#include "scpi.h"
#include "protocol.h"
+SR_PRIV void hmo_queue_logic_data(struct dev_context *devc,
+ size_t group, GByteArray *pod_data);
+SR_PRIV void hmo_send_logic_packet(struct sr_dev_inst *sdi,
+ struct dev_context *devc);
+SR_PRIV void hmo_cleanup_logic_data(struct dev_context *devc);
+
static const char *hameg_scpi_dialect[] = {
[SCPI_CMD_GET_DIG_DATA] = ":FORM UINT,8;:POD%d:DATA?",
[SCPI_CMD_GET_TIMEBASE] = ":TIM:SCAL?",
[SCPI_CMD_GET_PROBE_UNIT] = ":PROB%d:SET:ATT:UNIT?",
};
-static const uint32_t hmo_devopts[] = {
+static const uint32_t devopts[] = {
SR_CONF_OSCILLOSCOPE,
SR_CONF_LIMIT_FRAMES | SR_CONF_GET | SR_CONF_SET,
- SR_CONF_TRIGGER_SOURCE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
+ SR_CONF_SAMPLERATE | SR_CONF_GET,
SR_CONF_TIMEBASE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
SR_CONF_NUM_HDIV | SR_CONF_GET,
- SR_CONF_TRIGGER_SLOPE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
SR_CONF_HORIZ_TRIGGERPOS | SR_CONF_GET | SR_CONF_SET,
- SR_CONF_SAMPLERATE | SR_CONF_GET,
+ SR_CONF_TRIGGER_SOURCE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
+ SR_CONF_TRIGGER_SLOPE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
};
-static const uint32_t hmo_analog_devopts[] = {
+static const uint32_t devopts_cg_analog[] = {
SR_CONF_NUM_VDIV | SR_CONF_GET,
- SR_CONF_COUPLING | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
SR_CONF_VDIV | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
+ SR_CONF_COUPLING | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
};
-static const char *hmo_coupling_options[] = {
+static const char *coupling_options[] = {
"AC", // AC with 50 Ohm termination (152x, 202x, 30xx, 1202)
"ACL", // AC with 1 MOhm termination
"DC", // DC with 50 Ohm termination
"DCL", // DC with 1 MOhm termination
"GND",
- NULL,
};
static const char *scope_trigger_slopes[] = {
"POS",
"NEG",
"EITH",
- NULL,
};
-static const char *hmo_compact2_trigger_sources[] = {
- "CH1",
- "CH2",
- "LINE",
- "EXT",
- "PATT",
- "BUS1",
- "BUS2",
- "D0",
- "D1",
- "D2",
- "D3",
- "D4",
- "D5",
- "D6",
- "D7",
- NULL,
+static const char *compact2_trigger_sources[] = {
+ "CH1", "CH2",
+ "LINE", "EXT", "PATT", "BUS1", "BUS2",
+ "D0", "D1", "D2", "D3", "D4", "D5", "D6", "D7",
};
-static const char *hmo_compact4_trigger_sources[] = {
- "CH1",
- "CH2",
- "CH3",
- "CH4",
- "LINE",
- "EXT",
- "PATT",
- "BUS1",
- "BUS2",
- "D0",
- "D1",
- "D2",
- "D3",
- "D4",
- "D5",
- "D6",
- "D7",
- NULL,
+static const char *compact4_trigger_sources[] = {
+ "CH1", "CH2", "CH3", "CH4",
+ "LINE", "EXT", "PATT", "BUS1", "BUS2",
+ "D0", "D1", "D2", "D3", "D4", "D5", "D6", "D7",
};
-static const char *hmo_compact4_dig16_trigger_sources[] = {
- "CH1",
- "CH2",
- "CH3",
- "CH4",
- "LINE",
- "EXT",
- "PATT",
- "BUS1",
- "BUS2",
- "D0",
- "D1",
- "D2",
- "D3",
- "D4",
- "D5",
- "D6",
- "D7",
- "D8",
- "D9",
- "D10",
- "D11",
- "D12",
- "D13",
- "D14",
- "D15",
- NULL,
+static const char *compact4_dig16_trigger_sources[] = {
+ "CH1", "CH2", "CH3", "CH4",
+ "LINE", "EXT", "PATT", "BUS1", "BUS2",
+ "D0", "D1", "D2", "D3", "D4", "D5", "D6", "D7",
+ "D8", "D9", "D10", "D11", "D12", "D13", "D14", "D15",
};
-static const uint64_t hmo_timebases[][2] = {
+static const uint64_t timebases[][2] = {
/* nanoseconds */
{ 2, 1000000000 },
{ 5, 1000000000 },
{ 50, 1 },
};
-static const uint64_t hmo_vdivs[][2] = {
+static const uint64_t vdivs[][2] = {
