/* * Copyright 2017 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package android.media; import android.annotation.IntDef; import android.annotation.NonNull; import android.annotation.Nullable; import android.os.Parcel; import android.os.Parcelable; import java.lang.annotation.Retention; import java.lang.annotation.RetentionPolicy; import java.lang.AutoCloseable; import java.lang.ref.WeakReference; import java.util.Arrays; import java.util.Objects; /** * The {@code VolumeShaper} class is used to automatically control audio volume during media * playback, allowing simple implementation of transition effects and ducking. * * The {@link VolumeShaper} appears as an additional scaling on the audio output, * and adjusts independently of track or stream volume controls. */ public final class VolumeShaper implements AutoCloseable { /* member variables */ private int mId; private final WeakReference mWeakPlayerBase; /* package */ VolumeShaper( @NonNull Configuration configuration, @NonNull PlayerBase playerBase) { mWeakPlayerBase = new WeakReference(playerBase); mId = applyPlayer(configuration, new Operation.Builder().defer().build()); } /* package */ int getId() { return mId; } /** * Applies the {@link VolumeShaper.Operation} to the {@code VolumeShaper}. * @param operation the {@code operation} to apply. */ public void apply(@NonNull Operation operation) { /* void */ applyPlayer(new VolumeShaper.Configuration(mId), operation); } /** * Replaces the current {@code VolumeShaper} * {@code configuration} with a new {@code configuration}. * * This allows the user to change the volume shape * while the existing {@code VolumeShaper} is in effect. * * @param configuration the new {@code configuration} to use. * @param operation the operation to apply to the {@code VolumeShaper} * @param join if true, match the start volume of the * new {@code configuration} to the current volume of the existing * {@code VolumeShaper}, to avoid discontinuity. */ public void replace( @NonNull Configuration configuration, @NonNull Operation operation, boolean join) { mId = applyPlayer( configuration, new Operation.Builder(operation).replace(mId, join).build()); } /** * Returns the current volume scale attributable to the {@code VolumeShaper}. * * @return the volume, linearly represented as a value between 0.f and 1.f. */ public float getVolume() { return getStatePlayer(mId).getVolume(); } /** * Releases the {@code VolumeShaper} object; any volume scale due to the * {@code VolumeShaper} is removed. */ @Override public void close() { try { /* void */ applyPlayer( new VolumeShaper.Configuration(mId), new Operation.Builder().terminate().build()); } catch (IllegalStateException ise) { ; // ok } if (mWeakPlayerBase != null) { mWeakPlayerBase.clear(); } } @Override protected void finalize() { close(); // ensure we remove the native volume shaper } /** * Internal call to apply the configuration and operation to the Player. * Returns a valid shaper id or throws the appropriate exception. * @param configuration * @param operation * @return id a non-negative shaper id. * @throws IllegalStateException if the player has been deallocated or is uninitialized. */ private int applyPlayer( @NonNull VolumeShaper.Configuration configuration, @NonNull VolumeShaper.Operation operation) { final int id; if (mWeakPlayerBase != null) { PlayerBase player = mWeakPlayerBase.get(); if (player == null) { throw new IllegalStateException("player deallocated"); } id = player.playerApplyVolumeShaper(configuration, operation); } else { throw new IllegalStateException("uninitialized shaper"); } if (id < 0) { // TODO - get INVALID_OPERATION from platform. final int VOLUME_SHAPER_INVALID_OPERATION = -38; // must match with platform // Due to RPC handling, we translate integer codes to exceptions right before // delivering to the user. if (id == VOLUME_SHAPER_INVALID_OPERATION) { throw new IllegalStateException("player or volume shaper deallocated"); } else { throw new IllegalArgumentException("invalid configuration or operation: " + id); } } return id; } /** * Internal call to retrieve the current VolumeShaper state. * @param id * @return the current {@vode VolumeShaper.State} * @throws IllegalStateException if the player has been deallocated or is uninitialized. */ private @NonNull VolumeShaper.State getStatePlayer(int id) { final VolumeShaper.State state; if (mWeakPlayerBase != null) { PlayerBase player = mWeakPlayerBase.get(); if (player == null) { throw new IllegalStateException("player deallocated"); } state = player.playerGetVolumeShaperState(id); } else { throw new IllegalStateException("uninitialized shaper"); } if (state == null) { throw new IllegalStateException("shaper cannot be found"); } return state; } /** * The {@code VolumeShaper.Configuration} class contains curve * and duration information. * It is constructed by the {@link VolumeShaper.Configuration.Builder}. *

