#include <config.h>
+#include <math.h>
#include <string.h>
#include "protocol.h"
+/* These are the Modbus RTU registers for the family of rdtech-dps devices. */
enum rdtech_dps_register {
- REG_USET = 0x00, /* Mirror of 0x50 */
- REG_ISET = 0x01, /* Mirror of 0x51 */
- REG_UOUT = 0x02,
- REG_IOUT = 0x03,
- REG_POWER = 0x04,
- REG_UIN = 0x05,
- REG_LOCK = 0x06,
- REG_PROTECT = 0x07,
- REG_CV_CC = 0x08,
- REG_ENABLE = 0x09,
- REG_BACKLIGHT = 0x0A, /* Mirror of 0x55 */
- REG_MODEL = 0x0B,
- REG_VERSION = 0x0C,
-
- REG_PRESET = 0x23, /* Loads a preset into preset 0. */
+ REG_DPS_USET = 0x00, /* Mirror of 0x50 */
+ REG_DPS_ISET = 0x01, /* Mirror of 0x51 */
+ REG_DPS_UOUT = 0x02,
+ REG_DPS_IOUT = 0x03,
+ REG_DPS_POWER = 0x04,
+ REG_DPS_UIN = 0x05,
+ REG_DPS_LOCK = 0x06,
+ REG_DPS_PROTECT = 0x07,
+ REG_DPS_CV_CC = 0x08,
+ REG_DPS_ENABLE = 0x09,
+ REG_DPS_BACKLIGHT = 0x0A, /* Mirror of 0x55 */
+ REG_DPS_MODEL = 0x0B,
+ REG_DPS_VERSION = 0x0C,
+
+ REG_DPS_PRESET = 0x23, /* Loads a preset into preset 0. */
/*
* Add (preset * 0x10) to each of the following, for preset 1-9.
* Preset 0 regs below are the active output settings.
*/
- PRE_USET = 0x50,
- PRE_ISET = 0x51,
- PRE_OVPSET = 0x52,
- PRE_OCPSET = 0x53,
- PRE_OPPSET = 0x54,
- PRE_BACKLIGHT = 0x55,
- PRE_DISABLE = 0x56, /* Disable output if 0 is copied here from a preset (1 is no change). */
- PRE_BOOT = 0x57, /* Enable output at boot if 1. */
+ PRE_DPS_USET = 0x50,
+ PRE_DPS_ISET = 0x51,
+ PRE_DPS_OVPSET = 0x52,
+ PRE_DPS_OCPSET = 0x53,
+ PRE_DPS_OPPSET = 0x54,
+ PRE_DPS_BACKLIGHT = 0x55,
+ PRE_DPS_DISABLE = 0x56, /* Disable output if 0 is copied here from a preset (1 is no change). */
+ PRE_DPS_BOOT = 0x57, /* Enable output at boot if 1. */
};
-#define REG_PRESET_STRIDE 0x10
+#define PRE_DPS_STRIDE 0x10
enum rdtech_dps_protect_state {
STATE_NORMAL = 0,
MODE_CC = 1,
};
+/*
+ * Some registers are specific to a certain device. For example,
+ * REG_RD_RANGE is specific to RD6012P.
+ */
+enum rdtech_rd_register {
+ REG_RD_MODEL = 0, /* u16 */
+ REG_RD_SERIAL = 1, /* u32 */
+ REG_RD_FIRMWARE = 3, /* u16 */
+ REG_RD_TEMP_INT = 4, /* 2x u16 */
+ REG_RD_TEMP_INT_F = 6, /* 2x u16 */
+ REG_RD_VOLT_TGT = 8, /* u16 */
+ REG_RD_CURR_LIM = 9, /* u16 */
+ REG_RD_VOLTAGE = 10, /* u16 */
+ REG_RD_CURRENT = 11, /* u16 */
+ REG_RD_ENERGY = 12, /* u16 */
+ REG_RD_POWER = 13, /* u16 */
+ REG_RD_VOLT_IN = 14, /* u16 */
+ REG_RD_PROTECT = 16, /* u16 */
+ REG_RD_REGULATION = 17, /* u16 */
+ REG_RD_ENABLE = 18, /* u16 */
+ REG_RD_PRESET = 19, /* u16 */
+ REG_RD_RANGE = 20, /* u16 */
+ /*
+ * Battery at 32 == 0x20 pp:
+ * Mode, voltage, temperature, capacity, energy.
