#define LOG_PREFIX "input/csv"
+#define CHUNK_SIZE (4 * 1024 * 1024)
+
/*
* The CSV input module has the following options:
*
* all of robustness and flexibility and correctness.
* - The current implementation splits on "any run of CR and LF". Which
* translates to: Line numbers are wrong in the presence of empty
- * lines in the input stream.
- * - The current implementation insists in the presence of end-of-line
- * markers on _every_ line in the input stream. "Incomplete" text
- * files that are so typical on the Windows platform get rejected as
- * invalid.
+ * lines in the input stream. See below for an (expensive) fix.
* - Dropping support for CR style end-of-line markers could improve
* the situation a lot. Code could search for and split on LF, and
* trim optional trailing CR. This would result in proper support
* input stream is scanned for the first occurance of either of the
* supported termination styles (which is good). For the remaining
* session a consistent encoding of the text lines is assumed (which
- * is acceptable). Potential absence of the terminator for the last
- * line is orthogonal, and can get handled by a "force" flag when
- * the end() routine calls the process_buffer() routine.
+ * is acceptable).
* - When line numbers need to be correct and reliable, _and_ the full
* set of previously supported line termination sequences are required,
* and potentially more are to get added for improved compatibility
/* Format sample data is stored in single column mode. */
int format;
- /* Size of the sample buffer. */
- size_t sample_buffer_size;
+ size_t sample_unit_size; /**!< Byte count for a single sample. */
+ uint8_t *sample_buffer; /**!< Buffer for a single sample. */
- /* Buffer to store sample data. */
- uint8_t *sample_buffer;
+ uint8_t *datafeed_buffer; /**!< Queue for datafeed submission. */
+ size_t datafeed_buf_size;
+ size_t datafeed_buf_fill;
/* Current line number. */
size_t line_number;
}
/* Clear buffer in order to set bits only. */
- memset(inc->sample_buffer, 0, (inc->num_channels + 7) >> 3);
+ memset(inc->sample_buffer, 0, inc->sample_unit_size);
i = inc->first_channel;
}
/* Clear buffer in order to set bits only. */
- memset(inc->sample_buffer, 0, (inc->num_channels + 7) >> 3);
+ memset(inc->sample_buffer, 0, inc->sample_unit_size);
/* Calculate the position of the first hexadecimal digit. */
i = inc->first_channel / 4;
}
/* Clear buffer in order to set bits only. */
- memset(inc->sample_buffer, 0, (inc->num_channels + 7) >> 3);
+ memset(inc->sample_buffer, 0, inc->sample_unit_size);
/* Calculate the position of the first octal digit. */
i = inc->first_channel / 3;
char *column;
/* Clear buffer in order to set bits only. */
- memset(inc->sample_buffer, 0, (inc->num_channels + 7) >> 3);
+ memset(inc->sample_buffer, 0, inc->sample_unit_size);
for (i = 0; i < inc->num_channels; i++) {
column = columns[i];
return res;
}
-static int send_samples(const struct sr_dev_inst *sdi, uint8_t *buffer,
- gsize buffer_size, gsize count)
+static int flush_samples(const struct sr_input *in)
{
+ struct context *inc;
struct sr_datafeed_packet packet;
struct sr_datafeed_logic logic;
- int res;
- gsize i;
+ int rc;
+
+ inc = in->priv;
+ if (!inc->datafeed_buf_fill)
+ return SR_OK;
+ memset(&packet, 0, sizeof(packet));
+ memset(&logic, 0, sizeof(logic));
packet.type = SR_DF_LOGIC;
packet.payload = &logic;
- logic.unitsize = buffer_size;
- logic.length = buffer_size;
- logic.data = buffer;
-
- for (i = 0; i < count; i++) {
- res = sr_session_send(sdi, &packet);
- if (res != SR_OK)
- return res;
- }
+ logic.unitsize = inc->sample_unit_size;
+ logic.length = inc->datafeed_buf_fill;
+ logic.data = inc->datafeed_buffer;
+
+ rc = sr_session_send(in->sdi, &packet);
+ if (rc != SR_OK)
+ return rc;
+ inc->datafeed_buf_fill = 0;
+ return SR_OK;
+}
+
+static int queue_samples(const struct sr_input *in)
+{
+ struct context *inc;
+ int rc;
+
+ inc = in->priv;
+
+ inc->datafeed_buf_fill += inc->sample_unit_size;
+ if (inc->datafeed_buf_fill == inc->datafeed_buf_size) {
+ rc = flush_samples(in);
+ if (rc != SR_OK)
+ return rc;
+ }
+ inc->sample_buffer = &inc->datafeed_buffer[inc->datafeed_buf_fill];
return SR_OK;
}
g_string_free(channel_name, TRUE);
/*
- * Calculate the minimum buffer size to store the sample data of the
- * channels.
+ * Calculate the minimum buffer size to store the set of samples
+ * of all channels (unit size). Determine a larger buffer size
+ * for datafeed submission that is a multiple of the unit size.
+ * Allocate the larger buffer, and have the "sample buffer" point
+ * to a location within that large buffer.
*/
- inc->sample_buffer_size = (inc->num_channels + 7) >> 3;
- inc->sample_buffer = g_malloc(inc->sample_buffer_size);
+ inc->sample_unit_size = (inc->num_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;
+ inc->sample_buffer = &inc->datafeed_buffer[inc->datafeed_buf_fill];
out:
if (columns)
return ret;
}
-static int process_buffer(struct sr_input *in)
+static int process_buffer(struct sr_input *in, gboolean is_eof)
{
struct sr_datafeed_packet packet;
struct sr_datafeed_meta meta;
* maximum amount of accumulated data that consists of full text
* lines, and process what has been received so far, leaving not
* yet complete lines for the next invocation.
