from ..Internal.Core import Core
from ..Internal.CommandsGroup import CommandsGroup
from ..Internal.StructBase import StructBase
from ..Internal.ArgStruct import ArgStruct
# noinspection PyPep8Naming,PyAttributeOutsideInit,SpellCheckingInspection
[docs]class Throughput:
"""Throughput commands group definition. 23 total commands, 2 Sub-groups, 5 group commands"""
def __init__(self, core: Core, parent):
self._core = core
self._base = CommandsGroup("throughput", core, parent)
@property
def state(self):
"""state commands group. 1 Sub-classes, 1 commands."""
if not hasattr(self, '_state'):
from .Throughput_.State import State
self._state = State(self._core, self._base)
return self._state
@property
def trace(self):
"""trace commands group. 2 Sub-classes, 0 commands."""
if not hasattr(self, '_trace'):
from .Throughput_.Trace import Trace
self._trace = Trace(self._core, self._base)
return self._trace
[docs] def stop(self) -> None:
"""SCPI: STOP:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: driver.throughput.stop() \n
INTRO_CMD_HELP: Starts, stops, or aborts the measurement: \n
- INITiate... starts or restarts the measurement. The measurement enters the 'RUN' state.
- STOP... halts the measurement immediately. The measurement enters the 'RDY' state. Measurement results are kept. The resources remain allocated to the measurement.
- ABORt... halts the measurement immediately. The measurement enters the 'OFF' state. All measurement values are set to NAV. Allocated resources are released.
Use FETCh...STATe? to query the current measurement state. \n
"""
self._core.io.write(f'STOP:WCDMa:SIGNaling<Instance>:THRoughput')
[docs] def stop_with_opc(self) -> None:
"""SCPI: STOP:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: driver.throughput.stop_with_opc() \n
INTRO_CMD_HELP: Starts, stops, or aborts the measurement: \n
- INITiate... starts or restarts the measurement. The measurement enters the 'RUN' state.
- STOP... halts the measurement immediately. The measurement enters the 'RDY' state. Measurement results are kept. The resources remain allocated to the measurement.
- ABORt... halts the measurement immediately. The measurement enters the 'OFF' state. All measurement values are set to NAV. Allocated resources are released.
Use FETCh...STATe? to query the current measurement state. \n
Same as stop, but waits for the operation to complete before continuing further. Use the RsCmwWcdmaSig.utilities.opc_timeout_set() to set the timeout value. \n
"""
self._core.io.write_with_opc(f'STOP:WCDMa:SIGNaling<Instance>:THRoughput')
[docs] def abort(self) -> None:
"""SCPI: ABORt:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: driver.throughput.abort() \n
INTRO_CMD_HELP: Starts, stops, or aborts the measurement: \n
- INITiate... starts or restarts the measurement. The measurement enters the 'RUN' state.
- STOP... halts the measurement immediately. The measurement enters the 'RDY' state. Measurement results are kept. The resources remain allocated to the measurement.
- ABORt... halts the measurement immediately. The measurement enters the 'OFF' state. All measurement values are set to NAV. Allocated resources are released.
Use FETCh...STATe? to query the current measurement state. \n
"""
self._core.io.write(f'ABORt:WCDMa:SIGNaling<Instance>:THRoughput')
[docs] def abort_with_opc(self) -> None:
"""SCPI: ABORt:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: driver.throughput.abort_with_opc() \n
INTRO_CMD_HELP: Starts, stops, or aborts the measurement: \n
- INITiate... starts or restarts the measurement. The measurement enters the 'RUN' state.
- STOP... halts the measurement immediately. The measurement enters the 'RDY' state. Measurement results are kept. The resources remain allocated to the measurement.
- ABORt... halts the measurement immediately. The measurement enters the 'OFF' state. All measurement values are set to NAV. Allocated resources are released.
Use FETCh...STATe? to query the current measurement state. \n
Same as abort, but waits for the operation to complete before continuing further. Use the RsCmwWcdmaSig.utilities.opc_timeout_set() to set the timeout value. \n
"""
self._core.io.write_with_opc(f'ABORt:WCDMa:SIGNaling<Instance>:THRoughput')
[docs] def initiate(self) -> None:
"""SCPI: INITiate:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: driver.throughput.initiate() \n
INTRO_CMD_HELP: Starts, stops, or aborts the measurement: \n
- INITiate... starts or restarts the measurement. The measurement enters the 'RUN' state.
- STOP... halts the measurement immediately. The measurement enters the 'RDY' state. Measurement results are kept. The resources remain allocated to the measurement.
- ABORt... halts the measurement immediately. The measurement enters the 'OFF' state. All measurement values are set to NAV. Allocated resources are released.
Use FETCh...STATe? to query the current measurement state. \n
"""
self._core.io.write(f'INITiate:WCDMa:SIGNaling<Instance>:THRoughput')
[docs] def initiate_with_opc(self) -> None:
"""SCPI: INITiate:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: driver.throughput.initiate_with_opc() \n
INTRO_CMD_HELP: Starts, stops, or aborts the measurement: \n
- INITiate... starts or restarts the measurement. The measurement enters the 'RUN' state.
- STOP... halts the measurement immediately. The measurement enters the 'RDY' state. Measurement results are kept. The resources remain allocated to the measurement.
- ABORt... halts the measurement immediately. The measurement enters the 'OFF' state. All measurement values are set to NAV. Allocated resources are released.
