bench/SkVMBench.cpp - platform/external/skia - Gitiles

 /*
  * Copyright 2019 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "bench/Benchmark.h"
 #include "src/core/SkOpts.h"
 #include "src/core/SkVM.h"

 namespace {

     enum Mode {Opts, RP, F32, I32, I32_SWAR};
     static const char* kMode_name[] = { "Opts", "RP","F32", "I32", "I32_SWAR" };

     struct SrcoverBuilder_F32 : public skvm::Builder {
         SrcoverBuilder_F32() {

             skvm::Arg src = arg(0),
                       dst = arg(1);

             auto byte_to_f32 = [&](skvm::I32 byte) {
                 return mul(splat(1/255.0f), to_f32(byte));
             };
             auto f32_to_byte = [&](skvm::F32 f32) {
                 return to_i32(mad(f32, splat(255.0f), splat(0.5f)));
             };

             auto load = [&](skvm::Arg ptr,
                             skvm::F32* r, skvm::F32* g, skvm::F32* b, skvm::F32* a) {
                 skvm::I32 rgba = load32(ptr);
                 *r = byte_to_f32(bit_and(    rgba     , splat(0xff)));
                 *g = byte_to_f32(bit_and(shr(rgba,  8), splat(0xff)));
                 *b = byte_to_f32(bit_and(shr(rgba, 16), splat(0xff)));
                 *a = byte_to_f32(        shr(rgba, 24)              );
             };

             skvm::F32 r,g,b,a;
             load(src, &r,&g,&b,&a);

             skvm::F32 dr,dg,db,da;
             load(dst, &dr,&dg,&db,&da);

             skvm::F32 invA = sub(splat(1.0f), a);
             r = mad(dr, invA, r);
             g = mad(dg, invA, g);
             b = mad(db, invA, b);
             a = mad(da, invA, a);

             store32(dst, bit_or(    f32_to_byte(r)     ,
                          bit_or(shl(f32_to_byte(g),  8),
                          bit_or(shl(f32_to_byte(b), 16),
                                 shl(f32_to_byte(a), 24)))));
         }
     };

     struct SrcoverBuilder_I32 : public skvm::Builder {
         SrcoverBuilder_I32() {
             skvm::Arg src = arg(0),
                       dst = arg(1);

             auto load = [&](skvm::Arg ptr,
                             skvm::I32* r, skvm::I32* g, skvm::I32* b, skvm::I32* a) {
                 skvm::I32 rgba = load32(ptr);
                 *r = bit_and(    rgba     , splat(0xff));
                 *g = bit_and(shr(rgba,  8), splat(0xff));
                 *b = bit_and(shr(rgba, 16), splat(0xff));
                 *a =         shr(rgba, 24)              ;
             };

             auto mul_unorm8 = [&](skvm::I32 x, skvm::I32 y) {
                 // (x*y + 127)/255 ~= (x*y+255)/256
                 return shr(add(mul(x, y), splat(0xff)), 8);
             };

             skvm::I32 r,g,b,a;
             load(src, &r,&g,&b,&a);

             skvm::I32 dr,dg,db,da;
             load(dst, &dr,&dg,&db,&da);

             skvm::I32 invA = sub(splat(0xff), a);
             r = add(r, mul_unorm8(dr, invA));
             g = add(g, mul_unorm8(dg, invA));
             b = add(b, mul_unorm8(db, invA));
             a = add(a, mul_unorm8(da, invA));

             store32(dst, bit_or(    r     ,
                          bit_or(shl(g,  8),
                          bit_or(shl(b, 16),
                                 shl(a, 24)))));
         }
     };

     struct SrcoverBuilder_I32_SWAR : public skvm::Builder {
         SrcoverBuilder_I32_SWAR() {
             skvm::Arg src = arg(0),
                       dst = arg(1);

