simd/jfdctfst-sse2-64.asm - Issue 1939823002: Update to libjpeg_turbo 1.4.90

Side by Side Diff: simd/jfdctfst-sse2-64.asm

Issue 1939823002: Update to libjpeg_turbo 1.4.90 (Closed) Base URL: https://chromium.googlesource.com/chromium/deps/libjpeg_turbo.git@master

Patch Set: Response to comments Created 4 years, 7 months ago

Use n/p to move between diff chunks; N/P to move between comments. Draft comments are only viewable by you.

Jump to:

View unified diff | Download patch

OLD	NEW
(Empty)
	1 ;

	2 ; jfdctfst.asm - fast integer FDCT (64-bit SSE2)

	3 ;

	4 ; Copyright 2009 Pierre Ossman <ossman@cendio.se> for Cendio AB

	5 ; Copyright 2009 D. R. Commander

	6 ;

	7 ; Based on

	8 ; x86 SIMD extension for IJG JPEG library

	9 ; Copyright (C) 1999-2006, MIYASAKA Masaru.

	10 ; For conditions of distribution and use, see copyright notice in jsimdext.inc

	11 ;

	12 ; This file should be assembled with NASM (Netwide Assembler),

	13 ; can not be assembled with Microsoft's MASM or any compatible

	14 ; assembler (including Borland's Turbo Assembler).

	15 ; NASM is available from http://nasm.sourceforge.net/ or

	16 ; http://sourceforge.net/project/showfiles.php?group_id=6208

	17 ;

	18 ; This file contains a fast, not so accurate integer implementation of

	19 ; the forward DCT (Discrete Cosine Transform). The following code is

	20 ; based directly on the IJG's original jfdctfst.c; see the jfdctfst.c

	21 ; for more details.

	22 ;

	23 ; [TAB8]

	24

	25 %include "jsimdext.inc"

	26 %include "jdct.inc"

	27

	28 ; --------------------------------------------------------------------------

	29

	30 %define CONST_BITS 8 ; 14 is also OK.

	31

	32 %if CONST_BITS == 8

	33 F_0_382 equ 98 ; FIX(0.382683433)

	34 F_0_541 equ 139 ; FIX(0.541196100)

	35 F_0_707 equ 181 ; FIX(0.707106781)

	36 F_1_306 equ 334 ; FIX(1.306562965)

	37 %else

	38 ; NASM cannot do compile-time arithmetic on floating-point constants.

	39 %define DESCALE(x,n) (((x)+(1<<((n)-1)))>>(n))

	40 F_0_382 equ DESCALE( 410903207,30-CONST_BITS) ; FIX(0.382683433)

	41 F_0_541 equ DESCALE( 581104887,30-CONST_BITS) ; FIX(0.541196100)

	42 F_0_707 equ DESCALE( 759250124,30-CONST_BITS) ; FIX(0.707106781)

	43 F_1_306 equ DESCALE(1402911301,30-CONST_BITS) ; FIX(1.306562965)

	44 %endif

	45

	46 ; --------------------------------------------------------------------------

	47 SECTION SEG_CONST

	48

	49 ; PRE_MULTIPLY_SCALE_BITS <= 2 (to avoid overflow)

	50 ; CONST_BITS + CONST_SHIFT + PRE_MULTIPLY_SCALE_BITS == 16 (for pmulhw)

	51

	52 %define PRE_MULTIPLY_SCALE_BITS 2

	53 %define CONST_SHIFT (16 - PRE_MULTIPLY_SCALE_BITS - CONST_BITS)

	54

	55 alignz 16

	56 global EXTN(jconst_fdct_ifast_sse2)

	57

	58 EXTN(jconst_fdct_ifast_sse2):

	59

	60 PW_F0707 times 8 dw F_0_707 << CONST_SHIFT

	61 PW_F0382 times 8 dw F_0_382 << CONST_SHIFT

	62 PW_F0541 times 8 dw F_0_541 << CONST_SHIFT

	63 PW_F1306 times 8 dw F_1_306 << CONST_SHIFT

	64

	65 alignz 16

	66

	67 ; --------------------------------------------------------------------------

	68 SECTION SEG_TEXT

	69 BITS 64

	70 ;

	71 ; Perform the forward DCT on one block of samples.

