use std::{collections::HashMap, error::Error, fs, path::Path}; use agb_tracker_interop::PatternEffect; use proc_macro2::TokenStream; use proc_macro_error::abort; use quote::quote; use syn::LitStr; use agb_fixnum::Num; use xmrs::{prelude::*, xm::xmmodule::XmModule}; pub fn agb_xm_core(args: TokenStream) -> TokenStream { let input = match syn::parse::(args.into()) { Ok(input) => input, Err(err) => return err.to_compile_error(), }; let filename = input.value(); let root = std::env::var("CARGO_MANIFEST_DIR").expect("Failed to get cargo manifest dir"); let path = Path::new(&root).join(&*filename); let include_path = path.to_string_lossy(); let module = match load_module_from_file(&path) { Ok(track) => track, Err(e) => abort!(input, e), }; let parsed = parse_module(&module); quote! { { const _: &[u8] = include_bytes!(#include_path); #parsed } } } pub fn load_module_from_file(xm_path: &Path) -> Result> { let file_content = fs::read(xm_path)?; Ok(XmModule::load(&file_content)?.to_module()) } pub fn parse_module(module: &Module) -> TokenStream { let instruments = &module.instrument; let mut instruments_map = HashMap::new(); struct SampleData { data: Vec, should_loop: bool, fine_tune: f64, relative_note: i8, restart_point: u32, volume: Num, } let mut samples = vec![]; for (instrument_index, instrument) in instruments.iter().enumerate() { let InstrumentType::Default(ref instrument) = instrument.instr_type else { continue; }; for (sample_index, sample) in instrument.sample.iter().enumerate() { let should_loop = !matches!(sample.flags, LoopType::No); let fine_tune = sample.finetune as f64 * 128.0; let relative_note = sample.relative_note; let restart_point = sample.loop_start; let sample_len = if sample.loop_length > 0 { (sample.loop_length + sample.loop_start) as usize } else { usize::MAX }; let volume = Num::from_raw((sample.volume * (1 << 8) as f32) as i16); let sample = match &sample.data { SampleDataType::Depth8(depth8) => depth8 .iter() .map(|value| *value as u8) .take(sample_len) .collect::>(), SampleDataType::Depth16(depth16) => depth16 .iter() .map(|sample| (sample >> 8) as i8 as u8) .take(sample_len) .collect::>(), }; instruments_map.insert((instrument_index, sample_index), samples.len()); samples.push(SampleData { data: sample, should_loop, fine_tune, relative_note, restart_point, volume, }); } } let mut patterns = vec![]; let mut pattern_data = vec![]; for pattern in &module.pattern { let start_pos = pattern_data.len(); let mut effect_parameters: [u8; 255] = [0; u8::MAX as usize]; let mut tone_portamento_directions = vec![0; module.get_num_channels()]; let mut note_and_sample = vec![None; module.get_num_channels()]; for row in pattern.iter() { for (i, slot) in row.iter().enumerate() { let channel_number = i % module.get_num_channels(); let sample = if slot.instrument == 0 { 0 } else { let instrument_index = (slot.instrument - 1) as usize; if let InstrumentType::Default(ref instrument) = module.instrument[instrument_index].instr_type { let sample_slot = instrument.sample_for_note[slot.note as usize] as usize; instruments_map .get(&(instrument_index, sample_slot)) .map(|sample_idx| sample_idx + 1) .unwrap_or(0) } else { 0 } }; let mut effect1 = PatternEffect::None; let previous_note_and_sample = note_and_sample[channel_number]; let maybe_note_and_sample = if matches!(slot.note, Note::KeyOff) { effect1 = PatternEffect::Stop; // note_and_sample[channel_number] = None; ¬e_and_sample[channel_number] } else if !matches!(slot.note, Note::None) { if sample != 0 { note_and_sample[channel_number] = Some((slot.note, &samples[sample - 1])); } else if let Some((note, _)) = &mut note_and_sample[channel_number] { *note = slot.note; } ¬e_and_sample[channel_number] } else { ¬e_and_sample[channel_number] }; if matches!