Source code of Windows XP (NT5)
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38 KiB

#include "stdafx.h"
#pragma hdrstop
/***************************************************************************
*
* INTEL Corporation Proprietary Information
*
*
* Copyright (c) 1996 Intel Corporation.
* All rights reserved.
*
***************************************************************************
*/
/*
* jidctfst.c
*
* Copyright (C) 1994-1996, Thomas G. Lane.
* This file is part of the Independent JPEG Group's software.
* For conditions of distribution and use, see the accompanying README file.
*
* This file contains a fast, not so accurate integer implementation of the
* inverse DCT (Discrete Cosine Transform). In the IJG code, this routine
* must also perform dequantization of the input coefficients.
*
* A 2-D IDCT can be done by 1-D IDCT on each column followed by 1-D IDCT
* on each row (or vice versa, but it's more convenient to emit a row at
* a time). Direct algorithms are also available, but they are much more
* complex and seem not to be any faster when reduced to code.
*
* This implementation is based on Arai, Agui, and Nakajima's algorithm for
* scaled DCT. Their original paper (Trans. IEICE E-71(11):1095) is in
* Japanese, but the algorithm is described in the Pennebaker & Mitchell
* JPEG textbook (see REFERENCES section in file README). The following code
* is based directly on figure 4-8 in P&M.
* While an 8-point DCT cannot be done in less than 11 multiplies, it is
* possible to arrange the computation so that many of the multiplies are
* simple scalings of the final outputs. These multiplies can then be
* folded into the multiplications or divisions by the JPEG quantization
* table entries. The AA&N method leaves only 5 multiplies and 29 adds
* to be done in the DCT itself.
* The primary disadvantage of this method is that with fixed-point math,
* accuracy is lost due to imprecise representation of the scaled
* quantization values. The smaller the quantization table entry, the less
* precise the scaled value, so this implementation does worse with high-
* quality-setting files than with low-quality ones.
*/
#define JPEG_INTERNALS
#include "jinclude.h"
#include "jpeglib.h"
#include "jdct.h" /* Private declarations for DCT subsystem */
#ifdef DCT_IFAST_SUPPORTED
/*
* This module is specialized to the case DCTSIZE = 8.
*/
#if DCTSIZE != 8
Sorry, this code only copes with 8x8 DCTs. /* deliberate syntax err */
#endif
/* Scaling decisions are generally the same as in the LL&M algorithm;
* see jidctint.c for more details. However, we choose to descale
* (right shift) multiplication products as soon as they are formed,
* rather than carrying additional fractional bits into subsequent additions.
* This compromises accuracy slightly, but it lets us save a few shifts.
* More importantly, 16-bit arithmetic is then adequate (for 8-bit samples)
* everywhere except in the multiplications proper; this saves a good deal
* of work on 16-bit-int machines.
*
* The dequantized coefficients are not integers because the AA&N scaling
* factors have been incorporated. We represent them scaled up by PASS1_BITS,
* so that the first and second IDCT rounds have the same input scaling.
* For 8-bit JSAMPLEs, we choose IFAST_SCALE_BITS = PASS1_BITS so as to
* avoid a descaling shift; this compromises accuracy rather drastically
* for small quantization table entries, but it saves a lot of shifts.
* For 12-bit JSAMPLEs, there's no hope of using 16x16 multiplies anyway,
* so we use a much larger scaling factor to preserve accuracy.
*
* A final compromise is to represent the multiplicative constants to only
* 8 fractional bits, rather than 13. This saves some shifting work on some
* machines, and may also reduce the cost of multiplication (since there
* are fewer one-bits in the constants).
*/
#if BITS_IN_JSAMPLE == 8
#define CONST_BITS 8
#define PASS1_BITS 2
#else
#define CONST_BITS 8
#define PASS1_BITS 1 /* lose a little precision to avoid overflow */
#endif
/* Some C compilers fail to reduce "FIX(constant)" at compile time, thus
* causing a lot of useless floating-point operations at run time.
* To get around this we use the following pre-calculated constants.
* If you change CONST_BITS you may want to add appropriate values.
* (With a reasonable C compiler, you can just rely on the FIX() macro...)
*/
#if CONST_BITS == 8
#define FIX_1_082392200 ((INT32) 277) /* FIX(1.082392200) */
#define FIX_1_414213562 ((INT32) 362) /* FIX(1.414213562) */
#define FIX_1_847759065 ((INT32) 473) /* FIX(1.847759065) */
#define FIX_2_613125930 ((INT32) 669) /* FIX(2.613125930) */
#else
#define FIX_1_082392200 FIX(1.082392200)
#define FIX_1_414213562 FIX(1.414213562)
#define FIX_1_847759065 FIX(1.847759065)
#define FIX_2_613125930 FIX(2.613125930)
#endif
/* We can gain a little more speed, with a further compromise in accuracy,
* by omitting the addition in a descaling shift. This yields an incorrectly
* rounded result half the time...
*/
#ifndef USE_ACCURATE_ROUNDING
#undef DESCALE
#define DESCALE(x,n) RIGHT_SHIFT(x, n)
#endif
//#define DESCALE(x,n) RIGHT_SHIFT((x) + (ONE << ((n)-1)), n)
/* Multiply a DCTELEM variable by an INT32 constant, and immediately
* descale to yield a DCTELEM result.
