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FFmpeg/libswscale/x86/input.asm

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  1. ;******************************************************************************

  2. ;* x86-optimized input routines; does shuffling of packed

  3. ;* YUV formats into individual planes, and converts RGB

  4. ;* into YUV planes also.

  5. ;* Copyright (c) 2012 Ronald S. Bultje <rsbultje@gmail.com>

  6. ;*

  7. ;* This file is part of FFmpeg.

  8. ;*

  9. ;* FFmpeg is free software; you can redistribute it and/or

  10. ;* modify it under the terms of the GNU Lesser General Public

  11. ;* License as published by the Free Software Foundation; either

  12. ;* version 2.1 of the License, or (at your option) any later version.

  13. ;*

  14. ;* FFmpeg is distributed in the hope that it will be useful,

  15. ;* but WITHOUT ANY WARRANTY; without even the implied warranty of

  16. ;* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

  17. ;* Lesser General Public License for more details.

  18. ;*

  19. ;* You should have received a copy of the GNU Lesser General Public

  20. ;* License along with FFmpeg; if not, write to the Free Software

  21. ;* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

  22. ;******************************************************************************

  23. 

  24. %include "libavutil/x86/x86util.asm"

  25. 

  26. SECTION_RODATA

  27. 

  28. %define RY 0x20DE

  29. %define GY 0x4087

  30. %define BY 0x0C88

  31. %define RU 0xECFF

  32. %define GU 0xDAC8

  33. %define BU 0x3838

  34. %define RV 0x3838

  35. %define GV 0xD0E3

  36. %define BV 0xF6E4

  37. 

  38. rgb_Yrnd:        times 4 dd 0x80100        ;  16.5 << 15

  39. rgb_UVrnd:       times 4 dd 0x400100       ; 128.5 << 15

  40. %define bgr_Ycoeff_12x4 16*4 + 16* 0 + tableq

  41. %define bgr_Ycoeff_3x56 16*4 + 16* 1 + tableq

  42. %define rgb_Ycoeff_12x4 16*4 + 16* 2 + tableq

  43. %define rgb_Ycoeff_3x56 16*4 + 16* 3 + tableq

  44. %define bgr_Ucoeff_12x4 16*4 + 16* 4 + tableq

  45. %define bgr_Ucoeff_3x56 16*4 + 16* 5 + tableq

  46. %define rgb_Ucoeff_12x4 16*4 + 16* 6 + tableq

  47. %define rgb_Ucoeff_3x56 16*4 + 16* 7 + tableq

  48. %define bgr_Vcoeff_12x4 16*4 + 16* 8 + tableq

  49. %define bgr_Vcoeff_3x56 16*4 + 16* 9 + tableq

  50. %define rgb_Vcoeff_12x4 16*4 + 16*10 + tableq

  51. %define rgb_Vcoeff_3x56 16*4 + 16*11 + tableq

  52. 

  53. %define rgba_Ycoeff_rb 16*4 + 16*12 + tableq

  54. %define rgba_Ycoeff_br 16*4 + 16*13 + tableq

  55. %define rgba_Ycoeff_ga 16*4 + 16*14 + tableq

  56. %define rgba_Ycoeff_ag 16*4 + 16*15 + tableq

  57. %define rgba_Ucoeff_rb 16*4 + 16*16 + tableq

  58. %define rgba_Ucoeff_br 16*4 + 16*17 + tableq

  59. %define rgba_Ucoeff_ga 16*4 + 16*18 + tableq

  60. %define rgba_Ucoeff_ag 16*4 + 16*19 + tableq

  61. %define rgba_Vcoeff_rb 16*4 + 16*20 + tableq

  62. %define rgba_Vcoeff_br 16*4 + 16*21 + tableq

  63. %define rgba_Vcoeff_ga 16*4 + 16*22 + tableq

  64. %define rgba_Vcoeff_ag 16*4 + 16*23 + tableq

  65. 

  66. ; bgr_Ycoeff_12x4: times 2 dw BY, GY, 0, BY

  67. ; bgr_Ycoeff_3x56: times 2 dw RY, 0, GY, RY

  68. ; rgb_Ycoeff_12x4: times 2 dw RY, GY, 0, RY

  69. ; rgb_Ycoeff_3x56: times 2 dw BY, 0, GY, BY

  70. ; bgr_Ucoeff_12x4: times 2 dw BU, GU, 0, BU

  71. ; bgr_Ucoeff_3x56: times 2 dw RU, 0, GU, RU

  72. ; rgb_Ucoeff_12x4: times 2 dw RU, GU, 0, RU

  73. ; rgb_Ucoeff_3x56: times 2 dw BU, 0, GU, BU

  74. ; bgr_Vcoeff_12x4: times 2 dw BV, GV, 0, BV

  75. ; bgr_Vcoeff_3x56: times 2 dw RV, 0, GV, RV

  76. ; rgb_Vcoeff_12x4: times 2 dw RV, GV, 0, RV

  77. ; rgb_Vcoeff_3x56: times 2 dw BV, 0, GV, BV

  78. 

  79. ; rgba_Ycoeff_rb:  times 4 dw RY, BY

  80. ; rgba_Ycoeff_br:  times 4 dw BY, RY

  81. ; rgba_Ycoeff_ga:  times 4 dw GY, 0

  82. ; rgba_Ycoeff_ag:  times 4 dw 0,  GY

  83. ; rgba_Ucoeff_rb:  times 4 dw RU, BU

  84. ; rgba_Ucoeff_br:  times 4 dw BU, RU

  85. ; rgba_Ucoeff_ga:  times 4 dw GU, 0

  86. ; rgba_Ucoeff_ag:  times 4 dw 0,  GU

  87. ; rgba_Vcoeff_rb:  times 4 dw RV, BV

  88. ; rgba_Vcoeff_br:  times 4 dw BV, RV

  89. ; rgba_Vcoeff_ga:  times 4 dw GV, 0

  90. ; rgba_Vcoeff_ag:  times 4 dw 0,  GV

  91. 