	72 ;

	73 ; GLOBAL(void)

	74 ; jsimd_fdct_ifast_sse2 (DCTELEM *data)

	75 ;

	76

	77 ; r10 = DCTELEM *data

	78

	79 %define wk(i) rbp-(WK_NUM-(i))*SIZEOF_XMMWORD ; xmmword wk[WK_NUM]

	80 %define WK_NUM 2

	81

	82 align 16

	83 global EXTN(jsimd_fdct_ifast_sse2)

	84

	85 EXTN(jsimd_fdct_ifast_sse2):

	86 push rbp

	87 mov rax,rsp ; rax = original rbp

	88 sub rsp, byte 4

	89 and rsp, byte (-SIZEOF_XMMWORD) ; align to 128 bits

	90 mov [rsp],rax

	91 mov rbp,rsp ; rbp = aligned rbp

	92 lea rsp, [wk(0)]

	93 collect_args

	94

	95 ; ---- Pass 1: process rows.

	96

	97 mov rdx, r10 ; (DCTELEM *)

	98

	99 movdqa xmm0, XMMWORD [XMMBLOCK(0,0,rdx,SIZEOF_DCTELEM)]

	100 movdqa xmm1, XMMWORD [XMMBLOCK(1,0,rdx,SIZEOF_DCTELEM)]

	101 movdqa xmm2, XMMWORD [XMMBLOCK(2,0,rdx,SIZEOF_DCTELEM)]

	102 movdqa xmm3, XMMWORD [XMMBLOCK(3,0,rdx,SIZEOF_DCTELEM)]

	103

	104 ; xmm0=(00 01 02 03 04 05 06 07), xmm2=(20 21 22 23 24 25 26 27)

	105 ; xmm1=(10 11 12 13 14 15 16 17), xmm3=(30 31 32 33 34 35 36 37)

	106

	107 movdqa xmm4,xmm0 ; transpose coefficients(phase 1)

	108 punpcklwd xmm0,xmm1 ; xmm0=(00 10 01 11 02 12 03 13)

	109 punpckhwd xmm4,xmm1 ; xmm4=(04 14 05 15 06 16 07 17)

	110 movdqa xmm5,xmm2 ; transpose coefficients(phase 1)

	111 punpcklwd xmm2,xmm3 ; xmm2=(20 30 21 31 22 32 23 33)

	112 punpckhwd xmm5,xmm3 ; xmm5=(24 34 25 35 26 36 27 37)

	113

	114 movdqa xmm6, XMMWORD [XMMBLOCK(4,0,rdx,SIZEOF_DCTELEM)]

	115 movdqa xmm7, XMMWORD [XMMBLOCK(5,0,rdx,SIZEOF_DCTELEM)]

	116 movdqa xmm1, XMMWORD [XMMBLOCK(6,0,rdx,SIZEOF_DCTELEM)]

	117 movdqa xmm3, XMMWORD [XMMBLOCK(7,0,rdx,SIZEOF_DCTELEM)]

	118

	119 ; xmm6=( 4 12 20 28 36 44 52 60), xmm1=( 6 14 22 30 38 46 54 62)

	120 ; xmm7=( 5 13 21 29 37 45 53 61), xmm3=( 7 15 23 31 39 47 55 63)

	121

	122 movdqa XMMWORD [wk(0)], xmm2 ; wk(0)=(20 30 21 31 22 32 23 33)

	123 movdqa XMMWORD [wk(1)], xmm5 ; wk(1)=(24 34 25 35 26 36 27 37)

	124

	125 movdqa xmm2,xmm6 ; transpose coefficients(phase 1)

	126 punpcklwd xmm6,xmm7 ; xmm6=(40 50 41 51 42 52 43 53)

	127 punpckhwd xmm2,xmm7 ; xmm2=(44 54 45 55 46 56 47 57)

	128 movdqa xmm5,xmm1 ; transpose coefficients(phase 1)

	129 punpcklwd xmm1,xmm3 ; xmm1=(60 70 61 71 62 72 63 73)

	130 punpckhwd xmm5,xmm3 ; xmm5=(64 74 65 75 66 76 67 77)

	131

	132 movdqa xmm7,xmm6 ; transpose coefficients(phase 2)

	133 punpckldq xmm6,xmm1 ; xmm6=(40 50 60 70 41 51 61 71)

	134 punpckhdq xmm7,xmm1 ; xmm7=(42 52 62 72 43 53 63 73)

	135 movdqa xmm3,xmm2 ; transpose coefficients(phase 2)

	136 punpckldq xmm2,xmm5 ; xmm2=(44 54 64 74 45 55 65 75)

	137 punpckhdq xmm3,xmm5 ; xmm3=(46 56 66 76 47 57 67 77)

