//! Convenience functions for formatting and parsing parameter values in various common formats. //! //! Functions prefixed with `v2s_` are meant to be used with the `.value_to_string()` parameter //! functions, while the `s2v_` functions are meant to be used wit the `.string_to_value()`. //! functions. Most of these formatters come as a pair. Check each formatter's documentation for any //! additional usage information. use std::cmp::Ordering; use std::sync::Arc; use crate::util; // TODO: The v2s and s2v naming convention isn't ideal, but at least it's unambiguous. Is there a // better way to name these functions? Should we just split this up into two modules? /// Round an `f32` value to always have a specific number of decimal digits. pub fn v2s_f32_rounded(digits: usize) -> Arc String + Send + Sync> { Arc::new(move |value| format!("{:.digits$}", value)) } /// Format a `[0, 1]` number as a percentage. Does not include the percent sign, you should specify /// this as the parameter's unit. pub fn v2s_f32_percentage(digits: usize) -> Arc String + Send + Sync> { Arc::new(move |value| format!("{:.digits$}", value * 100.0)) } /// Parse a `[0, 100]` percentage to a `[0, 1]` number. Handles the percentage unit for you. Used in /// conjunction with [`v2s_f32_percentage()`]. pub fn s2v_f32_percentage() -> Arc Option + Send + Sync> { Arc::new(|string| { string .trim_end_matches(&[' ', '%']) .parse() .ok() .map(|x: f32| x / 100.0) }) } /// Format a positive number as a compression ratio. A value of 4 will be formatted as `4.0:1` while /// 0.25 is formatted as `1:4.0`. pub fn v2s_compression_ratio(digits: usize) -> Arc String + Send + Sync> { Arc::new(move |value| { if value >= 1.0 { format!("{:.digits$}:1", value) } else { format!("1:{:.digits$}", value.recip()) } }) } /// Parse a `x:y` compression ratio back to a floating point number. Used in conjunction with /// [`v2s_compression_ratio()`]. Plain numbers are parsed directly for UX's sake. pub fn s2v_compression_ratio() -> Arc Option + Send + Sync> { Arc::new(|string| { let string = string.trim(); string .trim() .split_once(':') .and_then(|(numerator, denominator)| { let numerator: f32 = numerator.trim().parse().ok()?; let denominator: f32 = denominator.trim().parse().ok()?; Some(numerator / denominator) }) // Just parse the value directly if it doesn't contain a colon .or_else(|| string.parse().ok()) }) } /// Turn an `f32` value from voltage gain to decibels using the semantics described in /// [`util::gain_to_db()]. You should use either `" dB"` or `" dBFS"` for the parameter's unit. pub fn v2s_f32_gain_to_db(digits: usize) -> Arc String + Send + Sync> { Arc::new(move |value| { // Never print -0.0 since that just looks weird and confusing let value_db = util::gain_to_db(value); let value_db = if value_db.abs() < 1e-6 { 0.0 } else { value_db }; format!("{:.digits$}", value_db) }) } /// Parse a decibel value to a linear voltage gain ratio. Handles the `dB` or `dBFS` units for you. /// Used in conjunction with [`v2s_f32_gain_to_db()`]. pub fn s2v_f32_gain_to_db() -> Arc Option + Send + Sync> { Arc::new(|string| { string .trim_end_matches(&[' ', 'd', 'D', 'b', 'B', 'f', 'F', 's', 'S']) .parse() .ok() .map(util::db_to_gain) }) } /// Turn an `f32` `[-1, 1]` value to a panning value where negative values are represented by /// `[100L, 1L]`, 0 gets turned into `C`, and positive values become `[1R, 100R]` values. pub fn v2s_f32_panning() -> Arc String + Send + Sync> { Arc::new(move |value| match value.partial_cmp(&0.0) { Some(Ordering::Less) => format!("{:.0}L", value * -100.0), Some(Ordering::Equal) => String::from("C"), Some(Ordering::Greater) => format!