6753fb5138
git-svn-id: svn://svn.rockbox.org/rockbox/trunk@7187 a1c6a512-1295-4272-9138-f99709370657
773 lines
27 KiB
C
773 lines
27 KiB
C
////////////////////////////////////////////////////////////////////////////
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// **** WAVPACK **** //
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// Hybrid Lossless Wavefile Compressor //
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// Copyright (c) 1998 - 2004 Conifer Software. //
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// All Rights Reserved. //
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// Distributed under the BSD Software License (see license.txt) //
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////////////////////////////////////////////////////////////////////////////
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// unpack.c
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// This module actually handles the decompression of the audio data, except
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// for the entropy decoding which is handled by the words.c module. For
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// maximum efficiency, the conversion is isolated to tight loops that handle
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// an entire buffer.
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#include "wavpack.h"
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#include <stdlib.h>
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#include <string.h>
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static void strcpy_loc (char *dst, char *src) { while ((*dst++ = *src++) != 0); }
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#define LOSSY_MUTE
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///////////////////////////// executable code ////////////////////////////////
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// This function initializes everything required to unpack a WavPack block
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// and must be called before unpack_samples() is called to obtain audio data.
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// It is assumed that the WavpackHeader has been read into the wps->wphdr
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// (in the current WavpackStream). This is where all the metadata blocks are
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// scanned up to the one containing the audio bitstream.
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int unpack_init (WavpackContext *wpc)
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{
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WavpackStream *wps = &wpc->stream;
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WavpackMetadata wpmd;
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if (wps->wphdr.block_samples && wps->wphdr.block_index != (ulong) -1)
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wps->sample_index = wps->wphdr.block_index;
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wps->mute_error = FALSE;
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wps->crc = 0xffffffff;
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CLEAR (wps->wvbits);
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CLEAR (wps->decorr_passes);
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CLEAR (wps->w);
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while (read_metadata_buff (wpc, &wpmd)) {
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if (!process_metadata (wpc, &wpmd)) {
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strcpy_loc (wpc->error_message, "invalid metadata!");
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return FALSE;
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}
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if (wpmd.id == ID_WV_BITSTREAM)
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break;
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}
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if (wps->wphdr.block_samples && !bs_is_open (&wps->wvbits)) {
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strcpy_loc (wpc->error_message, "invalid WavPack file!");
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return FALSE;
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}
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if (wps->wphdr.block_samples) {
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if ((wps->wphdr.flags & INT32_DATA) && wps->int32_sent_bits)
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wpc->lossy_blocks = TRUE;
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if ((wps->wphdr.flags & FLOAT_DATA) &&
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wps->float_flags & (FLOAT_EXCEPTIONS | FLOAT_ZEROS_SENT | FLOAT_SHIFT_SENT | FLOAT_SHIFT_SAME))
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wpc->lossy_blocks = TRUE;
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}
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return TRUE;
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}
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// This function initialzes the main bitstream for audio samples, which must
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// be in the "wv" file.
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int init_wv_bitstream (WavpackContext *wpc, WavpackMetadata *wpmd)
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{
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WavpackStream *wps = &wpc->stream;
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if (wpmd->data)
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bs_open_read (&wps->wvbits, wpmd->data, (char *) wpmd->data + wpmd->byte_length, NULL, 0);
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else if (wpmd->byte_length)
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bs_open_read (&wps->wvbits, wpc->read_buffer, wpc->read_buffer + sizeof (wpc->read_buffer),
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wpc->infile, wpmd->byte_length + (wpmd->byte_length & 1));
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return TRUE;
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}
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// Read decorrelation terms from specified metadata block into the
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// decorr_passes array. The terms range from -3 to 8, plus 17 & 18;
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// other values are reserved and generate errors for now. The delta
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// ranges from 0 to 7 with all values valid. Note that the terms are
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// stored in the opposite order in the decorr_passes array compared
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// to packing.