(effect1, PatternEffect::None) { effect1 = match slot.volume { 0x10..=0x50 => PatternEffect::Volume( (Num::new((slot.volume - 0x10) as i16) / 64) * maybe_note_and_sample .map(|note_and_sample| note_and_sample.1.volume) .unwrap_or(1.into()), ), 0x60..=0x6F => { PatternEffect::VolumeSlide(-Num::new((slot.volume - 0x60) as i16) / 64) } 0x70..=0x7F => { PatternEffect::VolumeSlide(Num::new((slot.volume - 0x70) as i16) / 64) } 0x80..=0x8F => PatternEffect::FineVolumeSlide( -Num::new((slot.volume - 0x80) as i16) / 64, ), 0x90..=0x9F => PatternEffect::FineVolumeSlide( Num::new((slot.volume - 0x90) as i16) / 64, ), 0xC0..=0xCF => PatternEffect::Panning( Num::new(slot.volume as i16 - (0xC0 + (0xCF - 0xC0) / 2)) / 8, ), _ => PatternEffect::None, }; } let effect_parameter = if slot.effect_parameter != 0 { effect_parameters[slot.effect_type as usize] = slot.effect_parameter; slot.effect_parameter } else { effect_parameters[slot.effect_type as usize] }; let effect2 = match slot.effect_type { 0x0 => { if slot.effect_parameter == 0 { PatternEffect::None } else if let Some((note, sample)) = maybe_note_and_sample { let first_arpeggio = slot.effect_parameter >> 4; let second_arpeggio = slot.effect_parameter & 0xF; let first_arpeggio_speed = note_to_speed( *note, sample.fine_tune, sample.relative_note + first_arpeggio as i8, module.frequency_type, ); let second_arpeggio_speed = note_to_speed( *note, sample.fine_tune, sample.relative_note + second_arpeggio as i8, module.frequency_type, ); PatternEffect::Arpeggio( first_arpeggio_speed .try_change_base() .expect("Arpeggio size too large"), second_arpeggio_speed .try_change_base() .expect("Arpeggio size too large"), ) } else { PatternEffect::None } } 0x1 => { let c4_speed: Num = note_to_speed(Note::C4, 0.0, 0, module.frequency_type).change_base(); let speed: Num = note_to_speed( Note::C4, effect_parameter as f64 * 8.0, 0, module.frequency_type, ) .change_base(); let portamento_amount = speed / c4_speed; PatternEffect::Portamento(portamento_amount.try_change_base().unwrap()) } 0x2 => { let c4_speed = note_to_speed(Note::C4, 0.0, 0, module.frequency_type); let speed = note_to_speed( Note::C4, effect_parameter as f64 * 8.0, 0, module.frequency_type, ); let portamento_amount = c4_speed / speed; PatternEffect::Portamento(portamento_amount.try_change_base().unwrap()) } 0x3 => { if let (Some((note, sample)), Some((prev_note, _))) = (maybe_note_and_sample, previous_note_and_sample) { let target_speed = note_to_speed( *note, sample.fine_tune, sample.relative_note, module.frequency_type, ); let direction = match (prev_note as usize).cmp(&(*note as usize)) { std::cmp::Ordering::Less => 1, std::cmp::Ordering::Equal => { tone_portamento_directions[channel_number] } std::cmp::Ordering::Greater => -1, }; tone_portamento_directions[channel_number] = direction; let c4_speed = note_to_speed(Note::C4, 0.0, 0, module.frequency_type); let speed = note_to_speed( Note::C4, effect_parameter as f64 * 8.0, 0, module.frequency_type, ); let portamento_amount = if direction > 0 { speed / c4_speed } else { c4_speed / speed }; PatternEffect::TonePortamento( portamento_amount.try_change_base().unwrap(), target_speed.try_change_base().unwrap(), ) } else { PatternEffect::None } } 0x8 => { PatternEffect::Panning(Num::new(slot.effect_parameter as i16 - 128) / 128) } 0xA => { let first = effect_parameter >> 4; let second = effect_parameter & 0xF; if first == 0 { PatternEffect::VolumeSlide(-Num::new(second as i16) / 16) } else { PatternEffect::VolumeSlide(Num::new(first as i16) / 16) } } 0xC => { if let Some((_, sample)) = maybe_note_and_sample { PatternEffect::Volume( (Num::new(slot.effect_parameter as i16) / 64) * sample.volume, ) } else { PatternEffect::None } } 0xE => match slot.effect_parameter >> 4 { 0xA => PatternEffect::FineVolumeSlide( Num::new((slot.effect_parameter & 0xf) as i16) / 64, ), 0xB => PatternEffect::FineVolumeSlide( -Num::new((slot.effect_parameter & 0xf) as i16) / 64, ), 0xC => PatternEffect::NoteCut((slot.effect_parameter & 0xf).into()), _ => PatternEffect::None, }, _ => PatternEffect::None, }; if sample == 0 || matches!