assimp/include/assimp/anim.h

/*
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Open Asset Import Library (assimp)
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*/

/**
  * @file   anim.h
  * @brief  Defines the data structures in which the imported animations
  *         are returned.
  */
#pragma once
#ifndef AI_ANIM_H_INC
#define AI_ANIM_H_INC

#ifdef __GNUC__
#pragma GCC system_header
#endif

#include <assimp/quaternion.h>
#include <assimp/types.h>

#ifdef __cplusplus
extern "C" {
#endif

// ---------------------------------------------------------------------------
/** A time-value pair specifying a certain 3D vector for the given time. */
struct aiVectorKey {
    /** The time of this key */
    double mTime;

    /** The value of this key */
    C_STRUCT aiVector3D mValue;

#ifdef __cplusplus

    /// @brief  The default constructor.
    aiVectorKey() AI_NO_EXCEPT
            : mTime(0.0),
              mValue() {
        // empty
    }

    /// @brief  Construction from a given time and key value.

    aiVectorKey(double time, const aiVector3D &value) :
            mTime(time), mValue(value) {
        // empty
    }

    typedef aiVector3D elem_type;

    // Comparison operators. For use with std::find();
    bool operator==(const aiVectorKey &rhs) const {
        return rhs.mValue == this->mValue;
    }
    bool operator!=(const aiVectorKey &rhs) const {
        return rhs.mValue != this->mValue;
    }

    // Relational operators. For use with std::sort();
    bool operator<(const aiVectorKey &rhs) const {
        return mTime < rhs.mTime;
    }

    bool operator>(const aiVectorKey &rhs) const {
        return mTime > rhs.mTime;
    }
#endif // __cplusplus
};

// ---------------------------------------------------------------------------
/** A time-value pair specifying a rotation for the given time.
 *  Rotations are expressed with quaternions. */
struct aiQuatKey {
    /** The time of this key */
    double mTime;

    /** The value of this key */
    C_STRUCT aiQuaternion mValue;

#ifdef __cplusplus
    aiQuatKey() AI_NO_EXCEPT
            : mTime(0.0),
              mValue() {
        // empty
    }

    /** Construction from a given time and key value */
    aiQuatKey(double time, const aiQuaternion &value) :
            mTime(time), mValue(value) {}

    typedef aiQuaternion elem_type;

    // Comparison operators. For use with std::find();
    bool operator==(const aiQuatKey &rhs) const {
        return rhs.mValue == this->mValue;
    }

    bool operator!=(const aiQuatKey &rhs) const {
        return rhs.mValue != this->mValue;
    }

    // Relational operators. For use with std::sort();
    bool operator<(const aiQuatKey &rhs) const {
        return mTime < rhs.mTime;
    }

    bool operator>(const aiQuatKey &rhs) const {
        return mTime > rhs.mTime;
    }
#endif
};

// ---------------------------------------------------------------------------
/** Binds a anim-mesh to a specific point in time. */
struct aiMeshKey {
    /** The time of this key */
    double mTime;

    /** Index into the aiMesh::mAnimMeshes array of the
     *  mesh corresponding to the #aiMeshAnim hosting this
     *  key frame. The referenced anim mesh is evaluated
     *  according to the rules defined in the docs for #aiAnimMesh.*/
    unsigned int mValue;

#ifdef __cplusplus

    aiMeshKey() AI_NO_EXCEPT
            : mTime(0.0),
              mValue(0) {
    }

    /** Construction from a given time and key value */
    aiMeshKey(double time, const unsigned int value) :
            mTime(time), mValue(value) {}

    typedef unsigned int elem_type;

    // Comparison operators. For use with std::find();
    bool operator==(const aiMeshKey &o) const {
        return o.mValue == this->mValue;
    }
    bool operator!=(const aiMeshKey &o) const {
        return o.mValue != this->mValue;
    }

    // Relational operators. For use with std::sort();
    bool operator<(const aiMeshKey &o) const {
        return mTime < o.mTime;
    }
    bool operator>(const aiMeshKey &o) const {
        return mTime > o.mTime;
    }

#endif
};

// ---------------------------------------------------------------------------
/** Binds a morph anim mesh to a specific point in time. */
struct aiMeshMorphKey {
    /** The time of this key */
    double mTime;

    /** The values and weights at the time of this key
     *   - mValues: index of attachment mesh to apply weight at the same position in mWeights
     *   - mWeights: weight to apply to the blend shape index at the same position in mValues
     */
    unsigned int *mValues;
    double *mWeights;

