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9ac53e9a2a
Original commit message from CVS: don't mix tabs and spaces
380 lines
15 KiB
C
380 lines
15 KiB
C
/*
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* jrevdct.c
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*
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* Copyright (C) 1991, 1992, Thomas G. Lane.
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* This file is part of the Independent JPEG Group's software.
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* For conditions of distribution and use, see the accompanying README file.
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*
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* This file contains the basic inverse-DCT transformation subroutine.
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*
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* This implementation is based on an algorithm described in
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* C. Loeffler, A. Ligtenberg and G. Moschytz, "Practical Fast 1-D DCT
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* Algorithms with 11 Multiplications", Proc. Int'l. Conf. on Acoustics,
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* Speech, and Signal Processing 1989 (ICASSP '89), pp. 988-991.
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* The primary algorithm described there uses 11 multiplies and 29 adds.
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* We use their alternate method with 12 multiplies and 32 adds.
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* The advantage of this method is that no data path contains more than one
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* multiplication; this allows a very simple and accurate implementation in
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* scaled fixed-point arithmetic, with a minimal number of shifts.
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*/
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include "dct.h"
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/* We assume that right shift corresponds to signed division by 2 with
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* rounding towards minus infinity. This is correct for typical "arithmetic
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* shift" instructions that shift in copies of the sign bit. But some
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* C compilers implement >> with an unsigned shift. For these machines you
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* must define RIGHT_SHIFT_IS_UNSIGNED.
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* RIGHT_SHIFT provides a proper signed right shift of an INT32 quantity.
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* It is only applied with constant shift counts. SHIFT_TEMPS must be
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* included in the variables of any routine using RIGHT_SHIFT.
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*/
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#ifdef RIGHT_SHIFT_IS_UNSIGNED
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#define SHIFT_TEMPS INT32 shift_temp;
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#define RIGHT_SHIFT(x,shft) \
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((shift_temp = (x)) < 0 ? \
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(shift_temp >> (shft)) | ((~((INT32) 0)) << (32-(shft))) : \
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(shift_temp >> (shft)))
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#else
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#define SHIFT_TEMPS
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#define RIGHT_SHIFT(x,shft) ((x) >> (shft))
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#endif
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/*
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* This routine is specialized to the case DCTSIZE = 8.
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*/
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#if DCTSIZE != 8
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Sorry, this code only copes with 8 x8 DCTs. /* deliberate syntax err */
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#endif
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/*
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* A 2-D IDCT can be done by 1-D IDCT on each row followed by 1-D IDCT
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* on each column. Direct algorithms are also available, but they are
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* much more complex and seem not to be any faster when reduced to code.
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*
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* The poop on this scaling stuff is as follows:
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*
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* Each 1-D IDCT step produces outputs which are a factor of sqrt(N)
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* larger than the true IDCT outputs. The final outputs are therefore
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* a factor of N larger than desired; since N=8 this can be cured by
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* a simple right shift at the end of the algorithm. The advantage of
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* this arrangement is that we save two multiplications per 1-D IDCT,
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* because the y0 and y4 inputs need not be divided by sqrt(N).
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*
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* We have to do addition and subtraction of the integer inputs, which
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* is no problem, and multiplication by fractional constants, which is
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* a problem to do in integer arithmetic. We multiply all the constants
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* by CONST_SCALE and convert them to integer constants (thus retaining
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* CONST_BITS bits of precision in the constants). After doing a
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* multiplication we have to divide the product by CONST_SCALE, with proper
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* rounding, to produce the correct output. This division can be done
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* cheaply as a right shift of CONST_BITS bits. We postpone shifting
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* as long as possible so that partial sums can be added together with
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* full fractional precision.
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*
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* The outputs of the first pass are scaled up by PASS1_BITS bits so that
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* they are represented to better-than-integral precision. These outputs
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* require BITS_IN_JSAMPLE + PASS1_BITS + 3 bits; this fits in a 16-bit word
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* with the recommended scaling. (To scale up 12-bit sample data further, an
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* intermediate INT32 array would be needed.)