+ */
+ /*
+ * Date/time at 48 == 0x30 pp:
+ * Year, month, day, hour, minute, second.
+ */
+ /* Backlight at 72 == 0x48. */
+ REG_RD_OVP_THR = 82, /* 0x52 */
+ REG_RD_OCP_THR = 83, /* 0x53 */
+ /* One "live" slot and 9 "memory" positions. */
+ REG_RD_START_MEM = 84, /* 0x54 */
+};
+
/* Retries failed modbus read attempts for improved reliability. */
static int rdtech_dps_read_holding_registers(struct sr_modbus_dev_inst *modbus,
int address, int nb_registers, uint16_t *registers)
int ret;
retries = 3;
- while (retries--) {
+ do {
ret = sr_modbus_read_holding_registers(modbus,
address, nb_registers, registers);
if (ret == SR_OK)
return ret;
- }
+ } while (--retries);
return ret;
}
-/* Get one 16bit register. */
-static int rdtech_dps_get_reg(const struct sr_dev_inst *sdi,
- uint16_t address, uint16_t *value)
+/* Set one 16bit register. LE format for DPS devices. */
+static int rdtech_dps_set_reg(const struct sr_dev_inst *sdi,
+ uint16_t address, uint16_t value)
{
struct dev_context *devc;
struct sr_modbus_dev_inst *modbus;
uint16_t registers[1];
int ret;
- const uint8_t *rdptr;
+ uint8_t *wrptr;
devc = sdi->priv;
modbus = sdi->conn;
+ wrptr = (void *)registers;
+ write_u16be(wrptr, value);
+
g_mutex_lock(&devc->rw_mutex);
- ret = rdtech_dps_read_holding_registers(modbus,
- address, ARRAY_SIZE(registers), registers);
+ ret = sr_modbus_write_multiple_registers(modbus, address,
+ ARRAY_SIZE(registers), registers);
g_mutex_unlock(&devc->rw_mutex);
- rdptr = (void *)registers;
- *value = read_u16le(rdptr);
-
return ret;
}
-/* Set one 16bit register. */
-static int rdtech_dps_set_reg(const struct sr_dev_inst *sdi,
+/* Set one 16bit register. BE format for RD devices. */
+static int rdtech_rd_set_reg(const struct sr_dev_inst *sdi,
uint16_t address, uint16_t value)
{
struct dev_context *devc;
modbus = sdi->conn;
wrptr = (void *)registers;
- write_u16le(wrptr, value);
+ write_u16be(wrptr, value);
g_mutex_lock(&devc->rw_mutex);
ret = sr_modbus_write_multiple_registers(modbus, address,
/* Get DPS model number and firmware version from a connected device. */
SR_PRIV int rdtech_dps_get_model_version(struct sr_modbus_dev_inst *modbus,
- uint16_t *model, uint16_t *version)
+ enum rdtech_dps_model_type model_type,
+ uint16_t *model, uint16_t *version, uint32_t *serno)
{
- uint16_t registers[REG_VERSION + 1 - REG_MODEL];
+ uint16_t registers[4];
int ret;
const uint8_t *rdptr;
- /* Silence a compiler warning about an unused routine. */
- (void)rdtech_dps_get_reg;
+ /*
+ * No mutex here because when the routine executes then the
+ * device instance was not created yet (probe phase).
