tools/remote_demo.cpp - skia - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkCanvas.h"
 #include "SkPathEffect.h"
 #include "SkMaskFilter.h"
 #include "SkData.h"
 #include "SkDescriptor.h"
 #include "SkGraphics.h"
 #include "SkSemaphore.h"
 #include "SkPictureRecorder.h"
 #include "SkSerialProcs.h"
 #include "SkSurface.h"
 #include "SkTypeface.h"
 #include "SkWriteBuffer.h"

 #include <chrono>
 #include <ctype.h>
 #include <err.h>
 #include <memory>
 #include <stdio.h>
 #include <thread>
 #include <iostream>
 #include <unordered_map>

 #include <sys/types.h>
 #include <sys/wait.h>
 #include <unistd.h>
 #include <sys/mman.h>
 #include "SkTypeface_remote.h"

 static const size_t kPageSize = 4096;

 struct WireTypeface {
     std::thread::id thread_id;
     SkFontID        typeface_id;
     SkFontStyle     style;
     bool            is_fixed;
 };

 class ScalerContextRecDescriptor {
 public:
     explicit ScalerContextRecDescriptor(const SkScalerContextRec& rec) {
         auto desc = reinterpret_cast<SkDescriptor*>(&fDescriptor);
         desc->init();
         desc->addEntry(kRec_SkDescriptorTag, sizeof(rec), &rec);
     }

     const SkDescriptor& desc() const {
         return *reinterpret_cast<const SkDescriptor*>(&fDescriptor);
     }

     struct Hash {
         size_t operator()(ScalerContextRecDescriptor const& s) const {
             return SkOpts::hash_fn(&s.desc(), sizeof(s), 0);
         }
     };

     struct Equal {
         bool operator()( const ScalerContextRecDescriptor& lhs,
                          const ScalerContextRecDescriptor& rhs ) const {
             return lhs.desc() == rhs.desc();
         }
     };

 private:
     // The system only passes descriptors without effects. That is why it uses a fixed size
     // descriptor. storageFor is needed because some of the constructors below are private.
     template <typename T>
     using storageFor = typename std::aligned_storage<sizeof(T), alignof(T)>::type;
     struct {
         storageFor<SkDescriptor>        dummy1;
         storageFor<SkDescriptor::Entry> dummy2;
         storageFor<SkScalerContextRec>  dummy3;
     } fDescriptor;
 };

 class Op {
 public:
     explicit Op(const SkScalerContextRec& rec) : descriptor{rec} {}
     int32_t op;
     SkFontID typeface_id;
     union {
         // op 0
         SkPaint::FontMetrics fontMetrics;
         // op 1 and 2
         SkGlyph glyph;
         // op 3
         struct {
             SkGlyphID glyphId;
             size_t pathSize;
         };
     };
     ScalerContextRecDescriptor descriptor;
 };

 class RemoteScalerContextPassThread : public SkRemoteScalerContext {
 public:
     explicit RemoteScalerContextPassThread(int readFd, int writeFd)
         : fReadFd{readFd}
         , fWriteFd{writeFd} { }
     void generateFontMetrics(const SkTypefaceProxy& tf,
                              const SkScalerContextRec& rec,
                              SkPaint::FontMetrics* metrics) override {
         Op* op = this->createOp(0, tf, rec);
         write(fWriteFd, fBuffer, sizeof(*op));
         read(fReadFd, fBuffer, sizeof(fBuffer));
         memcpy(metrics, &op->fontMetrics, sizeof(op->fontMetrics));
         op->~Op();
     }

     void generateMetrics(const SkTypefaceProxy& tf,
                          const SkScalerContextRec& rec,
                          SkGlyph* glyph) override {
         Op* op = this->createOp(1, tf, rec);
         memcpy(&op->glyph, glyph, sizeof(*glyph));
         write(fWriteFd, fBuffer, sizeof(*op));
         read(fReadFd, fBuffer, sizeof(fBuffer));
         memcpy(glyph, &op->glyph, sizeof(op->glyph));
         op->~Op();
     }