  92. shuf_rgb_12x4:   db 0, 0x80, 1, 0x80,  2, 0x80,  3, 0x80, \

  93.                     6, 0x80, 7, 0x80,  8, 0x80,  9, 0x80

  94. shuf_rgb_3x56:   db 2, 0x80, 3, 0x80,  4, 0x80,  5, 0x80, \

  95.                     8, 0x80, 9, 0x80, 10, 0x80, 11, 0x80

  96. 

  97. SECTION .text

  98. 

  99. ;-----------------------------------------------------------------------------

  100. ; RGB to Y/UV.

  101. ;

  102. ; void <fmt>ToY_<opt>(uint8_t *dst, const uint8_t *src, int w);

  103. ; and

  104. ; void <fmt>toUV_<opt>(uint8_t *dstU, uint8_t *dstV, const uint8_t *src,

  105. ;                      const uint8_t *unused, int w);

  106. ;-----------------------------------------------------------------------------

  107. 

  108. ; %1 = nr. of XMM registers

  109. ; %2 = rgb or bgr

  110. %macro RGB24_TO_Y_FN 2-3

  111. cglobal %2 %+ 24ToY, 6, 6, %1, dst, src, u1, u2, w, table

  112. %if mmsize == 8

  113.     mova           m5, [%2_Ycoeff_12x4]

  114.     mova           m6, [%2_Ycoeff_3x56]

  115. %define coeff1 m5

  116. %define coeff2 m6

  117. %elif ARCH_X86_64

  118.     mova           m8, [%2_Ycoeff_12x4]

  119.     mova           m9, [%2_Ycoeff_3x56]

  120. %define coeff1 m8

  121. %define coeff2 m9

  122. %else ; x86-32 && mmsize == 16

  123. %define coeff1 [%2_Ycoeff_12x4]

  124. %define coeff2 [%2_Ycoeff_3x56]

  125. %endif ; x86-32/64 && mmsize == 8/16

  126. %if (ARCH_X86_64 || mmsize == 8) && %0 == 3

  127.     jmp mangle(private_prefix %+ _ %+ %3 %+ 24ToY %+ SUFFIX).body

  128. %else ; (ARCH_X86_64 && %0 == 3) || mmsize == 8

  129. .body:

  130. %if cpuflag(ssse3)

  131.     mova           m7, [shuf_rgb_12x4]

  132. %define shuf_rgb1 m7

  133. %if ARCH_X86_64

  134.     mova          m10, [shuf_rgb_3x56]

  135. %define shuf_rgb2 m10

  136. %else ; x86-32

  137. %define shuf_rgb2 [shuf_rgb_3x56]

  138. %endif ; x86-32/64

  139. %endif ; cpuflag(ssse3)

  140. %if ARCH_X86_64

  141.     movsxd         wq, wd

  142. %endif

  143.     add            wq, wq

  144.     add          dstq, wq

  145.     neg            wq

  146. %if notcpuflag(ssse3)

  147.     pxor           m7, m7

  148. %endif ; !cpuflag(ssse3)

  149.     mova           m4, [rgb_Yrnd]

  150. .loop:

  151. %if cpuflag(ssse3)

  152.     movu           m0, [srcq+0]           ; (byte) { Bx, Gx, Rx }[0-3]

  153.     movu           m2, [srcq+12]          ; (byte) { Bx, Gx, Rx }[4-7]

  154.     pshufb         m1, m0, shuf_rgb2      ; (word) { R0, B1, G1, R1, R2, B3, G3, R3 }

  155.     pshufb         m0, shuf_rgb1          ; (word) { B0, G0, R0, B1, B2, G2, R2, B3 }

  156.     pshufb         m3, m2, shuf_rgb2      ; (word) { R4, B5, G5, R5, R6, B7, G7, R7 }

  157.     pshufb         m2, shuf_rgb1          ; (word) { B4, G4, R4, B5, B6, G6, R6, B7 }

  158. %else ; !cpuflag(ssse3)

  159.     movd           m0, [srcq+0]           ; (byte) { B0, G0, R0, B1 }

  160.     movd           m1, [srcq+2]           ; (byte) { R0, B1, G1, R1 }

  161.     movd           m2, [srcq+6]           ; (byte) { B2, G2, R2, B3 }

  162.     movd           m3, [srcq+8]           ; (byte) { R2, B3, G3, R3 }

  163. %if mmsize == 16 ; i.e. sse2

  164.     punpckldq      m0, m2                 ; (byte) { B0, G0, R0, B1, B2, G2, R2, B3 }

  165.     punpckldq      m1, m3                 ; (byte) { R0, B1, G1, R1, R2, B3, G3, R3 }

  166.     movd           m2, [srcq+12]          ; (byte) { B4, G4, R4, B5 }

  167.     movd           m3, [srcq+14]          ; (byte) { R4, B5, G5, R5 }

  168.     movd           m5, [srcq+18]          ; (byte) { B6, G6, R6, B7 }

  169.     movd           m6, [srcq+20]          ; (byte) { R6, B7, G7, R7 }

  170.     punpckldq      m2, m5                 ; (byte) { B4, G4, R4, B5, B6, G6, R6, B7 }

  171.     punpckldq      m3, m6                 ; (byte) { R4, B5, G5, R5, R6, B7, G7, R7 }

