mirror of
https://github.com/irmen/prog8.git
synced 2024-11-19 11:32:17 +00:00
259 lines
8.4 KiB
Lua
259 lines
8.4 KiB
Lua
%import textio
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%import floats
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%option no_sysinit
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%zeropage basicsafe
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;
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; IMA ADPCM decoding and playback example.
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; https://wiki.multimedia.cx/index.php/IMA_ADPCM
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; https://wiki.multimedia.cx/index.php/Microsoft_IMA_ADPCM
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;
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; IMA ADPCM encodes two 16-bit PCM audio samples in 1 byte (1 word per nibble)
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; thus compressing the audio data by a factor of 4.
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; The encoding precision is about 13 bits per sample so it's a lossy compression scheme.
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;
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; NOTE: this program requires 16 bits MONO audio, and 256 byte encoded block size!
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; HOW TO CREATE SUCH IMA-ADPCM ENCODED AUDIO? Use sox or ffmpeg:
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; $ sox --guard source.mp3 -r 8000 -c 1 -e ima-adpcm out.wav trim 01:27.50 00:09
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; $ ffmpeg -i source.mp3 -ss 00:01:27.50 -to 00:01:36.50 -ar 8000 -ac 1 -c:a adpcm_ima_wav -block_size 256 -map_metadata -1 -bitexact out.wav
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; Or use a tool such as https://github.com/dbry/adpcm-xq .
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;
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main {
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ubyte adpcm_blocks_left
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uword @requirezp nibblesptr
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sub start() {
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wavfile.parse()
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txt.print_uw(wavfile.adpcm_size)
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txt.print(" adpcm data size = ")
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txt.print_ub(wavfile.num_adpcm_blocks)
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txt.print(" blocks\nsamplerate = ")
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txt.print_uw(wavfile.sample_rate)
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txt.print(" vera rate = ")
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txt.print_uw(wavfile.vera_rate_hz)
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txt.print("\n(b)enchmark or (p)layback? ")
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when c64.CHRIN() {
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'b' -> benchmark()
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'p' -> playback()
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}
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}
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sub benchmark() {
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nibblesptr = wavfile.adpcm_data_ptr
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txt.print("\ndecoding all blocks...\n")
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c64.SETTIM(0,0,0)
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repeat wavfile.num_adpcm_blocks {
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adpcm.init(peekw(nibblesptr), @(nibblesptr+2))
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nibblesptr += 4
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repeat 252 {
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ubyte @zp nibble = @(nibblesptr)
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adpcm.decode_nibble(nibble & 15) ; first word
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adpcm.decode_nibble(nibble>>4) ; second word
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nibblesptr++
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}
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}
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float duration_secs = (c64.RDTIM16() as float) / 60.0
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float words_per_second = 505.0 * (wavfile.num_adpcm_blocks as float) / duration_secs
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txt.print_uw(words_per_second as uword)
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txt.print(" words/sec\n")
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}
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sub playback() {
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nibblesptr = wavfile.adpcm_data_ptr
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adpcm_blocks_left = wavfile.num_adpcm_blocks
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cx16.VERA_AUDIO_CTRL = %10101111 ; mono 16 bit
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cx16.VERA_AUDIO_RATE = 0 ; halt playback
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repeat 1024 {
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cx16.VERA_AUDIO_DATA = 0
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}
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sys.set_irqd()
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cx16.CINV = &irq_handler
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cx16.VERA_IEN = %00001000 ; enable AFLOW
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sys.clear_irqd()
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cx16.VERA_AUDIO_RATE = wavfile.vera_rate ; start playback
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txt.print("\naudio via irq\n")
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repeat {
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; audio will play via the IRQ.
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}
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; not reached:
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; cx16.VERA_AUDIO_CTRL = %00100000
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; cx16.VERA_AUDIO_RATE = 0
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; txt.print("audio off.\n")
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}
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sub irq_handler() {
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if cx16.VERA_ISR & %00001000 {
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; AFLOW irq.
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;; cx16.vpoke(1,$fa0c, $a0) ; paint a screen color
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; refill the fifo buffer with two decoded adpcm blocks (252 nibbles -> 1008 bytes per block)
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repeat 2 {
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adpcm.init(peekw(nibblesptr), @(nibblesptr+2))
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nibblesptr += 4
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repeat 252 {
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ubyte @zp nibble = @(nibblesptr)
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adpcm.decode_nibble(nibble & 15) ; first word
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cx16.VERA_AUDIO_DATA = lsb(adpcm.predict)
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cx16.VERA_AUDIO_DATA = msb(adpcm.predict)
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adpcm.decode_nibble(nibble>>4) ; second word
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cx16.VERA_AUDIO_DATA = lsb(adpcm.predict)
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cx16.VERA_AUDIO_DATA = msb(adpcm.predict)
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nibblesptr++
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}
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adpcm_blocks_left--
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if adpcm_blocks_left==0 {
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; restart adpcm data from the beginning
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nibblesptr = wavfile.adpcm_data_ptr
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adpcm_blocks_left = wavfile.num_adpcm_blocks
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}
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}
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} else {
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; TODO not AFLOW, handle other IRQ
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}
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;; cx16.vpoke(1,$fa0c, 0) ; back to other screen color
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%asm {{
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ply
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plx
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pla
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rti
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}}
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}
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}
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adpcm {
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; IMA ADPCM decoder.
