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2170a0e6ad
Also implement SSE2/AVX variants.
243 lines
7.7 KiB
NASM
243 lines
7.7 KiB
NASM
;******************************************************************************
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;* x86-optimized input routines; does shuffling of packed
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;* YUV formats into individual planes, and converts RGB
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;* into YUV planes also.
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;* Copyright (c) 2012 Ronald S. Bultje <rsbultje@gmail.com>
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;*
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;* This file is part of Libav.
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;*
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;* Libav is free software; you can redistribute it and/or
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;* modify it under the terms of the GNU Lesser General Public
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;* License as published by the Free Software Foundation; either
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;* version 2.1 of the License, or (at your option) any later version.
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;*
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;* Libav is distributed in the hope that it will be useful,
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;* but WITHOUT ANY WARRANTY; without even the implied warranty of
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;* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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;* Lesser General Public License for more details.
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;*
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;* You should have received a copy of the GNU Lesser General Public
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;* License along with Libav; if not, write to the Free Software
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;* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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;******************************************************************************
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%include "x86inc.asm"
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%include "x86util.asm"
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SECTION_RODATA
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SECTION .text
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;-----------------------------------------------------------------------------
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; YUYV/UYVY/NV12/NV21 packed pixel shuffling.
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;
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; void <fmt>ToY_<opt>(uint8_t *dst, const uint8_t *src, int w);
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; and
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; void <fmt>toUV_<opt>(uint8_t *dstU, uint8_t *dstV, const uint8_t *src,
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; const uint8_t *unused, int w);
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;-----------------------------------------------------------------------------
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; %1 = a (aligned) or u (unaligned)
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; %2 = yuyv or uyvy
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%macro LOOP_YUYV_TO_Y 2
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.loop_%1:
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mov%1 m0, [srcq+wq*2] ; (byte) { Y0, U0, Y1, V0, ... }
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mov%1 m1, [srcq+wq*2+mmsize] ; (byte) { Y8, U4, Y9, V4, ... }
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%ifidn %2, yuyv
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pand m0, m2 ; (word) { Y0, Y1, ..., Y7 }
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pand m1, m2 ; (word) { Y8, Y9, ..., Y15 }
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%else ; uyvy
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psrlw m0, 8 ; (word) { Y0, Y1, ..., Y7 }
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psrlw m1, 8 ; (word) { Y8, Y9, ..., Y15 }
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%endif ; yuyv/uyvy
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packuswb m0, m1 ; (byte) { Y0, ..., Y15 }
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mova [dstq+wq], m0
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add wq, mmsize
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jl .loop_%1
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REP_RET
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%endmacro
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; %1 = nr. of XMM registers
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; %2 = yuyv or uyvy
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; %3 = if specified, it means that unaligned and aligned code in loop
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; will be the same (i.e. YUYV+AVX), and thus we don't need to
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; split the loop in an aligned and unaligned case
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%macro YUYV_TO_Y_FN 2-3
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cglobal %2ToY, 3, 3, %1, dst, src, w
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%ifdef ARCH_X86_64
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movsxd wq, wd
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%endif
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add dstq, wq
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%if mmsize == 16
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test srcq, 15
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%endif
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lea srcq, [srcq+wq*2]
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%ifidn %2, yuyv
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pcmpeqb m2, m2 ; (byte) { 0xff } x 16
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psrlw m2, 8 ; (word) { 0x00ff } x 8
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%endif ; yuyv
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%if mmsize == 16
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jnz .loop_u_start
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neg wq
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LOOP_YUYV_TO_Y a, %2
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.loop_u_start:
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neg wq
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LOOP_YUYV_TO_Y u, %2
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%else ; mmsize == 8
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neg wq
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LOOP_YUYV_TO_Y a, %2
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%endif ; mmsize == 8/16
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%endmacro
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; %1 = a (aligned) or u (unaligned)
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; %2 = yuyv or uyvy
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%macro LOOP_YUYV_TO_UV 2
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.loop_%1:
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%ifidn %2, yuyv
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mov%1 m0, [srcq+wq*4] ; (byte) { Y0, U0, Y1, V0, ... }
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mov%1 m1, [srcq+wq*4+mmsize] ; (byte) { Y8, U4, Y9, V4, ... }
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psrlw m0, 8 ; (word) { U0, V0, ..., U3, V3 }
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psrlw m1, 8 ; (word) { U4, V4, ..., U7, V7 }
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%else ; uyvy
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%if cpuflag(avx)
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vpand m0, m2, [srcq+wq*4] ; (word) { U0, V0, ..., U3, V3 }
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vpand m1, m2, [srcq+wq*4+mmsize] ; (word) { U4, V4, ..., U7, V7 }
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%else
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mov%1 m0, [srcq+wq*4] ; (byte) { Y0, U0, Y1, V0, ... }
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mov%1 m1, [srcq+wq*4+mmsize] ; (byte) { Y8, U4, Y9, V4, ... }
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pand m0, m2 ; (word) { U0, V0, ..., U3, V3 }
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pand m1, m2 ; (word) { U4, V4, ..., U7, V7 }
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%endif
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%endif ; yuyv/uyvy
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packuswb m0, m1 ; (byte) { U0, V0, ..., U7, V7 }
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pand m1, m0, m2 ; (word) { U0, U1, ..., U7 }
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psrlw m0, 8 ; (word) { V0, V1, ..., V7 }