     void generateImage(const SkTypefaceProxy& tf,
                        const SkScalerContextRec& rec,
                        const SkGlyph& glyph) override {
         Op* op = this->createOp(2, tf, rec);
         memcpy(&op->glyph, &glyph, sizeof(glyph));
         write(fWriteFd, fBuffer, sizeof(*op));
         read(fReadFd, fBuffer, sizeof(fBuffer));
         memcpy(glyph.fImage, fBuffer + sizeof(Op), glyph.rowBytes() * glyph.fHeight);
         op->~Op();
     }

     void generatePath(const SkTypefaceProxy& tf,
                       const SkScalerContextRec& rec,
                       SkGlyphID glyph, SkPath* path) override {
         Op* op = this->createOp(3, tf, rec);
         op->glyphId = glyph;
         write(fWriteFd, fBuffer, sizeof(*op));
         read(fReadFd, fBuffer, sizeof(fBuffer));
         path->readFromMemory(fBuffer + sizeof(Op), op->pathSize);
         op->~Op();
     }

 private:
     Op* createOp(uint32_t opID, const SkTypefaceProxy& tf,
                  const SkScalerContextRec& rec) {
         Op* op = new (fBuffer) Op(rec);
         op->op = opID;
         op->typeface_id = tf.fontID();

         return op;
     }

     const int fReadFd,
               fWriteFd;
     uint8_t   fBuffer[1024 * kPageSize];
 };

 static sk_sp<SkTypeface> gpu_from_renderer_by_ID(const void* buf, size_t len, void* ctx) {
     static std::unordered_map<SkFontID, sk_sp<SkTypefaceProxy>> mapIdToTypeface;
     WireTypeface wire;
     if (len >= sizeof(wire)) {
         memcpy(&wire, buf, sizeof(wire));
         auto i = mapIdToTypeface.find(wire.typeface_id);
         if (i == mapIdToTypeface.end()) {

             auto newTypeface = sk_make_sp<SkTypefaceProxy>(
                 wire.typeface_id,
                 wire.thread_id,
                 wire.style,
                 wire.is_fixed,
                 (SkRemoteScalerContext*)ctx);

             i = mapIdToTypeface.emplace_hint(i, wire.typeface_id, newTypeface);
         }
         return i->second;
     }
     SK_ABORT("Bad data");
     return nullptr;
 }

 std::unordered_map<SkFontID, sk_sp<SkTypeface>> gTypefaceMap;


 // TODO: Figure out how to manage the entries.
 std::unordered_map<ScalerContextRecDescriptor,
                    std::unique_ptr<SkScalerContext>,
                    ScalerContextRecDescriptor::Hash,
                    ScalerContextRecDescriptor::Equal>
     gScalerContextMap(16,
                       ScalerContextRecDescriptor::Hash(),
                       ScalerContextRecDescriptor::Equal());

 static SkScalerContext* scaler_context_from_op(Op* op) {

     SkScalerContext* sc;
     auto j = gScalerContextMap.find(op->descriptor);
     if (j != gScalerContextMap.end()) {
         sc = j->second.get();
     } else {
         auto i = gTypefaceMap.find(op->typeface_id);
         if (i == gTypefaceMap.end()) {
             std::cerr << "bad typeface id: " << op->typeface_id << std::endl;
             SK_ABORT("unknown type face");
         }
         auto tf = i->second;
         SkScalerContextEffects effects;
         auto mapSc = tf->createScalerContext(effects, &op->descriptor.desc(), false);
         sc = mapSc.get();
         gScalerContextMap.emplace_hint(j, op->descriptor, std::move(mapSc));
     }
     return sc;

