* This file is part of the libsigrok project.
*
* Copyright (C) 2015 Hannu Vuolasaho <vuokkosetae@gmail.com>
- * Copyright (C) 2018 Frank Stettner <frank-stettner@gmx.net>
+ * Copyright (C) 2018-2019 Frank Stettner <frank-stettner@gmx.net>
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
#include <config.h>
#include "protocol.h"
-#define REQ_TIMEOUT_MS 500
#define DEVICE_PROCESSING_TIME_MS 80
SR_PRIV int korad_kaxxxxp_send_cmd(struct sr_serial_dev_inst *serial,
return ret;
}
+/**
+ * Read a variable length non-terminated string (caller specified maximum size).
+ *
+ * @param[in] serial The serial port to read from.
+ * @param[in] count The maximum amount of data to read.
+ * @param[out] buf The buffer to read data into. Must be larger than @a count.
+ *
+ * @return The amount of received data, or negative in case of error.
+ * See @ref SR_ERR and other error codes.
+ *
+ * @internal
+ *
+ * The protocol has no concept of request/response termination. The only
+ * terminating conditions are either the caller's expected maxmimum byte
+ * count, or a period of time without receive data. It's essential to
+ * accept a longer initial period of time before the first receive data
+ * is seen. The supported devices can be very slow to respond.
+ *
+ * The protocol is text based. That's why the 'count' parameter specifies
+ * the expected number of text characters, and does not include the NUL
+ * termination which is not part of the wire protocol but gets added by
+ * the receive routine. The caller provided buffer is expected to have
+ * enough space for the text data and the NUL termination.
+ *
+ * Implementation detail: It's assumed that once receive data was seen,
+ * remaining response data will follow at wire speed. No further delays
+ * are expected beyond bitrate expectations. All normal commands in the
+ * acquisition phase are of fixed length which is known to the caller.
+ * Identification during device scan needs to deal with variable length
+ * data. Quick termination after reception is important there, as is the
+ * larger initial timeout period before receive data is seen.
+ */
SR_PRIV int korad_kaxxxxp_read_chars(struct sr_serial_dev_inst *serial,
- int count, char *buf)
+ size_t count, char *buf)
{
- int ret, received, turns;
+ int timeout_first, timeout_later, timeout;
+ size_t retries_first, retries_later, retries;
+ size_t received;
+ int ret;
+ /* Clear the buffer early, to simplify the receive code path. */
+ memset(buf, 0, count + 1);
+
+ /*
+ * This calculation is aiming for backwards compatibility with
+ * an earlier implementation. An initial timeout is used which
+ * depends on the expected response byte count, and a maximum
+ * iteration count is used for read attempts.
+ *
+ * TODO Consider an absolute initial timeout instead, to reduce
+ * accumulated rounding errors for serial timeout results. The
+ * iteration with a short period is still required for variable
+ * length responses, because otherwise the serial communication
+ * layer would spend the total amount of time waiting for the
+ * remaining bytes, while the device probe code path by design
+ * passes a larger acceptable count than the typical and legal
+ * response would occupy.
+ *
+ * After initial receive data was seen, a shorter timeout is
+ * used which corresponds to a few bytes at wire speed. Idle
+ * periods without receive data longer than this threshold are
+ * taken as the end of the response. This is not compatible to
+ * the previous implementation, but was found to work as well.
+ * And severely reduces the time spent scanning for devices.
+ */
+ timeout_first = serial_timeout(serial, count);
+ retries_first = 100;
+ timeout_later = serial_timeout(serial, 3);
+ retries_later = 1;
+
+ sr_spew("want %zu bytes, timeout/retry: init %d/%zu, later %d/%zu.",
+ count, timeout_first, retries_first,
+ timeout_later, retries_later);
+
+ /*
+ * Run a sequence of read attempts. Try with the larger timeout
+ * and a high retry count until the first receive data became
+ * available. Then continue with a short timeout and small retry
+ * count.
+ *
+ * Failed read is fatal, immediately terminates the read sequence.
+ * A timeout in the initial phase just keeps repeating. A timeout
+ * after receive data was seen regularly terminates the sequence.
+ * Successful reads of non-empty responses keep extending the
+ * read sequence until no more receive data is available.