	138

	139 movdqa xmm1, XMMWORD [wk(0)] ; xmm1=(20 30 21 31 22 32 23 33)

	140 movdqa xmm5, XMMWORD [wk(1)] ; xmm5=(24 34 25 35 26 36 27 37)

	141 movdqa XMMWORD [wk(0)], xmm7 ; wk(0)=(42 52 62 72 43 53 63 73)

	142 movdqa XMMWORD [wk(1)], xmm2 ; wk(1)=(44 54 64 74 45 55 65 75)

	143

	144 movdqa xmm7,xmm0 ; transpose coefficients(phase 2)

	145 punpckldq xmm0,xmm1 ; xmm0=(00 10 20 30 01 11 21 31)

	146 punpckhdq xmm7,xmm1 ; xmm7=(02 12 22 32 03 13 23 33)

	147 movdqa xmm2,xmm4 ; transpose coefficients(phase 2)

	148 punpckldq xmm4,xmm5 ; xmm4=(04 14 24 34 05 15 25 35)

	149 punpckhdq xmm2,xmm5 ; xmm2=(06 16 26 36 07 17 27 37)

	150

	151 movdqa xmm1,xmm0 ; transpose coefficients(phase 3)

	152 punpcklqdq xmm0,xmm6 ; xmm0=(00 10 20 30 40 50 60 70)=data0

	153 punpckhqdq xmm1,xmm6 ; xmm1=(01 11 21 31 41 51 61 71)=data1

	154 movdqa xmm5,xmm2 ; transpose coefficients(phase 3)

	155 punpcklqdq xmm2,xmm3 ; xmm2=(06 16 26 36 46 56 66 76)=data6

	156 punpckhqdq xmm5,xmm3 ; xmm5=(07 17 27 37 47 57 67 77)=data7

	157

	158 movdqa xmm6,xmm1

	159 movdqa xmm3,xmm0

	160 psubw xmm1,xmm2 ; xmm1=data1-data6=tmp6

	161 psubw xmm0,xmm5 ; xmm0=data0-data7=tmp7

	162 paddw xmm6,xmm2 ; xmm6=data1+data6=tmp1

	163 paddw xmm3,xmm5 ; xmm3=data0+data7=tmp0

	164

	165 movdqa xmm2, XMMWORD [wk(0)] ; xmm2=(42 52 62 72 43 53 63 73)

	166 movdqa xmm5, XMMWORD [wk(1)] ; xmm5=(44 54 64 74 45 55 65 75)

	167 movdqa XMMWORD [wk(0)], xmm1 ; wk(0)=tmp6

	168 movdqa XMMWORD [wk(1)], xmm0 ; wk(1)=tmp7

	169

	170 movdqa xmm1,xmm7 ; transpose coefficients(phase 3)

	171 punpcklqdq xmm7,xmm2 ; xmm7=(02 12 22 32 42 52 62 72)=data2

	172 punpckhqdq xmm1,xmm2 ; xmm1=(03 13 23 33 43 53 63 73)=data3

	173 movdqa xmm0,xmm4 ; transpose coefficients(phase 3)

