/* * Copyright 2018 Google LLC * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "include/android/SkAnimatedImage.h" #include "include/codec/SkAndroidCodec.h" #include "include/core/SkBlendMode.h" #include "include/core/SkBlurTypes.h" #include "include/core/SkCanvas.h" #include "include/core/SkColor.h" #include "include/core/SkColorFilter.h" #include "include/core/SkColorSpace.h" #include "include/core/SkData.h" #include "include/core/SkDrawable.h" #include "include/core/SkEncodedImageFormat.h" #include "include/core/SkFilterQuality.h" #include "include/core/SkImage.h" #include "include/core/SkImageFilter.h" #include "include/core/SkImageInfo.h" #include "include/core/SkM44.h" #include "include/core/SkMaskFilter.h" #include "include/core/SkPaint.h" #include "include/core/SkPath.h" #include "include/core/SkPathEffect.h" #include "include/core/SkPathMeasure.h" #include "include/core/SkPicture.h" #include "include/core/SkPictureRecorder.h" #include "include/core/SkRRect.h" #include "include/core/SkSamplingOptions.h" #include "include/core/SkScalar.h" #include "include/core/SkShader.h" #include "include/core/SkString.h" #include "include/core/SkStrokeRec.h" #include "include/core/SkSurface.h" #include "include/core/SkSurfaceProps.h" #include "include/core/SkTextBlob.h" #include "include/core/SkTypeface.h" #include "include/core/SkTypes.h" #include "include/core/SkVertices.h" #include "include/effects/SkCornerPathEffect.h" #include "include/effects/SkDashPathEffect.h" #include "include/effects/SkDiscretePathEffect.h" #include "include/effects/SkGradientShader.h" #include "include/effects/SkImageFilters.h" #include "include/effects/SkPerlinNoiseShader.h" #include "include/effects/SkRuntimeEffect.h" #include "include/effects/SkTrimPathEffect.h" #include "include/private/SkShadowFlags.h" #include "include/utils/SkParsePath.h" #include "include/utils/SkShadowUtils.h" #include "modules/skshaper/include/SkShaper.h" #include "src/core/SkFontMgrPriv.h" #include "src/core/SkImagePriv.h" #include "src/core/SkPathPriv.h" #include "src/core/SkResourceCache.h" #include "src/image/SkImage_Base.h" #include "src/sksl/SkSLCompiler.h" #include #include #include "modules/canvaskit/WasmCommon.h" #include #include #ifdef SK_GL #include "include/gpu/GrBackendSurface.h" #include "include/gpu/GrDirectContext.h" #include "include/gpu/gl/GrGLInterface.h" #include "include/gpu/gl/GrGLTypes.h" #include #include #endif #ifndef SK_NO_FONTS #include "include/core/SkFont.h" #include "include/core/SkFontMgr.h" #include "include/core/SkFontTypes.h" #endif #ifdef SK_INCLUDE_PARAGRAPH #include "modules/skparagraph/include/Paragraph.h" #endif #ifdef SK_INCLUDE_PATHOPS #include "include/pathops/SkPathOps.h" #endif #ifndef SK_NO_FONTS sk_sp SkFontMgr_New_Custom_Data(const uint8_t** datas, const size_t* sizes, int n); #endif struct OptionalMatrix : SkMatrix { OptionalMatrix(uintptr_t mPtr) { if (mPtr) { const SkScalar* nineMatrixValues = reinterpret_cast(mPtr); this->set9(nineMatrixValues); } } }; SkColor4f ptrToSkColor4f(uintptr_t /* float* */ cPtr) { float* fourFloats = reinterpret_cast(cPtr); SkColor4f color; memcpy(&color, fourFloats, 4 * sizeof(float)); return color; } SkRRect ptrToSkRRect(uintptr_t /* float* */ fPtr) { // In order, these floats should be 4 floats for the rectangle // (left, top, right, bottom) and then 8 floats for the radii // (upper left, upper right, lower right, lower left). const SkScalar* twelveFloats = reinterpret_cast(fPtr); const SkRect rect = reinterpret_cast(twelveFloats)[0]; const SkVector* radiiValues = reinterpret_cast(twelveFloats + 4); SkRRect rr; rr.setRectRadii(rect, radiiValues); return rr; } // Surface creation structs and helpers struct SimpleImageInfo { int width; int height; SkColorType colorType; SkAlphaType alphaType; sk_sp colorSpace; }; SkImageInfo toSkImageInfo(const SimpleImageInfo& sii) { return SkImageInfo::Make(sii.width, sii.height, sii.colorType, sii.alphaType, sii.colorSpace); } #ifdef SK_GL // Set the pixel format based on the colortype. // These degrees of freedom are removed from canvaskit only to keep the interface simpler. struct ColorSettings { ColorSettings(sk_sp colorSpace) { if (colorSpace == nullptr || colorSpace->isSRGB()) { colorType = kRGBA_8888_SkColorType; pixFormat = GL_RGBA8; } else { colorType = kRGBA_F16_SkColorType; pixFormat = GL_RGBA16F; } }; SkColorType colorType; GrGLenum pixFormat; }; sk_sp MakeGrContext(EMSCRIPTEN_WEBGL_CONTEXT_HANDLE context) { EMSCRIPTEN_RESULT r = emscripten_webgl_make_context_current(context); if (r < 0) { printf("failed to make webgl context current %d\n", r); return nullptr; } // setup interface auto interface = GrGLMakeNativeInterface(); // setup context return GrDirectContext::MakeGL(interface); } sk_sp MakeOnScreenGLSurface(sk_sp dContext, int width, int height, sk_sp colorSpace) { // WebGL should already be clearing the color and stencil buffers, but do it again here to // ensure Skia receives them in the expected state. glBindFramebuffer(GL_FRAMEBUFFER, 0); glClearColor(0, 0, 0, 0); glClearStencil(0); glClear(GL_COLOR_BUFFER_BIT | GL_STENCIL_BUFFER_BIT); dContext->resetContext(kRenderTarget_GrGLBackendState | kMisc_GrGLBackendState); // The on-screen canvas is FBO 0. Wrap it in a Skia render target so Skia can render to it. GrGLFramebufferInfo info; info.fFBOID = 0; GrGLint sampleCnt; glGetIntegerv(GL_SAMPLES, &sampleCnt); GrGLint stencil; glGetIntegerv(GL_STENCIL_BITS, &stencil); const auto colorSettings = ColorSettings(colorSpace); info.fFormat = colorSettings.pixFormat; GrBackendRenderTarget target(width, height, sampleCnt, stencil, info); sk_sp surface(SkSurface::MakeFromBackendRenderTarget(dContext.get(), target, kBottomLeft_GrSurfaceOrigin, colorSettings.colorType, colorSpace, nullptr)); return surface; } sk_sp MakeRenderTarget(sk_sp dContext, int width, int height) { SkImageInfo info = SkImageInfo::MakeN32(width, height, SkAlphaType::kPremul_SkAlphaType); sk_sp surface(SkSurface::MakeRenderTarget(dContext.get(), SkBudgeted::kYes, info, 0, kBottomLeft_GrSurfaceOrigin, nullptr, true)); return surface; } sk_sp MakeRenderTarget(sk_sp dContext, SimpleImageInfo sii) { sk_sp surface(SkSurface::MakeRenderTarget(dContext.get(), SkBudgeted::kYes, toSkImageInfo(sii), 0, kBottomLeft_GrSurfaceOrigin, nullptr, true)); return surface; } #endif //======================================================================================== // Path things //======================================================================================== // All these Apply* methods are simple wrappers to avoid returning an object. // The default WASM bindings produce code that will leak if a return value // isn't assigned to a JS variable and has delete() called on it. // These Apply methods, combined with the smarter binding code allow for chainable // commands that don't leak if the return value is ignored (i.e. when used intuitively). void ApplyAddPath(SkPath& orig, const SkPath& newPath, SkScalar scaleX, SkScalar skewX, SkScalar transX, SkScalar skewY, SkScalar scaleY, SkScalar transY, SkScalar pers0, SkScalar pers1, SkScalar pers2, bool extendPath) { SkMatrix m = SkMatrix::MakeAll(scaleX, skewX , transX, skewY , scaleY, transY, pers0 , pers1 , pers2); orig.addPath(newPath, m, extendPath ? SkPath::kExtend_AddPathMode : SkPath::kAppend_AddPathMode); } void ApplyArcToTangent(SkPath& p, SkScalar x1, SkScalar y1, SkScalar x2, SkScalar y2, SkScalar radius) { p.arcTo(x1, y1, x2, y2, radius); } void ApplyArcToArcSize(SkPath& orig, SkScalar rx, SkScalar ry, SkScalar xAxisRotate, bool useSmallArc, bool ccw, SkScalar x, SkScalar y) { auto arcSize = useSmallArc ? SkPath::ArcSize::kSmall_ArcSize : SkPath::ArcSize::kLarge_ArcSize; auto sweep = ccw ? SkPathDirection::kCCW : SkPathDirection::kCW; orig.arcTo(rx, ry, xAxisRotate, arcSize, sweep, x, y); } void ApplyRArcToArcSize(SkPath& orig, SkScalar rx, SkScalar ry, SkScalar xAxisRotate, bool useSmallArc, bool ccw, SkScalar dx, SkScalar dy) { auto arcSize = useSmallArc ? SkPath::ArcSize::kSmall_ArcSize : SkPath::ArcSize::kLarge_ArcSize; auto sweep = ccw ? SkPathDirection::kCCW : SkPathDirection::kCW; orig.rArcTo(rx, ry, xAxisRotate, arcSize, sweep, dx, dy); } void ApplyClose(SkPath& p) { p.close(); } void ApplyConicTo(SkPath& p, SkScalar x1, SkScalar y1, SkScalar x2, SkScalar y2, SkScalar w) { p.conicTo(x1, y1, x2, y2, w); } void ApplyRConicTo(SkPath& p, SkScalar dx1, SkScalar dy1, SkScalar dx2, SkScalar dy2, SkScalar w) { p.rConicTo(dx1, dy1, dx2, dy2, w); } void ApplyCubicTo(SkPath& p, SkScalar x1, SkScalar y1, SkScalar x2, SkScalar y2, SkScalar x3, SkScalar y3) { p.cubicTo(x1, y1, x2, y2, x3, y3); } void ApplyRCubicTo(SkPath& p, SkScalar dx1, SkScalar dy1, SkScalar dx2, SkScalar dy2, SkScalar dx3, SkScalar dy3) { p.rCubicTo(dx1, dy1, dx2, dy2, dx3, dy3); } void ApplyLineTo(SkPath& p, SkScalar