add visualizer_sample_multiplier config option

[ncmpcpp.git] / src / visualizer.cpp

/***************************************************************************
 *   Copyright (C) 2008-2014 by Andrzej Rybczak                            *
 *   electricityispower@gmail.com                                          *
 *                                                                         *
 *   This program is free software; you can redistribute it and/or modify  *
 *   it under the terms of the GNU General Public License as published by  *
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 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the         *
 *   GNU General Public License for more details.                          *
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#include "visualizer.h"

#ifdef ENABLE_VISUALIZER

#include <cerrno>
#include <cmath>
#include <cstring>
#include <fstream>
#include <limits>
#include <fcntl.h>

#include "global.h"
#include "settings.h"
#include "status.h"
#include "statusbar.h"
#include "title.h"
#include "screen_switcher.h"
#include "status.h"

using Global::MainStartY;
using Global::MainHeight;

Visualizer *myVisualizer;

namespace {

const int fps = 25;

}

Visualizer::Visualizer()
: Screen(NC::Window(0, MainStartY, COLS, MainHeight, "", Config.visualizer_color, NC::Border::None))
{
        ResetFD();
        m_samples = 44100/fps;
        if (Config.visualizer_in_stereo)
                m_samples *= 2;
#       ifdef HAVE_FFTW3_H
        m_fftw_results = m_samples/2+1;
        m_freq_magnitudes = new double[m_fftw_results];
        m_fftw_input = static_cast<double *>(fftw_malloc(sizeof(double)*m_samples));
        m_fftw_output = static_cast<fftw_complex *>(fftw_malloc(sizeof(fftw_complex)*m_fftw_results));
        m_fftw_plan = fftw_plan_dft_r2c_1d(m_samples, m_fftw_input, m_fftw_output, FFTW_ESTIMATE);
#       endif // HAVE_FFTW3_H
}

void Visualizer::switchTo()
{
        SwitchTo::execute(this);
        w.clear();
        SetFD();
        m_timer = boost::posix_time::from_time_t(0);
        drawHeader();
}

void Visualizer::resize()
{
        size_t x_offset, width;
        getWindowResizeParams(x_offset, width);
        w.resize(width, MainHeight);
        w.moveTo(x_offset, MainStartY);
        hasToBeResized = 0;
}

std::wstring Visualizer::title()
{
        return L"Music visualizer";
}

void Visualizer::update()
{
        if (m_fifo < 0)
                return;
        
        // PCM in format 44100:16:1 (for mono visualization) and 44100:16:2 (for stereo visualization) is supported
        int16_t buf[m_samples];
        ssize_t data = read(m_fifo, buf, sizeof(buf));
        if (data < 0) // no data available in fifo
                return;
        
        if (m_output_id != -1 && Global::Timer - m_timer > Config.visualizer_sync_interval)
        {
                Mpd.DisableOutput(m_output_id);
                usleep(50000);
                Mpd.EnableOutput(m_output_id);
                m_timer = Global::Timer;
        }
        
        void (Visualizer::*draw)(int16_t *, ssize_t, size_t, size_t);
#       ifdef HAVE_FFTW3_H
        if (!Config.visualizer_use_wave)
                draw = &Visualizer::DrawFrequencySpectrum;
        else
#       endif // HAVE_FFTW3_H
                draw = &Visualizer::DrawSoundWave;

        const ssize_t samples_read = data/sizeof(int16_t);
        std::for_each(buf, buf+samples_read, [](int16_t &sample) {
                int32_t tmp = sample * Config.visualizer_sample_multiplier;
                if (tmp < std::numeric_limits<int16_t>::min())
                        sample = std::numeric_limits<int16_t>::min();
                else if (tmp > std::numeric_limits<int16_t>::max())
                        sample = std::numeric_limits<int16_t>::max();
                else
                        sample = tmp;
        });

        w.clear();
        if (Config.visualizer_in_stereo)
        {
                int16_t buf_left[samples_read/2], buf_right[samples_read/2];
                for (ssize_t i = 0, j = 0; i < samples_read; i += 2, ++j)
                {
                        buf_left[j] = buf[i];
                        buf_right[j] = buf[i+1];
                }
                size_t half_height = MainHeight/2;
                (this->*draw)(buf_left, samples_read/2, 0, half_height);
                (this->*draw)(buf_right, samples_read/2, half_height+(draw == &Visualizer::DrawSoundWave ? 1 : 0), half_height+(draw != &Visualizer::DrawSoundWave ? 1 : 0));
        }
        else
                (this->*draw)(buf, samples_read, 0, MainHeight);
        w.refresh();
}

