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https://codeberg.org/ashley/poke.git
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343 lines
8.1 KiB
C
343 lines
8.1 KiB
C
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/*
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* Copyright (c) 2011 Apple Inc. All rights reserved.
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*
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* @APPLE_APACHE_LICENSE_HEADER_START@
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*
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* @APPLE_APACHE_LICENSE_HEADER_END@
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*/
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/*
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File: matrix_enc.c
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Contains: ALAC mixing/matrixing encode routines.
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Copyright: (c) 2004-2011 Apple, Inc.
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*/
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#include "matrixlib.h"
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#include "ALACAudioTypes.h"
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// up to 24-bit "offset" macros for the individual bytes of a 20/24-bit word
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#if TARGET_RT_BIG_ENDIAN
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#define LBYTE 2
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#define MBYTE 1
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#define HBYTE 0
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#else
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#define LBYTE 0
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#define MBYTE 1
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#define HBYTE 2
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#endif
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/*
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There is no plain middle-side option; instead there are various mixing
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modes including middle-side, each lossless, as embodied in the mix()
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and unmix() functions. These functions exploit a generalized middle-side
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transformation:
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u := [(rL + (m-r)R)/m];
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v := L - R;
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where [ ] denotes integer floor. The (lossless) inverse is
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L = u + v - [rV/m];
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R = L - v;
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*/
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// 16-bit routines
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void mix16( int16_t * in, uint32_t stride, int32_t * u, int32_t * v, int32_t numSamples, int32_t mixbits, int32_t mixres )
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{
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int16_t * ip = in;
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int32_t j;
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if ( mixres != 0 )
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{
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int32_t mod = 1 << mixbits;
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int32_t m2;
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/* matrixed stereo */
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m2 = mod - mixres;
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for ( j = 0; j < numSamples; j++ )
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{
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int32_t l, r;
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l = (int32_t) ip[0];
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r = (int32_t) ip[1];
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ip += stride;
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u[j] = (mixres * l + m2 * r) >> mixbits;
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v[j] = l - r;
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}
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}
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else
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{
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/* Conventional separated stereo. */
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for ( j = 0; j < numSamples; j++ )
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{
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u[j] = (int32_t) ip[0];
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v[j] = (int32_t) ip[1];
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ip += stride;
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}
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}
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}
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// 20-bit routines
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// - the 20 bits of data are left-justified in 3 bytes of storage but right-aligned for input/output predictor buffers
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void mix20( uint8_t * in, uint32_t stride, int32_t * u, int32_t * v, int32_t numSamples, int32_t mixbits, int32_t mixres )
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{
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int32_t l, r;
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uint8_t * ip = in;
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int32_t j;
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if ( mixres != 0 )
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{
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/* matrixed stereo */
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int32_t mod = 1 << mixbits;
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int32_t m2 = mod - mixres;
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for ( j = 0; j < numSamples; j++ )
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{
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l = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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l = (l << 8) >> 12;
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ip += 3;
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r = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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r = (r << 8) >> 12;
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ip += (stride - 1) * 3;
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u[j] = (mixres * l + m2 * r) >> mixbits;
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v[j] = l - r;
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}
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}
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else
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{
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/* Conventional separated stereo. */
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for ( j = 0; j < numSamples; j++ )
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{
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l = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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u[j] = (l << 8) >> 12;
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ip += 3;
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r = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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v[j] = (r << 8) >> 12;
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ip += (stride - 1) * 3;
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}
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}
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}
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// 24-bit routines
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// - the 24 bits of data are right-justified in the input/output predictor buffers
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void mix24( uint8_t * in, uint32_t stride, int32_t * u, int32_t * v, int32_t numSamples,
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int32_t mixbits, int32_t mixres, uint16_t * shiftUV, int32_t bytesShifted )
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{
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int32_t l, r;
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uint8_t * ip = in;
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int32_t shift = bytesShifted * 8;
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uint32_t mask = (1ul << shift) - 1;
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int32_t j, k;
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if ( mixres != 0 )
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{
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/* matrixed stereo */
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int32_t mod = 1 << mixbits;
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int32_t m2 = mod - mixres;
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if ( bytesShifted != 0 )
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{
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for ( j = 0, k = 0; j < numSamples; j++, k += 2 )
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{
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l = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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l = (l << 8) >> 8;
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ip += 3;
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r = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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r = (r << 8) >> 8;
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ip += (stride - 1) * 3;
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shiftUV[k + 0] = (uint16_t)(l & mask);
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shiftUV[k + 1] = (uint16_t)(r & mask);
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l >>= shift;
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r >>= shift;
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u[j] = (mixres * l + m2 * r) >> mixbits;