             auto load = [&](skvm::Arg ptr,
                             skvm::I32* rb, skvm::I32* ga) {
                 skvm::I32 rgba = load32(ptr);
                 *rb = bit_and(    rgba,     splat(0x00ff00ff));
                 *ga = bit_and(shr(rgba, 8), splat(0x00ff00ff));
             };

             auto mul_unorm8 = [&](skvm::I32 x, skvm::I32 y) {
                 // As above, assuming x is two SWAR bytes in lanes 0 and 2, and y is a byte.
                 return bit_and(shr(add(mul(x, y),
                                        splat(0x00ff00ff)),
                                    8),
                                splat(0x00ff00ff));
             };

             skvm::I32 rb, ga;
             load(src, &rb, &ga);

             skvm::I32 drb, dga;
             load(dst, &drb, &dga);

             skvm::I32 invA = sub(splat(0xff), shr(ga, 16));
             rb = add(rb, mul_unorm8(drb, invA));
             ga = add(ga, mul_unorm8(dga, invA));

             store32(dst, bit_or(rb, shl(ga, 8)));
         }
     };
 }

 class SkVMBench : public Benchmark {
 public:
     SkVMBench(int pixels, Mode mode)
         : fPixels(pixels)
         , fMode(mode)
         , fName(SkStringPrintf("SkVM_%d_%s", pixels, kMode_name[mode]))
     {}

 private:
     const char* onGetName() override { return fName.c_str(); }
     bool isSuitableFor(Backend backend) override { return backend == kNonRendering_Backend; }

     void onDelayedSetup() override {
         this->setUnits(fPixels);
         fSrc.resize(fPixels, 0x7f123456);  // Arbitrary non-opaque non-transparent value.
         fDst.resize(fPixels, 0xff987654);  // Arbitrary value.

         if (fMode == F32     ) { fProgram = SrcoverBuilder_F32     {}.done(); }
         if (fMode == I32     ) { fProgram = SrcoverBuilder_I32     {}.done(); }
         if (fMode == I32_SWAR) { fProgram = SrcoverBuilder_I32_SWAR{}.done(); }

         if (fMode == RP) {
             fSrcCtx = { fSrc.data(), 0 };
             fDstCtx = { fDst.data(), 0 };
             fPipeline.append(SkRasterPipeline::load_8888    , &fSrcCtx);
             fPipeline.append(SkRasterPipeline::load_8888_dst, &fDstCtx);
             fPipeline.append(SkRasterPipeline::srcover);
             fPipeline.append(SkRasterPipeline::store_8888, &fDstCtx);
         }

         // Trigger one run now so we can do a quick correctness check.
         this->draw(1,nullptr);
         for (int i = 0; i < fPixels; i++) {
             SkASSERT(fDst[i] == 0xff5e6f80);
         }
     }

     void onDraw(int loops, SkCanvas*) override {
         while (loops --> 0) {
             if (fMode == Opts) {
                 SkOpts::blit_row_s32a_opaque(fDst.data(), fSrc.data(), fPixels, 0xff);
             } else if (fMode == RP) {
                 fPipeline.run(0,0,fPixels,1);
             } else {
                 fProgram.eval(fPixels, fSrc.data(), fDst.data());
             }
         }
     }

     int                   fPixels;
     Mode                  fMode;
     SkString              fName;
     std::vector<uint32_t> fSrc,
                           fDst;
     skvm::Program         fProgram;

     SkRasterPipeline_MemoryCtx fSrcCtx,
                                fDstCtx;
     SkRasterPipeline_<256>     fPipeline;
 };

 DEF_BENCH(return (new SkVMBench{   1, Opts});)
 DEF_BENCH(return (new SkVMBench{   4, Opts});)
 DEF_BENCH(return (new SkVMBench{  16, Opts});)
 DEF_BENCH(return (new SkVMBench{  64, Opts});)
 DEF_BENCH(return (new SkVMBench{ 256, Opts});)
 DEF_BENCH(return (new SkVMBench{1024, Opts});)
 DEF_BENCH(return (new SkVMBench{4096, Opts});)

