}
static int sigma_read_dram(struct dev_context *devc,
- uint16_t startchunk, size_t numchunks, uint8_t *data)
+ size_t startchunk, size_t numchunks, uint8_t *data)
{
uint8_t buf[128], *wrptr, regval;
size_t chunk;
SR_PRIV int sigma_write_trigger_lut(struct dev_context *devc,
struct triggerlut *lut)
{
- int lut_addr;
+ size_t lut_addr;
uint16_t bit;
uint8_t m3d, m2d, m1d, m0d;
- uint8_t buf[6], *wrptr;
+ uint8_t buf[6], *wrptr, v8;
uint16_t selreg;
int ret;
buf, wrptr - buf);
if (ret != SR_OK)
return ret;
- ret = sigma_set_register(devc, WRITE_TRIGGER_SELECT2,
- TRGSEL2_RESET | TRGSEL2_LUT_WRITE |
- (lut_addr & TRGSEL2_LUT_ADDR_MASK));
+ v8 = TRGSEL2_RESET | TRGSEL2_LUT_WRITE |
+ (lut_addr & TRGSEL2_LUT_ADDR_MASK);
+ ret = sigma_set_register(devc, WRITE_TRIGGER_SELECT2, v8);
if (ret != SR_OK)
return ret;
}
BB_PIN_CCLK,
BB_PIN_CCLK,
};
- int retries, ret;
+ size_t retries;
+ int ret;
uint8_t data;
/* Section 2. part 1), do the FPGA suicide. */
* by the caller of this function.
*/
static int sigma_fw_2_bitbang(struct sr_context *ctx, const char *name,
- uint8_t **bb_cmd, gsize *bb_cmd_size)
+ uint8_t **bb_cmd, size_t *bb_cmd_size)
{
uint8_t *firmware;
size_t file_size;
uint64_t worst_cluster_time_ms;
uint64_t count_msecs, acquire_msecs;
- sr_sw_limits_init(&devc->acq_limits);
+ sr_sw_limits_init(&devc->limit.acquire);
/* Get sample count limit, convert to msecs. */
- ret = sr_sw_limits_config_get(&devc->cfg_limits,
+ ret = sr_sw_limits_config_get(&devc->limit.config,
SR_CONF_LIMIT_SAMPLES, &data);
if (ret != SR_OK)
return ret;
g_variant_unref(data);
count_msecs = 0;
if (user_count)
- count_msecs = 1000 * user_count / devc->samplerate + 1;
+ count_msecs = 1000 * user_count / devc->clock.samplerate + 1;
/* Get time limit, which is in msecs. */
- ret = sr_sw_limits_config_get(&devc->cfg_limits,
+ ret = sr_sw_limits_config_get(&devc->limit.config,
SR_CONF_LIMIT_MSEC, &data);
if (ret != SR_OK)
return ret;
return SR_OK;
/* Add some slack, and use that timeout for acquisition. */
- worst_cluster_time_ms = 1000 * 65536 / devc->samplerate;
+ worst_cluster_time_ms = 1000 * 65536 / devc->clock.samplerate;
acquire_msecs += 2 * worst_cluster_time_ms;
data = g_variant_new_uint64(acquire_msecs);
- ret = sr_sw_limits_config_set(&devc->acq_limits,
+ ret = sr_sw_limits_config_set(&devc->limit.acquire,
SR_CONF_LIMIT_MSEC, data);
g_variant_unref(data);
if (ret != SR_OK)
return ret;
- sr_sw_limits_acquisition_start(&devc->acq_limits);
+ sr_sw_limits_acquisition_start(&devc->limit.acquire);
return SR_OK;
}
return SR_ERR_ARG;
}
-SR_PRIV uint64_t sigma_get_samplerate(const struct sr_dev_inst *sdi)
+/* Gets called at probe time. Can seed software settings from hardware state. */
+SR_PRIV int sigma_fetch_hw_config(const struct sr_dev_inst *sdi)
{
- /* TODO Retrieve value from hardware. */
+ struct dev_context *devc;
+ int ret;
+ uint8_t regaddr, regval;
+
+ devc = sdi->priv;
+ if (!devc)
+ return SR_ERR_ARG;
+
+ /* Seed configuration values from defaults. */
+ devc->firmware_idx = SIGMA_FW_NONE;
+ devc->clock.samplerate = samplerates[0];
+
+ /* TODO
+ * Ideally the device driver could retrieve recently stored
+ * details from hardware registers, thus re-use user specified
+ * configuration values across sigrok sessions. Which could
+ * avoid repeated expensive though unnecessary firmware uploads,
+ * improve performance and usability. Unfortunately it appears
+ * that the registers range which is documented as available for
+ * application use keeps providing 0xff data content. At least
+ * with the netlist version which ships with sigrok. The same
+ * was observed with unused registers in the first page.