*/
//#define MULTIPLY(var,const) ((DCTELEM) DESCALE((var) * (const), CONST_BITS))
#define MULTIPLY(var,const) ((DCTELEM) ((var) * (const)))
/* Dequantize a coefficient by multiplying it by the multiplier-table
* entry; produce a DCTELEM result. For 8-bit data a 16x16->16
* multiplication will do. For 12-bit data, the multiplier table is
* declared INT32, so a 32-bit multiply will be used.
*/
#if BITS_IN_JSAMPLE == 8
//#define DEQUANTIZE(coef,quantval) (((IFAST_MULT_TYPE) (coef)) * (quantval))
#define DEQUANTIZE(coef,quantval) (((coef)) * (quantval))
#else
#define DEQUANTIZE(coef,quantval) \
DESCALE((coef)*(quantval), IFAST_SCALE_BITS-PASS1_BITS)
#endif
/* Like DESCALE, but applies to a DCTELEM and produces an int.
* We assume that int right shift is unsigned if INT32 right shift is.
*/
#ifdef RIGHT_SHIFT_IS_UNSIGNED
#define ISHIFT_TEMPS DCTELEM ishift_temp;
#if BITS_IN_JSAMPLE == 8
#define DCTELEMBITS 16 /* DCTELEM may be 16 or 32 bits */
#else
#define DCTELEMBITS 32 /* DCTELEM must be 32 bits */
#endif
#define IRIGHT_SHIFT(x,shft) \
((ishift_temp = (x)) < 0 ? \
(ishift_temp >> (shft)) | ((~((DCTELEM) 0)) << (DCTELEMBITS-(shft))) : \
(ishift_temp >> (shft)))
#else
#define ISHIFT_TEMPS
#define IRIGHT_SHIFT(x,shft) ((x) >> (shft))
#endif
#ifdef USE_ACCURATE_ROUNDING
#define IDESCALE(x,n) ((int) IRIGHT_SHIFT((x) + (1 << ((n)-1)), n))
#else
#define IDESCALE(x,n) ((int) IRIGHT_SHIFT(x, n))
#endif
static const __int64 x5a825a825a825a82 = 0x0000016a0000016a ;
static const __int64 x539f539f539f539f = 0x0000fd630000fd63 ;
static const __int64 x4546454645464546 = 0x0000011500000115 ;
static const __int64 x61f861f861f861f8 = 0x000001d9000001d9 ;
static const __int64 const_mask = 0x03ff03ff03ff03ff ;
static const __int64 const_zero = 0x0000000000000000 ;
/*
* Perform dequantization and inverse DCT on one block of coefficients.
*/
GLOBAL(void)
midct8x8aan (JCOEFPTR coef_block, short * wsptr, short * quantptr,
JSAMPARRAY output_buf, JDIMENSION output_col, JSAMPLE *range_limit )
{
__int64 scratch3, scratch5, scratch7 ;
// do the 2-Dal idct and store the corresponding results
// from the range_limit array
__asm {
mov ebx, coef_block ; source coeff
mov esi, wsptr ; temp results
mov edi, quantptr ; quant factors
movq mm0, [ebx+8*12] ; V12
pmullw mm0, [edi+8*12]
movq mm1, [ebx+8*4] ; V4
pmullw mm1, [edi+8*4]
movq mm3, [ebx+8*0] ; V0
pmullw mm3, [edi+8*0]
movq mm5, [ebx+8*8] ; V8
movq mm2, mm1 ; duplicate V4
pmullw mm5, [edi+8*8]
psubw mm1, mm0 ; V16 (s1)
movq mm7, x5a825a825a825a82 ; 23170 ->V18 (s3)
;***************************************************PackMulW
movq mm6, mm1
punpcklwd mm1, const_zero
paddw mm2, mm0 ; V17
pmaddwd mm1, mm7
movq mm0, mm2 ; duplicate V17
punpckhwd mm6, const_zero
movq mm4, mm3 ; duplicate V0
pmaddwd mm6, mm7
paddw mm3, mm5 ; V19
psrad mm1, 8
psubw mm4, mm5 ; V20 ;mm5 free
psrad mm6, 8 ; mm6 = (s1)
packssdw mm1, mm6
;**********************************************************
movq mm6, mm3 ; duplicate t74=t81
psubw mm1, mm0 ; V21 ; mm0 free
paddw mm3, mm2 ; V22
movq mm5, mm1 ; duplicate V21
paddw mm1, mm4 ; V23
movq [esi+8*4], mm3 ; V22
psubw mm4, mm5 ; V24; mm5 free
movq [esi+8*12], mm1 ; V23
psubw mm6, mm2 ; V25; mm2 free
movq [esi+8*0], mm4 ; V24
; keep mm6 alive all along the next block
movq mm7, [ebx+8*10] ; V10
pmullw mm7, [edi+8*10]
movq mm0, [ebx+8*6] ; V6
pmullw mm0, [edi+8*6]
movq mm3, mm7 ; duplicate V10
movq mm5, [ebx+8*2] ; V2
pmullw mm5, [edi+8*2]
psubw mm7, mm0 ; V26 (s1/7)
movq mm4, [ebx+8*14] ; V14
pmullw mm4, [edi+8*14]
paddw mm3, mm0 ; V29 ; free mm0
movq mm1, x539f539f539f539f ;23170 ->V18 (scratch3)
;mm0 = s5,
;***************************************************PackMulW
movq scratch7, mm7
movq mm2, mm7
punpcklwd mm7, const_zero
movq mm0, mm5 ; duplicate V2
pmaddwd mm7, mm1
paddw mm5, mm4 ; V27
punpckhwd mm2, const_zero
psubw mm0, mm4 ;(s1) for next ; V28 ; free mm4
pmaddwd mm2, mm1
movq mm4, mm0
punpcklwd mm0, const_zero
psrad mm7, 8
psrad mm2, 8 ; mm2 = scratch1
movq mm1, mm4 ; duplicate V28
punpckhwd mm4, const_zero
packssdw mm7, mm2
movq mm2, x4546454645464546 ; 23170 ->V18
;**********************************************************
