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512 lines
18 KiB
C
512 lines
18 KiB
C
/******************************************************************************
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*
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* Copyright (C) 2014 The Android Open Source Project
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* Copyright 2003 - 2004 Open Interface North America, Inc. All rights reserved.
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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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******************************************************************************/
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/**********************************************************************************
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$Revision: #1 $
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***********************************************************************************/
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/** @file
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This file, along with synthesis-generated.c, contains the synthesis
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filterbank routines. The operations performed correspond to the
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operations described in A2DP Appendix B, Figure 12.3. Several
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mathematical optimizations are performed, particularly for the
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8-subband case.
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One important optimization is to note that the "matrixing" operation
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can be decomposed into the product of a type II discrete cosine kernel
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and another, sparse matrix.
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According to Fig 12.3, in the 8-subband case,
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@code
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N[k][i] = cos((i+0.5)*(k+4)*pi/8), k = 0..15 and i = 0..7
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@endcode
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N can be factored as R * C2, where C2 is an 8-point type II discrete
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cosine kernel given by
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@code
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C2[k][i] = cos((i+0.5)*k*pi/8)), k = 0..7 and i = 0..7
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@endcode
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R turns out to be a sparse 16x8 matrix with the following non-zero
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entries:
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@code
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R[k][k+4] = 1, k = 0..3
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R[k][abs(12-k)] = -1, k = 5..15
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@endcode
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The spec describes computing V[0..15] as N * R.
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@code
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V[0..15] = N * R = (R * C2) * R = R * (C2 * R)
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@endcode
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C2 * R corresponds to computing the discrete cosine transform of R, so
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V[0..15] can be computed by taking the DCT of R followed by assignment
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and selective negation of the DCT result into V.
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Although this was derived empirically using GNU Octave, it is
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formally demonstrated in, e.g., Liu, Chi-Min and Lee,
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Wen-Chieh. "A Unified Fast Algorithm for Cosine Modulated
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Filter Banks in Current Audio Coding Standards." Journal of
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the AES 47 (December 1999): 1061.
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Given the shift operation performed prior to computing V[0..15], it is
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clear that V[0..159] represents a rolling history of the 10 most
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recent groups of blocks input to the synthesis operation. Interpreting
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the matrix N in light of its factorization into C2 and R, R's
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sparseness has implications for interpreting the values in V. In
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particular, there is considerable redundancy in the values stored in
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V. Furthermore, since R[4][0..7] are all zeros, one out of every 16
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values in V will be zero regardless of the input data. Within each
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block of 16 values in V, fully half of them are redundant or
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irrelevant:
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@code
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V[ 0] = DCT[4]
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V[ 1] = DCT[5]
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V[ 2] = DCT[6]
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V[ 3] = DCT[7]
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V[ 4] = 0
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V[ 5] = -DCT[7] = -V[3] (redundant)
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V[ 6] = -DCT[6] = -V[2] (redundant)
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V[ 7] = -DCT[5] = -V[1] (redundant)
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V[ 8] = -DCT[4] = -V[0] (redundant)
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V[ 9] = -DCT[3]
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V[10] = -DCT[2]
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V[11] = -DCT[1]
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V[12] = -DCT[0]
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V[13] = -DCT[1] = V[11] (redundant)
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V[14] = -DCT[2] = V[10] (redundant)
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V[15] = -DCT[3] = V[ 9] (redundant)
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@endcode
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Since the elements of V beyond 15 were originally computed the same
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way during a previous run, what holds true for V[x] also holds true
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for V[x+16]. Thus, so long as care is taken to maintain the mapping,
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we need only actually store the unique values, which correspond to the
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output of the DCT, in some cases inverted. In fact, instead of storing
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V[0..159], we could store DCT[0..79] which would contain a history of
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DCT results. More on this in a bit.
