FreeDATA/modem/data cemetery/test/util_callback_multimode_tx.py
2023-12-17 12:35:21 +01:00

256 lines
8.8 KiB
Python

#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Created on Wed Dec 23 07:04:24 2020
@author: DJ2LS
"""
import argparse
import ctypes
import queue
import sys
import time
import numpy as np
import pyaudio
sys.path.insert(0, "..")
from modem import codec2
# --------------------------------------------GET PARAMETER INPUTS
parser = argparse.ArgumentParser(description="FreeDATA audio test")
parser.add_argument("--bursts", dest="N_BURSTS", default=1, type=int)
parser.add_argument("--framesperburst", dest="N_FRAMES_PER_BURST", default=1, type=int)
parser.add_argument("--delay", dest="DELAY_BETWEEN_BURSTS", default=500, type=int)
parser.add_argument(
"--audiodev",
dest="AUDIO_OUTPUT_DEVICE",
default=-1,
type=int,
help="audio output device number to use",
)
parser.add_argument(
"--list",
dest="LIST",
action="store_true",
help="list audio devices by number and exit",
)
parser.add_argument(
"--testframes",
dest="TESTFRAMES",
action="store_true",
default=False,
help="generate testframes",
)
args, _ = parser.parse_known_args()
if args.LIST:
p = pyaudio.PyAudio()
for dev in range(p.get_device_count()):
print("audiodev: ", dev, p.get_device_info_by_index(dev)["name"])
sys.exit()
class Test:
def __init__(self):
self.dataqueue = queue.Queue()
self.N_BURSTS = args.N_BURSTS
self.N_FRAMES_PER_BURST = args.N_FRAMES_PER_BURST
self.AUDIO_OUTPUT_DEVICE = args.AUDIO_OUTPUT_DEVICE
self.DELAY_BETWEEN_BURSTS = args.DELAY_BETWEEN_BURSTS / 1000
# AUDIO PARAMETERS
# v-- consider increasing if you get nread_exceptions > 0
self.AUDIO_FRAMES_PER_BUFFER = 2400
self.MODEM_SAMPLE_RATE = codec2.api.FREEDV_FS_8000
self.AUDIO_SAMPLE_RATE_TX = 48000
# make sure our resampler will work
assert (
self.AUDIO_SAMPLE_RATE_TX / self.MODEM_SAMPLE_RATE
) == codec2.api.FDMDV_OS_48
self.transmit = True
self.resampler = codec2.resampler()
# check if we want to use an audio device then do a pyaudio init
if self.AUDIO_OUTPUT_DEVICE != -1:
self.p = pyaudio.PyAudio()
# auto search for loopback devices
if self.AUDIO_OUTPUT_DEVICE == -2:
loopback_list = [
dev
for dev in range(self.p.get_device_count())
if "Loopback: PCM" in self.p.get_device_info_by_index(dev)["name"]
]
if len(loopback_list) >= 2:
self.AUDIO_OUTPUT_DEVICE = loopback_list[0] # 0 = RX 1 = TX
print(f"loopback_list rx: {loopback_list}", file=sys.stderr)
else:
sys.exit()
print(
f"AUDIO OUTPUT DEVICE: {self.AUDIO_OUTPUT_DEVICE} "
f"DEVICE: {self.p.get_device_info_by_index(self.AUDIO_OUTPUT_DEVICE)['name']} "
f"AUDIO SAMPLE RATE: {self.AUDIO_SAMPLE_RATE_TX}",
file=sys.stderr,
)
self.stream_tx = self.p.open(
format=pyaudio.paInt16,
channels=1,
rate=self.AUDIO_SAMPLE_RATE_TX,
frames_per_buffer=self.AUDIO_FRAMES_PER_BUFFER,
input=False,
output=True,
output_device_index=self.AUDIO_OUTPUT_DEVICE,
stream_callback=self.callback,
)
else:
print("test_callback_multimode_tx: Not written for STDOUT usage.")
print("Exiting.")
sys.exit()
# Copy received 48 kHz to a file. Listen to this file with:
# aplay -r 48000 -f S16_LE rx48_callback.raw
# Corruption of this file is a good way to detect audio card issues
self.ftx = open("tx48_callback.raw", mode="wb")
# data binary string
if args.TESTFRAMES:
self.data_out = bytearray(14)
self.data_out[:1] = bytes([255])
self.data_out[1:2] = bytes([1])
self.data_out[2:] = b"HELLO WORLD"
else:
self.data_out = b"HELLO WORLD!"
