/*
 * Copyright 2015 Google Inc.
 *
 * Use of this source code is governed by a BSD-style license that can be
 * found in the LICENSE file.
 */

#include "include/core/SkScalar.h"
#include "include/core/SkTime.h"

#ifndef AnimTimer_DEFINED
#define AnimTimer_DEFINED

/**
 *  Class to track a "timer". It supports 3 states: stopped, paused, and running.
 *  Playback speed is variable.
 *
 *  The caller must call updateTime() to resync with the clock (typically just before
 *  using the timer). Forcing the caller to do this ensures that the timer's return values
 *  are consistent if called repeatedly, as they only reflect the time since the last
 *  calle to updateTimer().
 */
class AnimTimer {
public:
    enum State { kStopped_State, kPaused_State, kRunning_State };

    /**
     *  Class begins in the "stopped" state.
     */
    AnimTimer() : fPreviousNanos(0), fElapsedNanos(0), fSpeed(1), fState(kStopped_State) {}

    AnimTimer(double elapsed)
            : fPreviousNanos(0), fElapsedNanos(elapsed), fSpeed(1), fState(kRunning_State) {}

    bool isStopped() const { return kStopped_State == fState; }
    bool isRunning() const { return kRunning_State == fState; }
    bool isPaused() const { return kPaused_State == fState; }

    /**
     *  Stops the timer, and resets it, such that the next call to run or togglePauseResume
     *  will begin at time 0.
     */
    void stop() { this->setState(kStopped_State); }

    /**
     *  If the timer is paused or stopped, it will resume (or start if it was stopped).
     */
    void run() { this->setState(kRunning_State); }

    /**
     *  Control the rate at which time advances.
     */
    float getSpeed() const { return fSpeed; }
    void  setSpeed(float speed) { fSpeed = speed; }

    /**
     *  If the timer is stopped, start running, else it toggles between paused and running.
     */
    void togglePauseResume() {
        if (kRunning_State == fState) {
            this->setState(kPaused_State);
        } else {
            this->setState(kRunning_State);
        }
    }

    /**
     *  Call this each time you want to sample the clock for the timer. This is NOT done
     *  automatically, so that repeated calls to msec() or secs() will always return the
     *  same value.
     *
     *  This may safely be called with the timer in any state.
     */
    void updateTime() {
        if (kRunning_State == fState) {
            double now = SkTime::GetNSecs();
            fElapsedNanos += (now - fPreviousNanos) * fSpeed;
            fPreviousNanos = now;
        }
    }

    /**
     *  Return the time in milliseconds the timer has been in the running state.
     *  Returns 0 if the timer is stopped. Behavior is undefined if the timer
     *  has been running longer than SK_MSecMax.
     */
    SkMSec msec() const {
        const double msec = fElapsedNanos * 1e-6;
        SkASSERT(SK_MSecMax >= msec);
        return static_cast<SkMSec>(msec);
    }

    /**
     *  Return the time in seconds the timer has been in the running state.
     *  Returns 0 if the timer is stopped.
     */
    double secs() const { return fElapsedNanos * 1e-9; }

    /**
     *  Return the time in seconds the timer has been in the running state,
     *  scaled by "speed" and (if not zero) mod by period.
     *  Returns 0 if the timer is stopped.
     */
    SkScalar scaled(SkScalar speed, SkScalar period = 0) const {
        double value = this->secs() * speed;
        if (period) {
            value = ::fmod(value, SkScalarToDouble(period));
        }
        return SkDoubleToScalar(value);
    }

    /**
     * Transitions from ends->mid->ends linearly over period seconds. The phase specifies a phase
     * shift in seconds.
     */
    SkScalar pingPong(SkScalar period, SkScalar phase, SkScalar ends, SkScalar mid) const {
        return PingPong(this->secs(), period, phase, ends, mid);
    }

    /** Helper for computing a ping-pong value without a AnimTimer object. */
    static SkScalar PingPong(double   t,
                             SkScalar period,
                             SkScalar phase,
                             SkScalar ends,
                             SkScalar mid) {
        double value = ::fmod(t + phase, period);
        double half  = period / 2.0;
        double diff  = ::fabs(value - half);
        return SkDoubleToScalar(ends + (1.0 - diff / half) * (mid - ends));
    }

private:
    double fPreviousNanos;
    double fElapsedNanos;
    float  fSpeed;
    State  fState;

    void setState(State newState) {
        switch (newState) {
            case kStopped_State:
                fPreviousNanos = fElapsedNanos = 0;
                fState                         = kStopped_State;
                break;
            case kPaused_State:
                if (kRunning_State == fState) {
                    fState = kPaused_State;
                }  // else stay stopped or paused
                break;
            case kRunning_State:
                switch (fState) {
                    case kStopped_State:
                        fPreviousNanos = SkTime::GetNSecs();
                        fElapsedNanos  = 0;
                        break;
                    case kPaused_State:  // they want "resume"
                        fPreviousNanos = SkTime::GetNSecs();
                        break;
                    case kRunning_State: break;
                }
                fState = kRunning_State;
                break;
        }
    }
};

#endif