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int read_decorr_terms (WavpackStream *wps, WavpackMetadata *wpmd)
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{
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int termcnt = wpmd->byte_length;
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uchar *byteptr = wpmd->data;
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struct decorr_pass *dpp;
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if (termcnt > MAX_NTERMS)
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return FALSE;
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wps->num_terms = termcnt;
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for (dpp = wps->decorr_passes + termcnt - 1; termcnt--; dpp--) {
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dpp->term = (int)(*byteptr & 0x1f) - 5;
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dpp->delta = (*byteptr++ >> 5) & 0x7;
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if (!dpp->term || dpp->term < -3 || (dpp->term > MAX_TERM && dpp->term < 17) || dpp->term > 18)
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return FALSE;
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}
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return TRUE;
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}
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// Read decorrelation weights from specified metadata block into the
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// decorr_passes array. The weights range +/-1024, but are rounded and
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// truncated to fit in signed chars for metadata storage. Weights are
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// separate for the two channels and are specified from the "last" term
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// (first during encode). Unspecified weights are set to zero.
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int read_decorr_weights (WavpackStream *wps, WavpackMetadata *wpmd)
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{
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int termcnt = wpmd->byte_length, tcount;
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char *byteptr = wpmd->data;
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struct decorr_pass *dpp;
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if (!(wps->wphdr.flags & MONO_FLAG))
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termcnt /= 2;
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if (termcnt > wps->num_terms)
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return FALSE;
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for (tcount = wps->num_terms, dpp = wps->decorr_passes; tcount--; dpp++)
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dpp->weight_A = dpp->weight_B = 0;
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while (--dpp >= wps->decorr_passes && termcnt--) {
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dpp->weight_A = restore_weight (*byteptr++);
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if (!(wps->wphdr.flags & MONO_FLAG))
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dpp->weight_B = restore_weight (*byteptr++);
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}
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return TRUE;
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}
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// Read decorrelation samples from specified metadata block into the
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// decorr_passes array. The samples are signed 32-bit values, but are
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// converted to signed log2 values for storage in metadata. Values are
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// stored for both channels and are specified from the "last" term
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// (first during encode) with unspecified samples set to zero. The
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// number of samples stored varies with the actual term value, so
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// those must obviously come first in the metadata.
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int read_decorr_samples (WavpackStream *wps, WavpackMetadata *wpmd)
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{
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uchar *byteptr = wpmd->data;
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uchar *endptr = byteptr + wpmd->byte_length;
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struct decorr_pass *dpp;
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int tcount;
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for (tcount = wps->num_terms, dpp = wps->decorr_passes; tcount--; dpp++) {
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CLEAR (dpp->samples_A);
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CLEAR (dpp->samples_B);
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}
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if (wps->wphdr.version == 0x402 && (wps->wphdr.flags & HYBRID_FLAG)) {
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byteptr += 2;
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if (!(wps->wphdr.flags & MONO_FLAG))
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byteptr += 2;
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}
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while (dpp-- > wps->decorr_passes && byteptr < endptr)
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if (dpp->term > MAX_TERM) {
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dpp->samples_A [0] = exp2s ((short)(byteptr [0] + (byteptr [1] << 8)));
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dpp->samples_A [1] = exp2s ((short)(byteptr [2] + (byteptr [3] << 8)));
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byteptr += 4;
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if (!(wps->wphdr.flags & MONO_FLAG)) {
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dpp->samples_B [0] = exp2s ((short)(byteptr [0] + (byteptr [1] << 8)));
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dpp->samples_B [1] = exp2s ((short)(byteptr [2] + (byteptr [3] << 8)));
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byteptr += 4;
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}
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}
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else if (dpp->term < 0) {
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dpp->samples_A [0] = exp2s ((short)(byteptr [0] + (byteptr [1] << 8)));
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dpp->samples_B [0] = exp2s ((short)(byteptr [2] + (byteptr [3] << 8)));
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byteptr += 4;
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}
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else {
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int m = 0, cnt = dpp->term;
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while (cnt--) {
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dpp->samples_A [m] = exp2s ((short)(byteptr [0] + (byteptr [1] << 8)));
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byteptr += 2;
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if (!(wps->wphdr.flags & MONO_FLAG)) {
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dpp->samples_B [m] = exp2s ((short)(byteptr [0] + (byteptr [1] << 8)));
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byteptr += 2;
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}
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m++;
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}
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}
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return byteptr == endptr;
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}
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// Read the int32 data from the specified metadata into the specified stream.