 }

 static sk_sp<SkData> renderer_to_gpu_by_ID(SkTypeface* tf, void* ctx) {
     WireTypeface wire = {
             std::this_thread::get_id(),
             SkTypeface::UniqueID(tf),
             tf->fontStyle(),
             tf->isFixedPitch()
     };
     auto i = gTypefaceMap.find(SkTypeface::UniqueID(tf));
     if (i == gTypefaceMap.end()) {
         gTypefaceMap.insert({SkTypeface::UniqueID(tf), sk_ref_sp(tf)});
     }
     return SkData::MakeWithCopy(&wire, sizeof(wire));
 }

 static void final_draw(std::string outFilename,
                        SkDeserialProcs* procs,
                        uint8_t* picData,
                        size_t picSize) {

     auto pic = SkPicture::MakeFromData(picData, picSize, procs);

     auto cullRect = pic->cullRect();
     auto r = cullRect.round();

     auto s = SkSurface::MakeRasterN32Premul(r.width(), r.height());
     auto c = s->getCanvas();

     auto picUnderTest = SkPicture::MakeFromData(picData, picSize, procs);
     auto start = std::chrono::high_resolution_clock::now();

     for (int i = 0; i < 40; i++) {

         c->drawPicture(picUnderTest);
     }

     auto end = std::chrono::high_resolution_clock::now();

     std::chrono::duration<double> elapsed_seconds = end-start;

     std::cout << "elapsed time: " << elapsed_seconds.count() << "s\n";

     auto i = s->makeImageSnapshot();
     auto data = i->encodeToData();
     SkFILEWStream f(outFilename.c_str());
     f.write(data->data(), data->size());
 }

 static void gpu(int readFd, int writeFd) {

     size_t picSize = 0;
     read(readFd, &picSize, sizeof(picSize));

     static constexpr size_t kBufferSize = 10 * 1024 * kPageSize;
     std::unique_ptr<uint8_t[]> picBuffer{new uint8_t[kBufferSize]};

     size_t readSoFar = 0;
     while (readSoFar < picSize) {
         ssize_t readSize;
         if((readSize = read(readFd, &picBuffer[readSoFar], kBufferSize - readSoFar)) <= 0) {
             if (readSize == 0) return;
             err(1, "gpu pic read error %d", errno);
         }
         readSoFar += readSize;
     }

     SkDeserialProcs procs;
     std::unique_ptr<SkRemoteScalerContext> rsc{
             new RemoteScalerContextPassThread{readFd, writeFd}};
     procs.fTypefaceProc = gpu_from_renderer_by_ID;
     procs.fTypefaceCtx = rsc.get();
     final_draw("test.png", &procs, picBuffer.get(), picSize);
     /*
     auto pic = SkPicture::MakeFromData(picBuffer.get(), picSize, &procs);

     auto cullRect = pic->cullRect();
     auto r = cullRect.round();
     auto s = SkSurface::MakeRasterN32Premul(r.width(), r.height());

     auto c = s->getCanvas();
     c->drawPicture(pic);

     auto i = s->makeImageSnapshot();
     auto data = i->encodeToData();
     SkFILEWStream f("test.png");
     f.write(data->data(), data->size());
      */
     close(writeFd);
     close(readFd);
 }

 static int renderer(const std::string& skpName, int readFd, int writeFd) {
     std::string prefix{"skps/"};
     std::string fileName{prefix + skpName + ".skp"};

     auto skp = SkData::MakeFromFileName(fileName.c_str());
     auto pic = SkPicture::MakeFromData(skp.get());

     bool toGpu = true;

