Olá. Estou a criar um programa que permite ao usuário saber qual nota está a cantar e a sua respetiva frequência, em tempo real. No entanto, durante a atualização da janela, o programa deixa de funcionar e só atualiza ao fim de alguns segundos, acontecendo várias vezes ao longo da execução do programa. Código:
# -*- coding: cp1252 -*-
from numba import jit
import pyximport; pyximport.install()
import sys
from audiolazy import (tostream, AudioIO, freq2str, sHz, chunks, lowpass, envelope, pi, thub, Stream, maverage)
from numpy.fft import rfft
import matplotlib
import matplotlib.pyplot as plt
import ttk
import pyaudio
import pylab
import random
#-----------------------------------------------------------------------------#
#funcoes de calculo do pitch--------------------------------------------------#
#variaveis do pyaudio
f_a=440.0
chunk=2048
FORMAT=pyaudio.paInt16
CHANNELS=1
RATE=44100
RECORD_S=2.
WAVE_OUTPUT_NAME="sing.wav"
pa=pyaudio.PyAudio()
# pylab.ioff()
stream=pa.open(format=FORMAT,
channels=CHANNELS,
rate=RATE,
input=True,
frames_per_buffer=chunk)
#calcula a frequencia
def real_freq():
all_v=[]
all_data=""
x_array=numpy.array([],dtype=numpy.int16)
n_chunks=int(RECORD_S*RATE/chunk)
npts=n_chunks*chunk
for i in range(0, n_chunks):
try:
data=stream.read(chunk)
except:
data=stream.read(chunk)
all_v.append(data)
all_data += data
x=numpy.fromstring(data, dtype=numpy.int16)
numpy.append(x_array,x)
all_x=numpy.fromstring(all_data, dtype=numpy.int16)
#p2p = 2.*numpy.sqrt(2.*all_x.var())
z = abs(pylab.fft(all_x))
max_arg = numpy.argmax(z[0:npts/2])
#peak = z[max_arg]
freq = pylab.arange(npts)*1.*RATE/npts
fmax = freq[max_arg] + 0.01
fmax = round(fmax, 2)
return fmax
def limiter(sig, threshold=.1, size=256, env=envelope.rms, cutoff=pi/2048):
sig = thub(sig, 2)
return sig * Stream( 1. if el <= threshold else threshold / el for el in maverage(size)(env(sig, cutoff=cutoff)) )
@tostream
def dft_pitch(sig, size=2048, hop=None):
for blk in Stream(sig).blocks(size=size, hop=hop):
dft_data = rfft(blk)
idx, vmax = max(enumerate(dft_data), key=lambda el: abs(el[1]) / (2 * el[0] / size + 1))
yield 2 * pi * idx / size
def pitch_from_mic(upd_time_in_ms):
rate = 44100
s, Hz = sHz(rate)
api = sys.argv[1] if sys.argv[1:] else None # Choose API via command-line
chunks.size = 1 if api == "jack" else 16
with AudioIO(api) as recorder:
snd = recorder.record(rate=rate)
sndlow = lowpass(400 * Hz)(limiter(snd, cutoff=20 * Hz))
hop = int(upd_time_in_ms * 1e-3 * s)
for pitch in freq2str(dft_pitch(sndlow, size=2*hop, hop=hop) / Hz):
first_cut = pitch.find('+')
second_cut = pitch.find('-')
if ((first_cut != -1) and (second_cut == -1)):
yield pitch[0:first_cut]
elif ((first_cut == -1) and (second_cut != -1)):
yield pitch[0:second_cut]
#funcao que define a afinacao (semelhante com a funcao pitch_from_mic())
def pitch_tune(upd_time_in_ms):
#calcula o pitch
rate = 44100
s, Hz = sHz(rate)
api = sys.argv[1] if sys.argv[1:] else None # Choose API via command-line
chunks.size = 1 if api == "jack" else 16
with AudioIO(api) as recorder:
snd = recorder.record(rate=rate)
sndlow = lowpass(400 * Hz)(limiter(snd, cutoff=20 * Hz))
hop = int(upd_time_in_ms * 1e-3 * s)
#calculado o pitch, le o valor encontrado e retorna a afinacao