	174 punpcklqdq xmm4,xmm5 ; xmm4=(04 14 24 34 44 54 64 74)=data4

	175 punpckhqdq xmm0,xmm5 ; xmm0=(05 15 25 35 45 55 65 75)=data5

	176

	177 movdqa xmm2,xmm1

	178 movdqa xmm5,xmm7

	179 paddw xmm1,xmm4 ; xmm1=data3+data4=tmp3

	180 paddw xmm7,xmm0 ; xmm7=data2+data5=tmp2

	181 psubw xmm2,xmm4 ; xmm2=data3-data4=tmp4

	182 psubw xmm5,xmm0 ; xmm5=data2-data5=tmp5

	183

	184 ; -- Even part

	185

	186 movdqa xmm4,xmm3

	187 movdqa xmm0,xmm6

	188 psubw xmm3,xmm1 ; xmm3=tmp13

	189 psubw xmm6,xmm7 ; xmm6=tmp12

	190 paddw xmm4,xmm1 ; xmm4=tmp10

	191 paddw xmm0,xmm7 ; xmm0=tmp11

	192

	193 paddw xmm6,xmm3

	194 psllw xmm6,PRE_MULTIPLY_SCALE_BITS

	195 pmulhw xmm6,[rel PW_F0707] ; xmm6=z1

	196

	197 movdqa xmm1,xmm4

	198 movdqa xmm7,xmm3

	199 psubw xmm4,xmm0 ; xmm4=data4

	200 psubw xmm3,xmm6 ; xmm3=data6

	201 paddw xmm1,xmm0 ; xmm1=data0

	202 paddw xmm7,xmm6 ; xmm7=data2

	203

	204 movdqa xmm0, XMMWORD [wk(0)] ; xmm0=tmp6

	205 movdqa xmm6, XMMWORD [wk(1)] ; xmm6=tmp7

	206 movdqa XMMWORD [wk(0)], xmm4 ; wk(0)=data4

	207 movdqa XMMWORD [wk(1)], xmm3 ; wk(1)=data6

	208

	209 ; -- Odd part

	210

	211 paddw xmm2,xmm5 ; xmm2=tmp10

	212 paddw xmm5,xmm0 ; xmm5=tmp11

	213 paddw xmm0,xmm6 ; xmm0=tmp12, xmm6=tmp7

	214

	215 psllw xmm2,PRE_MULTIPLY_SCALE_BITS

	216 psllw xmm0,PRE_MULTIPLY_SCALE_BITS

	217

	218 psllw xmm5,PRE_MULTIPLY_SCALE_BITS

	219 pmulhw xmm5,[rel PW_F0707] ; xmm5=z3

	220

	221 movdqa xmm4,xmm2 ; xmm4=tmp10

	222 psubw xmm2,xmm0

	223 pmulhw xmm2,[rel PW_F0382] ; xmm2=z5

	224 pmulhw xmm4,[rel PW_F0541] ; xmm4=MULTIPLY(tmp10,FIX_0_541196)

	225 pmulhw xmm0,[rel PW_F1306] ; xmm0=MULTIPLY(tmp12,FIX_1_306562)

	226 paddw xmm4,xmm2 ; xmm4=z2

	227 paddw xmm0,xmm2 ; xmm0=z4

	228

	229 movdqa xmm3,xmm6

	230 psubw xmm6,xmm5 ; xmm6=z13

	231 paddw xmm3,xmm5 ; xmm3=z11

	232

	233 movdqa xmm2,xmm6

	234 movdqa xmm5,xmm3

	235 psubw xmm6,xmm4 ; xmm6=data3

	236 psubw xmm3,xmm0 ; xmm3=data7

	237 paddw xmm2,xmm4 ; xmm2=data5

	238 paddw xmm5,xmm0 ; xmm5=data1

	239

	240 ; ---- Pass 2: process columns.

	241

	242 ; xmm1=(00 10 20 30 40 50 60 70), xmm7=(02 12 22 32 42 52 62 72)

	243 ; xmm5=(01 11 21 31 41 51 61 71), xmm6=(03 13 23 33 43 53 63 73)

	244

	245 movdqa xmm4,xmm1 ; transpose coefficients(phase 1)

	246 punpcklwd xmm1,xmm5 ; xmm1=(00 01 10 11 20 21 30 31)

	247 punpckhwd xmm4,xmm5 ; xmm4=(40 41 50 51 60 61 70 71)

	248 movdqa xmm0,xmm7 ; transpose coefficients(phase 1)

	249 punpcklwd xmm7,xmm6 ; xmm7=(02 03 12 13 22 23 32 33)

	250 punpckhwd xmm0,xmm6 ; xmm0=(42 43 52 53 62 63 72 73)

	251

	252 movdqa xmm5, XMMWORD [wk(0)] ; xmm5=col4

	253 movdqa xmm6, XMMWORD [wk(1)] ; xmm6=col6

	254

	255 ; xmm5=(04 14 24 34 44 54 64 74), xmm6=(06 16 26 36 46 56 66 76)

	256 ; xmm2=(05 15 25 35 45 55 65 75), xmm3=(07 17 27 37 47 57 67 77)

	257

	258 movdqa XMMWORD [wk(0)], xmm7 ; wk(0)=(02 03 12 13 22 23 32 33)

	259 movdqa XMMWORD [wk(1)], xmm0 ; wk(1)=(42 43 52 53 62 63 72 73)

	260

	261 movdqa xmm7,xmm5 ; transpose coefficients(phase 1)

	262 punpcklwd xmm5,xmm2 ; xmm5=(04 05 14 15 24 25 34 35)

	263 punpckhwd xmm7,xmm2 ; xmm7=(44 45 54 55 64 65 74 75)

	264 movdqa xmm0,xmm6 ; transpose coefficients(phase 1)

	265 punpcklwd xmm6,xmm3 ; xmm6=(06 07 16 17 26 27 36 37)