  172. %endif ; mmsize == 16

  173.     punpcklbw      m0, m7                 ; (word) { B0, G0, R0, B1, B2, G2, R2, B3 }

  174.     punpcklbw      m1, m7                 ; (word) { R0, B1, G1, R1, R2, B3, G3, R3 }

  175.     punpcklbw      m2, m7                 ; (word) { B4, G4, R4, B5, B6, G6, R6, B7 }

  176.     punpcklbw      m3, m7                 ; (word) { R4, B5, G5, R5, R6, B7, G7, R7 }

  177. %endif ; cpuflag(ssse3)

  178.     add          srcq, 3 * mmsize / 2

  179.     pmaddwd        m0, coeff1             ; (dword) { B0*BY + G0*GY, B1*BY, B2*BY + G2*GY, B3*BY }

  180.     pmaddwd        m1, coeff2             ; (dword) { R0*RY, G1+GY + R1*RY, R2*RY, G3+GY + R3*RY }

  181.     pmaddwd        m2, coeff1             ; (dword) { B4*BY + G4*GY, B5*BY, B6*BY + G6*GY, B7*BY }

  182.     pmaddwd        m3, coeff2             ; (dword) { R4*RY, G5+GY + R5*RY, R6*RY, G7+GY + R7*RY }

  183.     paddd          m0, m1                 ; (dword) { Bx*BY + Gx*GY + Rx*RY }[0-3]

  184.     paddd          m2, m3                 ; (dword) { Bx*BY + Gx*GY + Rx*RY }[4-7]

  185.     paddd          m0, m4                 ; += rgb_Yrnd, i.e. (dword) { Y[0-3] }

  186.     paddd          m2, m4                 ; += rgb_Yrnd, i.e. (dword) { Y[4-7] }

  187.     psrad          m0, 9

  188.     psrad          m2, 9

  189.     packssdw       m0, m2                 ; (word) { Y[0-7] }

  190.     mova    [dstq+wq], m0

  191.     add            wq, mmsize

  192.     jl .loop

  193.     REP_RET

  194. %endif ; (ARCH_X86_64 && %0 == 3) || mmsize == 8

  195. %endmacro

  196. 

  197. ; %1 = nr. of XMM registers

  198. ; %2 = rgb or bgr

  199. %macro RGB24_TO_UV_FN 2-3

  200. cglobal %2 %+ 24ToUV, 7, 7, %1, dstU, dstV, u1, src, u2, w, table

  201. %if ARCH_X86_64

  202.     mova           m8, [%2_Ucoeff_12x4]

  203.     mova           m9, [%2_Ucoeff_3x56]

  204.     mova          m10, [%2_Vcoeff_12x4]

  205.     mova          m11, [%2_Vcoeff_3x56]

  206. %define coeffU1 m8

  207. %define coeffU2 m9

  208. %define coeffV1 m10

  209. %define coeffV2 m11

  210. %else ; x86-32

  211. %define coeffU1 [%2_Ucoeff_12x4]

  212. %define coeffU2 [%2_Ucoeff_3x56]

  213. %define coeffV1 [%2_Vcoeff_12x4]

  214. %define coeffV2 [%2_Vcoeff_3x56]

  215. %endif ; x86-32/64

  216. %if ARCH_X86_64 && %0 == 3

  217.     jmp mangle(private_prefix %+ _ %+ %3 %+ 24ToUV %+ SUFFIX).body

  218. %else ; ARCH_X86_64 && %0 == 3

  219. .body:

  220. %if cpuflag(ssse3)

  221.     mova           m7, [shuf_rgb_12x4]

  222. %define shuf_rgb1 m7

  223. %if ARCH_X86_64

  224.     mova          m12, [shuf_rgb_3x56]

  225. %define shuf_rgb2 m12

  226. %else ; x86-32

  227. %define shuf_rgb2 [shuf_rgb_3x56]

  228. %endif ; x86-32/64

  229. %endif ; cpuflag(ssse3)

  230. %if ARCH_X86_64

  231.     movsxd         wq, dword r5m

  232. %else ; x86-32

  233.     mov            wq, r5m

  234. %endif

  235.     add            wq, wq

  236.     add         dstUq, wq

  237.     add         dstVq, wq

  238.     neg            wq

  239.     mova           m6, [rgb_UVrnd]

  240. %if notcpuflag(ssse3)

  241.     pxor           m7, m7

  242. %endif

  243. .loop:

  244. %if cpuflag(ssse3)

  245.     movu           m0, [srcq+0]           ; (byte) { Bx, Gx, Rx }[0-3]

  246.     movu           m4, [srcq+12]          ; (byte) { Bx, Gx, Rx }[4-7]

  247.     pshufb         m1, m0, shuf_rgb2      ; (word) { R0, B1, G1, R1, R2, B3, G3, R3 }

  248.     pshufb         m0, shuf_rgb1          ; (word) { B0, G0, R0, B1, B2, G2, R2, B3 }

  249. %else ; !cpuflag(ssse3)

  250.     movd           m0, [srcq+0]           ; (byte) { B0, G0, R0, B1 }

  251.     movd           m1, [srcq+2]           ; (byte) { R0, B1, G1, R1 }

  252.     movd           m4, [srcq+6]           ; (byte) { B2, G2, R2, B3 }

  253.     movd           m5, [srcq+8]           ; (byte) { R2, B3, G3, R3 }

  254. %if mmsize == 16

  255.     punpckldq      m0, m4                 ; (byte) { B0, G0, R0, B1, B2, G2, R2, B3 }

  256.     punpckldq      m1, m5                 ; (byte) { R0, B1, G1, R1, R2, B3, G3, R3 }

