src/media/base/simd/convert_rgb_to_yuv_ssse3.inc - cobalt - Git at Google

 ; Copyright (c) 2011 The Chromium Authors. All rights reserved.
 ; Use of this source code is governed by a BSD-style license that can be
 ; found in the LICENSE file.

 ;
 ; void SYMBOL(const uint8* argb, uint8* y, uint8* u, uint8* v, int width);
 ;
 ; The main code that converts RGB pixels to YUV pixels. This function roughly
 ; consists of three parts: converting one ARGB pixel to YUV pixels, converting
 ; two ARGB pixels to YUV pixels, and converting four ARGB pixels to YUV pixels.
 ; To write the structure of this function in C, it becomes the snippet listed
 ; below.
 ;
 ;   if (width & 1) {
 ;     --width;
 ;     // Convert one ARGB pixel to one Y pixel, one U pixel, and one V pixel.
 ;   }
 ;
 ;   if (width & 2) {
 ;     width -= 2;
 ;     // Convert two ARGB pixels to two Y pixels, one U pixel, and one V pixel.
 ;   }
 ;
 ;   while (width) {
 ;     width -= 4;
 ;     // Convert four ARGB pixels to four Y pixels, two U pixels, and two V
 ;     // pixels.
 ;   }
 ;
   global    mangle(SYMBOL) PRIVATE
   align     function_align

 mangle(SYMBOL):
   %assign stack_offset 0
   PROLOGUE 5, 6, 8, ARGB, Y, U, V, WIDTH, TEMP

   ; Initialize constants used in this function. (We use immediates to avoid
   ; dependency onto GOT.)
   LOAD_XMM  XMM_CONST_Y0, 0x00420219
   LOAD_XMM  XMM_CONST_Y1, 0x00007F00
   LOAD_XMM  XMM_CONST_U, 0x00DAB670
   LOAD_XMM  XMM_CONST_V, 0x0070A2EE
   LOAD_XMM  XMM_CONST_128, 0x00800080

 .convert_one_pixel:
   ; Divide the input width by two so it represents the offsets for u[] and v[].
   ; When the width is odd, We read the rightmost ARGB pixel and convert its
   ; colorspace to YUV. This code stores one Y pixel, one U pixel, and one V
   ; pixel.
   sar       WIDTHq, 1
   jnc       .convert_two_pixels

   ; Read one ARGB (or RGB) pixel.
   READ_ARGB xmm0, 1

   ; Calculate y[0] from one RGB pixel read above.
   CALC_Y    xmm1, xmm0
   movd      TEMPd, xmm1
   mov       BYTE [Yq + WIDTHq * 2], TEMPb

   ; Calculate u[0] from one RGB pixel read above. If this is an odd line, the
   ; output pixel contains the U value calculated in the previous call. We also
   ; read this pixel and calculate their average.
   INIT_UV   TEMPd, Uq, 4
   CALC_UV   xmm1, xmm0, XMM_CONST_U, TEMPd
   movd      TEMPd, xmm1
   mov       BYTE [Uq + WIDTHq], TEMPb

   ; Calculate v[0] from one RGB pixel. Same as u[0], we read the result of the
   ; previous call and get their average.
   INIT_UV   TEMPd, Uq, 4
   CALC_UV   xmm1, xmm0, XMM_CONST_V, TEMPd
   movd      TEMPd, xmm1
   mov       BYTE [Vq + WIDTHq], TEMPb

 .convert_two_pixels:
   ; If the input width is not a multiple of four, read the rightmost two ARGB
   ; pixels and convert their colorspace to YUV. This code stores two Y pixels,
   ; one U pixel, and one V pixel.
   test      WIDTHb, 2 / 2
   jz        .convert_four_pixels
   sub       WIDTHb, 2 / 2

   ; Read two ARGB (or RGB) pixels.
   READ_ARGB xmm0, 2

   ; Calculate r[0] and r[1] from two RGB pixels read above.
   CALC_Y    xmm1, xmm0
   movd      TEMPd, xmm1
   mov       WORD [Yq + WIDTHq * 2], TEMPw