     SkSerialProcs procs;
     if (toGpu) {
         procs.fTypefaceProc = renderer_to_gpu_by_ID;
     }

     auto stream = pic->serialize(&procs);

     std::cerr << "stream is " << stream->size() << " bytes long" << std::endl;

     size_t picSize = stream->size();
     uint8_t* picBuffer = (uint8_t*) stream->data();

     if (!toGpu) {
         final_draw("test-direct.png", nullptr, picBuffer, picSize);
         close(writeFd);
         close(readFd);
         return 0;
     }

     write(writeFd, &picSize, sizeof(picSize));

     size_t writeSoFar = 0;
     while (writeSoFar < picSize) {
         ssize_t writeSize = write(writeFd, &picBuffer[writeSoFar], picSize - writeSoFar);
         if (writeSize <= 0) {
             if (writeSize == 0) {
                 std::cerr << "Exit" << std::endl;
                 return 1;
             }
             perror("Can't write picture from render to GPU ");
             return 1;
         }
         writeSoFar += writeSize;
     }
     std::cerr << "Waiting for scaler context ops." << std::endl;

     static constexpr size_t kBufferSize = 1024 * kPageSize;
     std::unique_ptr<uint8_t[]> glyphBuffer{new uint8_t[kBufferSize]};

     Op* op = (Op*)glyphBuffer.get();
     while (true) {
         ssize_t size = read(readFd, glyphBuffer.get(), sizeof(*op));
         if (size <= 0) { std::cerr << "Exit op loop" << std::endl; break;}
         size_t writeSize = sizeof(*op);

             auto sc = scaler_context_from_op(op);
             switch (op->op) {
                 case 0: {
                     sc->getFontMetrics(&op->fontMetrics);
                     break;
                 }
                 case 1: {
                     sc->getMetrics(&op->glyph);
                     break;
                 }
                 case 2: {
                     // TODO: check for buffer overflow.
                     op->glyph.fImage = &glyphBuffer[sizeof(Op)];
                     sc->getImage(op->glyph);
                     writeSize += op->glyph.rowBytes() * op->glyph.fHeight;
                     break;
                 }
                 case 3: {
                     // TODO: check for buffer overflow.
                     SkPath path;
                     sc->getPath(op->glyphId, &path);
                     op->pathSize = path.writeToMemory(&glyphBuffer[sizeof(Op)]);
                     writeSize += op->pathSize;
                     break;
                 }
                 default:
                     SkASSERT("Bad op");
             }
         write(writeFd, glyphBuffer.get(), writeSize);
     }

     close(readFd);
     close(writeFd);

     std::cerr << "Returning from render" << std::endl;

     return 0;
 }

 enum direction : int {kRead = 0, kWrite = 1};

 static void start_gpu(int render_to_gpu[2], int gpu_to_render[2]) {
     std::cout << "gpu - Starting GPU" << std::endl;
     close(gpu_to_render[kRead]);
     close(render_to_gpu[kWrite]);
     gpu(render_to_gpu[kRead], gpu_to_render[kWrite]);
 }

 static void start_render(std::string& skpName, int render_to_gpu[2], int gpu_to_render[2]) {
     std::cout << "renderer - Starting Renderer" << std::endl;
     close(render_to_gpu[kRead]);
     close(gpu_to_render[kWrite]);
     renderer(skpName, gpu_to_render[kRead], render_to_gpu[kWrite]);
 }

 int main(int argc, char** argv) {
     std::string skpName = argc > 1 ? std::string{argv[1]} : std::string{"desk_nytimes"};
     printf("skp: %s\n", skpName.c_str());

     int render_to_gpu[2],
         gpu_to_render[2];

     int r = pipe(render_to_gpu);
     if (r < 0) {
         perror("Can't write picture from render to GPU ");
         return 1;
     }
     r = pipe(gpu_to_render);
     if (r < 0) {
         perror("Can't write picture from render to GPU ");
         return 1;
     }

     bool useProcess = true;

     if (useProcess) {
         pid_t child = fork();
         SkGraphics::Init();

         if (child == 0) {
             start_render(skpName, render_to_gpu, gpu_to_render);
         } else {
             start_gpu(render_to_gpu, gpu_to_render);
             std::cerr << "Waiting for renderer." << std::endl;
             waitpid(child, nullptr, 0);
         }
     } else {
         SkGraphics::Init();
         std::thread(gpu, render_to_gpu[kRead], gpu_to_render[kWrite]).detach();
         renderer(skpName, gpu_to_render[kRead], render_to_gpu[kWrite]);
     }

     return 0;
 }
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkCanvas.h"
	#include "SkPathEffect.h"
	#include "SkMaskFilter.h"
	#include "SkData.h"
	#include "SkDescriptor.h"
	#include "SkGraphics.h"
	#include "SkSemaphore.h"
	#include "SkPictureRecorder.h"
	#include "SkSerialProcs.h"
	#include "SkSurface.h"
	#include "SkTypeface.h"
	#include "SkWriteBuffer.h"