  257.     movd           m4, [srcq+12]          ; (byte) { B4, G4, R4, B5 }

  258.     movd           m5, [srcq+14]          ; (byte) { R4, B5, G5, R5 }

  259. %endif ; mmsize == 16

  260.     punpcklbw      m0, m7                 ; (word) { B0, G0, R0, B1, B2, G2, R2, B3 }

  261.     punpcklbw      m1, m7                 ; (word) { R0, B1, G1, R1, R2, B3, G3, R3 }

  262. %endif ; cpuflag(ssse3)

  263.     pmaddwd        m2, m0, coeffV1        ; (dword) { B0*BV + G0*GV, B1*BV, B2*BV + G2*GV, B3*BV }

  264.     pmaddwd        m3, m1, coeffV2        ; (dword) { R0*BV, G1*GV + R1*BV, R2*BV, G3*GV + R3*BV }

  265.     pmaddwd        m0, coeffU1            ; (dword) { B0*BU + G0*GU, B1*BU, B2*BU + G2*GU, B3*BU }

  266.     pmaddwd        m1, coeffU2            ; (dword) { R0*BU, G1*GU + R1*BU, R2*BU, G3*GU + R3*BU }

  267.     paddd          m0, m1                 ; (dword) { Bx*BU + Gx*GU + Rx*RU }[0-3]

  268.     paddd          m2, m3                 ; (dword) { Bx*BV + Gx*GV + Rx*RV }[0-3]

  269. %if cpuflag(ssse3)

  270.     pshufb         m5, m4, shuf_rgb2      ; (word) { R4, B5, G5, R5, R6, B7, G7, R7 }

  271.     pshufb         m4, shuf_rgb1          ; (word) { B4, G4, R4, B5, B6, G6, R6, B7 }

  272. %else ; !cpuflag(ssse3)

  273. %if mmsize == 16

  274.     movd           m1, [srcq+18]          ; (byte) { B6, G6, R6, B7 }

  275.     movd           m3, [srcq+20]          ; (byte) { R6, B7, G7, R7 }

  276.     punpckldq      m4, m1                 ; (byte) { B4, G4, R4, B5, B6, G6, R6, B7 }

  277.     punpckldq      m5, m3                 ; (byte) { R4, B5, G5, R5, R6, B7, G7, R7 }

  278. %endif ; mmsize == 16 && !cpuflag(ssse3)

  279.     punpcklbw      m4, m7                 ; (word) { B4, G4, R4, B5, B6, G6, R6, B7 }

  280.     punpcklbw      m5, m7                 ; (word) { R4, B5, G5, R5, R6, B7, G7, R7 }

  281. %endif ; cpuflag(ssse3)

  282.     add          srcq, 3 * mmsize / 2

  283.     pmaddwd        m1, m4, coeffU1        ; (dword) { B4*BU + G4*GU, B5*BU, B6*BU + G6*GU, B7*BU }

  284.     pmaddwd        m3, m5, coeffU2        ; (dword) { R4*BU, G5*GU + R5*BU, R6*BU, G7*GU + R7*BU }

  285.     pmaddwd        m4, coeffV1            ; (dword) { B4*BV + G4*GV, B5*BV, B6*BV + G6*GV, B7*BV }

  286.     pmaddwd        m5, coeffV2            ; (dword) { R4*BV, G5*GV + R5*BV, R6*BV, G7*GV + R7*BV }

  287.     paddd          m1, m3                 ; (dword) { Bx*BU + Gx*GU + Rx*RU }[4-7]

  288.     paddd          m4, m5                 ; (dword) { Bx*BV + Gx*GV + Rx*RV }[4-7]

  289.     paddd          m0, m6                 ; += rgb_UVrnd, i.e. (dword) { U[0-3] }

  290.     paddd          m2, m6                 ; += rgb_UVrnd, i.e. (dword) { V[0-3] }

  291.     paddd          m1, m6                 ; += rgb_UVrnd, i.e. (dword) { U[4-7] }

  292.     paddd          m4, m6                 ; += rgb_UVrnd, i.e. (dword) { V[4-7] }

  293.     psrad          m0, 9

  294.     psrad          m2, 9

  295.     psrad          m1, 9

  296.     psrad          m4, 9

  297.     packssdw       m0, m1                 ; (word) { U[0-7] }

  298.     packssdw       m2, m4                 ; (word) { V[0-7] }

  299. %if mmsize == 8

  300.     mova   [dstUq+wq], m0

  301.     mova   [dstVq+wq], m2

  302. %else ; mmsize == 16

  303.     mova   [dstUq+wq], m0

  304.     mova   [dstVq+wq], m2

  305. %endif ; mmsize == 8/16

  306.     add            wq, mmsize

  307.     jl .loop

  308.     REP_RET

  309. %endif ; ARCH_X86_64 && %0 == 3

  310. %endmacro

  311. 

  312. ; %1 = nr. of XMM registers for rgb-to-Y func

  313. ; %2 = nr. of XMM registers for rgb-to-UV func

  314. %macro RGB24_FUNCS 2

  315. RGB24_TO_Y_FN %1, rgb

  316. RGB24_TO_Y_FN %1, bgr, rgb

  317. RGB24_TO_UV_FN %2, rgb

  318. RGB24_TO_UV_FN %2, bgr, rgb

  319. %endmacro

  320. 

  321. %if ARCH_X86_32

  322. INIT_MMX mmx

  323. RGB24_FUNCS 0, 0

  324. %endif

  325. 

  326. INIT_XMM sse2

  327. RGB24_FUNCS 10, 12

  328. 

  329. INIT_XMM ssse3

  330. RGB24_FUNCS 11, 13

  331. 

  332. %if HAVE_AVX_EXTERNAL

  333. INIT_XMM avx

  334. RGB24_FUNCS 11, 13

  335. %endif

  336. 