("{:.0}R", value * 100.0), None => String::from("NaN"), }) } /// Parse a pan value in the format of [`v2s_f32_panning()] to a linear value in the range `[-1, /// 1]`. pub fn s2v_f32_panning() -> Arc Option + Send + Sync> { Arc::new(|string| { let string = string.trim(); let cleaned_string = string.trim_end_matches(&[' ', 'l', 'L']).parse().ok(); match string.chars().last()?.to_uppercase().next()? { 'L' => cleaned_string.map(|x: f32| x / -100.0), 'C' => Some(0.0), 'R' => cleaned_string.map(|x: f32| x / 100.0), _ => None, } }) } /// Format a `f32` Hertz value as a rounded `Hz` below 1000 Hz, and as a rounded `kHz` value above /// 1000 Hz. This already includes the unit. pub fn v2s_f32_hz_then_khz(digits: usize) -> Arc String + Send + Sync> { Arc::new(move |value| { if value < 1000.0 { format!("{:.digits$} Hz", value) } else { format!("{:.digits$} kHz", value / 1000.0, digits = digits.max(1)) } }) } /// Convert an input in the same format at that of [`v2s_f32_hz_then_khz()] to a Hertz value. This /// additionally also accepts note names in the same format as [`s2v_i32_note_formatter()`]. pub fn s2v_f32_hz_then_khz() -> Arc Option + Send + Sync> { // FIXME: This is a very crude way to reuse the note value formatter. There's no real runtime // penalty for doing it this way, but it does look less pretty. let note_formatter = s2v_i32_note_formatter(); Arc::new(move |string| { // If the user inputs a note representation, then we'll use that if let Some(midi_note_number) = note_formatter(string) { return Some(util::midi_note_to_freq(midi_note_number.clamp(0, 127) as u8) as f32); } let string = string.trim(); let cleaned_string = string .trim_end_matches(&[' ', 'k', 'K', 'h', 'H', 'z', 'Z']) .parse() .ok(); match string.get(string.len().saturating_sub(3)..) { Some(unit) if unit.eq_ignore_ascii_case("khz") => cleaned_string.map(|x| x * 1000.0), // Even if there's no unit at all, just assume the input is in Hertz _ => cleaned_string, } }) } /// Format an order/power of two. Useful in conjunction with [`s2v_i32_power_of_two()`] to limit /// integer parameter ranges to be only powers of two. pub fn v2s_i32_power_of_two() -> Arc String + Send + Sync> { Arc::new(|value| format!("{}", 1 << value)) } /// Parse a parameter input string to a power of two. Useful in conjunction with /// [`v2s_i32_power_of_two()`] to limit integer parameter ranges to be only powers of two. pub fn s2v_i32_power_of_two() -> Arc Option + Send + Sync> { Arc::new(|string| string.parse().ok().map(|n: i32| (n as f32).log2() as i32)) } /// Turns an integer MIDI note number (usually in the range [0, 127]) into a note name, where 60 is /// C4 and 69 is A4 (nice). pub fn v2s_i32_note_formatter() -> Arc String + Send + Sync> { Arc::new(move |value| { let note_name = util::NOTES[value as usize % 12]; let octave = (value / 12) - 1; format!("{note_name}{octave}") }) } /// Parse a note name to a MIDI number using the inverse mapping from [`v2s_i32_note_formatter()]. pub fn s2v_i32_note_formatter() -> Arc Option + Send + Sync> { Arc::new(|string| { let string = string.trim(); if string.len() < 2 { return None; } // A valid trimmed string will either be be two characters (we already checked the length), // or two characters separated by spaces let (note_name, octave) = string .split_once(|c: char| c.is_whitespace()) .unwrap_or_else(|| (&string[..1], &string[1..])); let note_id = util::NOTES .iter() .position(|&candidate| note_name.eq_ignore_ascii_case(candidate))? as i32; let octave: i32 = octave.trim().parse().ok()?; // 0 = C-1, 12 = C0, 24 = C1 Some(note_id + (12 * (octave + 1))) }) } /// Display 'Bypassed' or 'Not Bypassed' depending on whether the parameter is true or false. /// 'Enabled' would have also been a possibility here, but that could be a bit confusing. pub fn v2s_bool_bypass() -> Arc String + Send + Sync> { Arc::new(move |value| { if value { String::from("Bypassed") } else { String::from("Not Bypassed") } }) } /// Parse a string in the same format as [`v2s_bool_bypass()]. pub fn s2v_bool_bypass() -> Arc Option + Send + Sync> { Arc::new(|string| { let string = string.trim(); if string.eq_ignore_ascii_case("bypassed") { Some(true) } else if string.eq_ignore_ascii_case("not bypassed") { Some(false) } else { None } }) }