(effect2, PatternEffect::TonePortamento(_, _)) || matches!(effect1, PatternEffect::Stop) { pattern_data.push(agb_tracker_interop::PatternSlot { speed: 0.into(), sample: 0, effect1, effect2, }); } else { let sample_played = &samples[sample - 1]; let speed = note_to_speed( slot.note, sample_played.fine_tune, sample_played.relative_note, module.frequency_type, ); pattern_data.push(agb_tracker_interop::PatternSlot { speed: speed.try_change_base().unwrap(), sample: sample as u16, effect1, effect2, }); } } } patterns.push(agb_tracker_interop::Pattern { length: pattern.len(), start_position: start_pos, }); } let samples: Vec<_> = samples .iter() .map(|sample| agb_tracker_interop::Sample { data: &sample.data, should_loop: sample.should_loop, restart_point: sample.restart_point, volume: sample.volume, }) .collect(); let patterns_to_play = module .pattern_order .iter() .map(|order| *order as usize) .collect::>(); // Number 150 here deduced experimentally let frames_per_tick = Num::::new(150) / module.default_bpm as u32; let ticks_per_step = module.default_tempo; let interop = agb_tracker_interop::Track { samples: &samples, pattern_data: &pattern_data, patterns: &patterns, num_channels: module.get_num_channels(), patterns_to_play: &patterns_to_play, frames_per_tick, ticks_per_step: ticks_per_step.into(), repeat: module.restart_position as usize, }; quote!(#interop) } fn note_to_speed( note: Note, fine_tune: f64, relative_note: i8, frequency_type: FrequencyType, ) -> Num { let frequency = match frequency_type { FrequencyType::LinearFrequencies => { note_to_frequency_linear(note, fine_tune, relative_note) } FrequencyType::AmigaFrequencies => note_to_frequency_amega(note, fine_tune, relative_note), }; let gba_audio_frequency = 18157f64; let speed: f64 = frequency / gba_audio_frequency; Num::from_raw((speed * (1 << 12) as f64) as u32) } fn note_to_frequency_linear(note: Note, fine_tune: f64, relative_note: i8) -> f64 { let real_note = (note as usize as f64) + (relative_note as f64); let period = 10.0 * 12.0 * 16.0 * 4.0 - real_note * 16.0 * 4.0 - fine_tune / 2.0; 8363.0 * 2.0f64.powf((6.0 * 12.0 * 16.0 * 4.0 - period) / (12.0 * 16.0 * 4.0)) } fn note_to_frequency_amega(note: Note, fine_tune: f64, relative_note: i8) -> f64 { let note = (note as usize) .checked_add_signed(relative_note as isize) .expect("Note gone negative"); let pos = (note % 12) * 8 + (fine_tune / 16.0) as usize; let frac = (fine_tune / 16.0) - (fine_tune / 16.0).floor(); let period = ((AMEGA_FREQUENCIES[pos] as f64 * (1.0 - frac)) + AMEGA_FREQUENCIES[pos + 1] as f64 * frac) * 32.0 // docs say 16 here, but for some reason I need 32 :/ / (1 << ((note as i64) / 12)) as f64; 8363.0 * 1712.0 / period } const AMEGA_FREQUENCIES: &[u32] = &[ 907, 900, 894, 887, 881, 875, 868, 862, 856, 850, 844, 838, 832, 826, 820, 814, 808, 802, 796, 791, 785, 779, 774, 768, 762, 757, 752, 746, 741, 736, 730, 725, 720, 715, 709, 704, 699, 694, 689, 684, 678, 675, 670, 665, 660, 655, 651, 646, 640, 636, 632, 628, 623, 619, 614, 610, 604, 601, 597, 592, 588, 584, 580, 575, 570, 567, 563, 559, 555, 551, 547, 543, 538, 535, 532, 528, 524, 520, 516, 513, 508, 505, 502, 498, 494, 491, 487, 484, 480, 477, 474, 470, 467, 463, 460, 457, ];