2019-06-03 22:10:59 +00:00
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/*
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* Copyright 2019 Google Inc.
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*
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* Use of this source code is governed by a BSD-style license that can be
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* found in the LICENSE file.
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*/
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#include "tools/SkVMBuilders.h"
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// Some parts of this builder code are written less fluently than possible,
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// to avoid any ambiguity of function argument evaluation order. This lets
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// our golden tests work portably. In general there's no reason to fear
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// nesting calls to Builder routines.
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SrcoverBuilder_F32::SrcoverBuilder_F32(Fmt srcFmt, Fmt dstFmt) {
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2019-07-15 15:04:08 +00:00
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auto load = [&](Fmt fmt, skvm::F32* r, skvm::F32* g, skvm::F32* b, skvm::F32* a) {
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skvm::Arg ptr;
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2019-06-03 22:10:59 +00:00
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switch (fmt) {
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case Fmt::A8: {
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2019-07-30 14:44:30 +00:00
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ptr = varying<uint8_t>();
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2019-06-03 22:10:59 +00:00
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*r = *g = *b = splat(0.0f);
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2020-03-04 20:59:09 +00:00
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*a = from_unorm(8, load8(ptr));
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2019-06-03 22:10:59 +00:00
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} break;
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case Fmt::G8: {
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2019-07-30 14:44:30 +00:00
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ptr = varying<uint8_t>();
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2020-03-04 20:59:09 +00:00
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*r = *g = *b = from_unorm(8, load8(ptr));
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2019-06-03 22:10:59 +00:00
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*a = splat(1.0f);
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} break;
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case Fmt::RGBA_8888: {
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2019-07-30 14:44:30 +00:00
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ptr = varying<int>();
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2019-06-04 16:33:25 +00:00
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skvm::I32 rgba = load32(ptr);
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2020-03-04 20:59:09 +00:00
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*r = from_unorm(8, extract(rgba, 0, splat(0xff)));
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*g = from_unorm(8, extract(rgba, 8, splat(0xff)));
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*b = from_unorm(8, extract(rgba, 16, splat(0xff)));
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*a = from_unorm(8, extract(rgba, 24, splat(0xff)));
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2019-06-03 22:10:59 +00:00
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} break;
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}
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2019-07-15 15:04:08 +00:00
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return ptr;
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2019-06-03 22:10:59 +00:00
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};
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skvm::F32 r,g,b,a;
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2019-07-15 15:04:08 +00:00
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(void)load(srcFmt, &r,&g,&b,&a);
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2019-06-03 22:10:59 +00:00
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skvm::F32 dr,dg,db,da;
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2019-07-15 15:04:08 +00:00
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skvm::Arg dst = load(dstFmt, &dr,&dg,&db,&da);
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2019-06-03 22:10:59 +00:00
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skvm::F32 invA = sub(splat(1.0f), a);
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r = mad(dr, invA, r);
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g = mad(dg, invA, g);
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b = mad(db, invA, b);
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a = mad(da, invA, a);
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switch (dstFmt) {
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case Fmt::A8: {
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2020-03-04 20:59:09 +00:00
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store8(dst, to_unorm(8, a));
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2019-06-03 22:10:59 +00:00
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} break;
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case Fmt::G8: {
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skvm::F32 _2126 = splat(0.2126f),
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_7152 = splat(0.7152f),
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_0722 = splat(0.0722f);
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2020-03-04 20:59:09 +00:00
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store8(dst, to_unorm(8, mad(r, _2126,
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2019-06-03 22:10:59 +00:00
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mad(g, _7152,
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mul(b, _0722)))));
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} break;
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case Fmt::RGBA_8888: {
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2020-03-04 20:59:09 +00:00
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skvm::I32 R = to_unorm(8, r),
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G = to_unorm(8, g),
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B = to_unorm(8, b),
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A = to_unorm(8, a);
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2019-06-03 22:10:59 +00:00
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2019-06-04 15:41:49 +00:00
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R = pack(R, G, 8);
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B = pack(B, A, 8);
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R = pack(R, B, 16);
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2019-06-03 22:10:59 +00:00
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store32(dst, R);
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} break;
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}
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}
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2019-06-20 16:37:10 +00:00
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SrcoverBuilder_I32_Naive::SrcoverBuilder_I32_Naive() {
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2019-07-30 14:44:30 +00:00
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skvm::Arg src = varying<int>(),
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dst = varying<int>();
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2019-06-20 16:37:10 +00:00
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auto load = [&](skvm::Arg ptr,
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skvm::I32* r, skvm::I32* g, skvm::I32* b, skvm::I32* a) {
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skvm::I32 rgba = load32(ptr);
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*r = extract(rgba, 0, splat(0xff));
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*g = extract(rgba, 8, splat(0xff));
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*b = extract(rgba, 16, splat(0xff));
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*a = extract(rgba, 24, splat(0xff));
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};
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skvm::I32 r,g,b,a;
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load(src, &r,&g,&b,&a);
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skvm::I32 dr,dg,db,da;
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load(dst, &dr,&dg,&db,&da);
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// (xy + x)/256 is a good approximation of (xy + 127)/255
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//
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// == (d*(255-a) + d)/256
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// == (d*(255-a+1) )/256
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// == (d*(256-a ) )/256
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skvm::I32 invA = sub(splat(256), a);
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r = add(r, shr(mul(dr, invA), 8));
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g = add(g, shr(mul(dg, invA), 8));
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b = add(b, shr(mul(db, invA), 8));
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a = add(a, shr(mul(da, invA), 8));
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r = pack(r, g, 8);
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b = pack(b, a, 8);
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r = pack(r, b, 16);
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store32(dst, r);
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}
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2019-06-03 22:10:59 +00:00
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SrcoverBuilder_I32::SrcoverBuilder_I32() {
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2019-07-30 14:44:30 +00:00
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skvm::Arg src = varying<int>(),
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dst = varying<int>();
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2019-06-03 22:10:59 +00:00
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auto load = [&](skvm::Arg ptr,
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skvm::I32* r, skvm::I32* g, skvm::I32* b, skvm::I32* a) {
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2019-06-04 16:33:25 +00:00
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skvm::I32 rgba = load32(ptr);
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2020-04-03 17:01:24 +00:00
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*r = extract(rgba, 0, splat(0xff));
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*g = extract(rgba, 8, splat(0xff));
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*b = extract(rgba, 16, splat(0xff));
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*a = extract(rgba, 24, splat(0xff));
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2019-06-03 22:10:59 +00:00
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};
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skvm::I32 r,g,b,a;
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load(src, &r,&g,&b,&a);
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skvm::I32 dr,dg,db,da;
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load(dst, &dr,&dg,&db,&da);
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2019-06-13 15:56:51 +00:00
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// (xy + x)/256 is a good approximation of (xy + 127)/255
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//
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// == (d*(255-a) + d)/256
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// == (d*(255-a+1) )/256
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// == (d*(256-a ) )/256
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2019-06-13 16:29:26 +00:00
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// We're doing 8x8 bit multiplies in 32-bit lanes.