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Going back to figure 12.3 in the spec, it should be clear that the
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vector U need not actually be explicitly constructed, but that with
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suitable indexing into V during the window operation, the same end can
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be accomplished. In the same spirit of the pseudocode shown in the
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figure, the following is the construction of W without using U:
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@code
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for i=0 to 79 do
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W[i] = D[i]*VSIGN(i)*V[remap_V(i)] where remap_V(i) = 32*(int(i/16)) + (i % 16) + (i % 16 >= 8 ? 16 : 0)
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and VSIGN(i) maps i%16 into {1, 1, 1, 1, 0, -1, -1, -1, -1, 1, 1, 1, 1, 1, 1 }
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These values correspond to the
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signs of the redundant values as
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shown in the explanation three
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paragraphs above.
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@endcode
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We saw above how V[4..8,13..15] (and by extension
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V[(4..8,13..15)+16*n]) can be defined in terms of other elements
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within the subblock of V. V[0..3,9..12] correspond to DCT elements.
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@code
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for i=0 to 79 do
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W[i] = D[i]*DSIGN(i)*DCT[remap_DCT(i)]
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@endcode
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The DCT is calculated using the Arai-Agui-Nakajima factorization,
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which saves some computation by producing output that needs to be
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multiplied by scaling factors before being used.
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@code
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for i=0 to 79 do
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W[i] = D[i]*SCALE[i%8]*AAN_DCT[remap_DCT(i)]
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@endcode
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D can be premultiplied with the DCT scaling factors to yield
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@code
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for i=0 to 79 do
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W[i] = DSCALED[i]*AAN_DCT[remap_DCT(i)] where DSCALED[i] = D[i]*SCALE[i%8]
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@endcode
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The output samples X[0..7] are defined as sums of W:
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@code
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X[j] = sum{i=0..9}(W[j+8*i])
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@endcode
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@ingroup codec_internal
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*/
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/**
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@addtogroup codec_internal
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@{
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*/
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#include "common/bt_target.h"
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#include "oi_codec_sbc_private.h"
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#if (defined(SBC_DEC_INCLUDED) && SBC_DEC_INCLUDED == TRUE)
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const OI_INT32 dec_window_4[21] = {
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0, /* +0.00000000E+00 */
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97, /* +5.36548976E-04 */
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270, /* +1.49188357E-03 */
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495, /* +2.73370904E-03 */
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694, /* +3.83720193E-03 */
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704, /* +3.89205149E-03 */
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338, /* +1.86581691E-03 */
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-554, /* -3.06012286E-03 */
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1974, /* +1.09137620E-02 */
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3697, /* +2.04385087E-02 */
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5224, /* +2.88757392E-02 */
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5824, /* +3.21939290E-02 */
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4681, /* +2.58767811E-02 */
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1109, /* +6.13245186E-03 */
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-5214, /* -2.88217274E-02 */
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-14047, /* -7.76463494E-02 */
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24529, /* +1.35593274E-01 */
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35274, /* +1.94987841E-01 */
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44618, /* +2.46636662E-01 */
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50984, /* +2.81828203E-01 */
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53243, /* +2.94315332E-01 */
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};
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#define DCTII_4_K06_FIX ( 11585)/* S1.14 11585 0.707107*/
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#define DCTII_4_K08_FIX ( 21407)/* S1.14 21407 1.306563*/
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#define DCTII_4_K09_FIX (-15137)/* S1.14 -15137 -0.923880*/
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#define DCTII_4_K10_FIX ( -8867)/* S1.14 -8867 -0.541196*/
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/** Scales x by y bits to the right, adding a rounding factor.
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*/
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#ifndef SCALE
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#define SCALE(x, y) (((x) + (1 <<((y)-1))) >> (y))
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#endif
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#ifndef CLIP_INT16
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#define CLIP_INT16(x) do { if (x > OI_INT16_MAX) { x = OI_INT16_MAX; } else if (x < OI_INT16_MIN) { x = OI_INT16_MIN; } } while (0)
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#endif
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/**
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* Default C language implementation of a 16x32->32 multiply. This function may
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* be replaced by a platform-specific version for speed.