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*
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* To avoid overflow of the 32-bit intermediate results in pass 2, we must
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* have BITS_IN_JSAMPLE + CONST_BITS + PASS1_BITS <= 26. Error analysis
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* shows that the values given below are the most effective.
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*/
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#ifdef EIGHT_BIT_SAMPLES
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#define CONST_BITS 13
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#define PASS1_BITS 2
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#else
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#define CONST_BITS 13
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#define PASS1_BITS 1 /* lose a little precision to avoid overflow */
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#endif
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#define ONE ((INT32) 1)
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#define CONST_SCALE (ONE << CONST_BITS)
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/* Convert a positive real constant to an integer scaled by CONST_SCALE. */
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#define FIX(x) ((INT32) ((x) * CONST_SCALE + 0.5))
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/* Some C compilers fail to reduce "FIX(constant)" at compile time, thus
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* causing a lot of useless floating-point operations at run time.
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* To get around this we use the following pre-calculated constants.
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* If you change CONST_BITS you may want to add appropriate values.
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* (With a reasonable C compiler, you can just rely on the FIX() macro...)
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*/
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#if CONST_BITS == 13
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#define FIX_0_298631336 ((INT32) 2446) /* FIX(0.298631336) */
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#define FIX_0_390180644 ((INT32) 3196) /* FIX(0.390180644) */
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#define FIX_0_541196100 ((INT32) 4433) /* FIX(0.541196100) */
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#define FIX_0_765366865 ((INT32) 6270) /* FIX(0.765366865) */
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#define FIX_0_899976223 ((INT32) 7373) /* FIX(0.899976223) */
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#define FIX_1_175875602 ((INT32) 9633) /* FIX(1.175875602) */
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#define FIX_1_501321110 ((INT32) 12299) /* FIX(1.501321110) */
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#define FIX_1_847759065 ((INT32) 15137) /* FIX(1.847759065) */
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#define FIX_1_961570560 ((INT32) 16069) /* FIX(1.961570560) */
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#define FIX_2_053119869 ((INT32) 16819) /* FIX(2.053119869) */
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#define FIX_2_562915447 ((INT32) 20995) /* FIX(2.562915447) */
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#define FIX_3_072711026 ((INT32) 25172) /* FIX(3.072711026) */
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#else
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#define FIX_0_298631336 FIX(0.298631336)
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#define FIX_0_390180644 FIX(0.390180644)
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#define FIX_0_541196100 FIX(0.541196100)
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#define FIX_0_765366865 FIX(0.765366865)
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#define FIX_0_899976223 FIX(0.899976223)
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#define FIX_1_175875602 FIX(1.175875602)
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#define FIX_1_501321110 FIX(1.501321110)
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#define FIX_1_847759065 FIX(1.847759065)
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#define FIX_1_961570560 FIX(1.961570560)
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#define FIX_2_053119869 FIX(2.053119869)
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#define FIX_2_562915447 FIX(2.562915447)
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#define FIX_3_072711026 FIX(3.072711026)
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#endif
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/* Descale and correctly round an INT32 value that's scaled by N bits.
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* We assume RIGHT_SHIFT rounds towards minus infinity, so adding
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* the fudge factor is correct for either sign of X.
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*/
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#define DESCALE(x,n) RIGHT_SHIFT((x) + (ONE << ((n)-1)), n)
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/* Multiply an INT32 variable by an INT32 constant to yield an INT32 result.
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* For 8-bit samples with the recommended scaling, all the variable
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* and constant values involved are no more than 16 bits wide, so a
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* 16x16->32 bit multiply can be used instead of a full 32x32 multiply;
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* this provides a useful speedup on many machines.
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* There is no way to specify a 16x16->32 multiply in portable C, but
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* some C compilers will do the right thing if you provide the correct
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* combination of casts.
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* NB: for 12-bit samples, a full 32-bit multiplication will be needed.