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%if mmsize == 16
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packuswb m1, m0 ; (byte) { U0, ... U7, V1, ... V7 }
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movh [dstUq+wq], m1
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movhps [dstVq+wq], m1
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%else ; mmsize == 8
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packuswb m1, m1 ; (byte) { U0, ... U3 }
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packuswb m0, m0 ; (byte) { V0, ... V3 }
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movh [dstUq+wq], m1
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movh [dstVq+wq], m0
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%endif ; mmsize == 8/16
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add wq, mmsize / 2
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jl .loop_%1
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REP_RET
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%endmacro
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; %1 = nr. of XMM registers
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; %2 = yuyv or uyvy
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; %3 = if specified, it means that unaligned and aligned code in loop
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; will be the same (i.e. UYVY+AVX), and thus we don't need to
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; split the loop in an aligned and unaligned case
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%macro YUYV_TO_UV_FN 2-3
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cglobal %2ToUV, 3, 4, %1, dstU, dstV, src, w
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%ifdef ARCH_X86_64
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movsxd wq, r4m
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%else ; x86-32
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mov wq, r4m
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%endif
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add dstUq, wq
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add dstVq, wq
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%if mmsize == 16 && %0 == 2
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test srcq, 15
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%endif
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lea srcq, [srcq+wq*4]
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pcmpeqb m2, m2 ; (byte) { 0xff } x 16
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psrlw m2, 8 ; (word) { 0x00ff } x 8
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; NOTE: if uyvy+avx, u/a are identical
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%if mmsize == 16 && %0 == 2
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jnz .loop_u_start
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neg wq
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LOOP_YUYV_TO_UV a, %2
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.loop_u_start:
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neg wq
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LOOP_YUYV_TO_UV u, %2
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%else ; mmsize == 8
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neg wq
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LOOP_YUYV_TO_UV a, %2
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%endif ; mmsize == 8/16
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%endmacro
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; %1 = a (aligned) or u (unaligned)
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; %2 = nv12 or nv21
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%macro LOOP_NVXX_TO_UV 2
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.loop_%1:
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mov%1 m0, [srcq+wq*2] ; (byte) { U0, V0, U1, V1, ... }
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mov%1 m1, [srcq+wq*2+mmsize] ; (byte) { U8, V8, U9, V9, ... }
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pand m2, m0, m4 ; (word) { U0, U1, ..., U7 }
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pand m3, m1, m4 ; (word) { U8, U9, ..., U15 }
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psrlw m0, 8 ; (word) { V0, V1, ..., V7 }
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psrlw m1, 8 ; (word) { V8, V9, ..., V15 }
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packuswb m2, m3 ; (byte) { U0, ..., U15 }
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packuswb m0, m1 ; (byte) { V0, ..., V15 }
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%ifidn %2, nv12
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mova [dstUq+wq], m2
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mova [dstVq+wq], m0
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%else ; nv21
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mova [dstVq+wq], m2
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mova [dstUq+wq], m0
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%endif ; nv12/21
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add wq, mmsize
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jl .loop_%1
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REP_RET
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%endmacro
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; %1 = nr. of XMM registers
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; %2 = nv12 or nv21
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%macro NVXX_TO_UV_FN 2
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cglobal %2ToUV, 3, 4, %1, dstU, dstV, src, w
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%ifdef ARCH_X86_64
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movsxd wq, r4m
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%else ; x86-32
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mov wq, r4m
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%endif
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add dstUq, wq
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add dstVq, wq
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%if mmsize == 16
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test srcq, 15
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%endif
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lea srcq, [srcq+wq*2]
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pcmpeqb m4, m4 ; (byte) { 0xff } x 16
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psrlw m4, 8 ; (word) { 0x00ff } x 8
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%if mmsize == 16
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jnz .loop_u_start
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neg wq
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LOOP_NVXX_TO_UV a, %2
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.loop_u_start:
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neg wq
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LOOP_NVXX_TO_UV u, %2
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%else ; mmsize == 8
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neg wq
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LOOP_NVXX_TO_UV a, %2
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%endif ; mmsize == 8/16
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%endmacro
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%ifdef ARCH_X86_32
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INIT_MMX mmx
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YUYV_TO_Y_FN 0, yuyv
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YUYV_TO_Y_FN 0, uyvy
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YUYV_TO_UV_FN 0, yuyv
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YUYV_TO_UV_FN 0, uyvy
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NVXX_TO_UV_FN 0, nv12
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NVXX_TO_UV_FN 0, nv21
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%endif
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INIT_XMM sse2
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YUYV_TO_Y_FN 3, yuyv
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YUYV_TO_Y_FN 2, uyvy
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YUYV_TO_UV_FN 3, yuyv
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YUYV_TO_UV_FN 3, uyvy
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NVXX_TO_UV_FN 5, nv12
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NVXX_TO_UV_FN 5, nv21
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INIT_XMM avx
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; in theory, we could write a yuy2-to-y using vpand (i.e. AVX), but
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; that's not faster in practice
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YUYV_TO_UV_FN 3, yuyv
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YUYV_TO_UV_FN 3, uyvy, 1
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NVXX_TO_UV_FN 5, nv12
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NVXX_TO_UV_FN 5, nv21
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