/* millivolts */
{ 1, 1000 },
{ 2, 1000 },
};
static const char *scope_analog_channel_names[] = {
- "CH1",
- "CH2",
- "CH3",
- "CH4",
+ "CH1", "CH2", "CH3", "CH4",
};
static const char *scope_digital_channel_names[] = {
- "D0",
- "D1",
- "D2",
- "D3",
- "D4",
- "D5",
- "D6",
- "D7",
- "D8",
- "D9",
- "D10",
- "D11",
- "D12",
- "D13",
- "D14",
- "D15",
+ "D0", "D1", "D2", "D3", "D4", "D5", "D6", "D7",
+ "D8", "D9", "D10", "D11", "D12", "D13", "D14", "D15",
};
static const struct scope_config scope_models[] = {
.analog_names = &scope_analog_channel_names,
.digital_names = &scope_digital_channel_names,
- .devopts = &hmo_devopts,
- .num_devopts = ARRAY_SIZE(hmo_devopts),
+ .devopts = &devopts,
+ .num_devopts = ARRAY_SIZE(devopts),
+
+ .devopts_cg_analog = &devopts_cg_analog,
+ .num_devopts_cg_analog = ARRAY_SIZE(devopts_cg_analog),
- .analog_devopts = &hmo_analog_devopts,
- .num_analog_devopts = ARRAY_SIZE(hmo_analog_devopts),
+ .coupling_options = &coupling_options,
+ .num_coupling_options = ARRAY_SIZE(coupling_options),
+
+ .trigger_sources = &compact2_trigger_sources,
+ .num_trigger_sources = ARRAY_SIZE(compact2_trigger_sources),
- .coupling_options = &hmo_coupling_options,
- .trigger_sources = &hmo_compact2_trigger_sources,
.trigger_slopes = &scope_trigger_slopes,
+ .num_trigger_slopes = ARRAY_SIZE(scope_trigger_slopes),
- .timebases = &hmo_timebases,
- .num_timebases = ARRAY_SIZE(hmo_timebases),
+ .timebases = &timebases,
+ .num_timebases = ARRAY_SIZE(timebases),
- .vdivs = &hmo_vdivs,
- .num_vdivs = ARRAY_SIZE(hmo_vdivs),
+ .vdivs = &vdivs,
+ .num_vdivs = ARRAY_SIZE(vdivs),
.num_xdivs = 12,
.num_ydivs = 8,
.analog_names = &scope_analog_channel_names,
.digital_names = &scope_digital_channel_names,
- .devopts = &hmo_devopts,
- .num_devopts = ARRAY_SIZE(hmo_devopts),
+ .devopts = &devopts,
+ .num_devopts = ARRAY_SIZE(devopts),
+
+ .devopts_cg_analog = &devopts_cg_analog,
+ .num_devopts_cg_analog = ARRAY_SIZE(devopts_cg_analog),
+
+ .coupling_options = &coupling_options,
+ .num_coupling_options = ARRAY_SIZE(coupling_options),
- .analog_devopts = &hmo_analog_devopts,
- .num_analog_devopts = ARRAY_SIZE(hmo_analog_devopts),
+ .trigger_sources = &compact4_trigger_sources,
+ .num_trigger_sources = ARRAY_SIZE(compact4_trigger_sources),
- .coupling_options = &hmo_coupling_options,
- .trigger_sources = &hmo_compact4_trigger_sources,
.trigger_slopes = &scope_trigger_slopes,
+ .num_trigger_slopes = ARRAY_SIZE(scope_trigger_slopes),
- .timebases = &hmo_timebases,
- .num_timebases = ARRAY_SIZE(hmo_timebases),
+ .timebases = &timebases,
+ .num_timebases = ARRAY_SIZE(timebases),
- .vdivs = &hmo_vdivs,
- .num_vdivs = ARRAY_SIZE(hmo_vdivs),
+ .vdivs = &vdivs,
+ .num_vdivs = ARRAY_SIZE(vdivs),
.num_xdivs = 12,
.num_ydivs = 8,
.scpi_dialect = &hameg_scpi_dialect,
},
{
- .name = {"HMO2524", "HMO3034", "HMO3044", "HMO3054", NULL},
+ .name = {"HMO2524", "HMO3034", "HMO3044", "HMO3054", "HMO3524", NULL},
.analog_channels = 4,
.digital_channels = 16,
.digital_pods = 2,
.analog_names = &scope_analog_channel_names,
.digital_names = &scope_digital_channel_names,
- .devopts = &hmo_devopts,
- .num_devopts = ARRAY_SIZE(hmo_devopts),
+ .devopts = &devopts,
+ .num_devopts = ARRAY_SIZE(devopts),
- .analog_devopts = &hmo_analog_devopts,
- .num_analog_devopts = ARRAY_SIZE(hmo_analog_devopts),
+ .devopts_cg_analog = &devopts_cg_analog,
