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FFmpeg/libavcodec/x86/dsputil_yasm.asm

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

  2. ;* MMX optimized DSP utils

  3. ;* Copyright (c) 2008 Loren Merritt

  4. ;*

  5. ;* This file is part of Libav.

  6. ;*

  7. ;* Libav is free software; you can redistribute it and/or

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

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

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

  11. ;*

  12. ;* Libav is distributed in the hope that it will be useful,

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

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

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

  16. ;*

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

  18. ;* License along with Libav; if not, write to the Free Software

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

  20. ;******************************************************************************

  21. 

  22. %include "x86inc.asm"

  23. %include "x86util.asm"

  24. 

  25. SECTION_RODATA

  26. pb_f: times 16 db 15

  27. pb_zzzzzzzz77777777: times 8 db -1

  28. pb_7: times 8 db 7

  29. pb_zzzz3333zzzzbbbb: db -1,-1,-1,-1,3,3,3,3,-1,-1,-1,-1,11,11,11,11

  30. pb_zz11zz55zz99zzdd: db -1,-1,1,1,-1,-1,5,5,-1,-1,9,9,-1,-1,13,13

  31. pb_revwords: db 14, 15, 12, 13, 10, 11, 8, 9, 6, 7, 4, 5, 2, 3, 0, 1

  32. pd_16384: times 4 dd 16384

  33. pb_bswap32: db 3, 2, 1, 0, 7, 6, 5, 4, 11, 10, 9, 8, 15, 14, 13, 12

  34. 

  35. SECTION_TEXT

  36. 

  37. %macro SCALARPRODUCT 1

  38. ; int scalarproduct_int16(int16_t *v1, int16_t *v2, int order, int shift)

  39. cglobal scalarproduct_int16_%1, 3,3,4, v1, v2, order, shift

  40.     shl orderq, 1

  41.     add v1q, orderq

  42.     add v2q, orderq

  43.     neg orderq

  44.     movd    m3, shiftm

  45.     pxor    m2, m2

  46. .loop:

  47.     movu    m0, [v1q + orderq]

  48.     movu    m1, [v1q + orderq + mmsize]

  49.     pmaddwd m0, [v2q + orderq]

  50.     pmaddwd m1, [v2q + orderq + mmsize]

  51.     paddd   m2, m0

  52.     paddd   m2, m1

  53.     add     orderq, mmsize*2

  54.     jl .loop

  55. %if mmsize == 16

  56.     movhlps m0, m2

  57.     paddd   m2, m0

  58.     psrad   m2, m3

  59.     pshuflw m0, m2, 0x4e

  60. %else

  61.     psrad   m2, m3

  62.     pshufw  m0, m2, 0x4e

  63. %endif

  64.     paddd   m2, m0

  65.     movd   eax, m2

  66.     RET

  67. 

  68. ; int scalarproduct_and_madd_int16(int16_t *v1, int16_t *v2, int16_t *v3, int order, int mul)

  69. cglobal scalarproduct_and_madd_int16_%1, 4,4,8, v1, v2, v3, order, mul

  70.     shl orderq, 1

  71.     movd    m7, mulm

  72. %if mmsize == 16

  73.     pshuflw m7, m7, 0

  74.     punpcklqdq m7, m7

  75. %else

  76.     pshufw  m7, m7, 0

  77. %endif

  78.     pxor    m6, m6

  79.     add v1q, orderq

  80.     add v2q, orderq

  81.     add v3q, orderq

  82.     neg orderq

  83. .loop:

  84.     movu    m0, [v2q + orderq]

  85.     movu    m1, [v2q + orderq + mmsize]

  86.     mova    m4, [v1q + orderq]

  87.     mova    m5, [v1q + orderq + mmsize]

  88.     movu    m2, [v3q + orderq]

  89.     movu    m3, [v3q + orderq + mmsize]

  90.     pmaddwd m0, m4

  91.     pmaddwd m1, m5

  92.     pmullw  m2, m7

  93.     pmullw  m3, m7

  94.     paddd   m6, m0

  95.     paddd   m6, m1

  96.     paddw   m2, m4

  97.     paddw   m3, m5

  98.     mova    [v1q + orderq], m2

  99.     mova    [v1q + orderq + mmsize], m3

  100.     add     orderq, mmsize*2

  101.     jl .loop

  102. %if mmsize == 16

  103.     movhlps m0, m6

  104.     paddd   m6, m0

  105.     pshuflw m0, m6, 0x4e

  106. %else

  107.     pshufw  m0, m6, 0x4e

  108. %endif

  109.     paddd   m6, m0

  110.     movd   eax, m6

  111.     RET

  112. %endmacro

  113. 

  114. INIT_MMX

  115. SCALARPRODUCT mmx2

  116. INIT_XMM

  117. SCALARPRODUCT sse2

  118. 

  119. %macro SCALARPRODUCT_LOOP 1

  120. align 16

  121. .loop%1:

  122.     sub     orderq, mmsize*2

  123. %if %1

  124.     mova    m1, m4

  125.     mova    m4, [v2q + orderq]

  126.     mova    m0, [v2q + orderq + mmsize]

  127.     palignr m1, m0, %1

  128.     palignr m0, m4, %1

  129.     mova    m3, m5

  130.     mova    m5, [v3q + orderq]

  131.     mova    m2, [v3q + orderq + mmsize]

  132.     palignr m3, m2, %1

  133.     palignr m2, m5, %1

  134. %else

  135.     mova    m0, [v2q + orderq]

  136.     mova    m1, [v2q + orderq + mmsize]

  137.     mova    m2, [v3q + orderq]

  138.     mova    m3, [v3q + orderq + mmsize]

  139. %endif

  140.     %define t0  [v1q + orderq]

  141.     %define t1  [v1q + orderq + mmsize]

  142. %if ARCH_X86_64

  143.     mova    m8, t0

  144.     mova    m9, t1

  145.     %define t0  m8

  146.     %define t1  m9

  147. %endif

  148.     pmaddwd m0, t0

  149.     pmaddwd m1, t1

  150.     pmullw  m2, m7

  151.     pmullw  m3, m7

  152.     paddw   m2, t0

  153.     paddw   m3, t1

  154.     paddd   m6, m0

  155.     paddd   m6, m1

  156.     mova    [v1q + orderq], m2

  157.     mova    [v1q + orderq + mmsize], m3

  158.     jg .loop%1

  159. %if %1

  160.     jmp .end

  161. %endif

  162. %endmacro

  163. 

