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b4f3c3be46
NS_GFX last meant something prior to bug 648911, which removed support for non-libxul builds. Now that it's meaningless, let's get rid of it.
673 lines
23 KiB
C++
673 lines
23 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include <stdlib.h>
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#include <limits.h>
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#include "nsDebug.h"
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#include "ycbcr_to_rgb565.h"
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#include "nsAlgorithm.h"
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#ifdef HAVE_YCBCR_TO_RGB565
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namespace mozilla {
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namespace gfx {
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/*This contains all of the parameters that are needed to convert a row.
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Passing them in a struct instead of as individual parameters saves the need
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to continually push onto the stack the ones that are fixed for every row.*/
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struct yuv2rgb565_row_scale_bilinear_ctx{
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uint16_t *rgb_row;
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const uint8_t *y_row;
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const uint8_t *u_row;
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const uint8_t *v_row;
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int y_yweight;
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int y_pitch;
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int width;
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int source_x0_q16;
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int source_dx_q16;
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/*Not used for 4:4:4, except with chroma-nearest.*/
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int source_uv_xoffs_q16;
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/*Not used for 4:4:4 or chroma-nearest.*/
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int uv_pitch;
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/*Not used for 4:2:2, 4:4:4, or chroma-nearest.*/
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int uv_yweight;
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};
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/*This contains all of the parameters that are needed to convert a row.
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Passing them in a struct instead of as individual parameters saves the need
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to continually push onto the stack the ones that are fixed for every row.*/
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struct yuv2rgb565_row_scale_nearest_ctx{
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uint16_t *rgb_row;
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const uint8_t *y_row;
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const uint8_t *u_row;
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const uint8_t *v_row;
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int width;
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int source_x0_q16;
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int source_dx_q16;
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/*Not used for 4:4:4.*/
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int source_uv_xoffs_q16;
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};
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typedef void (*yuv2rgb565_row_scale_bilinear_func)(
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const yuv2rgb565_row_scale_bilinear_ctx *ctx, int dither);
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typedef void (*yuv2rgb565_row_scale_nearest_func)(
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const yuv2rgb565_row_scale_nearest_ctx *ctx, int dither);
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//TODO: fix NEON asm for iOS
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# if defined(MOZILLA_MAY_SUPPORT_NEON) && !defined(__APPLE__)
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extern "C" void ScaleYCbCr42xToRGB565_BilinearY_Row_NEON(
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const yuv2rgb565_row_scale_bilinear_ctx *ctx, int dither);
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void __attribute((noinline)) yuv42x_to_rgb565_row_neon(uint16 *dst,
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const uint8 *y,
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const uint8 *u,
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const uint8 *v,
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int n,
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int oddflag);
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#endif
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/*Bilinear interpolation of a single value.
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This uses the exact same formulas as the asm, even though it adds some extra
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shifts that do nothing but reduce accuracy.*/
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static int bislerp(const uint8_t *row,
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int pitch,
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int source_x,
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int xweight,
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int yweight) {
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int a;
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int b;
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int c;
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int d;
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a = row[source_x];
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b = row[source_x+1];
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c = row[source_x+pitch];
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d = row[source_x+pitch+1];
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a = ((a<<8)+(c-a)*yweight+128)>>8;
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b = ((b<<8)+(d-b)*yweight+128)>>8;
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return ((a<<8)+(b-a)*xweight+128)>>8;
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}
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/*Convert a single pixel from Y'CbCr to RGB565.
