/* * 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 "SkottiePriv.h" #include "SkData.h" #include "SkFontMgr.h" #include "SkImage.h" #include "SkJSON.h" #include "SkMakeUnique.h" #include "SkottieJson.h" #include "SkottieValue.h" #include "SkParse.h" #include "SkSGClipEffect.h" #include "SkSGColor.h" #include "SkSGDraw.h" #include "SkSGGroup.h" #include "SkSGImage.h" #include "SkSGMaskEffect.h" #include "SkSGMerge.h" #include "SkSGOpacityEffect.h" #include "SkSGPath.h" #include "SkSGRect.h" #include "SkSGTransform.h" #include #include namespace skottie { namespace internal { namespace { struct MaskInfo { SkBlendMode fBlendMode; // used when masking with layers/blending sksg::Merge::Mode fMergeMode; // used when clipping bool fInvertGeometry; }; const MaskInfo* GetMaskInfo(char mode) { static constexpr MaskInfo k_add_info = { SkBlendMode::kSrcOver , sksg::Merge::Mode::kUnion , false }; static constexpr MaskInfo k_int_info = { SkBlendMode::kSrcIn , sksg::Merge::Mode::kIntersect , false }; // AE 'subtract' is the same as 'intersect' + inverted geometry // (draws the opacity-adjusted paint *outside* the shape). static constexpr MaskInfo k_sub_info = { SkBlendMode::kSrcIn , sksg::Merge::Mode::kIntersect , true }; static constexpr MaskInfo k_dif_info = { SkBlendMode::kDifference, sksg::Merge::Mode::kDifference, false }; switch (mode) { case 'a': return &k_add_info; case 'f': return &k_dif_info; case 'i': return &k_int_info; case 's': return &k_sub_info; default: break; } return nullptr; } sk_sp AttachMask(const skjson::ArrayValue* jmask, const AnimationBuilder* abuilder, AnimatorScope* ascope, sk_sp childNode) { if (!jmask) return childNode; struct MaskRecord { sk_sp mask_path; // for clipping and masking sk_sp mask_paint; // for masking sksg::Merge::Mode merge_mode; // for clipping }; SkSTArray<4, MaskRecord, true> mask_stack; bool has_opacity = false; for (const skjson::ObjectValue* m : *jmask) { if (!m) continue; const skjson::StringValue* jmode = (*m)["mode"]; if (!jmode || jmode->size() != 1) { abuilder->log(Logger::Level::kError, &(*m)["mode"], "Invalid mask mode."); continue; } const auto mode = *jmode->begin(); if (mode == 'n') { // "None" masks have no effect. continue; } const auto* mask_info = GetMaskInfo(mode); if (!mask_info) { abuilder->log(Logger::Level::kWarning, nullptr, "Unsupported mask mode: '%c'.", mode); continue; } auto mask_path = abuilder->attachPath((*m)["pt"], ascope); if (!mask_path) { abuilder->log(Logger::Level::kError, m, "Could not parse mask path."); continue; } // "inv" is cumulative with mask info fInvertGeometry const auto inverted = (mask_info->fInvertGeometry != ParseDefault((*m)["inv"], false)); mask_path->setFillType(inverted ? SkPath::kInverseWinding_FillType : SkPath::kWinding_FillType); auto mask_paint = sksg::Color::Make(SK_ColorBLACK); mask_paint->setAntiAlias(true); // First mask in the stack initializes the mask buffer. mask_paint->setBlendMode(mask_stack.empty() ? SkBlendMode::kSrc : mask_info->fBlendMode); has_opacity |= abuilder->bindProperty((*m)["o"], ascope, [mask_paint](const ScalarValue& o) { mask_paint->setOpacity(o * 0.01f); }, 100.0f); mask_stack.push_back({mask_path, mask_paint, mask_info->fMergeMode}); } if (mask_stack.empty()) return childNode; // If the masks are fully opaque, we can clip. if (!has_opacity) { sk_sp clip_node; if (mask_stack.count() == 1) { // Single path -> just clip. clip_node = std::move(mask_stack.front().mask_path); } else { // Multiple clip paths -> merge. std::vector merge_recs; merge_recs.reserve(SkToSizeT(mask_stack.count())); for (auto& mask : mask_stack) { const auto mode = merge_recs.empty() ? sksg::Merge::Mode::kMerge : mask.merge_mode; merge_recs.push_back({std::move(mask.mask_path), mode}); } clip_node = sksg::Merge::Make(std::move(merge_recs)); } return sksg::ClipEffect::Make(std::move(childNode), std::move(clip_node), true); } sk_sp maskNode; if (mask_stack.count() == 1) { // no group needed for single mask maskNode = sksg::Draw::Make(std::move(mask_stack.front().mask_path), std::move(mask_stack.front().mask_paint)); } else { std::vector> masks; masks.reserve(SkToSizeT(mask_stack.count())); for (auto& rec : mask_stack) { masks.push_back(sksg::Draw::Make(std::move(rec.mask_path), std::move(rec.mask_paint))); } maskNode = sksg::Group::Make(std::move(masks)); } return sksg::MaskEffect::Make(std::move(childNode), std::move(maskNode)); } } // namespace sk_sp AnimationBuilder::attachNestedAnimation(const char* name, AnimatorScope* ascope) const { class SkottieSGAdapter final : public sksg::RenderNode { public: explicit SkottieSGAdapter(sk_sp animation) : fAnimation(std::move(animation)) { SkASSERT(fAnimation); } protected: SkRect onRevalidate(sksg::InvalidationController*, const SkMatrix&) override { return SkRect::MakeSize(fAnimation->size()); } void onRender(SkCanvas* canvas, const RenderContext* ctx) const override { const auto local_scope = ScopedRenderContext(canvas, ctx).setIsolation(this->bounds(), true); fAnimation->render(canvas); } private: const sk_sp fAnimation; }; class SkottieAnimatorAdapter final : public sksg::Animator { public: SkottieAnimatorAdapter(sk_sp animation, float time_scale) : fAnimation(std::move(animation)) , fTimeScale(time_scale) { SkASSERT(fAnimation); } protected: void onTick(float t) { // TODO: we prolly need more sophisticated timeline mapping for nested animations. fAnimation->seek(t * fTimeScale); } private: const sk_sp fAnimation; const float fTimeScale; }; const auto data = fResourceProvider->load("", name); if (!data) { this->log(Logger::Level::kError, nullptr, "Could not load: %s.", name); return nullptr; } auto animation = Animation::Builder() .setResourceProvider(fResourceProvider) .setFontManager(fLazyFontMgr.getMaybeNull()) .make(static_cast(data->data()), data->size()); if (!animation) { this->log(Logger::Level::kError, nullptr, "Could not parse nested animation: %s.", name); return nullptr; } ascope->push_back( skstd::make_unique(animation, animation->duration() / fDuration)); return sk_make_sp(std::move(animation)); } sk_sp AnimationBuilder::attachAssetRef( const skjson::ObjectValue& jlayer, AnimatorScope* ascope, const std::function(const skjson::ObjectValue&, AnimatorScope*)>& func) const { const auto refId = ParseDefault(jlayer["refId"], SkString()); if (refId.isEmpty()) { this->log(Logger::Level::kError, nullptr, "Layer missing refId."); return nullptr; } if (refId.startsWith("$")) { return this->attachNestedAnimation(refId.c_str() + 1, ascope); } const auto* asset_info = fAssets.find(refId); if (!asset_info) { this->log(Logger::Level::kError, nullptr, "Asset not found: '%s'.", refId.c_str()); return nullptr; } if (asset_info->fIsAttaching) { this->log(Logger::Level::kError, nullptr, "Asset cycle detected for: '%s'", refId.c_str()); return nullptr; } asset_info->fIsAttaching = true; auto asset = func(*asset_info->fAsset, ascope); asset_info->fIsAttaching = false; return asset; } sk_sp AnimationBuilder::attachSolidLayer(const skjson::ObjectValue& jlayer, const LayerInfo&, AnimatorScope*) const { const auto size = SkSize::Make(ParseDefault(jlayer["sw"], 0.0f), ParseDefault(jlayer["sh"], 0.0f)); const skjson::StringValue* hex_str = jlayer["sc"]; uint32_t c; if (size.isEmpty() || !hex_str || *hex_str->begin() != '#' || !SkParse::FindHex(hex_str->begin() + 1, &c)) { this->log(Logger::Level::kError, &jlayer, "Could not parse solid layer."); return nullptr; } const SkColor color = 0xff000000 | c; return sksg::Draw::Make(sksg::Rect::Make(SkRect::MakeSize(size)), sksg::Color::Make(color)); } const AnimationBuilder::ImageAssetInfo* AnimationBuilder::loadImageAsset(const skjson::ObjectValue& jimage) const { const skjson::StringValue* name = jimage["p"]; const skjson::StringValue* path = jimage["u"]; if (!name) { return nullptr; } const auto name_cstr = name->begin(), path_cstr = path ? path->begin() : ""; const auto res_id = SkStringPrintf("%s|%s", path_cstr, name_cstr); if (auto* cached_info = fImageAssetCache.find(res_id)) { return cached_info; } auto asset = fResourceProvider->loadImageAsset(path_cstr, name_cstr); if (!asset) { this->log(Logger::Level::kError, nullptr, "Could not load image asset: %s/%s.", path_cstr, name_cstr); return nullptr; } const auto size = SkISize::Make(ParseDefault(jimage["w"], 0), ParseDefault(jimage["h"], 0)); return fImageAssetCache.set(res_id, { std::move(asset), size }); } sk_sp AnimationBuilder::attachImageAsset(const skjson::ObjectValue& jimage, const LayerInfo& layer_info, AnimatorScope* ascope) const { const auto* asset_info = this->loadImageAsset(jimage); if (!asset_info) { return nullptr; } SkASSERT(asset_info->fAsset); auto image = asset_info->fAsset->getFrame(0); if (!image) { this->log(Logger::Level::kError, nullptr, "Could not load first image asset frame."); return nullptr; } auto image_node = sksg::Image::Make(image); if (asset_info->fAsset->isMultiFrame()) { class MultiFrameAnimator final : public sksg::Animator { public: MultiFrameAnimator(sk_sp asset, sk_sp image_node, float time_bias, float time_scale) : fAsset(std::move(asset)) , fImageNode(std::move(image_node)) , fTimeBias(time_bias) , fTimeScale(time_scale) {} void onTick(float t) override { fImageNode->setImage(fAsset->getFrame((t + fTimeBias) * fTimeScale)); } private: sk_sp fAsset; sk_sp fImageNode; float fTimeBias, fTimeScale; }; ascope->push_back(skstd::make_unique(asset_info->fAsset, image_node, layer_info.fInPoint, 1 / fFrameRate)); } const auto asset_size = SkISize::Make( asset_info->fSize.width() > 0 ? asset_info->fSize.width() : image->width(), asset_info->fSize.height() > 0 ? asset_info->fSize.height() : image->height()); if (asset_size == image->bounds().size()) { // No resize needed. return std::move(image_node); } return sksg::TransformEffect::Make(std::move(image_node), SkMatrix::MakeRectToRect(SkRect::Make(image->bounds()), SkRect::Make(asset_size), SkMatrix::kCenter_ScaleToFit)); } sk_sp AnimationBuilder::attachImageLayer(const skjson::ObjectValue& jlayer, const LayerInfo& layer_info, AnimatorScope* ascope) const { return