  337. ; %1 = nr. of XMM registers

  338. ; %2-5 = rgba, bgra, argb or abgr (in individual characters)

  339. %macro RGB32_TO_Y_FN 5-6

  340. cglobal %2%3%4%5 %+ ToY, 6, 6, %1, dst, src, u1, u2, w, table

  341.     mova           m5, [rgba_Ycoeff_%2%4]

  342.     mova           m6, [rgba_Ycoeff_%3%5]

  343. %if %0 == 6

  344.     jmp mangle(private_prefix %+ _ %+ %6 %+ ToY %+ SUFFIX).body

  345. %else ; %0 == 6

  346. .body:

  347. %if ARCH_X86_64

  348.     movsxd         wq, wd

  349. %endif

  350.     add            wq, wq

  351.     sub            wq, mmsize - 1

  352.     lea          srcq, [srcq+wq*2]

  353.     add          dstq, wq

  354.     neg            wq

  355.     mova           m4, [rgb_Yrnd]

  356.     pcmpeqb        m7, m7

  357.     psrlw          m7, 8                  ; (word) { 0x00ff } x4

  358. .loop:

  359.     ; FIXME check alignment and use mova

  360.     movu           m0, [srcq+wq*2+0]      ; (byte) { Bx, Gx, Rx, xx }[0-3]

  361.     movu           m2, [srcq+wq*2+mmsize] ; (byte) { Bx, Gx, Rx, xx }[4-7]

  362.     DEINTB          1,  0,  3,  2,  7     ; (word) { Gx, xx (m0/m2) or Bx, Rx (m1/m3) }[0-3]/[4-7]

  363.     pmaddwd        m1, m5                 ; (dword) { Bx*BY + Rx*RY }[0-3]

  364.     pmaddwd        m0, m6                 ; (dword) { Gx*GY }[0-3]

  365.     pmaddwd        m3, m5                 ; (dword) { Bx*BY + Rx*RY }[4-7]

  366.     pmaddwd        m2, m6                 ; (dword) { Gx*GY }[4-7]

  367.     paddd          m0, m4                 ; += rgb_Yrnd

  368.     paddd          m2, m4                 ; += rgb_Yrnd

  369.     paddd          m0, m1                 ; (dword) { Y[0-3] }

  370.     paddd          m2, m3                 ; (dword) { Y[4-7] }

  371.     psrad          m0, 9

  372.     psrad          m2, 9

  373.     packssdw       m0, m2                 ; (word) { Y[0-7] }

  374.     mova    [dstq+wq], m0

  375.     add            wq, mmsize

  376.     jl .loop

  377.     sub            wq, mmsize - 1

  378.     jz .end

  379.     add            srcq, 2*mmsize - 2

  380.     add            dstq, mmsize - 1

  381. .loop2:

  382.     movd           m0, [srcq+wq*2+0]      ; (byte) { Bx, Gx, Rx, xx }[0-3]

  383.     DEINTB          1,  0,  3,  2,  7     ; (word) { Gx, xx (m0/m2) or Bx, Rx (m1/m3) }[0-3]/[4-7]

  384.     pmaddwd        m1, m5                 ; (dword) { Bx*BY + Rx*RY }[0-3]

  385.     pmaddwd        m0, m6                 ; (dword) { Gx*GY }[0-3]

  386.     paddd          m0, m4                 ; += rgb_Yrnd

  387.     paddd          m0, m1                 ; (dword) { Y[0-3] }

  388.     psrad          m0, 9

  389.     packssdw       m0, m0                 ; (word) { Y[0-7] }

  390.     movd    [dstq+wq], m0

  391.     add            wq, 2

  392.     jl .loop2

  393. .end:

  394.     REP_RET

  395. %endif ; %0 == 3

  396. %endmacro

  397. 

  398. ; %1 = nr. of XMM registers

  399. ; %2-5 = rgba, bgra, argb or abgr (in individual characters)

  400. %macro RGB32_TO_UV_FN 5-6

  401. cglobal %2%3%4%5 %+ ToUV, 7, 7, %1, dstU, dstV, u1, src, u2, w, table

  402. %if ARCH_X86_64

  403.     mova           m8, [rgba_Ucoeff_%2%4]

  404.     mova           m9, [rgba_Ucoeff_%3%5]

  405.     mova          m10, [rgba_Vcoeff_%2%4]

  406.     mova          m11, [rgba_Vcoeff_%3%5]

  407. %define coeffU1 m8

  408. %define coeffU2 m9

  409. %define coeffV1 m10

  410. %define coeffV2 m11

  411. %else ; x86-32

  412. %define coeffU1 [rgba_Ucoeff_%2%4]

  413. %define coeffU2 [rgba_Ucoeff_%3%5]

  414. %define coeffV1 [rgba_Vcoeff_%2%4]

  415. %define coeffV2 [rgba_Vcoeff_%3%5]

  416. %endif ; x86-64/32

  417. %if ARCH_X86_64 && %0 == 6

  418.     jmp mangle(private_prefix %+ _ %+ %6 %+ ToUV %+ SUFFIX).body

  419. %else ; ARCH_X86_64 && %0 == 6

  420. .body:

  421. %if ARCH_X86_64

  422.     movsxd         wq, dword r5m

  423. %else ; x86-32

  424.     mov            wq, r5m

  425. %endif

  426.     add            wq, wq

  427.     sub            wq, mmsize - 1

  428.     add         dstUq, wq

  429.     add         dstVq, wq

  430.     lea          srcq, [srcq+wq*2]