x, SkScalar y) { p.lineTo(x, y); } void ApplyRLineTo(SkPath& p, SkScalar dx, SkScalar dy) { p.rLineTo(dx, dy); } void ApplyMoveTo(SkPath& p, SkScalar x, SkScalar y) { p.moveTo(x, y); } void ApplyRMoveTo(SkPath& p, SkScalar dx, SkScalar dy) { p.rMoveTo(dx, dy); } void ApplyReset(SkPath& p) { p.reset(); } void ApplyRewind(SkPath& p) { p.rewind(); } void ApplyQuadTo(SkPath& p, SkScalar x1, SkScalar y1, SkScalar x2, SkScalar y2) { p.quadTo(x1, y1, x2, y2); } void ApplyRQuadTo(SkPath& p, SkScalar dx1, SkScalar dy1, SkScalar dx2, SkScalar dy2) { p.rQuadTo(dx1, dy1, dx2, dy2); } void ApplyTransform(SkPath& orig, SkScalar scaleX, SkScalar skewX, SkScalar transX, SkScalar skewY, SkScalar scaleY, SkScalar transY, SkScalar pers0, SkScalar pers1, SkScalar pers2) { SkMatrix m = SkMatrix::MakeAll(scaleX, skewX , transX, skewY , scaleY, transY, pers0 , pers1 , pers2); orig.transform(m); } #ifdef SK_INCLUDE_PATHOPS bool ApplySimplify(SkPath& path) { return Simplify(path, &path); } bool ApplyPathOp(SkPath& pathOne, const SkPath& pathTwo, SkPathOp op) { return Op(pathOne, pathTwo, op, &pathOne); } SkPathOrNull MakePathFromOp(const SkPath& pathOne, const SkPath& pathTwo, SkPathOp op) { SkPath out; if (Op(pathOne, pathTwo, op, &out)) { return emscripten::val(out); } return emscripten::val::null(); } #endif JSString ToSVGString(const SkPath& path) { SkString s; SkParsePath::ToSVGString(path, &s); return emscripten::val(s.c_str()); } SkPathOrNull MakePathFromSVGString(std::string str) { SkPath path; if (SkParsePath::FromSVGString(str.c_str(), &path)) { return emscripten::val(path); } return emscripten::val::null(); } SkPath CopyPath(const SkPath& a) { SkPath copy(a); return copy; } bool Equals(const SkPath& a, const SkPath& b) { return a == b; } // ================================================================================= // Creating/Exporting Paths with cmd arrays // ================================================================================= static const int MOVE = 0; static const int LINE = 1; static const int QUAD = 2; static const int CONIC = 3; static const int CUBIC = 4; static const int CLOSE = 5; JSArray ToCmds(const SkPath& path) { JSArray cmds = emscripten::val::array(); for (auto [verb, pts, w] : SkPathPriv::Iterate(path)) { JSArray cmd = emscripten::val::array(); switch (verb) { case SkPathVerb::kMove: cmd.call("push", MOVE, pts[0].x(), pts[0].y()); break; case SkPathVerb::kLine: cmd.call("push", LINE, pts[1].x(), pts[1].y()); break; case SkPathVerb::kQuad: cmd.call("push", QUAD, pts[1].x(), pts[1].y(), pts[2].x(), pts[2].y()); break; case SkPathVerb::kConic: cmd.call("push", CONIC, pts[1].x(), pts[1].y(), pts[2].x(), pts[2].y(), *w); break; case SkPathVerb::kCubic: cmd.call("push", CUBIC, pts[1].x(), pts[1].y(), pts[2].x(), pts[2].y(), pts[3].x(), pts[3].y()); break; case SkPathVerb::kClose: cmd.call("push", CLOSE); break; } cmds.call("push", cmd); } return cmds; } // This type signature is a mess, but it's necessary. See, we can't use "bind" (EMSCRIPTEN_BINDINGS) // and pointers to primitive types (Only bound types like SkPoint). We could if we used // cwrap (see https://becominghuman.ai/passing-and-returning-webassembly-array-parameters-a0f572c65d97) // but that requires us to stick to C code and, AFAIK, doesn't allow us to return nice things like // SkPath or SkOpBuilder. // // So, basically, 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. SkPathOrNull MakePathFromCmds(uintptr_t /* float* */ cptr, int numCmds) { const auto* cmds = reinterpret_cast(cptr); SkPath path; float x1, y1, x2, y2, x3, y3; // if there are not enough arguments, bail with the path we've constructed so far. #define CHECK_NUM_ARGS(n) \ if ((i + n) > numCmds) { \ SkDebugf("Not enough args to match the verbs. Saw %d commands\n", numCmds); \ return emscripten::val::null(); \ } for(int i = 0; i < numCmds;){ switch (sk_float_floor2int(cmds[i++])) { case MOVE: CHECK_NUM_ARGS(2); x1 = cmds[i++], y1 = cmds[i++]; path.moveTo(x1, y1); break; case LINE: CHECK_NUM_ARGS(2); x1 = cmds[i++], y1 = cmds[i++]; path.lineTo(x1, y1); break; case QUAD: CHECK_NUM_ARGS(4); x1 = cmds[i++], y1 = cmds[i++]; x2 = cmds[i++], y2 = cmds[i++]; path.quadTo(x1, y1, x2, y2); break; case CONIC: CHECK_NUM_ARGS(5); x1 = cmds[i++], y1 = cmds[i++]; x2 = cmds[i++], y2 = cmds[i++]; x3 = cmds[i++]; // weight path.conicTo(x1, y1, x2, y2, x3); break; case CUBIC: CHECK_NUM_ARGS(6); x1 = cmds[i++], y1 = cmds[i++]; x2 = cmds[i++], y2 = cmds[i++]; x3 = cmds[i++], y3 = cmds[i++]; path.cubicTo(x1, y1, x2, y2, x3, y3); break; case CLOSE: path.close(); break; default: SkDebugf(" path: UNKNOWN command %f, aborting dump...\n", cmds[i-1]); return emscripten::val::null(); } } #undef CHECK_NUM_ARGS return emscripten::val(path); } void PathAddVerbsPointsWeights(SkPath& path, uintptr_t /* uint8_t* */ verbsPtr, int numVerbs, uintptr_t /* float* */ ptsPtr, int numPts, uintptr_t /* float* */ wtsPtr, int numWts) { const uint8_t* verbs = reinterpret_cast(verbsPtr); const float* pts = reinterpret_cast(ptsPtr); const float* weights = reinterpret_cast(wtsPtr); #define CHECK_NUM_POINTS(n) \ if ((ptIdx + n) > numPts) { \ SkDebugf("Not enough points to match the verbs. Saw %d points\n", numPts); \ return; \ } #define CHECK_NUM_WEIGHTS(n) \ if ((wtIdx + n) > numWts) { \ SkDebugf("Not enough weights to match the verbs. Saw %d weights\n", numWts); \ return; \ } path.incReserve(numPts); int ptIdx = 0; int wtIdx = 0; for (int v = 0; v < numVerbs; ++v) { switch (verbs[v]) { case MOVE: CHECK_NUM_POINTS(2); path.moveTo(pts[ptIdx], pts[ptIdx+1]); ptIdx += 2; break; case LINE: CHECK_NUM_POINTS(2); path.lineTo(pts[ptIdx], pts[ptIdx+1]); ptIdx += 2; break; case QUAD: CHECK_NUM_POINTS(4); path.quadTo(pts[ptIdx], pts[ptIdx+1], pts[ptIdx+2], pts[ptIdx+3]); ptIdx += 4; break; case CONIC: CHECK_NUM_POINTS(4); CHECK_NUM_WEIGHTS(1); path.conicTo(pts[ptIdx], pts[ptIdx+1], pts[ptIdx+2], pts[ptIdx+3], weights[wtIdx]); ptIdx += 4; wtIdx++; break; case CUBIC: CHECK_NUM_POINTS(6); path.cubicTo(pts[ptIdx ], pts[ptIdx+1], pts[ptIdx+2], pts[ptIdx+3], pts[ptIdx+4], pts[ptIdx+5]); ptIdx += 6; break; case CLOSE: path.close(); break; } } #undef CHECK_NUM_POINTS #undef CHECK_NUM_WEIGHTS } SkPath MakePathFromVerbsPointsWeights(uintptr_t /* uint8_t* */ verbsPtr, int numVerbs, uintptr_t ptsPtr, int numPts, uintptr_t wtsPtr, int numWts) { SkPath path; PathAddVerbsPointsWeights(path, verbsPtr, numVerbs, ptsPtr, numPts, wtsPtr, numWts); return path; } //======================================================================================== // Path Effects //======================================================================================== bool ApplyDash(SkPath& path, SkScalar on, SkScalar off, SkScalar phase) { SkScalar intervals[] = { on, off }; auto pe = SkDashPathEffect::Make(intervals, 2, phase); if (!pe) { SkDebugf("Invalid args to dash()\n"); return false; } SkStrokeRec rec(SkStrokeRec::InitStyle::kHairline_InitStyle); if (pe->filterPath(&path, path, &rec, nullptr)) { return true; } SkDebugf("Could not make dashed path\n"); return false; } bool ApplyTrim(SkPath& path, SkScalar startT, SkScalar stopT, bool isComplement) { auto mode = isComplement ? SkTrimPathEffect::Mode::kInverted : SkTrimPathEffect::Mode::kNormal; auto pe = SkTrimPathEffect::Make(startT, stopT, mode); if (!pe) { SkDebugf("Invalid args to trim(): startT and stopT must be in [0,1]\n"); return false; } SkStrokeRec rec(SkStrokeRec::InitStyle::kHairline_InitStyle); if (pe->filterPath(&path, path, &rec, nullptr)) { return true; } SkDebugf("Could not trim path\n"); return false; } struct StrokeOpts { // Default values are set in interface.js which allows clients // to set any number of them. Otherwise, the binding code complains if // any are omitted. SkScalar width; SkScalar miter_limit; SkPaint::Join join; SkPaint::Cap cap; float precision; }; bool ApplyStroke(SkPath& path, StrokeOpts opts) { SkPaint p; p.setStyle(SkPaint::kStroke_Style); p.setStrokeCap(opts.cap); p.setStrokeJoin(opts.join); p.setStrokeWidth(opts.width); p.setStrokeMiter(opts.miter_limit); return p.getFillPath(path, &path, nullptr, opts.precision); } // This function is private, we call it in interface.js void computeTonalColors(uintptr_t cPtrAmbi /* float * */, uintptr_t cPtrSpot /* float * */) { // private methods accepting colors take pointers to floats already copied into wasm memory. float* ambiFloats = reinterpret_cast(cPtrAmbi); float* spotFloats = reinterpret_cast(cPtrSpot); SkColor4f ambiColor = { ambiFloats[0], ambiFloats[1], ambiFloats[2], ambiFloats[3]}; SkColor4f spotColor = { spotFloats[0], spotFloats[1], spotFloats[2], spotFloats[3]}; // This function takes SkColor SkColor resultAmbi, resultSpot; SkShadowUtils::ComputeTonalColors( ambiColor.toSkColor(), spotColor.toSkColor(), &resultAmbi, &resultSpot); // Convert back to color4f