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// This data is used for integer data that has more than 24 bits of magnitude
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// or, in some cases, used to eliminate redundant bits from any audio stream.
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int read_int32_info (WavpackStream *wps, WavpackMetadata *wpmd)
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{
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int bytecnt = wpmd->byte_length;
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char *byteptr = wpmd->data;
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if (bytecnt != 4)
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return FALSE;
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wps->int32_sent_bits = *byteptr++;
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wps->int32_zeros = *byteptr++;
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wps->int32_ones = *byteptr++;
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wps->int32_dups = *byteptr;
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return TRUE;
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}
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// Read multichannel information from metadata. The first byte is the total
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// number of channels and the following bytes represent the channel_mask
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// as described for Microsoft WAVEFORMATEX.
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int read_channel_info (WavpackContext *wpc, WavpackMetadata *wpmd)
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{
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int bytecnt = wpmd->byte_length, shift = 0;
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char *byteptr = wpmd->data;
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ulong mask = 0;
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if (!bytecnt || bytecnt > 5)
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return FALSE;
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wpc->config.num_channels = *byteptr++;
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while (--bytecnt) {
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mask |= (ulong) *byteptr++ << shift;
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shift += 8;
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}
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wpc->config.channel_mask = mask;
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return TRUE;
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}
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// Read configuration information from metadata.
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int read_config_info (WavpackContext *wpc, WavpackMetadata *wpmd)
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{
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int bytecnt = wpmd->byte_length;
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uchar *byteptr = wpmd->data;
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if (bytecnt >= 3) {
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wpc->config.flags &= 0xff;
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wpc->config.flags |= (long) *byteptr++ << 8;
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wpc->config.flags |= (long) *byteptr++ << 16;
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wpc->config.flags |= (long) *byteptr << 24;
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}
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return TRUE;
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}
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// This monster actually unpacks the WavPack bitstream(s) into the specified
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// buffer as 32-bit integers or floats (depending on orignal data). Lossy
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// samples will be clipped to their original limits (i.e. 8-bit samples are
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// clipped to -128/+127) but are still returned in longs. It is up to the
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// caller to potentially reformat this for the final output including any
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// multichannel distribution, block alignment or endian compensation. The
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// function unpack_init() must have been called and the entire WavPack block
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// must still be visible (although wps->blockbuff will not be accessed again).
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// For maximum clarity, the function is broken up into segments that handle
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// various modes. This makes for a few extra infrequent flag checks, but
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// makes the code easier to follow because the nesting does not become so
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// deep. For maximum efficiency, the conversion is isolated to tight loops
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// that handle an entire buffer. The function returns the total number of
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// samples unpacked, which can be less than the number requested if an error
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// occurs or the end of the block is reached.
