openwebrx-clone/owrx/source.py
2019-05-09 16:52:42 +02:00

333 lines
12 KiB
Python

import subprocess
from owrx.config import PropertyManager, FeatureDetector
import threading
import csdr
import time
import os
import signal
class RtlNmuxSource(object):
types = {
"rtl_sdr": {
"command": "rtl_sdr -s {samp_rate} -f {center_freq} -p {ppm} -g {rf_gain} -",
"format_conversion": "csdr convert_u8_f"
},
"hackrf": {
"command": "hackrf_transfer -s {samp_rate} -f {center_freq} -g {rf_gain} -l{lna_gain} -a{rf_amp} -r-",
"format_conversion": "csdr convert_s8_f"
},
"sdrplay": {
"command": "rx_sdr -F CF32 -s {samp_rate} -f {center_freq} -p {ppm} -g {rf_gain} -",
"format_conversion": None,
"sleep": 1
}
}
def setup(self):
self.props = props = PropertyManager.getSharedInstance().collect(
"rtl_type", "samp_rate", "nmux_memory", "iq_server_port", "center_freq", "ppm",
"rf_gain", "lna_gain", "rf_amp"
)
def restart(name, value):
print("restarting rtl source due to property change: {0} changed to {1}".format(name, value))
self.stop()
self.start()
props.wire(restart)
self.start()
def start(self):
props = self.props
featureDetector = FeatureDetector()
if not featureDetector.is_available(props["rtl_type"]):
print("The RTL source type {0} is not available. please check requirements.".format(props["rtl_type"]))
return
self.params = RtlNmuxSource.types[props["rtl_type"]]
start_sdr_command = self.params["command"].format(
samp_rate = props["samp_rate"],
center_freq = props["center_freq"],
ppm = props["ppm"],
rf_gain = props["rf_gain"],
lna_gain = props["lna_gain"],
rf_amp = props["rf_amp"]
)
if self.params["format_conversion"] is not None:
start_sdr_command += " | " + self.params["format_conversion"]
nmux_bufcnt = nmux_bufsize = 0
while nmux_bufsize < props["samp_rate"]/4: nmux_bufsize += 4096
while nmux_bufsize * nmux_bufcnt < props["nmux_memory"] * 1e6: nmux_bufcnt += 1
if nmux_bufcnt == 0 or nmux_bufsize == 0:
print("[RtlNmuxSource] Error: nmux_bufsize or nmux_bufcnt is zero. These depend on nmux_memory and samp_rate options in config_webrx.py")
return
print("[RtlNmuxSource] nmux_bufsize = %d, nmux_bufcnt = %d" % (nmux_bufsize, nmux_bufcnt))
cmd = start_sdr_command + " | nmux --bufsize %d --bufcnt %d --port %d --address 127.0.0.1" % (nmux_bufsize, nmux_bufcnt, props["iq_server_port"])
self.process = subprocess.Popen(cmd, shell=True, preexec_fn=os.setpgrp)
print("[RtlNmuxSource] Started rtl source: " + cmd)
# TODO use this to monitor unexpected failures / shutdowns and react accordingly
def wait_for_process_to_end():
rc = self.process.wait()
print("[RtlNmuxSource] shut down with RC={0}".format(rc))
self.monitor = threading.Thread(target = wait_for_process_to_end)
self.monitor.start()
def stop(self):
os.killpg(os.getpgid(self.process.pid), signal.SIGTERM)
self.monitor.join()
if "sleep" in self.params:
time.sleep(self.params["sleep"])
class SpectrumThread(threading.Thread):
sharedInstance = None
@staticmethod
def getSharedInstance():
if SpectrumThread.sharedInstance is None:
SpectrumThread.sharedInstance = SpectrumThread()
SpectrumThread.sharedInstance.start()
return SpectrumThread.sharedInstance
def __init__(self):
self.clients = []
self.doRun = True
super().__init__()
def run(self):
props = PropertyManager.getSharedInstance().collect(
"samp_rate", "fft_size", "fft_fps", "fft_voverlap_factor", "fft_compression",