  431.     neg            wq

  432.     pcmpeqb        m7, m7

  433.     psrlw          m7, 8                  ; (word) { 0x00ff } x4

  434.     mova           m6, [rgb_UVrnd]

  435. .loop:

  436.     ; FIXME check alignment and use mova

  437.     movu           m0, [srcq+wq*2+0]      ; (byte) { Bx, Gx, Rx, xx }[0-3]

  438.     movu           m4, [srcq+wq*2+mmsize] ; (byte) { Bx, Gx, Rx, xx }[4-7]

  439.     DEINTB          1,  0,  5,  4,  7     ; (word) { Gx, xx (m0/m4) or Bx, Rx (m1/m5) }[0-3]/[4-7]

  440.     pmaddwd        m3, m1, coeffV1        ; (dword) { Bx*BV + Rx*RV }[0-3]

  441.     pmaddwd        m2, m0, coeffV2        ; (dword) { Gx*GV }[0-3]

  442.     pmaddwd        m1, coeffU1            ; (dword) { Bx*BU + Rx*RU }[0-3]

  443.     pmaddwd        m0, coeffU2            ; (dword) { Gx*GU }[0-3]

  444.     paddd          m3, m6                 ; += rgb_UVrnd

  445.     paddd          m1, m6                 ; += rgb_UVrnd

  446.     paddd          m2, m3                 ; (dword) { V[0-3] }

  447.     paddd          m0, m1                 ; (dword) { U[0-3] }

  448.     pmaddwd        m3, m5, coeffV1        ; (dword) { Bx*BV + Rx*RV }[4-7]

  449.     pmaddwd        m1, m4, coeffV2        ; (dword) { Gx*GV }[4-7]

  450.     pmaddwd        m5, coeffU1            ; (dword) { Bx*BU + Rx*RU }[4-7]

  451.     pmaddwd        m4, coeffU2            ; (dword) { Gx*GU }[4-7]

  452.     paddd          m3, m6                 ; += rgb_UVrnd

  453.     paddd          m5, m6                 ; += rgb_UVrnd

  454.     psrad          m0, 9

  455.     paddd          m1, m3                 ; (dword) { V[4-7] }

  456.     paddd          m4, m5                 ; (dword) { U[4-7] }

  457.     psrad          m2, 9

  458.     psrad          m4, 9

  459.     psrad          m1, 9

  460.     packssdw       m0, m4                 ; (word) { U[0-7] }

  461.     packssdw       m2, m1                 ; (word) { V[0-7] }

  462. %if mmsize == 8

  463.     mova   [dstUq+wq], m0

  464.     mova   [dstVq+wq], m2

  465. %else ; mmsize == 16

  466.     mova   [dstUq+wq], m0

  467.     mova   [dstVq+wq], m2

  468. %endif ; mmsize == 8/16

  469.     add            wq, mmsize

  470.     jl .loop

  471.     sub            wq, mmsize - 1

  472.     jz .end

  473.     add            srcq , 2*mmsize - 2

  474.     add            dstUq, mmsize - 1

  475.     add            dstVq, mmsize - 1

  476. .loop2:

  477.     movd           m0, [srcq+wq*2]        ; (byte) { Bx, Gx, Rx, xx }[0-3]

  478.     DEINTB          1,  0,  5,  4,  7     ; (word) { Gx, xx (m0/m4) or Bx, Rx (m1/m5) }[0-3]/[4-7]

  479.     pmaddwd        m3, m1, coeffV1        ; (dword) { Bx*BV + Rx*RV }[0-3]

  480.     pmaddwd        m2, m0, coeffV2        ; (dword) { Gx*GV }[0-3]

  481.     pmaddwd        m1, coeffU1            ; (dword) { Bx*BU + Rx*RU }[0-3]

  482.     pmaddwd        m0, coeffU2            ; (dword) { Gx*GU }[0-3]

  483.     paddd          m3, m6                 ; += rgb_UVrnd

  484.     paddd          m1, m6                 ; += rgb_UVrnd

  485.     paddd          m2, m3                 ; (dword) { V[0-3] }

  486.     paddd          m0, m1                 ; (dword) { U[0-3] }

  487.     psrad          m0, 9

  488.     psrad          m2, 9

  489.     packssdw       m0, m0                 ; (word) { U[0-7] }

  490.     packssdw       m2, m2                 ; (word) { V[0-7] }

  491.     movd   [dstUq+wq], m0

  492.     movd   [dstVq+wq], m2

  493.     add            wq, 2

  494.     jl .loop2

  495. .end:

  496.     REP_RET

  497. %endif ; ARCH_X86_64 && %0 == 3

  498. %endmacro

  499. 

  500. ; %1 = nr. of XMM registers for rgb-to-Y func

  501. ; %2 = nr. of XMM registers for rgb-to-UV func

  502. %macro RGB32_FUNCS 2

  503. RGB32_TO_Y_FN %1, r, g, b, a

  504. RGB32_TO_Y_FN %1, b, g, r, a, rgba

  505. RGB32_TO_Y_FN %1, a, r, g, b, rgba

  506. RGB32_TO_Y_FN %1, a, b, g, r, rgba

  507. 

  508. RGB32_TO_UV_FN %2, r, g, b, a

  509. RGB32_TO_UV_FN %2, b, g, r, a, rgba

  510. RGB32_TO_UV_FN %2, a, r, g, b, rgba

  511. RGB32_TO_UV_FN %2, a, b, g, r, rgba

  512. %endmacro

  513. 

  514. %if ARCH_X86_32

  515. INIT_MMX mmx

  516. RGB32_FUNCS 0, 0

  517. %endif

  518. 

  519. INIT_XMM sse2

  520. RGB32_FUNCS 8, 12

  521. 