  164. ; int scalarproduct_and_madd_int16(int16_t *v1, int16_t *v2, int16_t *v3, int order, int mul)

  165. cglobal scalarproduct_and_madd_int16_ssse3, 4,5,10, v1, v2, v3, order, mul

  166.     shl orderq, 1

  167.     movd    m7, mulm

  168.     pshuflw m7, m7, 0

  169.     punpcklqdq m7, m7

  170.     pxor    m6, m6

  171.     mov    r4d, v2d

  172.     and    r4d, 15

  173.     and    v2q, ~15

  174.     and    v3q, ~15

  175.     mova    m4, [v2q + orderq]

  176.     mova    m5, [v3q + orderq]

  177.     ; linear is faster than branch tree or jump table, because the branches taken are cyclic (i.e. predictable)

  178.     cmp    r4d, 0

  179.     je .loop0

  180.     cmp    r4d, 2

  181.     je .loop2

  182.     cmp    r4d, 4

  183.     je .loop4

  184.     cmp    r4d, 6

  185.     je .loop6

  186.     cmp    r4d, 8

  187.     je .loop8

  188.     cmp    r4d, 10

  189.     je .loop10

  190.     cmp    r4d, 12

  191.     je .loop12

  192. SCALARPRODUCT_LOOP 14

  193. SCALARPRODUCT_LOOP 12

  194. SCALARPRODUCT_LOOP 10

  195. SCALARPRODUCT_LOOP 8

  196. SCALARPRODUCT_LOOP 6

  197. SCALARPRODUCT_LOOP 4

  198. SCALARPRODUCT_LOOP 2

  199. SCALARPRODUCT_LOOP 0

  200. .end:

  201.     movhlps m0, m6

  202.     paddd   m6, m0

  203.     pshuflw m0, m6, 0x4e

  204.     paddd   m6, m0

  205.     movd   eax, m6

  206.     RET

  207. 

  208. 

  209. ;-----------------------------------------------------------------------------

  210. ; void ff_apply_window_int16(int16_t *output, const int16_t *input,

  211. ;                            const int16_t *window, unsigned int len)

  212. ;-----------------------------------------------------------------------------

  213. 

  214. %macro REVERSE_WORDS_MMXEXT 1-2

  215.     pshufw   %1, %1, 0x1B

  216. %endmacro

  217. 

  218. %macro REVERSE_WORDS_SSE2 1-2

  219.     pshuflw  %1, %1, 0x1B

  220.     pshufhw  %1, %1, 0x1B

  221.     pshufd   %1, %1, 0x4E

  222. %endmacro

  223. 

  224. %macro REVERSE_WORDS_SSSE3 2

  225.     pshufb  %1, %2

  226. %endmacro

  227. 

  228. ; dst = (dst * src) >> 15

  229. ; pmulhw cuts off the bottom bit, so we have to lshift by 1 and add it back

  230. ; in from the pmullw result.

  231. %macro MUL16FIXED_MMXEXT 3 ; dst, src, temp

  232.     mova    %3, %1

  233.     pmulhw  %1, %2

  234.     pmullw  %3, %2

  235.     psrlw   %3, 15

  236.     psllw   %1, 1

  237.     por     %1, %3

  238. %endmacro

  239. 

  240. ; dst = ((dst * src) + (1<<14)) >> 15

  241. %macro MUL16FIXED_SSSE3 3 ; dst, src, unused

  242.     pmulhrsw   %1, %2

  243. %endmacro

  244. 

  245. %macro APPLY_WINDOW_INT16 3 ; %1=instruction set, %2=mmxext/sse2 bit exact version, %3=has_ssse3

  246. cglobal apply_window_int16_%1, 4,5,6, output, input, window, offset, offset2

  247.     lea     offset2q, [offsetq-mmsize]

  248. %if %2

  249.     mova          m5, [pd_16384]

  250. %elifidn %1, ssse3

  251.     mova          m5, [pb_revwords]

  252.     ALIGN 16

  253. %endif

  254. .loop:

  255. %if %2

  256.     ; This version expands 16-bit to 32-bit, multiplies by the window,

  257.     ; adds 16384 for rounding, right shifts 15, then repacks back to words to

  258.     ; save to the output. The window is reversed for the second half.

  259.     mova          m3, [windowq+offset2q]

  260.     mova          m4, [ inputq+offset2q]

  261.     pxor          m0, m0

  262.     punpcklwd     m0, m3

  263.     punpcklwd     m1, m4

  264.     pmaddwd       m0, m1

  265.     paddd         m0, m5

  266.     psrad         m0, 15

  267.     pxor          m2, m2

  268.     punpckhwd     m2, m3

  269.     punpckhwd     m1, m4

  270.     pmaddwd       m2, m1

  271.     paddd         m2, m5

  272.     psrad         m2, 15

  273.     packssdw      m0, m2

  274.     mova  [outputq+offset2q], m0

  275.     REVERSE_WORDS m3

  276.     mova          m4, [ inputq+offsetq]

  277.     pxor          m0, m0

  278.     punpcklwd     m0, m3

  279.     punpcklwd     m1, m4

  280.     pmaddwd       m0, m1

  281.     paddd         m0, m5

  282.     psrad         m0, 15

  283.     pxor          m2, m2

  284.     punpckhwd     m2, m3

  285.     punpckhwd     m1, m4

  286.     pmaddwd       m2, m1

  287.     paddd         m2, m5

  288.     psrad         m2, 15

  289.     packssdw      m0, m2

  290.     mova  [outputq+offsetq], m0

  291. %elif %3

  292.     ; This version does the 16x16->16 multiplication in-place without expanding

  293.     ; to 32-bit. The ssse3 version is bit-identical.

  294.     mova          m0, [windowq+offset2q]

  295.     mova          m1, [ inputq+offset2q]

  296.     pmulhrsw      m1, m0

  297.     REVERSE_WORDS m0, m5

  298.     pmulhrsw      m0, [ inputq+offsetq ]

  299.     mova  [outputq+offset2q], m1

  300.     mova  [outputq+offsetq ], m0

  301. %else

  302.     ; This version does the 16x16->16 multiplication in-place without expanding

  303.     ; to 32-bit. The mmxext and sse2 versions do not use rounding, and

  304.     ; therefore are not bit-identical to the C version.

  305.     mova          m0, [windowq+offset2q]

  306.     mova          m1, [ inputq+offset2q]

  307.     mova          m2, [ inputq+offsetq ]

  308.     MUL16FIXED    m1, m0, m3

  309.     REVERSE_WORDS m0

  310.     MUL16FIXED    m2, m0, m3

  311.     mova  [outputq+offset2q], m1

  312.     mova  [outputq+offsetq ], m2

  313. %endif

  314.     add      offsetd, mmsize

  315.     sub     offset2d, mmsize

  316.     jae .loop

  317.     REP_RET

  318. %endmacro

  319. 

  320. INIT_MMX

  321. %define REVERSE_WORDS REVERSE_WORDS_MMXEXT

  322. %define MUL16FIXED MUL16FIXED_MMXEXT

  323. APPLY_WINDOW_INT16 mmxext,     0, 0

  324. APPLY_WINDOW_INT16 mmxext_ba,  1, 0

  325. INIT_XMM

  326. %define REVERSE_WORDS REVERSE_WORDS_SSE2

  327. APPLY_WINDOW_INT16 sse2,       0, 0

  328. APPLY_WINDOW_INT16 sse2_ba,    1, 0

  329. APPLY_WINDOW_INT16 ssse3_atom, 0, 1

  330. %define REVERSE_WORDS REVERSE_WORDS_SSSE3

  331. APPLY_WINDOW_INT16 ssse3,      0, 1

  332. 

  333. 