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This uses the exact same formulas as the asm, even though we could make the
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constants a lot more accurate with 32-bit wide registers.*/
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static uint16_t yu2rgb565(int y, int u, int v, int dither) {
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/*This combines the constant offset that needs to be added during the Y'CbCr
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conversion with a rounding offset that depends on the dither parameter.*/
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static const int DITHER_BIAS[4][3]={
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{-14240, 8704, -17696},
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{-14240+128,8704+64, -17696+128},
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{-14240+256,8704+128,-17696+256},
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{-14240+384,8704+192,-17696+384}
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};
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int r;
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int g;
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int b;
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r = clamped((74*y+102*v+DITHER_BIAS[dither][0])>>9, 0, 31);
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g = clamped((74*y-25*u-52*v+DITHER_BIAS[dither][1])>>8, 0, 63);
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b = clamped((74*y+129*u+DITHER_BIAS[dither][2])>>9, 0, 31);
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return (uint16_t)(r<<11 | g<<5 | b);
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}
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static void ScaleYCbCr420ToRGB565_Bilinear_Row_C(
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const yuv2rgb565_row_scale_bilinear_ctx *ctx, int dither){
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int x;
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int source_x_q16;
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source_x_q16 = ctx->source_x0_q16;
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for (x = 0; x < ctx->width; x++) {
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int source_x;
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int xweight;
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int y;
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int u;
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int v;
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xweight = ((source_x_q16&0xFFFF)+128)>>8;
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source_x = source_x_q16>>16;
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y = bislerp(ctx->y_row, ctx->y_pitch, source_x, xweight, ctx->y_yweight);
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xweight = (((source_x_q16+ctx->source_uv_xoffs_q16)&0x1FFFF)+256)>>9;
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source_x = (source_x_q16+ctx->source_uv_xoffs_q16)>>17;
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source_x_q16 += ctx->source_dx_q16;
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u = bislerp(ctx->u_row, ctx->uv_pitch, source_x, xweight, ctx->uv_yweight);
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v = bislerp(ctx->v_row, ctx->uv_pitch, source_x, xweight, ctx->uv_yweight);
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ctx->rgb_row[x] = yu2rgb565(y, u, v, dither);
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dither ^= 3;
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}
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}
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static void ScaleYCbCr422ToRGB565_Bilinear_Row_C(
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const yuv2rgb565_row_scale_bilinear_ctx *ctx, int dither){
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int x;
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int source_x_q16;
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source_x_q16 = ctx->source_x0_q16;
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for (x = 0; x < ctx->width; x++) {
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int source_x;
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int xweight;
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int y;
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int u;
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int v;
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xweight = ((source_x_q16&0xFFFF)+128)>>8;
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source_x = source_x_q16>>16;
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y = bislerp(ctx->y_row, ctx->y_pitch, source_x, xweight, ctx->y_yweight);
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xweight = (((source_x_q16+ctx->source_uv_xoffs_q16)&0x1FFFF)+256)>>9;
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source_x = (source_x_q16+ctx->source_uv_xoffs_q16)>>17;
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source_x_q16 += ctx->source_dx_q16;
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u = bislerp(ctx->u_row, ctx->uv_pitch, source_x, xweight, ctx->y_yweight);
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v = bislerp(ctx->v_row, ctx->uv_pitch, source_x, xweight, ctx->y_yweight);
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ctx->rgb_row[x] = yu2rgb565(y, u, v, dither);
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dither ^= 3;
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}
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}
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static void ScaleYCbCr444ToRGB565_Bilinear_Row_C(
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const yuv2rgb565_row_scale_bilinear_ctx *ctx, int dither){
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int x;
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int source_x_q16;
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source_x_q16 = ctx->source_x0_q16;
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for (x = 0; x < ctx->width; x++) {
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int source_x;
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int xweight;
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int y;
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int u;
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int v;
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xweight = ((source_x_q16&0xFFFF)+128)>>8;
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source_x = source_x_q16>>16;
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source_x_q16 += ctx->source_dx_q16;
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y = bislerp(ctx->y_row, ctx->y_pitch, source_x, xweight, ctx->y_yweight);
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u = bislerp(ctx->u_row, ctx->y_pitch, source_x, xweight, ctx->y_yweight);
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v = bislerp(ctx->v_row, ctx->y_pitch, source_x, xweight, ctx->y_yweight);
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ctx->rgb_row[x] = yu2rgb565(y, u, v, dither);
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dither ^= 3;
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}
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}
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static void ScaleYCbCr42xToRGB565_BilinearY_Row_C(
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const yuv2rgb565_row_scale_bilinear_ctx *ctx, int dither){
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int x;
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int source_x_q16;
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source_x_q16 = ctx->source_x0_q16;
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for (x = 0; x < ctx->width; x++) {
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int source_x;
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int xweight;
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int y;
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int u;
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int v;
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xweight = ((source_x_q16&0xFFFF)+128)>>8;
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source_x = source_x_q16>>16;
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y = bislerp(ctx->y_row, ctx->y_pitch, source_x, xweight, ctx->y_yweight);
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source_x = (source_x_q16+ctx->source_uv_xoffs_q16)>>17;
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source_x_q16 += ctx->source_dx_q16;
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u = ctx->u_row[source_x];
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v = ctx->v_row[source_x];
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ctx->rgb_row[x] = yu2rgb565(y, u, v, dither);
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dither ^= 3;