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*/
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#ifdef EIGHT_BIT_SAMPLES
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#ifdef SHORTxSHORT_32 /* may work if 'int' is 32 bits */
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#define MULTIPLY(var,const) (((INT16) (var)) * ((INT16) (const)))
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#endif
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#ifdef SHORTxLCONST_32 /* known to work with Microsoft C 6.0 */
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#define MULTIPLY(var,const) (((INT16) (var)) * ((INT32) (const)))
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#endif
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#endif
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#ifndef MULTIPLY /* default definition */
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#define MULTIPLY(var,const) ((var) * (const))
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#endif
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/*
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* Perform the inverse DCT on one block of coefficients.
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*/
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void
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gst_idct_int_idct (DCTBLOCK data)
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{
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INT32 tmp0, tmp1, tmp2, tmp3;
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INT32 tmp10, tmp11, tmp12, tmp13;
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INT32 z1, z2, z3, z4, z5;
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register DCTELEM *dataptr;
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int rowctr;
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SHIFT_TEMPS
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/* Pass 1: process rows. */
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/* Note results are scaled up by sqrt(8) compared to a true IDCT; */
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/* furthermore, we scale the results by 2**PASS1_BITS. */
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dataptr = data;
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for (rowctr = DCTSIZE - 1; rowctr >= 0; rowctr--) {
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/* Due to quantization, we will usually find that many of the input
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* coefficients are zero, especially the AC terms. We can exploit this
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* by short-circuiting the IDCT calculation for any row in which all
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* the AC terms are zero. In that case each output is equal to the
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* DC coefficient (with scale factor as needed).
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* With typical images and quantization tables, half or more of the
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* row DCT calculations can be simplified this way.
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*/
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if ((dataptr[1] | dataptr[2] | dataptr[3] | dataptr[4] |
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dataptr[5] | dataptr[6] | dataptr[7]) == 0) {
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/* AC terms all zero */
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DCTELEM dcval = (DCTELEM) (dataptr[0] << PASS1_BITS);
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dataptr[0] = dcval;
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dataptr[1] = dcval;
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dataptr[2] = dcval;
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dataptr[3] = dcval;
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dataptr[4] = dcval;
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dataptr[5] = dcval;
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dataptr[6] = dcval;
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dataptr[7] = dcval;
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dataptr += DCTSIZE; /* advance pointer to next row */
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continue;
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}
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/* Even part: reverse the even part of the forward DCT. */
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/* The rotator is sqrt(2)*c(-6). */
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z2 = (INT32) dataptr[2];
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z3 = (INT32) dataptr[6];
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z1 = MULTIPLY (z2 + z3, FIX_0_541196100);
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tmp2 = z1 + MULTIPLY (z3, -FIX_1_847759065);
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tmp3 = z1 + MULTIPLY (z2, FIX_0_765366865);
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tmp0 = ((INT32) dataptr[0] + (INT32) dataptr[4]) << CONST_BITS;
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tmp1 = ((INT32) dataptr[0] - (INT32) dataptr[4]) << CONST_BITS;
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tmp10 = tmp0 + tmp3;
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tmp13 = tmp0 - tmp3;
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tmp11 = tmp1 + tmp2;
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tmp12 = tmp1 - tmp2;
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/* Odd part per figure 8; the matrix is unitary and hence its
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* transpose is its inverse. i0..i3 are y7,y5,y3,y1 respectively.