;***************************************************PackMulW
pmaddwd mm0, mm2
pmaddwd mm4, mm2
psrad mm0, 8
movq mm2, x61f861f861f861f8 ; 23170 ->V18
psrad mm4, 8
packssdw mm0, mm4
movq mm4, mm1
movq mm1, scratch7
;**********************************************************
movq scratch5, mm0
paddw mm1, mm4 ; V32 ; free mm4
;***************************************************PackMulW
movq mm0, mm1
punpcklwd mm1, const_zero
movq mm4, mm5 ; duplicate t90=t93
pmaddwd mm1, mm2
paddw mm5, mm3 ; V31
punpckhwd mm0, const_zero
psubw mm4, mm3 ; V30 ; free mm3
movq mm3, x5a825a825a825a82 ; 23170 ->V18
pmaddwd mm0, mm2
psrad mm1, 8
movq mm2, mm4 ; make a copy of mm4
punpcklwd mm4, const_zero
psrad mm0, 8
pmaddwd mm4, mm3
packssdw mm1, mm0
;**********************************************************
;***************************************************PackMulW
punpckhwd mm2, const_zero
movq mm0, scratch5
pmaddwd mm2, mm3
psubw mm0, mm1 ; V38
paddw mm1, mm7 ; V37 ; free mm7
movq mm7, [esi+8*4] ; V22
psrad mm4, 8
psrad mm2, 8
movq mm3, mm6 ; duplicate V25
packssdw mm4, mm2
psubw mm1, mm5 ; V39 (mm5 still needed for next block)
;**********************************************************
movq mm2, [esi+8*12] ; V23
psubw mm4, mm1 ; V40
paddw mm0, mm4 ; V41; free mm0
psubw mm6, mm0 ; tm6
paddw mm3, mm0 ; tm8; free mm1
movq mm0, mm1 ; line added by Kumar
movq mm1, mm7 ; duplicate V22
movq [esi+8*8], mm3 ; tm8; free mm3
paddw mm7, mm5 ; tm0
movq [esi+8*6], mm6 ; tm6; free mm6
psubw mm1, mm5 ; tm14; free mm5
movq mm6, [esi+8*0] ; V24
movq mm3, mm2 ; duplicate t117=t125
movq [esi+8*0], mm7 ; tm0; free mm7
paddw mm2, mm0 ; tm2
movq [esi+8*14], mm1 ; tm14; free mm1
psubw mm3, mm0 ; tm12; free mm0
movq [esi+8*2], mm2 ; tm2; free mm2
movq mm0, mm6 ; duplicate t119=t123
movq [esi+8*12], mm3 ; tm12; free mm3
paddw mm6, mm4 ; tm4
movq mm1, [ebx+8*5] ; V5
psubw mm0, mm4 ; tm10; free mm4
pmullw mm1, [edi+8*5]
movq [esi+8*4], mm6 ; tm4; free mm6
movq [esi+8*10], mm0 ; tm10; free mm0
; column 1: even part
; use V5, V13, V1, V9 to produce V56..V59
movq mm7, [ebx+8*13] ; V13
movq mm2, mm1 ; duplicate t128=t130
pmullw mm7, [edi+8*13]
movq mm3, [ebx+8*1] ; V1
pmullw mm3, [edi+8*1]
movq mm5, [ebx+8*9] ; V9
psubw mm1, mm7 ; V50
pmullw mm5, [edi+8*9]
paddw mm2, mm7 ; V51
movq mm7, x5a825a825a825a82 ; 23170 ->V18
;***************************************************PackMulW
movq mm4, mm1
punpcklwd mm1, const_zero
movq mm6, mm2 ; duplicate V51
pmaddwd mm1, mm7
punpckhwd mm4, const_zero
movq mm0, [ebx+8*11] ; V11
pmaddwd mm4, mm7
pmullw mm0, [edi+8*11]
psrad mm1, 8
psrad mm4, 8
packssdw mm1, mm4
movq mm4, mm3 ; duplicate V1
;**********************************************************
paddw mm3, mm5 ; V53
psubw mm4, mm5 ; V54 ;mm5 free
movq mm7, mm3 ; duplicate V53
psubw mm1, mm6 ; V55 ; mm6 free
movq mm6, [ebx+8*7] ; V7
paddw mm3, mm2 ; V56
movq mm5, mm4 ; duplicate t140=t142
paddw mm4, mm1 ; V57
movq [esi+8*5], mm3 ; V56
psubw mm5, mm1 ; V58; mm1 free
pmullw mm6, [edi+8*7]
psubw mm7, mm2 ; V59; mm2 free
movq [esi+8*13], mm4 ; V57
movq mm3, mm0 ; duplicate V11
; keep mm7 alive all along the next block
movq [esi+8*9], mm5 ; V58
paddw mm0, mm6 ; V63
movq mm4, [ebx+8*15] ; V15
psubw mm3, mm6 ; V60 ; free mm6
pmullw mm4, [edi+8*15]
; note that V15 computation has a correction step:
; this is a 'magic' constant that rebiases the results to be closer to the expected result
; this magic constant can be refined to reduce the error even more
; by doing the correction step in a later stage when the number is actually multiplied by 16
movq mm1, mm3 ; duplicate V60
movq mm5, [ebx+8*3] ; V3
movq mm2, mm1
pmullw mm5, [edi+8*3]
movq scratch7, mm7
movq mm6, mm5 ; duplicate V3
movq mm7, x539f539f539f539f ; 23170 ->V18
paddw mm5, mm4 ; V61
;***************************************************PackMulW
punpcklwd mm1, const_zero
psubw mm6, mm4 ; V62 ; free mm4
pmaddwd mm1, mm7
movq mm4, mm5 ; duplicate V61
punpckhwd mm2, const_zero
paddw mm5, mm0 ; V65 -> result
pmaddwd mm2, mm7
psubw mm4, mm0 ; V64 ; free mm0
movq scratch3, mm3
psrad mm1, 8
movq mm3, x5a825a825a825a82 ; 23170 ->V18
psrad mm2, 8