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#if defined(CPU_COLDFIRE) && !defined(SIMULATOR)
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extern void decorr_stereo_pass_cont_mcf5249 (struct decorr_pass *dpp, long *buffer, long sample_count);
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#else
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static void decorr_stereo_pass_cont (struct decorr_pass *dpp, long *buffer, long sample_count);
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#endif
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static void decorr_mono_pass (struct decorr_pass *dpp, long *buffer, long sample_count);
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static void decorr_stereo_pass (struct decorr_pass *dpp, long *buffer, long sample_count);
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static void fixup_samples (WavpackStream *wps, long *buffer, ulong sample_count);
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long unpack_samples (WavpackContext *wpc, long *buffer, ulong sample_count)
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{
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WavpackStream *wps = &wpc->stream;
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ulong flags = wps->wphdr.flags, crc = wps->crc, i;
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long mute_limit = (1L << ((flags & MAG_MASK) >> MAG_LSB)) + 2;
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struct decorr_pass *dpp;
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long *bptr, *eptr;
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int tcount;
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if (wps->sample_index + sample_count > wps->wphdr.block_index + wps->wphdr.block_samples)
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sample_count = wps->wphdr.block_index + wps->wphdr.block_samples - wps->sample_index;
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if (wps->mute_error) {
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memset (buffer, 0, sample_count * (flags & MONO_FLAG ? 4 : 8));
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wps->sample_index += sample_count;
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return sample_count;
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}
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if (flags & HYBRID_FLAG)
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mute_limit *= 2;
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///////////////////// handle version 4 mono data /////////////////////////
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if (flags & MONO_FLAG) {
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eptr = buffer + sample_count;
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i = get_words (buffer, sample_count, flags, &wps->w, &wps->wvbits);
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for (tcount = wps->num_terms, dpp = wps->decorr_passes; tcount--; dpp++)
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decorr_mono_pass (dpp, buffer, sample_count);
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for (bptr = buffer; bptr < eptr; ++bptr) {
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if (labs (bptr [0]) > mute_limit) {
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i = bptr - buffer;
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break;
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}
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crc = crc * 3 + bptr [0];
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}
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}
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//////////////////// handle version 4 stereo data ////////////////////////
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else {
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eptr = buffer + (sample_count * 2);
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i = get_words (buffer, sample_count, flags, &wps->w, &wps->wvbits);
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if (sample_count < 16)
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for (tcount = wps->num_terms, dpp = wps->decorr_passes; tcount--; dpp++)
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decorr_stereo_pass (dpp, buffer, sample_count);
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else
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for (tcount = wps->num_terms, dpp = wps->decorr_passes; tcount--; dpp++) {
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decorr_stereo_pass (dpp, buffer, 8);
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#if defined(CPU_COLDFIRE) && !defined(SIMULATOR)