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// Since the inputs and results both fit in 16 bits,
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// we can use mul_16x2, which tends to be faster than mul.
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//
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// (The top 2 zero bytes of the inputs will also multiply
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// with each other to produce zero... perfect.)
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2019-06-13 15:56:51 +00:00
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skvm::I32 invA = sub(splat(256), a);
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2019-06-13 16:29:26 +00:00
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r = add(r, shr(mul_16x2(dr, invA), 8));
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g = add(g, shr(mul_16x2(dg, invA), 8));
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b = add(b, shr(mul_16x2(db, invA), 8));
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a = add(a, shr(mul_16x2(da, invA), 8));
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2019-06-03 22:10:59 +00:00
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2019-06-04 15:41:49 +00:00
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r = pack(r, g, 8);
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b = pack(b, a, 8);
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r = pack(r, b, 16);
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2019-06-03 22:10:59 +00:00
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store32(dst, r);
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}
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SrcoverBuilder_I32_SWAR::SrcoverBuilder_I32_SWAR() {
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2019-07-30 14:44:30 +00:00
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skvm::Arg src = varying<int>(),
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dst = varying<int>();
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2019-06-03 22:10:59 +00:00
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2019-06-13 18:12:38 +00:00
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// The s += d*invA adds won't overflow,
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// so we don't have to unpack s beyond grabbing the alpha channel.
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skvm::I32 s = load32(src),
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2020-04-03 17:01:24 +00:00
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ax2 = extract(s, 24, splat(0x000000ff))
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| extract(s, 8, splat(0x00ff0000));
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2019-06-03 22:10:59 +00:00
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2019-06-13 18:12:38 +00:00
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// We'll use the same approximation math as above, this time making sure to
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// use both i16 multiplies to our benefit, one for r/g, the other for b/a.
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proposed: add bytes() op
I'm staring at this assembly,
vmovups (%rsi), %ymm3
vpsrld $24, %ymm3, %ymm4
vpslld $16, %ymm4, %ymm15
vorps %ymm4, %ymm15, %ymm4
vpsubw %ymm4, %ymm0, %ymm4
Just knowing that could be
vmovups (%rsi), %ymm3
vpshufb 0x??(%rip), %ymm3, %ymm4
vpsubw %ymm4, %ymm0, %ymm4
That is, instead of shifting, shifting, and bit-oring
to create the 0a0a scale factor from ymm3, we could just
byte shuffle directly using some pre-baked control pattern
(stored at the end of the program like other constants)
pshufb lets you arbitrarily remix bytes from its argument and
zero bytes, and NEON has a similar family of vtbl instructions,
even including that same feature of injecting zeroes.
I think I've got this working, and the speedup is great,
from 0.19 to 0.16 ns/px for I32_SWAR, and
from 0.43 to 0.38 ns/px for I32.
Change-Id: Iab850275e826b4187f0efc9495a4b9eab4402c38
Reviewed-on: https://skia-review.googlesource.com/c/skia/+/220871
Commit-Queue: Mike Klein <mtklein@google.com>
Reviewed-by: Herb Derby <herb@google.com>
2019-06-13 21:43:18 +00:00
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skvm::I32 invAx2 = sub_16x2(splat(0x01000100), ax2);
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2019-06-13 15:56:51 +00:00
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2019-06-13 20:51:39 +00:00
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skvm::I32 d = load32(dst),
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rb = bit_and (d, splat(0x00ff00ff)),
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ga = shr_16x2(d, 8);
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2019-06-13 15:56:51 +00:00
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2019-06-13 18:12:38 +00:00
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rb = shr_16x2(mul_16x2(rb, invAx2), 8); // Put the high 8 bits back in the low lane.
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ga = mul_16x2(ga, invAx2); // Keep the high 8 bits up high...
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2020-04-05 15:25:32 +00:00
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ga = bit_clear(ga, splat(0x00ff00ff)); // ...and mask off the low bits.
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2019-06-03 22:10:59 +00:00
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2019-06-13 18:12:38 +00:00
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store32(dst, add(s, bit_or(rb, ga)));
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2019-06-03 22:10:59 +00:00
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}
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