mirror of
https://github.com/RfidResearchGroup/proxmark3.git
synced 2024-09-21 15:56:21 +08:00
79 lines
1.9 KiB
Python
79 lines
1.9 KiB
Python
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#!/usr/bin/python3
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### Parameters
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# Sound output parameters
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volume = 1.0
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sample_buf_size = 44
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sampling_freq = 44100 #Hz
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# Frequency generator parameters
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min_freq = 200 #Hz
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max_freq = 2000 #Hz
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# Proxmark3 parameters
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pm3_client="/usr/local/bin/proxmark3"
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pm3_reader_dev_file="/dev/ttyACM0"
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pm3_tune_cmd="hf tune"
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### Modules
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import numpy
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import pyaudio
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from select import select
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from subprocess import Popen, DEVNULL, PIPE
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### Main program
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p = pyaudio.PyAudio()
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# For paFloat32 sample values must be in range [-1.0, 1.0]
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stream = p.open(format=pyaudio.paFloat32,
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channels=1,
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rate=sampling_freq,
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output=True)
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# Initial voltage to frequency values
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min_v = 100.0
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max_v = 0.0
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v = 0
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out_freq = min_freq
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# Spawn the Proxmark3 client
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pm3_proc = Popen([pm3_client, pm3_reader_dev_file, "-c", pm3_tune_cmd],
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bufsize=0, env={}, stdin=DEVNULL, stdout=PIPE, stderr=DEVNULL)
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mv_recbuf = ""
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# Read voltages from the Proxmark3, generate the sine wave, output to soundcard
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sample_buf = [0.0 for x in range(0, sample_buf_size)]
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i = 0
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sinev = 0
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while True:
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# Read Proxmark3 client's stdout and extract voltage values
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if(select([pm3_proc.stdout], [], [], 0)[0]):
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b = pm3_proc.stdout.read(256).decode("ascii")
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for c in b:
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if c in "0123456789 mV":
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mv_recbuf += c
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else:
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mv_recbuf = ""
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if mv_recbuf[-3:] == " mV":
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v = int(mv_recbuf[:-3]) / 1000
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if v < min_v:
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min_v = v - 0.001
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if v > max_v:
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max_v = v
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# Recalculate the audio frequency to generate
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out_freq = (max_freq - min_freq) * (max_v - v) / (max_v - min_v) + min_freq
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# Generate the samples and write them to the soundcard
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sinevs = out_freq / sampling_freq * numpy.pi * 2
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sample_buf[i] = sinev
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sinev += sinevs
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sinev = sinev if sinev < numpy.pi * 2 else sinev - numpy.pi * 2
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i = (i + 1) % sample_buf_size
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if not i:
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stream.write((numpy.sin(sample_buf) * volume).astype(numpy.float32).tobytes())
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