packssdw mm1, mm2
movq mm2, mm4
;**********************************************************
;***************************************************PackMulW
punpcklwd mm4, const_zero
pmaddwd mm4, mm3
punpckhwd mm2, const_zero
pmaddwd mm2, mm3
psrad mm4, 8
movq mm3, scratch3
movq mm0, x61f861f861f861f8 ; 23170 ->V18
paddw mm3, mm6 ; V66
psrad mm2, 8
movq mm7, mm3
packssdw mm4, mm2
movq mm2, mm5 ; duplicate V65
;**********************************************************
;***************************************************PackMulW
punpcklwd mm3, const_zero
pmaddwd mm3, mm0
punpckhwd mm7, const_zero
pmaddwd mm7, mm0
movq mm0, mm6
psrad mm3, 8
punpcklwd mm6, const_zero
psrad mm7, 8
packssdw mm3, mm7
;**********************************************************
movq mm7, x4546454645464546 ; 23170 ->V18
;***************************************************PackMulW
punpckhwd mm0, const_zero
pmaddwd mm6, mm7
pmaddwd mm0, mm7
psrad mm6, 8
psrad mm0, 8
packssdw mm6, mm0
;**********************************************************
movq mm0, [esi+8*5] ; V56
psubw mm6, mm3 ; V72
paddw mm3, mm1 ; V71 ; free mm1
psubw mm3, mm2 ; V73 ; free mm2
movq mm1, mm0 ; duplicate t177=t188
psubw mm4, mm3 ; V74
paddw mm0, mm5 ; tm1
movq mm2, [esi+8*13] ; V57
paddw mm6, mm4 ; V75
;location
; 5 - V56
; 13 - V57
; 9 - V58
; X - V59, mm7
; X - V65, mm5
; X - V73, mm6
; X - V74, mm4
; X - V75, mm3
; free mm0, mm1 & mm2
movq mm7, scratch7 ; tm1; free mm0
psubw mm1, mm5 ; tm15; free mm5
;save the store as used directly in the transpose
movq [esi+8*1], mm0 ; tm1; free mm0
movq mm5, mm7 ; duplicate t182=t184
movq mm0, [esi+8*9] ; V58
psubw mm7, mm6 ; tm7
paddw mm5, mm6 ; tm9; free mm6
movq mm6, mm3
movq [esi+8*7], mm7 ; tm7; free mm7
movq mm3, mm2 ; duplicate V57
psubw mm3, mm6 ; tm13
paddw mm2, mm6 ; tm3 ; free mm6
movq [esi+8*3], mm2 ; tm3; free mm2
movq mm6, mm0 ; duplicate V58
paddw mm0, mm4 ; tm5
psubw mm6, mm4 ; tm11; free mm4
movq [esi+8*5], mm0 ; tm5; free mm0
movq mm0, mm5 ; copy w4---0,1,3,5,6
; transpose the bottom right quadrant(4X4) of the matrix
; --------- ---------
; | M1 | M2 | | M1'| M3'|
; --------- --> ---------
; | M3 | M4 | | M2'| M4'|
; --------- ---------
punpcklwd mm5, mm6 ;
punpckhwd mm0, mm6 ;---0,1,3,5,6
movq mm6, [esi+8*0] ;get w0 of top left quadrant
movq mm2, mm3 ;---0,1,2,3,5,6
punpcklwd mm3, mm1 ;
movq mm7, [esi+8*2] ;get w1 of top left quadrant
punpckhwd mm2, mm1 ;---0,2,3,5,6,7
movq mm4, mm5 ;---0,2,3,4,5,6,7
punpckldq mm5, mm3 ; transposed w4
movq [esi+8*9], mm5 ; store w4
punpckhdq mm4, mm3 ; transposed w5---0,2,4,6,7
movq mm3, mm0 ;---0,2,3,4,6,7
punpckldq mm0, mm2 ; transposed w6
movq [esi+8*11], mm4 ; store w5
punpckhdq mm3, mm2 ; transposed w7---0,3,6,7
movq [esi+8*13], mm0 ; store w6---3,5,6,7
movq mm5, mm6 ; copy w0
movq [esi+8*15], mm3 ; store w7---5,6,7
punpcklwd mm6, mm7
; transpose the top left quadrant(4X4) of the matrix
punpckhwd mm5, mm7 ;---5,6,7
movq mm7, [esi+8*4] ; get w2 of TL quadrant
movq mm4, [esi+8*6] ; get w3 of TL quadrant
movq mm3, mm7 ; copy w2---3,4,5,6,7
movq mm2, mm6
punpcklwd mm7, mm4 ;---2,3,4,5,6,7
punpckhwd mm3, mm4 ;---2,3,4,5,6,7
movq mm4, mm5 ;
movq mm1, mm5
punpckldq mm6, mm7 ;---1,2,3,4,5,6,7
movq [esi+8*0], mm6 ; store w0 of TL quadrant
punpckhdq mm2, mm7 ;---1,2,3,4,5,6,7
movq [esi+8*2], mm2 ; store w1 of TL quadrant
punpckldq mm5, mm3 ;---1,2,3,4,5,6,7
movq [esi+8*4], mm5 ; store w2 of TL quadrant
punpckhdq mm1, mm3 ;---1,2,3,4,5,6,7
movq [esi+8*6], mm1 ; store w3 of TL quadrant
; transpose the top right quadrant(4X4) of the matrix
movq mm0, [esi+8*1] ;---0
movq mm1, [esi+8*3] ;---0,1,2
movq mm2, mm0
movq mm3, [esi+8*5]
punpcklwd mm0, mm1 ;---0,1,2,3
punpckhwd mm2, mm1
movq mm1, [esi+8*7] ;---0,1,2,3
movq mm4, mm3
punpcklwd mm3, mm1 ;---0,1,2,3,4
punpckhwd mm4, mm1 ;---0,1,2,3,4
movq mm1, mm0
movq mm5, mm2
punpckldq mm0, mm3 ;---0,1,2,3,4,5
punpckhdq mm1, mm3 ;---0,1,2,3,4,5
movq mm3, [esi+8*8]
movq [esi+8*8], mm0
punpckldq mm2, mm4 ;---1,2,3,4,5
punpckhdq mm5, mm4 ;---1,2,3,4,5
movq mm4, [esi+8*10]
; transpose the bottom left quadrant(4X4) of the matrix
; Also store w1,w2,w3 of top right quadrant into