+ */
+ return SR_ERR_NA;
+
+ /* This is for research, currently does not work yet. */
+ ret = sigma_check_open(sdi);
+ regaddr = 16;
+ regaddr = 14;
+ ret = sigma_set_register(devc, regaddr, 'F');
+ ret = sigma_get_register(devc, regaddr, ®val);
+ sr_warn("%s() reg[%u] val[%u] rc[%d]", __func__, regaddr, regval, ret);
+ ret = sigma_check_close(devc);
+ return ret;
+}
+
+/* Gets called after successful (volatile) hardware configuration. */
+SR_PRIV int sigma_store_hw_config(const struct sr_dev_inst *sdi)
+{
+ /* TODO See above, registers seem to not hold written data. */
(void)sdi;
- return samplerates[0];
+ return SR_ERR_NA;
}
SR_PRIV int sigma_set_samplerate(const struct sr_dev_inst *sdi)
struct drv_context *drvc;
uint64_t samplerate;
int ret;
- int num_channels;
+ size_t num_channels;
devc = sdi->priv;
drvc = sdi->driver->context;
/* Accept any caller specified rate which the hardware supports. */
- ret = sigma_normalize_samplerate(devc->samplerate, &samplerate);
+ ret = sigma_normalize_samplerate(devc->clock.samplerate, &samplerate);
if (ret != SR_OK)
return ret;
devc->samples_per_event = 16 / devc->num_channels;
}
+ /*
+ * Store the firmware type and most recently configured samplerate
+ * in hardware, such that subsequent sessions can start from there.
+ * This is a "best effort" approach. Failure is non-fatal.
+ */
+ if (ret == SR_OK)
+ (void)sigma_store_hw_config(sdi);
+
return ret;
}
if (!buffer->sample_data)
return SR_ERR_MALLOC;
buffer->write_pointer = buffer->sample_data;
- sr_sw_limits_init(&devc->feed_limits);
+ sr_sw_limits_init(&devc->limit.submit);
buffer->sdi = sdi;
memset(&buffer->logic, 0, sizeof(buffer->logic));
GVariant *data;
uint64_t total;
- limits = &devc->feed_limits;
+ limits = &devc->limit.submit;
- ret = sr_sw_limits_config_get(&devc->cfg_limits,
+ ret = sr_sw_limits_config_get(&devc->limit.config,
SR_CONF_LIMIT_SAMPLES, &data);
if (ret != SR_OK)
return ret;
int ret;
buffer = devc->buffer;
- limits = &devc->feed_limits;
+ limits = &devc->limit.submit;
if (sr_sw_limits_check(limits))
count = 0;
struct sr_trigger_stage *stage;
struct sr_trigger_match *match;
const GSList *l, *m;
- int channelbit, trigger_set;
+ uint16_t channelbit;
+ size_t trigger_set;
devc = sdi->priv;
memset(&devc->trigger, 0, sizeof(devc->trigger));
+ devc->use_triggers = FALSE;
trigger = sr_session_trigger_get(sdi->session);
if (!trigger)
return SR_OK;
+ if (!ASIX_SIGMA_WITH_TRIGGER) {
+ sr_warn("Trigger support is not implemented. Ignoring the spec.");
+ return SR_OK;
+ }
+
trigger_set = 0;
for (l = trigger->stages; l; l = l->next) {
stage = l->data;
if (!match->channel->enabled)
continue;
channelbit = 1 << match->channel->index;
- if (devc->samplerate >= SR_MHZ(100)) {
+ if (devc->clock.samplerate >= SR_MHZ(100)) {
/* Fast trigger support. */
if (trigger_set) {
sr_err("100/200MHz modes limited to single trigger pin.");
}
}
+ /* Keep track whether triggers are involved during acquisition. */
+ devc->use_triggers = TRUE;
+
return SR_OK;
}
struct sigma_trigger *t)
{
const uint8_t *rdptr;
- int i;
+ size_t i;
uint16_t sample;
rdptr = samples;
* See the previous get_trigger_offset() implementation. This
* code needs to get re-used here.