   ; Skip calculating u and v if the output buffer is NULL.
   test      Uq, Uq
   jz        .convert_four_pixels

   ; Calculate u[0] from two RGB pixels read above. (For details, read the above
   ; comment in .convert_one_pixel).
   INIT_UV   TEMPd, Uq, 2
   CALC_UV   xmm1, xmm0, XMM_CONST_U, TEMPd
   movd      TEMPd, xmm1
   mov       BYTE [Uq + WIDTHq], TEMPb

   ; Calculate v[0] from two RGB pixels read above.
   INIT_UV   TEMPd, Vq, 2
   CALC_UV   xmm1, xmm0, XMM_CONST_V, TEMPd
   movd      TEMPd, xmm1
   mov       BYTE [Vq + WIDTHq], TEMPb

 .convert_four_pixels:
   ; Read four ARGB pixels and convert their colorspace to YUV. This code stores
   ; four Y pixels, two U pixels, and two V pixels.
   test      WIDTHq, WIDTHq
   jz        .convert_finish

 %if PIXELSIZE == 4
   ; Check if the input buffer is aligned to a 16-byte boundary and use movdqa
   ; for reading the ARGB pixels.
   test      ARGBw, 15
   jnz       .convert_four_pixels_unaligned

 .convert_four_pixels_aligned:
   sub       WIDTHq, 4 / 2

   ; Read four ARGB pixels. (We can use movdqa here since we have checked if the
   ; source address is aligned.)
   movdqa    xmm0, DQWORD [ARGBq + WIDTHq * 4 * 2]

   ; Calculate y[0], y[1], y[2],and, y[3] from the input ARGB pixels.
   CALC_Y    xmm1, xmm0
   movd      DWORD [Yq + WIDTHq * 2], xmm1

 %if SUBSAMPLING == 0
   ; Skip calculating u and v if the output buffer is NULL, which means we are
   ; converting an odd line. (When we enable subsampling, these buffers must
   ; contain the u and v values for the previous call, i.e. these variables must
   ; not be NULL.)
   test      Uq, Uq
   jz        .convert_four_pixels_aligned_next
 %endif

   ; Calculate u[0] and u[1] from four ARGB pixels read above.
   INIT_UV   TEMPd, Uq, 4
   CALC_UV   xmm1, xmm0, XMM_CONST_U, TEMPd
   movd      TEMPd, xmm1
   mov       WORD [Uq + WIDTHq], TEMPw

   ; Calculate v[0] and v[1] from four ARGB pixels read above.
   INIT_UV   TEMPd, Vq, 4
   CALC_UV   xmm1, xmm0, XMM_CONST_V, TEMPd
   movd      TEMPd, xmm1
   mov       WORD [Vq + WIDTHq], TEMPw

 %if SUBSAMPLING == 0
 .convert_four_pixels_aligned_next:
 %endif

   test      WIDTHq, WIDTHq
   jnz       .convert_four_pixels_aligned

   jmp       .convert_finish
 %endif

 .convert_four_pixels_unaligned:
   sub       WIDTHq, 4 / 2

   ; Read four ARGB (or RGB) pixels.
   READ_ARGB xmm0, 4

   ; Calculate y[0], y[1], y[2],and, y[3] from the input ARGB pixels.
   CALC_Y    xmm1, xmm0
   movd      DWORD [Yq + WIDTHq * 2], xmm1

 %if SUBSAMPLING == 0
   ; Skip calculating u and v if the output buffer is NULL.
   test      Uq, Uq
   jz        .convert_four_pixels_unaligned_next
 %endif

   ; Calculate u[0] and u[1] from the input ARGB pixels.
   INIT_UV   TEMPd, Uq, 4
   CALC_UV   xmm1, xmm0, XMM_CONST_U, TEMPd
   movd      TEMPd, xmm1
   mov       WORD [Uq + WIDTHq], TEMPw

   ; Calculate v[0] and v[1] from the input ARGB pixels.
   INIT_UV   TEMPd, Vq, 4
   CALC_UV   xmm1, xmm0, XMM_CONST_V, TEMPd
   movd      TEMPd, xmm1
   mov       WORD [Vq + WIDTHq], TEMPw

 %if SUBSAMPLING == 0
 .convert_four_pixels_unaligned_next:
 %endif

   test      WIDTHq, WIDTHq
   jnz       .convert_four_pixels_unaligned

 .convert_finish:
   ; Just exit this function since this is a void function.
   RET
	; Copyright (c) 2011 The Chromium Authors. All rights reserved.
	; Use of this source code is governed by a BSD-style license that can be
	; found in the LICENSE file.