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*
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* @param u A signed 16-bit multiplicand
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* @param v A signed 32-bit multiplier
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* @return A signed 32-bit value corresponding to the 32 most significant bits
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* of the 48-bit product of u and v.
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*/
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static INLINE OI_INT32 default_mul_16s_32s_hi(OI_INT16 u, OI_INT32 v)
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{
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OI_UINT16 v0;
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OI_INT16 v1;
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OI_INT32 w, x;
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v0 = (OI_UINT16)(v & 0xffff);
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v1 = (OI_INT16) (v >> 16);
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w = v1 * u;
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x = u * v0;
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return w + (x >> 16);
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}
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#define MUL_16S_32S_HI(_x, _y) default_mul_16s_32s_hi(_x, _y)
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#define LONG_MULT_DCT(K, sample) (MUL_16S_32S_HI(K, sample)<<2)
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PRIVATE void SynthWindow80_generated(OI_INT16 *pcm, SBC_BUFFER_T const *RESTRICT buffer, OI_UINT strideShift);
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PRIVATE void SynthWindow112_generated(OI_INT16 *pcm, SBC_BUFFER_T const *RESTRICT buffer, OI_UINT strideShift);
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PRIVATE void dct2_8(SBC_BUFFER_T *RESTRICT out, OI_INT32 const *RESTRICT x);
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typedef void (*SYNTH_FRAME)(OI_CODEC_SBC_DECODER_CONTEXT *context, OI_INT16 *pcm, OI_UINT blkstart, OI_UINT blkcount);
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#ifndef COPY_BACKWARD_32BIT_ALIGNED_72_HALFWORDS
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#define COPY_BACKWARD_32BIT_ALIGNED_72_HALFWORDS(dest, src) do { shift_buffer(dest, src, 72); } while (0)
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#endif
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#ifndef DCT2_8
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#define DCT2_8(dst, src) dct2_8(dst, src)
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#endif
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#ifndef SYNTH80
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#define SYNTH80 SynthWindow80_generated
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#endif
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#ifndef SYNTH112
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#define SYNTH112 SynthWindow112_generated
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#endif
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PRIVATE void OI_SBC_SynthFrame_80(OI_CODEC_SBC_DECODER_CONTEXT *context, OI_INT16 *pcm, OI_UINT blkstart, OI_UINT blkcount)
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{
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OI_UINT blk;
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OI_UINT ch;
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OI_UINT nrof_channels = context->common.frameInfo.nrof_channels;
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OI_UINT pcmStrideShift = context->common.pcmStride == 1 ? 0 : 1;
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OI_UINT offset = context->common.filterBufferOffset;
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OI_INT32 *s = context->common.subdata + 8 * nrof_channels * blkstart;
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OI_UINT blkstop = blkstart + blkcount;
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for (blk = blkstart; blk < blkstop; blk++) {
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if (offset == 0) {
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COPY_BACKWARD_32BIT_ALIGNED_72_HALFWORDS(context->common.filterBuffer[0] + context->common.filterBufferLen - 72, context->common.filterBuffer[0]);
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if (nrof_channels == 2) {
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COPY_BACKWARD_32BIT_ALIGNED_72_HALFWORDS(context->common.filterBuffer[1] + context->common.filterBufferLen - 72, context->common.filterBuffer[1]);
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}
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offset = context->common.filterBufferLen - 80;