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}
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}
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static void ScaleYCbCr444ToRGB565_BilinearY_Row_C(
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const yuv2rgb565_row_scale_bilinear_ctx *ctx, int dither){
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int x;
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int source_x_q16;
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source_x_q16 = ctx->source_x0_q16;
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for (x = 0; x < ctx->width; x++) {
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int source_x;
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int xweight;
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int y;
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int u;
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int v;
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xweight = ((source_x_q16&0xFFFF)+128)>>8;
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source_x = source_x_q16>>16;
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y = bislerp(ctx->y_row, ctx->y_pitch, source_x, xweight, ctx->y_yweight);
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source_x = (source_x_q16+ctx->source_uv_xoffs_q16)>>16;
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source_x_q16 += ctx->source_dx_q16;
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u = ctx->u_row[source_x];
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v = ctx->v_row[source_x];
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ctx->rgb_row[x] = yu2rgb565(y, u, v, dither);
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dither ^= 3;
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}
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}
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static void ScaleYCbCr42xToRGB565_Nearest_Row_C(
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const yuv2rgb565_row_scale_nearest_ctx *ctx, int dither){
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int y;
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int u;
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int v;
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int x;
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int source_x_q16;
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int source_x;
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source_x_q16 = ctx->source_x0_q16;
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for (x = 0; x < ctx->width; x++) {
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source_x = source_x_q16>>16;
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y = ctx->y_row[source_x];
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source_x = (source_x_q16+ctx->source_uv_xoffs_q16)>>17;
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source_x_q16 += ctx->source_dx_q16;
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u = ctx->u_row[source_x];
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v = ctx->v_row[source_x];
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ctx->rgb_row[x] = yu2rgb565(y, u, v, dither);
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dither ^= 3;
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}
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}
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static void ScaleYCbCr444ToRGB565_Nearest_Row_C(
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const yuv2rgb565_row_scale_nearest_ctx *ctx, int dither){
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int y;
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int u;
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int v;
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int x;
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int source_x_q16;
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int source_x;
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source_x_q16 = ctx->source_x0_q16;
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for (x = 0; x < ctx->width; x++) {
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source_x = source_x_q16>>16;
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source_x_q16 += ctx->source_dx_q16;
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y = ctx->y_row[source_x];
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u = ctx->u_row[source_x];
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v = ctx->v_row[source_x];
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ctx->rgb_row[x] = yu2rgb565(y, u, v, dither);
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dither ^= 3;
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}
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}
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void ScaleYCbCrToRGB565(const uint8_t *y_buf,
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const uint8_t *u_buf,
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const uint8_t *v_buf,
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uint8_t *rgb_buf,
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int source_x0,
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int source_y0,
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int source_width,
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int source_height,
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int width,
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int height,
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int y_pitch,
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int uv_pitch,
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int rgb_pitch,
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YUVType yuv_type,
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ScaleFilter filter) {
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int source_x0_q16;
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int source_y0_q16;
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int source_dx_q16;
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int source_dy_q16;
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int source_uv_xoffs_q16;
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int source_uv_yoffs_q16;
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int x_shift;
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int y_shift;
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int ymin;
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int ymax;
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int uvmin;
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int uvmax;
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int dither;
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/*We don't support negative destination rectangles (just flip the source
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instead), and for empty ones there's nothing to do.*/
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if (width <= 0 || height <= 0)
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return;
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/*These bounds are required to avoid 16.16 fixed-point overflow.*/
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NS_ASSERTION(source_x0 > (INT_MIN>>16) && source_x0 < (INT_MAX>>16),
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"ScaleYCbCrToRGB565 source X offset out of bounds.");
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NS_ASSERTION(source_x0+source_width > (INT_MIN>>16)
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&& source_x0+source_width < (INT_MAX>>16),
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"ScaleYCbCrToRGB565 source width out of bounds.");
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NS_ASSERTION(source_y0 > (INT_MIN>>16) && source_y0 < (INT_MAX>>16),
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"ScaleYCbCrToRGB565 source Y offset out of bounds.");
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NS_ASSERTION(source_y0+source_height > (INT_MIN>>16)
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&& source_y0+source_height < (INT_MAX>>16),
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"ScaleYCbCrToRGB565 source height out of bounds.");
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/*We require the same stride for Y' and Cb and Cr for 4:4:4 content.*/
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NS_ASSERTION(yuv_type != YV24 || y_pitch == uv_pitch,
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"ScaleYCbCrToRGB565 luma stride differs from chroma for 4:4:4 content.");
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/*We assume we can read outside the bounds of the input, because it makes
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the code much simpler (and in practice is true: both Theora and VP8 return
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padded reference frames).