const SkColor4f ambi4f = SkColor4f::FromColor(resultAmbi); const SkColor4f spot4f = SkColor4f::FromColor(resultSpot); // Re-use the caller's allocated memory to hold the result. memcpy(ambiFloats, ambi4f.vec(), 4 * sizeof(SkScalar)); memcpy(spotFloats, spot4f.vec(), 4 * sizeof(SkScalar)); } #ifdef SK_INCLUDE_RUNTIME_EFFECT struct RuntimeEffectUniform { int columns; int rows; int slot; // the index into the uniforms array that this uniform begins. }; RuntimeEffectUniform fromUniform(const SkRuntimeEffect::Uniform& u) { RuntimeEffectUniform su; su.rows = u.count; // arrayLength su.columns = 1; switch (u.type) { case SkRuntimeEffect::Uniform::Type::kFloat: break; case SkRuntimeEffect::Uniform::Type::kFloat2: su.columns = 2; break; case SkRuntimeEffect::Uniform::Type::kFloat3: su.columns = 3; break; case SkRuntimeEffect::Uniform::Type::kFloat4: su.columns = 4; break; case SkRuntimeEffect::Uniform::Type::kFloat2x2: su.columns = 2; su.rows *= 2; break; case SkRuntimeEffect::Uniform::Type::kFloat3x3: su.columns = 3; su.rows *= 3; break; case SkRuntimeEffect::Uniform::Type::kFloat4x4: su.columns = 4; su.rows *= 4; break; } su.slot = u.offset / sizeof(float); return su; } #endif // These objects have private destructors / delete methods - I don't think // we need to do anything other than tell emscripten to do nothing. namespace emscripten { namespace internal { template void raw_destructor(ClassType *); template<> void raw_destructor(SkContourMeasure *ptr) { } template<> void raw_destructor(SkVertices *ptr) { } #ifndef SK_NO_FONTS template<> void raw_destructor(SkTextBlob *ptr) { } template<> void raw_destructor(SkTypeface *ptr) { } #endif } } // toBytes returns a Uint8Array that has a copy of the data in the given SkData. Uint8Array toBytes(sk_sp data) { // By making the copy using the JS transliteration, we don't risk the SkData object being // cleaned up before we make the copy. return emscripten::val( // https://emscripten.org/docs/porting/connecting_cpp_and_javascript/embind.html#memory-views typed_memory_view(data->size(), data->bytes()) ).call("slice"); // slice with no args makes a copy of the memory view. } // Some signatures below have uintptr_t instead of a pointer to a primitive // type (e.g. SkScalar). This is necessary because we can't use "bind" (EMSCRIPTEN_BINDINGS) // and pointers to primitive types (Only bound types like SkPoint). We could if we used // cwrap (see https://becominghuman.ai/passing-and-returning-webassembly-array-parameters-a0f572c65d97) // but that requires us to stick to C code and, AFAIK, doesn't allow us to return nice things like // SkPath or SkCanvas. // // So, basically, 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. EMSCRIPTEN_BINDINGS(Skia) { #ifdef SK_GL function("currentContext", &emscripten_webgl_get_current_context); function("setCurrentContext", &emscripten_webgl_make_context_current); function("MakeGrContext", &MakeGrContext); function("MakeOnScreenGLSurface", &MakeOnScreenGLSurface); function("MakeRenderTarget", select_overload(sk_sp, int, int)>(&MakeRenderTarget)); function("MakeRenderTarget", select_overload(sk_sp, SimpleImageInfo)>(&MakeRenderTarget)); constant("gpu", true); #endif function("getDecodeCacheLimitBytes", &SkResourceCache::GetTotalByteLimit); function("setDecodeCacheLimitBytes", &SkResourceCache::SetTotalByteLimit); function("getDecodeCacheUsedBytes" , &SkResourceCache::GetTotalBytesUsed); function("_computeTonalColors", &computeTonalColors); function("_decodeAnimatedImage", optional_override([](uintptr_t /* uint8_t* */ iptr, size_t length)->sk_sp { uint8_t* imgData = reinterpret_cast(iptr); auto bytes = SkData::MakeFromMalloc(imgData, length); auto aCodec = SkAndroidCodec::MakeFromData(std::move(bytes)); if (nullptr == aCodec) { return nullptr; } return SkAnimatedImage::Make(std::move(aCodec)); }), allow_raw_pointers()); function("_decodeImage", optional_override([](uintptr_t /* uint8_t* */ iptr, size_t length)->sk_sp { uint8_t* imgData = reinterpret_cast(iptr); sk_sp bytes = SkData::MakeFromMalloc(imgData, length); return SkImage::MakeFromEncoded(std::move(bytes)); }), allow_raw_pointers()); // These won't be called directly, there are corresponding JS helpers to deal with arrays. function("_MakeImage", optional_override([](SimpleImageInfo ii, uintptr_t /* uint8_t* */ pPtr, int plen, size_t rowBytes)->sk_sp { uint8_t* pixels = reinterpret_cast(pPtr); SkImageInfo info = toSkImageInfo(ii); sk_sp pixelData = SkData::MakeFromMalloc(pixels, plen); return SkImage::MakeRasterData(info, pixelData, rowBytes); }), allow_raw_pointers()); function("_getShadowLocalBounds", optional_override([]( uintptr_t /* float* */ ctmPtr, const SkPath& path, uintptr_t /* float* */ zPlaneParamPtr, uintptr_t /* float* */ lightPosPtr, SkScalar lightRadius, uint32_t flags, uintptr_t /* SkRect* */ outPtr) -> bool { SkMatrix ctm; const SkScalar* nineMatrixValues = reinterpret_cast(ctmPtr); ctm.set9(nineMatrixValues); const SkVector3* zPlaneParams = reinterpret_cast(zPlaneParamPtr); const SkVector3* lightPos = reinterpret_cast(lightPosPtr); SkRect* outputBounds = reinterpret_cast(outPtr); return SkShadowUtils::GetLocalBounds(ctm, path, *zPlaneParams, *lightPos, lightRadius, flags, outputBounds); })); #ifdef SK_SERIALIZE_SKP function("_MakePicture", optional_override([](uintptr_t /* unint8_t* */ dPtr, size_t bytes)->sk_sp { uint8_t* d = reinterpret_cast(dPtr); sk_sp data = SkData::MakeFromMalloc(d, bytes); return SkPicture::MakeFromData(data.get(), nullptr); }), allow_raw_pointers()); #endif #ifdef SK_GL class_("GrDirectContext") .smart_ptr>("sk_sp") .function("getResourceCacheLimitBytes", optional_override([](GrDirectContext& self)->size_t { int maxResources = 0;// ignored size_t currMax = 0; self.getResourceCacheLimits(&maxResources, &currMax); return currMax; })) .function("getResourceCacheUsageBytes", optional_override([](GrDirectContext& self)->size_t { int usedResources = 0;// ignored size_t currUsage = 0; self.getResourceCacheUsage(&usedResources, &currUsage); return currUsage; })) .function("releaseResourcesAndAbandonContext", &GrDirectContext::releaseResourcesAndAbandonContext) .function("setResourceCacheLimitBytes", optional_override([](GrDirectContext& self, size_t maxResourceBytes)->void { int maxResources = 0; size_t currMax = 0; // ignored self.getResourceCacheLimits(&maxResources, &currMax); self.setResourceCacheLimits(maxResources, maxResourceBytes); })); #endif class_("AnimatedImage") .smart_ptr>("sk_sp") .function("decodeNextFrame", &SkAnimatedImage::decodeNextFrame) // Deprecated; prefer makeImageAtCurrentFrame .function("getCurrentFrame", &SkAnimatedImage::getCurrentFrame) .function("getFrameCount", &SkAnimatedImage::getFrameCount) .function("getRepetitionCount", &SkAnimatedImage::getRepetitionCount) .function("height", optional_override([](SkAnimatedImage& self)->int32_t { // getBounds returns an SkRect, but internally, the width and height are ints. return SkScalarFloorToInt(self.getBounds().height()); })) .function("makeImageAtCurrentFrame", &SkAnimatedImage::getCurrentFrame) .function("reset", &SkAnimatedImage::reset) .function("width", optional_override([](SkAnimatedImage& self)->int32_t { return SkScalarFloorToInt(self.getBounds().width()); })); class_("Canvas") .constructor<>() .function("_clear", optional_override([](SkCanvas& self, uintptr_t /* float* */ cPtr) { self.clear(ptrToSkColor4f(cPtr)); })) .function("clipPath", select_overload(&SkCanvas::clipPath)) .function("_clipRRect", optional_override([](SkCanvas& self, uintptr_t /* float* */ fPtr, SkClipOp op, bool doAntiAlias) { self.clipRRect(ptrToSkRRect(fPtr), op, doAntiAlias); })) .function("_clipRect", optional_override([](SkCanvas& self, uintptr_t /* float* */ fPtr, SkClipOp op, bool doAntiAlias) { const SkRect* rect = reinterpret_cast(fPtr); self.clipRect(*rect, op, doAntiAlias); })) .function("_concat", optional_override([](SkCanvas& self, uintptr_t /* SkScalar* */ mPtr) { //TODO(skbug.com/10108): make the JS side be column major. const SkScalar* sixteenMatrixValues = reinterpret_cast(mPtr); SkM44 m = SkM44::RowMajor(sixteenMatrixValues); self.concat(m); })) .function("_drawArc", optional_override([](SkCanvas& self, uintptr_t /* float* */ fPtr, SkScalar startAngle, SkScalar sweepAngle, bool useCenter, const SkPaint& paint) { const SkRect* oval = reinterpret_cast(fPtr); self.drawArc(*oval, startAngle, sweepAngle, useCenter, paint); })) // _drawAtlas takes an array of SkColor. There is no SkColor4f override. // TODO: take sampling as an explicit parameter from the caller .function("_drawAtlas", optional_override([](SkCanvas& self, const sk_sp& atlas, uintptr_t /* SkRSXform* */ xptr, uintptr_t /* SkRect* */ rptr, uintptr_t /* SkColor* */ cptr, int count, SkBlendMode mode, const SkPaint* paint)->void { const SkRSXform* dstXforms = reinterpret_cast(xptr); const