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} else {
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offset -= 1 * 8;
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}
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for (ch = 0; ch < nrof_channels; ch++) {
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DCT2_8(context->common.filterBuffer[ch] + offset, s);
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SYNTH80(pcm + ch, context->common.filterBuffer[ch] + offset, pcmStrideShift);
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s += 8;
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}
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pcm += (8 << pcmStrideShift);
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}
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context->common.filterBufferOffset = offset;
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}
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PRIVATE void OI_SBC_SynthFrame_4SB(OI_CODEC_SBC_DECODER_CONTEXT *context, OI_INT16 *pcm, OI_UINT blkstart, OI_UINT blkcount)
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{
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OI_UINT blk;
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OI_UINT ch;
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OI_UINT nrof_channels = context->common.frameInfo.nrof_channels;
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OI_UINT pcmStrideShift = context->common.pcmStride == 1 ? 0 : 1;
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OI_UINT offset = context->common.filterBufferOffset;
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OI_INT32 *s = context->common.subdata + 8 * nrof_channels * blkstart;
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OI_UINT blkstop = blkstart + blkcount;
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for (blk = blkstart; blk < blkstop; blk++) {
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if (offset == 0) {
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COPY_BACKWARD_32BIT_ALIGNED_72_HALFWORDS(context->common.filterBuffer[0] + context->common.filterBufferLen - 72, context->common.filterBuffer[0]);
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if (nrof_channels == 2) {
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COPY_BACKWARD_32BIT_ALIGNED_72_HALFWORDS(context->common.filterBuffer[1] + context->common.filterBufferLen - 72, context->common.filterBuffer[1]);
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}
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offset = context->common.filterBufferLen - 80;
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} else {
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offset -= 8;
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}
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for (ch = 0; ch < nrof_channels; ch++) {
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cosineModulateSynth4(context->common.filterBuffer[ch] + offset, s);
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SynthWindow40_int32_int32_symmetry_with_sum(pcm + ch,
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context->common.filterBuffer[ch] + offset,
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pcmStrideShift);
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s += 4;
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}
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pcm += (4 << pcmStrideShift);
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}
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context->common.filterBufferOffset = offset;
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}
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#ifdef SBC_ENHANCED
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PRIVATE void OI_SBC_SynthFrame_Enhanced(OI_CODEC_SBC_DECODER_CONTEXT *context, OI_INT16 *pcm, OI_UINT blkstart, OI_UINT blkcount)
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{
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OI_UINT blk;
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OI_UINT ch;
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OI_UINT nrof_channels = context->common.frameInfo.nrof_channels;
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OI_UINT pcmStrideShift = context->common.pcmStride == 1 ? 0 : 1;
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OI_UINT offset = context->common.filterBufferOffset;
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OI_INT32 *s = context->common.subdata + 8 * nrof_channels * blkstart;
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OI_UINT blkstop = blkstart + blkcount;
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for (blk = blkstart; blk < blkstop; blk++) {
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if (offset == 0) {
