//////////////////////////////////////////////////////////// // Headers //////////////////////////////////////////////////////////// #include #include #include #include #include #include #include #include namespace { constexpr auto windowWidth = 800u; constexpr auto windowHeight = 600u; constexpr auto pi = 3.14159265359f; constexpr auto sqrt2 = 2.0f * 0.707106781186547524401f; std::filesystem::path resourcesDir() { #ifdef SFML_SYSTEM_IOS return ""; #else return "resources"; #endif } } // namespace //////////////////////////////////////////////////////////// // Base class for effects //////////////////////////////////////////////////////////// class Effect : public sf::Drawable { public: static void setFont(const sf::Font& font) { s_font = &font; } const std::string& getName() const { return m_name; } void update(float time, float x, float y) { onUpdate(time, x, y); } void draw(sf::RenderTarget& target, sf::RenderStates states) const override { onDraw(target, states); } void start() { onStart(); } void stop() { onStop(); } void handleKey(sf::Keyboard::Key key) { onKey(key); } protected: Effect(std::string name) : m_name(std::move(name)) { } static const sf::Font& getFont() { assert(s_font != nullptr && "Cannot get font until setFont() is called"); return *s_font; } private: // Virtual functions to be implemented in derived effects virtual void onUpdate(float time, float x, float y) = 0; virtual void onDraw(sf::RenderTarget& target, sf::RenderStates states) const = 0; virtual void onStart() = 0; virtual void onStop() = 0; virtual void onKey(sf::Keyboard::Key) { } std::string m_name; // NOLINTNEXTLINE(readability-identifier-naming) static inline const sf::Font* s_font{nullptr}; }; //////////////////////////////////////////////////////////// // Surround Sound / Positional Audio Effect / Attenuation //////////////////////////////////////////////////////////// class Surround : public Effect { public: Surround() : Effect("Surround / Attenuation") { m_listener.setPosition({(windowWidth - 20.f) / 2.f, (windowHeight - 20.f) / 2.f}); m_listener.setFillColor(sf::Color::Red); // Load the music file if (!m_music.openFromFile(resourcesDir() / "doodle_pop.ogg")) std::cerr << "Failed to load " << (resourcesDir() / "doodle_pop.ogg").string() << std::endl; // Set the music to loop m_music.setLoop(true); // Set attenuation to a nice value m_music.setAttenuation(0.04f); } void onUpdate(float /*time*/, float x, float y) override { m_position = {windowWidth * x - 10.f, windowHeight * y - 10.f}; m_music.setPosition({m_position.x, m_position.y, 0.f}); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const override { auto statesCopy(states); statesCopy.transform = sf::Transform::Identity; statesCopy.transform.translate(m_position); target.draw(m_listener, states); target.draw(m_soundShape, statesCopy); } void onStart() override { // Synchronize listener audio position with graphical position sf::Listener::setPosition({m_listener.getPosition().x, m_listener.getPosition().y, 0.f}); m_music.play(); } void onStop() override { m_music.stop(); } private: sf::CircleShape m_listener{20.f}; sf::CircleShape m_soundShape{20.f}; sf::Vector2f m_position; sf::Music m_music; }; //////////////////////////////////////////////////////////// // Pitch / Volume Effect //////////////////////////////////////////////////////////// class PitchVolume : public Effect { public: PitchVolume() : Effect("Pitch / Volume"), m_pitchText(getFont(), "Pitch: " + std::to_string(m_pitch)), m_volumeText(getFont(), "Volume: " + std::to_string(m_volume)) { // Load the music file if (!m_music.openFromFile(resourcesDir() / "doodle_pop.ogg")) std::cerr << "Failed to load " << (resourcesDir() / "doodle_pop.ogg").string() << std::endl; // Set the music