	#include <chrono>
	#include <ctype.h>
	#include <err.h>
	#include <memory>
	#include <stdio.h>
	#include <thread>
	#include <iostream>
	#include <unordered_map>

	#include <sys/types.h>
	#include <sys/wait.h>
	#include <unistd.h>
	#include <sys/mman.h>
	#include "SkTypeface_remote.h"

	static const size_t kPageSize = 4096;

	struct WireTypeface {
	std::thread::id thread_id;
	SkFontID typeface_id;
	SkFontStyle style;
	bool is_fixed;
	};

	class ScalerContextRecDescriptor {
	public:
	explicit ScalerContextRecDescriptor(const SkScalerContextRec& rec) {
	auto desc = reinterpret_cast<SkDescriptor*>(&fDescriptor);
	desc->init();
	desc->addEntry(kRec_SkDescriptorTag, sizeof(rec), &rec);
	}

	const SkDescriptor& desc() const {
	return reinterpret_cast<const SkDescriptor>(&fDescriptor);
	}

	struct Hash {
	size_t operator()(ScalerContextRecDescriptor const& s) const {
	return SkOpts::hash_fn(&s.desc(), sizeof(s), 0);
	}
	};

	struct Equal {
	bool operator()( const ScalerContextRecDescriptor& lhs,
	const ScalerContextRecDescriptor& rhs ) const {
	return lhs.desc() == rhs.desc();
	}
	};

	private:
	// The system only passes descriptors without effects. That is why it uses a fixed size
	// descriptor. storageFor is needed because some of the constructors below are private.
	template <typename T>
	using storageFor = typename std::aligned_storage<sizeof(T), alignof(T)>::type;
	struct {
	storageFor<SkDescriptor> dummy1;
	storageFor<SkDescriptor::Entry> dummy2;
	storageFor<SkScalerContextRec> dummy3;
	} fDescriptor;
	};

	class Op {
	public:
	explicit Op(const SkScalerContextRec& rec) : descriptor{rec} {}
	int32_t op;
	SkFontID typeface_id;
	union {
	// op 0
	SkPaint::FontMetrics fontMetrics;
	// op 1 and 2
	SkGlyph glyph;
	// op 3
	struct {
	SkGlyphID glyphId;
	size_t pathSize;
	};
	};
	ScalerContextRecDescriptor descriptor;
	};

	class RemoteScalerContextPassThread : public SkRemoteScalerContext {
	public:
	explicit RemoteScalerContextPassThread(int readFd, int writeFd)
	: fReadFd{readFd}
	, fWriteFd{writeFd} { }
	void generateFontMetrics(const SkTypefaceProxy& tf,
	const SkScalerContextRec& rec,
	SkPaint::FontMetrics* metrics) override {
	Op* op = this->createOp(0, tf, rec);
	write(fWriteFd, fBuffer, sizeof(*op));
	read(fReadFd, fBuffer, sizeof(fBuffer));
	memcpy(metrics, &op->fontMetrics, sizeof(op->fontMetrics));
	op->~Op();
	}

	void generateMetrics(const SkTypefaceProxy& tf,
	const SkScalerContextRec& rec,
	SkGlyph* glyph) override {
	Op* op = this->createOp(1, tf, rec);
	memcpy(&op->glyph, glyph, sizeof(*glyph));
	write(fWriteFd, fBuffer, sizeof(*op));
	read(fReadFd, fBuffer, sizeof(fBuffer));
	memcpy(glyph, &op->glyph, sizeof(op->glyph));
	op->~Op();
	}