; w5,w6,w7 of bottom left quadrant. Storing w0 of TR in w4
; of BL is already done.
movq [esi+8*10], mm1
movq mm1, mm3 ;---1,2,3,4,5
movq mm0, [esi+8*12]
punpcklwd mm3, mm4 ;---0,1,2,3,4,5
punpckhwd mm1, mm4 ;---0,1,2,3,4,5
movq mm4, [esi+8*14]
movq [esi+8*12], mm2
movq mm2, mm0
movq [esi+8*14], mm5
punpcklwd mm0, mm4 ;---0,1,2,3,4
punpckhwd mm2, mm4 ;---0,1,2,3,4
movq mm4, mm3
movq mm5, mm1
punpckldq mm3, mm0 ;---0,1,2,3,4,5
movq [esi+8*1], mm3
punpckhdq mm4, mm0 ;---1,2,4,5
movq [esi+8*3], mm4
punpckldq mm1, mm2 ;---1,2,5
movq [esi+8*5], mm1
punpckhdq mm5, mm2 ;---5
movq [esi+8*7], mm5
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;;;;;;;; 1D DCT of the rows ;;;;;;;;;;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
mov esi, wsptr ; source
; column 0: even part
; use V4, V12, V0, V8 to produce V22..V25
movq mm0, [esi+8*12] ; V12
movq mm1, [esi+8*4] ; V4
movq mm3, [esi+8*0] ; V0
movq mm2, mm1 ; duplicate V4
movq mm5, [esi+8*8] ; V8
psubw mm1, mm0 ; V16
movq mm6, x5a825a825a825a82 ; 23170 ->V18
;***************************************************PackMulW
movq mm4, mm1
punpcklwd mm1, const_zero
paddw mm2, mm0 ; V17
pmaddwd mm1, mm6
movq mm0, mm2 ; duplicate V17
punpckhwd mm4, const_zero
pmaddwd mm4, mm6
psrad mm1, 8
psrad mm4, 8
packssdw mm1, mm4
movq mm4, mm3 ; duplicate V0
;**********************************************************
paddw mm3, mm5 ; V19
psubw mm4, mm5 ; V20 ;mm5 free
movq mm6, mm3 ; duplicate t74=t81
psubw mm1, mm0 ; V21 ; mm0 free
paddw mm3, mm2 ; V22
movq mm5, mm1 ; duplicate V21
paddw mm1, mm4 ; V23
movq [esi+8*4], mm3 ; V22
psubw mm4, mm5 ; V24; mm5 free
movq [esi+8*12], mm1 ; V23
psubw mm6, mm2 ; V25; mm2 free
movq [esi+8*0], mm4 ; V24
; keep mm6 alive all along the next block
; column 0: odd part
; use V2, V6, V10, V14 to produce V31, V39, V40, V41
movq mm7, [esi+8*10] ; V10
movq mm0, [esi+8*6] ; V6
movq mm3, mm7 ; duplicate V10
movq mm5, [esi+8*2] ; V2
psubw mm7, mm0 ; V26
movq mm4, [esi+8*14] ; V14
paddw mm3, mm0 ; V29 ; free mm0
movq mm2, x539f539f539f539f ; 23170 ->V18
movq mm1, mm7 ; duplicate V26
;***************************************************PackMulW
movq scratch5, mm6 ; store mm6
movq mm0, mm7
punpcklwd mm7, const_zero
pmaddwd mm7, mm2
punpckhwd mm0, const_zero
pmaddwd mm0, mm2
psrad mm7, 8
movq mm6, x4546454645464546 ; 23170 ->V18
psrad mm0, 8
packssdw mm7, mm0
movq mm0, mm5 ; duplicate V2
;**********************************************************
paddw mm5, mm4 ; V27
psubw mm0, mm4 ; V28 ; free mm4
movq mm2, mm0 ; duplicate V28
;***************************************************PackMulW
movq mm4, mm0
punpcklwd mm0, const_zero
pmaddwd mm0, mm6
punpckhwd mm4, const_zero
pmaddwd mm4, mm6
paddw mm1, mm2 ; V32 ; free mm2
movq mm2, x61f861f861f861f8 ; 23170 ->V18
psrad mm0, 8
psrad mm4, 8
movq mm6, mm1
packssdw mm0, mm4
movq mm4, mm5 ; duplicate t90=t93
;**********************************************************
;***************************************************PackMulW
punpcklwd mm1, const_zero
paddw mm5, mm3 ; V31
pmaddwd mm1, mm2
psubw mm4, mm3 ; V30 ; free mm3
punpckhwd mm6, const_zero
pmaddwd mm6, mm2
psrad mm1, 8
psrad mm6, 8
packssdw mm1, mm6
;**********************************************************
psubw mm0, mm1 ; V38
paddw mm1, mm7 ; V37 ; free mm7
movq mm7, x5a825a825a825a82 ; 23170 ->V18
;***************************************************PackMulW
movq mm3, mm4
punpcklwd mm4, const_zero
psubw mm1, mm5 ; V39 (mm5 still needed for next block)
pmaddwd mm4, mm7
punpckhwd mm3, const_zero
movq mm6, scratch5
pmaddwd mm3, mm7
movq mm2, [esi+8*12] ; V23
psrad mm4, 8
movq mm7, [esi+8*4] ; V22
psrad mm3, 8
packssdw mm4, mm3
movq mm3, mm6 ; duplicate V25
;**********************************************************
psubw mm4, mm1 ; V40
paddw mm0, mm4 ; V41; free mm0
; column 0: output butterfly
psubw mm6, mm0 ; tm6
paddw mm3, mm0 ; tm8; free mm1
movq mm0, mm1 ; line added by Kumar
movq mm1, mm7 ; duplicate V22
movq [esi+8*8], mm3 ; tm8; free mm3
paddw mm7, mm5 ; tm0
movq [esi+8*6], mm6 ; tm6; free mm6
psubw mm1, mm5 ; tm14; free mm5
movq mm6, [esi+8*0] ; V24
movq mm3, mm2 ; duplicate t117=t125