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*/
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tmp0 = (INT32) dataptr[7];
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tmp1 = (INT32) dataptr[5];
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tmp2 = (INT32) dataptr[3];
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tmp3 = (INT32) dataptr[1];
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z1 = tmp0 + tmp3;
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z2 = tmp1 + tmp2;
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z3 = tmp0 + tmp2;
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z4 = tmp1 + tmp3;
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z5 = MULTIPLY (z3 + z4, FIX_1_175875602); /* sqrt(2) * c3 */
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tmp0 = MULTIPLY (tmp0, FIX_0_298631336); /* sqrt(2) * (-c1+c3+c5-c7) */
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tmp1 = MULTIPLY (tmp1, FIX_2_053119869); /* sqrt(2) * ( c1+c3-c5+c7) */
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tmp2 = MULTIPLY (tmp2, FIX_3_072711026); /* sqrt(2) * ( c1+c3+c5-c7) */
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tmp3 = MULTIPLY (tmp3, FIX_1_501321110); /* sqrt(2) * ( c1+c3-c5-c7) */
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z1 = MULTIPLY (z1, -FIX_0_899976223); /* sqrt(2) * (c7-c3) */
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z2 = MULTIPLY (z2, -FIX_2_562915447); /* sqrt(2) * (-c1-c3) */
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z3 = MULTIPLY (z3, -FIX_1_961570560); /* sqrt(2) * (-c3-c5) */
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z4 = MULTIPLY (z4, -FIX_0_390180644); /* sqrt(2) * (c5-c3) */
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z3 += z5;
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z4 += z5;
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tmp0 += z1 + z3;
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tmp1 += z2 + z4;
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tmp2 += z2 + z3;
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tmp3 += z1 + z4;
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/* Final output stage: inputs are tmp10..tmp13, tmp0..tmp3 */
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dataptr[0] = (DCTELEM) DESCALE (tmp10 + tmp3, CONST_BITS - PASS1_BITS);
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dataptr[7] = (DCTELEM) DESCALE (tmp10 - tmp3, CONST_BITS - PASS1_BITS);
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dataptr[1] = (DCTELEM) DESCALE (tmp11 + tmp2, CONST_BITS - PASS1_BITS);
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dataptr[6] = (DCTELEM) DESCALE (tmp11 - tmp2, CONST_BITS - PASS1_BITS);
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dataptr[2] = (DCTELEM) DESCALE (tmp12 + tmp1, CONST_BITS - PASS1_BITS);
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dataptr[5] = (DCTELEM) DESCALE (tmp12 - tmp1, CONST_BITS - PASS1_BITS);
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dataptr[3] = (DCTELEM) DESCALE (tmp13 + tmp0, CONST_BITS - PASS1_BITS);
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dataptr[4] = (DCTELEM) DESCALE (tmp13 - tmp0, CONST_BITS - PASS1_BITS);
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dataptr += DCTSIZE; /* advance pointer to next row */
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}
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/* Pass 2: process columns. */
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/* Note that we must descale the results by a factor of 8 == 2**3, */
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/* and also undo the PASS1_BITS scaling. */
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dataptr = data;
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for (rowctr = DCTSIZE - 1; rowctr >= 0; rowctr--) {
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/* Columns of zeroes can be exploited in the same way as we did with rows.
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* However, the row calculation has created many nonzero AC terms, so the
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* simplification applies less often (typically 5% to 10% of the time).
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* On machines with very fast multiplication, it's possible that the
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* test takes more time than it's worth. In that case this section
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* may be commented out.
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*/
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#ifndef NO_ZERO_COLUMN_TEST
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if ((dataptr[DCTSIZE * 1] | dataptr[DCTSIZE * 2] | dataptr[DCTSIZE * 3] |
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dataptr[DCTSIZE * 4] | dataptr[DCTSIZE * 5] | dataptr[DCTSIZE * 6] |
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dataptr[DCTSIZE * 7]) == 0) {
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/* AC terms all zero */
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DCTELEM dcval = (DCTELEM) DESCALE ((INT32) dataptr[0], PASS1_BITS + 3);
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dataptr[DCTSIZE * 0] = dcval;
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dataptr[DCTSIZE * 1] = dcval;
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dataptr[DCTSIZE * 2] = dcval;
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dataptr[DCTSIZE * 3] = dcval;
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dataptr[DCTSIZE * 4] = dcval;
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dataptr[DCTSIZE * 5] = dcval;
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dataptr[DCTSIZE * 6] = dcval;
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dataptr[DCTSIZE * 7] = dcval;
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dataptr++; /* advance pointer to next column */
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continue;
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}
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#endif
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/* Even part: reverse the even part of the forward DCT. */
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/* The rotator is sqrt(2)*c(-6). */
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z2 = (INT32) dataptr[DCTSIZE * 2];
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z3 = (INT32) dataptr[DCTSIZE * 6];
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z1 = MULTIPLY (z2 + z3, FIX_0_541196100);
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tmp2 = z1 + MULTIPLY (z3, -FIX_1_847759065);
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tmp3 = z1 + MULTIPLY (z2, FIX_0_765366865);
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tmp0 =
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((INT32) dataptr[DCTSIZE * 0] +
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(INT32) dataptr[DCTSIZE * 4]) << CONST_BITS;
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tmp1 =
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((INT32) dataptr[DCTSIZE * 0] -
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(INT32) dataptr[DCTSIZE * 4]) << CONST_BITS;
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tmp10 = tmp0 + tmp3;
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tmp13 = tmp0 - tmp3;
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tmp11 = tmp1 + tmp2;
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tmp12 = tmp1 - tmp2;
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/* Odd part per figure 8; the matrix is unitary and hence its
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* transpose is its inverse. i0..i3 are y7,y5,y3,y1 respectively.