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decorr_stereo_pass_cont_mcf5249 (dpp, buffer + 16, sample_count - 8);
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#else
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decorr_stereo_pass_cont (dpp, buffer + 16, sample_count - 8);
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#endif
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}
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if (flags & JOINT_STEREO)
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for (bptr = buffer; bptr < eptr; bptr += 2) {
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bptr [0] += (bptr [1] -= (bptr [0] >> 1));
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if (labs (bptr [0]) > mute_limit || labs (bptr [1]) > mute_limit) {
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i = (bptr - buffer) / 2;
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break;
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}
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crc = (crc * 3 + bptr [0]) * 3 + bptr [1];
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}
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else
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for (bptr = buffer; bptr < eptr; bptr += 2) {
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if (labs (bptr [0]) > mute_limit || labs (bptr [1]) > mute_limit) {
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i = (bptr - buffer) / 2;
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break;
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}
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crc = (crc * 3 + bptr [0]) * 3 + bptr [1];
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}
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}
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if (i != sample_count) {
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memset (buffer, 0, sample_count * (flags & MONO_FLAG ? 4 : 8));
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wps->mute_error = TRUE;
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i = sample_count;
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}
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fixup_samples (wps, buffer, i);
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if (flags & FLOAT_DATA)
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float_normalize (buffer, (flags & MONO_FLAG) ? i : i * 2,
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127 - wps->float_norm_exp + wpc->norm_offset);
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wps->sample_index += i;
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wps->crc = crc;
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return i;
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}
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static void decorr_stereo_pass (struct decorr_pass *dpp, long *buffer, long sample_count)
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{
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long delta = dpp->delta, weight_A = dpp->weight_A, weight_B = dpp->weight_B;
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long *bptr, *eptr = buffer + (sample_count * 2), sam_A, sam_B;
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int m, k;
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switch (dpp->term) {
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case 17:
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for (bptr = buffer; bptr < eptr; bptr += 2) {
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sam_A = 2 * dpp->samples_A [0] - dpp->samples_A [1];
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dpp->samples_A [1] = dpp->samples_A [0];
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dpp->samples_A [0] = apply_weight (weight_A, sam_A) + bptr [0];
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update_weight (weight_A, delta, sam_A, bptr [0]);
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bptr [0] = dpp->samples_A [0];
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sam_A = 2 * dpp->samples_B [0] - dpp->samples_B [1];
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dpp->samples_B [1] = dpp->samples_B [0];
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dpp->samples_B [0] = apply_weight (weight_B, sam_A) + bptr [1];
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update_weight (weight_B, delta, sam_A, bptr [1]);
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bptr [1] = dpp->samples_B [0];
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}