 DEF_BENCH(return (new SkVMBench{   1, RP});)
 DEF_BENCH(return (new SkVMBench{   4, RP});)
 DEF_BENCH(return (new SkVMBench{  16, RP});)
 DEF_BENCH(return (new SkVMBench{  64, RP});)
 DEF_BENCH(return (new SkVMBench{ 256, RP});)
 DEF_BENCH(return (new SkVMBench{1024, RP});)
 DEF_BENCH(return (new SkVMBench{4096, RP});)

 DEF_BENCH(return (new SkVMBench{   1, F32});)
 DEF_BENCH(return (new SkVMBench{   4, F32});)
 DEF_BENCH(return (new SkVMBench{  16, F32});)
 DEF_BENCH(return (new SkVMBench{  64, F32});)
 DEF_BENCH(return (new SkVMBench{ 256, F32});)
 DEF_BENCH(return (new SkVMBench{1024, F32});)
 DEF_BENCH(return (new SkVMBench{4096, F32});)

 DEF_BENCH(return (new SkVMBench{   1, I32});)
 DEF_BENCH(return (new SkVMBench{   4, I32});)
 DEF_BENCH(return (new SkVMBench{  16, I32});)
 DEF_BENCH(return (new SkVMBench{  64, I32});)
 DEF_BENCH(return (new SkVMBench{ 256, I32});)
 DEF_BENCH(return (new SkVMBench{1024, I32});)
 DEF_BENCH(return (new SkVMBench{4096, I32});)

 DEF_BENCH(return (new SkVMBench{   1, I32_SWAR});)
 DEF_BENCH(return (new SkVMBench{   4, I32_SWAR});)
 DEF_BENCH(return (new SkVMBench{  16, I32_SWAR});)
 DEF_BENCH(return (new SkVMBench{  64, I32_SWAR});)
 DEF_BENCH(return (new SkVMBench{ 256, I32_SWAR});)
 DEF_BENCH(return (new SkVMBench{1024, I32_SWAR});)
 DEF_BENCH(return (new SkVMBench{4096, I32_SWAR});)
	/*
	* Copyright 2019 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "bench/Benchmark.h"
	#include "src/core/SkOpts.h"
	#include "src/core/SkVM.h"

	namespace {

	enum Mode {Opts, RP, F32, I32, I32_SWAR};
	static const char* kMode_name[] = { "Opts", "RP","F32", "I32", "I32_SWAR" };

	struct SrcoverBuilder_F32 : public skvm::Builder {
	SrcoverBuilder_F32() {

	skvm::Arg src = arg(0),
	dst = arg(1);

	auto byte_to_f32 = [&](skvm::I32 byte) {
	return mul(splat(1/255.0f), to_f32(byte));
	};
	auto f32_to_byte = [&](skvm::F32 f32) {
	return to_i32(mad(f32, splat(255.0f), splat(0.5f)));
	};

	auto load = [&](skvm::Arg ptr,
	skvm::F32* r, skvm::F32* g, skvm::F32* b, skvm::F32* a) {
	skvm::I32 rgba = load32(ptr);
	*r = byte_to_f32(bit_and( rgba , splat(0xff)));
	*g = byte_to_f32(bit_and(shr(rgba, 8), splat(0xff)));
	*b = byte_to_f32(bit_and(shr(rgba, 16), splat(0xff)));
	*a = byte_to_f32( shr(rgba, 24) );
	};

	skvm::F32 r,g,b,a;
	load(src, &r,&g,&b,&a);

	skvm::F32 dr,dg,db,da;
	load(dst, &dr,&dg,&db,&da);

	skvm::F32 invA = sub(splat(1.0f), a);
	r = mad(dr, invA, r);
	g = mad(dg, invA, g);
	b = mad(db, invA, b);
	a = mad(da, invA, a);

	store32(dst, bit_or( f32_to_byte(r) ,
	bit_or(shl(f32_to_byte(g), 8),
	bit_or(shl(f32_to_byte(b), 16),
	shl(f32_to_byte(a), 24)))));
	}
	};