SkRect* srcRects = reinterpret_cast(rptr); const SkColor* colors = nullptr; if (cptr) { colors = reinterpret_cast(cptr); } SkSamplingOptions sampling(SkFilterMode::kLinear); self.drawAtlas(atlas.get(), dstXforms, srcRects, colors, count, mode, sampling, nullptr, paint); }), allow_raw_pointers()) .function("drawCircle", select_overload(&SkCanvas::drawCircle)) .function("_drawColor", optional_override([](SkCanvas& self, uintptr_t /* float* */ cPtr) { self.drawColor(ptrToSkColor4f(cPtr)); })) .function("_drawColor", optional_override([](SkCanvas& self, uintptr_t /* float* */ cPtr, SkBlendMode mode) { self.drawColor(ptrToSkColor4f(cPtr), mode); })) .function("drawColorInt", optional_override([](SkCanvas& self, SkColor color) { self.drawColor(color); })) .function("drawColorInt", optional_override([](SkCanvas& self, SkColor color, SkBlendMode mode) { self.drawColor(color, mode); })) .function("_drawDRRect", optional_override([](SkCanvas& self, uintptr_t /* float* */ outerPtr, uintptr_t /* float* */ innerPtr, const SkPaint& paint) { self.drawDRRect(ptrToSkRRect(outerPtr), ptrToSkRRect(innerPtr), paint); })) // TODO: deprecate this version, and require sampling .function("drawImage", optional_override([](SkCanvas& self, const sk_sp& image, SkScalar x, SkScalar y, const SkPaint* paint) { SkSamplingOptions sampling(paint ? paint->getFilterQuality() : kNone_SkFilterQuality); self.drawImage(image.get(), x, y, sampling, paint); }), allow_raw_pointers()) .function("drawImageCubic", optional_override([](SkCanvas& self, const sk_sp& img, SkScalar left, SkScalar top, float B, float C, // See SkSamplingOptions.h for docs. const SkPaint* paint)->void { self.drawImage(img.get(), left, top, SkSamplingOptions({B, C}), paint); }), allow_raw_pointers()) .function("drawImageOptions", optional_override([](SkCanvas& self, const sk_sp& img, SkScalar left, SkScalar top, SkFilterMode filter, SkMipmapMode mipmap, const SkPaint* paint)->void { self.drawImage(img.get(), left, top, {filter, mipmap}, paint); }), allow_raw_pointers()) .function("drawImageAtCurrentFrame", optional_override([](SkCanvas& self, sk_sp aImg, SkScalar left, SkScalar top, const SkPaint* paint)->void { auto img = aImg->getCurrentFrame(); SkSamplingOptions sampling(paint ? paint->getFilterQuality() : kNone_SkFilterQuality); self.drawImage(img, left, top, sampling, paint); }), allow_raw_pointers()) .function("_drawImageNine", optional_override([](SkCanvas& self, const sk_sp& image, uintptr_t /* int* */ centerPtr, uintptr_t /* float* */ dstPtr, SkFilterMode filter, const SkPaint* paint)->void { const SkIRect* center = reinterpret_cast(centerPtr); const SkRect* dst = reinterpret_cast(dstPtr); self.drawImageNine(image.get(), *center, *dst, filter, paint); }), allow_raw_pointers()) // TODO: deprecate this version, and require sampling .function("_drawImageRect", optional_override([](SkCanvas& self, const sk_sp& image, uintptr_t /* float* */ srcPtr, uintptr_t /* float* */ dstPtr, const SkPaint* paint, bool fastSample)->void { const SkRect* src = reinterpret_cast(srcPtr); const SkRect* dst = reinterpret_cast(dstPtr); SkSamplingOptions sampling(paint ? paint->getFilterQuality() : kNone_SkFilterQuality); self.drawImageRect(image, *src, *dst, sampling, paint, fastSample ? SkCanvas::kFast_SrcRectConstraint: SkCanvas::kStrict_SrcRectConstraint); }), allow_raw_pointers()) .function("_drawImageRectCubic", optional_override([](SkCanvas& self, const sk_sp& image, uintptr_t /* float* */ srcPtr, uintptr_t /* float* */ dstPtr, float B, float C, // See SkSamplingOptions.h for docs. const SkPaint* paint)->void { const SkRect* src = reinterpret_cast(srcPtr); const SkRect* dst = reinterpret_cast(dstPtr); auto constraint = SkCanvas::kStrict_SrcRectConstraint; // TODO: get from caller self.drawImageRect(image.get(), *src, *dst, SkSamplingOptions({B, C}), paint, constraint); }), allow_raw_pointers()) .function("_drawImageRectOptions", optional_override([](SkCanvas& self, const sk_sp& image, uintptr_t /* float* */ srcPtr, uintptr_t /* float* */ dstPtr, SkFilterMode filter, SkMipmapMode mipmap, const SkPaint* paint)->void { const SkRect* src = reinterpret_cast(srcPtr); const SkRect* dst = reinterpret_cast(dstPtr); auto constraint = SkCanvas::kStrict_SrcRectConstraint; // TODO: get from caller self.drawImageRect(image.get(), *src, *dst, {filter, mipmap}, paint, constraint); }), allow_raw_pointers()) .function("drawLine", select_overload(&SkCanvas::drawLine)) .function("_drawOval", optional_override([](SkCanvas& self, uintptr_t /* float* */ fPtr, const SkPaint& paint)->void { const SkRect* oval = reinterpret_cast(fPtr); self.drawOval(*oval, paint); })) .function("drawPaint", &SkCanvas::drawPaint) #ifdef SK_INCLUDE_PARAGRAPH .function("drawParagraph", optional_override([](SkCanvas& self, skia::textlayout::Paragraph* p, SkScalar x, SkScalar y) { p->paint(&self, x, y); }), allow_raw_pointers()) #endif .function("drawPath", &SkCanvas::drawPath) // Of note, picture is *not* what is colloquially thought of as a "picture", what we call // a bitmap. An SkPicture is a series of draw commands. .function("drawPicture", select_overload&)>(&SkCanvas::drawPicture)) .function("_drawPoints", optional_override([](SkCanvas& self, SkCanvas::PointMode mode, uintptr_t /* SkPoint* */ pptr, int count, SkPaint& paint)->void { const SkPoint* pts = reinterpret_cast(pptr); self.drawPoints(mode, count, pts, paint); })) .function("_drawRRect",optional_override([](SkCanvas& self, uintptr_t /* float* */ fPtr, const SkPaint& paint) { self.drawRRect(ptrToSkRRect(fPtr), paint); })) .function("_drawRect", optional_override([](SkCanvas& self, uintptr_t /* float* */ fPtr, const SkPaint& paint)->void { const SkRect* rect = reinterpret_cast(fPtr); self.drawRect(*rect, paint); })) .function("drawRect4f", optional_override([](SkCanvas& self, SkScalar left, SkScalar top, SkScalar right, SkScalar bottom, const SkPaint& paint)->void { const SkRect rect = SkRect::MakeLTRB(left, top, right, bottom); self.drawRect(rect, paint); })) .function("_drawShadow", optional_override([](SkCanvas& self, const SkPath& path, uintptr_t /* float* */ zPlaneParamPtr, uintptr_t /* float* */ lightPosPtr, SkScalar lightRadius, uintptr_t /* float* */ ambientColorPtr, uintptr_t /* float* */ spotColorPtr, uint32_t flags) { const SkVector3* zPlaneParams = reinterpret_cast(zPlaneParamPtr); const SkVector3* lightPos = reinterpret_cast(lightPosPtr); SkShadowUtils::DrawShadow(&self, path, *zPlaneParams, *lightPos, lightRadius, ptrToSkColor4f(ambientColorPtr).toSkColor(), ptrToSkColor4f(spotColorPtr).toSkColor(), flags); })) #ifndef SK_NO_FONTS .function("_drawSimpleText", optional_override([](SkCanvas& self, uintptr_t /* char* */ sptr, size_t len, SkScalar x, SkScalar y, const SkFont& font, const SkPaint& paint) { const char* str = reinterpret_cast(sptr); self.drawSimpleText(str, len, SkTextEncoding::kUTF8, x, y, font, paint); })) .function("drawTextBlob", select_overload&, SkScalar, SkScalar, const SkPaint&)>(&SkCanvas::drawTextBlob)) #endif .function("drawVertices", select_overload&, SkBlendMode, const SkPaint&)>(&SkCanvas::drawVertices)) .function("_findMarkedCTM", optional_override([](SkCanvas& self, std::string marker, uintptr_t /* SkScalar* */ mPtr) -> bool { SkScalar* sixteenMatrixValues = reinterpret_cast(mPtr); if (!sixteenMatrixValues) { return false; // matrix cannot be null } SkM44 m; if (self.findMarkedCTM(marker.c_str(), &m)) { m.getRowMajor(sixteenMatrixValues); return true; } return false; })) .function("flush", &SkCanvas::flush) // Deprecated - will be removed // 4x4 matrix functions // Just like with getTotalMatrix, we allocate the buffer for the 16 floats to go in from // interface.js, so it can also free them when its done. .function("_getLocalToDevice", optional_override([](const SkCanvas& self, uintptr_t /* SkScalar* */ mPtr) { SkScalar* sixteenMatrixValues = reinterpret_cast(mPtr); if (!sixteenMatrixValues) { return; // matrix cannot be null } SkM44 m = self.getLocalToDevice(); m.getRowMajor(sixteenMatrixValues); })) .function("getSaveCount", &SkCanvas::getSaveCount) // We allocate room for the matrix from the JS side and free it there so as to not have // an awkward moment where we malloc something here and "just know" to free it on the // JS side. .function("_getTotalMatrix", optional_override([](const SkCanvas& self, uintptr_t /* uint8_t* */ mPtr) { SkScalar* nineMatrixValues = reinterpret_cast(mPtr); if (!nineMatrixValues) { return; // matrix cannot be null } SkMatrix m = self.getTotalMatrix(); m.get9(nineMatrixValues); })) .function("makeSurface", optional_override([](SkCanvas& self, SimpleImageInfo sii)->sk_sp { return self.makeSurface(toSkImageInfo(sii), nullptr); }), allow_raw_pointers()) .function("markCTM", optional_override([](SkCanvas& self, std::string