#include #include #include #include using namespace baselib; static const int NUM_FRAMES_STOP = 512; static const float NUM_FRAMES_STOP_INV = 1.0f/(float)NUM_FRAMES_STOP; static const int NUM_FRAMES_LERP = 512; static const float NUM_FRAMES_LERP_INV = 1.0f/(float)NUM_FRAMES_LERP; static const float GLOBAL_VOLUME_SCALE = 0.75f; static const int64 GLOBAL_SOUND_DELAY = 1000; // --- sound --- class sound_data { public: short *data; int num_samples; int rate; int channels; int sustain_start; int sustain_end; int64 last_played; }; inline short clamp(int i) { if(i > 0x7fff) return 0x7fff; if(i < -0x7fff) return -0x7fff; return i; } static class mixer : public audio_stream { public: class channel { public: channel() { data = 0; lerp = -1; stop = -1; } sound_data *data; int tick; int loop; float pan; float vol; float old_vol; float new_vol; int lerp; int stop; }; enum { MAX_CHANNELS=8, }; channel channels[MAX_CHANNELS]; void fill_mono(short *out, unsigned long frames, channel *c, float dv = 0.0f) { for(unsigned long i = 0; i < frames; i++) { float p = (1.0f-(c->pan+1.0f)*0.5f); int val = (int)(p*c->vol * c->data->data[c->tick]); out[i<<1] += (short)val; out[(i<<1)+1] += (short)val; c->tick++; c->vol += dv; if(c->vol < 0.0f) c->vol = 0.0f; } } void fill_stereo(short *out, unsigned long frames, channel *c, float dv = 0.0f) { for(unsigned long i = 0; i < frames; i++) { float pl = c->pan<0.0f?-c->pan:1.0f; float pr = c->pan>0.0f?1.0f-c->pan:1.0f; int vl = (int)(pl*c->vol * c->data->data[c->tick]); int vr = (int)(pr*c->vol * c->data->data[c->tick + 1]); out[i<<1] += (short)vl; out[(i<<1)+1] += (short)vr; c->tick += 2; c->vol += dv; if(c->vol < 0.0f) c->vol = 0.0f; } } virtual void fill(void *output, unsigned long frames) { short *out = (short*)output; for(unsigned long i = 0; i < frames; i++) { out[i<<1] = 0; out[(i<<1)+1] = 0; } for(int c = 0; c < MAX_CHANNELS; c++) { unsigned long filled = 0; while(channels[c].data && filled < frames) { unsigned long to_fill = frames; float dv = 0.0f; if(channels[c].stop >= 0) to_fill = (unsigned)channels[c].stop>frames?frames:channels[c].stop; if(channels[c].loop >= 0 && channels[c].data->sustain_start >= 0) { unsigned long tmp = channels[c].data->sustain_end - channels[c].tick; to_fill = tmp>frames?frames:tmp; } if(channels[c].lerp >= 0) { dv = (channels[c].new_vol - channels[c].old_vol) * NUM_FRAMES_LERP_INV; } if(channels[c].data->channels == 1) fill_mono(out, to_fill, &channels[c], dv); else fill_stereo(out, to_fill, &channels[c], dv); if(channels[c].loop >= 0 && channels[c].data->sustain_start >= 0 && channels[c].tick >= channels[c].data->sustain_end) channels[c].tick = channels[c].data->sustain_start; if(channels[c].tick >= channels[c].data->num_samples) channels[c].data = 0; channels[c].lerp -= to_fill; if(channels[c].lerp < 0) channels[c].lerp = -1; filled += to_fill; } } } int play(sound_data *sound, unsigned loop, float vol, float pan) { if(time_get() - sound->last_played < GLOBAL_SOUND_DELAY) return -1; for(int c = 0; c < MAX_CHANNELS; c++) { if(channels[c].data == 0) { channels[c].data = sound; channels[c].tick = 0; channels[c].loop = loop; channels[c].vol = vol * GLOBAL_VOLUME_SCALE; channels[c].pan = pan; channels[c].lerp = -1; sound->last_played = time_get(); return c; } } return -1; } void stop(int id) { dbg_assert(id >= 0 && id < MAX_CHANNELS, "id out of bounds"); channels[id].old_vol = channels[id].vol; channels[id].stop = NUM_FRAMES_STOP; } void set_vol(int id, float vol) { dbg_assert(id >= 0 && id < MAX_CHANNELS, "id out of bounds"); channels[id].new_vol = vol * GLOBAL_VOLUME_SCALE; channels[id].old_vol = channels[id].vol; channels[id].lerp = NUM_FRAMES_LERP; } } mixer; struct sound_holder { sound_data sound; int next; }; static const int MAX_SOUNDS = 1024; static sound_holder sounds[MAX_SOUNDS]; static int first_free_sound; static float master_volume = 1.0f; bool snd_init() { first_free_sound = 0; for(int i = 0; i < MAX_SOUNDS; i++) sounds[i].next = i+1; sounds[MAX_SOUNDS-1].next = -1; return mixer.create(); } bool snd_shutdown() { mixer.destroy(); return true; } float snd_get_master_volume() { return master_volume; } void snd_set_master_volume(float