+ *
+ * Enforce that all previously buffered data gets processed in
+ * the "EOF" condition. Do not insist in the presence of the
+ * termination sequence for the last line (may often be missing
+ * on Windows). A present termination sequence will just result
+ * in the "execution of an empty line", and does not harm.
*/
if (!in->buf->len)
return SR_OK;
- p = g_strrstr_len(in->buf->str, in->buf->len, inc->termination);
- if (!p)
- return SR_ERR;
- *p = '\0';
- p += strlen(inc->termination);
+ if (is_eof) {
+ p = in->buf->str + in->buf->len;
+ } else {
+ p = g_strrstr_len(in->buf->str, in->buf->len, inc->termination);
+ if (!p)
+ return SR_ERR;
+ *p = '\0';
+ p += strlen(inc->termination);
+ }
g_strstrip(in->buf->str);
ret = SR_OK;
columns = parse_line(line, inc, max_columns);
if (!columns) {
sr_err("Error while parsing line %zu.", inc->line_number);
+ g_strfreev(lines);
return SR_ERR;
}
num_columns = g_strv_length(columns);
sr_err("Column %u in line %zu is out of bounds.",
inc->first_column, inc->line_number);
g_strfreev(columns);
+ g_strfreev(lines);
return SR_ERR;
}
/*
sr_err("Not enough columns for desired number of channels in line %zu.",
inc->line_number);
g_strfreev(columns);
+ g_strfreev(lines);
return SR_ERR;
}
ret = parse_single_column(columns[0], inc);
if (ret != SR_OK) {
g_strfreev(columns);
+ g_strfreev(lines);
return SR_ERR;
}
/* Send sample data to the session bus. */
- ret = send_samples(in->sdi, inc->sample_buffer,
- inc->sample_buffer_size, 1);
+ ret = queue_samples(in);
if (ret != SR_OK) {
sr_err("Sending samples failed.");
+ g_strfreev(columns);
+ g_strfreev(lines);
return SR_ERR;
}
+
g_strfreev(columns);
}
g_strfreev(lines);
return SR_OK;
}
- ret = process_buffer(in);
+ ret = process_buffer(in, FALSE);
return ret;
}
int ret;
if (in->sdi_ready)
- ret = process_buffer(in);
+ ret = process_buffer(in, TRUE);
else
ret = SR_OK;
+ if (ret != SR_OK)
+ return ret;
+
+ ret = flush_samples(in);
+ if (ret != SR_OK)
+ return ret;
inc = in->priv;
if (inc->started)
g_string_free(inc->comment, TRUE);
g_free(inc->termination);
- g_free(inc->sample_buffer);
+ g_free(inc->datafeed_buffer);
}
static int reset(struct sr_input *in)
}
static struct sr_option options[] = {
- { "single-column", "Single column", "Enable/specify single column", NULL, NULL },
- { "numchannels", "Max channels", "Number of channels", NULL, NULL },
- { "delimiter", "Delimiter", "Column delimiter", NULL, NULL },
- { "format", "Format", "Numeric format", NULL, NULL },
- { "comment", "Comment", "Comment prefix character", NULL, NULL },
- { "samplerate", "Samplerate", "Samplerate used during capture", NULL, NULL },
- { "first-channel", "First channel", "Column number of first channel", NULL, NULL },
- { "header", "Header", "Treat first line as header with channel names", NULL, NULL },
- { "startline", "Start line", "Line number at which to start processing samples", NULL, NULL },
+ { "single-column", "Single column", "Enable single-column mode, using the specified column (>= 1); 0: multi-col. mode", NULL, NULL },
+ { "numchannels", "Number of logic channels", "The number of (logic) channels (single-col. mode: number of bits beginning at 'first channel', LSB-first)", NULL, NULL },
+ { "delimiter", "Column delimiter", "The column delimiter (>= 1 characters)", NULL, NULL },
+ { "format", "Data format (single-col. mode)", "The numeric format of the data (single-col. mode): bin, hex, oct", NULL, NULL },
+ { "comment", "Comment character(s)", "The comment prefix character(s)", NULL, NULL },
+ { "samplerate", "Samplerate (Hz)", "The sample rate (used during capture) in Hz", NULL, NULL },
+ { "first-channel", "First channel", "The column number of the first channel (multi-col. mode); bit position for the first channel (single-col. mode)", NULL, NULL },
+ { "header", "Interpret first line as header (multi-col. mode)", "Treat the first line as header with channel names (multi-col. mode)", NULL, NULL },
+ { "startline", "Start line", "The line number at which to start processing samples (>= 1)", NULL, NULL },
ALL_ZERO
};
static const struct sr_option *get_options(void)
{
+ GSList *l;
+
if (!options[0].def) {
options[0].def = g_variant_ref_sink(g_variant_new_int32(0));
options[1].def = g_variant_ref_sink(g_variant_new_int32(0));
options[2].def = g_variant_ref_sink(g_variant_new_string(","));
options[3].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[3].values = l;
options[4].def = g_variant_ref_sink(g_variant_new_string(";"));
options[5].def = g_variant_ref_sink(g_variant_new_uint64(0));
options[6].def = g_variant_ref_sink(g_variant_new_int32(0));