+ */
received = 0;
- turns = 0;
-
- do {
- if ((ret = serial_read_blocking(serial, buf + received,
- count - received,
- serial_timeout(serial, count))) < 0) {
- sr_err("Error %d reading %d bytes from device.",
+ timeout = timeout_first;
+ retries = retries_first;
+ while (received < count && retries--) {
+ ret = serial_read_blocking(serial,
+ &buf[received], count - received, timeout);
+ if (ret < 0) {
+ sr_err("Error %d reading %zu bytes from device.",
ret, count);
return ret;
}
+ if (ret == 0 && !received)
+ continue;
+ if (ret == 0 && received) {
+ sr_spew("receive timed out, want %zu, received %zu.",
+ count, received);
+ break;
+ }
received += ret;
- turns++;
- } while ((received < count) && (turns < 100));
-
- buf[count] = 0;
-
- sr_spew("Received: '%s'.", buf);
+ timeout = timeout_later;
+ retries = retries_later;
+ }
+ /* TODO Escape non-printables? Seen those with status queries. */
+ sr_dbg("got %zu bytes, received: '%s'.", received, buf);
- return ret;
+ return received;
}
static void give_device_time_to_process(struct dev_context *devc)
SR_PRIV int korad_kaxxxxp_set_value(struct sr_serial_dev_inst *serial,
int target, struct dev_context *devc)
{
- char *msg;
- const char *cmd;
- float value;
+ char msg[20];
int ret;
g_mutex_lock(&devc->rw_mutex);
give_device_time_to_process(devc);
+ msg[0] = '\0';
+ ret = SR_OK;
switch (target) {
case KAXXXXP_CURRENT:
case KAXXXXP_VOLTAGE:
case KAXXXXP_STATUS:
- sr_err("Can't set measurable parameter %d.", target);
- g_mutex_unlock(&devc->rw_mutex);
- return SR_ERR;
- case KAXXXXP_CURRENT_MAX:
- cmd = "ISET1:%05.3f";
- value = devc->current_max;
+ sr_err("Can't set measured value %d.", target);
+ ret = SR_ERR;
break;
- case KAXXXXP_VOLTAGE_MAX:
- cmd = "VSET1:%05.2f";
- value = devc->voltage_max;
+ case KAXXXXP_CURRENT_LIMIT:
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "ISET1:%05.3f", devc->set_current_limit);
+ break;
+ case KAXXXXP_VOLTAGE_TARGET:
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "VSET1:%05.2f", devc->set_voltage_target);
break;
case KAXXXXP_OUTPUT:
- cmd = "OUT%01.0f";
- value = (devc->output_enabled) ? 1 : 0;
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "OUT%1d", (devc->set_output_enabled) ? 1 : 0);
+ /* Set value back to recognize changes */
+ devc->output_enabled = devc->set_output_enabled;
break;
case KAXXXXP_BEEP:
- cmd = "BEEP%01.0f";
- value = (devc->beep_enabled) ? 1 : 0;
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "BEEP%1d", (devc->set_beep_enabled) ? 1 : 0);
break;
case KAXXXXP_OCP:
- cmd = "OCP%01.0f";
- value = (devc->ocp_enabled) ? 1 : 0;
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "OCP%1d", (devc->set_ocp_enabled) ? 1 : 0);
+ /* Set value back to recognize changes */
+ devc->ocp_enabled = devc->set_ocp_enabled;
break;
case KAXXXXP_OVP:
- cmd = "OVP%01.0f";
- value = (devc->ovp_enabled) ? 1 : 0;
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "OVP%1d", (devc->set_ovp_enabled) ? 1 : 0);
+ /* Set value back to recognize changes */
+ devc->ovp_enabled = devc->set_ovp_enabled;
break;
case KAXXXXP_SAVE:
- cmd = "SAV%01.0f";
if (devc->program < 1 || devc->program > 5) {