to loop m_music.setLoop(true); // We don't care about attenuation in this effect m_music.setAttenuation(0.f); // Set initial pitch m_music.setPitch(m_pitch); // Set initial volume m_music.setVolume(m_volume); m_pitchText.setPosition({windowWidth / 2.f - 120.f, windowHeight / 2.f - 80.f}); m_volumeText.setPosition({windowWidth / 2.f - 120.f, windowHeight / 2.f - 30.f}); } void onUpdate(float /*time*/, float x, float y) override { m_pitch = std::clamp(2.f * x, 0.f, 2.f); m_volume = std::clamp(100.f * (1.f - y), 0.f, 100.f); m_music.setPitch(m_pitch); m_music.setVolume(m_volume); m_pitchText.setString("Pitch: " + std::to_string(m_pitch)); m_volumeText.setString("Volume: " + std::to_string(m_volume)); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const override { target.draw(m_pitchText, states); target.draw(m_volumeText, states); } void onStart() override { // We set the listener position back to the default // so that the music is right on top of the listener sf::Listener::setPosition({0.f, 0.f, 0.f}); m_music.play(); } void onStop() override { m_music.stop(); } private: float m_pitch{1.f}; float m_volume{100.f}; sf::Text m_pitchText; sf::Text m_volumeText; sf::Music m_music; }; //////////////////////////////////////////////////////////// // Attenuation Effect //////////////////////////////////////////////////////////// class Attenuation : public Effect { public: Attenuation() : Effect("Attenuation"), m_text(getFont()) { m_listener.setPosition({(windowWidth - 20.f) / 2.f, (windowHeight - 20.f) / 2.f + 100.f}); m_listener.setFillColor(sf::Color::Red); m_soundShape.setFillColor(sf::Color::Magenta); // Sound cone parameters static constexpr auto coneHeight = windowHeight * 2.f; static constexpr auto outerConeAngle = sf::degrees(120.f); static constexpr auto innerConeAngle = sf::degrees(30.f); // Set common properties of both cones for (auto* cone : {&m_soundConeOuter, &m_soundConeInner}) { cone->setPointCount(3); cone->setPoint(0, {0.f, 0.f}); cone->setPosition({20.f, 20.f}); } m_soundConeOuter.setFillColor(sf::Color::Black); m_soundConeInner.setFillColor(sf::Color::Cyan); // Make each cone based on their angle and height static constexpr auto makeCone = [](auto& shape, const auto& angle) { const auto theta = sf::degrees(90.f) - (angle / 2); const auto x = coneHeight / std::tan(theta.asRadians()); shape.setPoint(1, {-x, coneHeight}); shape.setPoint(2, {x, coneHeight}); }; makeCone(m_soundConeOuter, outerConeAngle); makeCone(m_soundConeInner, innerConeAngle); // Load the music file if (!m_music.openFromFile(resourcesDir() / "doodle_pop.ogg")) std::cerr << "Failed to load " << (resourcesDir() / "doodle_pop.ogg").string() << std::endl; // Set the music to loop m_music.setLoop(true); // Set attenuation factor m_music.setAttenuation(m_attenuation); // Set direction to face "downwards" m_music.setDirection({0.f, 1.f, 0.f}); // Set cone m_music.setCone({innerConeAngle, outerConeAngle, 0.f}); m_text.setString( "Attenuation factor dampens full volume of sound while within inner cone based on distance to " "listener.\nCone outer gain determines " "volume of sound while outside outer cone.\nWhen within outer cone, volume is linearly interpolated " "between " "inner and outer volumes."); m_text.setCharacterSize(18); m_text.setPosition({20.f, 20.f}); } void onUpdate(float /*time*/, float x, float y) override { m_position = {windowWidth * x - 10.f, windowHeight * y - 10.f}; m_music.setPosition({m_position.x, m_position.y, 0.f}); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const override { auto statesCopy(states); statesCopy.transform = sf::Transform::Identity; statesCopy.transform.translate(m_position); target.draw(m_soundConeOuter, statesCopy); target.draw(m_soundConeInner, statesCopy); target.draw(m_soundShape, statesCopy); target.draw(m_listener, states); target.draw(m_text, states); } void