  522. %if HAVE_AVX_EXTERNAL

  523. INIT_XMM avx

  524. RGB32_FUNCS 8, 12

  525. %endif

  526. 

  527. ;-----------------------------------------------------------------------------

  528. ; YUYV/UYVY/NV12/NV21 packed pixel shuffling.

  529. ;

  530. ; void <fmt>ToY_<opt>(uint8_t *dst, const uint8_t *src, int w);

  531. ; and

  532. ; void <fmt>toUV_<opt>(uint8_t *dstU, uint8_t *dstV, const uint8_t *src,

  533. ;                      const uint8_t *unused, int w);

  534. ;-----------------------------------------------------------------------------

  535. 

  536. ; %1 = a (aligned) or u (unaligned)

  537. ; %2 = yuyv or uyvy

  538. %macro LOOP_YUYV_TO_Y 2

  539. .loop_%1:

  540.     mov%1          m0, [srcq+wq*2]        ; (byte) { Y0, U0, Y1, V0, ... }

  541.     mov%1          m1, [srcq+wq*2+mmsize] ; (byte) { Y8, U4, Y9, V4, ... }

  542. %ifidn %2, yuyv

  543.     pand           m0, m2                 ; (word) { Y0, Y1, ..., Y7 }

  544.     pand           m1, m2                 ; (word) { Y8, Y9, ..., Y15 }

  545. %else ; uyvy

  546.     psrlw          m0, 8                  ; (word) { Y0, Y1, ..., Y7 }

  547.     psrlw          m1, 8                  ; (word) { Y8, Y9, ..., Y15 }

  548. %endif ; yuyv/uyvy

  549.     packuswb       m0, m1                 ; (byte) { Y0, ..., Y15 }

  550.     mova    [dstq+wq], m0

  551.     add            wq, mmsize

  552.     jl .loop_%1

  553.     REP_RET

  554. %endmacro

  555. 

  556. ; %1 = nr. of XMM registers

  557. ; %2 = yuyv or uyvy

  558. ; %3 = if specified, it means that unaligned and aligned code in loop

  559. ;      will be the same (i.e. YUYV+AVX), and thus we don't need to

  560. ;      split the loop in an aligned and unaligned case

  561. %macro YUYV_TO_Y_FN 2-3

  562. cglobal %2ToY, 5, 5, %1, dst, unused0, unused1, src, w

  563. %if ARCH_X86_64

  564.     movsxd         wq, wd

  565. %endif

  566.     add          dstq, wq

  567. %if mmsize == 16

  568.     test         srcq, 15

  569. %endif

  570.     lea          srcq, [srcq+wq*2]

  571. %ifidn %2, yuyv

  572.     pcmpeqb        m2, m2                 ; (byte) { 0xff } x 16

  573.     psrlw          m2, 8                  ; (word) { 0x00ff } x 8

  574. %endif ; yuyv

  575. %if mmsize == 16

  576.     jnz .loop_u_start

  577.     neg            wq

  578.     LOOP_YUYV_TO_Y  a, %2

  579. .loop_u_start:

  580.     neg            wq

  581.     LOOP_YUYV_TO_Y  u, %2

  582. %else ; mmsize == 8

  583.     neg            wq

  584.     LOOP_YUYV_TO_Y  a, %2

  585. %endif ; mmsize == 8/16

  586. %endmacro

  587. 

  588. ; %1 = a (aligned) or u (unaligned)

  589. ; %2 = yuyv or uyvy

  590. %macro LOOP_YUYV_TO_UV 2

  591. .loop_%1:

  592. %ifidn %2, yuyv

  593.     mov%1          m0, [srcq+wq*4]        ; (byte) { Y0, U0, Y1, V0, ... }

  594.     mov%1          m1, [srcq+wq*4+mmsize] ; (byte) { Y8, U4, Y9, V4, ... }

  595.     psrlw          m0, 8                  ; (word) { U0, V0, ..., U3, V3 }

  596.     psrlw          m1, 8                  ; (word) { U4, V4, ..., U7, V7 }

  597. %else ; uyvy

  598. %if cpuflag(avx)

  599.     vpand          m0, m2, [srcq+wq*4]        ; (word) { U0, V0, ..., U3, V3 }

  600.     vpand          m1, m2, [srcq+wq*4+mmsize] ; (word) { U4, V4, ..., U7, V7 }

  601. %else

  602.     mov%1          m0, [srcq+wq*4]        ; (byte) { Y0, U0, Y1, V0, ... }

  603.     mov%1          m1, [srcq+wq*4+mmsize] ; (byte) { Y8, U4, Y9, V4, ... }

  604.     pand           m0, m2                 ; (word) { U0, V0, ..., U3, V3 }

  605.     pand           m1, m2                 ; (word) { U4, V4, ..., U7, V7 }

  606. %endif

  607. %endif ; yuyv/uyvy

  608.     packuswb       m0, m1                 ; (byte) { U0, V0, ..., U7, V7 }

  609.     pand           m1, m0, m2             ; (word) { U0, U1, ..., U7 }

  610.     psrlw          m0, 8                  ; (word) { V0, V1, ..., V7 }

  611. %if mmsize == 16

  612.     packuswb       m1, m0                 ; (byte) { U0, ... U7, V1, ... V7 }

  613.     movh   [dstUq+wq], m1

  614.     movhps [dstVq+wq], m1

  615. %else ; mmsize == 8

  616.     packuswb       m1, m1                 ; (byte) { U0, ... U3 }

  617.     packuswb       m0, m0                 ; (byte) { V0, ... V3 }

  618.     movh   [dstUq+wq], m1

  619.     movh   [dstVq+wq], m0

  620. %endif ; mmsize == 8/16

  621.     add            wq, mmsize / 2

  622.     jl .loop_%1

  623.     REP_RET

  624. %endmacro

  625. 