- sr_err("Only programs 1-5 supported and %d isn't "
- "between them.", devc->program);
- g_mutex_unlock(&devc->rw_mutex);
- return SR_ERR;
+ sr_err("Program %d is not in the supported 1-5 range.",
+ devc->program);
+ ret = SR_ERR;
+ break;
}
- value = devc->program;
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "SAV%1d", devc->program);
break;
case KAXXXXP_RECALL:
- cmd = "RCL%01.0f";
if (devc->program < 1 || devc->program > 5) {
- sr_err("Only programs 1-5 supported and %d isn't "
- "between them.", devc->program);
- g_mutex_unlock(&devc->rw_mutex);
- return SR_ERR;
+ sr_err("Program %d is not in the supported 1-5 range.",
+ devc->program);
+ ret = SR_ERR;
+ break;
}
- value = devc->program;
+ sr_snprintf_ascii(msg, sizeof(msg),
+ "RCL%1d", devc->program);
break;
default:
- sr_err("Don't know how to set %d.", target);
- g_mutex_unlock(&devc->rw_mutex);
- return SR_ERR;
+ sr_err("Don't know how to set target %d.", target);
+ ret = SR_ERR;
+ break;
}
- msg = g_malloc0(20 + 1);
- if (cmd)
- sr_snprintf_ascii(msg, 20, cmd, value);
-
- ret = korad_kaxxxxp_send_cmd(serial, msg);
- devc->req_sent_at = g_get_monotonic_time();
- g_free(msg);
+ if (ret == SR_OK && msg[0]) {
+ ret = korad_kaxxxxp_send_cmd(serial, msg);
+ devc->req_sent_at = g_get_monotonic_time();
+ }
g_mutex_unlock(&devc->rw_mutex);
char reply[6];
float *value;
char status_byte;
+ gboolean needs_ovp_quirk;
+ gboolean prev_status;
g_mutex_lock(&devc->rw_mutex);
give_device_time_to_process(devc);
ret = korad_kaxxxxp_send_cmd(serial, "IOUT1?");
value = &(devc->current);
break;
- case KAXXXXP_CURRENT_MAX:
+ case KAXXXXP_CURRENT_LIMIT:
/* Read set current from device. */
ret = korad_kaxxxxp_send_cmd(serial, "ISET1?");
- value = &(devc->current_max);
+ value = &(devc->current_limit);
break;
case KAXXXXP_VOLTAGE:
/* Read voltage from device. */
ret = korad_kaxxxxp_send_cmd(serial, "VOUT1?");
value = &(devc->voltage);
break;
- case KAXXXXP_VOLTAGE_MAX:
+ case KAXXXXP_VOLTAGE_TARGET:
/* Read set voltage from device. */
ret = korad_kaxxxxp_send_cmd(serial, "VSET1?");
- value = &(devc->voltage_max);
+ value = &(devc->voltage_target);
break;
case KAXXXXP_STATUS:
case KAXXXXP_OUTPUT:
break;
default:
sr_err("Don't know how to query %d.", target);
+ ret = SR_ERR;
+ }
+ if (ret < 0) {
g_mutex_unlock(&devc->rw_mutex);
- return SR_ERR;
+ return ret;
}
devc->req_sent_at = g_get_monotonic_time();
return ret;
}
- reply[count] = 0;
-
if (value) {
sr_atof_ascii((const char *)&reply, value);
sr_dbg("value: %f", *value);
} else {
/* We have status reply. */
status_byte = reply[0];
- /* Constant current */
- devc->cc_mode[0] = !(status_byte & (1 << 0)); /* Channel one */
- devc->cc_mode[1] = !(status_byte & (1 << 1)); /* Channel two */
+
+ /* Constant current channel one. */
+ prev_status = devc->cc_mode[0];
+ devc->cc_mode[0] = !(status_byte & (1 << 0));
+ devc->cc_mode_1_changed = devc->cc_mode[0] != prev_status;
+ /* Constant current channel two. */
+ prev_status = devc->cc_mode[1];
+ devc->cc_mode[1] = !(status_byte & (1 << 1));
+ devc->cc_mode_2_changed = devc->cc_mode[1] != prev_status;
+
/*
- * Tracking
+ * Tracking:
* status_byte & ((1 << 2) | (1 << 3))
* 00 independent 01 series 11 parallel