val) { if(val < 0.0f) val = 0.0f; else if(val > 1.0f) val = 1.0f; master_volume = val; } static int snd_alloc_sound() { if(first_free_sound < 0) return -1; int id = first_free_sound; first_free_sound = sounds[id].next; sounds[id].next = -1; return id; } int snd_load_wav(const char *filename) { sound_data snd; // open file for reading file_stream file; if(!file.open_r(filename)) { dbg_msg("sound/wav", "failed to open file. filename='%s'", filename); return -1; } int id = -1; int state = 0; while(1) { // read chunk header unsigned char head[8]; if(file.read(head, sizeof(head)) != 8) { break; } int chunk_size = head[4] | (head[5]<<8) | (head[6]<<16) | (head[7]<<24); head[4] = 0; if(state == 0) { // read the riff and wave headers if(head[0] != 'R' || head[1] != 'I' || head[2] != 'F' || head[3] != 'F') { dbg_msg("sound/wav", "not a RIFF file. filename='%s'", filename); return -1; } unsigned char type[4]; file.read(type, 4); if(type[0] != 'W' || type[1] != 'A' || type[2] != 'V' || type[3] != 'E') { dbg_msg("sound/wav", "RIFF file is not a WAVE. filename='%s'", filename); return -1; } state++; } else if(state == 1) { // read the format chunk if(head[0] == 'f' && head[1] == 'm' && head[2] == 't' && head[3] == ' ') { unsigned char fmt[16]; if(file.read(fmt, sizeof(fmt)) != sizeof(fmt)) { dbg_msg("sound/wav", "failed to read format. filename='%s'", filename); return -1; } // decode format int compression_code = fmt[0] | (fmt[1]<<8); snd.channels = fmt[2] | (fmt[3]<<8); snd.rate = fmt[4] | (fmt[5]<<8) | (fmt[6]<<16) | (fmt[7]<<24); if(compression_code != 1) { dbg_msg("sound/wav", "file is not uncompressed. filename='%s'", filename); return -1; } if(snd.channels > 2) { dbg_msg("sound/wav", "file is not mono or stereo. filename='%s'", filename); return -1; } if(snd.rate != 44100) { dbg_msg("sound/wav", "file is %d Hz, not 44100 Hz. filename='%s'", snd.rate, filename); return -1; } int bps = fmt[14] | (fmt[15]<<8); if(bps != 16) { dbg_msg("sound/wav", "bps is %d, not 16, filname='%s'", bps, filename); return -1; } // next state state++; } else file.skip(chunk_size); } else if(state == 2) { // read the data if(head[0] == 'd' && head[1] == 'a' && head[2] == 't' && head[3] == 'a') { snd.data = (short*)mem_alloc(chunk_size, 1); file.read(snd.data, chunk_size); snd.num_samples = chunk_size/(2); #if defined(CONF_ARCH_ENDIAN_BIG) for(unsigned i = 0; i < (unsigned)snd.num_samples; i++) { unsigned j = i << 1; snd.data[i] = ((short)((char*)snd.data)[j]) + ((short)((char*)snd.data)[j+1] << 8); } #endif snd.sustain_start = -1; snd.sustain_end = -1; snd.last_played = 0; id = snd_alloc_sound(); sounds[id].sound = snd; state++; } else file.skip(chunk_size); } else if(state == 3) { if(head[0] == 's' && head[1] == 'm' && head[2] == 'p' && head[3] == 'l') { unsigned char smpl[36]; unsigned char loop[24]; dbg_msg("sound/wav", "got sustain"); file.read(smpl, sizeof(smpl)); unsigned num_loops = (smpl[28] | (smpl[29]<<8) | (smpl[30]<<16) | (smpl[31]<<24)); unsigned skip = (smpl[32] | (smpl[33]<<8) | (smpl[34]<<16) | (smpl[35]<<24)); if(num_loops > 0) { file.read(loop, sizeof(loop)); unsigned start = (loop[8] | (loop[9]<<8) | (loop[10]<<16) | (loop[11]<<24)); unsigned end = (loop[12] | (loop[13]<<8) | (loop[14]<<16) | (loop[15]<<24)); sounds[id].sound.sustain_start = start * sounds[id].sound.channels; sounds[id].sound.sustain_end = end * sounds[id].sound.channels; } if(num_loops > 1) file.skip((num_loops-1) * sizeof(loop)); file.skip(skip); state++; } else file.skip(chunk_size); } else file.skip(chunk_size); } if(id >= 0) dbg_msg("sound/wav", "loaded %s, sustain start: %d end: %d", filename, sounds[id].sound.sustain_start, sounds[id].sound.sustain_end); else dbg_msg("sound/wav", "failed to load %s", filename); return id; } int snd_play(int id, int loop, float vol, float pan) { if(id < 0) { dbg_msg("snd", "bad sound id"); return -1; } dbg_assert(sounds[id].sound.data != 0, "null sound"); dbg_assert(sounds[id].next == -1, "sound isn't allocated"); return mixer.play(&sounds[id].sound, loop, master_volume * vol, pan); } void snd_stop(int id) { if(id >= 0) mixer.stop(id); } void snd_set_vol(int id, float vol) { if(id >= 0) mixer.set_vol(id, vol); }