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v[j] = l - r;
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}
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}
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else
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{
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for ( j = 0; j < numSamples; j++ )
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{
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l = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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l = (l << 8) >> 8;
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ip += 3;
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r = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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r = (r << 8) >> 8;
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ip += (stride - 1) * 3;
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u[j] = (mixres * l + m2 * r) >> mixbits;
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v[j] = l - r;
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}
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}
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}
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else
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{
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/* Conventional separated stereo. */
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if ( bytesShifted != 0 )
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{
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for ( j = 0, k = 0; j < numSamples; j++, k += 2 )
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{
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l = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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l = (l << 8) >> 8;
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ip += 3;
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r = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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r = (r << 8) >> 8;
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ip += (stride - 1) * 3;
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shiftUV[k + 0] = (uint16_t)(l & mask);
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shiftUV[k + 1] = (uint16_t)(r & mask);
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l >>= shift;
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r >>= shift;
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u[j] = l;
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v[j] = r;
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}
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}
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else
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{
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for ( j = 0; j < numSamples; j++ )
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{
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l = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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u[j] = (l << 8) >> 8;
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ip += 3;
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r = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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v[j] = (r << 8) >> 8;
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ip += (stride - 1) * 3;
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}
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}
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}
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}
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// 32-bit routines
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// - note that these really expect the internal data width to be < 32 but the arrays are 32-bit
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// - otherwise, the calculations might overflow into the 33rd bit and be lost
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// - therefore, these routines deal with the specified "unused lower" bytes in the "shift" buffers
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void mix32( int32_t * in, uint32_t stride, int32_t * u, int32_t * v, int32_t numSamples,
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int32_t mixbits, int32_t mixres, uint16_t * shiftUV, int32_t bytesShifted )
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{
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int32_t * ip = in;
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int32_t shift = bytesShifted * 8;
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uint32_t mask = (1ul << shift) - 1;
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int32_t l, r;
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int32_t j, k;
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if ( mixres != 0 )
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{
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int32_t mod = 1 << mixbits;
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int32_t m2;
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//Assert( bytesShifted != 0 );
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/* matrixed stereo with shift */
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m2 = mod - mixres;
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for ( j = 0, k = 0; j < numSamples; j++, k += 2 )
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{
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l = ip[0];
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r = ip[1];
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ip += stride;
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shiftUV[k + 0] = (uint16_t)(l & mask);
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shiftUV[k + 1] = (uint16_t)(r & mask);
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l >>= shift;
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r >>= shift;
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u[j] = (mixres * l + m2 * r) >> mixbits;
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v[j] = l - r;
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}
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}
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else
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{
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if ( bytesShifted == 0 )
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{
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/* de-interleaving w/o shift */
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for ( j = 0; j < numSamples; j++ )
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{
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u[j] = ip[0];
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v[j] = ip[1];
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ip += stride;
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}
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}
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else
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{
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/* de-interleaving with shift */
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for ( j = 0, k = 0; j < numSamples; j++, k += 2 )
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{
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l = ip[0];
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r = ip[1];
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ip += stride;
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shiftUV[k + 0] = (uint16_t)(l & mask);
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shiftUV[k + 1] = (uint16_t)(r & mask);
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l >>= shift;
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r >>= shift;
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u[j] = l;
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v[j] = r;
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}
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}
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}
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}
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// 20/24-bit <-> 32-bit helper routines (not really matrixing but convenient to put here)
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void copy20ToPredictor( uint8_t * in, uint32_t stride, int32_t * out, int32_t numSamples )
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{
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uint8_t * ip = in;
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int32_t j;
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for ( j = 0; j < numSamples; j++ )
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{
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int32_t val;
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// 20-bit values are left-aligned in the 24-bit input buffer but right-aligned in the 32-bit output buffer
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val = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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out[j] = (val << 8) >> 12;
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ip += stride * 3;
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}
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}
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void copy24ToPredictor( uint8_t * in, uint32_t stride, int32_t * out, int32_t numSamples )
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{
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uint8_t * ip = in;
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int32_t j;
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for ( j = 0; j < numSamples; j++ )
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{
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int32_t val;
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val = (int32_t)( ((uint32_t)ip[HBYTE] << 16) | ((uint32_t)ip[MBYTE] << 8) | (uint32_t)ip[LBYTE] );
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out[j] = (val << 8) >> 8;
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ip += stride * 3;
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}
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}
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