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In practice, we do not even _have_ the actual bounds of the source, as
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we are passed a crop rectangle from it, and not the dimensions of the full
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image.
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This assertion will not guarantee our out-of-bounds reads are safe, but it
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should at least catch the simple case of passing in an unpadded buffer.*/
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NS_ASSERTION(abs(y_pitch) >= abs(source_width)+16,
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"ScaleYCbCrToRGB565 source image unpadded?");
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/*The NEON code requires the pointers to be aligned to a 16-byte boundary at
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the start of each row.
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This should be true for all of our sources.
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We could try to fix this up if it's not true by adjusting source_x0, but
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that would require the mis-alignment to be the same for the U and V
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planes.*/
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NS_ASSERTION((y_pitch&15) == 0 && (uv_pitch&15) == 0 &&
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((y_buf-(uint8_t *)nullptr)&15) == 0 &&
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((u_buf-(uint8_t *)nullptr)&15) == 0 &&
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((v_buf-(uint8_t *)nullptr)&15) == 0,
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"ScaleYCbCrToRGB565 source image unaligned");
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/*We take an area-based approach to pixel coverage to avoid shifting by small
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amounts (or not so small, when up-scaling or down-scaling by a large
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factor).
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An illustrative example: scaling 4:2:0 up by 2, using JPEG chroma cositing^.
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+ = RGB destination locations
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* = Y' source locations
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- = Cb, Cr source locations
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+ + + + + + + +
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* * * *
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+ + + + + + + +
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- -
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+ + + + + + + +
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* * * *
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+ + + + + + + +
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+ + + + + + + +
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* * * *
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+ + + + + + + +
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- -
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+ + + + + + + +
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* * * *
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+ + + + + + + +
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So, the coordinates of the upper-left + (first destination site) should
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be (-0.25,-0.25) in the source Y' coordinate system.
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Similarly, the coordinates should be (-0.375,-0.375) in the source Cb, Cr
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coordinate system.
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Note that the origin and scale of these two coordinate systems is not the
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same!
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^JPEG cositing is required for Theora; VP8 doesn't specify cositing rules,
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but nearly all software converters in existence (at least those that are
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open source, and many that are not) use JPEG cositing instead of MPEG.*/
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source_dx_q16 = (source_width<<16) / width;
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source_x0_q16 = (source_x0<<16)+(source_dx_q16>>1)-0x8000;
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source_dy_q16 = (source_height<<16) / height;
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source_y0_q16 = (source_y0<<16)+(source_dy_q16>>1)-0x8000;
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x_shift = (yuv_type != YV24);
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y_shift = (yuv_type == YV12);
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/*These two variables hold the difference between the origins of the Y' and
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the Cb, Cr coordinate systems, using the scale of the Y' coordinate
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system.*/
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source_uv_xoffs_q16 = -(x_shift<<15);
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source_uv_yoffs_q16 = -(y_shift<<15);
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/*Compute the range of source rows we'll actually use.
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This doesn't guarantee we won't read outside this range.*/
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ymin = source_height >= 0 ? source_y0 : source_y0+source_height-1;
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ymax = source_height >= 0 ? source_y0+source_height-1 : source_y0;
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uvmin = ymin>>y_shift;
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uvmax = ((ymax+1+y_shift)>>y_shift)-1;
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/*Pick a dithering pattern.