"csdr_dynamic_bufsize", "csdr_print_bufsizes", "csdr_through", "iq_server_port"
)
dsp = csdr.dsp()
dsp.nc_port = props["iq_server_port"]
dsp.set_demodulator("fft")
props.getProperty("samp_rate").wire(dsp.set_samp_rate)
props.getProperty("fft_size").wire(dsp.set_fft_size)
props.getProperty("fft_fps").wire(dsp.set_fft_fps)
props.getProperty("fft_compression").wire(dsp.set_fft_compression)
def set_fft_averages(key, value):
samp_rate = props["samp_rate"]
fft_size = props["fft_size"]
fft_fps = props["fft_fps"]
fft_voverlap_factor = props["fft_voverlap_factor"]
dsp.set_fft_averages(int(round(1.0 * samp_rate / fft_size / fft_fps / (1.0 - fft_voverlap_factor))) if fft_voverlap_factor>0 else 0)
props.collect("samp_rate", "fft_size", "fft_fps", "fft_voverlap_factor").wire(set_fft_averages)
set_fft_averages(None, None)
dsp.csdr_dynamic_bufsize = props["csdr_dynamic_bufsize"]
dsp.csdr_print_bufsizes = props["csdr_print_bufsizes"]
dsp.csdr_through = props["csdr_through"]
print("[openwebrx-spectrum] Spectrum thread initialized successfully.")
dsp.start()
if props["csdr_dynamic_bufsize"]:
dsp.read(8) #dummy read to skip bufsize & preamble
print("[openwebrx-spectrum] Note: CSDR_DYNAMIC_BUFSIZE_ON = 1")
print("[openwebrx-spectrum] Spectrum thread started.")
bytes_to_read=int(dsp.get_fft_bytes_to_read())
while self.doRun:
data=dsp.read(bytes_to_read)
if len(data) == 0:
time.sleep(1)
else:
for c in self.clients:
c.write_spectrum_data(data)
dsp.stop()
print("spectrum thread shut down")
def add_client(self, c):
self.clients.append(c)
def remove_client(self, c):
self.clients.remove(c)
if not self.clients:
self.shutdown()
def shutdown(self):
print("shutting down spectrum thread")
SpectrumThread.sharedInstance = None
self.doRun = False
class DspManager(object):
def __init__(self, handler):
self.doRun = True
self.handler = handler
self.localProps = PropertyManager.getSharedInstance().collect(
"audio_compression", "fft_compression", "digimodes_fft_size", "csdr_dynamic_bufsize",
"csdr_print_bufsizes", "csdr_through", "iq_server_port", "digimodes_enable", "samp_rate"
)
self.dsp = csdr.dsp()
#dsp_initialized=False
self.localProps.getProperty("audio_compression").wire(self.dsp.set_audio_compression)
self.localProps.getProperty("fft_compression").wire(self.dsp.set_fft_compression)
self.dsp.set_offset_freq(0)
self.dsp.set_bpf(-4000,4000)
self.localProps.getProperty("digimodes_fft_size").wire(self.dsp.set_secondary_fft_size)
self.dsp.nc_port = self.localProps["iq_server_port"]
self.dsp.csdr_dynamic_bufsize = self.localProps["csdr_dynamic_bufsize"]
self.dsp.csdr_print_bufsizes = self.localProps["csdr_print_bufsizes"]
self.dsp.csdr_through = self.localProps["csdr_through"]
self.localProps.getProperty("samp_rate").wire(self.dsp.set_samp_rate)
self.localProps.getProperty("output_rate").wire(self.dsp.set_output_rate)
self.localProps.getProperty("offset_freq").wire(self.dsp.set_offset_freq)
self.localProps.getProperty("squelch_level").wire(self.dsp.set_squelch_level)
def set_low_cut(cut):
bpf = self.dsp.get_bpf()
bpf[0] = cut
self.dsp.set_bpf(*bpf)
self.localProps.getProperty("low_cut").wire(set_low_cut)
def set_high_cut(cut):
bpf = self.dsp.get_bpf()
bpf[1] = cut
self.dsp.set_bpf(*bpf)
self.localProps.getProperty("high_cut").wire(set_high_cut)
self.localProps.getProperty("mod").wire(self.dsp.set_demodulator)