movq [esi+8*0], mm7 ; tm0; free mm7
paddw mm2, mm0 ; tm2
movq [esi+8*14], mm1 ; tm14; free mm1
psubw mm3, mm0 ; tm12; free mm0
movq [esi+8*2], mm2 ; tm2; free mm2
movq mm0, mm6 ; duplicate t119=t123
movq [esi+8*12], mm3 ; tm12; free mm3
paddw mm6, mm4 ; tm4
movq mm1, [esi+8*5] ; V5
psubw mm0, mm4 ; tm10; free mm4
movq [esi+8*4], mm6 ; tm4; free mm6
movq [esi+8*10], mm0 ; tm10; free mm0
; column 1: even part
; use V5, V13, V1, V9 to produce V56..V59
movq mm7, [esi+8*13] ; V13
movq mm2, mm1 ; duplicate t128=t130
movq mm3, [esi+8*1] ; V1
psubw mm1, mm7 ; V50
movq mm5, [esi+8*9] ; V9
paddw mm2, mm7 ; V51
movq mm4, x5a825a825a825a82 ; 23170 ->V18
;***************************************************PackMulW
movq mm6, mm1
punpcklwd mm1, const_zero
pmaddwd mm1, mm4
punpckhwd mm6, const_zero
pmaddwd mm6, mm4
movq mm4, mm3 ; duplicate V1
paddw mm3, mm5 ; V53
psrad mm1, 8
psubw mm4, mm5 ; V54 ;mm5 free
movq mm7, mm3 ; duplicate V53
psrad mm6, 8
packssdw mm1, mm6
movq mm6, mm2 ; duplicate V51
;**********************************************************
psubw mm1, mm6 ; V55 ; mm6 free
paddw mm3, mm2 ; V56
movq mm5, mm4 ; duplicate t140=t142
paddw mm4, mm1 ; V57
movq [esi+8*5], mm3 ; V56
psubw mm5, mm1 ; V58; mm1 free
movq [esi+8*13], mm4 ; V57
psubw mm7, mm2 ; V59; mm2 free
movq [esi+8*9], mm5 ; V58
; keep mm7 alive all along the next block
movq mm0, [esi+8*11] ; V11
movq mm6, [esi+8*7] ; V7
movq mm4, [esi+8*15] ; V15
movq mm3, mm0 ; duplicate V11
movq mm5, [esi+8*3] ; V3
paddw mm0, mm6 ; V63
; note that V15 computation has a correction step:
; this is a 'magic' constant that rebiases the results to be closer to the expected result
; this magic constant can be refined to reduce the error even more
; by doing the correction step in a later stage when the number is actually multiplied by 16
movq scratch7, mm7
psubw mm3, mm6 ; V60 ; free mm6
movq mm6, x539f539f539f539f ; 23170 ->V18
movq mm1, mm3 ; duplicate V60
;***************************************************PackMulW
movq mm7, mm1
punpcklwd mm1, const_zero
pmaddwd mm1, mm6
punpckhwd mm7, const_zero
pmaddwd mm7, mm6
movq mm6, mm5 ; duplicate V3
paddw mm5, mm4 ; V61
psrad mm1, 8
psubw mm6, mm4 ; V62 ; free mm4
movq mm4, mm5 ; duplicate V61
psrad mm7, 8
paddw mm5, mm0 ; V65 -> result
packssdw mm1, mm7
psubw mm4, mm0 ; V64 ; free mm0
;**********************************************************
movq mm7, x5a825a825a825a82 ; 23170 ->V18
;***************************************************PackMulW
movq mm2, mm4
punpcklwd mm4, const_zero
paddw mm3, mm6 ; V66
pmaddwd mm4, mm7
punpckhwd mm2, const_zero
pmaddwd mm2, mm7
movq mm7, x61f861f861f861f8 ; 23170 ->V18
psrad mm4, 8
psrad mm2, 8
packssdw mm4, mm2
;**********************************************************
;***************************************************PackMulW
movq mm2, mm3
punpcklwd mm3, const_zero
pmaddwd mm3, mm7
punpckhwd mm2, const_zero
pmaddwd mm2, mm7
movq mm7, x4546454645464546 ; 23170 ->V18
psrad mm3, 8
psrad mm2, 8
packssdw mm3, mm2
;**********************************************************
;***************************************************PackMulW
movq mm2, mm6
punpcklwd mm6, const_zero
pmaddwd mm6, mm7
punpckhwd mm2, const_zero
pmaddwd mm2, mm7
movq mm0, [esi+8*5] ; V56
psrad mm6, 8
movq mm7, scratch7
psrad mm2, 8
packssdw mm6, mm2
movq mm2, mm5 ; duplicate V65
;**********************************************************
psubw mm6, mm3 ; V72
paddw mm3, mm1 ; V71 ; free mm1
psubw mm3, mm2 ; V73 ; free mm2
movq mm1, mm0 ; duplicate t177=t188
psubw mm4, mm3 ; V74
paddw mm0, mm5 ; tm1
movq mm2, [esi+8*13] ; V57
paddw mm6, mm4 ; V75
;location
; 5 - V56
; 13 - V57
; 9 - V58
; X - V59, mm7
; X - V65, mm5
; X - V73, mm6
; X - V74, mm4
; X - V75, mm3
; free mm0, mm1 & mm2
movq [esi+8*1], mm0 ; tm1; free mm0
psubw mm1, mm5 ; tm15; free mm5
;save the store as used directly in the transpose
movq mm5, mm7 ; duplicate t182=t184
psubw mm7, mm6 ; tm7
paddw mm5, mm6 ; tm9; free mm3
movq mm6, mm3
movq mm0, [esi+8*9] ; V58
movq mm3, mm2 ; duplicate V57
movq [esi+8*7], mm7 ; tm7; free mm7
psubw mm3, mm6 ; tm13
paddw mm2, mm6 ; tm3 ; free mm6
movq mm6, mm0 ; duplicate V58
