diff --git a/plugins/diopser/src/editor/analyzer.rs b/plugins/diopser/src/editor/analyzer.rs index a884409c..52378967 100644 --- a/plugins/diopser/src/editor/analyzer.rs +++ b/plugins/diopser/src/editor/analyzer.rs @@ -90,7 +90,7 @@ impl View for SpectrumAnalyzer { let line_width = cx.style.dpi_factor as f32 * 1.5; let paint = vg::Paint::color(cx.font_color().cloned().unwrap_or_default().into()) .with_line_width(line_width); - for (bin_idx, magnetude) in spectrum.iter().enumerate() { + for (bin_idx, magnitude) in spectrum.iter().enumerate() { // We'll match up the bin's x-coordinate with the filter frequency parameter let frequency = (bin_idx as f32 / spectrum.len() as f32) * nyquist; // NOTE: This takes the safe-mode switch into acocunt. When it is enabled, the range is @@ -100,11 +100,11 @@ impl View for SpectrumAnalyzer { continue; } - // Scale this so that 1.0/0 dBFS magnetude is at 80% of the height, the bars begin at + // Scale this so that 1.0/0 dBFS magnitude is at 80% of the height, the bars begin at // -80 dBFS, and that the scaling is linear - nih_debug_assert!(*magnetude >= 0.0); - let magnetude_db = nih_plug::util::gain_to_db(*magnetude); - let height = ((magnetude_db + 80.0) / 100.0).clamp(0.0, 1.0); + nih_debug_assert!(*magnitude >= 0.0); + let magnitude_db = nih_plug::util::gain_to_db(*magnitude); + let height = ((magnitude_db + 80.0) / 100.0).clamp(0.0, 1.0); let mut path = vg::Path::new(); path.move_to( diff --git a/plugins/diopser/src/spectrum.rs b/plugins/diopser/src/spectrum.rs index b54b828b..1ba70cfd 100644 --- a/plugins/diopser/src/spectrum.rs +++ b/plugins/diopser/src/spectrum.rs @@ -131,12 +131,12 @@ impl SpectrumInput { .iter() .zip(&mut self.spectrum_result_buffer) { - let magnetude = bin.norm(); - if magnetude > *spectrum_result { - *spectrum_result = magnetude; + let magnitude = bin.norm(); + if magnitude > *spectrum_result { + *spectrum_result = magnitude; } else { *spectrum_result = (*spectrum_result * self.smoothing_decay_weight) - + (magnetude * (1.0 - self.smoothing_decay_weight)); + + (magnitude * (1.0 - self.smoothing_decay_weight)); } } diff --git a/plugins/spectral_compressor/src/compressor_bank.rs b/plugins/spectral_compressor/src/compressor_bank.rs index e3209b96..28e0d916 100644 --- a/plugins/spectral_compressor/src/compressor_bank.rs +++ b/plugins/spectral_compressor/src/compressor_bank.rs @@ -646,7 +646,7 @@ impl CompressorBank { self.update_sidechain_spectra(sc_buffer, channel_idx); } - /// Update the envelope followers based on the bin magnetudes. + /// Update the envelope followers based on the bin magnitudes. fn update_envelopes( &mut self, buffer: &mut [Complex32], diff --git a/plugins/spectral_compressor/src/editor/analyzer.rs b/plugins/spectral_compressor/src/editor/analyzer.rs index 6c2630b8..c3863752 100644 --- a/plugins/spectral_compressor/src/editor/analyzer.rs +++ b/plugins/spectral_compressor/src/editor/analyzer.rs @@ -106,7 +106,7 @@ impl View for Analyzer { } /// Draw the spectrum analyzer part of the analyzer. These are drawn as vertical bars until the -/// spacing between the bars becomes less than 1 pixel, at which point it's drawn as a solid mesh +/// spacing between the bars becomes less the line width, at which point it's drawn as a solid mesh /// instead. fn draw_spectrum( cx: &mut DrawContext, @@ -118,34 +118,116 @@ fn draw_spectrum( let line_width = cx.style.dpi_factor as f32 * 1.5; let text_color: vg::Color = cx.font_color().cloned().unwrap_or_default().into(); + // This is used to draw the individual bars let spectrum_paint = vg::Paint::color(text_color).with_line_width(line_width); + // And this color is used to draw the mesh part of the spectrum. We'll create a gradient paint + // that fades from this to `text_color` when we know the mesh's x-coordinates. + let mut lighter_text_color = text_color; + lighter_text_color.r = (lighter_text_color.r + 0.25) / 1.25; + lighter_text_color.g = (lighter_text_color.g + 0.25) / 1.25; + lighter_text_color.b = (lighter_text_color.b + 0.25) / 1.25; + // The frequency belonging to a bin in Hz let bin_frequency = |bin_idx: f32| (bin_idx / analyzer_data.num_bins as f32) * nyquist_hz; + // A `[0, 1]` value indicating at which relative x-coordinate a bin should be drawn at + let bin_t = |bin_idx: f32| (bin_frequency(bin_idx).ln() - LN_40_HZ) / LN_FREQ_RANGE; + // Converts a linear magnitude value in to a `[0, 1]` value where 0 is -80 dB or lower, and 1 is + // +20 dB or higher. + let magnitude_height = |magnitude: f32| { + nih_debug_assert!