*/
- (void)devc;
+ if (!devc->use_triggers)
+ return FALSE;
+
(void)sample;
(void)get_trigger_offset;
{
struct sigma_state *ss;
uint16_t tsdiff, ts, sample, item16;
- unsigned int i;
+ size_t count;
+ size_t evt;
if (!devc->use_triggers || !ASIX_SIGMA_WITH_TRIGGER)
triggered = FALSE;
ts = sigma_dram_cluster_ts(dram_cluster);
tsdiff = ts - ss->lastts;
if (tsdiff > 0) {
- size_t count;
sample = ss->lastsample;
count = tsdiff * devc->samples_per_event;
(void)check_and_submit_sample(devc, sample, count, FALSE);
* buffer depth is neither assumed nor required here.
*/
sample = 0;
- for (i = 0; i < events_in_cluster; i++) {
- item16 = sigma_dram_cluster_data(dram_cluster, i);
- if (devc->samplerate == SR_MHZ(200)) {
+ for (evt = 0; evt < events_in_cluster; evt++) {
+ item16 = sigma_dram_cluster_data(dram_cluster, evt);
+ if (devc->clock.samplerate == SR_MHZ(200)) {
sample = sigma_deinterlace_200mhz_data(item16, 0);
check_and_submit_sample(devc, sample, 1, triggered);
sample = sigma_deinterlace_200mhz_data(item16, 1);
check_and_submit_sample(devc, sample, 1, triggered);
sample = sigma_deinterlace_200mhz_data(item16, 3);
check_and_submit_sample(devc, sample, 1, triggered);
- } else if (devc->samplerate == SR_MHZ(100)) {
+ } else if (devc->clock.samplerate == SR_MHZ(100)) {
sample = sigma_deinterlace_100mhz_data(item16, 0);
check_and_submit_sample(devc, sample, 1, triggered);
sample = sigma_deinterlace_100mhz_data(item16, 1);
size_t events_in_line, size_t trigger_event)
{
struct sigma_dram_cluster *dram_cluster;
- unsigned int clusters_in_line;
- unsigned int events_in_cluster;
- unsigned int i;
- uint32_t trigger_cluster;
+ size_t clusters_in_line;
+ size_t events_in_cluster;
+ size_t cluster;
+ size_t trigger_cluster;
clusters_in_line = events_in_line;
clusters_in_line += EVENTS_PER_CLUSTER - 1;
clusters_in_line /= EVENTS_PER_CLUSTER;
- trigger_cluster = ~0;
/* Check if trigger is in this chunk. */
+ trigger_cluster = ~0UL;
if (trigger_event < EVENTS_PER_ROW) {
- if (devc->samplerate <= SR_MHZ(50)) {
+ if (devc->clock.samplerate <= SR_MHZ(50)) {
trigger_event -= MIN(EVENTS_PER_CLUSTER - 1,
trigger_event);
}
}
/* For each full DRAM cluster. */
- for (i = 0; i < clusters_in_line; i++) {
- dram_cluster = &dram_line->cluster[i];
+ for (cluster = 0; cluster < clusters_in_line; cluster++) {
+ dram_cluster = &dram_line->cluster[cluster];
/* The last cluster might not be full. */
- if ((i == clusters_in_line - 1) &&
+ if ((cluster == clusters_in_line - 1) &&
(events_in_line % EVENTS_PER_CLUSTER)) {