	;
	; void SYMBOL(const uint8* argb, uint8* y, uint8* u, uint8* v, int width);
	;
	; The main code that converts RGB pixels to YUV pixels. This function roughly
	; consists of three parts: converting one ARGB pixel to YUV pixels, converting
	; two ARGB pixels to YUV pixels, and converting four ARGB pixels to YUV pixels.
	; To write the structure of this function in C, it becomes the snippet listed
	; below.
	;
	; if (width & 1) {
	; --width;
	; // Convert one ARGB pixel to one Y pixel, one U pixel, and one V pixel.
	; }
	;
	; if (width & 2) {
	; width -= 2;
	; // Convert two ARGB pixels to two Y pixels, one U pixel, and one V pixel.
	; }
	;
	; while (width) {
	; width -= 4;
	; // Convert four ARGB pixels to four Y pixels, two U pixels, and two V
	; // pixels.
	; }
	;
	global mangle(SYMBOL) PRIVATE
	align function_align

	mangle(SYMBOL):
	%assign stack_offset 0
	PROLOGUE 5, 6, 8, ARGB, Y, U, V, WIDTH, TEMP

	; Initialize constants used in this function. (We use immediates to avoid
	; dependency onto GOT.)
	LOAD_XMM XMM_CONST_Y0, 0x00420219
	LOAD_XMM XMM_CONST_Y1, 0x00007F00
	LOAD_XMM XMM_CONST_U, 0x00DAB670
	LOAD_XMM XMM_CONST_V, 0x0070A2EE
	LOAD_XMM XMM_CONST_128, 0x00800080

	.convert_one_pixel:
	; Divide the input width by two so it represents the offsets for u[] and v[].
	; When the width is odd, We read the rightmost ARGB pixel and convert its
	; colorspace to YUV. This code stores one Y pixel, one U pixel, and one V
	; pixel.
	sar WIDTHq, 1
	jnc .convert_two_pixels

	; Read one ARGB (or RGB) pixel.
	READ_ARGB xmm0, 1

	; Calculate y[0] from one RGB pixel read above.
	CALC_Y xmm1, xmm0
	movd TEMPd, xmm1
	mov BYTE [Yq + WIDTHq * 2], TEMPb

	; Calculate u[0] from one RGB pixel read above. If this is an odd line, the
	; output pixel contains the U value calculated in the previous call. We also
	; read this pixel and calculate their average.
	INIT_UV TEMPd, Uq, 4
	CALC_UV xmm1, xmm0, XMM_CONST_U, TEMPd
	movd TEMPd, xmm1
	mov BYTE [Uq + WIDTHq], TEMPb

	; Calculate v[0] from one RGB pixel. Same as u[0], we read the result of the
	; previous call and get their average.
	INIT_UV TEMPd, Uq, 4
	CALC_UV xmm1, xmm0, XMM_CONST_V, TEMPd
	movd TEMPd, xmm1
	mov BYTE [Vq + WIDTHq], TEMPb

	.convert_two_pixels:
	; If the input width is not a multiple of four, read the rightmost two ARGB
	; pixels and convert their colorspace to YUV. This code stores two Y pixels,
	; one U pixel, and one V pixel.
	test WIDTHb, 2 / 2
	jz .convert_four_pixels
	sub WIDTHb, 2 / 2

	; Read two ARGB (or RGB) pixels.
	READ_ARGB xmm0, 2

	; Calculate r[0] and r[1] from two RGB pixels read above.
	CALC_Y xmm1, xmm0
	movd TEMPd, xmm1
	mov WORD [Yq + WIDTHq * 2], TEMPw

	; Skip calculating u and v if the output buffer is NULL.
	test Uq, Uq
	jz .convert_four_pixels