def callback(self, data_in48k, frame_count, time_info, status):
data_out48k = self.dataqueue.get()
return (data_out48k, pyaudio.paContinue)
def run_audio(self):
try:
print("starting pyaudio callback", file=sys.stderr)
self.stream_tx.start_stream()
except Exception as e:
print(f"pyAudio error: {e}", file=sys.stderr)
sheeps = 0
while self.transmit:
time.sleep(1)
sheeps = sheeps + 1
print(f"counting sheeps...{sheeps}")
self.ftx.close()
# close pyaudio instance
self.stream_tx.close()
self.p.terminate()
def create_modulation(self):
modes = [
codec2.FREEDV_MODE.datac13.value,
codec2.FREEDV_MODE.datac1.value,
codec2.FREEDV_MODE.datac3.value,
]
for m in modes:
freedv = ctypes.cast(codec2.api.freedv_open(m), ctypes.c_void_p)
n_tx_modem_samples = codec2.api.freedv_get_n_tx_modem_samples(freedv)
mod_out = ctypes.create_string_buffer(2 * n_tx_modem_samples)
n_tx_preamble_modem_samples = (
codec2.api.freedv_get_n_tx_preamble_modem_samples(freedv)
)
mod_out_preamble = ctypes.create_string_buffer(
2 * n_tx_preamble_modem_samples
)
n_tx_postamble_modem_samples = (
codec2.api.freedv_get_n_tx_postamble_modem_samples(freedv)
)
mod_out_postamble = ctypes.create_string_buffer(
2 * n_tx_postamble_modem_samples
)
bytes_per_frame = int(
codec2.api.freedv_get_bits_per_modem_frame(freedv) / 8
)
payload_per_frame = bytes_per_frame - 2
buffer = bytearray(payload_per_frame)
# set buffer size to length of data which will be sent
buffer[: len(self.data_out)] = self.data_out
crc = ctypes.c_ushort(
codec2.api.freedv_gen_crc16(bytes(buffer), payload_per_frame)
) # generate CRC16
# convert crc to 2 byte hex string
crc = crc.value.to_bytes(2, byteorder="big")
buffer += crc # append crc16 to buffer
data = (ctypes.c_ubyte * bytes_per_frame).from_buffer_copy(buffer)
for i in range(1, self.N_BURSTS + 1):
# write preamble to txbuffer
codec2.api.freedv_rawdatapreambletx(freedv, mod_out_preamble)
txbuffer = bytes(mod_out_preamble)
# create modulaton for N = FRAMESPERBURST and append it to txbuffer
for n in range(1, self.N_FRAMES_PER_BURST + 1):
data = (ctypes.c_ubyte * bytes_per_frame).from_buffer_copy(buffer)
codec2.api.freedv_rawdatatx(
freedv, mod_out, data
) # modulate DATA and save it into mod_out pointer
txbuffer += bytes(mod_out)
print(
f"GENERATING TX BURST: {i}/{self.N_BURSTS} FRAME: {n}/{self.N_FRAMES_PER_BURST}",
file=sys.stderr,
)
# append postamble to txbuffer
codec2.api.freedv_rawdatapostambletx(freedv, mod_out_postamble)
txbuffer += bytes(mod_out_postamble)
# append a delay between bursts as audio silence
samples_delay = int(self.MODEM_SAMPLE_RATE * self.DELAY_BETWEEN_BURSTS)
mod_out_silence = ctypes.create_string_buffer(samples_delay * 2)
txbuffer += bytes(mod_out_silence)
# resample up to 48k (resampler works on np.int16)
x = np.frombuffer(txbuffer, dtype=np.int16)
txbuffer_48k = self.resampler.resample8_to_48(x)
# split modulated audio to chunks
# https://newbedev.com/how-to-split-a-byte-string-into-separate-bytes-in-python
txbuffer_48k = bytes(txbuffer_48k)
chunk = [
txbuffer_48k[i : i + self.AUDIO_FRAMES_PER_BUFFER * 2]
for i in range(
0, len(txbuffer_48k), self.AUDIO_FRAMES_PER_BUFFER * 2
)
]
# add modulated chunks to fifo buffer
for c in chunk:
# if data is shorter than the expcected audio frames per buffer we need to append 0
# to prevent the callback from stucking/crashing
if len(c) < self.AUDIO_FRAMES_PER_BUFFER * 2:
c += bytes(self.AUDIO_FRAMES_PER_BUFFER * 2 - len(c))
self.dataqueue.put(c)
test = Test()
test.create_modulation()
test.run_audio()