movq [esi+8*3], mm2 ; tm3; free mm2
paddw mm0, mm4 ; tm5
psubw mm6, mm4 ; tm11; free mm4
movq [esi+8*5], mm0 ; tm5; free mm0
; Final results to be stored after the transpose
; transpose the bottom right quadrant(4X4) of the matrix
; --------- ---------
; | M1 | M2 | | M1'| M3'|
; --------- --> ---------
; | M3 | M4 | | M2'| M4'|
; --------- ---------
;
; get the pointer to array "range"
mov edi, range_limit
; calculate the destination address
mov edx, output_buf ; get output_buf[4]
mov ebx, [edx+16]
add ebx, output_col ; add to output_col
movq mm0, mm5 ; copy w4---0,1,3,5,6
punpcklwd mm5, mm6 ;
punpckhwd mm0, mm6 ;---0,1,3,5,6
movq mm2, mm3 ;---0,1,2,3,5,6
movq mm6, [esi+8*0] ;get w0 of top left quadrant
punpcklwd mm3, mm1 ;
movq mm7, [esi+8*2] ;get w1 of top left quadrant
punpckhwd mm2, mm1 ;---0,2,3,5,6,7
movq mm4, mm5 ;---0,2,3,4,5,6,7
punpckldq mm5, mm3 ; transposed w4
psrlw mm5, 5
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+4], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+5], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+6], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+7], al
mov ebx, [edx+20]
add ebx, output_col ; add to output_col
punpckhdq mm4, mm3 ; transposed w5---0,2,4,6,7
movq mm3, mm0 ;---0,2,3,4,6,7
punpckldq mm0, mm2 ; transposed w6
psrlw mm4, 5
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+4], al
psrlq mm4, 16
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+5], al
psrlq mm4, 16
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+6], al
psrlq mm4, 16
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+7], al
mov ecx, [edx+24]
add ecx, output_col ; add to output_col
punpckhdq mm3, mm2 ; transposed w7---0,3,6,7
psrlw mm0, 5
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+4], al
psrlq mm0, 16
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+5], al
psrlq mm0, 16
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+6], al
psrlq mm0, 16
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+7], al
mov ebx, [edx+28]
add ebx, output_col ; add to output_col
movq mm5, mm6 ; copy w0
psrlw mm3, 5
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+4], al
psrlq mm3, 16
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+5], al
psrlq mm3, 16
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+6], al
psrlq mm3, 16
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+7], al
punpcklwd mm6, mm7
; transpose the top left quadrant(4X4) of the matrix
; calculate the destination address
mov edx, output_buf ; get output_buf[0]
mov ebx, [edx+0]
add ebx, output_col ; add to output_col
movq mm4, [esi+8*6] ; get w3 of TL quadrant
punpckhwd mm5, mm7 ;---5,6,7
movq mm7, [esi+8*4] ; get w2 of TL quadrant
movq mm2, mm6
movq mm3, mm7 ; copy w2---3,4,5,6,7
punpcklwd mm7, mm4 ;---2,3,4,5,6,7
punpckhwd mm3, mm4 ;---2,3,4,5,6,7
movq mm4, mm5 ;
movq mm1, mm5
punpckldq mm6, mm7 ;---1,2,3,4,5,6,7
psrlw mm6, 5
movd eax, mm6
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx], al
psrlq mm6, 16
movd eax, mm6
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+1], al
psrlq mm6, 16
movd eax, mm6
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+2], al
psrlq mm6, 16
movd eax, mm6
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+3], al
mov ebx, [edx+4]
add ebx, output_col ; add to output_col
punpckhdq mm2, mm7 ;---1,2,3,4,5,6,7
psrlw mm2, 5
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx], al
psrlq mm2, 16
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+1], al
psrlq mm2, 16
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+2], al
psrlq mm2, 16
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+3], al
mov ecx, [edx+8]
add ecx, output_col ; add to output_col
punpckldq mm5, mm3 ;---1,2,3,4,5,6,7
psrlw mm5, 5
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+1], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+2], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+3], al
mov ebx, [edx+12]
add ebx, output_col ; add to output_col
punpckhdq mm1, mm3 ;---1,2,3,4,5,6,7
psrlw mm1, 5
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+1], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+2], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+3], al