	; Calculate u[0] from two RGB pixels read above. (For details, read the above
	; comment in .convert_one_pixel).
	INIT_UV TEMPd, Uq, 2
	CALC_UV xmm1, xmm0, XMM_CONST_U, TEMPd
	movd TEMPd, xmm1
	mov BYTE [Uq + WIDTHq], TEMPb

	; Calculate v[0] from two RGB pixels read above.
	INIT_UV TEMPd, Vq, 2
	CALC_UV xmm1, xmm0, XMM_CONST_V, TEMPd
	movd TEMPd, xmm1
	mov BYTE [Vq + WIDTHq], TEMPb

	.convert_four_pixels:
	; Read four ARGB pixels and convert their colorspace to YUV. This code stores
	; four Y pixels, two U pixels, and two V pixels.
	test WIDTHq, WIDTHq
	jz .convert_finish

	%if PIXELSIZE == 4
	; Check if the input buffer is aligned to a 16-byte boundary and use movdqa
	; for reading the ARGB pixels.
	test ARGBw, 15
	jnz .convert_four_pixels_unaligned

	.convert_four_pixels_aligned:
	sub WIDTHq, 4 / 2

	; Read four ARGB pixels. (We can use movdqa here since we have checked if the
	; source address is aligned.)
	movdqa xmm0, DQWORD [ARGBq + WIDTHq * 4 * 2]

	; Calculate y[0], y[1], y[2],and, y[3] from the input ARGB pixels.
	CALC_Y xmm1, xmm0
	movd DWORD [Yq + WIDTHq * 2], xmm1

	%if SUBSAMPLING == 0
	; Skip calculating u and v if the output buffer is NULL, which means we are
	; converting an odd line. (When we enable subsampling, these buffers must
	; contain the u and v values for the previous call, i.e. these variables must
	; not be NULL.)
	test Uq, Uq
	jz .convert_four_pixels_aligned_next
	%endif

	; Calculate u[0] and u[1] from four ARGB pixels read above.
	INIT_UV TEMPd, Uq, 4
	CALC_UV xmm1, xmm0, XMM_CONST_U, TEMPd
	movd TEMPd, xmm1
	mov WORD [Uq + WIDTHq], TEMPw

	; Calculate v[0] and v[1] from four ARGB pixels read above.
	INIT_UV TEMPd, Vq, 4
	CALC_UV xmm1, xmm0, XMM_CONST_V, TEMPd
	movd TEMPd, xmm1
	mov WORD [Vq + WIDTHq], TEMPw

	%if SUBSAMPLING == 0
	.convert_four_pixels_aligned_next:
	%endif

	test WIDTHq, WIDTHq
	jnz .convert_four_pixels_aligned

	jmp .convert_finish
	%endif

	.convert_four_pixels_unaligned:
	sub WIDTHq, 4 / 2

	; Read four ARGB (or RGB) pixels.
	READ_ARGB xmm0, 4

	; Calculate y[0], y[1], y[2],and, y[3] from the input ARGB pixels.
	CALC_Y xmm1, xmm0
	movd DWORD [Yq + WIDTHq * 2], xmm1

	%if SUBSAMPLING == 0
	; Skip calculating u and v if the output buffer is NULL.
	test Uq, Uq
	jz .convert_four_pixels_unaligned_next
	%endif

	; Calculate u[0] and u[1] from the input ARGB pixels.
	INIT_UV TEMPd, Uq, 4
	CALC_UV xmm1, xmm0, XMM_CONST_U, TEMPd
	movd TEMPd, xmm1
	mov WORD [Uq + WIDTHq], TEMPw

	; Calculate v[0] and v[1] from the input ARGB pixels.
	INIT_UV TEMPd, Vq, 4
	CALC_UV xmm1, xmm0, XMM_CONST_V, TEMPd
	movd TEMPd, xmm1
	mov WORD [Vq + WIDTHq], TEMPw

	%if SUBSAMPLING == 0
	.convert_four_pixels_unaligned_next:
	%endif

	test WIDTHq, WIDTHq
	jnz .convert_four_pixels_unaligned

	.convert_finish:
	; Just exit this function since this is a void function.
	RET