	void generateImage(const SkTypefaceProxy& tf,
	const SkScalerContextRec& rec,
	const SkGlyph& glyph) override {
	Op* op = this->createOp(2, tf, rec);
	memcpy(&op->glyph, &glyph, sizeof(glyph));
	write(fWriteFd, fBuffer, sizeof(*op));
	read(fReadFd, fBuffer, sizeof(fBuffer));
	memcpy(glyph.fImage, fBuffer + sizeof(Op), glyph.rowBytes() * glyph.fHeight);
	op->~Op();
	}

	void generatePath(const SkTypefaceProxy& tf,
	const SkScalerContextRec& rec,
	SkGlyphID glyph, SkPath* path) override {
	Op* op = this->createOp(3, tf, rec);
	op->glyphId = glyph;
	write(fWriteFd, fBuffer, sizeof(*op));
	read(fReadFd, fBuffer, sizeof(fBuffer));
	path->readFromMemory(fBuffer + sizeof(Op), op->pathSize);
	op->~Op();
	}

	private:
	Op* createOp(uint32_t opID, const SkTypefaceProxy& tf,
	const SkScalerContextRec& rec) {
	Op* op = new (fBuffer) Op(rec);
	op->op = opID;
	op->typeface_id = tf.fontID();

	return op;
	}

	const int fReadFd,
	fWriteFd;
	uint8_t fBuffer[1024 * kPageSize];
	};

	static sk_sp<SkTypeface> gpu_from_renderer_by_ID(const void* buf, size_t len, void* ctx) {
	static std::unordered_map<SkFontID, sk_sp<SkTypefaceProxy>> mapIdToTypeface;
	WireTypeface wire;
	if (len >= sizeof(wire)) {
	memcpy(&wire, buf, sizeof(wire));
	auto i = mapIdToTypeface.find(wire.typeface_id);
	if (i == mapIdToTypeface.end()) {

	auto newTypeface = sk_make_sp<SkTypefaceProxy>(
	wire.typeface_id,
	wire.thread_id,
	wire.style,
	wire.is_fixed,
	(SkRemoteScalerContext*)ctx);

	i = mapIdToTypeface.emplace_hint(i, wire.typeface_id, newTypeface);
	}
	return i->second;
	}
	SK_ABORT("Bad data");
	return nullptr;
	}

	std::unordered_map<SkFontID, sk_sp<SkTypeface>> gTypefaceMap;


	// TODO: Figure out how to manage the entries.
	std::unordered_map<ScalerContextRecDescriptor,
	std::unique_ptr<SkScalerContext>,
	ScalerContextRecDescriptor::Hash,
	ScalerContextRecDescriptor::Equal>
	gScalerContextMap(16,
	ScalerContextRecDescriptor::Hash(),
	ScalerContextRecDescriptor::Equal());

	static SkScalerContext* scaler_context_from_op(Op* op) {

	SkScalerContext* sc;
	auto j = gScalerContextMap.find(op->descriptor);
	if (j != gScalerContextMap.end()) {
	sc = j->second.get();
	} else {
	auto i = gTypefaceMap.find(op->typeface_id);
	if (i == gTypefaceMap.end()) {
	std::cerr << "bad typeface id: " << op->typeface_id << std::endl;
	SK_ABORT("unknown type face");
	}
	auto tf = i->second;
	SkScalerContextEffects effects;
	auto mapSc = tf->createScalerContext(effects, &op->descriptor.desc(), false);
	sc = mapSc.get();
	gScalerContextMap.emplace_hint(j, op->descriptor, std::move(mapSc));
	}
	return sc;

