1 /*
2  * Copyright 2020 Google Inc.
3  *
4  * Use of this source code is governed by a BSD-style license that can be
5  * found in the LICENSE file.
6  */
7 
8 #include "modules/skottie/src/animator/KeyframeAnimator.h"
9 
10 #include "modules/skottie/src/SkottieJson.h"
11 
12 #define DUMP_KF_RECORDS 0
13 
14 namespace skottie::internal {
15 
16 KeyframeAnimator::~KeyframeAnimator() = default;
17 
getLERPInfo(float t) const18 KeyframeAnimator::LERPInfo KeyframeAnimator::getLERPInfo(float t) const {
19     SkASSERT(!fKFs.empty());
20 
21     if (t <= fKFs.front().t) {
22         // Constant/clamped segment.
23         return { 0, fKFs.front().v, fKFs.front().v };
24     }
25     if (t >= fKFs.back().t) {
26         // Constant/clamped segment.
27         return { 0, fKFs.back().v, fKFs.back().v };
28     }
29 
30     // Cache the current segment (most queries have good locality).
31     if (!fCurrentSegment.contains(t)) {
32         fCurrentSegment = this->find_segment(t);
33     }
34     SkASSERT(fCurrentSegment.contains(t));
35 
36     if (fCurrentSegment.kf0->mapping == Keyframe::kConstantMapping) {
37         // Constant/hold segment.
38         return { 0, fCurrentSegment.kf0->v, fCurrentSegment.kf0->v };
39     }
40 
41     return {
42         this->compute_weight(fCurrentSegment, t),
43         fCurrentSegment.kf0->v,
44         fCurrentSegment.kf1->v,
45     };
46 }
47 
find_segment(float t) const48 KeyframeAnimator::KFSegment KeyframeAnimator::find_segment(float t) const {
49     SkASSERT(fKFs.size() > 1);
50     SkASSERT(t > fKFs.front().t);
51     SkASSERT(t < fKFs.back().t);
52 
53     auto kf0 = &fKFs.front(),
54          kf1 = &fKFs.back();
55 
56     // Binary-search, until we reduce to sequential keyframes.
57     while (kf0 + 1 != kf1) {
58         SkASSERT(kf0 < kf1);
59         SkASSERT(kf0->t <= t && t < kf1->t);
60 
61         const auto mid_kf = kf0 + (kf1 - kf0) / 2;
62 
63         if (t >= mid_kf->t) {
64             kf0 = mid_kf;
65         } else {
66             kf1 = mid_kf;
67         }
68     }
69 
70     return {kf0, kf1};
71 }
72 
compute_weight(const KFSegment & seg,float t) const73 float KeyframeAnimator::compute_weight(const KFSegment &seg, float t) const {
74     SkASSERT(seg.contains(t));
75 
76     // Linear weight.
77     auto w = (t - seg.kf0->t) / (seg.kf1->t - seg.kf0->t);
78 
79     // Optional cubic mapper.
80     if (seg.kf0->mapping >= Keyframe::kCubicIndexOffset) {
81         SkASSERT(seg.kf0->v != seg.kf1->v);
82         const auto mapper_index = SkToSizeT(seg.kf0->mapping - Keyframe::kCubicIndexOffset);
83         w = fCMs[mapper_index].computeYFromX(w);
84     }
85 
86     return w;
87 }
88 
89 KeyframeAnimatorBuilder::~KeyframeAnimatorBuilder() = default;
90 
parseKeyframes(const AnimationBuilder & abuilder,const skjson::ArrayValue & jkfs)91 bool KeyframeAnimatorBuilder::parseKeyframes(const AnimationBuilder& abuilder,
92                                              const skjson::ArrayValue& jkfs) {
93     // Keyframe format:
94     //
95     // [                        // array of
96     //   {
97     //     "t": <float>         // keyframe time
98     //     "s": <T>             // keyframe value
99     //     "h": <bool>          // optional constant/hold keyframe marker
100     //     "i": [<float,float>] // optional "in" Bezier control point
101     //     "o": [<float,float>] // optional "out" Bezier control point
102     //   },
103     //   ...
