/* This file is part of Telegram Desktop, the official desktop version of Telegram messaging app, see https://telegram.org Telegram Desktop is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. It is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. In addition, as a special exception, the copyright holders give permission to link the code of portions of this program with the OpenSSL library. Full license: https://github.com/telegramdesktop/tdesktop/blob/master/LICENSE Copyright (c) 2014-2016 John Preston, https://desktop.telegram.org */ #pragma once #include "core/basic_types.h" #include #include namespace Media { namespace Clip { class Reader; class ReaderPointer { public: ReaderPointer(std_::nullptr_t = nullptr) { } explicit ReaderPointer(Reader *pointer) : _pointer(pointer) { } ReaderPointer(const ReaderPointer &other) = delete; ReaderPointer &operator=(const ReaderPointer &other) = delete; ReaderPointer(ReaderPointer &&other) : _pointer(base::take(other._pointer)) { } ReaderPointer &operator=(ReaderPointer &&other) { swap(other); return *this; } void swap(ReaderPointer &other) { qSwap(_pointer, other._pointer); } Reader *get() const { return valid() ? _pointer : nullptr; } Reader *operator->() const { return get(); } void setBad() { reset(); _pointer = BadPointer; } void reset() { ReaderPointer temp; swap(temp); } bool isBad() const { return (_pointer == BadPointer); } bool valid() const { return _pointer && !isBad(); } explicit operator bool() const { return valid(); } ~ReaderPointer(); private: Reader *_pointer = nullptr; static Reader *const BadPointer; }; class Manager; enum Notification { NotificationReinit, NotificationRepaint, }; } // namespace Clip } // namespace Media namespace anim { using transition = base::lambda_copy; extern transition linear; extern transition sineInOut; extern transition halfSine; extern transition easeOutBack; extern transition easeInCirc; extern transition easeOutCirc; extern transition easeInCubic; extern transition easeOutCirc; extern transition easeInQuint; extern transition easeOutQuint; inline transition bumpy(float64 bump) { auto dt0 = (bump - sqrt(bump * (bump - 1.))); auto k = (1 / (2 * dt0 - 1)); return [bump, dt0, k](float64 delta, float64 dt) { return delta * (bump - k * (dt - dt0) * (dt - dt0)); }; } // Basic animated value. class value { public: using ValueType = float64; value() = default; value(float64 from) : _cur(from), _from(from) { } value(float64 from, float64 to) : _cur(from), _from(from), _delta(to - from) { } void start(float64 to) { _from = _cur; _delta = to - _from; } void restart() { _delta = _from + _delta - _cur; _from = _cur; } float64 from() const { return _from; } float64 current() const { return _cur; } float64 to() const { return _from + _delta; } void add(float64 delta) { _from += delta; _cur += delta; } value &update(float64 dt, const transition &func) { _cur = _from + func(_delta, dt); return *this; } void finish() { _cur = _from + _delta; _from = _cur; _delta = 0; } private: float64 _cur = 0.; float64 _from = 0.; float64 _delta = 0.; }; using fvalue = value; class ivalue { // int animated value public: using ValueType = int; ivalue() = default; ivalue(int from) : _cur(from), _from(float64(from)) { } ivalue(int from, int to) : _cur(from), _from(float64(from)), _delta(float64(to - from)) { } void start(int32 to) { _from = float64(_cur); _delta = float64(to) - _from; } void restart() { _delta = _from + _delta - float64(_cur); _from = float64(_cur); } int from() const { return _from; } int current() const { return _cur; } int to() const { return qRound(_from + _delta); } void add(int delta) { _from += delta; _cur += delta; } ivalue &update(float64 dt, const transition &func) { _cur = qRound(_from + func(_delta, dt)); return *this; } void finish() { _cur = qRound(_from + _delta); _from = _cur; _delta = 0; } private: int _cur = 0; float64 _from = 0.; float64 _delta = 0.; }; void startManager(); void stopManager(); void registerClipManager(Media::Clip::Manager *manager); FORCE_INLINE int interpolate(int a, int b, float64 b_ratio) { return qRound(a + float64(b - a) * b_ratio); } #ifdef ARCH_CPU_32_BITS #define SHIFTED_USE_32BIT #endif // ARCH_CPU_32_BITS #ifdef SHIFTED_USE_32BIT using ShiftedMultiplier = uint32; struct