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The "&3" at the end is just in case RAND_MAX is lying.*/
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dither = (rand()/(RAND_MAX>>2))&3;
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/*Nearest-neighbor scaling.*/
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if (filter == FILTER_NONE) {
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yuv2rgb565_row_scale_nearest_ctx ctx;
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yuv2rgb565_row_scale_nearest_func scale_row;
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int y;
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/*Add rounding offsets once, in advance.*/
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source_x0_q16 += 0x8000;
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source_y0_q16 += 0x8000;
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source_uv_xoffs_q16 += (x_shift<<15);
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source_uv_yoffs_q16 += (y_shift<<15);
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if (yuv_type == YV12)
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scale_row = ScaleYCbCr42xToRGB565_Nearest_Row_C;
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else
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scale_row = ScaleYCbCr444ToRGB565_Nearest_Row_C;
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ctx.width = width;
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ctx.source_x0_q16 = source_x0_q16;
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ctx.source_dx_q16 = source_dx_q16;
|
|
ctx.source_uv_xoffs_q16 = source_uv_xoffs_q16;
|
|
for (y=0; y<height; y++) {
|
|
int source_y;
|
|
ctx.rgb_row = (uint16_t *)(rgb_buf + y*rgb_pitch);
|
|
source_y = source_y0_q16>>16;
|
|
source_y = clamped(source_y, ymin, ymax);
|
|
ctx.y_row = y_buf + source_y*y_pitch;
|
|
source_y = (source_y0_q16+source_uv_yoffs_q16)>>(16+y_shift);
|
|
source_y = clamped(source_y, uvmin, uvmax);
|
|
source_y0_q16 += source_dy_q16;
|
|
ctx.u_row = u_buf + source_y*uv_pitch;
|
|
ctx.v_row = v_buf + source_y*uv_pitch;
|
|
(*scale_row)(&ctx, dither);
|
|
dither ^= 2;
|
|
}
|
|
}
|
|
/*Bilinear scaling.*/
|
|
else {
|
|
yuv2rgb565_row_scale_bilinear_ctx ctx;
|
|
yuv2rgb565_row_scale_bilinear_func scale_row;
|
|
int uvxscale_min;
|
|
int uvxscale_max;
|
|
int uvyscale_min;
|
|
int uvyscale_max;
|
|
int y;
|
|
/*Check how close the chroma scaling is to unity.
|
|
If it's close enough, we can get away with nearest-neighbor chroma
|
|
sub-sampling, and only doing bilinear on luma.
|
|
If a given axis is subsampled, we use bounds on the luma step of
|
|
[0.67...2], which is equivalent to scaling chroma by [1...3].
|
|
If it's not subsampled, we use bounds of [0.5...1.33], which is
|
|
equivalent to scaling chroma by [0.75...2].
|
|
The lower bound is chosen as a trade-off between speed and how terrible
|
|
nearest neighbor looks when upscaling.*/
|
|
# define CHROMA_NEAREST_SUBSAMP_STEP_MIN 0xAAAA
|
|
# define CHROMA_NEAREST_NORMAL_STEP_MIN 0x8000
|
|
# define CHROMA_NEAREST_SUBSAMP_STEP_MAX 0x20000
|
|
# define CHROMA_NEAREST_NORMAL_STEP_MAX 0x15555
|
|
uvxscale_min = yuv_type != YV24 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MIN : CHROMA_NEAREST_NORMAL_STEP_MIN;
|
|