*/
- devc->beep_enabled = (1 << 4);
- devc->ocp_enabled = (status_byte & (1 << 5));
- devc->output_enabled = (status_byte & (1 << 6));
- /* Velleman LABPS3005 quirk */
- if (devc->output_enabled)
- devc->ovp_enabled = (status_byte & (1 << 7));
+ devc->beep_enabled = status_byte & (1 << 4);
+
+ /* OCP enabled. */
+ prev_status = devc->ocp_enabled;
+ devc->ocp_enabled = status_byte & (1 << 5);
+ devc->ocp_enabled_changed = devc->ocp_enabled != prev_status;
+
+ /* Output status. */
+ prev_status = devc->output_enabled;
+ devc->output_enabled = status_byte & (1 << 6);
+ devc->output_enabled_changed = devc->output_enabled != prev_status;
+
+ /* OVP enabled, special handling for Velleman LABPS3005 quirk. */
+ needs_ovp_quirk = devc->model->quirks & KORAD_QUIRK_LABPS_OVP_EN;
+ if (!needs_ovp_quirk || devc->output_enabled) {
+ prev_status = devc->ovp_enabled;
+ devc->ovp_enabled = status_byte & (1 << 7);
+ devc->ovp_enabled_changed = devc->ovp_enabled != prev_status;
+ }
+
sr_dbg("Status: 0x%02x", status_byte);
sr_spew("Status: CH1: constant %s CH2: constant %s. "
- "Tracking would be %s. Device is "
- "%s and %s. Buttons are %s. Output is %s "
- "and extra byte is %s.",
+ "Tracking would be %s and %s. Output is %s. "
+ "OCP is %s, OVP is %s. Device is %s.",
(status_byte & (1 << 0)) ? "voltage" : "current",
(status_byte & (1 << 1)) ? "voltage" : "current",
(status_byte & (1 << 2)) ? "parallel" : "series",
(status_byte & (1 << 3)) ? "tracking" : "independent",
- (status_byte & (1 << 4)) ? "beeping" : "silent",
- (status_byte & (1 << 5)) ? "locked" : "unlocked",
(status_byte & (1 << 6)) ? "enabled" : "disabled",
- (status_byte & (1 << 7)) ? "true" : "false");
+ (status_byte & (1 << 5)) ? "enabled" : "disabled",
+ (status_byte & (1 << 7)) ? "enabled" : "disabled",
+ (status_byte & (1 << 4)) ? "beeping" : "silent");
}
/* Read the sixth byte from ISET? BUG workaround. */
- if (target == KAXXXXP_CURRENT_MAX)
+ if (target == KAXXXXP_CURRENT_LIMIT)
serial_read_blocking(serial, &status_byte, 1, 10);
g_mutex_unlock(&devc->rw_mutex);
analog.data = &devc->voltage;
sr_session_send(sdi, &packet);
sr_sw_limits_update_samples_read(&devc->limits, 1);
+ } else if (devc->acquisition_target == KAXXXXP_STATUS) {
+ if (devc->cc_mode_1_changed) {
+ sr_session_send_meta(sdi, SR_CONF_REGULATION,
+ g_variant_new_string((devc->cc_mode[0]) ? "CC" : "CV"));
+ devc->cc_mode_1_changed = FALSE;
+ }
+ if (devc->cc_mode_2_changed) {
+ sr_session_send_meta(sdi, SR_CONF_REGULATION,
+ g_variant_new_string((devc->cc_mode[1]) ? "CC" : "CV"));
+ devc->cc_mode_2_changed = FALSE;
+ }
+ if (devc->output_enabled_changed) {
+ sr_session_send_meta(sdi, SR_CONF_ENABLED,
+ g_variant_new_boolean(devc->output_enabled));
+ devc->output_enabled_changed = FALSE;
+ }
+ if (devc->ocp_enabled_changed) {
+ sr_session_send_meta(sdi, SR_CONF_OVER_CURRENT_PROTECTION_ENABLED,
+ g_variant_new_boolean(devc->ocp_enabled));
+ devc->ocp_enabled_changed = FALSE;
+ }
+ if (devc->ovp_enabled_changed) {
+ sr_session_send_meta(sdi, SR_CONF_OVER_VOLTAGE_PROTECTION_ENABLED,
+ g_variant_new_boolean(devc->ovp_enabled));
+ devc->ovp_enabled_changed = FALSE;
+ }
}
next_measurement(devc);