	struct SrcoverBuilder_I32 : public skvm::Builder {
	SrcoverBuilder_I32() {
	skvm::Arg src = arg(0),
	dst = arg(1);

	auto load = [&](skvm::Arg ptr,
	skvm::I32* r, skvm::I32* g, skvm::I32* b, skvm::I32* a) {
	skvm::I32 rgba = load32(ptr);
	*r = bit_and( rgba , splat(0xff));
	*g = bit_and(shr(rgba, 8), splat(0xff));
	*b = bit_and(shr(rgba, 16), splat(0xff));
	*a = shr(rgba, 24) ;
	};

	auto mul_unorm8 = [&](skvm::I32 x, skvm::I32 y) {
	// (xy + 127)/255 ~= (xy+255)/256
	return shr(add(mul(x, y), splat(0xff)), 8);
	};

	skvm::I32 r,g,b,a;
	load(src, &r,&g,&b,&a);

	skvm::I32 dr,dg,db,da;
	load(dst, &dr,&dg,&db,&da);

	skvm::I32 invA = sub(splat(0xff), a);
	r = add(r, mul_unorm8(dr, invA));
	g = add(g, mul_unorm8(dg, invA));
	b = add(b, mul_unorm8(db, invA));
	a = add(a, mul_unorm8(da, invA));

	store32(dst, bit_or( r ,
	bit_or(shl(g, 8),
	bit_or(shl(b, 16),
	shl(a, 24)))));
	}
	};

	struct SrcoverBuilder_I32_SWAR : public skvm::Builder {
	SrcoverBuilder_I32_SWAR() {
	skvm::Arg src = arg(0),
	dst = arg(1);

	auto load = [&](skvm::Arg ptr,
	skvm::I32* rb, skvm::I32* ga) {
	skvm::I32 rgba = load32(ptr);
	*rb = bit_and( rgba, splat(0x00ff00ff));
	*ga = bit_and(shr(rgba, 8), splat(0x00ff00ff));
	};

	auto mul_unorm8 = [&](skvm::I32 x, skvm::I32 y) {
	// As above, assuming x is two SWAR bytes in lanes 0 and 2, and y is a byte.
	return bit_and(shr(add(mul(x, y),
	splat(0x00ff00ff)),
	8),
	splat(0x00ff00ff));
	};

	skvm::I32 rb, ga;
	load(src, &rb, &ga);

	skvm::I32 drb, dga;
	load(dst, &drb, &dga);

	skvm::I32 invA = sub(splat(0xff), shr(ga, 16));
	rb = add(rb, mul_unorm8(drb, invA));
	ga = add(ga, mul_unorm8(dga, invA));

	store32(dst, bit_or(rb, shl(ga, 8)));
	}
	};
	}

	class SkVMBench : public Benchmark {
	public:
	SkVMBench(int pixels, Mode mode)
	: fPixels(pixels)
	, fMode(mode)
	, fName(SkStringPrintf("SkVM_%d_%s", pixels, kMode_name[mode]))
	{}

	private:
	const char* onGetName() override { return fName.c_str(); }
	bool isSuitableFor(Backend backend) override { return backend == kNonRendering_Backend; }

	void onDelayedSetup() override {
	this->setUnits(fPixels);
	fSrc.resize(fPixels, 0x7f123456); // Arbitrary non-opaque non-transparent value.
	fDst.resize(fPixels, 0xff987654); // Arbitrary value.

	if (fMode == F32 ) { fProgram = SrcoverBuilder_F32 {}.done(); }
	if (fMode == I32 ) { fProgram = SrcoverBuilder_I32 {}.done(); }
	if (fMode == I32_SWAR) { fProgram = SrcoverBuilder_I32_SWAR{}.done(); }

	if (fMode == RP) {
	fSrcCtx = { fSrc.data(), 0 };
	fDstCtx = { fDst.data(), 0 };
	fPipeline.append(SkRasterPipeline::load_8888 , &fSrcCtx);
	fPipeline.append(SkRasterPipeline::load_8888_dst, &fDstCtx);
	fPipeline.append(SkRasterPipeline::srcover);
	fPipeline.append(SkRasterPipeline::store_8888, &fDstCtx);
	}