this->attachAssetRef(jlayer, ascope, [this, &layer_info] (const skjson::ObjectValue& jimage, AnimatorScope* ascope) { return this->attachImageAsset(jimage, layer_info, ascope); }); } sk_sp AnimationBuilder::attachNullLayer(const skjson::ObjectValue& layer, const LayerInfo&, AnimatorScope*) const { // Null layers are used solely to drive dependent transforms, // but we use free-floating sksg::Matrices for that purpose. return nullptr; } struct AnimationBuilder::AttachLayerContext { AttachLayerContext(const skjson::ArrayValue& jlayers, AnimatorScope* scope) : fLayerList(jlayers), fScope(scope) {} const skjson::ArrayValue& fLayerList; AnimatorScope* fScope; SkTHashMap> fLayerMatrixMap; sk_sp fCurrentMatte; sk_sp attachLayerTransform(const skjson::ObjectValue& jlayer, const AnimationBuilder* abuilder) { const auto layer_index = ParseDefault(jlayer["ind"], -1); if (layer_index < 0) return nullptr; if (auto* m = fLayerMatrixMap.find(layer_index)) return *m; return this->attachLayerTransformImpl(jlayer, abuilder, layer_index); } private: sk_sp attachParentLayerTransform(const skjson::ObjectValue& jlayer, const AnimationBuilder* abuilder, int layer_index) { const auto parent_index = ParseDefault(jlayer["parent"], -1); if (parent_index < 0 || parent_index == layer_index) return nullptr; if (auto* m = fLayerMatrixMap.find(parent_index)) return *m; for (const skjson::ObjectValue* l : fLayerList) { if (!l) continue; if (ParseDefault((*l)["ind"], -1) == parent_index) { return this->attachLayerTransformImpl(*l, abuilder, parent_index); } } return nullptr; } sk_sp attachLayerTransformImpl(const skjson::ObjectValue& jlayer, const AnimationBuilder* abuilder, int layer_index) { SkASSERT(!fLayerMatrixMap.find(layer_index)); // Add a stub entry to break recursion cycles. fLayerMatrixMap.set(layer_index, nullptr); auto parent_matrix = this->attachParentLayerTransform(jlayer, abuilder, layer_index); if (const skjson::ObjectValue* jtransform = jlayer["ks"]) { auto transform_node = (ParseDefault(jlayer["ddd"], 0) == 0) ? abuilder->attachMatrix2D(*jtransform, fScope, std::move(parent_matrix)) : abuilder->attachMatrix3D(*jtransform, fScope, std::move(parent_matrix)); return *fLayerMatrixMap.set(layer_index, std::move(transform_node)); } return nullptr; } }; sk_sp AnimationBuilder::attachLayer(const skjson::ObjectValue* jlayer, AttachLayerContext* layerCtx) const { if (!jlayer) return nullptr; const LayerInfo layer_info = { ParseDefault((*jlayer)["ip"], 0.0f), ParseDefault((*jlayer)["op"], 0.0f) }; if (layer_info.fInPoint >= layer_info.fOutPoint) { this->log(Logger::Level::kError, nullptr, "Invalid layer in/out points: %f/%f.", layer_info.fInPoint, layer_info.fOutPoint); return nullptr; } const AutoPropertyTracker apt(this, *jlayer); using LayerAttacher = sk_sp (AnimationBuilder::*)(const skjson::ObjectValue&, const LayerInfo&, AnimatorScope*) const; static constexpr LayerAttacher gLayerAttachers[] = { &AnimationBuilder::attachPrecompLayer, // 'ty': 0 &AnimationBuilder::attachSolidLayer, // 'ty': 1 &AnimationBuilder::attachImageLayer, // 'ty': 2 &AnimationBuilder::attachNullLayer, // 'ty': 3 &AnimationBuilder::attachShapeLayer, // 'ty': 4 &AnimationBuilder::attachTextLayer, // 'ty': 5 }; int type = ParseDefault((*jlayer)["ty"], -1); if (type < 0 || type >= SkTo(SK_ARRAY_COUNT(gLayerAttachers))) { return nullptr; } AnimatorScope