+ */
+ switch (model_type) {
+ case MODEL_DPS:
+ /* Get the MODEL and VERSION registers. */
+ ret = rdtech_dps_read_holding_registers(modbus,
+ REG_DPS_MODEL, 2, registers);
+ if (ret != SR_OK)
+ return ret;
+ rdptr = (void *)registers;
+ *model = read_u16be_inc(&rdptr);
+ *version = read_u16be_inc(&rdptr);
+ *serno = 0;
+ sr_info("RDTech DPS/DPH model: %u version: %u",
+ *model, *version);
+ return SR_OK;
+ case MODEL_RD:
+ /* Get the MODEL, SERIAL, and FIRMWARE registers. */
+ ret = rdtech_dps_read_holding_registers(modbus,
+ REG_RD_MODEL, 4, registers);
+ if (ret != SR_OK)
+ return ret;
+ rdptr = (void *)registers;
+ *model = read_u16be_inc(&rdptr);
+ *serno = read_u32be_inc(&rdptr);
+ *version = read_u16be_inc(&rdptr);
+ sr_info("RDTech RD model: %u version: %u, serno %u",
+ *model, *version, *serno);
+ return SR_OK;
+ default:
+ sr_err("Unexpected RDTech PSU device type. Programming error?");
+ return SR_ERR_ARG;
+ }
+ /* UNREACH */
+}
+
+SR_PRIV void rdtech_dps_update_multipliers(const struct sr_dev_inst *sdi)
+{
+ struct dev_context *devc;
+ struct rdtech_dps_range *range;
+
+ devc = sdi->priv;
+ range = &devc->model->ranges[devc->curr_range];
+ devc->current_multiplier = pow(10.0, range->current_digits);
+ devc->voltage_multiplier = pow(10.0, range->voltage_digits);
+}
+
+/*
+ * Determine range of connected device. Don't do anything once
+ * acquisition has started (since the range will then be tracked).
+ */
+SR_PRIV int rdtech_dps_update_range(const struct sr_dev_inst *sdi)
+{
+ struct dev_context *devc;
+ uint16_t range;
+ int ret;
+
+ devc = sdi->priv;
/*
- * Get the MODEL and VERSION registers. No mutex here, because
- * there is no sr_dev_inst when this function is called.
+ * Only update range if there are multiple ranges and data
+ * acquisition hasn't started.
*/
- ret = rdtech_dps_read_holding_registers(modbus,
- REG_MODEL, ARRAY_SIZE(registers), registers);
+ if (devc->model->n_ranges == 1 || devc->acquisition_started)
+ return SR_OK;
+ if (devc->model->model_type != MODEL_RD)
+ return SR_ERR;
+
+ ret = rdtech_dps_read_holding_registers(sdi->conn,
+ REG_RD_RANGE, 1, &range);
if (ret != SR_OK)
return ret;
+ devc->curr_range = range ? 1 : 0;
+ rdtech_dps_update_multipliers(sdi);
- rdptr = (void *)registers;
- *model = read_u16le_inc(&rdptr);
- *version = read_u16le_inc(&rdptr);
- sr_info("RDTech DPS PSU model: %u version: %u", *model, *version);
-
- return ret;
+ return SR_OK;
}
/* Send a measured value to the session feed. */
* when the UART bitrate is only 9600bps?
*/
SR_PRIV int rdtech_dps_get_state(const struct sr_dev_inst *sdi,
- struct rdtech_dps_state *state)
+ struct rdtech_dps_state *state, enum rdtech_dps_state_context reason)
{
struct dev_context *devc;
struct sr_modbus_dev_inst *modbus;
- uint16_t registers[REG_ENABLE + 1 - REG_USET];
+ gboolean get_config, get_init_state, get_curr_meas;
+ uint16_t registers[14];
int ret;
const uint8_t *rdptr;
uint16_t uset_raw, iset_raw, uout_raw, iout_raw, power_raw;
uint16_t reg_val, reg_state, out_state, ovpset_raw, ocpset_raw;
gboolean is_lock, is_out_enabled, is_reg_cc;
gboolean uses_ovp, uses_ocp;