  626. ; %1 = nr. of XMM registers

  627. ; %2 = yuyv or uyvy

  628. ; %3 = if specified, it means that unaligned and aligned code in loop

  629. ;      will be the same (i.e. UYVY+AVX), and thus we don't need to

  630. ;      split the loop in an aligned and unaligned case

  631. %macro YUYV_TO_UV_FN 2-3

  632. cglobal %2ToUV, 4, 5, %1, dstU, dstV, unused, src, w

  633. %if ARCH_X86_64

  634.     movsxd         wq, dword r5m

  635. %else ; x86-32

  636.     mov            wq, r5m

  637. %endif

  638.     add         dstUq, wq

  639.     add         dstVq, wq

  640. %if mmsize == 16 && %0 == 2

  641.     test         srcq, 15

  642. %endif

  643.     lea          srcq, [srcq+wq*4]

  644.     pcmpeqb        m2, m2                 ; (byte) { 0xff } x 16

  645.     psrlw          m2, 8                  ; (word) { 0x00ff } x 8

  646.     ; NOTE: if uyvy+avx, u/a are identical

  647. %if mmsize == 16 && %0 == 2

  648.     jnz .loop_u_start

  649.     neg            wq

  650.     LOOP_YUYV_TO_UV a, %2

  651. .loop_u_start:

  652.     neg            wq

  653.     LOOP_YUYV_TO_UV u, %2

  654. %else ; mmsize == 8

  655.     neg            wq

  656.     LOOP_YUYV_TO_UV a, %2

  657. %endif ; mmsize == 8/16

  658. %endmacro

  659. 

  660. ; %1 = a (aligned) or u (unaligned)

  661. ; %2 = nv12 or nv21

  662. %macro LOOP_NVXX_TO_UV 2

  663. .loop_%1:

  664.     mov%1          m0, [srcq+wq*2]        ; (byte) { U0, V0, U1, V1, ... }

  665.     mov%1          m1, [srcq+wq*2+mmsize] ; (byte) { U8, V8, U9, V9, ... }

  666.     pand           m2, m0, m5             ; (word) { U0, U1, ..., U7 }

  667.     pand           m3, m1, m5             ; (word) { U8, U9, ..., U15 }

  668.     psrlw          m0, 8                  ; (word) { V0, V1, ..., V7 }

  669.     psrlw          m1, 8                  ; (word) { V8, V9, ..., V15 }

  670.     packuswb       m2, m3                 ; (byte) { U0, ..., U15 }

  671.     packuswb       m0, m1                 ; (byte) { V0, ..., V15 }

  672. %ifidn %2, nv12

  673.     mova   [dstUq+wq], m2

  674.     mova   [dstVq+wq], m0

  675. %else ; nv21

  676.     mova   [dstVq+wq], m2

  677.     mova   [dstUq+wq], m0

  678. %endif ; nv12/21

  679.     add            wq, mmsize

  680.     jl .loop_%1

  681.     REP_RET

  682. %endmacro

  683. 

  684. ; %1 = nr. of XMM registers

  685. ; %2 = nv12 or nv21

  686. %macro NVXX_TO_UV_FN 2

  687. cglobal %2ToUV, 4, 5, %1, dstU, dstV, unused, src, w

  688. %if ARCH_X86_64

  689.     movsxd         wq, dword r5m

  690. %else ; x86-32

  691.     mov            wq, r5m

  692. %endif

  693.     add         dstUq, wq

  694.     add         dstVq, wq

  695. %if mmsize == 16

  696.     test         srcq, 15

  697. %endif

  698.     lea          srcq, [srcq+wq*2]

  699.     pcmpeqb        m5, m5                 ; (byte) { 0xff } x 16

  700.     psrlw          m5, 8                  ; (word) { 0x00ff } x 8

  701. %if mmsize == 16

  702.     jnz .loop_u_start

  703.     neg            wq

  704.     LOOP_NVXX_TO_UV a, %2

  705. .loop_u_start:

  706.     neg            wq

  707.     LOOP_NVXX_TO_UV u, %2

  708. %else ; mmsize == 8

  709.     neg            wq

  710.     LOOP_NVXX_TO_UV a, %2

  711. %endif ; mmsize == 8/16

  712. %endmacro

  713. 

  714. %if ARCH_X86_32

  715. INIT_MMX mmx

  716. YUYV_TO_Y_FN  0, yuyv

  717. YUYV_TO_Y_FN  0, uyvy

  718. YUYV_TO_UV_FN 0, yuyv

  719. YUYV_TO_UV_FN 0, uyvy

  720. NVXX_TO_UV_FN 0, nv12

  721. NVXX_TO_UV_FN 0, nv21

  722. %endif

  723. 

  724. INIT_XMM sse2

  725. YUYV_TO_Y_FN  3, yuyv

  726. YUYV_TO_Y_FN  2, uyvy

  727. YUYV_TO_UV_FN 3, yuyv

  728. YUYV_TO_UV_FN 3, uyvy

  729. NVXX_TO_UV_FN 5, nv12

  730. NVXX_TO_UV_FN 5, nv21

  731. 

  732. %if HAVE_AVX_EXTERNAL

  733. INIT_XMM avx

  734. ; in theory, we could write a yuy2-to-y using vpand (i.e. AVX), but

  735. ; that's not faster in practice

  736. YUYV_TO_UV_FN 3, yuyv

  737. YUYV_TO_UV_FN 3, uyvy, 1

  738. NVXX_TO_UV_FN 5, nv12

  739. NVXX_TO_UV_FN 5, nv21

  740. %endif