	}

	static sk_sp<SkData> renderer_to_gpu_by_ID(SkTypeface* tf, void* ctx) {
	WireTypeface wire = {
	std::this_thread::get_id(),
	SkTypeface::UniqueID(tf),
	tf->fontStyle(),
	tf->isFixedPitch()
	};
	auto i = gTypefaceMap.find(SkTypeface::UniqueID(tf));
	if (i == gTypefaceMap.end()) {
	gTypefaceMap.insert({SkTypeface::UniqueID(tf), sk_ref_sp(tf)});
	}
	return SkData::MakeWithCopy(&wire, sizeof(wire));
	}

	static void final_draw(std::string outFilename,
	SkDeserialProcs* procs,
	uint8_t* picData,
	size_t picSize) {

	auto pic = SkPicture::MakeFromData(picData, picSize, procs);

	auto cullRect = pic->cullRect();
	auto r = cullRect.round();

	auto s = SkSurface::MakeRasterN32Premul(r.width(), r.height());
	auto c = s->getCanvas();

	auto picUnderTest = SkPicture::MakeFromData(picData, picSize, procs);
	auto start = std::chrono::high_resolution_clock::now();

	for (int i = 0; i < 40; i++) {

	c->drawPicture(picUnderTest);
	}

	auto end = std::chrono::high_resolution_clock::now();

	std::chrono::duration<double> elapsed_seconds = end-start;

	std::cout << "elapsed time: " << elapsed_seconds.count() << "s\n";

	auto i = s->makeImageSnapshot();
	auto data = i->encodeToData();
	SkFILEWStream f(outFilename.c_str());
	f.write(data->data(), data->size());
	}

	static void gpu(int readFd, int writeFd) {

	size_t picSize = 0;
	read(readFd, &picSize, sizeof(picSize));

	static constexpr size_t kBufferSize = 10 * 1024 * kPageSize;
	std::unique_ptr<uint8_t[]> picBuffer{new uint8_t[kBufferSize]};

	size_t readSoFar = 0;
	while (readSoFar < picSize) {
	ssize_t readSize;
	if((readSize = read(readFd, &picBuffer[readSoFar], kBufferSize - readSoFar)) <= 0) {
	if (readSize == 0) return;
	err(1, "gpu pic read error %d", errno);
	}
	readSoFar += readSize;
	}

	SkDeserialProcs procs;
	std::unique_ptr<SkRemoteScalerContext> rsc{
	new RemoteScalerContextPassThread{readFd, writeFd}};
	procs.fTypefaceProc = gpu_from_renderer_by_ID;
	procs.fTypefaceCtx = rsc.get();
	final_draw("test.png", &procs, picBuffer.get(), picSize);
	/*
	auto pic = SkPicture::MakeFromData(picBuffer.get(), picSize, &procs);

	auto cullRect = pic->cullRect();
	auto r = cullRect.round();
	auto s = SkSurface::MakeRasterN32Premul(r.width(), r.height());

	auto c = s->getCanvas();
	c->drawPicture(pic);

	auto i = s->makeImageSnapshot();
	auto data = i->encodeToData();
	SkFILEWStream f("test.png");
	f.write(data->data(), data->size());
	*/
	close(writeFd);
	close(readFd);
	}

	static int renderer(const std::string& skpName, int readFd, int writeFd) {
	std::string prefix{"skps/"};
	std::string fileName{prefix + skpName + ".skp"};

	auto skp = SkData::MakeFromFileName(fileName.c_str());
	auto pic = SkPicture::MakeFromData(skp.get());

	bool toGpu = true;