+ uint16_t range;
float volt_target, curr_limit;
float ovp_threshold, ocp_threshold;
float curr_voltage, curr_current, curr_power;
if (!state)
return SR_ERR_ARG;
- /* Transfer a chunk of registers in a single call. */
- g_mutex_lock(&devc->rw_mutex);
- ret = rdtech_dps_read_holding_registers(modbus,
- REG_USET, ARRAY_SIZE(registers), registers);
- g_mutex_unlock(&devc->rw_mutex);
- if (ret != SR_OK)
- return ret;
-
- /* Interpret the registers' values. */
- rdptr = (const void *)registers;
- uset_raw = read_u16le_inc(&rdptr);
- volt_target = uset_raw / devc->voltage_multiplier;
- iset_raw = read_u16le_inc(&rdptr);
- curr_limit = iset_raw / devc->current_multiplier;
- uout_raw = read_u16le_inc(&rdptr);
- curr_voltage = uout_raw / devc->voltage_multiplier;
- iout_raw = read_u16le_inc(&rdptr);
- curr_current = iout_raw / devc->current_multiplier;
- power_raw = read_u16le_inc(&rdptr);
- curr_power = power_raw / 100.0f;
- (void)read_u16le_inc(&rdptr); /* UIN */
- reg_val = read_u16le_inc(&rdptr); /* LOCK */
- is_lock = reg_val != 0;
- reg_val = read_u16le_inc(&rdptr); /* PROTECT */
- uses_ovp = reg_val == STATE_OVP;
- uses_ocp = reg_val == STATE_OCP;
- reg_state = read_u16le_inc(&rdptr); /* CV_CC */
- is_reg_cc = reg_state == MODE_CC;
- out_state = read_u16le_inc(&rdptr); /* ENABLE */
- is_out_enabled = out_state != 0;
+ /* Determine the requested level of response detail. */
+ get_config = FALSE;
+ get_init_state = FALSE;
+ get_curr_meas = FALSE;
+ switch (reason) {
+ case ST_CTX_CONFIG:
+ get_config = TRUE;
+ get_init_state = TRUE;
+ get_curr_meas = TRUE;
+ break;
+ case ST_CTX_PRE_ACQ:
+ get_init_state = TRUE;
+ get_curr_meas = TRUE;
+ break;
+ case ST_CTX_IN_ACQ:
+ get_curr_meas = TRUE;
+ break;
+ default:
+ /* EMPTY */
+ break;
+ }
+ /*
+ * TODO Make use of this information to reduce the transfer
+ * volume, especially on low bitrate serial connections. Though
+ * the device firmware's samplerate is probably more limiting
+ * than communication bandwidth is.
+ */
+ (void)get_config;
+ (void)get_init_state;
+ (void)get_curr_meas;
/*
- * Transfer another chunk of registers in a single call.
- * TODO Unfortunately this call site open codes a fixed number
- * of registers to read. But there is already some leakage of
- * the register layout in this routine, and adding more device
- * types in the future will make things "worse". So accept it.
+ * The model RD6012P has two voltage/current ranges. We set a
+ * default value here such that the compiler doesn't generate
+ * an uninitialized variable warning.
*/
- g_mutex_lock(&devc->rw_mutex);
- ret = rdtech_dps_read_holding_registers(modbus,
- PRE_OVPSET, 2, registers);
- g_mutex_unlock(&devc->rw_mutex);
- if (ret != SR_OK)
- return ret;
+ range = 0;
+
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ /*
+ * Transfer a chunk of registers in a single call. It's
+ * unfortunate that the model dependency and the sparse
+ * register map force us to open code addresses, sizes,
+ * and the sequence of the registers and how to interpret
+ * their bit fields. But then this is not too unusual for
+ * a hardware specific device driver ...