int Visualizer::windowTimeout()
{
        if (m_fifo >= 0 && Status::State::player() == MPD::psPlay)
                return 1000/fps;
        else
                return Screen<WindowType>::windowTimeout();
}

void Visualizer::spacePressed()
{
#       ifdef HAVE_FFTW3_H
        Config.visualizer_use_wave = !Config.visualizer_use_wave;
        Statusbar::printf("Visualization type: %1%",
                Config.visualizer_use_wave ? "sound wave" : "frequency spectrum"
        );
#       endif // HAVE_FFTW3_H
}

void Visualizer::DrawSoundWave(int16_t *buf, ssize_t samples, size_t y_offset, size_t height)
{
        const int samples_per_col = samples/w.getWidth();
        const int half_height = height/2;
        double prev_point_pos = 0;
        const size_t win_width = w.getWidth();
        for (size_t i = 0; i < win_width; ++i)
        {
                double point_pos = 0;
                for (int j = 0; j < samples_per_col; ++j)
                        point_pos += buf[i*samples_per_col+j];
                point_pos /= samples_per_col;
                point_pos /= std::numeric_limits<int16_t>::max();
                point_pos *= half_height;
                w << NC::XY(i, y_offset+half_height+point_pos) << Config.visualizer_chars[0];
                if (i && abs(prev_point_pos-point_pos) > 2)
                {
                        // if gap is too big. intermediate values are needed
                        // since without them all we see are blinking points
                        const int breakpoint = std::max(prev_point_pos, point_pos);
                        const int half = (prev_point_pos+point_pos)/2;
                        for (int k = std::min(prev_point_pos, point_pos)+1; k < breakpoint; k += 2)
                                w << NC::XY(i-(k < half), y_offset+half_height+k) << Config.visualizer_chars[0];
                }
                prev_point_pos = point_pos;
        }
}

#ifdef HAVE_FFTW3_H
void Visualizer::DrawFrequencySpectrum(int16_t *buf, ssize_t samples, size_t y_offset, size_t height)
{
        for (unsigned i = 0, j = 0; i < m_samples; ++i)
        {
                if (j < samples)
                        m_fftw_input[i] = buf[j++];
                else
                        m_fftw_input[i] = 0;
        }
        
        fftw_execute(m_fftw_plan);
        
        // count magnitude of each frequency and scale it to fit the screen
        for (unsigned i = 0; i < m_fftw_results; ++i)
                m_freq_magnitudes[i] = sqrt(m_fftw_output[i][0]*m_fftw_output[i][0] + m_fftw_output[i][1]*m_fftw_output[i][1])/1e5*height;
        
        const size_t win_width = w.getWidth();
        // cut bandwidth a little to achieve better look
        const int freqs_per_col = m_fftw_results/win_width * 7/10;
        double bar_height;
        size_t bar_real_height;
        for (size_t i = 0; i < win_width; ++i)
        {
                bar_height = 0;
                for (int j = 0; j < freqs_per_col; ++j)
                        bar_height += m_freq_magnitudes[i*freqs_per_col+j];
                // buff higher frequencies
                bar_height *= log2(2 + i);
                // moderately normalize the heights
                bar_height = pow(bar_height, 0.6);
                bar_real_height = std::min(size_t(bar_height/freqs_per_col), height);
                const size_t start_y = y_offset > 0 ? y_offset : height-bar_real_height;
                const size_t stop_y = std::min(bar_real_height+start_y, w.getHeight());
                for (size_t j = start_y; j < stop_y; ++j)
                        w << NC::XY(i, j) << Config.visualizer_chars[1];
        }
}
#endif // HAVE_FFTW3_H

void Visualizer::SetFD()
{
        if (m_fifo < 0 && (m_fifo = open(Config.visualizer_fifo_path.c_str(), O_RDONLY | O_NONBLOCK)) < 0)
                Statusbar::printf("Couldn't open \"%1%\" for reading PCM data: %2%",
                        Config.visualizer_fifo_path, strerror(errno)
                );
}

void Visualizer::ResetFD()
{
        m_fifo = -1;
}

void Visualizer::FindOutputID()
{
        m_output_id = -1;
        if (!Config.visualizer_output_name.empty())
        {
                size_t idx = 0;
                Mpd.GetOutputs([this, &idx](MPD::Output output) {
                        if (output.name() == Config.visualizer_output_name)
                                m_output_id = idx;
                        ++idx;
                });
                if (m_output_id == -1)
                        Statusbar::printf("There is no output named \"%s\"", Config.visualizer_output_name);
        }
}

#endif // ENABLE_VISUALIZER