+ .num_devopts_cg_analog = ARRAY_SIZE(devopts_cg_analog),
+
+ .coupling_options = &coupling_options,
+ .num_coupling_options = ARRAY_SIZE(coupling_options),
+
+ .trigger_sources = &compact4_dig16_trigger_sources,
+ .num_trigger_sources = ARRAY_SIZE(compact4_dig16_trigger_sources),
- .coupling_options = &hmo_coupling_options,
- .trigger_sources = &hmo_compact4_dig16_trigger_sources,
.trigger_slopes = &scope_trigger_slopes,
+ .num_trigger_slopes = ARRAY_SIZE(scope_trigger_slopes),
- .timebases = &hmo_timebases,
- .num_timebases = ARRAY_SIZE(hmo_timebases),
+ .timebases = &timebases,
+ .num_timebases = ARRAY_SIZE(timebases),
- .vdivs = &hmo_vdivs,
- .num_vdivs = ARRAY_SIZE(hmo_vdivs),
+ .vdivs = &vdivs,
+ .num_vdivs = ARRAY_SIZE(vdivs),
.num_xdivs = 12,
.num_ydivs = 8,
state->digital_pods[i] ? "On" : "Off");
}
- tmp = sr_period_string((*config->timebases)[state->timebase][0] *
+ tmp = sr_period_string((*config->timebases)[state->timebase][0],
(*config->timebases)[state->timebase][1]);
sr_info("Current timebase: %s", tmp);
g_free(tmp);
}
static int scope_state_get_array_option(struct sr_scpi_dev_inst *scpi,
- const char *command, const char *(*array)[], int *result)
+ const char *command, const char *(*array)[], unsigned int n, int *result)
{
char *tmp;
- unsigned int i;
+ int idx;
if (sr_scpi_get_string(scpi, command, &tmp) != SR_OK) {
g_free(tmp);
return SR_ERR;
}
- for (i = 0; (*array)[i]; i++) {
- if (!g_strcmp0(tmp, (*array)[i])) {
- *result = i;
- g_free(tmp);
- tmp = NULL;
- break;
- }
- }
-
- if (tmp) {
+ if ((idx = std_str_idx_s(tmp, *array, n)) < 0) {
g_free(tmp);
- return SR_ERR;
+ return SR_ERR_ARG;
}
+ *result = idx;
+
+ g_free(tmp);
+
return SR_OK;
}
return SR_ERR;
}
-static int analog_channel_state_get(struct sr_scpi_dev_inst *scpi,
+static struct sr_channel *get_channel_by_index_and_type(GSList *channel_lhead,
+ int index, int type)
+{
+ while (channel_lhead) {
+ struct sr_channel *ch = channel_lhead->data;
+ if (ch->index == index && ch->type == type)
+ return ch;
+
+ channel_lhead = channel_lhead->next;
+ }
+
+ return 0;
+}
+
+static int analog_channel_state_get(struct sr_dev_inst *sdi,
const struct scope_config *config,
struct scope_state *state)
{
unsigned int i, j;
char command[MAX_COMMAND_SIZE];
char *tmp_str;
+ struct sr_channel *ch;
+ struct sr_scpi_dev_inst *scpi = sdi->conn;
for (i = 0; i < config->analog_channels; i++) {
g_snprintf(command, sizeof(command),
&state->analog_channels[i].state) != SR_OK)
return SR_ERR;
+ ch = get_channel_by_index_and_type(sdi->channels, i, SR_CHANNEL_ANALOG);
+ if (ch)
+ ch->enabled = state->analog_channels[i].state;
+
g_snprintf(command, sizeof(command),
(*config->scpi_dialect)[SCPI_CMD_GET_VERTICAL_DIV],
i + 1);
if (sr_scpi_get_string(scpi, command, &tmp_str) != SR_OK)
return SR_ERR;
- if (array_float_get(tmp_str, hmo_vdivs, ARRAY_SIZE(hmo_vdivs),
- &j) != SR_OK) {
+ if (array_float_get(tmp_str, ARRAY_AND_SIZE(vdivs), &j) != SR_OK) {
g_free(tmp_str);
sr_err("Could not determine array index for vertical div scale.");
return SR_ERR;
i + 1);
if (scope_state_get_array_option(scpi, command, config->coupling_options,
+ config->num_coupling_options,
&state->analog_channels[i].coupling) != SR_OK)
return SR_ERR;
return SR_OK;
}
-static int digital_channel_state_get(struct sr_scpi_dev_inst *scpi,
+static int digital_channel_state_get(struct sr_dev_inst *sdi,
const struct scope_config *config,