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; https://wiki.multimedia.cx/index.php/IMA_ADPCM
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; https://wiki.multimedia.cx/index.php/Microsoft_IMA_ADPCM
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ubyte[] t_index = [ -1, -1, -1, -1, 2, 4, 6, 8, -1, -1, -1, -1, 2, 4, 6, 8]
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uword[] t_step = [
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7, 8, 9, 10, 11, 12, 13, 14,
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16, 17, 19, 21, 23, 25, 28, 31,
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34, 37, 41, 45, 50, 55, 60, 66,
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73, 80, 88, 97, 107, 118, 130, 143,
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157, 173, 190, 209, 230, 253, 279, 307,
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337, 371, 408, 449, 494, 544, 598, 658,
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724, 796, 876, 963, 1060, 1166, 1282, 1411,
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1552, 1707, 1878, 2066, 2272, 2499, 2749, 3024,
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3327, 3660, 4026, 4428, 4871, 5358, 5894, 6484,
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7132, 7845, 8630, 9493, 10442, 11487, 12635, 13899,
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15289, 16818, 18500, 20350, 22385, 24623, 27086, 29794,
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32767]
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uword @zp predict
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ubyte @zp index
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uword @zp pstep
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sub init(uword startPredict, ubyte startIndex) {
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predict = startPredict
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index = startIndex
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pstep = t_step[index]
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}
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sub decode_nibble(ubyte nibble) {
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; this is the hotspot of the decoder algorithm!
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cx16.r0s = 0 ; difference
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if nibble & %0100
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cx16.r0s += pstep
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pstep >>= 1
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if nibble & %0010
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cx16.r0s += pstep
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pstep >>= 1
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if nibble & %0001
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cx16.r0s += pstep
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pstep >>= 1
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cx16.r0s += pstep
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if nibble & %1000
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cx16.r0s = -cx16.r0s
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predict += cx16.r0s as uword
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index += t_index[nibble]
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if index & 128
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index = 0
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else if index > len(t_step)-1
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index = len(t_step)-1
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pstep = t_step[index]
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}
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}
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wavfile {
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const ubyte WAVE_FORMAT_PCM = $1
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const ubyte WAVE_FORMAT_ADPCM = $2
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const ubyte WAVE_FORMAT_IEEE_FLOAT = $3
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const ubyte WAVE_FORMAT_ALAW = $6
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const ubyte WAVE_FORMAT_MULAW = $7
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const ubyte WAVE_FORMAT_DVI_ADPCM = $11
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uword sample_rate
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uword vera_rate_hz
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ubyte vera_rate
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uword adpcm_size
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uword adpcm_data_ptr
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ubyte num_adpcm_blocks
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sub parse() {
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; "RIFF" , filesize (int32) , "WAVE", "fmt ", fmtsize (int32)
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; we assume file sizes are <= 64Kb so don't have to worry about the upper 16 bits
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uword @zp header = &wavdata.wav_data
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if header[0]!=iso:'R' or header[1]!=iso:'I' or header[2]!=iso:'F' or header[3]!=iso:'F'
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or header[8]!=iso:'W' or header[9]!=iso:'A' or header[10]!=iso:'V' or header[11]!=iso:'E'
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or header[12]!=iso:'f' or header[13]!=iso:'m' or header[14]!=iso:'t' or header[15]!=iso:' ' {
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txt.print("not a valid wav file\n")
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sys.exit(1)
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}
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; uword filesize = peekw(header+4)
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uword chunksize = peekw(header+16)
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uword wavefmt = peekw(header+20)
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uword nchannels = peekw(header+22)
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sample_rate = peekw(header+24) ; we assume sample rate <= 65535 so we can ignore the upper word
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uword block_align = peekw(header+32)
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if block_align!=256 or nchannels!=1 or wavefmt!=WAVE_FORMAT_DVI_ADPCM {
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txt.print("invalid wav specs\n")
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sys.exit(1)
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}
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; skip chunks until we reach the 'data' chunk
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header += chunksize + 20
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repeat {
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chunksize = peekw(header+4) ; assume chunk size never exceeds 64kb so ignore upper word
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if header[0]==iso:'d' and header[1]==iso:'a' and header[2]==iso:'t' and header[3]==iso:'a'
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break
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header += 8 + chunksize
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}
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adpcm_data_ptr = header + 8
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adpcm_size = chunksize
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num_adpcm_blocks = (chunksize / 256) as ubyte ; NOTE: THE ADPCM DATA NEEDS TO BE ENCODED IN 256-byte BLOCKS !
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const float vera_freq_factor = 25e6 / 65536.0
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vera_rate = (sample_rate as float / vera_freq_factor) + 1.0 as ubyte
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vera_rate_hz = (vera_rate as float) * vera_freq_factor as uword
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}
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}
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wavdata {
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%option align_page
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wav_data:
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%asmbinary "adpcm-mono.wav"
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wav_data_end:
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}
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