Use FETCh...STATe? to query the current measurement state. \n
Same as initiate, but waits for the operation to complete before continuing further. Use the RsCmwWcdmaSig.utilities.opc_timeout_set() to set the timeout value. \n
"""
self._core.io.write_with_opc(f'INITiate:WCDMa:SIGNaling<Instance>:THRoughput')
# noinspection PyTypeChecker
[docs] class ResultData(StructBase):
"""Response structure. Fields: \n
- Reliability: int: See 'Reliability Indicator'
- Curr_Dl_Pdu: float: Current, average, maximum and minimum DL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Avg_Dl_Pdu: float: Current, average, maximum and minimum DL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Max_Dl_Pdu: float: Current, average, maximum and minimum DL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Min_Dl_Pdu: float: Current, average, maximum and minimum DL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Curr_Dl_Sdu: float: Current, average, maximum and minimum DL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Avg_Dl_Sdu: float: Current, average, maximum and minimum DL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Max_Dl_Sdu: float: Current, average, maximum and minimum DL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Min_Dl_Sdu: float: Current, average, maximum and minimum DL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Blocks_Dl_Pdu: int: Number of transmitted RLC PDUs Range: 0 to 4E+9
- Curr_Ul_Pdu: float: Current, average, maximum and minimum UL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Avg_Ul_Pdu: float: Current, average, maximum and minimum UL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Max_Ul_Pdu: float: Current, average, maximum and minimum UL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Min_Ul_Pdu: float: Current, average, maximum and minimum UL PDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Curr_Ul_Sdu: float: Current, average, maximum and minimum UL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Avg_Ul_Sdu: float: Current, average, maximum and minimum UL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Max_Ul_Sdu: float: Current, average, maximum and minimum UL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Min_Ul_Sdu: float: Current, average, maximum and minimum UL SDU results Range: 0 bit/s to 100E+6 bit/s, Unit: bit/s
- Blocks_Ul_Pdu: float: Number of received RLC PDUs Range: 0 to 4E+9"""
__meta_args_list = [
ArgStruct.scalar_int('Reliability', 'Reliability'),
ArgStruct.scalar_float('Curr_Dl_Pdu'),
ArgStruct.scalar_float('Avg_Dl_Pdu'),
ArgStruct.scalar_float('Max_Dl_Pdu'),
ArgStruct.scalar_float('Min_Dl_Pdu'),
ArgStruct.scalar_float('Curr_Dl_Sdu'),
ArgStruct.scalar_float('Avg_Dl_Sdu'),
ArgStruct.scalar_float('Max_Dl_Sdu'),
ArgStruct.scalar_float('Min_Dl_Sdu'),
ArgStruct.scalar_int('Blocks_Dl_Pdu'),
ArgStruct.scalar_float('Curr_Ul_Pdu'),
ArgStruct.scalar_float('Avg_Ul_Pdu'),
ArgStruct.scalar_float('Max_Ul_Pdu'),
ArgStruct.scalar_float('Min_Ul_Pdu'),
ArgStruct.scalar_float('Curr_Ul_Sdu'),
ArgStruct.scalar_float('Avg_Ul_Sdu'),
ArgStruct.scalar_float('Max_Ul_Sdu'),
ArgStruct.scalar_float('Min_Ul_Sdu'),
ArgStruct.scalar_float('Blocks_Ul_Pdu')]
def __init__(self):
StructBase.__init__(self, self)
self.Reliability: int = None
self.Curr_Dl_Pdu: float = None
self.Avg_Dl_Pdu: float = None
self.Max_Dl_Pdu: float = None
self.Min_Dl_Pdu: float = None
self.Curr_Dl_Sdu: float = None
self.Avg_Dl_Sdu: float = None
self.Max_Dl_Sdu: float = None
self.Min_Dl_Sdu: float = None
self.Blocks_Dl_Pdu: int = None
self.Curr_Ul_Pdu: float = None
self.Avg_Ul_Pdu: float = None
self.Max_Ul_Pdu: float = None
self.Min_Ul_Pdu: float = None
self.Curr_Ul_Sdu: float = None
self.Avg_Ul_Sdu: float = None
self.Max_Ul_Sdu: float = None
self.Min_Ul_Sdu: float = None
self.Blocks_Ul_Pdu: float = None
[docs] def fetch(self) -> ResultData:
"""SCPI: FETCh:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: value: ResultData = driver.throughput.fetch() \n
Returns all single value throughput results. \n
:return: structure: for return value, see the help for ResultData structure arguments."""
return self._core.io.query_struct(f'FETCh:WCDMa:SIGNaling<Instance>:THRoughput?', self.__class__.ResultData())
[docs] def read(self) -> ResultData:
"""SCPI: READ:WCDMa:SIGNaling<instance>:THRoughput \n
Snippet: value: ResultData = driver.throughput.read() \n
Returns all single value throughput results. \n
:return: structure: for return value, see the help for ResultData structure arguments."""
return self._core.io.query_struct(f'READ:WCDMa:SIGNaling<Instance>:THRoughput?', self.__class__.ResultData())
def clone(self) -> 'Throughput':
"""Clones the group by creating new object from it and its whole existing sub-groups
Also copies all the existing default Repeated Capabilities setting,
which you can change independently without affecting the original group"""
new_group = Throughput(self._core, self._base.parent)
self._base.synchronize_repcaps(new_group)
return new_group