onStart() override { // Synchronize listener audio position with graphical position sf::Listener::setPosition({m_listener.getPosition().x, m_listener.getPosition().y, 0.f}); m_music.play(); } void onStop() override { m_music.stop(); } private: sf::CircleShape m_listener{20.f}; sf::CircleShape m_soundShape{20.f}; sf::ConvexShape m_soundConeOuter; sf::ConvexShape m_soundConeInner; sf::Text m_text; sf::Vector2f m_position; sf::Music m_music; float m_attenuation{0.01f}; }; //////////////////////////////////////////////////////////// // Tone Generator //////////////////////////////////////////////////////////// class Tone : public sf::SoundStream, public Effect { public: Tone() : Effect("Tone Generator"), m_instruction(getFont(), "Press up and down arrows to change the current wave type"), m_currentType(getFont(), "Wave Type: Triangle"), m_currentAmplitude(getFont(), "Amplitude: 0.05"), m_currentFrequency(getFont(), "Frequency: 200 Hz") { m_instruction.setPosition({windowWidth / 2.f - 370.f, windowHeight / 2.f - 200.f}); m_currentType.setPosition({windowWidth / 2.f - 150.f, windowHeight / 2.f - 100.f}); m_currentAmplitude.setPosition({windowWidth / 2.f - 150.f, windowHeight / 2.f - 50.f}); m_currentFrequency.setPosition({windowWidth / 2.f - 150.f, windowHeight / 2.f}); sf::SoundStream::initialize(1, sampleRate, {sf::SoundChannel::Mono}); } void onUpdate(float /*time*/, float x, float y) override { m_amplitude = std::clamp(0.2f * (1.f - y), 0.f, 0.2f); m_frequency = std::clamp(500.f * x, 0.f, 500.f); m_currentAmplitude.setString("Amplitude: " + std::to_string(m_amplitude)); m_currentFrequency.setString("Frequency: " + std::to_string(m_frequency) + " Hz"); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const override { target.draw(m_instruction, states); target.draw(m_currentType, states); target.draw(m_currentAmplitude, states); target.draw(m_currentFrequency, states); } void onStart() override { // We set the listener position back to the default // so that the tone is right on top of the listener sf::Listener::setPosition({0.f, 0.f, 0.f}); play(); } void onStop() override { SoundStream::stop(); } void onKey(sf::Keyboard::Key key) override { auto ticks = 0; if (key == sf::Keyboard::Key::Down) ticks = 1; // Forward else if (key == sf::Keyboard::Key::Up) ticks = 3; // Reverse while (ticks--) { switch (m_type) { case Type::Sine: m_type = Type::Square; m_currentType.setString("Wave Type: Square"); break; case Type::Square: m_type = Type::Triangle; m_currentType.setString("Wave Type: Triangle"); break; case Type::Triangle: m_type = Type::Sawtooth; m_currentType.setString("Wave Type: Sawtooth"); break; case Type::Sawtooth: m_type = Type::Sine; m_currentType.setString("Wave Type: Sine"); break; } } } private: bool onGetData(sf::SoundStream::Chunk& chunk) override { const auto period = 1.f / m_frequency; for (auto i = 0u; i < chunkSize; ++i) { auto value = 0.f; switch (m_type) { case Type::Sine: { value = m_amplitude * std::sin(2 * pi * m_frequency * m_time); break; } case Type::Square: { value = m_amplitude * (2 * (2 * std::floor(m_frequency * m_time) - std::floor(2 * m_frequency * m_time)) + 1); break; } case Type::Triangle: { value = 4 * m_amplitude / period * std::abs(std::fmod(((std::fmod((m_time - period / 4), period)) + period), period) - period / 2) - m_amplitude; break; } case Type::Sawtooth: { value = m_amplitude * 2 * (m_time / period - std::floor(0.5f + m_time / period)); break; } } m_sampleBuffer[i] = static_cast(std::lround(value * std::numeric_limits::max())); m_time += timePerSample; } chunk.sampleCount = chunkSize; chunk.samples = m_sampleBuffer.data(); return