  334. ; void add_hfyu_median_prediction_mmx2(uint8_t *dst, const uint8_t *top, const uint8_t *diff, int w, int *left, int *left_top)

  335. cglobal add_hfyu_median_prediction_mmx2, 6,6,0, dst, top, diff, w, left, left_top

  336.     movq    mm0, [topq]

  337.     movq    mm2, mm0

  338.     movd    mm4, [left_topq]

  339.     psllq   mm2, 8

  340.     movq    mm1, mm0

  341.     por     mm4, mm2

  342.     movd    mm3, [leftq]

  343.     psubb   mm0, mm4 ; t-tl

  344.     add    dstq, wq

  345.     add    topq, wq

  346.     add   diffq, wq

  347.     neg      wq

  348.     jmp .skip

  349. .loop:

  350.     movq    mm4, [topq+wq]

  351.     movq    mm0, mm4

  352.     psllq   mm4, 8

  353.     por     mm4, mm1

  354.     movq    mm1, mm0 ; t

  355.     psubb   mm0, mm4 ; t-tl

  356. .skip:

  357.     movq    mm2, [diffq+wq]

  358. %assign i 0

  359. %rep 8

  360.     movq    mm4, mm0

  361.     paddb   mm4, mm3 ; t-tl+l

  362.     movq    mm5, mm3

  363.     pmaxub  mm3, mm1

  364.     pminub  mm5, mm1

  365.     pminub  mm3, mm4

  366.     pmaxub  mm3, mm5 ; median

  367.     paddb   mm3, mm2 ; +residual

  368. %if i==0

  369.     movq    mm7, mm3

  370.     psllq   mm7, 56

  371. %else

  372.     movq    mm6, mm3

  373.     psrlq   mm7, 8

  374.     psllq   mm6, 56

  375.     por     mm7, mm6

  376. %endif

  377. %if i<7

  378.     psrlq   mm0, 8

  379.     psrlq   mm1, 8

  380.     psrlq   mm2, 8

  381. %endif

  382. %assign i i+1

  383. %endrep

  384.     movq [dstq+wq], mm7

  385.     add      wq, 8

  386.     jl .loop

  387.     movzx   r2d, byte [dstq-1]

  388.     mov [leftq], r2d

  389.     movzx   r2d, byte [topq-1]

  390.     mov [left_topq], r2d

  391.     RET

  392. 

  393. 

  394. %macro ADD_HFYU_LEFT_LOOP 1 ; %1 = is_aligned

  395.     add     srcq, wq

  396.     add     dstq, wq

  397.     neg     wq

  398. %%.loop:

  399.     mova    m1, [srcq+wq]

  400.     mova    m2, m1

  401.     psllw   m1, 8

  402.     paddb   m1, m2

  403.     mova    m2, m1

  404.     pshufb  m1, m3

  405.     paddb   m1, m2

  406.     pshufb  m0, m5

  407.     mova    m2, m1

  408.     pshufb  m1, m4

  409.     paddb   m1, m2

  410. %if mmsize == 16

  411.     mova    m2, m1

  412.     pshufb  m1, m6

  413.     paddb   m1, m2

  414. %endif

  415.     paddb   m0, m1

  416. %if %1

  417.     mova    [dstq+wq], m0

  418. %else

  419.     movq    [dstq+wq], m0

  420.     movhps  [dstq+wq+8], m0

  421. %endif

  422.     add     wq, mmsize

  423.     jl %%.loop

  424.     mov     eax, mmsize-1

  425.     sub     eax, wd

  426.     movd    m1, eax

  427.     pshufb  m0, m1

  428.     movd    eax, m0

  429.     RET

  430. %endmacro

  431. 

  432. ; int add_hfyu_left_prediction(uint8_t *dst, const uint8_t *src, int w, int left)

  433. INIT_MMX

  434. cglobal add_hfyu_left_prediction_ssse3, 3,3,7, dst, src, w, left

  435. .skip_prologue:

  436.     mova    m5, [pb_7]

  437.     mova    m4, [pb_zzzz3333zzzzbbbb]

  438.     mova    m3, [pb_zz11zz55zz99zzdd]

  439.     movd    m0, leftm

  440.     psllq   m0, 56

  441.     ADD_HFYU_LEFT_LOOP 1

  442. 

  443. INIT_XMM

  444. cglobal add_hfyu_left_prediction_sse4, 3,3,7, dst, src, w, left

  445.     mova    m5, [pb_f]

  446.     mova    m6, [pb_zzzzzzzz77777777]

  447.     mova    m4, [pb_zzzz3333zzzzbbbb]

  448.     mova    m3, [pb_zz11zz55zz99zzdd]

  449.     movd    m0, leftm

  450.     pslldq  m0, 15

  451.     test    srcq, 15

  452.     jnz add_hfyu_left_prediction_ssse3.skip_prologue

  453.     test    dstq, 15

  454.     jnz .unaligned

  455.     ADD_HFYU_LEFT_LOOP 1

  456. .unaligned:

  457.     ADD_HFYU_LEFT_LOOP 0

  458. 

  459. 

  460. ; float scalarproduct_float_sse(const float *v1, const float *v2, int len)

  461. cglobal scalarproduct_float_sse, 3,3,2, v1, v2, offset

  462.     neg offsetq

  463.     shl offsetq, 2

  464.     sub v1q, offsetq

  465.     sub v2q, offsetq

  466.     xorps xmm0, xmm0

  467.     .loop:

  468.         movaps   xmm1, [v1q+offsetq]

  469.         mulps    xmm1, [v2q+offsetq]

  470.         addps    xmm0, xmm1

  471.         add      offsetq, 16

  472.         js       .loop

  473.     movhlps xmm1, xmm0

  474.     addps   xmm0, xmm1

  475.     movss   xmm1, xmm0

  476.     shufps  xmm0, xmm0, 1

  477.     addss   xmm0, xmm1

  478. %if ARCH_X86_64 == 0

  479.     movd    r0m,  xmm0

  480.     fld     dword r0m

  481. %endif

  482.     RET

  483. 

  484. ; extern void ff_emu_edge_core(uint8_t *buf, const uint8_t *src, x86_reg linesize,

  485. ;                              x86_reg start_y, x86_reg end_y, x86_reg block_h,

  486. ;                              x86_reg start_x, x86_reg end_x, x86_reg block_w);

  487. ;

  488. ; The actual function itself is below. It basically wraps a very simple

  489. ; w = end_x - start_x

  490. ; if (w) {

  491. ;   if (w > 22) {

  492. ;     jump to the slow loop functions

  493. ;   } else {

  494. ;     jump to the fast loop functions

  495. ;   }

  496. ; }

  497. ;

  498. ; ... and then the same for left/right extend also. See below for loop

  499. ; function implementations. Fast are fixed-width, slow is variable-width

  500. 

  501. %macro EMU_EDGE_FUNC 0

  502. %if ARCH_X86_64

  503. %define w_reg r10

  504. cglobal emu_edge_core, 6, 7, 1

  505.     mov        r11, r5          ; save block_h

  506. %else

  507. %define w_reg r6

  508. cglobal emu_edge_core, 2, 7, 0

  509.     mov         r4, r4m         ; end_y

  510.     mov         r5, r5m         ; block_h

  511. %endif

  512. 