struct scope_state *state)
{
unsigned int i;
char command[MAX_COMMAND_SIZE];
+ struct sr_channel *ch;
+ struct sr_scpi_dev_inst *scpi = sdi->conn;
for (i = 0; i < config->digital_channels; i++) {
g_snprintf(command, sizeof(command),
if (sr_scpi_get_bool(scpi, command,
&state->digital_channels[i]) != SR_OK)
return SR_ERR;
+
+ ch = get_channel_by_index_and_type(sdi->channels, i, SR_CHANNEL_LOGIC);
+ if (ch)
+ ch->enabled = state->digital_channels[i];
}
for (i = 0; i < config->digital_pods; i++) {
struct dev_context *devc;
struct scope_state *state;
const struct scope_config *config;
-
int tmp;
unsigned int i;
float tmp_float;
channel_found = FALSE;
for (i = 0; i < config->analog_channels; i++) {
- if (state->analog_channels[i].state) {
- g_snprintf(chan_name, sizeof(chan_name), "CHAN%d", i + 1);
+ if (!state->analog_channels[i].state)
+ continue;
+ g_snprintf(chan_name, sizeof(chan_name), "CHAN%d", i + 1);
+ g_snprintf(tmp_str, sizeof(tmp_str),
+ (*config->scpi_dialect)[SCPI_CMD_GET_SAMPLE_RATE_LIVE],
+ chan_name);
+ channel_found = TRUE;
+ break;
+ }
+
+ if (!channel_found) {
+ for (i = 0; i < config->digital_pods; i++) {
+ if (!state->digital_pods[i])
+ continue;
+ g_snprintf(chan_name, sizeof(chan_name), "POD%d", i);
g_snprintf(tmp_str, sizeof(tmp_str),
(*config->scpi_dialect)[SCPI_CMD_GET_SAMPLE_RATE_LIVE],
chan_name);
}
}
- if (!channel_found) {
- for (i = 0; i < config->digital_pods; i++) {
- if (state->digital_pods[i]) {
- g_snprintf(chan_name, sizeof(chan_name), "POD%d", i);
- g_snprintf(tmp_str, sizeof(tmp_str),
- (*config->scpi_dialect)[SCPI_CMD_GET_SAMPLE_RATE_LIVE],
- chan_name);
- channel_found = TRUE;
- break;
- }
- }
- }
-
/* No channel is active, ask the instrument for the sample rate
* in single shot mode */
if (!channel_found) {
sr_info("Fetching scope state");
- if (analog_channel_state_get(sdi->conn, config, state) != SR_OK)
+ if (analog_channel_state_get(sdi, config, state) != SR_OK)
return SR_ERR;
- if (digital_channel_state_get(sdi->conn, config, state) != SR_OK)
+ if (digital_channel_state_get(sdi, config, state) != SR_OK)
return SR_ERR;
if (sr_scpi_get_float(sdi->conn,
&tmp_str) != SR_OK)
return SR_ERR;
- if (array_float_get(tmp_str, hmo_timebases, ARRAY_SIZE(hmo_timebases),
- &i) != SR_OK) {
+ if (array_float_get(tmp_str, ARRAY_AND_SIZE(timebases), &i) != SR_OK) {
g_free(tmp_str);
sr_err("Could not determine array index for time base.");
return SR_ERR;
if (scope_state_get_array_option(sdi->conn,
(*config->scpi_dialect)[SCPI_CMD_GET_TRIGGER_SOURCE],
- config->trigger_sources, &state->trigger_source) != SR_OK)
+ config->trigger_sources, config->num_trigger_sources,
+ &state->trigger_source) != SR_OK)
return SR_ERR;
if (scope_state_get_array_option(sdi->conn,
- (*config->scpi_dialect)[SCPI_CMD_GET_TRIGGER_SLOPE],
- config->trigger_slopes, &state->trigger_slope) != SR_OK)
+ (*config->scpi_dialect)[SCPI_CMD_GET_TRIGGER_SLOPE],
+ config->trigger_slopes, config->num_trigger_slopes,
+ &state->trigger_slope) != SR_OK)
return SR_ERR;
if (hmo_update_sample_rate(sdi) != SR_OK)
SR_PRIV int hmo_init_device(struct sr_dev_inst *sdi)
{
- char tmp[25];
int model_index;
unsigned int i, j, group;
struct sr_channel *ch;
struct dev_context *devc;
+ int ret;
devc = sdi->priv;
model_index = -1;
devc->analog_groups = g_malloc0(sizeof(struct sr_channel_group*) *
scope_models[model_index].analog_channels);