marker) { self.markCTM(marker.c_str()); })) .function("_readPixels", optional_override([](SkCanvas& self, SimpleImageInfo di, uintptr_t /* uint8_t* */ pPtr, size_t dstRowBytes, int srcX, int srcY) { uint8_t* pixels = reinterpret_cast(pPtr); SkImageInfo dstInfo = toSkImageInfo(di); return self.readPixels(dstInfo, pixels, dstRowBytes, srcX, srcY); })) .function("restore", &SkCanvas::restore) .function("restoreToCount", &SkCanvas::restoreToCount) .function("rotate", select_overload(&SkCanvas::rotate)) .function("save", &SkCanvas::save) .function("_saveLayer", optional_override([](SkCanvas& self, const SkPaint* p, uintptr_t /* float* */ fPtr, const SkImageFilter* backdrop, SkCanvas::SaveLayerFlags flags)->int { SkRect* bounds = reinterpret_cast(fPtr); return self.saveLayer(SkCanvas::SaveLayerRec(bounds, p, backdrop, flags)); }), allow_raw_pointers()) .function("saveLayerPaint", optional_override([](SkCanvas& self, const SkPaint p)->int { return self.saveLayer(SkCanvas::SaveLayerRec(nullptr, &p, 0)); })) .function("scale", &SkCanvas::scale) .function("skew", &SkCanvas::skew) .function("translate", &SkCanvas::translate) .function("_writePixels", optional_override([](SkCanvas& self, SimpleImageInfo di, uintptr_t /* uint8_t* */ pPtr, size_t srcRowBytes, int dstX, int dstY) { uint8_t* pixels = reinterpret_cast(pPtr); SkImageInfo dstInfo = toSkImageInfo(di); return self.writePixels(dstInfo, pixels, srcRowBytes, dstX, dstY); })); class_("ColorFilter") .smart_ptr>("sk_sp>") .class_function("_MakeBlend", optional_override([](uintptr_t /* float* */ cPtr, SkBlendMode mode)->sk_sp { return SkColorFilters::Blend(ptrToSkColor4f(cPtr).toSkColor(), mode); })) .class_function("MakeCompose", &SkColorFilters::Compose) .class_function("MakeLerp", &SkColorFilters::Lerp) .class_function("MakeLinearToSRGBGamma", &SkColorFilters::LinearToSRGBGamma) .class_function("_makeMatrix", optional_override([](uintptr_t /* float* */ fPtr) { float* twentyFloats = reinterpret_cast(fPtr); return SkColorFilters::Matrix(twentyFloats); })) .class_function("MakeSRGBToLinearGamma", &SkColorFilters::SRGBToLinearGamma); class_("ContourMeasureIter") .constructor() .function("next", &SkContourMeasureIter::next); class_("ContourMeasure") .smart_ptr>("sk_sp>") .function("_getPosTan", optional_override([](SkContourMeasure& self, SkScalar distance, uintptr_t /* SkPoint* */ oPtr) -> void { SkPoint* pointAndVector = reinterpret_cast(oPtr); if (!self.getPosTan(distance, pointAndVector, pointAndVector + 1)) { SkDebugf("zero-length path in getPosTan\n"); } })) .function("getSegment", optional_override([](SkContourMeasure& self, SkScalar startD, SkScalar stopD, bool startWithMoveTo) -> SkPath { SkPath p; bool ok = self.getSegment(startD, stopD, &p, startWithMoveTo); if (ok) { return p; } return SkPath(); })) .function("isClosed", &SkContourMeasure::isClosed) .function("length", &SkContourMeasure::length); #ifndef SK_NO_FONTS class_("Font") .constructor<>() .constructor>() .constructor, SkScalar>() .constructor, SkScalar, SkScalar, SkScalar>() .function("_getGlyphWidthBounds", optional_override([](SkFont& self, uintptr_t /* SkGlyphID* */ gPtr, int numGlyphs, uintptr_t /* float* */ wPtr, uintptr_t /* float* */ rPtr, SkPaint* paint) { const SkGlyphID* glyphs = reinterpret_cast(gPtr); // On the JS side only one of these is set at a time for easier ergonomics. SkRect* outputRects = reinterpret_cast(rPtr); SkScalar* outputWidths = reinterpret_cast(wPtr); self.getWidthsBounds(glyphs, numGlyphs, outputWidths, outputRects, paint); }), allow_raw_pointers()) .function("_getGlyphIDs", optional_override([](SkFont& self, uintptr_t /* char* */ sptr, size_t strLen, size_t expectedCodePoints, uintptr_t /* SkGlyphID* */ iPtr) -> int { char* str = reinterpret_cast(sptr); SkGlyphID* glyphIDs = reinterpret_cast(iPtr); int actualCodePoints = self.textToGlyphs(str, strLen, SkTextEncoding::kUTF8, glyphIDs, expectedCodePoints); return actualCodePoints; })) .function("getScaleX", &SkFont::getScaleX) .function("getSize", &SkFont::getSize) .function("getSkewX", &SkFont::getSkewX) .function("getTypeface", &SkFont::getTypeface, allow_raw_pointers()) .function("setEdging", &SkFont::setEdging) .function("setEmbeddedBitmaps", &SkFont::setEmbeddedBitmaps) .function("setHinting", &SkFont::setHinting) .function("setLinearMetrics", &SkFont::setLinearMetrics) .function("setScaleX", &SkFont::setScaleX) .function("setSize", &SkFont::setSize) .function("setSkewX", &SkFont::setSkewX) .function("setSubpixel", &SkFont::setSubpixel) .function("setTypeface", &SkFont::setTypeface, allow_raw_pointers()); class_("FontMgr") .smart_ptr>("sk_sp") .class_function("_fromData", optional_override([](uintptr_t /* uint8_t** */ dPtr, uintptr_t /* size_t* */ sPtr, int numFonts)->sk_sp { auto datas = reinterpret_cast(dPtr); auto sizes = reinterpret_cast(sPtr); return SkFontMgr_New_Custom_Data(datas, sizes, numFonts); }), allow_raw_pointers()) .class_function("RefDefault", &SkFontMgr::RefDefault) .function("countFamilies", &SkFontMgr::countFamilies) .function("getFamilyName", optional_override([](SkFontMgr& self, int index)->JSString { if (index < 0 || index >= self.countFamilies()) { return emscripten::val::null(); } SkString s; self.getFamilyName(index, &s); return emscripten::val(s.c_str()); })) #ifdef SK_DEBUG .function("dumpFamilies", optional_override([](SkFontMgr& self) { int numFam = self.countFamilies(); SkDebugf("There are %d font families\n", numFam); for (int i = 0 ; i< numFam; i++) { SkString s; self.getFamilyName(i, &s); SkDebugf("\t%s\n", s.c_str()); } })) #endif .function("_makeTypefaceFromData", optional_override([](SkFontMgr& self, uintptr_t /* uint8_t* */ fPtr, int flen)->sk_sp { uint8_t* font = reinterpret_cast(fPtr); sk_sp fontData = SkData::MakeFromMalloc(font, flen); return self.makeFromData(fontData); }), allow_raw_pointers()); #endif // SK_NO_FONTS class_("Image") .smart_ptr>("sk_sp") // Note that this needs to be cleaned up with delete(). .function("getColorSpace", optional_override([](sk_sp self)->sk_sp { return self->imageInfo().refColorSpace(); }), allow_raw_pointers()) .function("getImageInfo", optional_override([](sk_sp self)->JSObject { // We cannot return a SimpleImageInfo because the colorspace object would be leaked. JSObject result = emscripten::val::object(); SkImageInfo ii = self->imageInfo(); result.set("alphaType", ii.alphaType()); result.set("colorType", ii.colorType()); result.set("height", ii.height()); result.set("width", ii.width()); return result; })) .function("height", &SkImage::height) .function("encodeToBytes", optional_override([](sk_sp self) -> Uint8Array { sk_sp data = self->encodeToData(); if (!data) { return emscripten::val::null(); } return toBytes(data); })) .function("encodeToBytes", optional_override([](sk_sp self, SkEncodedImageFormat fmt, int quality) -> Uint8Array { sk_sp data = self->encodeToData(fmt, quality); if (!data) { return emscripten::val::null(); } return toBytes(data); })) .function("makeCopyWithDefaultMipmaps", optional_override([](sk_sp self)->sk_sp { return self->withDefaultMipmaps(); })) .function("_makeShaderCubic", optional_override([](sk_sp self, SkTileMode tx, SkTileMode ty, float B, float C, // See SkSamplingOptions.h for docs. uintptr_t /* SkScalar* */ mPtr)->sk_sp { return self->makeShader(tx, ty, SkSamplingOptions({B, C}), OptionalMatrix(mPtr)); }), allow_raw_pointers()) .function("_makeShaderOptions", optional_override([](sk_sp self, SkTileMode tx, SkTileMode ty, SkFilterMode filter, SkMipmapMode mipmap, uintptr_t /* SkScalar* */ mPtr)->sk_sp { return self->makeShader(tx, ty, {filter, mipmap}, OptionalMatrix(mPtr)); }), allow_raw_pointers()) .function("_readPixels", optional_override([](sk_sp self, SimpleImageInfo sii, uintptr_t /* uint8_t* */ pPtr, size_t dstRowBytes, int srcX, int srcY)->bool { uint8_t* pixels = reinterpret_cast(pPtr); SkImageInfo ii = toSkImageInfo(sii); // TODO(adlai) Migrate CanvasKit API to require DirectContext arg here. GrDirectContext* dContext = nullptr; #ifdef SK_GL dContext = GrAsDirectContext(as_IB(self.get())->context()); #endif return self->readPixels(dContext, ii, pixels, dstRowBytes, srcX, srcY); }), allow_raw_pointers()) .function("width", &SkImage::width); class_("ImageFilter") .smart_ptr>("sk_sp") .class_function("MakeBlur", optional_override([](SkScalar sigmaX, SkScalar sigmaY, SkTileMode tileMode, sk_sp input)->sk_sp { return SkImageFilters::Blur(sigmaX, sigmaY, tileMode, input); })) .class_function("MakeColorFilter", optional_override([](sk_sp cf, sk_sp input)->sk_sp { return SkImageFilters::ColorFilter(cf, input); })) .class_function("MakeCompose", &SkImageFilters::Compose) .class_function("_MakeMatrixTransform", optional_override([](uintptr_t /* SkScalar* */ mPtr, SkFilterQuality fq, sk_sp input)->sk_sp { OptionalMatrix matr(mPtr); // TODO(kjlubick): pass in sampling directly from client auto sampling = SkSamplingOptions(fq, SkSamplingOptions::kMedium_asMipmapLinear); return SkImageFilters::MatrixTransform(matr, sampling, input); })); class_("MaskFilter") .smart_ptr>("sk_sp") .class_function("MakeBlur", optional_override([](SkBlurStyle style, SkScalar sigma, bool respectCTM)->sk_sp { // Adds a little helper because emscripten doesn't expose default params. return SkMaskFilter::MakeBlur(style, sigma, respectCTM); }), allow_raw_pointers()); class_("Paint") .constructor<>() .function("copy", optional_override([](const SkPaint& self)->SkPaint { SkPaint p(self); return p; })) .function("getBlendMode", &SkPaint::getBlendMode) // provide an allocated place to put the returned color .function("_getColor", optional_override([](SkPaint& self, uintptr_t /* float* */ cPtr)->void { const SkColor4f& c = self.getColor4f(); float* fourFloats = reinterpret_cast(cPtr); memcpy(fourFloats, c.vec(), 4 * sizeof(SkScalar)); })) .function("getFilterQuality", &SkPaint::getFilterQuality) .function("getStrokeCap", &SkPaint::getStrokeCap) .function("getStrokeJoin", &SkPaint::getStrokeJoin) .function("getStrokeMiter", &SkPaint::getStrokeMiter) .function("getStrokeWidth", &SkPaint::getStrokeWidth) .function("setAntiAlias", &SkPaint::setAntiAlias) .function("setAlphaf", &SkPaint::setAlphaf) .function("setBlendMode", &SkPaint::setBlendMode) .function("_setColor", optional_override([](SkPaint& self, uintptr_t /* float* */ cPtr, sk_sp colorSpace) { self.setColor(ptrToSkColor4f(cPtr), colorSpace.get()); })) .function("setColorInt", optional_override([](SkPaint& self, SkColor color) { self.setColor(SkColor4f::FromColor(color), nullptr); })) .function("setColorInt", optional_override([](SkPaint& self, SkColor color, sk_sp colorSpace) { self.setColor(SkColor4f::FromColor(color), colorSpace.get()); })) .function("setColorFilter", &SkPaint::setColorFilter) .function("setFilterQuality", &SkPaint::setFilterQuality) .function("setImageFilter", &SkPaint::setImageFilter) .function("setMaskFilter", &SkPaint::setMaskFilter) .function("setPathEffect", &SkPaint::setPathEffect) .function("setShader", &SkPaint::setShader) .function("setStrokeCap", &SkPaint::setStrokeCap) .function("setStrokeJoin", &SkPaint::setStrokeJoin) .function("setStrokeMiter", &SkPaint::setStrokeMiter) .function("setStrokeWidth", &SkPaint::setStrokeWidth) .function("setStyle", &SkPaint::setStyle); class_("ColorSpace") .smart_ptr>("sk_sp") .class_function("Equals", optional_override([](sk_sp a, sk_sp b)->bool { return SkColorSpace::Equals(a.get(), b.get()); })) // These are private because they are to be called once in interface.js to // avoid clients having to delete the returned objects. .class_function("_MakeSRGB", &SkColorSpace::MakeSRGB) .class_function("_MakeDisplayP3", optional_override([]()->sk_sp { return SkColorSpace::MakeRGB(SkNamedTransferFn::kSRGB, SkNamedGamut::kDisplayP3); })) .class_function("_MakeAdobeRGB", optional_override([]()->sk_sp { return SkColorSpace::MakeRGB(SkNamedTransferFn::k2Dot2, SkNamedGamut::kAdobeRGB); })); class_("PathEffect") .smart_ptr>("sk_sp") .class_function("MakeCorner", &SkCornerPathEffect::Make) .class_function("_MakeDash", optional_override([](uintptr_t /* float* */ cptr, int count, SkScalar phase)->sk_sp { const float* intervals = reinterpret_cast(cptr); return SkDashPathEffect::Make(intervals, count, phase); }), allow_raw_pointers()) .class_function("MakeDiscrete", &SkDiscretePathEffect::Make); // TODO(kjlubick, reed) Make SkPath immutable and only creatable via a factory/builder. class_("Path") .constructor<>() #ifdef SK_INCLUDE_PATHOPS .class_function("MakeFromOp", &MakePathFromOp) #endif .class_function("MakeFromSVGString", &MakePathFromSVGString) .class_function("_MakeFromCmds", &MakePathFromCmds) .class_function("_MakeFromVerbsPointsWeights", &MakePathFromVerbsPointsWeights) .function("_addArc", optional_override([](SkPath& self, uintptr_t /* float* */ fPtr, SkScalar startAngle, SkScalar sweepAngle)->void { const SkRect* oval = reinterpret_cast(fPtr); self.addArc(*oval, startAngle, sweepAngle); })) .function("_addOval", optional_override([](SkPath& self, uintptr_t /* float* */ fPtr, bool ccw, unsigned start)->void { const SkRect* oval = reinterpret_cast(fPtr); self.addOval(*oval, ccw ? SkPathDirection::kCCW : SkPathDirection::kCW, start); })) // interface.js has 3 overloads of addPath .function("_addPath", &ApplyAddPath) .function("_addPoly", optional_override([](SkPath& self, uintptr_t /* SkPoint* */ fPtr, int count, bool close)->void { const SkPoint* pts = reinterpret_cast(fPtr); self.addPoly(pts, count, close); })) .function("_addRect", optional_override([](SkPath& self, uintptr_t /* float* */ fPtr, bool ccw)->void { const SkRect* rect = reinterpret_cast(fPtr); self.addRect(*rect, ccw ? SkPathDirection::kCCW : SkPathDirection::kCW); })) .function("_addRRect", optional_override([](SkPath& self, uintptr_t /* float* */ fPtr, bool ccw)->void { self.addRRect(ptrToSkRRect(fPtr), ccw ? SkPathDirection::kCCW : SkPathDirection::kCW); })) .function("_addVerbsPointsWeights", &PathAddVerbsPointsWeights) .function("_arcToOval", optional_override([](SkPath& self, uintptr_t /* float* */ fPtr, SkScalar startAngle, SkScalar sweepAngle, bool forceMoveTo)->void { const SkRect* oval = reinterpret_cast(fPtr); self.arcTo(*oval, startAngle, sweepAngle, forceMoveTo); })) .function("_arcToRotated", &ApplyArcToArcSize) .function("_arcToTangent", ApplyArcToTangent) .function("_close", &ApplyClose) .function("_conicTo", &ApplyConicTo) .function("countPoints", &SkPath::countPoints) .function("contains", &SkPath::contains) .function("_cubicTo", &ApplyCubicTo) .function("_getPoint", optional_override([](SkPath& self, int index, uintptr_t /* float* */ oPtr)->void { SkPoint* output = reinterpret_cast(oPtr); *output = self.getPoint(index); })) .function("isEmpty", &SkPath::isEmpty) .function("isVolatile", &SkPath::isVolatile) .function("_lineTo", &ApplyLineTo) .function("_moveTo", &ApplyMoveTo) .function("_quadTo", &ApplyQuadTo) .function("_rArcTo", &ApplyRArcToArcSize) .function("_rConicTo", &ApplyRConicTo) .function("_rCubicTo", &ApplyRCubicTo) .function("_rLineTo", &ApplyRLineTo) .function("_rMoveTo", &ApplyRMoveTo) .function("_rQuadTo", &ApplyRQuadTo) .function("reset", &ApplyReset) .function("rewind", &ApplyRewind) .function("setIsVolatile", &SkPath::setIsVolatile) .function("_transform", select_overload(&ApplyTransform)) // PathEffects .function("_dash", &ApplyDash) .function("_trim", &ApplyTrim) .function("_stroke", &ApplyStroke) #ifdef SK_INCLUDE_PATHOPS // PathOps .function("_simplify", &ApplySimplify) .function("_op", &ApplyPathOp) #endif // Exporting .function("toSVGString", &ToSVGString) .function("toCmds", &ToCmds) .function("setFillType", select_overload(&SkPath::setFillType)) .function("getFillType", &SkPath::getFillType) .function("_getBounds", optional_override([](SkPath& self, uintptr_t /* float* */ fPtr)->void { SkRect* output = reinterpret_cast(fPtr); output[0] = self.getBounds(); })) .function("_computeTightBounds", optional_override([](SkPath& self, uintptr_t /* float* */ fPtr)->void { SkRect* output = reinterpret_cast(fPtr); output[0] = self.computeTightBounds(); })) .function("equals", &Equals) .function("copy", &CopyPath) #ifdef SK_DEBUG .function("dump", select_overload(&SkPath::dump)) .function("dumpHex", select_overload(&SkPath::dumpHex)) #endif ; class_("PictureRecorder") .constructor<>() .function("_beginRecording", optional_override([](SkPictureRecorder& self, uintptr_t /* float* */ fPtr) -> SkCanvas* { SkRect* bounds = reinterpret_cast(fPtr); return self.beginRecording(*bounds, nullptr); }), allow_raw_pointers()) .function("finishRecordingAsPicture", optional_override([](SkPictureRecorder& self) -> sk_sp { return self.finishRecordingAsPicture(); }), allow_raw_pointers()); class_("Picture") .smart_ptr>("sk_sp") #ifdef SK_SERIALIZE_SKP // The serialized format of an SkPicture (informally called an "skp"), is not something // that clients should ever rely on. The format may change at anytime and no promises // are made for backwards or forward compatibility. .function("serialize", optional_override([](SkPicture& self) -> Uint8Array { // Emscripten doesn't play well with optional arguments, which we don't // want to expose anyway. sk_sp data = self.serialize(); if (!data) { return emscripten::val::null(); } return toBytes(data); }), allow_raw_pointers()) #endif ; class_("Shader") .smart_ptr>("sk_sp") .class_function("MakeBlend", select_overload(SkBlendMode, sk_sp, sk_sp)>(&SkShaders::Blend)) .class_function("_MakeColor", optional_override([](uintptr_t /* float* */ cPtr, sk_sp colorSpace)->sk_sp { return SkShaders::Color(ptrToSkColor4f(cPtr), colorSpace); }) ) .class_function("MakeLerp", select_overload(float, sk_sp, sk_sp)>(&SkShaders::Lerp)) .class_function("MakeFractalNoise", optional_override([]( SkScalar