  513.     ; start with vertical extend (top/bottom) and body pixel copy

  514.     mov      w_reg, r7m

  515.     sub      w_reg, r6m         ; w = start_x - end_x

  516.     sub         r5, r4

  517. %if ARCH_X86_64

  518.     sub         r4, r3

  519. %else

  520.     sub         r4, dword r3m

  521. %endif

  522.     cmp      w_reg, 22

  523.     jg .slow_v_extend_loop

  524. %if ARCH_X86_32

  525.     mov         r2, r2m         ; linesize

  526. %endif

  527.     sal      w_reg, 7           ; w * 128

  528. %ifdef PIC

  529.     lea        rax, [.emuedge_v_extend_1 - (.emuedge_v_extend_2 - .emuedge_v_extend_1)]

  530.     add      w_reg, rax

  531. %else

  532.     lea      w_reg, [.emuedge_v_extend_1 - (.emuedge_v_extend_2 - .emuedge_v_extend_1)+w_reg]

  533. %endif

  534.     call     w_reg              ; fast top extend, body copy and bottom extend

  535. .v_extend_end:

  536. 

  537.     ; horizontal extend (left/right)

  538.     mov      w_reg, r6m         ; start_x

  539.     sub         r0, w_reg

  540. %if ARCH_X86_64

  541.     mov         r3, r0          ; backup of buf+block_h*linesize

  542.     mov         r5, r11

  543. %else

  544.     mov        r0m, r0          ; backup of buf+block_h*linesize

  545.     mov         r5, r5m

  546. %endif

  547.     test     w_reg, w_reg

  548.     jz .right_extend

  549.     cmp      w_reg, 22

  550.     jg .slow_left_extend_loop

  551.     mov         r1, w_reg

  552.     dec      w_reg

  553.     ; FIXME we can do a if size == 1 here if that makes any speed difference, test me

  554.     sar      w_reg, 1

  555.     sal      w_reg, 6

  556.     ; r0=buf+block_h*linesize,r10(64)/r6(32)=start_x offset for funcs

  557.     ; r6(rax)/r3(ebx)=val,r2=linesize,r1=start_x,r5=block_h

  558. %ifdef PIC

  559.     lea        rax, [.emuedge_extend_left_2]

  560.     add      w_reg, rax

  561. %else

  562.     lea      w_reg, [.emuedge_extend_left_2+w_reg]

  563. %endif

  564.     call     w_reg

  565. 

  566.     ; now r3(64)/r0(32)=buf,r2=linesize,r11/r5=block_h,r6/r3=val, r10/r6=end_x, r1=block_w

  567. .right_extend:

  568. %if ARCH_X86_32

  569.     mov         r0, r0m

  570.     mov         r5, r5m

  571. %endif

  572.     mov      w_reg, r7m         ; end_x

  573.     mov         r1, r8m         ; block_w

  574.     mov         r4, r1

  575.     sub         r1, w_reg

  576.     jz .h_extend_end            ; if (end_x == block_w) goto h_extend_end

  577.     cmp         r1, 22

  578.     jg .slow_right_extend_loop

  579.     dec         r1

  580.     ; FIXME we can do a if size == 1 here if that makes any speed difference, test me

  581.     sar         r1, 1

  582.     sal         r1, 6

  583. %ifdef PIC

  584.     lea        rax, [.emuedge_extend_right_2]

  585.     add         r1, rax

  586. %else

  587.     lea         r1, [.emuedge_extend_right_2+r1]

  588. %endif

  589.     call        r1

  590. .h_extend_end:

  591.     RET

  592. 

  593. %if ARCH_X86_64

  594. %define vall  al

  595. %define valh  ah

  596. %define valw  ax

  597. %define valw2 r10w

  598. %define valw3 r3w

  599. %if WIN64

  600. %define valw4 r4w

  601. %else ; unix64

  602. %define valw4 r3w

  603. %endif

  604. %define vald eax

  605. %else

  606. %define vall  bl

  607. %define valh  bh

  608. %define valw  bx

  609. %define valw2 r6w

  610. %define valw3 valw2

  611. %define valw4 valw3

  612. %define vald ebx

  613. %define stack_offset 0x14

  614. %endif

  615. 

  616. %endmacro

  617. 

  618. ; macro to read/write a horizontal number of pixels (%2) to/from registers

  619. ; on x86-64, - fills xmm0-15 for consecutive sets of 16 pixels

  620. ;            - if (%2 & 15 == 8) fills the last 8 bytes into rax

  621. ;            - else if (%2 & 8)  fills 8 bytes into mm0

  622. ;            - if (%2 & 7 == 4)  fills the last 4 bytes into rax

  623. ;            - else if (%2 & 4)  fills 4 bytes into mm0-1

  624. ;            - if (%2 & 3 == 3)  fills 2 bytes into r10/r3, and 1 into eax

  625. ;              (note that we're using r3 for body/bottom because it's a shorter

  626. ;               opcode, and then the loop fits in 128 bytes)

  627. ;            - else              fills remaining bytes into rax

  628. ; on x86-32, - fills mm0-7 for consecutive sets of 8 pixels

  629. ;            - if (%2 & 7 == 4)  fills 4 bytes into ebx

  630. ;            - else if (%2 & 4)  fills 4 bytes into mm0-7

  631. ;            - if (%2 & 3 == 3)  fills 2 bytes into r6, and 1 into ebx

  632. ;            - else              fills remaining bytes into ebx

  633. ; writing data out is in the same way

  634. %macro READ_NUM_BYTES 2

  635. %assign %%src_off 0 ; offset in source buffer

  636. %assign %%smidx   0 ; mmx register idx

  637. %assign %%sxidx   0 ; xmm register idx

  638. 

  639. %if cpuflag(sse)

  640. %rep %2/16

  641.     movups xmm %+ %%sxidx, [r1+%%src_off]

  642. %assign %%src_off %%src_off+16

  643. %assign %%sxidx   %%sxidx+1

  644. %endrep ; %2/16

  645. %endif

  646. 

  647. %if ARCH_X86_64

  648. %if (%2-%%src_off) == 8

  649.     mov           rax, [r1+%%src_off]

  650. %assign %%src_off %%src_off+8

  651. %endif ; (%2-%%src_off) == 8

  652. %endif ; x86-64

  653. 

  654. %rep (%2-%%src_off)/8

  655.     movq    mm %+ %%smidx, [r1+%%src_off]

  656. %assign %%src_off %%src_off+8

  657. %assign %%smidx   %%smidx+1

  658. %endrep ; (%2-%%dst_off)/8

  659. 

  660. %if (%2-%%src_off) == 4

  661.     mov          vald, [r1+%%src_off]

  662. %elif (%2-%%src_off) & 4

  663.     movd    mm %+ %%smidx, [r1+%%src_off]

  664. %assign %%src_off %%src_off+4

  665. %endif ; (%2-%%src_off) ==/& 4

  666. 