Shifted { Shifted() = default; Shifted(uint32 low, uint32 high) : low(low), high(high) { } uint32 low = 0; uint32 high = 0; }; FORCE_INLINE Shifted operator+(Shifted a, Shifted b) { return Shifted(a.low + b.low, a.high + b.high); } FORCE_INLINE Shifted operator*(Shifted shifted, ShiftedMultiplier multiplier) { return Shifted(shifted.low * multiplier, shifted.high * multiplier); } FORCE_INLINE Shifted operator*(ShiftedMultiplier multiplier, Shifted shifted) { return Shifted(shifted.low * multiplier, shifted.high * multiplier); } FORCE_INLINE Shifted shifted(uint32 components) { return Shifted( (components & 0x000000FFU) | ((components & 0x0000FF00U) << 8), ((components & 0x00FF0000U) >> 16) | ((components & 0xFF000000U) >> 8)); } FORCE_INLINE uint32 unshifted(Shifted components) { return ((components.low & 0x0000FF00U) >> 8) | ((components.low & 0xFF000000U) >> 16) | ((components.high & 0x0000FF00U) << 8) | (components.high & 0xFF000000U); } FORCE_INLINE Shifted reshifted(Shifted components) { return Shifted((components.low >> 8) & 0x00FF00FFU, (components.high >> 8) & 0x00FF00FFU); } FORCE_INLINE Shifted shifted(QColor color) { // Make it premultiplied. auto alpha = static_cast((color.alpha() & 0xFF) + 1); auto components = Shifted(static_cast(color.blue() & 0xFF) | (static_cast(color.green() & 0xFF) << 16), static_cast(color.red() & 0xFF) | (static_cast(255) << 16)); return reshifted(components * alpha); } FORCE_INLINE uint32 getPremultiplied(QColor color) { // Make it premultiplied. auto alpha = static_cast((color.alpha() & 0xFF) + 1); auto components = Shifted(static_cast(color.blue() & 0xFF) | (static_cast(color.green() & 0xFF) << 16), static_cast(color.red() & 0xFF) | (static_cast(255) << 16)); return unshifted(components * alpha); } FORCE_INLINE uint32 getAlpha(Shifted components) { return (components.high & 0x00FF0000U) >> 16; } FORCE_INLINE Shifted non_premultiplied(QColor color) { return Shifted(static_cast(color.blue() & 0xFF) | (static_cast(color.green() & 0xFF) << 16), static_cast(color.red() & 0xFF) | (static_cast(color.alpha() & 0xFF) << 16)); } FORCE_INLINE QColor color(QColor a, QColor b, float64 b_ratio) { auto bOpacity = snap(interpolate(0, 255, b_ratio), 0, 255) + 1; auto aOpacity = (256 - bOpacity); auto components = (non_premultiplied(a) * aOpacity + non_premultiplied(b) * bOpacity); return { static_cast((components.high >> 8) & 0xFF), static_cast((components.low >> 24) & 0xFF), static_cast((components.low >> 8) & 0xFF), static_cast((components.high >> 24) & 0xFF), }; } #else // SHIFTED_USE_32BIT using ShiftedMultiplier = uint64; struct Shifted { Shifted() = default; Shifted(uint32 value) : value(value) { } Shifted(uint64 value) : value(value) { } uint64 value = 0; }; FORCE_INLINE Shifted operator+(Shifted a, Shifted b) { return Shifted(a.value + b.value); } FORCE_INLINE Shifted operator*(Shifted shifted, ShiftedMultiplier multiplier) { return Shifted(shifted.value * multiplier); } FORCE_INLINE Shifted operator*(ShiftedMultiplier multiplier, Shifted shifted) { return Shifted(shifted.value * multiplier); } FORCE_INLINE Shifted shifted(uint32 components) { auto wide = static_cast(components); return (wide & 0x00000000000000FFULL) | ((wide & 0x000000000000FF00ULL) << 8) | ((wide & 0x0000000000FF0000ULL) << 16) | ((wide & 0x00000000FF000000ULL) << 24); } FORCE_INLINE uint32 unshifted(Shifted components) { return static_cast((components.value & 0x000000000000FF00ULL) >> 8) | static_cast((components.value & 0x00000000FF000000ULL) >> 16) | static_cast((components.value & 0x0000FF0000000000ULL) >> 24) | static_cast((components.value & 0xFF00000000000000ULL) >> 32); } FORCE_INLINE Shifted reshifted(Shifted components) { return (components.value >> 8) & 0x00FF00FF00FF00FFULL; } FORCE_INLINE Shifted shifted(QColor color) { // Make it premultiplied. auto alpha = static_cast((color.alpha() & 0xFF) + 1); auto components = static_cast(color.blue() & 0xFF) | (static_cast(color.green() & 0xFF) << 16) | (static_cast(color.red() & 0xFF) << 32) | (static_cast(255) << 48); return reshifted(components * alpha); } FORCE_INLINE uint32 getPremultiplied(QColor color) { // Make it premultiplied. auto alpha = static_cast((color.alpha() & 0xFF) + 1); auto components = static_cast(color.blue() & 