; transpose the top right quadrant(4X4) of the matrix
; calculate the destination address for **bottom left quadrant
mov edx, output_buf ; get output_buf[4]
mov ebx, [edx+16]
add ebx, output_col ; add to output_col
movq mm0, [esi+8*1] ;---0
movq mm1, [esi+8*3] ;---0,1,2
movq mm2, mm0
movq mm3, [esi+8*5]
punpcklwd mm0, mm1 ;---0,1,2,3
punpckhwd mm2, mm1
movq mm4, mm3
movq mm1, [esi+8*7] ;---0,1,2,3
movq mm5, mm2
punpcklwd mm3, mm1 ;---0,1,2,3,4
punpckhwd mm4, mm1 ;---0,1,2,3,4
movq mm1, mm0
punpckldq mm0, mm3 ;---0,1,2,3,4,5
punpckhdq mm1, mm3 ;---0,1,2,3,4,5
movq mm3, [esi+8*8]
psrlw mm0, 5
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx], al
psrlq mm0, 16
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+1], al
psrlq mm0, 16
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+2], al
psrlq mm0, 16
movd eax, mm0
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+3], al
mov ebx, [edx+20]
add ebx, output_col ; add to output_col
punpckldq mm2, mm4 ;---1,2,3,4,5
punpckhdq mm5, mm4 ;---1,2,3,4,5
movq mm4, [esi+8*10]
; transpose the bottom left quadrant(4X4) of the matrix
; Also store w1,w2,w3 of top right quadrant into
; w5,w6,w7 of bottom left quadrant. Storing w0 of TR in w4
; of BL is already done.
psrlw mm1, 5
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+1], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+2], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+3], al
mov ecx, [edx+24]
add ecx, output_col ; add to output_col
movq mm0, [esi+8*12]
movq mm1, mm3 ;---1,2,3,4,5
punpcklwd mm3, mm4 ;---0,1,2,3,4,5
punpckhwd mm1, mm4 ;---0,1,2,3,4,5
movq mm4, [esi+8*14]
psrlw mm2, 5
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx], al
psrlq mm2, 16
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+1], al
psrlq mm2, 16
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+2], al
psrlq mm2, 16
movd eax, mm2
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+3], al
mov ebx, [edx+28]
add ebx, output_col ; add to output_col
movq mm2, mm0
psrlw mm5, 5
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+1], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+2], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+3], al
punpcklwd mm0, mm4 ;---0,1,2,3,4
punpckhwd mm2, mm4 ;---0,1,2,3,4
movq mm4, mm3
movq mm5, mm1
punpckldq mm3, mm0 ;---0,1,2,3,4,5
; calculate the destination address for **top right quadrant
mov edx, output_buf ; get output_buf[0]
mov ebx, [edx+0]
add ebx, output_col ; add to output_col
psrlw mm3, 5
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+4], al
psrlq mm3, 16
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+5], al
psrlq mm3, 16
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+6], al
psrlq mm3, 16
movd eax, mm3
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+7], al
mov ebx, [edx+4]
add ebx, output_col ; add to output_col
punpckhdq mm4, mm0 ;---1,2,4,5
psrlw mm4, 5
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+4], al
psrlq mm4, 16
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+5], al
psrlq mm4, 16
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+6], al
psrlq mm4, 16
movd eax, mm4
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+7], al
mov ecx, [edx+8]
add ecx, output_col ; add to output_col
punpckldq mm1, mm2 ;---1,2,5
psrlw mm1, 5
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+4], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+5], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+6], al
psrlq mm1, 16
movd eax, mm1
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ecx+7], al
mov ebx, [edx+12]
add ebx, output_col ; add to output_col
punpckhdq mm5, mm2 ;---5
psrlw mm5, 5
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+4], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+5], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+6], al
psrlq mm5, 16
movd eax, mm5
and eax, 03ffh
mov al, byte ptr [edi][eax]
mov byte ptr [ebx+7], al
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
emms
} /* end of __asm */
}
#endif /* DCT_IFAST_SUPPORTED */