+ */
+ g_mutex_lock(&devc->rw_mutex);
+ ret = rdtech_dps_read_holding_registers(modbus, REG_DPS_USET,
+ REG_DPS_ENABLE - REG_DPS_USET + 1, registers);
+ g_mutex_unlock(&devc->rw_mutex);
+ if (ret != SR_OK)
+ return ret;
+
+ /* Interpret the registers' values. */
+ rdptr = (const void *)registers;
+ uset_raw = read_u16be_inc(&rdptr);
+ volt_target = uset_raw / devc->voltage_multiplier;
+ iset_raw = read_u16be_inc(&rdptr);
+ curr_limit = iset_raw / devc->current_multiplier;
+ uout_raw = read_u16be_inc(&rdptr);
+ curr_voltage = uout_raw / devc->voltage_multiplier;
+ iout_raw = read_u16be_inc(&rdptr);
+ curr_current = iout_raw / devc->current_multiplier;
+ power_raw = read_u16be_inc(&rdptr);
+ curr_power = power_raw / 100.0f;
+ (void)read_u16be_inc(&rdptr); /* UIN */
+ reg_val = read_u16be_inc(&rdptr); /* LOCK */
+ is_lock = reg_val != 0;
+ reg_val = read_u16be_inc(&rdptr); /* PROTECT */
+ uses_ovp = reg_val == STATE_OVP;
+ uses_ocp = reg_val == STATE_OCP;
+ reg_state = read_u16be_inc(&rdptr); /* CV_CC */
+ is_reg_cc = reg_state == MODE_CC;
+ out_state = read_u16be_inc(&rdptr); /* ENABLE */
+ is_out_enabled = out_state != 0;
+
+ /* Transfer another chunk of registers in a single call. */
+ g_mutex_lock(&devc->rw_mutex);
+ ret = rdtech_dps_read_holding_registers(modbus,
+ PRE_DPS_OVPSET, 2, registers);
+ g_mutex_unlock(&devc->rw_mutex);
+ if (ret != SR_OK)
+ return ret;
+
+ /* Interpret the second registers chunk's values. */
+ rdptr = (const void *)registers;
+ ovpset_raw = read_u16be_inc(&rdptr); /* PRE OVPSET */
+ ovp_threshold = ovpset_raw * devc->voltage_multiplier;
+ ocpset_raw = read_u16be_inc(&rdptr); /* PRE OCPSET */
+ ocp_threshold = ocpset_raw * devc->current_multiplier;
+
+ break;
+
+ case MODEL_RD:
+ /* Retrieve a set of adjacent registers. */
+ g_mutex_lock(&devc->rw_mutex);
+ ret = rdtech_dps_read_holding_registers(modbus,
+ REG_RD_VOLT_TGT,
+ devc->model->n_ranges > 1
+ ? REG_RD_RANGE - REG_RD_VOLT_TGT + 1
+ : REG_RD_ENABLE - REG_RD_VOLT_TGT + 1,
+ registers);
+ g_mutex_unlock(&devc->rw_mutex);
+ if (ret != SR_OK)
+ return ret;
+
+ /* Interpret the registers' raw content. */
+ rdptr = (const void *)registers;
+ uset_raw = read_u16be_inc(&rdptr); /* USET */
+ volt_target = uset_raw / devc->voltage_multiplier;
+ iset_raw = read_u16be_inc(&rdptr); /* ISET */
+ curr_limit = iset_raw / devc->current_multiplier;
+ uout_raw = read_u16be_inc(&rdptr); /* UOUT */
+ curr_voltage = uout_raw / devc->voltage_multiplier;
+ iout_raw = read_u16be_inc(&rdptr); /* IOUT */
+ curr_current = iout_raw / devc->current_multiplier;
+ (void)read_u16be_inc(&rdptr); /* ENERGY */
+ power_raw = read_u16be_inc(&rdptr); /* POWER */
+ curr_power = power_raw / 100.0f;
+ (void)read_u16be_inc(&rdptr); /* VOLT_IN */
+ (void)read_u16be_inc(&rdptr);
+ reg_val = read_u16be_inc(&rdptr); /* PROTECT */
+ uses_ovp = reg_val == STATE_OVP;
+ uses_ocp = reg_val == STATE_OCP;
+ reg_state = read_u16be_inc(&rdptr); /* REGULATION */
+ is_reg_cc = reg_state == MODE_CC;
+ out_state = read_u16be_inc(&rdptr); /* ENABLE */
+ is_out_enabled = out_state != 0;
+ if (devc->model->n_ranges > 1) {
+ rdptr += sizeof (uint16_t); /* PRESET */
+ range = read_u16be_inc(&rdptr) ? 1 : 0; /* RANGE */
+ }
+
+ /* Retrieve a set of adjacent registers. */
+ g_mutex_lock(&devc->rw_mutex);
+ ret = rdtech_dps_read_holding_registers(modbus,
+ REG_RD_OVP_THR, 2, registers);
+ g_mutex_unlock(&devc->rw_mutex);
+ if (ret != SR_OK)
+ return ret;
+
+ /* Interpret the registers' raw content. */
+ rdptr = (const void *)registers;
+ ovpset_raw = read_u16be_inc(&rdptr); /* OVP THR */
+ ovp_threshold = ovpset_raw / devc->voltage_multiplier;
+ ocpset_raw = read_u16be_inc(&rdptr); /* OCP THR */
+ ocp_threshold = ocpset_raw / devc->current_multiplier;
+
+ /* Details which we cannot query from the device. */
+ is_lock = FALSE;
- /* Interpret the registers' values. */
- rdptr = (const void *)registers;
- ovpset_raw = read_u16le_inc(&rdptr); /* PRE OVPSET */
- ovp_threshold = ovpset_raw * devc->voltage_multiplier;
- ocpset_raw = read_u16le_inc(&rdptr); /* PRE OCPSET */
- ocp_threshold = ocpset_raw * devc->current_multiplier;
+ break;
- /* Store gathered details in the high level container. */
+ default:
+ /* ShouldNotHappen(TM). Probe should have failed. */
+ return SR_ERR_ARG;
+ }
+
+ /*
+ * Store gathered details in the high level container.