layer_animators; // Layer content. auto layer = (this->*(gLayerAttachers[type]))(*jlayer, layer_info, &layer_animators); // Clip layers with explicit dimensions. float w = 0, h = 0; if (Parse((*jlayer)["w"], &w) && Parse((*jlayer)["h"], &h)) { layer = sksg::ClipEffect::Make(std::move(layer), sksg::Rect::Make(SkRect::MakeWH(w, h)), true); } // Optional layer mask. layer = AttachMask((*jlayer)["masksProperties"], this, &layer_animators, std::move(layer)); // Optional layer transform. if (auto layer_transform = layerCtx->attachLayerTransform(*jlayer, this)) { layer = sksg::TransformEffect::Make(std::move(layer), std::move(layer_transform)); } // Optional layer opacity. // TODO: de-dupe this "ks" lookup with matrix above. if (const skjson::ObjectValue* jtransform = (*jlayer)["ks"]) { layer = this->attachOpacity(*jtransform, &layer_animators, std::move(layer)); } // Optional layer effects. if (const skjson::ArrayValue* jeffects = (*jlayer)["ef"]) { layer = this->attachLayerEffects(*jeffects, &layer_animators, std::move(layer)); } class LayerController final : public sksg::GroupAnimator { public: LayerController(sksg::AnimatorList&& layer_animators, sk_sp controlNode, float in, float out) : INHERITED(std::move(layer_animators)) , fControlNode(std::move(controlNode)) , fIn(in) , fOut(out) {} void onTick(float t) override { const auto active = (t >= fIn && t <= fOut); // Keep the layer fully transparent except for its [in..out] lifespan. // (note: opacity == 0 disables rendering, while opacity == 1 is a noop) fControlNode->setOpacity(active ? 1 : 0); // Dispatch ticks only while active. if (active) this->INHERITED::onTick(t); } private: const sk_sp fControlNode; const float fIn, fOut; using INHERITED = sksg::GroupAnimator; }; auto controller_node = sksg::OpacityEffect::Make(std::move(layer)); if (!controller_node) { return nullptr; } layerCtx->fScope->push_back( skstd::make_unique(std::move(layer_animators), controller_node, layer_info.fInPoint, layer_info.fOutPoint)); if (ParseDefault((*jlayer)["td"], false)) { // This layer is a matte. We apply it as a mask to the next layer. layerCtx->fCurrentMatte = std::move(controller_node); return nullptr; } if (layerCtx->fCurrentMatte) { // There is a pending matte. Apply and reset. static constexpr sksg::MaskEffect::Mode gMaskModes[] = { sksg::MaskEffect::Mode::kNormal, // tt: 1 sksg::MaskEffect::Mode::kInvert, // tt: 2 }; const auto matteType = ParseDefault((*jlayer)["tt"], 1) - 1; if (matteType < SK_ARRAY_COUNT(gMaskModes)) { return sksg::MaskEffect::Make(std::move(controller_node), std::move(layerCtx->fCurrentMatte), gMaskModes[matteType]); } layerCtx->fCurrentMatte.reset(); } return std::move(controller_node); } sk_sp AnimationBuilder::attachComposition(const skjson::ObjectValue& comp, AnimatorScope* scope) const { const skjson::ArrayValue* jlayers = comp["layers"]; if (!jlayers) return nullptr; std::vector> layers; AttachLayerContext layerCtx(*jlayers, scope); layers.reserve(jlayers->size()); for (const auto& l : *jlayers) { if (auto layer = this->attachLayer(l, &layerCtx)) { layers.push_back(std::move(layer)); } } if (layers.empty()) { return nullptr; } // Layers are painted in bottom->top order. std::reverse(layers.begin(), layers.end()); layers.shrink_to_fit(); return sksg::Group::Make(std::move(layers)); } } // namespace internal } // namespace skottie