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COPY_BACKWARD_32BIT_ALIGNED_104_HALFWORDS(context->common.filterBuffer[0] + context->common.filterBufferLen - 104, context->common.filterBuffer[0]);
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if (nrof_channels == 2) {
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COPY_BACKWARD_32BIT_ALIGNED_104_HALFWORDS(context->common.filterBuffer[1] + context->common.filterBufferLen - 104, context->common.filterBuffer[1]);
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}
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offset = context->common.filterBufferLen - 112;
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} else {
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offset -= 8;
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}
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for (ch = 0; ch < nrof_channels; ++ch) {
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DCT2_8(context->common.filterBuffer[ch] + offset, s);
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SYNTH112(pcm + ch, context->common.filterBuffer[ch] + offset, pcmStrideShift);
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s += 8;
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}
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pcm += (8 << pcmStrideShift);
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}
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context->common.filterBufferOffset = offset;
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}
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static const SYNTH_FRAME SynthFrameEnhanced[] = {
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NULL, /* invalid */
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OI_SBC_SynthFrame_Enhanced, /* mono */
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OI_SBC_SynthFrame_Enhanced /* stereo */
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};
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#endif
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static const SYNTH_FRAME SynthFrame8SB[] = {
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NULL, /* invalid */
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OI_SBC_SynthFrame_80, /* mono */
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OI_SBC_SynthFrame_80 /* stereo */
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};
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static const SYNTH_FRAME SynthFrame4SB[] = {
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NULL, /* invalid */
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OI_SBC_SynthFrame_4SB, /* mono */
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OI_SBC_SynthFrame_4SB /* stereo */
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};
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PRIVATE void OI_SBC_SynthFrame(OI_CODEC_SBC_DECODER_CONTEXT *context, OI_INT16 *pcm, OI_UINT start_block, OI_UINT nrof_blocks)
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{
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OI_UINT nrof_subbands = context->common.frameInfo.nrof_subbands;
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OI_UINT nrof_channels = context->common.frameInfo.nrof_channels;
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OI_ASSERT(nrof_subbands == 4 || nrof_subbands == 8);
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if (nrof_subbands == 4) {
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SynthFrame4SB[nrof_channels](context, pcm, start_block, nrof_blocks);
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#ifdef SBC_ENHANCED
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} else if (context->common.frameInfo.enhanced) {
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SynthFrameEnhanced[nrof_channels](context, pcm, start_block, nrof_blocks);
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#endif /* SBC_ENHANCED */
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} else {
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SynthFrame8SB[nrof_channels](context, pcm, start_block, nrof_blocks);
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}
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}
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void SynthWindow40_int32_int32_symmetry_with_sum(OI_INT16 *pcm, SBC_BUFFER_T buffer[80], OI_UINT strideShift)
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{
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OI_INT32 pa;
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OI_INT32 pb;
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/* These values should be zero, since out[2] of the 4-band cosine modulation
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* is always zero. */
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OI_ASSERT(buffer[ 2] == 0);