    /** The number of values and weights */
    unsigned int mNumValuesAndWeights;
#ifdef __cplusplus
    aiMeshMorphKey() AI_NO_EXCEPT
            : mTime(0.0),
              mValues(nullptr),
              mWeights(nullptr),
              mNumValuesAndWeights(0) {
    }

    ~aiMeshMorphKey() {
        if (mNumValuesAndWeights && mValues && mWeights) {
            delete[] mValues;
            delete[] mWeights;
        }
    }
#endif
};

// ---------------------------------------------------------------------------
/** Defines how an animation channel behaves outside the defined time
 *  range. This corresponds to aiNodeAnim::mPreState and
 *  aiNodeAnim::mPostState.*/
enum aiAnimBehaviour {
    /** The value from the default node transformation is taken*/
    aiAnimBehaviour_DEFAULT = 0x0,

    /** The nearest key value is used without interpolation */
    aiAnimBehaviour_CONSTANT = 0x1,

    /** The value of the nearest two keys is linearly
     *  extrapolated for the current time value.*/
    aiAnimBehaviour_LINEAR = 0x2,

    /** The animation is repeated.
     *
     *  If the animation key go from n to m and the current
     *  time is t, use the value at (t-n) % (|m-n|).*/
    aiAnimBehaviour_REPEAT = 0x3,

/** This value is not used, it is just here to force the
     *  the compiler to map this enum to a 32 Bit integer  */
#ifndef SWIG
    _aiAnimBehaviour_Force32Bit = INT_MAX
#endif
};

// ---------------------------------------------------------------------------
/** Describes the animation of a single node. The name specifies the
 *  bone/node which is affected by this animation channel. The keyframes
 *  are given in three separate series of values, one each for position,
 *  rotation and scaling. The transformation matrix computed from these
 *  values replaces the node's original transformation matrix at a
 *  specific time.
 *  This means all keys are absolute and not relative to the bone default pose.
 *  The order in which the transformations are applied is
 *  - as usual - scaling, rotation, translation.
 *
 *  @note All keys are returned in their correct, chronological order.
 *  Duplicate keys don't pass the validation step. Most likely there
 *  will be no negative time values, but they are not forbidden also ( so
 *  implementations need to cope with them! ) */
struct aiNodeAnim {
    /** The name of the node affected by this animation. The node
     *  must exist and it must be unique.*/
    C_STRUCT aiString mNodeName;

    /** The number of position keys */
    unsigned int mNumPositionKeys;

    /** The position keys of this animation channel. Positions are
     * specified as 3D vector. The array is mNumPositionKeys in size.
     *
     * If there are position keys, there will also be at least one
     * scaling and one rotation key.*/
    C_STRUCT aiVectorKey *mPositionKeys;

    /** The number of rotation keys */
    unsigned int mNumRotationKeys;

    /** The rotation keys of this animation channel. Rotations are
     *  given as quaternions,  which are 4D vectors. The array is
     *  mNumRotationKeys in size.
     *
     * If there are rotation keys, there will also be at least one
     * scaling and one position key. */
    C_STRUCT aiQuatKey *mRotationKeys;

    /** The number of scaling keys */
    unsigned int mNumScalingKeys;

    /** The scaling keys of this animation channel. Scalings are
     *  specified as 3D vector. The array is mNumScalingKeys in size.
     *
     * If there are scaling keys, there will also be at least one
     * position and one rotation key.*/
    C_STRUCT aiVectorKey *mScalingKeys;

    /** Defines how the animation behaves before the first
     *  key is encountered.
     *
     *  The default value is aiAnimBehaviour_DEFAULT (the original
     *  transformation matrix of the affected node is used).*/
    C_ENUM aiAnimBehaviour mPreState;

    /** Defines how the animation behaves after the last
     *  key was processed.
     *
     *  The default value is aiAnimBehaviour_DEFAULT (the original
     *  transformation matrix of the affected node is taken).*/
    C_ENUM aiAnimBehaviour mPostState;

#ifdef __cplusplus
    aiNodeAnim() AI_NO_EXCEPT
            : mNumPositionKeys(0),
              mPositionKeys(nullptr),
              mNumRotationKeys(0),
              mRotationKeys(nullptr),
              mNumScalingKeys(0),
              mScalingKeys(nullptr),
              mPreState(aiAnimBehaviour_DEFAULT),
              mPostState(aiAnimBehaviour_DEFAULT) {
        // empty
    }

    ~aiNodeAnim() {
        delete[] mPositionKeys;
        delete[] mRotationKeys;
        delete[] mScalingKeys;
    }
#endif // __cplusplus
};