for tune in freq2str(dft_pitch(sndlow, size=2*hop, hop=hop) / Hz):
first_cut = tune.find('+')
second_cut = tune.find('-')
third_cut = tune.find('%')
if ((first_cut != -1) and (second_cut == -1)):
fourth_cut = tune[first_cut:third_cut]
flat_one = fourth_cut[1:]
flat_one = float(flat_one)
#le os valores e retorna a afinacao
if (flat_one <= 20):
yield 'Afinado'
elif ((flat_one > 20) and (flat_one <= 35)):
yield 'Lig. Desafinado'
elif (flat_one > 35):
yield 'Muito Desafinado'
elif ((first_cut == -1) and (second_cut != -1)):
fifth_cut = tune[second_cut:third_cut]
flat_two = fifth_cut[1:]
flat_two = float(flat_two)
#le os valores e retorna a afinacao
if (flat_two <= 20):
yield 'Afinado'
elif ((flat_two > 20) and (flat_two <= 35)):
yield 'Lig. Desafinado'
elif (flat_two > 35):
yield 'Muito Desafinado'
# ----------------------
#Parte grafica do codigo
# ----------------------
if __name__ == "__main__":
from Tkinter import *
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
import threading
import re
matplotlib.use('TkAgg')
#comeca a janela do programa
root = Tk()
#define o tamanho da janela
root.minsize(1200,500)
root.maxsize(1200,500)
root.configure(background='#d9d9d9')
root.focus_force()
#titulo da janela (outer widget)
root.title("SingMeter")
#stringvars
pitch_value = StringVar()
note_value = StringVar()
no_tone_deaf = StringVar()
#-----Frames secundaria(outer widgets)
#frame do pitch
sing_frame = LabelFrame(root, text='Informacão quantitativa', width=400, height=400, background='#d9d9d9')
sing_frame.place(x = 10, y = 30)
#frame da nota
graph_frame = LabelFrame(root, text='Gráfico', width=700, height=400, background='#d9d9d9')
graph_frame.place(x = 450, y = 30)
#listas e dicionarios de frequencias e notas (torna a base de dados propia para leitura)
database_dict = {}
freq_list = []
#funcoes do grafico-------------------------------------------------------#
xAchse=pylab.arange(0,100,1)
yAchse=pylab.array([0]*100)
fig = pylab.figure(1)
ax = fig.add_subplot(111)
ax.grid(True)
ax.set_xlabel("Tempo")
ax.set_ylabel("Frequência")
ax.axis([0,100, 50, 2000])
line1=ax.plot(xAchse,yAchse,'-')
canvas = FigureCanvasTkAgg(fig, master = graph_frame)
canvas.show()
canvas.get_tk_widget().place(x = 100, y = 50)
canvas._tkcanvas.place(x = 100, y = 25)
values=[]
values = [0 for x in range(100)]
Ta=0.01
fa=1.0/Ta
fcos=3.5
Konstant=1
T0=1.0
T1=Konstant
freq_list = []
def SinwaveformGenerator():
global values,T1,Konstant,T0,wScale2
#ohmegaCos=arccos(T1)/Ta
#print "fcos=", ohmegaCos/(2*pi), "Hz"
Tnext=((Konstant*T1)*2)-T0
if (len(values)%100>70):
try:
values.append(random.random())
except:
raise
else:
values.append(Tnext)
T0=T1
T1=Tnext
root.after(int(wScale2['to'])-wScale2.get(),SinwaveformGenerator)
def RealtimePloter():
global values,wScale,wScale2
NumberSamples=min(len(values),wScale.get())
CurrentXAxis=pylab.arange(len(values)-NumberSamples,len(values),1)
line1[0].set_data(CurrentXAxis,pylab.array(values[-NumberSamples:]))
ax.axis([CurrentXAxis.min(),CurrentXAxis.max(),50, 2000])
canvas.draw()
root.after(25,RealtimePloter)
#canvas.draw()
#manager.show()
wScale = Scale(master=root,label="View Width:", from_=3, to=1000,sliderlength=30, orient=HORIZONTAL)