events_in_cluster = events_in_line % EVENTS_PER_CLUSTER;
} else {
}
sigma_decode_dram_cluster(devc, dram_cluster,
- events_in_cluster, i == trigger_cluster);
+ events_in_cluster, cluster == trigger_cluster);
}
return SR_OK;
struct sigma_dram_line *dram_line;
uint32_t stoppos, triggerpos;
uint8_t modestatus;
- uint32_t i;
- uint32_t dl_lines_total, dl_lines_curr, dl_lines_done;
- uint32_t dl_first_line, dl_line;
- uint32_t dl_events_in_line, trigger_event;
- uint32_t trg_line, trg_event;
+ size_t line_idx;
+ size_t dl_lines_total, dl_lines_curr, dl_lines_done;
+ size_t dl_first_line, dl_line;
+ size_t dl_events_in_line, trigger_event;
+ size_t trg_line, trg_event;
int ret;
devc = sdi->priv;
sr_err("Could not query capture positions/state.");
return FALSE;
}
- trg_line = ~0;
- trg_event = ~0;
+ if (!devc->use_triggers)
+ triggerpos = ~0;
+ trg_line = ~0UL;
+ trg_event = ~0UL;
if (modestatus & RMR_TRIGGERED) {
trg_line = triggerpos >> ROW_SHIFT;
trg_event = triggerpos & ROW_MASK;
devc->state.lastsample = 0;
}
- for (i = 0; i < dl_lines_curr; i++) {
+ for (line_idx = 0; line_idx < dl_lines_curr; line_idx++) {
/* The last "DRAM line" need not span its full length. */
dl_events_in_line = EVENTS_PER_ROW;
- if (dl_lines_done + i == dl_lines_total - 1)
+ if (dl_lines_done + line_idx == dl_lines_total - 1)
dl_events_in_line = stoppos & ROW_MASK;
/* Test if the trigger happened on this line. */
- trigger_event = ~0;
- if (dl_lines_done + i == trg_line)
+ trigger_event = ~0UL;
+ if (dl_lines_done + line_idx == trg_line)
trigger_event = trg_event;
- decode_chunk_ts(devc, dram_line + i,
+ decode_chunk_ts(devc, dram_line + line_idx,
dl_events_in_line, trigger_event);
}
struct dev_context *devc;
devc = sdi->priv;
- if (sr_sw_limits_check(&devc->acq_limits))
+ if (sr_sw_limits_check(&devc->limit.acquire))
return download_capture(sdi);
return TRUE;
/* Add a logical function to LUT mask. */
static void add_trigger_function(enum triggerop oper, enum triggerfunc func,
- int index, int neg, uint16_t *mask)
+ size_t index, gboolean neg, uint16_t *mask)
{
- int i, j;
+ size_t i, j;
int x[2][2], tmp, a, b, aset, bset, rset;
memset(x, 0, sizeof(x));
struct triggerlut *lut)
{
uint16_t masks[2];
- int bitidx, condidx;
+ size_t bitidx, condidx;
uint16_t value, mask;
- /* Start assuming simple triggers. */
+ /* Setup something that "won't match" in the absence of a spec. */
memset(lut, 0, sizeof(*lut));
+ if (!devc->use_triggers)
+ return SR_OK;
+
+ /* Start assuming simple triggers. Edges are handled below. */
lut->m4 = 0xa000;
lut->m3q = 0xffff;