baseFreqX, SkScalar baseFreqY, int numOctaves, SkScalar seed, int tileW, int tileH)->sk_sp { // if tileSize is empty (e.g. tileW <= 0 or tileH <= 0, it will be ignored. SkISize tileSize = SkISize::Make(tileW, tileH); return SkPerlinNoiseShader::MakeFractalNoise(baseFreqX, baseFreqY, numOctaves, seed, &tileSize); })) // Here and in other gradient functions, cPtr is a pointer to an array of data // representing colors. whether this is an array of SkColor or SkColor4f is indicated // by the colorType argument. Only RGBA_8888 and RGBA_F32 are accepted. .class_function("_MakeLinearGradient", optional_override([]( uintptr_t /* SkPoint* */ fourFloatsPtr, uintptr_t cPtr, SkColorType colorType, uintptr_t /* SkScalar* */ pPtr, int count, SkTileMode mode, uint32_t flags, uintptr_t /* SkScalar* */ mPtr, sk_sp colorSpace)->sk_sp { const SkPoint* points = reinterpret_cast(fourFloatsPtr); const SkScalar* positions = reinterpret_cast(pPtr); OptionalMatrix localMatrix(mPtr); if (colorType == SkColorType::kRGBA_F32_SkColorType) { const SkColor4f* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeLinear(points, colors, colorSpace, positions, count, mode, flags, &localMatrix); } else if (colorType == SkColorType::kRGBA_8888_SkColorType) { const SkColor* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeLinear(points, colors, positions, count, mode, flags, &localMatrix); } SkDebugf("%d is not an accepted colorType\n", colorType); return nullptr; }), allow_raw_pointers()) .class_function("_MakeRadialGradient", optional_override([]( SkScalar cx, SkScalar cy, SkScalar radius, uintptr_t cPtr, SkColorType colorType, uintptr_t /* SkScalar* */ pPtr, int count, SkTileMode mode, uint32_t flags, uintptr_t /* SkScalar* */ mPtr, sk_sp colorSpace)->sk_sp { const SkScalar* positions = reinterpret_cast(pPtr); OptionalMatrix localMatrix(mPtr); if (colorType == SkColorType::kRGBA_F32_SkColorType) { const SkColor4f* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeRadial({cx, cy}, radius, colors, colorSpace, positions, count, mode, flags, &localMatrix); } else if (colorType == SkColorType::kRGBA_8888_SkColorType) { const SkColor* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeRadial({cx, cy}, radius, colors, positions, count, mode, flags, &localMatrix); } SkDebugf("%d is not an accepted colorType\n", colorType); return nullptr; }), allow_raw_pointers()) .class_function("_MakeSweepGradient", optional_override([](SkScalar cx, SkScalar cy, uintptr_t cPtr, SkColorType colorType, uintptr_t /* SkScalar* */ pPtr, int count, SkTileMode mode, SkScalar startAngle, SkScalar endAngle, uint32_t flags, uintptr_t /* SkScalar* */ mPtr, sk_sp colorSpace)->sk_sp { const SkScalar* positions = reinterpret_cast(pPtr); OptionalMatrix localMatrix(mPtr); if (colorType == SkColorType::kRGBA_F32_SkColorType) { const SkColor4f* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeSweep(cx, cy, colors, colorSpace, positions, count, mode, startAngle, endAngle, flags, &localMatrix); } else if (colorType == SkColorType::kRGBA_8888_SkColorType) { const SkColor* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeSweep(cx, cy, colors, positions, count, mode, startAngle, endAngle, flags, &localMatrix); } SkDebugf("%d is not an accepted colorType\n", colorType); return nullptr; }), allow_raw_pointers()) .class_function("MakeTurbulence", optional_override([]( SkScalar baseFreqX, SkScalar baseFreqY, int numOctaves, SkScalar seed, int tileW, int tileH)->sk_sp { // if tileSize is empty (e.g. tileW <= 0 or tileH <= 0, it will be ignored. SkISize tileSize = SkISize::Make(tileW, tileH); return SkPerlinNoiseShader::MakeTurbulence(baseFreqX, baseFreqY, numOctaves, seed, &tileSize); })) .class_function("_MakeTwoPointConicalGradient", optional_override([]( uintptr_t /* SkPoint* */ fourFloatsPtr, SkScalar startRadius, SkScalar endRadius, uintptr_t cPtr, SkColorType colorType, uintptr_t /* SkScalar* */ pPtr, int count, SkTileMode mode, uint32_t flags, uintptr_t /* SkScalar* */ mPtr, sk_sp colorSpace)->sk_sp { const SkPoint* startAndEnd = reinterpret_cast(fourFloatsPtr); const SkScalar* positions = reinterpret_cast(pPtr); OptionalMatrix localMatrix(mPtr); if (colorType == SkColorType::kRGBA_F32_SkColorType) { const SkColor4f* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeTwoPointConical(startAndEnd[0], startRadius, startAndEnd[1], endRadius, colors, colorSpace, positions, count, mode, flags, &localMatrix); } else if (colorType == SkColorType::kRGBA_8888_SkColorType) { const SkColor* colors = reinterpret_cast(cPtr); return SkGradientShader::MakeTwoPointConical(startAndEnd[0], startRadius, startAndEnd[1], endRadius, colors, positions, count, mode, flags, &localMatrix); } SkDebugf("%d is not an accepted colorType\n", colorType); return nullptr; }), allow_raw_pointers()); #ifdef SK_INCLUDE_RUNTIME_EFFECT class_("RuntimeEffect") .smart_ptr>("sk_sp") .class_function("_Make", optional_override([](std::string sksl, emscripten::val errHandler )->sk_sp { SkString s(sksl.c_str(), sksl.length()); auto [effect, errorText] = SkRuntimeEffect::Make(s); if (!effect) { errHandler.call("onError", val(errorText.c_str())); return nullptr; } return effect; })) .function("_makeShader", optional_override([](SkRuntimeEffect& self, uintptr_t fPtr, size_t fLen, bool isOpaque, uintptr_t /* SkScalar* */ mPtr)->sk_sp { void* inputData = reinterpret_cast(fPtr); sk_sp inputs = SkData::MakeFromMalloc(inputData, fLen); OptionalMatrix localMatrix(mPtr); return self.makeShader(inputs, nullptr, 0, &localMatrix, isOpaque); })) .function("_makeShaderWithChildren", optional_override([](SkRuntimeEffect& self, uintptr_t fPtr, size_t fLen, bool isOpaque, uintptr_t /** SkShader*[] */cPtrs, size_t cLen, uintptr_t /* SkScalar* */ mPtr)->sk_sp { void* inputData = reinterpret_cast(fPtr); sk_sp inputs = SkData::MakeFromMalloc(inputData, fLen); sk_sp* children = new sk_sp[cLen]; SkShader** childrenPtrs = reinterpret_cast(cPtrs); for (size_t i = 0; i < cLen; i++) { // This bare pointer was already part of an sk_sp (owned outside of here), // so we want to ref the new sk_sp so makeShader doesn't clean it up. children[i] = sk_ref_sp(childrenPtrs[i]); } OptionalMatrix localMatrix(mPtr); auto s = self.makeShader(inputs, children, cLen, &localMatrix, isOpaque); delete[] children; return s; })) .function("getUniformCount", optional_override([](SkRuntimeEffect& self)->int { return self.uniforms().count(); })) .function("getUniformFloatCount", optional_override([](SkRuntimeEffect& self)->int { return self.uniformSize() / sizeof(float); })) .function("getUniformName", optional_override([](SkRuntimeEffect& self, int i)->JSString { auto it = self.uniforms().begin() + i; return emscripten::val(it->name.c_str()); })) .function("getUniform", optional_override([](SkRuntimeEffect& self, int i)->RuntimeEffectUniform { auto it = self.uniforms().begin() + i; RuntimeEffectUniform su = fromUniform(*it); return su; })); value_object("RuntimeEffectUniform") .field("columns", &RuntimeEffectUniform::columns) .field("rows", &RuntimeEffectUniform::rows) .field("slot", &RuntimeEffectUniform::slot); #endif class_("Surface") .smart_ptr>("sk_sp") .class_function("_makeRasterDirect", optional_override([](const SimpleImageInfo ii, uintptr_t /* uint8_t* */ pPtr, size_t rowBytes)->sk_sp { uint8_t* pixels = reinterpret_cast(pPtr); SkImageInfo imageInfo = toSkImageInfo(ii); return SkSurface::MakeRasterDirect(imageInfo, pixels, rowBytes, nullptr); }), allow_raw_pointers()) .function("_flush", optional_override([](SkSurface& self) { self.flushAndSubmit(false); })) .function("getCanvas", &SkSurface::getCanvas, allow_raw_pointers()) .function("imageInfo", optional_override([](SkSurface& self)->SimpleImageInfo { const auto& ii = self.imageInfo(); return {ii.width(), ii.height(), ii.colorType(), ii.alphaType(), ii.refColorSpace()}; })) .function("height", &SkSurface::height) .function("_makeImageSnapshot", optional_override([](SkSurface& self, uintptr_t /* int* */ iPtr)->sk_sp { SkIRect* bounds = reinterpret_cast(iPtr); if (!bounds) { return self.makeImageSnapshot(); } return self.makeImageSnapshot(*bounds); })) .function("makeSurface", optional_override([](SkSurface& self, SimpleImageInfo sii)->sk_sp { return self.makeSurface(toSkImageInfo(sii)); }), allow_raw_pointers()) #ifdef SK_GL .function("reportBackendTypeIsGPU", optional_override([](SkSurface& self) -> bool { return self.getCanvas()->recordingContext() != nullptr; })) .function("sampleCnt", optional_override([](SkSurface& self)->int { auto backendRT = self.getBackendRenderTarget(SkSurface::kFlushRead_BackendHandleAccess); return (backendRT.isValid()) ? backendRT.sampleCnt() : 0; })) #else .function("reportBackendTypeIsGPU", optional_override([](SkSurface& self) -> bool { return false; })) #endif .function("width", &SkSurface::width); #ifndef SK_NO_FONTS