quisk-kc4upr/quisk_hardware_model.py

149 lines
8.5 KiB
Python
Executable File

# Please do not change this hardware control module for Quisk.
# You should use it as a base class for your own hardware modules.
# A custom hardware module should subclass this module; start it with:
# from quisk_hardware_model import Hardware as BaseHardware
# class Hardware(BaseHardware):
# def __init__(self, app, conf):
# BaseHardware.__init__(self, app, conf)
# ### your module starts here
from __future__ import print_function
from __future__ import absolute_import
from __future__ import division
import _quisk as QS
class Hardware:
def __init__(self, app, conf):
self.application = app # Application instance (to provide attributes)
self.conf = conf # Config file module
self.rf_gain_labels = () # Do not add the Rf Gain button
self.correct_smeter = conf.correct_smeter # Default correction for S-meter
self.use_sidetone = conf.use_sidetone # Copy from the config file
self.transverter_offset = 0 # Calculate the transverter offset in Hertz for each band
def pre_open(self): # Quisk calls this once before open() is called
pass
def open(self): # Quisk calls this once to open the Hardware
# Return an informative message for the config screen.
# This method must return a string showing whether the open succeeded or failed.
t = "Capture from sound card %s." % self.conf.name_of_sound_capt
return t
def close(self): # Quisk calls this once to close the Hardware
pass
def ChangeFrequency(self, tune, vfo, source='', band='', event=None):
# Change and return the tuning and VFO frequency in Hertz. The VFO frequency is the
# frequency in the center of the display; that is, the RF frequency corresponding to an
# audio frequency of zero Hertz. The tuning frequency is the RF frequency indicated by
# the tuning line on the display, and is equivalent to the transmit frequency. The quisk
# receive frequency is the tuning frequency plus the RIT (receive incremental tuning).
# If your hardware will not change to the requested frequencies, return different
# frequencies.
# The source is a string indicating the source of the change:
# BtnBand A band button
# BtnUpDown The band Up/Down buttons
# FreqEntry The user entered a frequency in the box
# MouseBtn1 Left mouse button press
# MouseBtn3 Right mouse button press
# MouseMotion The user is dragging with the left button
# MouseWheel The mouse wheel up/down
# NewDecim The decimation changed
# For "BtnBand", the string band is in the band argument.
# For the mouse events, the handler event is in the event argument.
return tune, vfo
def ReturnFrequency(self):
# Return the current tuning and VFO frequency. If neither have changed,
# you can return (None, None). This is called at about 10 Hz by the main.
# return (tune, vfo) # return changed frequencies
return None, None # frequencies have not changed
def ReturnVfoFloat(self):
# Return the accurate VFO frequency as a floating point number.
# You can return None to indicate that the integer VFO frequency is valid.
return None
def ChangeMode(self, mode): # Change the tx/rx mode
# mode is a string: "USB", "AM", etc.
pass
def ChangeBand(self, band):
# band is a string: "60", "40", "WWV", etc.
try:
self.transverter_offset = self.conf.bandTransverterOffset[band]
except:
self.transverter_offset = 0
def OnBtnFDX(self, is_fdx): # Status of FDX button, 0 or 1
pass
def HeartBeat(self): # Called at about 10 Hz by the main
pass
# The "VarDecim" methods are used to change the hardware decimation rate.
# If VarDecimGetChoices() returns any False value, no other methods are called.
def VarDecimGetChoices(self): # Return a list/tuple of strings for the decimation control.
return False # Return a False value for no decimation changes possible.
def VarDecimGetLabel(self): # Return a text label for the decimation control.
return ''
def VarDecimGetIndex(self): # Return the index 0, 1, ... of the current decimation.
return 0 # This is called before open() to initialize the control.
def VarDecimSet(self, index=None): # Called when the control is operated.
# Change the decimation here, and return the sample rate. The index is 0, 1, 2, ....
# Called with index == None before open() to set the initial sample rate.
# Note: The last used sample rate is available as self.application.vardecim_set if
# the persistent state option is True. If the value is unavailable for
# any reason, self.application.vardecim_set is None.
return 48000
def VarDecimRange(self): # Return the lowest and highest sample rate.
return (48000, 960000)
#
# The following methods are used to return I/Q samples from the hardware file to Quisk.
# None of these methods are called unless you call InitSamples().
# For an example of their use, see quisk_hardware_sdriq.py.
# Quisk calls all methods in the hardware file from the GUI thread except for StartSamples(),
# GetRxSamples() and StopSamples() which are called from the sound thread.
# The sound thread starts with StartSamples() and is not running during the calls to pre_open() and open().
def InitSamples(self, int_size, endian): # Rx sample initialization; you must call this from your hardware __init__().
# int_size is the number of bytes in each I or Q sample: 1, 2, 3, or 4
# endian is the order of bytes in the sample: 0 == little endian; 1 == big endian
# This can be called again to change the format. For example, a different number of bytes for different sample rates.
QS.set_params(rx_bytes=int_size, rx_endian=endian)
self.application.samples_from_python = True
def InitBscope(self, int_size, endian, clock, length): # Bandscope initialization; accept raw samples from the ADC
# You may call this once from your hardware __init__() after calling InitSamples(). The bandscope format can not be changed.
# int_size is the number of bytes in each sample: 1, 2, 3, or 4
# endian is the order of bytes in the sample: 0 == little endian; 1 == big endian
# clock is the integer ADC sample rate in Hertz
# length is the number of samples in each block of ADC samples, and equals the FFT size.
QS.set_params(bscope_bytes=int_size, bscope_endian=endian, bscope_size=length)
self.application.bandscope_clock = clock
def StartSamples(self): # Quisk calls this from the sound thread to start sending samples.
# If you return a string, it replaces the string returned from hardware open()
pass
def StopSamples(self): # Quisk calls this from the sound thread to stop sending samples.
pass
def GetRxSamples(self): # Quisk calls this frequently from the sound thread. Poll your hardware for samples.
# Return any available samples by calling AddRxSamples() and perhaps AddBscopeSamples() from within this method.
pass
def AddRxSamples(self, samples): # Call this from within GetRxSamples() to record the Rx samples.
# "samples" is int_size of integer I data followed by int_size of integer Q data, repeated.
# For Python 3, "samples" must be a byte array or bytes; use s = bytearray(2), or s = b"\x55\x44" or similar.
# For Python 2, "samples" must be a byte array or bytes or a string.
# The byte length must represent a whole number of samples. No partial records.
QS.add_rx_samples(samples)
def AddBscopeSamples(self, samples): # Call this from within GetRxSamples() to record the bandscope samples.
# "samples" is the whole block of integer samples from the ADC.
# For Python 3, "samples" must be a byte array or bytes; use s = bytearray(2), or s = b"\x55\x44" or similar.
# For Python 2, "samples" must be a byte array or bytes or a string.
# The number of bytes in "samples" must equal the block length times the bytes per sample.
QS.add_bscope_samples(samples)
def GotClip(self): # Call this to indicate that samples were received with the clip (overrange) indicator true.
QS.set_params(clip=1)
def GotReadError(self, print_msg, msg): # Call this to indicate an error in receiving the Rx samples.
if print_msg:
print(msg)
QS.set_params(read_error=1)
# If you import wx, there a few useful functions available. To set a busy cursor do this:
# try:
# wx.BeginBusyCursor()
# wx.Yield()
# self.ReallyTimeConsumingOperation()
# finally:
# wx.EndBusyCursor()
# To update the GUI during a long running operation, you can use wx.Yield() or wx.SafeYield().