uvxscale_max = yuv_type != YV24 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MAX : CHROMA_NEAREST_NORMAL_STEP_MAX;
|
|
uvyscale_min = yuv_type == YV12 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MIN : CHROMA_NEAREST_NORMAL_STEP_MIN;
|
|
uvyscale_max = yuv_type == YV12 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MAX : CHROMA_NEAREST_NORMAL_STEP_MAX;
|
|
if (uvxscale_min <= abs(source_dx_q16)
|
|
&& abs(source_dx_q16) <= uvxscale_max
|
|
&& uvyscale_min <= abs(source_dy_q16)
|
|
&& abs(source_dy_q16) <= uvyscale_max) {
|
|
/*Add the rounding offsets now.*/
|
|
source_uv_xoffs_q16 += 1<<(15+x_shift);
|
|
source_uv_yoffs_q16 += 1<<(15+y_shift);
|
|
if (yuv_type != YV24) {
|
|
scale_row =
|
|
//TODO: fix NEON asm for iOS
|
|
# if defined(MOZILLA_MAY_SUPPORT_NEON) && !defined(__APPLE__)
|
|
supports_neon() ? ScaleYCbCr42xToRGB565_BilinearY_Row_NEON :
|
|
# endif
|
|
ScaleYCbCr42xToRGB565_BilinearY_Row_C;
|
|
}
|
|
else
|
|
scale_row = ScaleYCbCr444ToRGB565_BilinearY_Row_C;
|
|
}
|
|
else {
|
|
if (yuv_type == YV12)
|
|
scale_row = ScaleYCbCr420ToRGB565_Bilinear_Row_C;
|
|
else if (yuv_type == YV16)
|
|
scale_row = ScaleYCbCr422ToRGB565_Bilinear_Row_C;
|
|
else
|
|
scale_row = ScaleYCbCr444ToRGB565_Bilinear_Row_C;
|
|
}
|
|
ctx.width = width;
|
|
ctx.y_pitch = y_pitch;
|
|
ctx.source_x0_q16 = source_x0_q16;
|
|
ctx.source_dx_q16 = source_dx_q16;
|
|
ctx.source_uv_xoffs_q16 = source_uv_xoffs_q16;
|
|
ctx.uv_pitch = uv_pitch;
|
|
for (y=0; y<height; y++) {
|
|
int source_y;
|
|
int yweight;
|
|
int uvweight;
|
|
ctx.rgb_row = (uint16_t *)(rgb_buf + y*rgb_pitch);
|
|
source_y = (source_y0_q16+128)>>16;
|
|
yweight = ((source_y0_q16+128)>>8)&0xFF;
|
|
if (source_y < ymin) {
|
|
source_y = ymin;
|
|
yweight = 0;
|
|
}
|
|
if (source_y > ymax) {
|
|
source_y = ymax;
|
|
yweight = 0;
|
|
}
|
|
ctx.y_row = y_buf + source_y*y_pitch;
|
|
source_y = source_y0_q16+source_uv_yoffs_q16+(128<<y_shift);
|
|
source_y0_q16 += source_dy_q16;
|
|
uvweight = source_y>>(8+y_shift)&0xFF;
|
|
source_y >>= 16+y_shift;
|
|
if (source_y < uvmin) {
|
|
source_y = uvmin;
|
|
uvweight = 0;
|
|
}
|
|
if (source_y > uvmax) {
|
|
source_y = uvmax;
|
|
uvweight = 0;
|
|
}
|
|
ctx.u_row = u_buf + source_y*uv_pitch;
|
|
ctx.v_row = v_buf + source_y*uv_pitch;
|
|
ctx.y_yweight = yweight;
|
|
ctx.uv_yweight = uvweight;
|
|
(*scale_row)(&ctx, dither);
|
|
dither ^= 2;
|
|
}
|
|
}
|
|
}
|
|
|
|
bool IsScaleYCbCrToRGB565Fast(int source_x0,
|
|
int source_y0,
|
|
int source_width,
|
|
int source_height,
|
|
int width,
|
|
int height,
|
|
YUVType yuv_type,
|
|
ScaleFilter filter)
|
|
{
|
|
// Very fast.
|
|
if (width <= 0 || height <= 0)
|
|
return true;
|
|
# if defined(MOZILLA_MAY_SUPPORT_NEON)
|
|
if (filter != FILTER_NONE) {
|
|
int source_dx_q16;
|
|
int source_dy_q16;
|
|
int uvxscale_min;
|
|
int uvxscale_max;
|
|
int uvyscale_min;
|
|
int uvyscale_max;
|
|
source_dx_q16 = (source_width<<16) / width;
|
|
source_dy_q16 = (source_height<<16) / height;
|
|
uvxscale_min = yuv_type != YV24 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MIN : CHROMA_NEAREST_NORMAL_STEP_MIN;
|
|
uvxscale_max = yuv_type != YV24 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MAX : CHROMA_NEAREST_NORMAL_STEP_MAX;
|
|
uvyscale_min = yuv_type == YV12 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MIN : CHROMA_NEAREST_NORMAL_STEP_MIN;
|
|
uvyscale_max = yuv_type == YV12 ?