class_("TextBlob") .smart_ptr>("sk_sp") .class_function("_MakeFromRSXform", optional_override([](uintptr_t /* char* */ sptr, size_t strBtyes, uintptr_t /* SkRSXform* */ xptr, const SkFont& font)->sk_sp { const char* str = reinterpret_cast(sptr); const SkRSXform* xforms = reinterpret_cast(xptr); return SkTextBlob::MakeFromRSXform(str, strBtyes, xforms, font, SkTextEncoding::kUTF8); }), allow_raw_pointers()) .class_function("_MakeFromRSXformGlyphs", optional_override([](uintptr_t /* SkGlyphID* */ gPtr, size_t byteLen, uintptr_t /* SkRSXform* */ xptr, const SkFont& font)->sk_sp { const SkGlyphID* glyphs = reinterpret_cast(gPtr); const SkRSXform* xforms = reinterpret_cast(xptr); return SkTextBlob::MakeFromRSXform(glyphs, byteLen, xforms, font, SkTextEncoding::kGlyphID); }), allow_raw_pointers()) .class_function("_MakeFromText", optional_override([](uintptr_t /* char* */ sptr, size_t len, const SkFont& font)->sk_sp { const char* str = reinterpret_cast(sptr); return SkTextBlob::MakeFromText(str, len, font, SkTextEncoding::kUTF8); }), allow_raw_pointers()) .class_function("_MakeFromGlyphs", optional_override([](uintptr_t /* SkGlyphID* */ gPtr, size_t byteLen, const SkFont& font)->sk_sp { const SkGlyphID* glyphs = reinterpret_cast(gPtr); return SkTextBlob::MakeFromText(glyphs, byteLen, font, SkTextEncoding::kGlyphID); }), allow_raw_pointers()); class_("Typeface") .smart_ptr>("sk_sp"); #endif class_("Vertices") .smart_ptr>("sk_sp") .function("_bounds", optional_override([](SkVertices& self, uintptr_t /* float* */ fPtr)->void { SkRect* output = reinterpret_cast(fPtr); output[0] = self.bounds(); })) .function("uniqueID", &SkVertices::uniqueID); // Not intended to be called directly by clients class_("_VerticesBuilder") .constructor() .function("colors", optional_override([](SkVertices::Builder& self)->uintptr_t /* SkColor* */{ // Emscripten won't let us return bare pointers, but we can return ints just fine. return reinterpret_cast(self.colors()); })) .function("detach", &SkVertices::Builder::detach) .function("indices", optional_override([](SkVertices::Builder& self)->uintptr_t /* uint16_t* */{ // Emscripten won't let us return bare pointers, but we can return ints just fine. return reinterpret_cast(self.indices()); })) .function("positions", optional_override([](SkVertices::Builder& self)->uintptr_t /* SkPoint* */{ // Emscripten won't let us return bare pointers, but we can return ints just fine. return reinterpret_cast(self.positions()); })) .function("texCoords", optional_override([](SkVertices::Builder& self)->uintptr_t /* SkPoint* */{ // Emscripten won't let us return bare pointers, but we can return ints just fine. return reinterpret_cast(self.texCoords()); })); enum_("AlphaType") .value("Opaque", SkAlphaType::kOpaque_SkAlphaType) .value("Premul", SkAlphaType::kPremul_SkAlphaType) .value("Unpremul", SkAlphaType::kUnpremul_SkAlphaType); enum_("BlendMode") .value("Clear", SkBlendMode::kClear) .value("Src", SkBlendMode::kSrc) .value("Dst", SkBlendMode::kDst) .value("SrcOver", SkBlendMode::kSrcOver) .value("DstOver", SkBlendMode::kDstOver) .value("SrcIn", SkBlendMode::kSrcIn) .value("DstIn", SkBlendMode::kDstIn) .value("SrcOut", SkBlendMode::kSrcOut) .value("DstOut", SkBlendMode::kDstOut) .value("SrcATop", SkBlendMode::kSrcATop) .value("DstATop", SkBlendMode::kDstATop) .value("Xor", SkBlendMode::kXor) .value("Plus", SkBlendMode::kPlus) .value("Modulate", SkBlendMode::kModulate) .value("Screen", SkBlendMode::kScreen) .value("Overlay", SkBlendMode::kOverlay) .value("Darken", SkBlendMode::kDarken) .value("Lighten", SkBlendMode::kLighten) .value("ColorDodge", SkBlendMode::kColorDodge) .value("ColorBurn", SkBlendMode::kColorBurn) .value("HardLight", SkBlendMode::kHardLight) .value("SoftLight", SkBlendMode::kSoftLight) .value("Difference", SkBlendMode::kDifference) .value("Exclusion", SkBlendMode::kExclusion) .value("Multiply", SkBlendMode::kMultiply) .value("Hue", SkBlendMode::kHue) .value("Saturation", SkBlendMode::kSaturation) .value("Color", SkBlendMode::kColor) .value("Luminosity", SkBlendMode::kLuminosity); enum_("BlurStyle") .value("Normal", SkBlurStyle::kNormal_SkBlurStyle) .value("Solid", SkBlurStyle::kSolid_SkBlurStyle) .value("Outer", SkBlurStyle::kOuter_SkBlurStyle) .value("Inner", SkBlurStyle::kInner_SkBlurStyle); enum_("ClipOp") .value("Difference", SkClipOp::kDifference) .value("Intersect", SkClipOp::kIntersect); enum_("ColorType") .value("Alpha_8", SkColorType::kAlpha_8_SkColorType) .value("RGB_565", SkColorType::kRGB_565_SkColorType) .value("RGBA_8888", SkColorType::kRGBA_8888_SkColorType) .value("BGRA_8888", SkColorType::kBGRA_8888_SkColorType) .value("RGBA_1010102", SkColorType::kRGBA_1010102_SkColorType) .value("RGB_101010x", SkColorType::kRGB_101010x_SkColorType) .value("Gray_8", SkColorType::kGray_8_SkColorType) .value("RGBA_F16", SkColorType::kRGBA_F16_SkColorType) .value("RGBA_F32", SkColorType::kRGBA_F32_SkColorType); enum_("FillType") .value("Winding", SkPathFillType::kWinding) .value("EvenOdd", SkPathFillType::kEvenOdd); enum_("FilterMode") .value("Nearest", SkFilterMode::kNearest) .value("Linear", SkFilterMode::kLinear); enum_("FilterQuality") .value("None", SkFilterQuality::kNone_SkFilterQuality) .value("Low", SkFilterQuality::kLow_SkFilterQuality) .value("Medium", SkFilterQuality::kMedium_SkFilterQuality) .value("High", SkFilterQuality::kHigh_SkFilterQuality); // Only used to control the encode function. // TODO(kjlubick): compile these out when the appropriate encoder is disabled. enum_("ImageFormat") .value("PNG", SkEncodedImageFormat::kPNG) .value("JPEG", SkEncodedImageFormat::kJPEG) .value("WEBP", SkEncodedImageFormat::kWEBP); enum_("MipmapMode") .value("None", SkMipmapMode::kNone) .value("Nearest", SkMipmapMode::kNearest) .value("Linear", SkMipmapMode::kLinear); enum_("PaintStyle") .value("Fill", SkPaint::Style::kFill_Style) .value("Stroke", SkPaint::Style::kStroke_Style); #ifdef SK_INCLUDE_PATHOPS enum_("PathOp") .value("Difference", SkPathOp::kDifference_SkPathOp) .value("Intersect", SkPathOp::kIntersect_SkPathOp) .value("Union", SkPathOp::kUnion_SkPathOp) .value("XOR", SkPathOp::kXOR_SkPathOp) .value("ReverseDifference", SkPathOp::kReverseDifference_SkPathOp); #endif enum_("PointMode") .value("Points", SkCanvas::PointMode::kPoints_PointMode) .value("Lines", SkCanvas::PointMode::kLines_PointMode) .value("Polygon", SkCanvas::PointMode::kPolygon_PointMode); enum_("StrokeCap") .value("Butt", SkPaint::Cap::kButt_Cap) .value("Round", SkPaint::Cap::kRound_Cap) .value("Square", SkPaint::Cap::kSquare_Cap); enum_("StrokeJoin") .value("Miter", SkPaint::Join::kMiter_Join) .value("Round", SkPaint::Join::kRound_Join) .value("Bevel", SkPaint::Join::kBevel_Join); #ifndef SK_NO_FONTS enum_("FontHinting") .value("None", SkFontHinting::kNone) .value("Slight", SkFontHinting::kSlight) .value("Normal", SkFontHinting::kNormal) .value("Full", SkFontHinting::kFull); enum_("FontEdging") #ifndef CANVASKIT_NO_ALIAS_FONT .value("Alias", SkFont::Edging::kAlias) #endif .value("AntiAlias", SkFont::Edging::kAntiAlias) .value("SubpixelAntiAlias", SkFont::Edging::kSubpixelAntiAlias); #endif enum_("TileMode") .value("Clamp", SkTileMode::kClamp) .value("Repeat", SkTileMode::kRepeat) .value("Mirror", SkTileMode::kMirror) .value("Decal", SkTileMode::kDecal); enum_("VertexMode") .value("Triangles", SkVertices::VertexMode::kTriangles_VertexMode) .value("TrianglesStrip", SkVertices::VertexMode::kTriangleStrip_VertexMode) .value("TriangleFan", SkVertices::VertexMode::kTriangleFan_VertexMode); // A value object is much simpler than a class - it is returned as a JS // object and does not require delete(). // https://emscripten.org/docs/porting/connecting_cpp_and_javascript/embind.html#value-types value_object("ImageInfo") .field("width", &SimpleImageInfo::width) .field("height", &SimpleImageInfo::height) .field("colorType", &SimpleImageInfo::colorType) .field("alphaType", &SimpleImageInfo::alphaType) .field("colorSpace", &SimpleImageInfo::colorSpace); value_object("StrokeOpts") .field("width", &StrokeOpts::width) .field("miter_limit", &StrokeOpts::miter_limit) .field("join", &StrokeOpts::join) .field("cap", &StrokeOpts::cap) .field("precision", &StrokeOpts::precision); constant("MOVE_VERB", MOVE); constant("LINE_VERB", LINE); constant("QUAD_VERB", QUAD); constant("CONIC_VERB", CONIC); constant("CUBIC_VERB", CUBIC); constant("CLOSE_VERB", CLOSE); constant("SaveLayerInitWithPrevious", (int)SkCanvas::SaveLayerFlagsSet::kInitWithPrevious_SaveLayerFlag); constant("SaveLayerF16ColorType", (int)SkCanvas::SaveLayerFlagsSet::kF16ColorType); constant("ShadowTransparentOccluder", (int)SkShadowFlags::kTransparentOccluder_ShadowFlag); constant("ShadowGeometricOnly", (int)SkShadowFlags::kGeometricOnly_ShadowFlag); constant("ShadowDirectionalLight", (int)SkShadowFlags::kDirectionalLight_ShadowFlag); }