(magnitude >= 0.0); + let magnitude_db = nih_plug::util::gain_to_db(magnitude); + ((magnitude_db + 80.0) / 100.0).clamp(0.0, 1.0) + }; - // TODO: Draw individual bars until the difference between the next two bars becomes less - // than one pixel. At that point draw it as a single mesh to get rid of aliasing. - for (bin_idx, magnetude) in analyzer_data.envelope_followers.iter().enumerate() { - let ln_frequency = bin_frequency(bin_idx as f32).ln(); - let t = (ln_frequency - LN_40_HZ) / LN_FREQ_RANGE; + // The first part of this drawing routing is simple. Individual bins are drawn as bars until the + // distance between the bars approaches `mesh_start_delta_threshold`. After that the rest is + // drawn as a solid mesh. + let mesh_start_delta_threshold = line_width + 0.5; + let mut mesh_bin_start_idx = analyzer_data.num_bins; + let mut previous_physical_x_coord = bounds.x - 2.0; + for (bin_idx, magnitude) in analyzer_data + .envelope_followers + .iter() + .enumerate() + .take(analyzer_data.num_bins) + { + let t = bin_t(bin_idx as f32); if t <= 0.0 || t >= 1.0 { continue; } - // Scale this so that 1.0/0 dBFS magnetude is at 80% of the height, the bars begin + let physical_x_coord = bounds.x + (bounds.w * t); + if physical_x_coord - previous_physical_x_coord < mesh_start_delta_threshold { + // NOTE: We'll draw this one bar earlier because we're not stroking the solid mesh part, + // and otherwise there would be a weird looking gap at the left side + mesh_bin_start_idx = bin_idx.saturating_sub(1); + previous_physical_x_coord = physical_x_coord; + break; + } + + // Scale this so that 1.0/0 dBFS magnitude is at 80% of the height, the bars begin // at -80 dBFS, and that the scaling is linear. This is the same scaling used in // Diopser's spectrum analyzer. - nih_debug_assert!(*magnetude >= 0.0); - let magnetude_db = nih_plug::util::gain_to_db(*magnetude); - let height = ((magnetude_db + 80.0) / 100.0).clamp(0.0, 1.0); + let height = magnitude_height(*magnitude); let mut path = vg::Path::new(); - path.move_to( - bounds.x + (bounds.w * t), - bounds.y + (bounds.h * (1.0 - height)), - ); - path.line_to(bounds.x + (bounds.w * t), bounds.y + bounds.h); + path.move_to(physical_x_coord, bounds.y + (bounds.h * (1.0 - height))); + path.line_to(physical_x_coord, bounds.y + bounds.h); canvas.stroke_path(&mut path, &spectrum_paint); + + previous_physical_x_coord = physical_x_coord; } + + // The mesh path starts at the bottom left, follows the top envelope of the spectrum analyzer, + // and ends in the bottom right + let mut mesh_path = vg::Path::new(); + let mesh_start_x_coordiante = bounds.x + (bounds.w * bin_t(mesh_bin_start_idx as f32)); + let mesh_start_y_coordinate = bounds.y + bounds.h; + + mesh_path.move_to(mesh_start_x_coordiante, mesh_start_y_coordinate); + for (bin_idx, magnitude) in analyzer_data + .envelope_followers + .iter() + .enumerate() + .take(analyzer_data.num_bins) + .skip(mesh_bin_start_idx) + { + let t = bin_t(bin_idx as f32); + if t <= 0.0 || t >= 1.0 { + continue; + } + + let physical_x_coord = bounds.x + (bounds.w * t); + previous_physical_x_coord = physical_x_coord; + let height = magnitude_height(*magnitude); + if height > 0.0 { + mesh_path.line_to( + physical_x_coord, + // This includes the line width, since this path is not stroked + bounds.y + (bounds.h * (1.0 - height) - (line_width / 2.0)).max(0.0), + ); + } else { + mesh_path.line_to(physical_x_coord, mesh_start_y_coordinate); + } + } + + mesh_path.line_to(previous_physical_x_coord, mesh_start_y_coordinate); + mesh_path.close(); + + let mesh_paint = vg::Paint::linear_gradient_stops( + mesh_start_x_coordiante, + 0.0, + previous_physical_x_coord, + 0.0, + &[ + (0.0, lighter_text_color), + (0.707, text_color), + (1.0, text_color), + ], + ) + // NOTE: This is very important, otherwise this looks all kinds of gnarly + .with_anti_alias(false); + canvas.fill_path(&mut mesh_path, &mesh_paint); } /// Overlays the gain reduction display over the spectrum analyzer. @@ -164,7 +246,12 @@ fn draw_gain_reduction( let bin_frequency = |bin_idx: f32| (bin_idx / analyzer_data.num_bins as f32) * nyquist_hz; // TODO: This should be drawn as one mesh, or multiple meshes if there are empty gain reduction bars - for (bin_idx, gain_difference_db) in analyzer_data.gain_difference_db.iter().enumerate() { + for (bin_idx, gain_difference_db) in analyzer_data + .gain_difference_db + .iter() + .enumerate() + .take(analyzer_data.num_bins) + { // TODO: Draw this as a single mesh instead, this doesn't work. // Avoid drawing tiny slivers for low gain reduction values if gain_difference_db.abs() > 0.2 {