true; } void onSeek(sf::Time) override { // It doesn't make sense to seek in a tone generator } enum class Type { Sine, Square, Triangle, Sawtooth }; static constexpr unsigned int sampleRate{44100}; static constexpr std::size_t chunkSize{sampleRate / 100}; static constexpr float timePerSample{1.f / static_cast(sampleRate)}; std::vector m_sampleBuffer = std::vector(chunkSize, 0); Type m_type{Type::Triangle}; float m_amplitude{0.05f}; float m_frequency{220}; float m_time{}; sf::Text m_instruction; sf::Text m_currentType; sf::Text m_currentAmplitude; sf::Text m_currentFrequency; }; //////////////////////////////////////////////////////////// // Dopper Shift Effect //////////////////////////////////////////////////////////// class Doppler : public sf::SoundStream, public Effect { public: Doppler() : Effect("Doppler Shift"), m_currentVelocity(getFont(), "Velocity: " + std::to_string(m_velocity)), m_currentFactor(getFont(), "Doppler Factor: " + std::to_string(m_factor)) { m_listener.setPosition({(windowWidth - 20.f) / 2.f, (windowHeight - 20.f) / 2.f}); m_listener.setFillColor(sf::Color::Red); m_position.y = (windowHeight - 20.f) / 2.f - 40.f; m_currentVelocity.setPosition({windowWidth / 2.f - 150.f, windowHeight * 3.f / 4.f - 50.f}); m_currentFactor.setPosition({windowWidth / 2.f - 150.f, windowHeight * 3.f / 4.f}); // Set attenuation to a nice value setAttenuation(0.05f); sf::SoundStream::initialize(1, sampleRate, {sf::SoundChannel::Mono}); } void onUpdate(float time, float x, float y) override { m_velocity = std::clamp(150.f * (1.f - y), 0.f, 150.f); m_factor = std::clamp(x, 0.f, 1.f); m_currentVelocity.setString("Velocity: " + std::to_string(m_velocity)); m_currentFactor.setString("Doppler Factor: " + std::to_string(m_factor)); m_position.x = std::fmod(time, 8.f) * windowWidth / 8.f; setPosition({m_position.x, m_position.y, 0.f}); setVelocity({m_velocity, 0.f, 0.f}); setDopplerFactor(m_factor); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const override { auto statesCopy(states); statesCopy.transform = sf::Transform::Identity; statesCopy.transform.translate(m_position - sf::Vector2f({20.f, 0.f})); target.draw(m_listener, states); target.draw(m_soundShape, statesCopy); target.draw(m_currentVelocity, states); target.draw(m_currentFactor, states); } void onStart() override { // Synchronize listener audio position with graphical position sf::Listener::setPosition({m_listener.getPosition().x, m_listener.getPosition().y, 0.f}); play(); } void onStop() override { SoundStream::stop(); } private: bool onGetData(sf::SoundStream::Chunk& chunk) override { const auto period = 1.f / m_frequency; for (auto i = 0u; i < chunkSize; ++i) { const auto value = m_amplitude * 2 * (m_time / period - std::floor(0.5f + m_time / period)); m_sampleBuffer[i] = static_cast(std::lround(value * std::numeric_limits::max())); m_time += timePerSample; } chunk.sampleCount = chunkSize; chunk.samples = m_sampleBuffer.data(); return true; } void onSeek(sf::Time) override { // It doesn't make sense to seek in a tone generator } static constexpr unsigned int sampleRate{44100}; static constexpr std::size_t chunkSize{sampleRate / 100}; static constexpr float timePerSample{1.f / static_cast(sampleRate)}; std::vector m_sampleBuffer = std::vector(chunkSize, 0); float m_amplitude{0.05f}; float m_frequency{220}; float m_time{}; float m_velocity{0.f}; float m_factor{1.f}; sf::CircleShape m_listener{20.f}; sf::CircleShape m_soundShape{20.f}; sf::Vector2f m_position; sf::Text m_currentVelocity; sf::Text m_currentFactor; }; //////////////////////////////////////////////////////////// // Processing base class //////////////////////////////////////////////////////////// class Processing : public Effect { public: void onUpdate([[maybe_unused]] float