	SkSerialProcs procs;
	if (toGpu) {
	procs.fTypefaceProc = renderer_to_gpu_by_ID;
	}

	auto stream = pic->serialize(&procs);

	std::cerr << "stream is " << stream->size() << " bytes long" << std::endl;

	size_t picSize = stream->size();
	uint8_t* picBuffer = (uint8_t*) stream->data();

	if (!toGpu) {
	final_draw("test-direct.png", nullptr, picBuffer, picSize);
	close(writeFd);
	close(readFd);
	return 0;
	}

	write(writeFd, &picSize, sizeof(picSize));

	size_t writeSoFar = 0;
	while (writeSoFar < picSize) {
	ssize_t writeSize = write(writeFd, &picBuffer[writeSoFar], picSize - writeSoFar);
	if (writeSize <= 0) {
	if (writeSize == 0) {
	std::cerr << "Exit" << std::endl;
	return 1;
	}
	perror("Can't write picture from render to GPU ");
	return 1;
	}
	writeSoFar += writeSize;
	}
	std::cerr << "Waiting for scaler context ops." << std::endl;

	static constexpr size_t kBufferSize = 1024 * kPageSize;
	std::unique_ptr<uint8_t[]> glyphBuffer{new uint8_t[kBufferSize]};

	Op* op = (Op*)glyphBuffer.get();
	while (true) {
	ssize_t size = read(readFd, glyphBuffer.get(), sizeof(*op));
	if (size <= 0) { std::cerr << "Exit op loop" << std::endl; break;}
	size_t writeSize = sizeof(*op);

	auto sc = scaler_context_from_op(op);
	switch (op->op) {
	case 0: {
	sc->getFontMetrics(&op->fontMetrics);
	break;
	}
	case 1: {
	sc->getMetrics(&op->glyph);
	break;
	}
	case 2: {
	// TODO: check for buffer overflow.
	op->glyph.fImage = &glyphBuffer[sizeof(Op)];
	sc->getImage(op->glyph);
	writeSize += op->glyph.rowBytes() * op->glyph.fHeight;
	break;
	}
	case 3: {
	// TODO: check for buffer overflow.
	SkPath path;
	sc->getPath(op->glyphId, &path);
	op->pathSize = path.writeToMemory(&glyphBuffer[sizeof(Op)]);
	writeSize += op->pathSize;
	break;
	}
	default:
	SkASSERT("Bad op");
	}
	write(writeFd, glyphBuffer.get(), writeSize);
	}

	close(readFd);
	close(writeFd);

	std::cerr << "Returning from render" << std::endl;

	return 0;
	}

	enum direction : int {kRead = 0, kWrite = 1};

	static void start_gpu(int render_to_gpu[2], int gpu_to_render[2]) {
	std::cout << "gpu - Starting GPU" << std::endl;
	close(gpu_to_render[kRead]);
	close(render_to_gpu[kWrite]);
	gpu(render_to_gpu[kRead], gpu_to_render[kWrite]);
	}

	static void start_render(std::string& skpName, int render_to_gpu[2], int gpu_to_render[2]) {
	std::cout << "renderer - Starting Renderer" << std::endl;
	close(render_to_gpu[kRead]);
	close(gpu_to_render[kWrite]);
	renderer(skpName, gpu_to_render[kRead], render_to_gpu[kWrite]);
	}

	int main(int argc, char** argv) {
	std::string skpName = argc > 1 ? std::string{argv[1]} : std::string{"desk_nytimes"};
	printf("skp: %s\n", skpName.c_str());

	int render_to_gpu[2],
	gpu_to_render[2];

	int r = pipe(render_to_gpu);
	if (r < 0) {
	perror("Can't write picture from render to GPU ");
	return 1;
	}
	r = pipe(gpu_to_render);
	if (r < 0) {
	perror("Can't write picture from render to GPU ");
	return 1;
	}

	bool useProcess = true;

	if (useProcess) {
	pid_t child = fork();
	SkGraphics::Init();

	if (child == 0) {
	start_render(skpName, render_to_gpu, gpu_to_render);
	} else {
	start_gpu(render_to_gpu, gpu_to_render);
	std::cerr << "Waiting for renderer." << std::endl;
	waitpid(child, nullptr, 0);
	}
	} else {
	SkGraphics::Init();
	std::thread(gpu, render_to_gpu[kRead], gpu_to_render[kWrite]).detach();
	renderer(skpName, gpu_to_render[kRead], render_to_gpu[kWrite]);
	}

	return 0;
	}