-
devc->digital_groups = g_malloc0(sizeof(struct sr_channel_group*) *
scope_models[model_index].digital_pods);
+ if (!devc->analog_groups || !devc->digital_groups) {
+ g_free(devc->analog_groups);
+ g_free(devc->digital_groups);
+ return SR_ERR_MALLOC;
+ }
/* Add analog channels. */
for (i = 0; i < scope_models[model_index].analog_channels; i++) {
}
/* Add digital channel groups. */
+ ret = SR_OK;
for (i = 0; i < scope_models[model_index].digital_pods; i++) {
- g_snprintf(tmp, 25, "POD%d", i);
-
devc->digital_groups[i] = g_malloc0(sizeof(struct sr_channel_group));
-
- devc->digital_groups[i]->name = g_strdup(tmp);
+ if (!devc->digital_groups[i]) {
+ ret = SR_ERR_MALLOC;
+ break;
+ }
+ devc->digital_groups[i]->name = g_strdup_printf("POD%d", i);
sdi->channel_groups = g_slist_append(sdi->channel_groups,
devc->digital_groups[i]);
}
+ if (ret != SR_OK)
+ return ret;
/* Add digital channels. */
for (i = 0; i < scope_models[model_index].digital_channels; i++) {
return SR_OK;
}
+/* Queue data of one channel group, for later submission. */
+SR_PRIV void hmo_queue_logic_data(struct dev_context *devc,
+ size_t group, GByteArray *pod_data)
+{
+ size_t size;
+ GByteArray *store;
+ uint8_t *logic_data;
+ size_t idx, logic_step;
+
+ /*
+ * Upon first invocation, allocate the array which can hold the
+ * combined logic data for all channels. Assume that each channel
+ * will yield an identical number of samples per receive call.
+ *
+ * As a poor man's safety measure: (Silently) skip processing
+ * for unexpected sample counts, and ignore samples for
+ * unexpected channel groups. Don't bother with complicated
+ * resize logic, considering that many models only support one
+ * pod, and the most capable supported models have two pods of
+ * identical size. We haven't yet seen any "odd" configuration.
+ */
+ if (!devc->logic_data) {
+ size = pod_data->len * devc->pod_count;
+ store = g_byte_array_sized_new(size);
+ memset(store->data, 0, size);
+ store = g_byte_array_set_size(store, size);
+ devc->logic_data = store;
+ } else {
+ store = devc->logic_data;
+ size = store->len / devc->pod_count;
+ if (size != pod_data->len)
+ return;
+ if (group >= devc->pod_count)
+ return;
+ }
+
+ /*
+ * Fold the data of the most recently received channel group into
+ * the storage, where data resides for all channels combined.
+ */
+ logic_data = store->data;
+ logic_data += group;
+ logic_step = devc->pod_count;
+ for (idx = 0; idx < pod_data->len; idx++) {
+ *logic_data = pod_data->data[idx];
+ logic_data += logic_step;
+ }
+}
+
+/* Submit data for all channels, after the individual groups got collected. */
+SR_PRIV void hmo_send_logic_packet(struct sr_dev_inst *sdi,
+ struct dev_context *devc)
+{
+ struct sr_datafeed_packet packet;
+ struct sr_datafeed_logic logic;
+
+ if (!devc->logic_data)
+ return;
+
+ logic.data = devc->logic_data->data;
+ logic.length = devc->logic_data->len;
+ logic.unitsize = devc->pod_count;
+
+ packet.type = SR_DF_LOGIC;
+ packet.payload = &logic;
+
+ sr_session_send(sdi, &packet);
+}
+
+/* Undo previous resource allocation. */
+SR_PRIV void hmo_cleanup_logic_data(struct dev_context *devc)
+{
+
+ if (devc->logic_data) {
+ g_byte_array_free(devc->logic_data, TRUE);
+ devc->logic_data = NULL;
+ }
+ /*
+ * Keep 'pod_count'! It's required when more frames will be
+ * received, and does not harm when kept after acquisition.