if (self.localProps["digimodes_enable"]):
def set_secondary_mod(mod):
if mod == False: mod = None
if self.dsp.get_secondary_demodulator() == mod: return
self.stopSecondaryThreads()
self.dsp.stop()
self.dsp.set_secondary_demodulator(mod)
if mod is not None:
self.handler.write_secondary_dsp_config({
"secondary_fft_size":self.localProps["digimodes_fft_size"],
"if_samp_rate":self.dsp.if_samp_rate(),
"secondary_bw":self.dsp.secondary_bw()
})
self.dsp.start()
if mod:
self.startSecondaryThreads()
self.localProps.getProperty("secondary_mod").wire(set_secondary_mod)
self.localProps.getProperty("secondary_offset_freq").wire(self.dsp.set_secondary_offset_freq)
super().__init__()
def start(self):
self.dsp.start()
threading.Thread(target = self.readDspOutput).start()
threading.Thread(target = self.readSMeterOutput).start()
def startSecondaryThreads(self):
self.runSecondary = True
self.secondaryDemodThread = threading.Thread(target = self.readSecondaryDemod)
self.secondaryDemodThread.start()
self.secondaryFftThread = threading.Thread(target = self.readSecondaryFft)
self.secondaryFftThread.start()
def stopSecondaryThreads(self):
self.runSecondary = False
self.secondaryDemodThread = None
self.secondaryFftThread = None
def readDspOutput(self):
while (self.doRun):
data = self.dsp.read(256)
if len(data) != 256:
time.sleep(1)
else:
self.handler.write_dsp_data(data)
def readSMeterOutput(self):
while (self.doRun):
level = self.dsp.get_smeter_level()
self.handler.write_s_meter_level(level)
def readSecondaryDemod(self):
while (self.runSecondary):
data = self.dsp.read_secondary_demod(1)
self.handler.write_secondary_demod(data)
def readSecondaryFft(self):
while (self.runSecondary):
data = self.dsp.read_secondary_fft(int(self.dsp.get_secondary_fft_bytes_to_read()))
self.handler.write_secondary_fft(data)
def stop(self):
self.doRun = False
self.runSecondary = False
self.dsp.stop()
def setProperty(self, prop, value):
self.localProps.getProperty(prop).setValue(value)
class CpuUsageThread(threading.Thread):
sharedInstance = None
@staticmethod
def getSharedInstance():
if CpuUsageThread.sharedInstance is None:
CpuUsageThread.sharedInstance = CpuUsageThread()
CpuUsageThread.sharedInstance.start()
return CpuUsageThread.sharedInstance
def __init__(self):
self.clients = []
self.doRun = True
self.last_worktime = 0
self.last_idletime = 0
super().__init__()
def run(self):
while self.doRun:
time.sleep(3)
try:
cpu_usage = self.get_cpu_usage()
except:
cpu_usage = 0
for c in self.clients:
c.write_cpu_usage(cpu_usage)
print("cpu usage thread shut down")
def get_cpu_usage(self):
try:
f = open("/proc/stat","r")
except:
return 0 #Workaround, possibly we're on a Mac
line = ""
while not "cpu " in line: line=f.readline()
f.close()
spl = line.split(" ")
worktime = int(spl[2]) + int(spl[3]) + int(spl[4])
idletime = int(spl[5])
dworktime = (worktime - self.last_worktime)
didletime = (idletime - self.last_idletime)
rate = float(dworktime) / (didletime+dworktime)
self.last_worktime = worktime
self.last_idletime = idletime
if (self.last_worktime==0): return 0
return rate
def add_client(self, c):
self.clients.append(c)
def remove_client(self, c):
self.clients.remove(c)
if not self.clients:
self.shutdown()
def shutdown(self):
print("shutting down cpu usage thread")
CpuUsageThread.sharedInstance = None
self.doRun = False