0xFF) | (static_cast(color.green() & 0xFF) << 16) | (static_cast(color.red() & 0xFF) << 32) | (static_cast(255) << 48); return unshifted(components * alpha); } FORCE_INLINE uint32 getAlpha(Shifted components) { return (components.value & 0x00FF000000000000ULL) >> 48; } FORCE_INLINE Shifted non_premultiplied(QColor color) { return static_cast(color.blue() & 0xFF) | (static_cast(color.green() & 0xFF) << 16) | (static_cast(color.red() & 0xFF) << 32) | (static_cast(color.alpha() & 0xFF) << 48); } FORCE_INLINE QColor color(QColor a, QColor b, float64 b_ratio) { auto bOpacity = snap(interpolate(0, 255, b_ratio), 0, 255) + 1; auto aOpacity = (256 - bOpacity); auto components = (non_premultiplied(a) * aOpacity + non_premultiplied(b) * bOpacity); return { static_cast((components.value >> 40) & 0xFF), static_cast((components.value >> 24) & 0xFF), static_cast((components.value >> 8) & 0xFF), static_cast((components.value >> 56) & 0xFF), }; } #endif // SHIFTED_USE_32BIT FORCE_INLINE QColor color(const style::color &a, QColor b, float64 b_ratio) { return color(a->c, b, b_ratio); } FORCE_INLINE QColor color(QColor a, const style::color &b, float64 b_ratio) { return color(a, b->c, b_ratio); } FORCE_INLINE QColor color(const style::color &a, const style::color &b, float64 b_ratio) { return color(a->c, b->c, b_ratio); } FORCE_INLINE QPen pen(QColor a, QColor b, float64 b_ratio) { return color(a, b, b_ratio); } FORCE_INLINE QPen pen(const style::color &a, QColor b, float64 b_ratio) { return (b_ratio > 0) ? pen(a->c, b, b_ratio) : a; } FORCE_INLINE QPen pen(QColor a, const style::color &b, float64 b_ratio) { return (b_ratio < 1) ? pen(a, b->c, b_ratio) : b; } FORCE_INLINE QPen pen(const style::color &a, const style::color &b, float64 b_ratio) { return (b_ratio > 0) ? ((b_ratio < 1) ? pen(a->c, b->c, b_ratio) : b) : a; } FORCE_INLINE QBrush brush(QColor a, QColor b, float64 b_ratio) { return color(a, b, b_ratio); } FORCE_INLINE QBrush brush(const style::color &a, QColor b, float64 b_ratio) { return (b_ratio > 0) ? brush(a->c, b, b_ratio) : a; } FORCE_INLINE QBrush brush(QColor a, const style::color &b, float64 b_ratio) { return (b_ratio < 1) ? brush(a, b->c, b_ratio) : b; } FORCE_INLINE QBrush brush(const style::color &a, const style::color &b, float64 b_ratio) { return (b_ratio > 0) ? ((b_ratio < 1) ? brush(a->c, b->c, b_ratio) : b) : a; } }; class Animation; class AnimationImplementation { public: virtual void start() {} virtual void step(Animation *a, uint64 ms, bool timer) = 0; virtual ~AnimationImplementation() {} }; class AnimationCallbacks { public: AnimationCallbacks(AnimationImplementation *implementation) : _implementation(implementation) {} AnimationCallbacks(const AnimationCallbacks &other) = delete; AnimationCallbacks &operator=(const AnimationCallbacks &other) = delete; AnimationCallbacks(AnimationCallbacks &&other) : _implementation(other._implementation) { other._implementation = nullptr; } AnimationCallbacks &operator=(AnimationCallbacks &&other) { std::swap(_implementation, other._implementation); return *this; } void start() { _implementation->start(); } void step(Animation *a, uint64 ms, bool timer) { _implementation->step(a, ms, timer); } ~AnimationCallbacks() { delete base::take(_implementation); } private: AnimationImplementation *_implementation; }; class Animation { public: Animation(AnimationCallbacks &&callbacks) : _callbacks(std_::move(callbacks)) , _animating(false) { } void start(); void stop(); void step(uint64 ms, bool timer = false) { _callbacks.step(this, ms, timer); } void step() { step(getms(), false); } bool animating() const { return _animating; } ~Animation() { if (_animating) stop(); } private: AnimationCallbacks _callbacks; bool _animating; }; template class AnimationCallbacksRelative : public AnimationImplementation { public: typedef void (Type::*Method)(float64, bool); AnimationCallbacksRelative(Type *obj, Method method) : _started(0), _obj(obj), _method(method) { } void start() { _started = float64(getms()); } void step(Animation *a, uint64 ms, bool timer) { (_obj->*_method)(ms - _started, timer); } private: float64 _started; Type *_obj; Method _method; }; template AnimationCallbacks animation(Type *obj, typename AnimationCallbacksRelative::Method method) { return AnimationCallbacks(new