  667. %if (%2-%%src_off) == 1

  668.     mov          vall, [r1+%%src_off]

  669. %elif (%2-%%src_off) == 2

  670.     mov          valw, [r1+%%src_off]

  671. %elif (%2-%%src_off) == 3

  672. %ifidn %1, top

  673.     mov         valw2, [r1+%%src_off]

  674. %elifidn %1, body

  675.     mov         valw3, [r1+%%src_off]

  676. %elifidn %1, bottom

  677.     mov         valw4, [r1+%%src_off]

  678. %endif ; %1 ==/!= top

  679.     mov          vall, [r1+%%src_off+2]

  680. %endif ; (%2-%%src_off) == 1/2/3

  681. %endmacro ; READ_NUM_BYTES

  682. 

  683. %macro WRITE_NUM_BYTES 2

  684. %assign %%dst_off 0 ; offset in destination buffer

  685. %assign %%dmidx   0 ; mmx register idx

  686. %assign %%dxidx   0 ; xmm register idx

  687. 

  688. %if cpuflag(sse)

  689. %rep %2/16

  690.     movups [r0+%%dst_off], xmm %+ %%dxidx

  691. %assign %%dst_off %%dst_off+16

  692. %assign %%dxidx   %%dxidx+1

  693. %endrep ; %2/16

  694. %endif

  695. 

  696. %if ARCH_X86_64

  697. %if (%2-%%dst_off) == 8

  698.     mov    [r0+%%dst_off], rax

  699. %assign %%dst_off %%dst_off+8

  700. %endif ; (%2-%%dst_off) == 8

  701. %endif ; x86-64

  702. 

  703. %rep (%2-%%dst_off)/8

  704.     movq   [r0+%%dst_off], mm %+ %%dmidx

  705. %assign %%dst_off %%dst_off+8

  706. %assign %%dmidx   %%dmidx+1

  707. %endrep ; (%2-%%dst_off)/8

  708. 

  709. %if (%2-%%dst_off) == 4

  710.     mov    [r0+%%dst_off], vald

  711. %elif (%2-%%dst_off) & 4

  712.     movd   [r0+%%dst_off], mm %+ %%dmidx

  713. %assign %%dst_off %%dst_off+4

  714. %endif ; (%2-%%dst_off) ==/& 4

  715. 

  716. %if (%2-%%dst_off) == 1

  717.     mov    [r0+%%dst_off], vall

  718. %elif (%2-%%dst_off) == 2

  719.     mov    [r0+%%dst_off], valw

  720. %elif (%2-%%dst_off) == 3

  721. %ifidn %1, top

  722.     mov    [r0+%%dst_off], valw2

  723. %elifidn %1, body

  724.     mov    [r0+%%dst_off], valw3

  725. %elifidn %1, bottom

  726.     mov    [r0+%%dst_off], valw4

  727. %endif ; %1 ==/!= top

  728.     mov  [r0+%%dst_off+2], vall

  729. %endif ; (%2-%%dst_off) == 1/2/3

  730. %endmacro ; WRITE_NUM_BYTES

  731. 

  732. ; vertical top/bottom extend and body copy fast loops

  733. ; these are function pointers to set-width line copy functions, i.e.

  734. ; they read a fixed number of pixels into set registers, and write

  735. ; those out into the destination buffer

  736. ; r0=buf,r1=src,r2=linesize,r3(64)/r3m(32)=start_x,r4=end_y,r5=block_h

  737. ; r6(eax/64)/r3(ebx/32)=val_reg

  738. %macro VERTICAL_EXTEND 0

  739. %assign %%n 1

  740. %rep 22

  741. ALIGN 128

  742. .emuedge_v_extend_ %+ %%n:

  743.     ; extend pixels above body

  744. %if ARCH_X86_64

  745.     test           r3 , r3                   ; if (!start_y)

  746.     jz .emuedge_copy_body_ %+ %%n %+ _loop   ;   goto body

  747. %else ; ARCH_X86_32

  748.     cmp      dword r3m, 0

  749.     je .emuedge_copy_body_ %+ %%n %+ _loop

  750. %endif ; ARCH_X86_64/32

  751.     READ_NUM_BYTES  top,    %%n              ; read bytes

  752. .emuedge_extend_top_ %+ %%n %+ _loop:        ; do {

  753.     WRITE_NUM_BYTES top,    %%n              ;   write bytes

  754.     add            r0 , r2                   ;   dst += linesize

  755. %if ARCH_X86_64

  756.     dec            r3d

  757. %else ; ARCH_X86_32

  758.     dec      dword r3m

  759. %endif ; ARCH_X86_64/32

  760.     jnz .emuedge_extend_top_ %+ %%n %+ _loop ; } while (--start_y)

  761. 

  762.     ; copy body pixels

  763. .emuedge_copy_body_ %+ %%n %+ _loop:         ; do {

  764.     READ_NUM_BYTES  body,   %%n              ;   read bytes

  765.     WRITE_NUM_BYTES body,   %%n              ;   write bytes

  766.     add            r0 , r2                   ;   dst += linesize

  767.     add            r1 , r2                   ;   src += linesize

  768.     dec            r4d

  769.     jnz .emuedge_copy_body_ %+ %%n %+ _loop  ; } while (--end_y)

  770. 

  771.     ; copy bottom pixels

  772.     test           r5 , r5                   ; if (!block_h)

  773.     jz .emuedge_v_extend_end_ %+ %%n         ;   goto end

  774.     sub            r1 , r2                   ; src -= linesize

  775.     READ_NUM_BYTES  bottom, %%n              ; read bytes

  776. .emuedge_extend_bottom_ %+ %%n %+ _loop:     ; do {

  777.     WRITE_NUM_BYTES bottom, %%n              ;   write bytes

  778.     add            r0 , r2                   ;   dst += linesize

  779.     dec            r5d

  780.     jnz .emuedge_extend_bottom_ %+ %%n %+ _loop ; } while (--block_h)

  781. 

  782. .emuedge_v_extend_end_ %+ %%n:

  783. %if ARCH_X86_64

  784.     ret

  785. %else ; ARCH_X86_32

  786.     rep ret

  787. %endif ; ARCH_X86_64/32

  788. %assign %%n %%n+1

  789. %endrep

  790. %endmacro VERTICAL_EXTEND

  791. 

  792. ; left/right (horizontal) fast extend functions

  793. ; these are essentially identical to the vertical extend ones above,

  794. ; just left/right separated because number of pixels to extend is

  795. ; obviously not the same on both sides.

  796. ; for reading, pixels are placed in eax (x86-64) or ebx (x86-64) in the

  797. ; lowest two bytes of the register (so val*0x0101), and are splatted

  798. ; into each byte of mm0 as well if n_pixels >= 8

  799. 

  800. %macro READ_V_PIXEL 2

  801.     mov        vall, %2

  802.     mov        valh, vall

  803. %if %1 >= 8

  804.     movd        mm0, vald

  805. %if cpuflag(mmx2)

  806.     pshufw      mm0, mm0, 0

  807. %else ; mmx

  808.     punpcklwd   mm0, mm0

  809.     punpckldq   mm0, mm0

  810. %endif ; sse

  811. %endif ; %1 >= 8

  812. %endmacro

  813. 