* A {@code VolumeShaper.Configuration} is used by * {@link VolumeAutomation#createVolumeShaper(Configuration) * VolumeAutomation.createVolumeShaper(Configuration)} to create * a {@code VolumeShaper} and * by {@link VolumeShaper#replace(Configuration, Operation, boolean) * VolumeShaper.replace(Configuration, Operation, boolean)} * to replace an existing {@code configuration}. */ public static final class Configuration implements Parcelable { private static final int MAXIMUM_CURVE_POINTS = 16; /** * Returns the maximum number of curve points allowed for * {@link VolumeShaper.Builder#setCurve(float[], float[])}. */ public static int getMaximumCurvePoints() { return MAXIMUM_CURVE_POINTS; } // These values must match the native VolumeShaper::Configuration::Type /** @hide */ @IntDef({ TYPE_ID, TYPE_SCALE, }) @Retention(RetentionPolicy.SOURCE) public @interface Type {} /** * Specifies a {@link VolumeShaper} handle created by {@link #VolumeShaper(int)} * from an id returned by {@code setVolumeShaper()}. * The type, curve, etc. may not be queried from * a {@code VolumeShaper} object of this type; * the handle is used to identify and change the operation of * an existing {@code VolumeShaper} sent to the player. */ /* package */ static final int TYPE_ID = 0; /** * Specifies a {@link VolumeShaper} to be used * as an additional scale to the current volume. * This is created by the {@link VolumeShaper.Builder}. */ /* package */ static final int TYPE_SCALE = 1; // These values must match the native InterpolatorType enumeration. /** @hide */ @IntDef({ INTERPOLATOR_TYPE_STEP, INTERPOLATOR_TYPE_LINEAR, INTERPOLATOR_TYPE_CUBIC, INTERPOLATOR_TYPE_CUBIC_MONOTONIC, }) @Retention(RetentionPolicy.SOURCE) public @interface InterpolatorType {} /** * Stepwise volume curve. */ public static final int INTERPOLATOR_TYPE_STEP = 0; /** * Linear interpolated volume curve. */ public static final int INTERPOLATOR_TYPE_LINEAR = 1; /** * Cubic interpolated volume curve. * This is default if unspecified. */ public static final int INTERPOLATOR_TYPE_CUBIC = 2; /** * Cubic interpolated volume curve * that preserves local monotonicity. * So long as the control points are locally monotonic, * the curve interpolation between those points are monotonic. * This is useful for cubic spline interpolated * volume ramps and ducks. */ public static final int INTERPOLATOR_TYPE_CUBIC_MONOTONIC = 3; // These values must match the native VolumeShaper::Configuration::InterpolatorType /** @hide */ @IntDef({ OPTION_FLAG_VOLUME_IN_DBFS, OPTION_FLAG_CLOCK_TIME, }) @Retention(RetentionPolicy.SOURCE) public @interface OptionFlag {} /** * @hide * Use a dB full scale volume range for the volume curve. *

* The volume scale is typically from 0.f to 1.f on a linear scale; * this option changes to -inf to 0.f on a db full scale, * where 0.f is equivalent to a scale of 1.f. */ public static final int OPTION_FLAG_VOLUME_IN_DBFS = (1 << 0); /** * @hide * Use clock time instead of media time. *

* The default implementation of {@code VolumeShaper} is to apply * volume changes by the media time of the player. * Hence, the {@code VolumeShaper} will speed or slow down to * match player changes of playback rate, pause, or resume. *

* The {@code OPTION_FLAG_CLOCK_TIME} option allows the {@code VolumeShaper} * progress to be determined by clock time instead of media time. */ public static final int OPTION_FLAG_CLOCK_TIME = (1 << 1); private static final int OPTION_FLAG_PUBLIC_ALL = OPTION_FLAG_VOLUME_IN_DBFS | OPTION_FLAG_CLOCK_TIME; /** * A one second linear ramp from silence to full volume. * Use {@link VolumeShaper.Builder#reflectTimes()} * or {@link VolumeShaper.Builder#invertVolumes()} to generate * the matching linear duck. */ public static final Configuration LINEAR_RAMP = new VolumeShaper.Configuration.Builder() .setInterpolatorType(INTERPOLATOR_TYPE_LINEAR) .setCurve(new float[] {0.f, 1.f} /* times */, new float[] {0.f, 1.f} /* volumes */) .setDurationMs(1000.) .build(); /** * A one second cubic ramp from silence to full volume. * Use {@link VolumeShaper.Builder#reflectTimes()} * or {@link VolumeShaper.Builder#invertVolumes()} to generate * the matching cubic duck. */ public static final Configuration CUBIC_RAMP = new VolumeShaper.Configuration.Builder() .setInterpolatorType(INTERPOLATOR_TYPE_CUBIC) .setCurve(new float[] {0.f, 1.f} /* times */, new float[] {0.f, 1.f} /* volumes */) .setDurationMs(1000.) .build(); /** * A one second sine curve * from silence to full volume for energy preserving cross fades. * Use {@link VolumeShaper.Builder#reflectTimes()} to generate * the matching cosine duck. */ public static final Configuration SINE_RAMP; /** * A one second