modules/canvaskit/WasmCommon.h - skia - Git at Google

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

 #ifndef WasmCommon_DEFINED
 #define WasmCommon_DEFINED

 #include <emscripten.h>
 #include <emscripten/bind.h>
 #include "include/core/SkColor.h"
 #include "include/core/SkSpan.h"
 #include "include/private/SkMalloc.h"

 using namespace emscripten;

 // Self-documenting types
 using JSArray = emscripten::val;
 using JSObject = emscripten::val;
 using JSString = emscripten::val;
 using SkPathOrNull = emscripten::val;
 using TypedArray = emscripten::val;
 using Uint8Array = emscripten::val;
 using Uint16Array = emscripten::val;
 using Uint32Array = emscripten::val;
 using Float32Array = emscripten::val;

 // If we are using C++ and EMSCRIPTEN_BINDINGS, we can't have primitive pointers in our function
 // type signatures. (this gives an error message like "Cannot call foo due to unbound
 // types Pi, Pf").  But, we can just pretend they are numbers and cast them to be pointers and
 // the compiler is happy.
 // These types refer to the TypedArray that the JS interface wrote into or will read out of.
 // This doesn't stop us from using these as different types; e.g. a float* can be treated as an
 // SkPoint* in some APIs.
 using WASMPointerF32 = uintptr_t;
 using WASMPointerU8  = uintptr_t;
 using WASMPointerU16 = uintptr_t;
 using WASMPointerU32 = uintptr_t;
 using WASMPointer = uintptr_t;

 #define SPECIALIZE_JSARRAYTYPE(type, name)                  \
     template <> struct JSArrayType<type> {                  \
         static constexpr const char* const gName = name;    \
     }

 template <typename T> struct JSArrayType {};

 SPECIALIZE_JSARRAYTYPE( int8_t,    "Int8Array");
 SPECIALIZE_JSARRAYTYPE(uint8_t,   "Uint8Array");
 SPECIALIZE_JSARRAYTYPE( int16_t,  "Int16Array");
 SPECIALIZE_JSARRAYTYPE(uint16_t, "Uint16Array");
 SPECIALIZE_JSARRAYTYPE( int32_t,  "Int32Array");
 SPECIALIZE_JSARRAYTYPE(uint32_t, "Uint32Array");
 SPECIALIZE_JSARRAYTYPE(float,   "Float32Array");

 #undef SPECIALIZE_JSARRAYTYPE

 /**
  *  Create a typed-array (in the JS heap) and initialize it with the provided
  *  data (from the wasm heap).
  */
 template <typename T> TypedArray MakeTypedArray(int count, const T src[]) {
     emscripten::val length = emscripten::val(count);
     emscripten::val jarray = emscripten::val::global(JSArrayType<T>::gName).new_(count);
     jarray.call<void>("set", val(typed_memory_view(count, src)));
     return jarray;
 }

 /**
  *  Gives read access to a JSArray
  *
  *  We explicitly use malloc/free (not new/delete) so this can be used with allocations from the JS
  *  side (ala CanvasKit.Malloc).
  */
 template <typename T> class JSSpan {
 public:
     // Note: Use of this constructor is 5-20x slower than manually copying the data on the JS side
     // and sending over a pointer, length, and boolean for the other constructor.
     JSSpan(JSArray src) {
         const size_t len = src["length"].as<size_t>();
         T* data;

         // If the buffer was allocated via CanvasKit' Malloc, we can peek directly at it!
         if (src["_ck"].isTrue()) {
             fOwned = false;
             data = reinterpret_cast<T*>(src["byteOffset"].as<size_t>());
         } else {
             fOwned = true;
             data = static_cast<T*>(sk_malloc_throw(len, sizeof(T)));

             // now actually copy into 'data'
             if (src.instanceof(emscripten::val::global(JSArrayType<T>::gName))) {
                 auto dst_view = emscripten::val(typed_memory_view(len, data));
                 dst_view.call<void>("set", src);
             } else {
                 for (size_t i = 0; i < len; ++i) {
                     data[i] = src[i].as<T>();
                 }
             }
         }
         fSpan = SkSpan(data, len);
     }

     JSSpan(WASMPointer ptr, size_t len, bool takeOwnership): fOwned(takeOwnership) {
         fSpan = SkSpan(reinterpret_cast<T*>(ptr), len);
     }

     ~JSSpan() {
         if (fOwned) {
             sk_free(fSpan.data());
         }
     }

     const T* data() const { return fSpan.data(); }
     size_t size() const { return fSpan.size(); }

 private:
     SkSpan<T>   fSpan;
     bool        fOwned;
 };