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break;
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case 18:
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for (bptr = buffer; bptr < eptr; bptr += 2) {
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sam_A = (3 * dpp->samples_A [0] - dpp->samples_A [1]) >> 1;
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dpp->samples_A [1] = dpp->samples_A [0];
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dpp->samples_A [0] = apply_weight (weight_A, sam_A) + bptr [0];
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update_weight (weight_A, delta, sam_A, bptr [0]);
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bptr [0] = dpp->samples_A [0];
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sam_A = (3 * dpp->samples_B [0] - dpp->samples_B [1]) >> 1;
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dpp->samples_B [1] = dpp->samples_B [0];
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dpp->samples_B [0] = apply_weight (weight_B, sam_A) + bptr [1];
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update_weight (weight_B, delta, sam_A, bptr [1]);
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bptr [1] = dpp->samples_B [0];
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}
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break;
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default:
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for (m = 0, k = dpp->term & (MAX_TERM - 1), bptr = buffer; bptr < eptr; bptr += 2) {
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sam_A = dpp->samples_A [m];
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dpp->samples_A [k] = apply_weight (weight_A, sam_A) + bptr [0];
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update_weight (weight_A, delta, sam_A, bptr [0]);
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bptr [0] = dpp->samples_A [k];
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sam_A = dpp->samples_B [m];
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dpp->samples_B [k] = apply_weight (weight_B, sam_A) + bptr [1];
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update_weight (weight_B, delta, sam_A, bptr [1]);
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bptr [1] = dpp->samples_B [k];
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m = (m + 1) & (MAX_TERM - 1);
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k = (k + 1) & (MAX_TERM - 1);
|
|
}
|
|
|
|
if (m) {
|
|
long temp_samples [MAX_TERM];
|
|
|
|
memcpy (temp_samples, dpp->samples_A, sizeof (dpp->samples_A));
|
|
|
|
for (k = 0; k < MAX_TERM; k++, m++)
|
|
dpp->samples_A [k] = temp_samples [m & (MAX_TERM - 1)];
|
|
|
|
memcpy (temp_samples, dpp->samples_B, sizeof (dpp->samples_B));
|
|
|
|
for (k = 0; k < MAX_TERM; k++, m++)
|
|
dpp->samples_B [k] = temp_samples [m & (MAX_TERM - 1)];
|
|
}
|
|
|
|
break;
|
|
|
|
case -1:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
sam_A = bptr [0] + apply_weight (weight_A, dpp->samples_A [0]);
|
|
update_weight_clip (weight_A, delta, dpp->samples_A [0], bptr [0]);
|
|
bptr [0] = sam_A;
|
|
dpp->samples_A [0] = bptr [1] + apply_weight (weight_B, sam_A);
|
|
update_weight_clip (weight_B, delta, sam_A, bptr [1]);
|
|
bptr [1] = dpp->samples_A [0];
|
|
}
|
|
|
|
break;
|
|
|
|
case -2:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
sam_B = bptr [1] + apply_weight (weight_B, dpp->samples_B [0]);
|
|
update_weight_clip (weight_B, delta, dpp->samples_B [0], bptr [1]);
|
|
bptr [1] = sam_B;
|
|
dpp->samples_B [0] = bptr [0] + apply_weight (weight_A, sam_B);
|
|
update_weight_clip (weight_A, delta, sam_B, bptr [0]);
|
|
bptr [0] = dpp->samples_B [0];
|
|
}
|
|
|
|
break;
|
|
|
|
case -3:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
sam_A = bptr [0] + apply_weight (weight_A, dpp->samples_A [0]);
|
|
update_weight_clip (weight_A, delta, dpp->samples_A [0], bptr [0]);
|
|
sam_B = bptr [1] + apply_weight (weight_B, dpp->samples_B [0]);
|
|
update_weight_clip (weight_B, delta, dpp->samples_B [0], bptr [1]);
|
|
bptr [0] = dpp->samples_B [0] = sam_A;
|
|
bptr [1] = dpp->samples_A [0] = sam_B;
|
|
}
|
|
|
|
break;
|
|
}
|
|
|
|
dpp->weight_A = weight_A;
|
|
dpp->weight_B = weight_B;
|
|
}
|
|
|
|
#if !defined(CPU_COLDFIRE) || defined(SIMULATOR)
|
|
|
|
static void decorr_stereo_pass_cont (struct decorr_pass *dpp, long *buffer, long sample_count)
|
|
{
|
|
long delta = dpp->delta, weight_A = dpp->weight_A, weight_B = dpp->weight_B;
|
|
long *bptr, *tptr, *eptr = buffer + (sample_count * 2), sam_A, sam_B;
|
|
int k, i;
|
|
|
|
switch (dpp->term) {
|
|
|
|
case 17:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