time, float x, float y) override { m_position = {windowWidth * x - 10.f, windowHeight * y - 10.f}; m_music.setPosition({m_position.x, m_position.y, 0.f}); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const override { auto statesCopy(states); statesCopy.transform = sf::Transform::Identity; statesCopy.transform.translate(m_position); target.draw(m_listener, states); target.draw(m_soundShape, statesCopy); target.draw(m_enabledText); target.draw(m_instructions); } void onStart() override { // Synchronize listener audio position with graphical position sf::Listener::setPosition({m_listener.getPosition().x, m_listener.getPosition().y, 0.f}); m_music.play(); } void onStop() override { m_music.stop(); } protected: Processing(std::string name) : Effect(std::move(name)), m_enabledText(getFont(), "Processing: Enabled"), m_instructions(getFont(), "Press Space to enable/disable processing") { m_listener.setPosition({(windowWidth - 20.f) / 2.f, (windowHeight - 20.f) / 2.f}); m_listener.setFillColor(sf::Color::Red); m_enabledText.setPosition({windowWidth / 2.f - 120.f, windowHeight * 3.f / 4.f - 50.f}); m_instructions.setPosition({windowWidth / 2.f - 250.f, windowHeight * 3.f / 4.f}); // Load the music file if (!m_music.openFromFile(resourcesDir() / "doodle_pop.ogg")) std::cerr << "Failed to load " << (resourcesDir() / "doodle_pop.ogg").string() << std::endl; // Set the music to loop m_music.setLoop(true); // Set attenuation to a nice value m_music.setAttenuation(0.0f); } sf::Music& getMusic() { return m_music; } const std::shared_ptr& getEnabled() const { return m_enabled; } private: void onKey(sf::Keyboard::Key key) override { if (key == sf::Keyboard::Key::Space) *m_enabled = !*m_enabled; m_enabledText.setString(*m_enabled ? "Processing: Enabled" : "Processing: Disabled"); } sf::CircleShape m_listener{20.f}; sf::CircleShape m_soundShape{20.f}; sf::Vector2f m_position; sf::Music m_music; std::shared_ptr m_enabled{std::make_shared(true)}; sf::Text m_enabledText; sf::Text m_instructions; }; //////////////////////////////////////////////////////////// // Biquad Filter (https://github.com/dimtass/DSP-Cpp-filters) //////////////////////////////////////////////////////////// class BiquadFilter : public Processing { protected: struct Coefficients { float a0{}; float a1{}; float a2{}; float b1{}; float b2{}; float c0{}; float d0{}; }; using Processing::Processing; void setCoefficients(const Coefficients& coefficients) { auto& music = getMusic(); struct State { float xnz1{}; float xnz2{}; float ynz1{}; float ynz2{}; }; // We use a mutable lambda to tie the lifetime of the state and coefficients to the lambda itself // This is necessary since the Echo object will be destroyed before the Music object // While the Music object exists, it is possible that the audio engine will try to call // this lambda hence we need to always have usable coefficients and state until the Music and the // associated lambda are destroyed music.setEffectProcessor( [coefficients, enabled = getEnabled(), state = std::vector(music.getChannelCount())](const float* inputFrames, unsigned int& inputFrameCount, float* outputFrames, unsigned int& outputFrameCount, unsigned int frameChannelCount) mutable { for (auto frame = 0u; frame < outputFrameCount; ++frame) { for (auto channel = 0u; channel < frameChannelCount; ++channel) { auto& channelState = state[channel]; const auto xn = inputFrames ? inputFrames[channel] : 0.f; // Read silence if no input data available const auto yn = coefficients.a0 * xn + coefficients.a1 * channelState.xnz1 + coefficients.a2 * channelState.xnz2 - coefficients.b1 * channelState.ynz1 - coefficients.b2 * channelState.ynz2; channelState.xnz2 = channelState.xnz1; channelState.xnz1 = xn; channelState.ynz2 = channelState.ynz1; channelState.ynz1 = yn; outputFrames[channel] = *enabled ? yn : xn; } inputFrames += (inputFrames ? frameChannelCount : 0u); outputFrames += frameChannelCount; } // We processed data 1:1 inputFrameCount = outputFrameCount; }); } }; //////////////////////////////////////////////////////////// // High-pass Filter (https://github.com/dimtass/DSP-Cpp-filters) //////////////////////////////////////////////////////////// struct HighPassFilter : BiquadFilter { HighPassFilter() : BiquadFilter("High-pass Filter") { static constexpr auto cutoffFrequency = 2000.f; const auto c = std::tan(pi * cutoffFrequency / static_cast(getMusic().getSampleRate())); Coefficients coefficients; coefficients.a0 = 1.f / (1.f + sqrt2 * c + std::pow(c, 2.f)); coefficients.a1 = -2.f * coefficients.a0; coefficients.a2 = coefficients.a0; coefficients.b1 = 2.f * coefficients.a0 * (std::pow(c, 2.f) - 1.f); coefficients.b2 = coefficients.a0 * (1.f - sqrt2 * c + std::pow(c, 2.f)); setCoefficients(coefficients); } }; //////////////////////////////////////////////////////////// // Low-pass Filter (https://github.com/dimtass/DSP-Cpp-filters) //////////////////////////////////////////////////////////// struct LowPassFilter : BiquadFilter { LowPassFilter() : BiquadFilter("Low-pass Filter") { static constexpr auto cutoffFrequency = 500.f; const auto c = 1.f / std::tan(pi * cutoffFrequency / static_cast(getMusic().getSampleRate())); Coefficients coefficients; coefficients.a0 = 1.f / (1.f + sqrt2 * c + std::pow(c, 2.f)); coefficients.a1 = 2.f * coefficients.a0; coefficients.a2 = coefficients.a0; coefficients.b1 = 2.f * coefficients.a0 * (1.f - std::pow(c, 2.f)); coefficients.b2 = coefficients.a0 * (1.f - sqrt2 * c + std::pow(c, 2.f)); setCoefficients(coefficients); } }; //////////////////////////////////////////////////////////// // Echo (miniaudio implementation) //////////////////////////////////////////////////////////// struct Echo : Processing { Echo() : Processing("Echo") { auto& music = getMusic(); static constexpr auto delay = 0.2f; static constexpr auto decay = 0.75f; static constexpr auto wet = 0.8f; static constexpr auto dry = 1.f; const auto channelCount = music.getChannelCount(); const auto sampleRate = music.getSampleRate(); const auto delayInFrames = static_cast(static_cast(sampleRate) * delay); // We use a mutable lambda to tie the lifetime of the state to the lambda itself // This is necessary since the Echo object will be destroyed before the Music object // While the Music object exists, it is possible that the audio engine will try to call // this lambda hence we need to always have a usable state until the Music and the // associated lambda are destroyed music.setEffectProcessor( [delayInFrames, enabled = getEnabled(), buffer = std::vector(delayInFrames * channelCount, 0.f), cursor = 0u](const float* inputFrames, unsigned int& inputFrameCount, float* outputFrames, unsigned int& outputFrameCount, unsigned int frameChannelCount) mutable { for (auto frame = 0u; frame < outputFrameCount; ++frame) { for (auto channel = 0u; channel < frameChannelCount; ++channel) { const auto input = inputFrames ? inputFrames[channel] : 0.f; // Read silence if no input data available const auto bufferIndex = (cursor * frameChannelCount) + channel; buffer[bufferIndex] = (buffer[bufferIndex] * decay) + (input * dry); outputFrames[channel] = *enabled ? buffer[bufferIndex] * wet : input; } cursor = (cursor + 1) % delayInFrames; inputFrames += (inputFrames ? frameChannelCount : 0u); outputFrames += frameChannelCount; } // We processed data 1:1 inputFrameCount = outputFrameCount; }); } }; //////////////////////////////////////////////////////////// // Reverb (https://github.com/sellicott/DSP-FFMpeg-Reverb) //////////////////////////////////////////////////////////// class Reverb : public Processing { public: Reverb() : Processing("Reverb") { auto& music = getMusic(); static constexpr auto sustain = 0.7f; // [0.f; 1.f] const auto channelCount = music.getChannelCount(); const auto sampleRate = music.getSampleRate(); std::vector> filters; filters.reserve(channelCount); for (auto i = 0u; i < channelCount; ++i) filters.emplace_back(sampleRate, sustain); // We use a mutable lambda to tie the lifetime of the state to the lambda itself // This is necessary since the Echo object will be destroyed before the Music object // While the Music object exists, it is possible that the audio engine will try to call // this lambda hence we need to always have a usable state until the Music and the // associated lambda are destroyed music.setEffectProcessor( [filters, enabled = getEnabled()](const float* inputFrames, unsigned int& inputFrameCount, float* outputFrames, unsigned int& outputFrameCount, unsigned int frameChannelCount) mutable { for (auto frame = 0u; frame < outputFrameCount; ++frame) { for (auto channel = 0u; channel < frameChannelCount; ++channel) { const auto input = inputFrames ? inputFrames[channel] : 0.f; // Read silence if no input data available outputFrames[channel] = *enabled ? filters[channel](input) : input; } inputFrames += (inputFrames ? frameChannelCount : 0u); outputFrames += frameChannelCount; } // We processed data 1:1 inputFrameCount = outputFrameCount; }); } private: template class AllPassFilter { public: AllPassFilter(std::size_t delay, float theGain) : m_buffer(delay, {}), m_gain(theGain) { } T operator()(T input) { const auto output = m_buffer[m_cursor]; input = static_cast(input + m_gain * output); m_buffer[m_cursor] = input; m_cursor = (m_cursor + 1) % m_buffer.size(); return static_cast(-m_gain * input + output); } private: std::vector m_buffer; std::size_t m_cursor{}; const float m_gain{}; }; template class FIRFilter { public: FIRFilter(std::vector taps) : m_taps(std::move(taps)) { } T operator()(T input) { m_buffer[m_cursor] = input; m_cursor = (m_cursor + 1) % m_buffer.size(); T output{}; for (auto i = 0u; i < m_taps.size(); ++i) output += static_cast(m_taps[i] * m_buffer[(m_cursor + i) % m_buffer.size()]); return output; } private: const std::vector m_taps; std::vector m_buffer = std::vector(m_taps.size(), {}); std::size_t m_cursor{}; }; template class ReverbFilter { public: ReverbFilter(unsigned int sampleRate, float feedbackGain) : m_allPass{{sampleRate / 10, 0.6f}, {sampleRate / 30, -0.6f}, {sampleRate / 90, 0.6f}, {sampleRate / 270, -0.6f}}, m_fir({0.003369f, 0.002810f, 0.001758f, 0.000340f, -0.001255f, -0.002793f, -0.004014f, -0.004659f, -0.004516f, -0.003464f, -0.001514f, 0.001148f, 0.004157f, 0.006986f, 0.009003f, 0.009571f, 0.008173f, 0.004560f, -0.001120f, -0.008222f, -0.015581f, -0.021579f, -0.024323f, -0.021933f, -0.012904f, 0.003500f, 0.026890f, 0.055537f, 0.086377f, 0.115331f, 0.137960f, 0.150407f, 0.150407f, 0.137960f, 0.115331f, 0.086377f, 0.055537f, 0.026890f, 0.003500f, -0.012904f, -0.021933f, -0.024323f, -0.021579f, -0.015581f, -0.008222f, -0.001120f, 0.004560f, 0.008173f, 0.009571f, 0.009003f, 0.006986f, 0.004157f, 0.001148f, -0.001514f, -0.003464f, -0.004516f, -0.004659f, -0.004014f, -0.002793f, -0.001255f, 0.000340f, 0.001758f, 0.002810f, 0.003369f}), m_buffer(sampleRate / 5, {}), // sample rate / 5 = 200ms buffer size m_feedbackGain(feedbackGain) { } T operator()(T input) { auto output = static_cast(0.7f * input + m_feedbackGain * m_buffer[m_cursor]); for (auto& f : m_allPass) output = f(output); output = m_fir(output); m_buffer[m_cursor] = output; m_cursor = (m_cursor + 1) % m_buffer.size(); output += 0.5f * m_buffer[(m_cursor + 1 * m_interval - 1) % m_buffer.size()]; output += 0.25f * m_buffer[(m_cursor + 2 * m_interval - 1) % m_buffer.size()]; output += 0.125f * m_buffer[(m_cursor + 3 * m_interval - 1) % m_buffer.size()]; return 0.6f * output + input; } private: AllPassFilter m_allPass[4]; FIRFilter m_fir; std::vector m_buffer; std::size_t m_cursor{}; const std::size_t m_interval{m_buffer.size() / 3}; const float m_feedbackGain{}; }; }; //////////////////////////////////////////////////////////// /// Entry point of application /// /// \return Application exit code /// //////////////////////////////////////////////////////////// int main() { // Create the main window sf::RenderWindow window(sf::VideoMode({windowWidth, windowHeight}), "SFML Sound Effects", sf::Style::Titlebar | sf::Style::Close); window.setVerticalSyncEnabled(true); // Load the application font and pass it to the Effect class const auto font = sf::Font::loadFromFile(resourcesDir() / "tuffy.ttf").value(); Effect::setFont(font); // Create the effects Surround surroundEffect; PitchVolume pitchVolumeEffect; Attenuation attenuationEffect; Tone toneEffect; Doppler dopplerEffect; HighPassFilter highPassFilterEffect; LowPassFilter lowPassFilterEffect; Echo echoEffect; Reverb reverbEffect; const std::array effects{&surroundEffect, &pitchVolumeEffect, &attenuationEffect, &toneEffect, &dopplerEffect, &highPassFilterEffect, &lowPassFilterEffect, &echoEffect, &reverbEffect}; std::size_t current = 0; effects[current]->start(); // Create the messages background sf::Texture textBackgroundTexture; if (!textBackgroundTexture.loadFromFile(resourcesDir() / "text-background.png")) return EXIT_FAILURE; sf::Sprite textBackground(textBackgroundTexture); textBackground.setPosition({0.f, 520.f}); textBackground.setColor(sf::Color(255, 255, 255, 200)); // Create the description text sf::Text description(font, "Current effect: " + effects[current]->getName(), 20); description.setPosition({10.f, 530.f}); description.setFillColor(sf::Color(80, 80, 80)); // Create the instructions text sf::Text instructions(font, "Press left and right arrows to change the current effect", 20); instructions.setPosition({280.f, 555.f}); instructions.setFillColor(sf::Color(80, 80, 80)); // Start the game loop const sf::Clock clock; while (window.isOpen()) { // Process events while (const auto event = window.pollEvent()) { // Close window: exit if (event.is()) window.close(); if (const auto* keyPressed = event.getIf()) { switch (keyPressed->code) { // Escape key: exit case sf::Keyboard::Key::Escape: window.close(); break; // Left arrow key: previous effect case sf::Keyboard::Key::Left: effects[current]->stop(); if (current == 0) current = effects.size() - 1; else --current; effects[current]->start(); description.setString("Current effect: " + effects[current]->getName()); break; // Right arrow key: next effect case sf::Keyboard::Key::Right: effects[current]->stop(); if (current == effects.size() - 1) current = 0; else ++current; effects[current]->start(); description.setString("Current effect: " + effects[current]->getName()); break; default: effects[current]->handleKey(keyPressed->code); break; } } } // Update the current example const auto [x, y] = sf::Vector2f(sf::Mouse::getPosition(window)).cwiseDiv(sf::Vector2f(window.getSize())); effects[current]->update(clock.getElapsedTime().asSeconds(), x, y); // Clear the window window.clear(sf::Color(50, 50, 50)); // Draw the current example window.draw(*effects[current]); // Draw the text window.draw(textBackground); window.draw(instructions); window.draw(description); // Finally, display the rendered frame on screen window.display(); } // Stop effect so that tone generators don't have to keep generating data while being destroyed effects[current]->stop(); }