+ *
+ * TODO Make use of the caller's context. The register access
+ * code path above need not have gathered every detail in every
+ * invocation.
+ */
memset(state, 0, sizeof(*state));
state->lock = is_lock;
state->mask |= STATE_LOCK;
state->mask |= STATE_CURRENT;
state->power = curr_power;
state->mask |= STATE_POWER;
+ if (devc->model->n_ranges > 1) {
+ state->range = range;
+ state->mask |= STATE_RANGE;
+ }
return SR_OK;
}
/* Only a subset of known values is settable. */
if (state->mask & STATE_OUTPUT_ENABLED) {
reg_value = state->output_enabled ? 1 : 0;
- ret = rdtech_dps_set_reg(sdi, REG_ENABLE, reg_value);
- if (ret != SR_OK)
- return ret;
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ ret = rdtech_dps_set_reg(sdi, REG_DPS_ENABLE, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ case MODEL_RD:
+ ret = rdtech_rd_set_reg(sdi, REG_RD_ENABLE, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ default:
+ return SR_ERR_ARG;
+ }
}
if (state->mask & STATE_VOLTAGE_TARGET) {
reg_value = state->voltage_target * devc->voltage_multiplier;
- ret = rdtech_dps_set_reg(sdi, REG_USET, reg_value);
- if (ret != SR_OK)
- return ret;
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ ret = rdtech_dps_set_reg(sdi, REG_DPS_USET, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ case MODEL_RD:
+ ret = rdtech_rd_set_reg(sdi, REG_RD_VOLT_TGT, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ default:
+ return SR_ERR_ARG;
+ }
}
if (state->mask & STATE_CURRENT_LIMIT) {
reg_value = state->current_limit * devc->current_multiplier;
- ret = rdtech_dps_set_reg(sdi, REG_ISET, reg_value);
- if (ret != SR_OK)
- return ret;
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ ret = rdtech_dps_set_reg(sdi, REG_DPS_ISET, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ case MODEL_RD:
+ ret = rdtech_rd_set_reg(sdi, REG_RD_CURR_LIM, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ default:
+ return SR_ERR_ARG;
+ }
}
if (state->mask & STATE_OVP_THRESHOLD) {
reg_value = state->ovp_threshold * devc->voltage_multiplier;
- ret = rdtech_dps_set_reg(sdi, PRE_OVPSET, reg_value);
- if (ret != SR_OK)
- return ret;
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ ret = rdtech_dps_set_reg(sdi, PRE_DPS_OVPSET, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ case MODEL_RD:
+ ret = rdtech_rd_set_reg(sdi, REG_RD_OVP_THR, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ default:
+ return SR_ERR_ARG;
+ }
}
if (state->mask & STATE_OCP_THRESHOLD) {
reg_value = state->ocp_threshold * devc->current_multiplier;
- ret = rdtech_dps_set_reg(sdi, PRE_OCPSET, reg_value);
- if (ret != SR_OK)
- return ret;
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ ret = rdtech_dps_set_reg(sdi, PRE_DPS_OCPSET, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ case MODEL_RD:
+ ret = rdtech_rd_set_reg(sdi, REG_RD_OCP_THR, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ default:
+ return SR_ERR_ARG;
+ }
}
if (state->mask & STATE_LOCK) {
- reg_value = state->lock ? 1 : 0;
- ret = rdtech_dps_set_reg(sdi, REG_LOCK, reg_value);
- if (ret != SR_OK)
- return ret;
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ reg_value = state->lock ? 1 : 0;
+ ret = rdtech_dps_set_reg(sdi, REG_DPS_LOCK, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ break;
+ case MODEL_RD:
+ /* Do nothing, _and_ silently succeed. */
+ break;
+ default:
+ return SR_ERR_ARG;
+ }
+ }
+ if (state->mask & STATE_RANGE) {
+ reg_value = state->range;
+ switch (devc->model->model_type) {
+ case MODEL_DPS:
+ if (reg_value > 0)
+ return SR_ERR_ARG;
+ break;
+ case MODEL_RD:
+ if (devc->model->n_ranges == 1)
+ /* No need to set. */
+ return SR_OK;
+ ret = rdtech_rd_set_reg(sdi, REG_RD_RANGE, reg_value);
+ if (ret != SR_OK)
+ return ret;
+ if (!devc->acquisition_started) {
+ devc->curr_range = reg_value ? 1 : 0;
+ rdtech_dps_update_multipliers(sdi);
+ }
+ /*
+ * We rely on the data acquisition to update
+ * devc->curr_range. If we do it here, there
+ * will be no range meta package.
+ */
+ break;
+ default:
+ return SR_ERR_ARG;
+ }
}
return SR_OK;
struct rdtech_dps_state state;
int ret;
- ret = rdtech_dps_get_state(sdi, &state);
+ if (!sdi || !sdi->priv)
+ return SR_ERR_ARG;
+ devc = sdi->priv;
+ devc->acquisition_started = TRUE;
+
+ ret = rdtech_dps_get_state(sdi, &state, ST_CTX_PRE_ACQ);
if (ret != SR_OK)
return ret;
devc->curr_cc_state = state.regulation_cc;
if (state.mask & STATE_OUTPUT_ENABLED)
devc->curr_out_state = state.output_enabled;
+ if (state.mask & STATE_RANGE) {
+ devc->curr_range = state.range;
+ rdtech_dps_update_multipliers(sdi);
+ }
return SR_OK;
}
devc = sdi->priv;
/* Get the device's current state. */
- ret = rdtech_dps_get_state(sdi, &state);
+ ret = rdtech_dps_get_state(sdi, &state, ST_CTX_IN_ACQ);
if (ret != SR_OK)
return ret;
ch = g_slist_nth_data(sdi->channels, 0);
send_value(sdi, ch, state.voltage,
SR_MQ_VOLTAGE, SR_MQFLAG_DC, SR_UNIT_VOLT,
- devc->model->voltage_digits);
+ devc->model->ranges[devc->curr_range].voltage_digits);
ch = g_slist_nth_data(sdi->channels, 1);
send_value(sdi, ch, state.current,
SR_MQ_CURRENT, SR_MQFLAG_DC, SR_UNIT_AMPERE,
- devc->model->current_digits);
+ devc->model->ranges[devc->curr_range].current_digits);
ch = g_slist_nth_data(sdi->channels, 2);
send_value(sdi, ch, state.power,
SR_MQ_POWER, 0, SR_UNIT_WATT, 2);
g_variant_new_boolean(state.output_enabled));
devc->curr_out_state = state.output_enabled;
}
+ if (devc->curr_range != state.range) {
+ (void)sr_session_send_meta(sdi, SR_CONF_RANGE,
+ g_variant_new_string(
+ devc->model->ranges[state.range].range_str));
+ devc->curr_range = state.range;
+ rdtech_dps_update_multipliers(sdi);
+ }
/* Check optional acquisition limits. */
sr_sw_limits_update_samples_read(&devc->limits, 1);