sine-squared s-curve ramp * from silence to full volume. * Use {@link VolumeShaper.Builder#reflectTimes()} * or {@link VolumeShaper.Builder#invertVolumes()} to generate * the matching sine-squared s-curve duck. */ public static final Configuration SCURVE_RAMP; static { final int POINTS = MAXIMUM_CURVE_POINTS; final float times[] = new float[POINTS]; final float sines[] = new float[POINTS]; final float scurve[] = new float[POINTS]; for (int i = 0; i < POINTS; ++i) { times[i] = (float)i / (POINTS - 1); final float sine = (float)Math.sin(times[i] * Math.PI / 2.); sines[i] = sine; scurve[i] = sine * sine; } SINE_RAMP = new VolumeShaper.Configuration.Builder() .setInterpolatorType(INTERPOLATOR_TYPE_CUBIC) .setCurve(times, sines) .setDurationMs(1000.) .build(); SCURVE_RAMP = new VolumeShaper.Configuration.Builder() .setInterpolatorType(INTERPOLATOR_TYPE_CUBIC) .setCurve(times, scurve) .setDurationMs(1000.) .build(); } /* * member variables - these are all final */ // type of VolumeShaper private final int mType; // valid when mType is TYPE_ID private final int mId; // valid when mType is TYPE_SCALE private final int mOptionFlags; private final double mDurationMs; private final int mInterpolatorType; private final float[] mTimes; private final float[] mVolumes; @Override public String toString() { return "VolumeShaper.Configuration{" + "mType = " + mType + ", mId = " + mId + (mType == TYPE_ID ? "}" : ", mOptionFlags = 0x" + Integer.toHexString(mOptionFlags).toUpperCase() + ", mDurationMs = " + mDurationMs + ", mInterpolatorType = " + mInterpolatorType + ", mTimes[] = " + Arrays.toString(mTimes) + ", mVolumes[] = " + Arrays.toString(mVolumes) + "}"); } @Override public int hashCode() { return mType == TYPE_ID ? Objects.hash(mType, mId) : Objects.hash(mType, mId, mOptionFlags, mDurationMs, mInterpolatorType, Arrays.hashCode(mTimes), Arrays.hashCode(mVolumes)); } @Override public boolean equals(Object o) { if (!(o instanceof Configuration)) return false; if (o == this) return true; final Configuration other = (Configuration) o; // Note that exact floating point equality may not be guaranteed // for a theoretically idempotent operation; for example, // there are many cases where a + b - b != a. return mType == other.mType && mId == other.mId && (mType == TYPE_ID || (mOptionFlags == other.mOptionFlags && mDurationMs == other.mDurationMs && mInterpolatorType == other.mInterpolatorType && Arrays.equals(mTimes, other.mTimes) && Arrays.equals(mVolumes, other.mVolumes))); } @Override public int describeContents() { return 0; } @Override public void writeToParcel(Parcel dest, int flags) { // this needs to match the native VolumeShaper.Configuration parceling dest.writeInt(mType); dest.writeInt(mId); if (mType != TYPE_ID) { dest.writeInt(mOptionFlags); dest.writeDouble(mDurationMs); // this needs to match the native Interpolator parceling dest.writeInt(mInterpolatorType); dest.writeFloat(0.f); // first slope dest.writeFloat(0.f); // last slope // mTimes and mVolumes should have the same length. dest.writeInt(mTimes.length); for (int i = 0; i < mTimes.length; ++i) { dest.writeFloat(mTimes[i]); dest.writeFloat(mVolumes[i]); } } } public static final Parcelable.Creator CREATOR = new Parcelable.Creator() { @Override public VolumeShaper.Configuration createFromParcel(Parcel p) { // this needs to match the native VolumeShaper.Configuration parceling final int type = p.readInt(); final int id = p.readInt(); if (type == TYPE_ID) { return new VolumeShaper.Configuration(id); } else { final int optionFlags = p.readInt(); final double durationMs = p.readDouble(); // this needs to match the native Interpolator parceling final int interpolatorType = p.readInt(); final float firstSlope = p.readFloat(); // ignored final float lastSlope = p.readFloat(); // ignored final int length = p.readInt(); final float[] times = new float[length]; final float[] volumes = new float[length]; for (int i = 0; i < length; ++i) { times[i] = p.readFloat(); volumes[i] = p.readFloat(); } return new VolumeShaper.Configuration( type, id, optionFlags, durationMs, interpolatorType, times, volumes); } } @Override public VolumeShaper.Configuration[] newArray(int size) { return new VolumeShaper.Configuration[size]; } }; /** * @hide * Constructs a volume shaper from an id. * * This is an opaque handle for controlling a {@code VolumeShaper} that has * already been sent to a player. The {@code id} is returned from the * initial {@code setVolumeShaper()} call on success. * * These configurations are for native use only, * they are never returned directly to the user. * * @param id * @throws IllegalArgumentException if id is negative. */ public Configuration(int id) { if (id < 0) { throw new IllegalArgumentException("negative id " + id); } mType = TYPE_ID; mId = id; mInterpolatorType = 0; mOptionFlags = 0; mDurationMs = 0; mTimes = null; mVolumes = null; } /** * Direct constructor for VolumeShaper. * Use the Builder instead. */ private Configuration(@Type int type, int id, @OptionFlag int optionFlags, double durationMs, @InterpolatorType int interpolatorType, @NonNull float[] times, @NonNull float[] volumes) { mType = type; mId = id; mOptionFlags = optionFlags; mDurationMs = durationMs; mInterpolatorType = interpolatorType; // Builder should have cloned these arrays already. mTimes = times; mVolumes = volumes; } /** * @hide * Returns the {@code VolumeShaper} type. */ public @Type int getType() { return mType; } /** * @hide * Returns the {@code VolumeShaper} id. */ public int getId() { return mId; } /** * Returns the interpolator type. */ public @InterpolatorType int getInterpolatorType() { return mInterpolatorType; } /** * @hide * Returns the option flags */ public @OptionFlag int getOptionFlags() { return mOptionFlags & OPTION_FLAG_PUBLIC_ALL; } /* package */ @OptionFlag int getAllOptionFlags() { return mOptionFlags; } /** * Returns the duration of the volume shape in milliseconds. */ public double getDurationMs() { return mDurationMs; } /** * Returns the times (x) coordinate array of the volume curve points. */ public float[] getTimes() { return mTimes; } /** * Returns the volumes (y) coordinate array of the volume curve points. */ public float[] getVolumes() { return mVolumes; } /** * Checks the validity of times and volumes point representation. * * {@code times[]} and {@code volumes[]} are two arrays representing points * for the volume curve. * * @param times the x coordinates for the points, * must be between 0.f and 1.f and be monotonic. * @param volumes the y coordinates for the points, * must be between 0.f and 1.f for linear and * must be no greater than 0.f for log (dBFS). * @param log set to true if the scale is logarithmic. * @return null if no error, or the reason in a {@code String} for an error. */ private static @Nullable String checkCurveForErrors( @Nullable float[] times, @Nullable float[] volumes, boolean log) { if (times == null) { return "times array must be non-null"; } else if (volumes == null) { return "volumes array must be non-null"; } else if (times.length != volumes.length) { return "array length must match"; } else if (times.length < 2) { return "array length must be at least 2"; } else if (times.length > MAXIMUM_CURVE_POINTS) { return "array length must be no larger than " + MAXIMUM_CURVE_POINTS; } else if (times[0] != 0.f) { return "times must start at 0.f"; } else if (times[times.length - 1] != 1.f) { return "times must end at 1.f"; } // validate points along the curve for (int i = 1; i < times.length; ++i) { if (!(times[i] > times[i - 1]) /* handle nan */) { return "times not monotonic increasing, check index " + i; } } if (log) { for (int i = 0; i < volumes.length; ++i) { if (!(volumes[i] <= 0.f) /* handle nan */) { return "volumes for log scale cannot be positive, " + "check index " + i; } } } else { for (int i = 0; i < volumes.length; ++i) { if (!(volumes[i] >= 0.f) || !(volumes[i] <= 1.f) /* handle nan */) { return "volumes for linear scale must be between 0.f and 1.f, " + "check index " + i; } } } return null; // no errors } private static void checkCurveForErrorsAndThrowException( @Nullable float[] times, @Nullable float[] volumes, boolean log) { final String error = checkCurveForErrors(times, volumes, log); if (error != null) { throw new IllegalArgumentException(error); } } private static void checkValidVolumeAndThrowException(float volume, boolean log) { if (log) { if (!(volume <= 0.f) /* handle nan */) { throw new IllegalArgumentException("dbfs volume must be 0.f or less"); } } else { if (!(volume >= 0.f) || !(volume <= 1.f) /* handle nan */) { throw new IllegalArgumentException("volume must be >= 0.f and <= 1.f"); } } } private static void clampVolume(float[] volumes, boolean log) { if (log) { for (int i = 0; i < volumes.length; ++i) { if (!(volumes[i] <= 0.f) /* handle nan */) { volumes[i] = 0.f; } } } else { for (int i = 0; i < volumes.length; ++i) { if (!(volumes[i] >= 0.f) /* handle nan */) { volumes[i] = 0.f; } else if (!(volumes[i] <= 1.f)) { volumes[i] = 1.f; } } } } /** * Builder class for a {@link VolumeShaper.Configuration} object. *

Here is an example where {@code Builder} is used to define the * {@link VolumeShaper.Configuration}. * *

         * VolumeShaper.Configuration LINEAR_RAMP =
         *         new VolumeShaper.Configuration.Builder()
         *             .setInterpolatorType(VolumeShaper.Configuration.INTERPOLATOR_TYPE_LINEAR)
         *             .setCurve(new float[] { 0.f, 1.f }, // times
         *                       new float[] { 0.f, 1.f }) // volumes
         *             .setDurationMs(1000.)