  814. %macro WRITE_V_PIXEL 2

  815. %assign %%dst_off 0

  816. %rep %1/8

  817.     movq [%2+%%dst_off], mm0

  818. %assign %%dst_off %%dst_off+8

  819. %endrep

  820. %if %1 & 4

  821. %if %1 >= 8

  822.     movd [%2+%%dst_off], mm0

  823. %else ; %1 < 8

  824.     mov  [%2+%%dst_off]  , valw

  825.     mov  [%2+%%dst_off+2], valw

  826. %endif ; %1 >=/< 8

  827. %assign %%dst_off %%dst_off+4

  828. %endif ; %1 & 4

  829. %if %1&2

  830.     mov  [%2+%%dst_off], valw

  831. %endif ; %1 & 2

  832. %endmacro

  833. 

  834. ; r0=buf+block_h*linesize, r1=start_x, r2=linesize, r5=block_h, r6/r3=val

  835. %macro LEFT_EXTEND 0

  836. %assign %%n 2

  837. %rep 11

  838. ALIGN 64

  839. .emuedge_extend_left_ %+ %%n:          ; do {

  840.     sub         r0, r2                 ;   dst -= linesize

  841.     READ_V_PIXEL  %%n, [r0+r1]         ;   read pixels

  842.     WRITE_V_PIXEL %%n, r0              ;   write pixels

  843.     dec         r5

  844.     jnz .emuedge_extend_left_ %+ %%n   ; } while (--block_h)

  845. %if ARCH_X86_64

  846.     ret

  847. %else ; ARCH_X86_32

  848.     rep ret

  849. %endif ; ARCH_X86_64/32

  850. %assign %%n %%n+2

  851. %endrep

  852. %endmacro ; LEFT_EXTEND

  853. 

  854. ; r3/r0=buf+block_h*linesize, r2=linesize, r11/r5=block_h, r0/r6=end_x, r6/r3=val

  855. %macro RIGHT_EXTEND 0

  856. %assign %%n 2

  857. %rep 11

  858. ALIGN 64

  859. .emuedge_extend_right_ %+ %%n:          ; do {

  860. %if ARCH_X86_64

  861.     sub        r3, r2                   ;   dst -= linesize

  862.     READ_V_PIXEL  %%n, [r3+w_reg-1]     ;   read pixels

  863.     WRITE_V_PIXEL %%n, r3+r4-%%n        ;   write pixels

  864.     dec       r11

  865. %else ; ARCH_X86_32

  866.     sub        r0, r2                   ;   dst -= linesize

  867.     READ_V_PIXEL  %%n, [r0+w_reg-1]     ;   read pixels

  868.     WRITE_V_PIXEL %%n, r0+r4-%%n        ;   write pixels

  869.     dec     r5

  870. %endif ; ARCH_X86_64/32

  871.     jnz .emuedge_extend_right_ %+ %%n   ; } while (--block_h)

  872. %if ARCH_X86_64

  873.     ret

  874. %else ; ARCH_X86_32

  875.     rep ret

  876. %endif ; ARCH_X86_64/32

  877. %assign %%n %%n+2

  878. %endrep

  879. 

  880. %if ARCH_X86_32

  881. %define stack_offset 0x10

  882. %endif

  883. %endmacro ; RIGHT_EXTEND

  884. 

  885. ; below follow the "slow" copy/extend functions, these act on a non-fixed

  886. ; width specified in a register, and run a loop to copy the full amount

  887. ; of bytes. They are optimized for copying of large amounts of pixels per

  888. ; line, so they unconditionally splat data into mm registers to copy 8

  889. ; bytes per loop iteration. It could be considered to use xmm for x86-64

  890. ; also, but I haven't optimized this as much (i.e. FIXME)

  891. %macro V_COPY_NPX 4-5

  892. %if %0 == 4

  893.     test     w_reg, %4

  894.     jz .%1_skip_%4_px

  895. %else ; %0 == 5

  896. .%1_%4_px_loop:

  897. %endif

  898.     %3          %2, [r1+cnt_reg]

  899.     %3 [r0+cnt_reg], %2

  900.     add    cnt_reg, %4

  901. %if %0 == 5

  902.     sub      w_reg, %4

  903.     test     w_reg, %5

  904.     jnz .%1_%4_px_loop

  905. %endif

  906. .%1_skip_%4_px:

  907. %endmacro

  908. 

  909. %macro V_COPY_ROW 2

  910. %ifidn %1, bottom

  911.     sub         r1, linesize

  912. %endif

  913. .%1_copy_loop:

  914.     xor    cnt_reg, cnt_reg

  915. %if notcpuflag(sse)

  916. %define linesize r2m

  917.     V_COPY_NPX %1,  mm0, movq,    8, 0xFFFFFFF8

  918. %else ; sse

  919.     V_COPY_NPX %1, xmm0, movups, 16, 0xFFFFFFF0

  920. %if ARCH_X86_64

  921. %define linesize r2

  922.     V_COPY_NPX %1, rax , mov,     8

  923. %else ; ARCH_X86_32

  924. %define linesize r2m

  925.     V_COPY_NPX %1,  mm0, movq,    8

  926. %endif ; ARCH_X86_64/32

  927. %endif ; sse

  928.     V_COPY_NPX %1, vald, mov,     4

  929.     V_COPY_NPX %1, valw, mov,     2

  930.     V_COPY_NPX %1, vall, mov,     1

  931.     mov      w_reg, cnt_reg

  932. %ifidn %1, body

  933.     add         r1, linesize

  934. %endif

  935.     add         r0, linesize

  936.     dec         %2

  937.     jnz .%1_copy_loop

  938. %endmacro

  939. 

  940. %macro SLOW_V_EXTEND 0

  941. .slow_v_extend_loop:

  942. ; r0=buf,r1=src,r2(64)/r2m(32)=linesize,r3(64)/r3m(32)=start_x,r4=end_y,r5=block_h

  943. ; r11(64)/r3(later-64)/r2(32)=cnt_reg,r6(64)/r3(32)=val_reg,r10(64)/r6(32)=w=end_x-start_x

  944. %if ARCH_X86_64

  945.     push       r11              ; save old value of block_h

  946.     test        r3, r3

  947. %define cnt_reg r11

  948.     jz .do_body_copy            ; if (!start_y) goto do_body_copy

  949.     V_COPY_ROW top, r3

  950. %else

  951.     cmp  dword r3m, 0

  952. %define cnt_reg r2

  953.     je .do_body_copy            ; if (!start_y) goto do_body_copy

  954.     V_COPY_ROW top, dword r3m

  955. %endif

  956. 

  957. .do_body_copy:

  958.     V_COPY_ROW body, r4

  959. 

  960. %if ARCH_X86_64

  961.     pop        r11              ; restore old value of block_h

  962. %define cnt_reg r3

  963. %endif

  964.     test        r5, r5

  965. %if ARCH_X86_64

  966.     jz .v_extend_end

  967. %else

  968.     jz .skip_bottom_extend

  969. %endif

  970.     V_COPY_ROW bottom, r5

  971. %if ARCH_X86_32

  972. .skip_bottom_extend:

  973.     mov         r2, r2m

  974. %endif

  975.     jmp .v_extend_end

  976. %endmacro

  977. 