104     // ]
105     //
106     // Legacy keyframe format:
107     //
108     // [                        // array of
109     //   {
110     //     "t": <float>         // keyframe time
111     //     "s": <T>             // keyframe start value
112     //     "e": <T>             // keyframe end value
113     //     "h": <bool>          // optional constant/hold keyframe marker (constant mapping)
114     //     "i": [<float,float>] // optional "in" Bezier control point (cubic mapping)
115     //     "o": [<float,float>] // optional "out" Bezier control point (cubic mapping)
116     //   },
117     //   ...
118     //   {
119     //     "t": <float>         // last keyframe only specifies a t
120     //                          // the value is prev. keyframe end value
121     //   }
122     // ]
123     //
124     // Note: the legacy format contains duplicates, as normal frames are contiguous:
125     //       frame(n).e == frame(n+1).s
126 
127     const auto parse_value = [&](const skjson::ObjectValue& jkf, size_t i, Keyframe::Value* v) {
128         auto parsed = this->parseKFValue(abuilder, jkf, jkf["s"], v);
129 
130         // A missing value is only OK for the last legacy KF
131         // (where it is pulled from prev KF 'end' value).
132         if (!parsed && i > 0 && i == jkfs.size() - 1) {
133             const skjson::ObjectValue* prev_kf = jkfs[i - 1];
134             SkASSERT(prev_kf);
135             parsed = this->parseKFValue(abuilder, jkf, (*prev_kf)["e"], v);
136         }
137 
138         return parsed;
139     };
140 
141     bool constant_value = true;
142 
143     fKFs.reserve(jkfs.size());
144 
145     for (size_t i = 0; i < jkfs.size(); ++i) {
146         const skjson::ObjectValue* jkf = jkfs[i];
147         if (!jkf) {
148             return false;
149         }
150 
151         float t;
152         if (!Parse<float>((*jkf)["t"], &t)) {
153             return false;
154         }
155 
156         Keyframe::Value v;
157         if (!parse_value(*jkf, i, &v)) {
158             return false;
159         }
160 
161         if (i > 0) {
162             auto& prev_kf = fKFs.back();
163 
164             // Ts must be strictly monotonic.
165             if (t <= prev_kf.t) {
166                 return false;
167             }
168 
169             // We can power-reduce the mapping of repeated values (implicitly constant).
170             if (v == prev_kf.v) {
171                 prev_kf.mapping = Keyframe::kConstantMapping;
172             }
173         }
174 
175         fKFs.push_back({t, v, this->parseMapping(*jkf)});
176 
177         constant_value = constant_value && (v == fKFs.front().v);
178     }
179 
180     SkASSERT(fKFs.size() == jkfs.size());
181     fCMs.shrink_to_fit();
182 
183     if (constant_value) {
184         // When all keyframes hold the same value, we can discard all but one
185         // (interpolation has no effect).
186         fKFs.resize(1);
187     }
188 
189 #if(DUMP_KF_RECORDS)
190     SkDEBUGF("Animator[%p], values: %lu, KF records: %zu\n",
191              this, fKFs.back().v_idx + 1, fKFs.size());
192     for (const auto& kf : fKFs) {
193         SkDEBUGF("  { t: %1.3f, v_idx: %lu, mapping: %lu }\n", kf.t, kf.v_idx, kf.mapping);
194     }
195 #endif
196     return true;
197 }
198 
parseMapping(const skjson::ObjectValue & jkf)199 uint32_t KeyframeAnimatorBuilder::parseMapping(const skjson::ObjectValue& jkf) {
200     if (ParseDefault(jkf["h"], false)) {
201         return Keyframe::kConstantMapping;
202     }
203 
204     SkPoint c0, c1;
205     if (!Parse(jkf["o"], &c0) ||
206         !Parse(jkf["i"], &c1) ||
207         SkCubicMap::IsLinear(c0, c1)) {
208         return Keyframe::kLinearMapping;
209     }
210 
211     // De-dupe sequential cubic mappers.
212     if (c0 != prev_c0 || c1 != prev_c1 || fCMs.empty()) {
213         fCMs.emplace_back(c0, c1);
214         prev_c0 = c0;
215         prev_c1 = c1;
216     }
217 
218     SkASSERT(!fCMs.empty());
219     return SkToU32(fCMs.size()) - 1 + Keyframe::kCubicIndexOffset;
220 }
221 
222 } // namespace skottie::internal
223