sam_A = 2 * bptr [-2] - bptr [-4];
|
|
bptr [0] = apply_weight (weight_A, sam_A) + (sam_B = bptr [0]);
|
|
update_weight (weight_A, delta, sam_A, sam_B);
|
|
|
|
sam_A = 2 * bptr [-1] - bptr [-3];
|
|
bptr [1] = apply_weight (weight_B, sam_A) + (sam_B = bptr [1]);
|
|
update_weight (weight_B, delta, sam_A, sam_B);
|
|
}
|
|
|
|
dpp->samples_B [0] = bptr [-1];
|
|
dpp->samples_A [0] = bptr [-2];
|
|
dpp->samples_B [1] = bptr [-3];
|
|
dpp->samples_A [1] = bptr [-4];
|
|
break;
|
|
|
|
case 18:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
sam_A = (3 * bptr [-2] - bptr [-4]) >> 1;
|
|
bptr [0] = apply_weight (weight_A, sam_A) + (sam_B = bptr [0]);
|
|
update_weight (weight_A, delta, sam_A, sam_B);
|
|
|
|
sam_A = (3 * bptr [-1] - bptr [-3]) >> 1;
|
|
bptr [1] = apply_weight (weight_B, sam_A) + (sam_B = bptr [1]);
|
|
update_weight (weight_B, delta, sam_A, sam_B);
|
|
}
|
|
|
|
dpp->samples_B [0] = bptr [-1];
|
|
dpp->samples_A [0] = bptr [-2];
|
|
dpp->samples_B [1] = bptr [-3];
|
|
dpp->samples_A [1] = bptr [-4];
|
|
break;
|
|
|
|
default:
|
|
for (bptr = buffer, tptr = buffer - (dpp->term * 2); bptr < eptr; bptr += 2, tptr += 2) {
|
|
bptr [0] = apply_weight (weight_A, tptr [0]) + (sam_A = bptr [0]);
|
|
update_weight (weight_A, delta, tptr [0], sam_A);
|
|
|
|
bptr [1] = apply_weight (weight_B, tptr [1]) + (sam_A = bptr [1]);
|
|
update_weight (weight_B, delta, tptr [1], sam_A);
|
|
}
|
|
|
|
for (k = dpp->term - 1, i = 8; i--; k--) {
|
|
dpp->samples_B [k & (MAX_TERM - 1)] = *--bptr;
|
|
dpp->samples_A [k & (MAX_TERM - 1)] = *--bptr;
|
|
}
|
|
|
|
break;
|
|
|
|
case -1:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
bptr [0] = apply_weight (weight_A, bptr [-1]) + (sam_A = bptr [0]);
|
|
update_weight_clip (weight_A, delta, bptr [-1], sam_A);
|
|
bptr [1] = apply_weight (weight_B, bptr [0]) + (sam_A = bptr [1]);
|
|
update_weight_clip (weight_B, delta, bptr [0], sam_A);
|
|
}
|
|
|
|
dpp->samples_A [0] = bptr [-1];
|
|
break;
|
|
|
|
case -2:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
bptr [1] = apply_weight (weight_B, bptr [-2]) + (sam_A = bptr [1]);
|
|
update_weight_clip (weight_B, delta, bptr [-2], sam_A);
|
|
bptr [0] = apply_weight (weight_A, bptr [1]) + (sam_A = bptr [0]);
|
|
update_weight_clip (weight_A, delta, bptr [1], sam_A);
|
|
}
|
|
|
|
dpp->samples_B [0] = bptr [-2];
|
|
break;
|
|
|
|
case -3:
|
|
for (bptr = buffer; bptr < eptr; bptr += 2) {
|
|
bptr [0] = apply_weight (weight_A, bptr [-1]) + (sam_A = bptr [0]);
|
|
update_weight_clip (weight_A, delta, bptr [-1], sam_A);
|
|
bptr [1] = apply_weight (weight_B, bptr [-2]) + (sam_A = bptr [1]);
|
|
update_weight_clip (weight_B, delta, bptr [-2], sam_A);
|
|
}
|
|
|
|
dpp->samples_A [0] = bptr [-1];
|
|
dpp->samples_B [0] = bptr [-2];
|
|
break;
|
|
}
|
|
|
|
dpp->weight_A = weight_A;
|
|
dpp->weight_B = weight_B;
|
|
}
|
|
|
|
#endif
|
|
|
|
static void decorr_mono_pass (struct decorr_pass *dpp, long *buffer, long sample_count)
|
|
{
|
|
long delta = dpp->delta, weight_A = dpp->weight_A;
|
|
long *bptr, *eptr = buffer + sample_count, sam_A;
|
|
int m, k;
|
|
|
|
switch (dpp->term) {
|
|
|
|
case 17:
|
|
for (bptr = buffer; bptr < eptr; bptr++) {
|
|
sam_A = 2 * dpp->samples_A [0] - dpp->samples_A [1];
|
|
dpp->samples_A [1] = dpp->samples_A [0];
|
|
dpp->samples_A [0] = apply_weight (weight_A, sam_A) + bptr [0];
|
|
update_weight (weight_A, delta, sam_A, bptr [0]);
|
|
bptr [0] = dpp->samples_A [0];
|
|
}
|
|
|
|
break;
|
|
|
|
case 18:
|
|
for (bptr = buffer; bptr < eptr; bptr++) {
|
|
sam_A = (3 * dpp->samples_A [0] - dpp->samples_A [1]) >> 1;
|
|
dpp->samples_A [1] = dpp->samples_A [0];
|
|
dpp->samples_A [0] = apply_weight (weight_A, sam_A) + bptr [0];
|
|
update_weight (weight_A, delta, sam_A, bptr [0]);
|
|
bptr [0] = dpp->samples_A [0];
|
|
}
|
|
|
|
break;
|
|
|
|
default:
|
|
for (m = 0, k = dpp->term & (MAX_TERM - 1), bptr = buffer; bptr < eptr; bptr++) {
|
|
sam_A = dpp->samples_A [m];
|
|
dpp->samples_A [k] = apply_weight (weight_A, sam_A) + bptr [0];
|
|
update_weight (weight_A, delta, sam_A, bptr [0]);
|
|
bptr [0] = dpp->samples_A [k];
|
|
m = (m + 1) & (MAX_TERM - 1);
|
|
k = (k + 1) & (MAX_TERM - 1);
|
|
}
|
|
|
|
if (m) {
|
|
long temp_samples [MAX_TERM];
|
|
|
|
memcpy (temp_samples, dpp->samples_A, sizeof (dpp->samples_A));
|
|
|
|
for (k = 0; k < MAX_TERM; k++, m++)
|
|
dpp->samples_A [k] = temp_samples [m & (MAX_TERM - 1)];
|
|
}
|
|
|
|
break;
|
|
}
|
|
|
|
dpp->weight_A = weight_A;
|
|
}
|
|
|
|
|
|
// This is a helper function for unpack_samples() that applies several final
|
|
// operations. First, if the data is 32-bit float data, then that conversion
|
|
// is done in the float.c module (whether lossy or lossless) and we return.