|
|
CHROMA_NEAREST_SUBSAMP_STEP_MAX : CHROMA_NEAREST_NORMAL_STEP_MAX;
|
|
if (uvxscale_min <= abs(source_dx_q16)
|
|
&& abs(source_dx_q16) <= uvxscale_max
|
|
&& uvyscale_min <= abs(source_dy_q16)
|
|
&& abs(source_dy_q16) <= uvyscale_max) {
|
|
if (yuv_type != YV24)
|
|
return supports_neon();
|
|
}
|
|
}
|
|
# endif
|
|
return false;
|
|
}
|
|
|
|
|
|
|
|
void yuv_to_rgb565_row_c(uint16 *dst,
|
|
const uint8 *y,
|
|
const uint8 *u,
|
|
const uint8 *v,
|
|
int x_shift,
|
|
int pic_x,
|
|
int pic_width)
|
|
{
|
|
int x;
|
|
for (x = 0; x < pic_width; x++)
|
|
{
|
|
dst[x] = yu2rgb565(y[pic_x+x],
|
|
u[(pic_x+x)>>x_shift],
|
|
v[(pic_x+x)>>x_shift],
|
|
2); // Disable dithering for now.
|
|
}
|
|
}
|
|
|
|
void ConvertYCbCrToRGB565(const uint8* y_buf,
|
|
const uint8* u_buf,
|
|
const uint8* v_buf,
|
|
uint8* rgb_buf,
|
|
int pic_x,
|
|
int pic_y,
|
|
int pic_width,
|
|
int pic_height,
|
|
int y_pitch,
|
|
int uv_pitch,
|
|
int rgb_pitch,
|
|
YUVType yuv_type)
|
|
{
|
|
int x_shift;
|
|
int y_shift;
|
|
x_shift = yuv_type != YV24;
|
|
y_shift = yuv_type == YV12;
|
|
//TODO: fix NEON asm for iOS
|
|
# if defined(MOZILLA_MAY_SUPPORT_NEON) && !defined(__APPLE__)
|
|
if (yuv_type != YV24 && supports_neon())
|
|
{
|
|
for (int i = 0; i < pic_height; i++) {
|
|
int yoffs;
|
|
int uvoffs;
|
|
yoffs = y_pitch * (pic_y+i) + pic_x;
|
|
uvoffs = uv_pitch * ((pic_y+i)>>y_shift) + (pic_x>>x_shift);
|
|
yuv42x_to_rgb565_row_neon((uint16*)(rgb_buf + rgb_pitch * i),
|
|
y_buf + yoffs,
|
|
u_buf + uvoffs,
|
|
v_buf + uvoffs,
|
|
pic_width,
|
|
pic_x&x_shift);
|
|
}
|
|
}
|
|
else
|
|
# endif
|
|
{
|
|
for (int i = 0; i < pic_height; i++) {
|
|
int yoffs;
|
|
int uvoffs;
|
|
yoffs = y_pitch * (pic_y+i);
|
|
uvoffs = uv_pitch * ((pic_y+i)>>y_shift);
|
|
yuv_to_rgb565_row_c((uint16*)(rgb_buf + rgb_pitch * i),
|
|
y_buf + yoffs,
|
|
u_buf + uvoffs,
|
|
v_buf + uvoffs,
|
|
x_shift,
|
|
pic_x,
|
|
pic_width);
|
|
}
|
|
}
|
|
}
|
|
|
|
bool IsConvertYCbCrToRGB565Fast(int pic_x,
|
|
int pic_y,
|
|
int pic_width,
|
|
int pic_height,
|
|
YUVType yuv_type)
|
|
{
|
|
# if defined(MOZILLA_MAY_SUPPORT_NEON)
|
|
return (yuv_type != YV24 && supports_neon());
|
|
# else
|
|
return false;
|
|
# endif
|
|
}
|
|
|
|
} // namespace gfx
|
|
|
|
} // namespace mozilla
|
|
|
|
#endif // HAVE_YCBCR_TO_RGB565
|