wScale2 = Scale(master=root,label="Generation Speed:", from_=1, to=200,sliderlength=30, orient=HORIZONTAL)
wScale.set(100)
wScale2.set(wScale2['to']-10)
#--------------------------------------------------------------------------
#fecha a janela
def _quit():
root.quit()
root.destroy()
#funcões com elementos (inner widgets) da janela
@jit
def entries_window(pitch, note, sing_state):
#exibidor do pitch
pitch_value.set(pitch)
show_pitch = ttk.Entry(sing_frame, textvariable = pitch_value, state = 'readonly')
show_pitch.place(x = 120, y = 58.5)
#exibidor da nota
note_value.set(note)
show_note = ttk.Entry(sing_frame, textvariable = note_value, state = 'readonly')
show_note.place(x = 120, y = 135)
#exibidor da performance das notas do cantor
no_tone_deaf.set(sing_state)
show_tone_deaf = ttk.Entry(sing_frame, textvariable = no_tone_deaf, state = 'readonly')
show_tone_deaf.place(x = 170, y = 211.5)
entries_window(None, None, None)
#@jit
def window():
#labels
#label PITCH
pitch_title = ttk.Label(sing_frame, text = "Pitch:", font = "Verdana 20", background='#d9d9d9')
pitch_title.place(x = 30, y = 50)
#label NOTE
note_title = ttk.Label(sing_frame, text = "Nota:", font = "Verdana 21", background='#d9d9d9')
note_title.place(x = 30, y = 126)
#label AFINACAO
tune_title = ttk.Label(sing_frame, text = "Afinação", font = "Verdana 21", background='#d9d9d9')
tune_title.place(x = 30, y = 202)
#------------------------
#botões
#botao SAIR
record = ttk.Button(sing_frame, text = 'Sair', command=_quit)
record.place(x = 70, y = 300)
"""#botao STOP
stop_button = ttk.Button(sing_frame, text = 'Parar')
stop_button.place(x = 160, y = 300)"""
window()
regex_note = re.compile(r"^([A-Gb#]*-?[0-9]*)([?+-]?)(.*?%?)$")
upd_time_in_ms = 200
# atualiza as funcoes
def upd_value():
pitches = iter(pitch_from_mic(upd_time_in_ms))
while not root.should_finish:
root.value = next(pitches)
#atualiza os valores da janela
#@jit
def upd_timer():
note_value.set("\n".join(regex_note.findall(root.value)[0]))
tunes = iter(pitch_tune(upd_time_in_ms))
tuning = next(tunes)
no_tone_deaf.set(str("\n".join(regex_note.findall(tuning)[0])))
pitch_value.set(real_freq())
root.after(upd_time_in_ms, upd_timer)
root.after(1, SinwaveformGenerator)
root.after(1 ,RealtimePloter)
# inicia as threads
root.should_finish = False
root.value = freq2str(0)
note_value.set(root.value)
root.upd_thread = threading.Thread(target=upd_value)
#acaba o programa e as threads
root.protocol("WM_DELETE_WINDOW", _quit)
root.after_idle(upd_timer)
root.upd_thread.start()
root.mainloop()
root.should_finish = True
root.upd_thread.join()
Tentei usar o numba (from numba import jit
) e o Cython para melhorar o desempenho da execução do programa, mas não tive melhorias significativas. Tentei ainda usar o PyPy, mas devido à sua incompatibilidade com o Numpy não consegui executar o código. As funções pitch_from_mic(upd_time_in_ms)
e pitch_tune(upd_time_in_ms)
calculam a nota da mesma forma (não consegui colocar toda esta parte do código numa única função, pois dava o seguinte erro: IOError: [Errno -9981] Input overflowed
). A função real_freq()
demora algum tempo a calcular a frequência, mas, se não forem chamadas as outras funções, o código possui um desempenho aceitável. Estou a usar o Windows 7 e tenho o Python 2.7.8.