         *             .build();
         *

*/ public static final class Builder { private int mType = TYPE_SCALE; private int mId = -1; // invalid private int mInterpolatorType = INTERPOLATOR_TYPE_CUBIC; private int mOptionFlags = OPTION_FLAG_CLOCK_TIME; private double mDurationMs = 1000.; private float[] mTimes = null; private float[] mVolumes = null; /** * Constructs a new {@code Builder} with the defaults. */ public Builder() { } /** * Constructs a new {@code Builder} with settings * copied from a given {@code VolumeShaper.Configuration}. * @param configuration prototypical configuration * which will be reused in the new {@code Builder}. */ public Builder(@NonNull Configuration configuration) { mType = configuration.getType(); mId = configuration.getId(); mOptionFlags = configuration.getAllOptionFlags(); mInterpolatorType = configuration.getInterpolatorType(); mDurationMs = configuration.getDurationMs(); mTimes = configuration.getTimes().clone(); mVolumes = configuration.getVolumes().clone(); } /** * @hide * Set the {@code id} for system defined shapers. * @param id the {@code id} to set. If non-negative, then it is used. * If -1, then the system is expected to assign one. * @return the same {@code Builder} instance. * @throws IllegalArgumentException if {@code id} < -1. */ public @NonNull Builder setId(int id) { if (id < -1) { throw new IllegalArgumentException("invalid id: " + id); } mId = id; return this; } /** * Sets the interpolator type. * * If omitted the interplator type is {@link #INTERPOLATOR_TYPE_CUBIC}. * * @param interpolatorType method of interpolation used for the volume curve. * One of {@link #INTERPOLATOR_TYPE_STEP}, * {@link #INTERPOLATOR_TYPE_LINEAR}, * {@link #INTERPOLATOR_TYPE_CUBIC}, * {@link #INTERPOLATOR_TYPE_CUBIC_MONOTONIC}. * @return the same {@code Builder} instance. * @throws IllegalArgumentException if {@code interpolatorType} is not valid. */ public @NonNull Builder setInterpolatorType(@InterpolatorType int interpolatorType) { switch (interpolatorType) { case INTERPOLATOR_TYPE_STEP: case INTERPOLATOR_TYPE_LINEAR: case INTERPOLATOR_TYPE_CUBIC: case INTERPOLATOR_TYPE_CUBIC_MONOTONIC: mInterpolatorType = interpolatorType; break; default: throw new IllegalArgumentException("invalid interpolatorType: " + interpolatorType); } return this; } /** * @hide * Sets the optional flags * * If omitted, flags are 0. If {@link #OPTION_FLAG_VOLUME_IN_DBFS} has * changed the volume curve needs to be set again as the acceptable * volume domain has changed. * * @param optionFlags new value to replace the old {@code optionFlags}. * @return the same {@code Builder} instance. * @throws IllegalArgumentException if flag is not recognized. */ public @NonNull Builder setOptionFlags(@OptionFlag int optionFlags) { if ((optionFlags & ~OPTION_FLAG_PUBLIC_ALL) != 0) { throw new IllegalArgumentException("invalid bits in flag: " + optionFlags); } mOptionFlags = mOptionFlags & ~OPTION_FLAG_PUBLIC_ALL | optionFlags; return this; } /** * Sets the volume shaper duration in milliseconds. * * If omitted, the default duration is 1 second. * * @param durationMs * @return the same {@code Builder} instance. * @throws IllegalArgumentException if {@code durationMs} * is not strictly positive. */ public @NonNull Builder setDurationMs(double durationMs) { if (durationMs <= 0.) { throw new IllegalArgumentException( "duration: " + durationMs + " not positive"); } mDurationMs = durationMs; return this; } /** * Sets the volume curve. * * The volume curve is represented by a set of control points given by * two float arrays of equal length, * one representing the time (x) coordinates * and one corresponding to the volume (y) coordinates. * The length must be at least 2 * and no greater than {@link VolumeShaper.Configuration#getMaximumCurvePoints()}. *

* The volume curve is normalized as follows: * time (x) coordinates should be monotonically increasing, from 0.f to 1.f; * volume (y) coordinates must be within 0.f to 1.f. *

* The time scale is set by {@link #setDurationMs}. *