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*/
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tmp0 = (INT32) dataptr[DCTSIZE * 7];
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tmp1 = (INT32) dataptr[DCTSIZE * 5];
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tmp2 = (INT32) dataptr[DCTSIZE * 3];
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tmp3 = (INT32) dataptr[DCTSIZE * 1];
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z1 = tmp0 + tmp3;
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z2 = tmp1 + tmp2;
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z3 = tmp0 + tmp2;
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z4 = tmp1 + tmp3;
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z5 = MULTIPLY (z3 + z4, FIX_1_175875602); /* sqrt(2) * c3 */
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tmp0 = MULTIPLY (tmp0, FIX_0_298631336); /* sqrt(2) * (-c1+c3+c5-c7) */
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tmp1 = MULTIPLY (tmp1, FIX_2_053119869); /* sqrt(2) * ( c1+c3-c5+c7) */
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tmp2 = MULTIPLY (tmp2, FIX_3_072711026); /* sqrt(2) * ( c1+c3+c5-c7) */
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tmp3 = MULTIPLY (tmp3, FIX_1_501321110); /* sqrt(2) * ( c1+c3-c5-c7) */
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z1 = MULTIPLY (z1, -FIX_0_899976223); /* sqrt(2) * (c7-c3) */
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z2 = MULTIPLY (z2, -FIX_2_562915447); /* sqrt(2) * (-c1-c3) */
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z3 = MULTIPLY (z3, -FIX_1_961570560); /* sqrt(2) * (-c3-c5) */
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z4 = MULTIPLY (z4, -FIX_0_390180644); /* sqrt(2) * (c5-c3) */
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z3 += z5;
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z4 += z5;
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tmp0 += z1 + z3;
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tmp1 += z2 + z4;
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tmp2 += z2 + z3;
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tmp3 += z1 + z4;
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/* Final output stage: inputs are tmp10..tmp13, tmp0..tmp3 */
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dataptr[DCTSIZE * 0] = (DCTELEM) DESCALE (tmp10 + tmp3,
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CONST_BITS + PASS1_BITS + 3);
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dataptr[DCTSIZE * 7] = (DCTELEM) DESCALE (tmp10 - tmp3,
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CONST_BITS + PASS1_BITS + 3);
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dataptr[DCTSIZE * 1] = (DCTELEM) DESCALE (tmp11 + tmp2,
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CONST_BITS + PASS1_BITS + 3);
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dataptr[DCTSIZE * 6] = (DCTELEM) DESCALE (tmp11 - tmp2,
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CONST_BITS + PASS1_BITS + 3);
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dataptr[DCTSIZE * 2] = (DCTELEM) DESCALE (tmp12 + tmp1,
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CONST_BITS + PASS1_BITS + 3);
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dataptr[DCTSIZE * 5] = (DCTELEM) DESCALE (tmp12 - tmp1,
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CONST_BITS + PASS1_BITS + 3);
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dataptr[DCTSIZE * 3] = (DCTELEM) DESCALE (tmp13 + tmp0,
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CONST_BITS + PASS1_BITS + 3);
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dataptr[DCTSIZE * 4] = (DCTELEM) DESCALE (tmp13 - tmp0,
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CONST_BITS + PASS1_BITS + 3);
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dataptr++; /* advance pointer to next column */
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}
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}
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