AnimationCallbacksRelative(obj, method)); } template class AnimationCallbacksAbsolute : public AnimationImplementation { public: typedef void (Type::*Method)(uint64, bool); AnimationCallbacksAbsolute(Type *obj, Method method) : _obj(obj), _method(method) { } void step(Animation *a, uint64 ms, bool timer) { (_obj->*_method)(ms, timer); } private: Type *_obj; Method _method; }; template AnimationCallbacks animation(Type *obj, typename AnimationCallbacksAbsolute::Method method) { return AnimationCallbacks(new AnimationCallbacksAbsolute(obj, method)); } template class AnimationCallbacksRelativeWithParam : public AnimationImplementation { public: typedef void (Type::*Method)(Param, float64, bool); AnimationCallbacksRelativeWithParam(Param param, Type *obj, Method method) : _started(0), _param(param), _obj(obj), _method(method) { } void start() { _started = float64(getms()); } void step(Animation *a, uint64 ms, bool timer) { (_obj->*_method)(_param, ms - _started, timer); } private: float64 _started; Param _param; Type *_obj; Method _method; }; template AnimationCallbacks animation(Param param, Type *obj, typename AnimationCallbacksRelativeWithParam::Method method) { return AnimationCallbacks(new AnimationCallbacksRelativeWithParam(param, obj, method)); } template class AnimationCallbacksAbsoluteWithParam : public AnimationImplementation { public: typedef void (Type::*Method)(Param, uint64, bool); AnimationCallbacksAbsoluteWithParam(Param param, Type *obj, Method method) : _param(param), _obj(obj), _method(method) { } void step(Animation *a, uint64 ms, bool timer) { (_obj->*_method)(_param, ms, timer); } private: Param _param; Type *_obj; Method _method; }; template AnimationCallbacks animation(Param param, Type *obj, typename AnimationCallbacksAbsoluteWithParam::Method method) { return AnimationCallbacks(new AnimationCallbacksAbsoluteWithParam(param, obj, method)); } template class SimpleAnimation { public: using ValueType = typename AnimType::ValueType; using Callback = base::lambda; void step(uint64 ms) { if (_data) { _data->a_animation.step(ms); if (_data && !_data->a_animation.animating()) { _data.reset(); } } } bool animating() const { if (_data) { if (_data->a_animation.animating()) { return true; } _data.reset(); } return false; } bool animating(uint64 ms) { step(ms); return animating(); } ValueType current() const { t_assert(_data != nullptr); return _data->value.current(); } ValueType current(const ValueType &def) const { return _data ? current() : def; } ValueType current(uint64 ms, const ValueType &def) { return animating(ms) ? current() : def; } template void start(Lambda &&updateCallback, const ValueType &from, const ValueType &to, float64 duration, const anim::transition &transition = anim::linear) { if (!_data) { _data = std_::make_unique(from, std_::forward(updateCallback)); } _data->value.start(to); _data->duration = duration; _data->transition = transition; _data->a_animation.start(); } void finish() { if (_data) { _data->value.finish(); _data->a_animation.stop(); _data.reset(); } } private: struct Data { template ::value>> Data(const ValueType &from, Lambda &&updateCallback) : value(from, from) , a_animation(animation(this, &Data::step)) , updateCallback(std_::move(updateCallback)) { } Data(const ValueType &from, const base::lambda_copy &updateCallback) : value(from, from) , a_animation(animation(this, &Data::step)) , updateCallback(base::lambda_copy(updateCallback)) { } void step(float64 ms, bool timer) { auto dt = (ms >= duration) ? 1. : (ms / duration); if (dt >= 1) { value.finish(); a_animation.stop(); } else { value.update(dt, transition); } updateCallback(); } AnimType value; Animation a_animation; Callback updateCallback; float64 duration = 0.; anim::transition transition = anim::linear; }; mutable std_::unique_ptr _data; }; using FloatAnimation = SimpleAnimation; using IntAnimation = SimpleAnimation; class AnimationManager : public QObject { Q_OBJECT public: AnimationManager(); void start(Animation *obj); void stop(Animation *obj); public slots: void timeout(); void clipCallback(Media::Clip::Reader *reader, qint32 threadIndex, qint32 notification); private: using AnimatingObjects = OrderedSet; AnimatingObjects _objects, _starting, _stopping; QTimer _timer; bool _iterating; };