  978. %macro SLOW_LEFT_EXTEND 0

  979. .slow_left_extend_loop:

  980. ; r0=buf+block_h*linesize,r2=linesize,r6(64)/r3(32)=val,r5=block_h,r4=cntr,r10/r6=start_x

  981.     mov         r4, 8

  982.     sub         r0, linesize

  983.     READ_V_PIXEL 8, [r0+w_reg]

  984. .left_extend_8px_loop:

  985.     movq [r0+r4-8], mm0

  986.     add         r4, 8

  987.     cmp         r4, w_reg

  988.     jle .left_extend_8px_loop

  989.     sub         r4, 8

  990.     cmp         r4, w_reg

  991.     jge .left_extend_loop_end

  992. .left_extend_2px_loop:

  993.     mov    [r0+r4], valw

  994.     add         r4, 2

  995.     cmp         r4, w_reg

  996.     jl .left_extend_2px_loop

  997. .left_extend_loop_end:

  998.     dec         r5

  999.     jnz .slow_left_extend_loop

  1000. %if ARCH_X86_32

  1001.     mov         r2, r2m

  1002. %endif

  1003.     jmp .right_extend

  1004. %endmacro

  1005. 

  1006. %macro SLOW_RIGHT_EXTEND 0

  1007. .slow_right_extend_loop:

  1008. ; r3(64)/r0(32)=buf+block_h*linesize,r2=linesize,r4=block_w,r11(64)/r5(32)=block_h,

  1009. ; r10(64)/r6(32)=end_x,r6/r3=val,r1=cntr

  1010. %if ARCH_X86_64

  1011. %define buf_reg r3

  1012. %define bh_reg r11

  1013. %else

  1014. %define buf_reg r0

  1015. %define bh_reg r5

  1016. %endif

  1017.     lea         r1, [r4-8]

  1018.     sub    buf_reg, linesize

  1019.     READ_V_PIXEL 8, [buf_reg+w_reg-1]

  1020. .right_extend_8px_loop:

  1021.     movq [buf_reg+r1], mm0

  1022.     sub         r1, 8

  1023.     cmp         r1, w_reg

  1024.     jge .right_extend_8px_loop

  1025.     add         r1, 8

  1026.     cmp         r1, w_reg

  1027.     je .right_extend_loop_end

  1028. .right_extend_2px_loop:

  1029.     sub         r1, 2

  1030.     mov [buf_reg+r1], valw

  1031.     cmp         r1, w_reg

  1032.     jg .right_extend_2px_loop

  1033. .right_extend_loop_end:

  1034.     dec         bh_reg

  1035.     jnz .slow_right_extend_loop

  1036.     jmp .h_extend_end

  1037. %endmacro

  1038. 

  1039. %macro emu_edge 1

  1040. INIT_XMM %1

  1041. EMU_EDGE_FUNC

  1042. VERTICAL_EXTEND

  1043. LEFT_EXTEND

  1044. RIGHT_EXTEND

  1045. SLOW_V_EXTEND

  1046. SLOW_LEFT_EXTEND

  1047. SLOW_RIGHT_EXTEND

  1048. %endmacro

  1049. 

  1050. emu_edge sse

  1051. %if ARCH_X86_32

  1052. emu_edge mmx

  1053. %endif

  1054. 

  1055. ;-----------------------------------------------------------------------------

  1056. ; void ff_vector_clip_int32(int32_t *dst, const int32_t *src, int32_t min,

  1057. ;                           int32_t max, unsigned int len)

  1058. ;-----------------------------------------------------------------------------

  1059. 

  1060. ; %1 = number of xmm registers used

  1061. ; %2 = number of inline load/process/store loops per asm loop

  1062. ; %3 = process 4*mmsize (%3=0) or 8*mmsize (%3=1) bytes per loop

  1063. ; %4 = CLIPD function takes min/max as float instead of int (CLIPD_SSE2)

  1064. ; %5 = suffix

  1065. %macro VECTOR_CLIP_INT32 4-5

  1066. cglobal vector_clip_int32%5, 5,5,%1, dst, src, min, max, len

  1067. %if %4

  1068.     cvtsi2ss  m4, minm

  1069.     cvtsi2ss  m5, maxm

  1070. %else

  1071.     movd      m4, minm

  1072.     movd      m5, maxm

  1073. %endif

  1074.     SPLATD    m4

  1075.     SPLATD    m5

  1076. .loop:

  1077. %assign %%i 1

  1078. %rep %2

  1079.     mova      m0,  [srcq+mmsize*0*%%i]

  1080.     mova      m1,  [srcq+mmsize*1*%%i]

  1081.     mova      m2,  [srcq+mmsize*2*%%i]

  1082.     mova      m3,  [srcq+mmsize*3*%%i]

  1083. %if %3

  1084.     mova      m7,  [srcq+mmsize*4*%%i]

  1085.     mova      m8,  [srcq+mmsize*5*%%i]

  1086.     mova      m9,  [srcq+mmsize*6*%%i]

  1087.     mova      m10, [srcq+mmsize*7*%%i]

  1088. %endif

  1089.     CLIPD  m0,  m4, m5, m6

  1090.     CLIPD  m1,  m4, m5, m6

  1091.     CLIPD  m2,  m4, m5, m6

  1092.     CLIPD  m3,  m4, m5, m6

  1093. %if %3

  1094.     CLIPD  m7,  m4, m5, m6

  1095.     CLIPD  m8,  m4, m5, m6

  1096.     CLIPD  m9,  m4, m5, m6

  1097.     CLIPD  m10, m4, m5, m6

  1098. %endif

  1099.     mova  [dstq+mmsize*0*%%i], m0

  1100.     mova  [dstq+mmsize*1*%%i], m1

  1101.     mova  [dstq+mmsize*2*%%i], m2

  1102.     mova  [dstq+mmsize*3*%%i], m3

  1103. %if %3

  1104.     mova  [dstq+mmsize*4*%%i], m7

  1105.     mova  [dstq+mmsize*5*%%i], m8

  1106.     mova  [dstq+mmsize*6*%%i], m9

  1107.     mova  [dstq+mmsize*7*%%i], m10

  1108. %endif

  1109. %assign %%i %%i+1

  1110. %endrep

  1111.     add     srcq, mmsize*4*(%2+%3)

  1112.     add     dstq, mmsize*4*(%2+%3)

  1113.     sub     lend, mmsize*(%2+%3)

  1114.     jg .loop

  1115.     REP_RET

  1116. %endmacro

  1117. 

  1118. INIT_MMX mmx

  1119. %define SPLATD SPLATD_MMX

  1120. %define CLIPD CLIPD_MMX

  1121. VECTOR_CLIP_INT32 0, 1, 0, 0

  1122. INIT_XMM sse2

  1123. %define SPLATD SPLATD_SSE2

  1124. VECTOR_CLIP_INT32 6, 1, 0, 0, _int

  1125. %define CLIPD CLIPD_SSE2

  1126. VECTOR_CLIP_INT32 6, 2, 0, 1

  1127. INIT_XMM sse4

  1128. %define CLIPD CLIPD_SSE41

  1129. %ifdef m8

  1130. VECTOR_CLIP_INT32 11, 1, 1, 0

  1131. %else

  1132. VECTOR_CLIP_INT32 6, 1, 0, 0

  1133. %endif

  1134. 