	// Trigger one run now so we can do a quick correctness check.
	this->draw(1,nullptr);
	for (int i = 0; i < fPixels; i++) {
	SkASSERT(fDst[i] == 0xff5e6f80);
	}
	}

	void onDraw(int loops, SkCanvas*) override {
	while (loops --> 0) {
	if (fMode == Opts) {
	SkOpts::blit_row_s32a_opaque(fDst.data(), fSrc.data(), fPixels, 0xff);
	} else if (fMode == RP) {
	fPipeline.run(0,0,fPixels,1);
	} else {
	fProgram.eval(fPixels, fSrc.data(), fDst.data());
	}
	}
	}

	int fPixels;
	Mode fMode;
	SkString fName;
	std::vector<uint32_t> fSrc,
	fDst;
	skvm::Program fProgram;

	SkRasterPipeline_MemoryCtx fSrcCtx,
	fDstCtx;
	SkRasterPipeline_<256> fPipeline;
	};

	DEF_BENCH(return (new SkVMBench{ 1, Opts});)
	DEF_BENCH(return (new SkVMBench{ 4, Opts});)
	DEF_BENCH(return (new SkVMBench{ 16, Opts});)
	DEF_BENCH(return (new SkVMBench{ 64, Opts});)
	DEF_BENCH(return (new SkVMBench{ 256, Opts});)
	DEF_BENCH(return (new SkVMBench{1024, Opts});)
	DEF_BENCH(return (new SkVMBench{4096, Opts});)

	DEF_BENCH(return (new SkVMBench{ 1, RP});)
	DEF_BENCH(return (new SkVMBench{ 4, RP});)
	DEF_BENCH(return (new SkVMBench{ 16, RP});)
	DEF_BENCH(return (new SkVMBench{ 64, RP});)
	DEF_BENCH(return (new SkVMBench{ 256, RP});)
	DEF_BENCH(return (new SkVMBench{1024, RP});)
	DEF_BENCH(return (new SkVMBench{4096, RP});)

	DEF_BENCH(return (new SkVMBench{ 1, F32});)
	DEF_BENCH(return (new SkVMBench{ 4, F32});)
	DEF_BENCH(return (new SkVMBench{ 16, F32});)
	DEF_BENCH(return (new SkVMBench{ 64, F32});)
	DEF_BENCH(return (new SkVMBench{ 256, F32});)
	DEF_BENCH(return (new SkVMBench{1024, F32});)
	DEF_BENCH(return (new SkVMBench{4096, F32});)

	DEF_BENCH(return (new SkVMBench{ 1, I32});)
	DEF_BENCH(return (new SkVMBench{ 4, I32});)
	DEF_BENCH(return (new SkVMBench{ 16, I32});)
	DEF_BENCH(return (new SkVMBench{ 64, I32});)
	DEF_BENCH(return (new SkVMBench{ 256, I32});)
	DEF_BENCH(return (new SkVMBench{1024, I32});)
	DEF_BENCH(return (new SkVMBench{4096, I32});)

	DEF_BENCH(return (new SkVMBench{ 1, I32_SWAR});)
	DEF_BENCH(return (new SkVMBench{ 4, I32_SWAR});)
	DEF_BENCH(return (new SkVMBench{ 16, I32_SWAR});)
	DEF_BENCH(return (new SkVMBench{ 64, I32_SWAR});)
	DEF_BENCH(return (new SkVMBench{ 256, I32_SWAR});)
	DEF_BENCH(return (new SkVMBench{1024, I32_SWAR});)
	DEF_BENCH(return (new SkVMBench{4096, I32_SWAR});)