from the specified column (number starting at 1).",
+ "Simple single-column mode, exclusively use text from the specified column (number starting at 1). Obsoleted by 'column_formats=4-,x16'.",
NULL, NULL,
},
[OPT_FIRST_COL] = {
"first_column", "First column",
- "Number of the first column with logic data in simple multi-column mode (number starting at 1, default 1).",
+ "First column with logic data in simple multi-column mode (number starting at 1, default 1). Obsoleted by 'column_formats=4-,*l'.",
NULL, NULL,
},
[OPT_NUM_LOGIC] = {
"logic_channels", "Number of logic channels",
- "Logic channel count, required in simple single-column mode, defaults to \"all remaining columns\" in simple multi-column mode. Obsoleted by 'column_formats'.",
+ "Logic channel count, required in simple single-column mode, defaults to \"all remaining columns\" in simple multi-column mode. Obsoleted by 'column_formats=8l'.",
NULL, NULL,
},
- [OPT_FORMAT] = {
+ [OPT_SINGLE_FMT] = {
"single_format", "Data format for simple single-column mode.",
- "The number format of single-column mode input data: bin, hex, oct.",
+ "The input text number format of simple single-column mode: bin, hex, oct. Obsoleted by 'column_formats=x8'.",
NULL, NULL,
},
- [OPT_START] = {
+ [OPT_START_LINE] = {
"start_line", "Start line",
"The line number at which to start processing input text (default: 1).",
NULL, NULL,
},
[OPT_HEADER] = {
"header", "Get channel names from first line.",
- "Use the first processed line's column captions (when available) as channel names.",
+ "Use the first processed line's column captions (when available) as channel names. Off by default",
NULL, NULL,
},
- [OPT_RATE] = {
+ [OPT_SAMPLERATE] = {
"samplerate", "Samplerate (Hz)",
- "The input data's sample rate in Hz.",
+ "The input data's sample rate in Hz. No default value.",
NULL, NULL,
},
- [OPT_DELIM] = {
+ [OPT_COL_SEP] = {
"column_separator", "Column separator",
"The sequence which separates text columns. Non-empty text, comma by default.",
NULL, NULL,
},
[OPT_COMMENT] = {
"comment_leader", "Comment leader character",
- "The text which starts comments at the end of text lines.",
+ "The text which starts comments at the end of text lines, semicolon by default.",
NULL, NULL,
},
[OPT_MAX] = ALL_ZERO,
options[OPT_SINGLE_COL].def = g_variant_ref_sink(g_variant_new_uint32(0));
options[OPT_FIRST_COL].def = g_variant_ref_sink(g_variant_new_uint32(1));
options[OPT_NUM_LOGIC].def = g_variant_ref_sink(g_variant_new_uint32(0));
- options[OPT_FORMAT].def = g_variant_ref_sink(g_variant_new_string("bin"));
+ options[OPT_SINGLE_FMT].def = g_variant_ref_sink(g_variant_new_string("bin"));
l = NULL;
l = g_slist_append(l, g_variant_ref_sink(g_variant_new_string("bin")));
l = g_slist_append(l, g_variant_ref_sink(g_variant_new_string("hex")));
l = g_slist_append(l, g_variant_ref_sink(g_variant_new_string("oct")));
- options[OPT_FORMAT].values = l;
- options[OPT_START].def = g_variant_ref_sink(g_variant_new_uint32(1));
+ options[OPT_SINGLE_FMT].values = l;
+ options[OPT_START_LINE].def = g_variant_ref_sink(g_variant_new_uint32(1));
options[OPT_HEADER].def = g_variant_ref_sink(g_variant_new_boolean(FALSE));
- options[OPT_RATE].def = g_variant_ref_sink(g_variant_new_uint64(0));
- options[OPT_DELIM].def = g_variant_ref_sink(g_variant_new_string(","));
+ options[OPT_SAMPLERATE].def = g_variant_ref_sink(g_variant_new_uint64(0));
+ options[OPT_COL_SEP].def = g_variant_ref_sink(g_variant_new_string(","));
options[OPT_COMMENT].def = g_variant_ref_sink(g_variant_new_string(";"));
}