  1135. ;-----------------------------------------------------------------------------

  1136. ; void ff_butterflies_float_interleave(float *dst, const float *src0,

  1137. ;                                      const float *src1, int len);

  1138. ;-----------------------------------------------------------------------------

  1139. 

  1140. %macro BUTTERFLIES_FLOAT_INTERLEAVE 0

  1141. cglobal butterflies_float_interleave, 4,4,3, dst, src0, src1, len

  1142. %if ARCH_X86_64

  1143.     movsxd    lenq, lend

  1144. %endif

  1145.     test      lenq, lenq

  1146.     jz .end

  1147.     shl       lenq, 2

  1148.     lea      src0q, [src0q +   lenq]

  1149.     lea      src1q, [src1q +   lenq]

  1150.     lea       dstq, [ dstq + 2*lenq]

  1151.     neg       lenq

  1152. .loop:

  1153.     mova        m0, [src0q + lenq]

  1154.     mova        m1, [src1q + lenq]

  1155.     subps       m2, m0, m1

  1156.     addps       m0, m0, m1

  1157.     unpcklps    m1, m0, m2

  1158.     unpckhps    m0, m0, m2

  1159. %if cpuflag(avx)

  1160.     vextractf128 [dstq + 2*lenq     ], m1, 0

  1161.     vextractf128 [dstq + 2*lenq + 16], m0, 0

  1162.     vextractf128 [dstq + 2*lenq + 32], m1, 1

  1163.     vextractf128 [dstq + 2*lenq + 48], m0, 1

  1164. %else

  1165.     mova [dstq + 2*lenq         ], m1

  1166.     mova [dstq + 2*lenq + mmsize], m0

  1167. %endif

  1168.     add       lenq, mmsize

  1169.     jl .loop

  1170. %if mmsize == 32

  1171.     vzeroupper

  1172.     RET

  1173. %endif

  1174. .end:

  1175.     REP_RET

  1176. %endmacro

  1177. 

  1178. INIT_XMM sse

  1179. BUTTERFLIES_FLOAT_INTERLEAVE

  1180. INIT_YMM avx

  1181. BUTTERFLIES_FLOAT_INTERLEAVE

  1182. 

  1183. INIT_XMM sse2

  1184. ; %1 = aligned/unaligned

  1185. %macro BSWAP_LOOPS_SSE2  1

  1186.     mov      r3, r2

  1187.     sar      r2, 3

  1188.     jz       .left4_%1

  1189. .loop8_%1:

  1190.     mov%1    m0, [r1 +  0]

  1191.     mov%1    m1, [r1 + 16]

  1192.     pshuflw  m0, m0, 10110001b

  1193.     pshuflw  m1, m1, 10110001b

  1194.     pshufhw  m0, m0, 10110001b

  1195.     pshufhw  m1, m1, 10110001b

  1196.     mova     m2, m0

  1197.     mova     m3, m1

  1198.     psllw    m0, 8

  1199.     psllw    m1, 8

  1200.     psrlw    m2, 8

  1201.     psrlw    m3, 8

  1202.     por      m2, m0

  1203.     por      m3, m1

  1204.     mova     [r0 +  0], m2

  1205.     mova     [r0 + 16], m3

  1206.     add      r1, 32

  1207.     add      r0, 32

  1208.     dec      r2

  1209.     jnz      .loop8_%1

  1210. .left4_%1:

  1211.     mov      r2, r3

  1212.     and      r3, 4

  1213.     jz       .left

  1214.     mov%1    m0, [r1]

  1215.     pshuflw  m0, m0, 10110001b

  1216.     pshufhw  m0, m0, 10110001b

  1217.     mova     m2, m0

  1218.     psllw    m0, 8

  1219.     psrlw    m2, 8

  1220.     por      m2, m0

  1221.     mova     [r0], m2

  1222.     add      r1, 16

  1223.     add      r0, 16

  1224. %endmacro

  1225. 

  1226. ; void bswap_buf(uint32_t *dst, const uint32_t *src, int w);

  1227. cglobal bswap32_buf, 3,4,5

  1228.     mov      r3, r1

  1229.     and      r3, 15

  1230.     jz       .start_align

  1231.     BSWAP_LOOPS_SSE2  u

  1232.     jmp      .left

  1233. .start_align:

  1234.     BSWAP_LOOPS_SSE2  a

  1235. .left:

  1236.     and      r2, 3

  1237.     jz       .end

  1238. .loop2:

  1239.     mov      r3d, [r1]

  1240.     bswap    r3d

  1241.     mov      [r0], r3d

  1242.     add      r1, 4

  1243.     add      r0, 4

  1244.     dec      r2

  1245.     jnz      .loop2

  1246. .end

  1247.     RET

  1248. 

  1249. ; %1 = aligned/unaligned

  1250. %macro BSWAP_LOOPS_SSSE3  1

  1251.     mov      r3, r2

  1252.     sar      r2, 3

  1253.     jz       .left4_%1

  1254. .loop8_%1:

  1255.     mov%1    m0, [r1 +  0]

  1256.     mov%1    m1, [r1 + 16]

  1257.     pshufb   m0, m2

  1258.     pshufb   m1, m2

  1259.     mova     [r0 +  0], m0

  1260.     mova     [r0 + 16], m1

  1261.     add      r0, 32

  1262.     add      r1, 32

  1263.     dec      r2

  1264.     jnz      .loop8_%1

  1265. .left4_%1:

  1266.     mov      r2, r3

  1267.     and      r3, 4

  1268.     jz       .left2

  1269.     mov%1    m0, [r1]

  1270.     pshufb   m0, m2

  1271.     mova     [r0], m0

  1272.     add      r1, 16

  1273.     add      r0, 16

  1274. %endmacro

  1275. 

  1276. INIT_XMM ssse3

  1277. ; void bswap_buf(uint32_t *dst, const uint32_t *src, int w);

  1278. cglobal bswap32_buf, 3,4,3

  1279.     mov      r3, r1

  1280.     mova     m2, [pb_bswap32]

  1281.     and      r3, 15

  1282.     jz       .start_align

  1283.     BSWAP_LOOPS_SSSE3  u

  1284.     jmp      .left2

  1285. .start_align:

  1286.     BSWAP_LOOPS_SSSE3  a

  1287. .left2:

  1288.     mov      r3, r2

  1289.     and      r2, 2

  1290.     jz       .left1

  1291.     movq     m0, [r1]

  1292.     pshufb   m0, m2

  1293.     movq     [r0], m0

  1294.     add      r1, 8

  1295.     add      r0, 8

  1296. .left1:

  1297.     and      r3, 1

  1298.     jz       .end

  1299.     mov      r2d, [r1]

  1300.     bswap    r2d

  1301.     mov      [r0], r2d

  1302. .end:

  1303.     RET