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

	#ifndef WasmCommon_DEFINED
	#define WasmCommon_DEFINED

	#include <emscripten.h>
	#include <emscripten/bind.h>
	#include "include/core/SkColor.h"
	#include "include/core/SkSpan.h"
	#include "include/private/SkMalloc.h"

	using namespace emscripten;

	// Self-documenting types
	using JSArray = emscripten::val;
	using JSObject = emscripten::val;
	using JSString = emscripten::val;
	using SkPathOrNull = emscripten::val;
	using TypedArray = emscripten::val;
	using Uint8Array = emscripten::val;
	using Uint16Array = emscripten::val;
	using Uint32Array = emscripten::val;
	using Float32Array = emscripten::val;

	// If we are using C++ and EMSCRIPTEN_BINDINGS, we can't have primitive pointers in our function
	// type signatures. (this gives an error message like "Cannot call foo due to unbound
	// types Pi, Pf"). But, we can just pretend they are numbers and cast them to be pointers and
	// the compiler is happy.
	// These types refer to the TypedArray that the JS interface wrote into or will read out of.
	// This doesn't stop us from using these as different types; e.g. a float* can be treated as an
	// SkPoint* in some APIs.
	using WASMPointerF32 = uintptr_t;
	using WASMPointerU8 = uintptr_t;
	using WASMPointerU16 = uintptr_t;
	using WASMPointerU32 = uintptr_t;
	using WASMPointer = uintptr_t;

	#define SPECIALIZE_JSARRAYTYPE(type, name) \
	template <> struct JSArrayType<type> { \
	static constexpr const char* const gName = name; \
	}

	template <typename T> struct JSArrayType {};

	SPECIALIZE_JSARRAYTYPE( int8_t, "Int8Array");
	SPECIALIZE_JSARRAYTYPE(uint8_t, "Uint8Array");
	SPECIALIZE_JSARRAYTYPE( int16_t, "Int16Array");
	SPECIALIZE_JSARRAYTYPE(uint16_t, "Uint16Array");
	SPECIALIZE_JSARRAYTYPE( int32_t, "Int32Array");
	SPECIALIZE_JSARRAYTYPE(uint32_t, "Uint32Array");
	SPECIALIZE_JSARRAYTYPE(float, "Float32Array");

	#undef SPECIALIZE_JSARRAYTYPE

	/**
	* Create a typed-array (in the JS heap) and initialize it with the provided
	* data (from the wasm heap).
	*/
	template <typename T> TypedArray MakeTypedArray(int count, const T src[]) {
	emscripten::val length = emscripten::val(count);
	emscripten::val jarray = emscripten::val::global(JSArrayType<T>::gName).new_(count);
	jarray.call<void>("set", val(typed_memory_view(count, src)));
	return jarray;
	}

	/**
	* Gives read access to a JSArray
	*
	* We explicitly use malloc/free (not new/delete) so this can be used with allocations from the JS
	* side (ala CanvasKit.Malloc).
	*/
	template <typename T> class JSSpan {
	public:
	// Note: Use of this constructor is 5-20x slower than manually copying the data on the JS side
	// and sending over a pointer, length, and boolean for the other constructor.
	JSSpan(JSArray src) {
	const size_t len = src["length"].as<size_t>();
	T* data;

	// If the buffer was allocated via CanvasKit' Malloc, we can peek directly at it!
	if (src["_ck"].isTrue()) {
	fOwned = false;
	data = reinterpret_cast<T*>(src["byteOffset"].as<size_t>());
	} else {
	fOwned = true;
	data = static_cast<T*>(sk_malloc_throw(len, sizeof(T)));

	// now actually copy into 'data'
	if (src.instanceof(emscripten::val::global(JSArrayType<T>::gName))) {
	auto dst_view = emscripten::val(typed_memory_view(len, data));
	dst_view.call<void>("set", src);
	} else {
	for (size_t i = 0; i < len; ++i) {
	data[i] = src[i].as<T>();
	}
	}
	}
	fSpan = SkSpan(data, len);
	}

	JSSpan(WASMPointer ptr, size_t len, bool takeOwnership): fOwned(takeOwnership) {
	fSpan = SkSpan(reinterpret_cast<T*>(ptr), len);
	}

	~JSSpan() {
	if (fOwned) {
	sk_free(fSpan.data());
	}
	}

	const T* data() const { return fSpan.data(); }
	size_t size() const { return fSpan.size(); }

	private:
	SkSpan<T> fSpan;
	bool fOwned;
	};

	#endif