	266 punpckhwd xmm0,xmm3 ; xmm0=(46 47 56 57 66 67 76 77)

	267

	268 movdqa xmm2,xmm5 ; transpose coefficients(phase 2)

	269 punpckldq xmm5,xmm6 ; xmm5=(04 05 06 07 14 15 16 17)

	270 punpckhdq xmm2,xmm6 ; xmm2=(24 25 26 27 34 35 36 37)

	271 movdqa xmm3,xmm7 ; transpose coefficients(phase 2)

	272 punpckldq xmm7,xmm0 ; xmm7=(44 45 46 47 54 55 56 57)

	273 punpckhdq xmm3,xmm0 ; xmm3=(64 65 66 67 74 75 76 77)

	274

	275 movdqa xmm6, XMMWORD [wk(0)] ; xmm6=(02 03 12 13 22 23 32 33)

	276 movdqa xmm0, XMMWORD [wk(1)] ; xmm0=(42 43 52 53 62 63 72 73)

	277 movdqa XMMWORD [wk(0)], xmm2 ; wk(0)=(24 25 26 27 34 35 36 37)

	278 movdqa XMMWORD [wk(1)], xmm7 ; wk(1)=(44 45 46 47 54 55 56 57)

	279

	280 movdqa xmm2,xmm1 ; transpose coefficients(phase 2)

	281 punpckldq xmm1,xmm6 ; xmm1=(00 01 02 03 10 11 12 13)

	282 punpckhdq xmm2,xmm6 ; xmm2=(20 21 22 23 30 31 32 33)

	283 movdqa xmm7,xmm4 ; transpose coefficients(phase 2)

	284 punpckldq xmm4,xmm0 ; xmm4=(40 41 42 43 50 51 52 53)

	285 punpckhdq xmm7,xmm0 ; xmm7=(60 61 62 63 70 71 72 73)

	286

	287 movdqa xmm6,xmm1 ; transpose coefficients(phase 3)

	288 punpcklqdq xmm1,xmm5 ; xmm1=(00 01 02 03 04 05 06 07)=data0

	289 punpckhqdq xmm6,xmm5 ; xmm6=(10 11 12 13 14 15 16 17)=data1

	290 movdqa xmm0,xmm7 ; transpose coefficients(phase 3)

	291 punpcklqdq xmm7,xmm3 ; xmm7=(60 61 62 63 64 65 66 67)=data6

	292 punpckhqdq xmm0,xmm3 ; xmm0=(70 71 72 73 74 75 76 77)=data7

	293

	294 movdqa xmm5,xmm6

	295 movdqa xmm3,xmm1

	296 psubw xmm6,xmm7 ; xmm6=data1-data6=tmp6

	297 psubw xmm1,xmm0 ; xmm1=data0-data7=tmp7

	298 paddw xmm5,xmm7 ; xmm5=data1+data6=tmp1

	299 paddw xmm3,xmm0 ; xmm3=data0+data7=tmp0

	300

	301 movdqa xmm7, XMMWORD [wk(0)] ; xmm7=(24 25 26 27 34 35 36 37)

	302 movdqa xmm0, XMMWORD [wk(1)] ; xmm0=(44 45 46 47 54 55 56 57)

	303 movdqa XMMWORD [wk(0)], xmm6 ; wk(0)=tmp6

	304 movdqa XMMWORD [wk(1)], xmm1 ; wk(1)=tmp7

	305

	306 movdqa xmm6,xmm2 ; transpose coefficients(phase 3)

	307 punpcklqdq xmm2,xmm7 ; xmm2=(20 21 22 23 24 25 26 27)=data2

	308 punpckhqdq xmm6,xmm7 ; xmm6=(30 31 32 33 34 35 36 37)=data3

	309 movdqa xmm1,xmm4 ; transpose coefficients(phase 3)