|
|
// Otherwise, if the extended integer data applies, then that operation is
|
|
// executed first. If the unpacked data is lossy (and not corrected) then
|
|
// it is clipped and shifted in a single operation. Otherwise, if it's
|
|
// lossless then the last step is to apply the final shift (if any).
|
|
|
|
static void fixup_samples (WavpackStream *wps, long *buffer, ulong sample_count)
|
|
{
|
|
ulong flags = wps->wphdr.flags;
|
|
int shift = (flags & SHIFT_MASK) >> SHIFT_LSB;
|
|
|
|
if (flags & FLOAT_DATA) {
|
|
float_values (wps, buffer, (flags & MONO_FLAG) ? sample_count : sample_count * 2);
|
|
return;
|
|
}
|
|
|
|
if (flags & INT32_DATA) {
|
|
ulong count = (flags & MONO_FLAG) ? sample_count : sample_count * 2;
|
|
int sent_bits = wps->int32_sent_bits, zeros = wps->int32_zeros;
|
|
int ones = wps->int32_ones, dups = wps->int32_dups;
|
|
// ulong mask = (1 << sent_bits) - 1;
|
|
long *dptr = buffer;
|
|
|
|
if (!(flags & HYBRID_FLAG) && !sent_bits && (zeros + ones + dups))
|
|
while (count--) {
|
|
if (zeros)
|
|
*dptr <<= zeros;
|
|
else if (ones)
|
|
*dptr = ((*dptr + 1) << ones) - 1;
|
|
else if (dups)
|
|
*dptr = ((*dptr + (*dptr & 1)) << dups) - (*dptr & 1);
|
|
|
|
dptr++;
|
|
}
|
|
else
|
|
shift += zeros + sent_bits + ones + dups;
|
|
}
|
|
|
|
if (flags & HYBRID_FLAG) {
|
|
long min_value, max_value, min_shifted, max_shifted;
|
|
|
|
switch (flags & BYTES_STORED) {
|
|
case 0:
|
|
min_shifted = (min_value = -128 >> shift) << shift;
|
|
max_shifted = (max_value = 127 >> shift) << shift;
|
|
break;
|
|
|
|
case 1:
|
|
min_shifted = (min_value = -32768 >> shift) << shift;
|
|
max_shifted = (max_value = 32767 >> shift) << shift;
|
|
break;
|
|
|
|
case 2:
|
|
min_shifted = (min_value = -8388608 >> shift) << shift;
|
|
max_shifted = (max_value = 8388607 >> shift) << shift;
|
|
break;
|
|
|
|
case 3:
|
|
default:
|
|
min_shifted = (min_value = (long) 0x80000000 >> shift) << shift;
|
|
max_shifted = (max_value = (long) 0x7FFFFFFF >> shift) << shift;
|
|
break;
|
|
}
|
|
|
|
if (!(flags & MONO_FLAG))
|
|
sample_count *= 2;
|
|
|
|
while (sample_count--) {
|
|
if (*buffer < min_value)
|
|
*buffer++ = min_shifted;
|
|
else if (*buffer > max_value)
|
|
*buffer++ = max_shifted;
|
|
else
|
|
*buffer++ <<= shift;
|
|
}
|
|
}
|
|
else if (shift) {
|
|
if (!(flags & MONO_FLAG))
|
|
sample_count *= 2;
|
|
|
|
while (sample_count--)
|
|
*buffer++ <<= shift;
|
|
}
|
|
}
|
|
|
|
// This function checks the crc value(s) for an unpacked block, returning the
|
|
// number of actual crc errors detected for the block. The block must be
|
|
// completely unpacked before this test is valid. For losslessly unpacked
|
|
// blocks of float or extended integer data the extended crc is also checked.
|
|
// Note that WavPack's crc is not a CCITT approved polynomial algorithm, but
|
|
// is a much simpler method that is virtually as robust for real world data.
|
|
|
|
int check_crc_error (WavpackContext *wpc)
|
|
{
|
|
WavpackStream *wps = &wpc->stream;
|
|
int result = 0;
|
|
|
|
if (wps->crc != wps->wphdr.crc)
|
|
++result;
|
|
|
|
return result;
|
|
}
|