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OI_ASSERT(buffer[10] == 0);
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OI_ASSERT(buffer[18] == 0);
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OI_ASSERT(buffer[26] == 0);
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OI_ASSERT(buffer[34] == 0);
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OI_ASSERT(buffer[42] == 0);
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OI_ASSERT(buffer[50] == 0);
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OI_ASSERT(buffer[58] == 0);
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OI_ASSERT(buffer[66] == 0);
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OI_ASSERT(buffer[74] == 0);
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pa = dec_window_4[ 4] * (buffer[12] + buffer[76]);
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pa += dec_window_4[ 8] * (buffer[16] - buffer[64]);
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pa += dec_window_4[12] * (buffer[28] + buffer[60]);
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pa += dec_window_4[16] * (buffer[32] - buffer[48]);
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pa += dec_window_4[20] * buffer[44];
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pa = SCALE(-pa, 15);
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CLIP_INT16(pa);
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pcm[0 << strideShift] = (OI_INT16)pa;
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pa = dec_window_4[ 1] * buffer[ 1]; pb = dec_window_4[ 1] * buffer[79];
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pb += dec_window_4[ 3] * buffer[ 3]; pa += dec_window_4[ 3] * buffer[77];
|
|
pa += dec_window_4[ 5] * buffer[13]; pb += dec_window_4[ 5] * buffer[67];
|
|
pb += dec_window_4[ 7] * buffer[15]; pa += dec_window_4[ 7] * buffer[65];
|
|
pa += dec_window_4[ 9] * buffer[17]; pb += dec_window_4[ 9] * buffer[63];
|
|
pb += dec_window_4[11] * buffer[19]; pa += dec_window_4[11] * buffer[61];
|
|
pa += dec_window_4[13] * buffer[29]; pb += dec_window_4[13] * buffer[51];
|
|
pb += dec_window_4[15] * buffer[31]; pa += dec_window_4[15] * buffer[49];
|
|
pa += dec_window_4[17] * buffer[33]; pb += dec_window_4[17] * buffer[47];
|
|
pb += dec_window_4[19] * buffer[35]; pa += dec_window_4[19] * buffer[45];
|
|
pa = SCALE(-pa, 15);
|
|
CLIP_INT16(pa);
|
|
pcm[1 << strideShift] = (OI_INT16)(pa);
|
|
pb = SCALE(-pb, 15);
|
|
CLIP_INT16(pb);
|
|
pcm[3 << strideShift] = (OI_INT16)(pb);
|
|
|
|
|
|
pa = dec_window_4[2] * (/*buffer[ 2] + */ buffer[78]); /* buffer[ 2] is always zero */
|
|
pa += dec_window_4[6] * (buffer[14] /* + buffer[66]*/); /* buffer[66] is always zero */
|
|
pa += dec_window_4[10] * (/*buffer[18] + */ buffer[62]); /* buffer[18] is always zero */
|
|
pa += dec_window_4[14] * (buffer[30] /* + buffer[50]*/); /* buffer[50] is always zero */
|
|
pa += dec_window_4[18] * (/*buffer[34] + */ buffer[46]); /* buffer[34] is always zero */
|
|
pa = SCALE(-pa, 15);
|
|
CLIP_INT16(pa);
|
|
pcm[2 << strideShift] = (OI_INT16)(pa);
|
|
}
|
|
|
|
|
|
/**
|
|
This routine implements the cosine modulation matrix for 4-subband
|
|
synthesis. This is called "matrixing" in the SBC specification. This
|
|
matrix, M4, can be factored into an 8-point Type II Discrete Cosine
|
|
Transform, DCTII_4 and a matrix S4, given here:
|
|
|
|
@code
|
|
__ __
|
|
| 0 0 1 0 |
|
|
| 0 0 0 1 |
|
|
| 0 0 0 0 |
|
|
| 0 0 0 -1 |
|
|
S4 = | 0 0 -1 0 |
|
|
| 0 -1 0 0 |
|
|
| -1 0 0 0 |
|
|
|__ 0 -1 0 0 __|
|
|
|
|
M4 * in = S4 * (DCTII_4 * in)
|
|
@endcode
|
|
|
|
(DCTII_4 * in) is computed using a Fast Cosine Transform. The algorithm
|
|
here is based on an implementation computed by the SPIRAL computer
|
|
algebra system, manually converted to fixed-point arithmetic. S4 can be
|
|
implemented using only assignment and negation.
|
|
*/
|
|
PRIVATE void cosineModulateSynth4(SBC_BUFFER_T *RESTRICT out, OI_INT32 const *RESTRICT in)
|
|
{
|
|
OI_INT32 f0, f1, f2, f3, f4, f7, f8, f9, f10;
|
|
OI_INT32 y0, y1, y2, y3;
|
|
|
|
f0 = (in[0] - in[3]);
|
|
f1 = (in[0] + in[3]);
|
|
f2 = (in[1] - in[2]);
|
|
f3 = (in[1] + in[2]);
|
|
|
|
f4 = f1 - f3;
|
|
|
|
y0 = -SCALE(f1 + f3, DCT_SHIFT);
|
|
y2 = -SCALE(LONG_MULT_DCT(DCTII_4_K06_FIX, f4), DCT_SHIFT);
|
|
f7 = f0 + f2;
|
|
f8 = LONG_MULT_DCT(DCTII_4_K08_FIX, f0);
|
|
f9 = LONG_MULT_DCT(DCTII_4_K09_FIX, f7);
|
|
f10 = LONG_MULT_DCT(DCTII_4_K10_FIX, f2);
|
|
y3 = -SCALE(f8 + f9, DCT_SHIFT);
|
|
y1 = -SCALE(f10 - f9, DCT_SHIFT);
|
|
|
|
out[0] = (OI_INT16) - y2;
|
|
out[1] = (OI_INT16) - y3;
|
|
out[2] = (OI_INT16)0;
|
|
out[3] = (OI_INT16)y3;
|
|
out[4] = (OI_INT16)y2;
|
|
out[5] = (OI_INT16)y1;
|
|
out[6] = (OI_INT16)y0;
|
|
out[7] = (OI_INT16)y1;
|
|
}
|
|
|
|
/**
|
|
@}
|
|
*/
|
|
#endif /* #if (defined(SBC_DEC_INCLUDED) && SBC_DEC_INCLUDED == TRUE) */
|