	310 punpcklqdq xmm4,xmm0 ; xmm4=(40 41 42 43 44 45 46 47)=data4

	311 punpckhqdq xmm1,xmm0 ; xmm1=(50 51 52 53 54 55 56 57)=data5

	312

	313 movdqa xmm7,xmm6

	314 movdqa xmm0,xmm2

	315 paddw xmm6,xmm4 ; xmm6=data3+data4=tmp3

	316 paddw xmm2,xmm1 ; xmm2=data2+data5=tmp2

	317 psubw xmm7,xmm4 ; xmm7=data3-data4=tmp4

	318 psubw xmm0,xmm1 ; xmm0=data2-data5=tmp5

	319

	320 ; -- Even part

	321

	322 movdqa xmm4,xmm3

	323 movdqa xmm1,xmm5

	324 psubw xmm3,xmm6 ; xmm3=tmp13

	325 psubw xmm5,xmm2 ; xmm5=tmp12

	326 paddw xmm4,xmm6 ; xmm4=tmp10

	327 paddw xmm1,xmm2 ; xmm1=tmp11

	328

	329 paddw xmm5,xmm3

	330 psllw xmm5,PRE_MULTIPLY_SCALE_BITS

	331 pmulhw xmm5,[rel PW_F0707] ; xmm5=z1

	332

	333 movdqa xmm6,xmm4

	334 movdqa xmm2,xmm3

	335 psubw xmm4,xmm1 ; xmm4=data4

	336 psubw xmm3,xmm5 ; xmm3=data6

	337 paddw xmm6,xmm1 ; xmm6=data0

	338 paddw xmm2,xmm5 ; xmm2=data2

	339

	340 movdqa XMMWORD [XMMBLOCK(4,0,rdx,SIZEOF_DCTELEM)], xmm4

	341 movdqa XMMWORD [XMMBLOCK(6,0,rdx,SIZEOF_DCTELEM)], xmm3

	342 movdqa XMMWORD [XMMBLOCK(0,0,rdx,SIZEOF_DCTELEM)], xmm6

	343 movdqa XMMWORD [XMMBLOCK(2,0,rdx,SIZEOF_DCTELEM)], xmm2

	344

	345 ; -- Odd part

	346

	347 movdqa xmm1, XMMWORD [wk(0)] ; xmm1=tmp6

	348 movdqa xmm5, XMMWORD [wk(1)] ; xmm5=tmp7

	349

	350 paddw xmm7,xmm0 ; xmm7=tmp10

	351 paddw xmm0,xmm1 ; xmm0=tmp11

	352 paddw xmm1,xmm5 ; xmm1=tmp12, xmm5=tmp7

	353

	354 psllw xmm7,PRE_MULTIPLY_SCALE_BITS

	355 psllw xmm1,PRE_MULTIPLY_SCALE_BITS

	356

	357 psllw xmm0,PRE_MULTIPLY_SCALE_BITS

	358 pmulhw xmm0,[rel PW_F0707] ; xmm0=z3

	359

	360 movdqa xmm4,xmm7 ; xmm4=tmp10

	361 psubw xmm7,xmm1

	362 pmulhw xmm7,[rel PW_F0382] ; xmm7=z5

	363 pmulhw xmm4,[rel PW_F0541] ; xmm4=MULTIPLY(tmp10,FIX_0_541196)

	364 pmulhw xmm1,[rel PW_F1306] ; xmm1=MULTIPLY(tmp12,FIX_1_306562)

	365 paddw xmm4,xmm7 ; xmm4=z2

	366 paddw xmm1,xmm7 ; xmm1=z4

	367

	368 movdqa xmm3,xmm5

	369 psubw xmm5,xmm0 ; xmm5=z13

	370 paddw xmm3,xmm0 ; xmm3=z11

	371

	372 movdqa xmm6,xmm5

	373 movdqa xmm2,xmm3

	374 psubw xmm5,xmm4 ; xmm5=data3

	375 psubw xmm3,xmm1 ; xmm3=data7

	376 paddw xmm6,xmm4 ; xmm6=data5

	377 paddw xmm2,xmm1 ; xmm2=data1

	378

	379 movdqa XMMWORD [XMMBLOCK(3,0,rdx,SIZEOF_DCTELEM)], xmm5

	380 movdqa XMMWORD [XMMBLOCK(7,0,rdx,SIZEOF_DCTELEM)], xmm3

	381 movdqa XMMWORD [XMMBLOCK(5,0,rdx,SIZEOF_DCTELEM)], xmm6

	382 movdqa XMMWORD [XMMBLOCK(1,0,rdx,SIZEOF_DCTELEM)], xmm2

	383

	384 uncollect_args

	385 mov rsp,rbp ; rsp <- aligned rbp

	386 pop rsp ; rsp <- original rbp

	387 pop rbp

	388 ret

	389

	390 ; For some reason, the OS X linker does not honor the request to align the

	391 ; segment unless we do this.

	392 align 16

OLD	NEW

« jdhuff.c ('K') | « simd/jfdctfst-sse2.asm ('k') | simd/jfdctint-altivec.c » ('j') | no next file with comments »