+ */
+}
+
SR_PRIV int hmo_receive_data(int fd, int revents, void *cb_data)
{
struct sr_channel *ch;
struct sr_analog_meaning meaning;
struct sr_analog_spec spec;
struct sr_datafeed_logic logic;
+ size_t group;
(void)fd;
(void)revents;
ch = devc->current_channel->data;
state = devc->model_state;
+ /*
+ * Send "frame begin" packet upon reception of data for the
+ * first enabled channel.
+ */
+ if (devc->current_channel == devc->enabled_channels) {
+ packet.type = SR_DF_FRAME_BEGIN;
+ sr_session_send(sdi, &packet);
+ }
+
+ /*
+ * Pass on the received data of the channel(s).
+ */
switch (ch->type) {
case SR_CHANNEL_ANALOG:
if (sr_scpi_get_block(sdi->conn, NULL, &data) != SR_OK) {
return TRUE;
}
- packet.type = SR_DF_FRAME_BEGIN;
- sr_session_send(sdi, &packet);
-
packet.type = SR_DF_ANALOG;
analog.data = data->data;
return TRUE;
}
- packet.type = SR_DF_FRAME_BEGIN;
- sr_session_send(sdi, &packet);
+ /*
+ * If only data from the first pod is involved in the
+ * acquisition, then the raw input bytes can get passed
+ * forward for performance reasons. When the second pod
+ * is involved (either alone, or in combination with the
+ * first pod), then the received bytes need to be put
+ * into memory in such a layout that all channel groups
+ * get combined, and a unitsize larger than a single byte
+ * applies. The "queue" logic transparently copes with
+ * any such configuration. This works around the lack
+ * of support for "meaning" to logic data, which is used
+ * above for analog data.
+ */
+ if (devc->pod_count == 1) {
+ packet.type = SR_DF_LOGIC;
+ logic.data = data->data;
+ logic.length = data->len;
+ logic.unitsize = 1;
+ packet.payload = &logic;
+ sr_session_send(sdi, &packet);
+ } else {
+ group = ch->index / 8;
+ hmo_queue_logic_data(devc, group, data);
+ }
- logic.length = data->len;
- logic.unitsize = 1;
- logic.data = data->data;
- packet.type = SR_DF_LOGIC;
- packet.payload = &logic;
- sr_session_send(sdi, &packet);
g_byte_array_free(data, TRUE);
data = NULL;
break;
break;
}
- packet.type = SR_DF_FRAME_END;
- sr_session_send(sdi, &packet);
-
+ /*
+ * Advance to the next enabled channel. When data for all enabled
+ * channels was received, then flush potentially queued logic data,
+ * and send the "frame end" packet.
+ */
if (devc->current_channel->next) {
devc->current_channel = devc->current_channel->next;
hmo_request_data(sdi);
- } else if (++devc->num_frames == devc->frame_limit) {
- sdi->driver->dev_acquisition_stop(sdi);
+ return TRUE;
+ }
+ hmo_send_logic_packet(sdi, devc);
+
+ /*
+ * Release the logic data storage after each frame. This copes
+ * with sample counts that differ in length per frame. -- Is
+ * this a real constraint when acquiring multiple frames with
+ * identical device settings?
+ */
+ hmo_cleanup_logic_data(devc);
+
+ packet.type = SR_DF_FRAME_END;
+ sr_session_send(sdi, &packet);
+
+ /*
+ * End of frame was reached. Stop acquisition after the specified
+ * number of frames, or continue reception by starting over at
+ * the first enabled channel.
+ */
+ if (++devc->num_frames == devc->frame_limit) {
+ sr_dev_acquisition_stop(sdi);
+ hmo_cleanup_logic_data(devc);
} else {
devc->current_channel = devc->enabled_channels;
hmo_request_data(sdi);