* @param times an array of float values representing * the time line of the volume curve. * @param volumes an array of float values representing * the amplitude of the volume curve. * @return the same {@code Builder} instance. * @throws IllegalArgumentException if {@code times} or {@code volumes} is invalid. */ /* Note: volume (y) coordinates must be non-positive for log scaling, * if {@link VolumeShaper.Configuration#OPTION_FLAG_VOLUME_IN_DBFS} is set. */ public @NonNull Builder setCurve(@NonNull float[] times, @NonNull float[] volumes) { checkCurveForErrorsAndThrowException( times, volumes, (mOptionFlags & OPTION_FLAG_VOLUME_IN_DBFS) != 0); mTimes = times.clone(); mVolumes = volumes.clone(); return this; } /** * Reflects the volume curve so that * the shaper changes volume from the end * to the start. * * @return the same {@code Builder} instance. * @throws IllegalArgumentException if curve has not been set. */ public @NonNull Builder reflectTimes() { checkCurveForErrorsAndThrowException( mTimes, mVolumes, (mOptionFlags & OPTION_FLAG_VOLUME_IN_DBFS) != 0); int i; for (i = 0; i < mTimes.length / 2; ++i) { float temp = mTimes[i]; mTimes[i] = 1.f - mTimes[mTimes.length - 1 - i]; mTimes[mTimes.length - 1 - i] = 1.f - temp; temp = mVolumes[i]; mVolumes[i] = mVolumes[mVolumes.length - 1 - i]; mVolumes[mVolumes.length - 1 - i] = temp; } if ((mTimes.length & 1) != 0) { mTimes[i] = 1.f - mTimes[i]; } return this; } /** * Inverts the volume curve so that the max volume * becomes the min volume and vice versa. * * @return the same {@code Builder} instance. * @throws IllegalArgumentException if curve has not been set. */ public @NonNull Builder invertVolumes() { checkCurveForErrorsAndThrowException( mTimes, mVolumes, (mOptionFlags & OPTION_FLAG_VOLUME_IN_DBFS) != 0); float min = mVolumes[0]; float max = mVolumes[0]; for (int i = 1; i < mVolumes.length; ++i) { if (mVolumes[i] < min) { min = mVolumes[i]; } else if (mVolumes[i] > max) { max = mVolumes[i]; } } final float maxmin = max + min; for (int i = 0; i < mVolumes.length; ++i) { mVolumes[i] = maxmin - mVolumes[i]; } return this; } /** * Scale the curve end volume to a target value. * * Keeps the start volume the same. * This works best if the volume curve is monotonic. * * @param volume the target end volume to use. * @return the same {@code Builder} instance. * @throws IllegalArgumentException if {@code volume} * is not valid or if curve has not been set. */ public @NonNull Builder scaleToEndVolume(float volume) { final boolean log = (mOptionFlags & OPTION_FLAG_VOLUME_IN_DBFS) != 0; checkCurveForErrorsAndThrowException(mTimes, mVolumes, log); checkValidVolumeAndThrowException(volume, log); final float startVolume = mVolumes[0]; final float endVolume = mVolumes[mVolumes.length - 1]; if (endVolume == startVolume) { // match with linear ramp final float offset = volume - startVolume; for (int i = 0; i < mVolumes.length; ++i) { mVolumes[i] = mVolumes[i] + offset * mTimes[i]; } } else { // scale final float scale = (volume - startVolume) / (endVolume - startVolume); for (int i = 0; i < mVolumes.length; ++i) { mVolumes[i] = scale * (mVolumes[i] - startVolume) + startVolume; } } clampVolume(mVolumes, log); return this; } /** * Scale the curve start volume to a target value. * * Keeps the end volume the same. * This works best if the volume curve is monotonic. * * @param volume the target start volume to use. * @return the same {@code Builder} instance. * @throws IllegalArgumentException if {@code volume} * is not valid or if curve has not been set. */ public @NonNull Builder scaleToStartVolume(float volume) { final boolean log = (mOptionFlags & OPTION_FLAG_VOLUME_IN_DBFS) != 0; checkCurveForErrorsAndThrowException(mTimes, mVolumes, log); checkValidVolumeAndThrowException(volume, log); final float startVolume = mVolumes[0]; final float endVolume = mVolumes[mVolumes.length - 1]; if (endVolume == startVolume) { // match with linear ramp final float offset = volume - startVolume; for (int i = 0; i < mVolumes.length; ++i) { mVolumes[i] = mVolumes[i] + offset * (1.f - mTimes[i]); } } else { final float scale = (volume - endVolume) / (startVolume - endVolume); for (int i = 0; i < mVolumes.length; ++i) { mVolumes[i] = scale * (mVolumes[i] - endVolume) + endVolume; } } clampVolume(mVolumes, log); return this; } /** * Builds a new {@link VolumeShaper} object. * * @return a new {@link VolumeShaper} object. * @throws IllegalArgumentException if curve is not properly set. */ public @NonNull Configuration build() { checkCurveForErrorsAndThrowException( mTimes, mVolumes, (mOptionFlags & OPTION_FLAG_VOLUME_IN_DBFS) != 0); return new Configuration(mType, mId, mOptionFlags, mDurationMs, mInterpolatorType, mTimes, mVolumes); } } // Configuration.Builder } // Configuration /** * The {@code VolumeShaper.Operation} class is used to specify operations * to the {@code VolumeShaper} that affect the volume change. */ public static final class Operation implements Parcelable { /** * Forward playback from current volume time position. * At the end of the {@code VolumeShaper} curve, * the last volume value persists. */ public static final Operation PLAY = new VolumeShaper.Operation.Builder() .build(); /** * Reverse playback from current volume time position. * When the position reaches the start of the {@code VolumeShaper} curve, * the first volume value persists. */ public static final Operation REVERSE = new VolumeShaper.Operation.Builder() .reverse() .build(); // No user serviceable parts below. // These flags must match the native VolumeShaper::Operation::Flag /** @hide */ @IntDef({ FLAG_NONE, FLAG_REVERSE, FLAG_TERMINATE, FLAG_JOIN, FLAG_DEFER, }) @Retention(RetentionPolicy.SOURCE) public @interface Flag {} /** * No special {@code VolumeShaper} operation. */ private static final int FLAG_NONE = 0; /** * Reverse the {@code VolumeShaper} progress. * * Reverses the {@code VolumeShaper} curve from its current * position. If the {@code VolumeShaper} curve has not started, * it automatically is considered finished. */ private static final int FLAG_REVERSE = 1 << 0; /** * Terminate the existing {@code VolumeShaper}. * This flag is generally used by itself; * it takes precedence over all other flags. */ private static final int FLAG_TERMINATE = 1 << 1; /** * Attempt to join as best as possible to the previous {@code VolumeShaper}. * This requires the previous {@code VolumeShaper} to be active and * {@link #setReplaceId} to be set. */ private static final int FLAG_JOIN = 1 << 2; /** * Defer playback until next operation is sent. This is used * when starting a VolumeShaper effect. */ private static final int FLAG_DEFER = 1 << 3; /** * Use the id specified in the configuration, creating * VolumeShaper as needed; the configuration should be * TYPE_SCALE. */ private static final int FLAG_CREATE_IF_NEEDED = 1 << 4; private static final int FLAG_PUBLIC_ALL = FLAG_REVERSE | FLAG_TERMINATE; private final int mFlags; private final int mReplaceId; @Override public String toString() { return "VolumeShaper.Operation{" + "mFlags = 0x" + Integer.toHexString(mFlags).toUpperCase() + ", mReplaceId = " + mReplaceId + "}"; } @Override public int hashCode() { return Objects.hash(mFlags, mReplaceId); } @Override public boolean equals(Object o) { if (!(o instanceof Operation)) return false; if (o == this) return true; final Operation other = (Operation) o; // if xOffset (native field only) is brought into Java // we need to do proper NaN comparison as that is allowed. return mFlags == other.mFlags && mReplaceId == other.mReplaceId; } @Override public int describeContents() { return 0; } @Override public void writeToParcel(Parcel dest, int flags) { // this needs to match the native VolumeShaper.Operation parceling dest.writeInt(mFlags); dest.writeInt(mReplaceId); dest.writeFloat(Float.NaN); // xOffset (ignored at Java level) } public static final Parcelable.Creator CREATOR = new Parcelable.Creator() { @Override public VolumeShaper.Operation createFromParcel(Parcel p) { // this needs to match the native VolumeShaper.Operation parceling final int flags = p.readInt(); final int replaceId = p.readInt(); final float xOffset = p.readFloat(); // ignored at Java level return new VolumeShaper.Operation( flags , replaceId); } @Override public VolumeShaper.Operation[] newArray(int size) { return new VolumeShaper.Operation[size]; } }; private Operation(@Flag int flags, int replaceId) { mFlags = flags; mReplaceId = replaceId; } /** * @hide * {@code Builder} class for {@link VolumeShaper.Operation} object. * * Not for public use. */ public static final class Builder { int mFlags; int mReplaceId; /** * Constructs a new {@code Builder} with the defaults. */ public Builder() { mFlags = 0; mReplaceId = -1; } /** * Constructs a new Builder from a given {@code VolumeShaper.Operation} * @param operation the {@code VolumeShaper.operation} whose data will be * reused in the new Builder. */ public Builder(@NonNull VolumeShaper.Operation operation) { mReplaceId = operation.mReplaceId; mFlags = operation.mFlags; } /** * Replaces the previous {@code VolumeShaper} specified by id. * It has no other effect if the {@code VolumeShaper} is * already expired. * @param id the id of the previous {@code VolumeShaper}. * @param join if true, match the volume of the previous * shaper to the start volume of the new {@code VolumeShaper}. * @return the same {@code Builder} instance. */ public @NonNull Builder replace(int id, boolean join) { mReplaceId = id; if (join) { mFlags |= FLAG_JOIN; } else { mFlags &= ~FLAG_JOIN; } return this; } /** * Defers all operations. * @return the same {@code Builder} instance. */ public @NonNull Builder defer() { mFlags |= FLAG_DEFER; return this; } /** * Terminates the VolumeShaper. * Do not call directly, use {@link VolumeShaper#release()}. * @return the same {@code Builder} instance. */ public @NonNull Builder terminate() { mFlags |= FLAG_TERMINATE; return this; } /** * Reverses direction. * @return the same {@code Builder} instance. */ public @NonNull Builder reverse() { mFlags ^= FLAG_REVERSE; return this; } /** * Use the id specified in the configuration, creating * VolumeShaper as needed; the configuration should be * TYPE_SCALE. * @return the same {@code Builder} instance. */ public @NonNull Builder createIfNeeded() { mFlags |= FLAG_CREATE_IF_NEEDED; return this; } /** * Sets the operation flag. Do not call this directly but one of the * other builder methods. * * @param flags new value for {@code flags}, consisting of ORed flags. * @return the same {@code Builder} instance. * @throws IllegalArgumentException if {@code flags} contains invalid set bits. */ private @NonNull Builder setFlags(@Flag int flags) { if ((flags & ~FLAG_PUBLIC_ALL) != 0) { throw new IllegalArgumentException("flag has unknown bits set: " + flags); } mFlags = mFlags & ~FLAG_PUBLIC_ALL | flags; return this; } /** * Builds a new {@link VolumeShaper.Operation} object. * * @return a new {@code VolumeShaper.Operation} object */ public @NonNull Operation build() { return new Operation(mFlags, mReplaceId); } } // Operation.Builder } // Operation /** * @hide * {@code VolumeShaper.State} represents the current progress * of the {@code VolumeShaper}. * * Not for public use. */ public static final class State implements Parcelable { private float mVolume; private float mXOffset; @Override public String toString() { return "VolumeShaper.State{" + "mVolume = " + mVolume + ", mXOffset = " + mXOffset + "}"; } @Override public int hashCode() { return Objects.hash(mVolume, mXOffset); } @Override public boolean equals(Object o) { if (!(o instanceof State)) return false; if (o == this) return true; final State other = (State) o; return mVolume == other.mVolume && mXOffset == other.mXOffset; } @Override public int describeContents() { return 0; } @Override public void writeToParcel(Parcel dest, int flags) { dest.writeFloat(mVolume); dest.writeFloat(mXOffset); } public static final Parcelable.Creator CREATOR = new Parcelable.Creator() { @Override public VolumeShaper.State createFromParcel(Parcel p) { return new VolumeShaper.State( p.readFloat() // volume , p.readFloat()); // xOffset } @Override public VolumeShaper.State[] newArray(int size) { return new VolumeShaper.State[size]; } }; /* package */ State(float volume, float xOffset) { mVolume = volume; mXOffset = xOffset; } /** * Gets the volume of the {@link VolumeShaper.State}. */ public float getVolume() { return mVolume; } /** * Gets the elapsed ms of the {@link VolumeShaper.State} */ public double getXOffset() { return mXOffset; } } // State }