// ---------------------------------------------------------------------------
/** Describes vertex-based animations for a single mesh or a group of
 *  meshes. Meshes carry the animation data for each frame in their
 *  aiMesh::mAnimMeshes array. The purpose of aiMeshAnim is to
 *  define keyframes linking each mesh attachment to a particular
 *  point in time. */
struct aiMeshAnim {
    /** Name of the mesh to be animated. An empty string is not allowed,
     *  animated meshes need to be named (not necessarily uniquely,
     *  the name can basically serve as wild-card to select a group
     *  of meshes with similar animation setup)*/
    C_STRUCT aiString mName;

    /** Size of the #mKeys array. Must be 1, at least. */
    unsigned int mNumKeys;

    /** Key frames of the animation. May not be nullptr. */
    C_STRUCT aiMeshKey *mKeys;

#ifdef __cplusplus

    aiMeshAnim() AI_NO_EXCEPT
            : mNumKeys(),
              mKeys() {}

    ~aiMeshAnim() {
        delete[] mKeys;
    }

#endif
};

// ---------------------------------------------------------------------------
/** Describes a morphing animation of a given mesh. */
struct aiMeshMorphAnim {
    /** Name of the mesh to be animated. An empty string is not allowed,
     *  animated meshes need to be named (not necessarily uniquely,
     *  the name can basically serve as wildcard to select a group
     *  of meshes with similar animation setup)*/
    C_STRUCT aiString mName;

    /** Size of the #mKeys array. Must be 1, at least. */
    unsigned int mNumKeys;

    /** Key frames of the animation. May not be nullptr. */
    C_STRUCT aiMeshMorphKey *mKeys;

#ifdef __cplusplus

    aiMeshMorphAnim() AI_NO_EXCEPT
            : mNumKeys(),
              mKeys() {}

    ~aiMeshMorphAnim() {
        delete[] mKeys;
    }

#endif
};

// ---------------------------------------------------------------------------
/** An animation consists of key-frame data for a number of nodes. For
 *  each node affected by the animation a separate series of data is given.*/
struct aiAnimation {
    /** The name of the animation. If the modeling package this data was
     *  exported from does support only a single animation channel, this
     *  name is usually empty (length is zero). */
    C_STRUCT aiString mName;

    /** Duration of the animation in ticks.  */
    double mDuration;

    /** Ticks per second. 0 if not specified in the imported file */
    double mTicksPerSecond;

    /** The number of bone animation channels. Each channel affects
     *  a single node. */
    unsigned int mNumChannels;

    /** The node animation channels. Each channel affects a single node.
     *  The array is mNumChannels in size. */
    C_STRUCT aiNodeAnim **mChannels;

    /** The number of mesh animation channels. Each channel affects
     *  a single mesh and defines vertex-based animation. */
    unsigned int mNumMeshChannels;

    /** The mesh animation channels. Each channel affects a single mesh.
     *  The array is mNumMeshChannels in size. */
    C_STRUCT aiMeshAnim **mMeshChannels;

    /** The number of mesh animation channels. Each channel affects
     *  a single mesh and defines morphing animation. */
    unsigned int mNumMorphMeshChannels;

    /** The morph mesh animation channels. Each channel affects a single mesh.
     *  The array is mNumMorphMeshChannels in size. */
    C_STRUCT aiMeshMorphAnim **mMorphMeshChannels;

#ifdef __cplusplus
    aiAnimation() AI_NO_EXCEPT
            : mDuration(-1.),
              mTicksPerSecond(0.),
              mNumChannels(0),
              mChannels(nullptr),
              mNumMeshChannels(0),
              mMeshChannels(nullptr),
              mNumMorphMeshChannels(0),
              mMorphMeshChannels(nullptr) {
        // empty
    }

    ~aiAnimation() {
        // DO NOT REMOVE THIS ADDITIONAL CHECK
        if (mNumChannels && mChannels) {
            for (unsigned int a = 0; a < mNumChannels; a++) {
                delete mChannels[a];
            }

            delete[] mChannels;
        }
        if (mNumMeshChannels && mMeshChannels) {
            for (unsigned int a = 0; a < mNumMeshChannels; a++) {
                delete mMeshChannels[a];
            }

            delete[] mMeshChannels;
        }
        if (mNumMorphMeshChannels && mMorphMeshChannels) {
            for (unsigned int a = 0; a < mNumMorphMeshChannels; a++) {
                delete mMorphMeshChannels[a];
            }

            delete[] mMorphMeshChannels;
        }
    }
#endif // __cplusplus
};

#ifdef __cplusplus
}

/// @brief  Some C++ utilities for inter- and extrapolation
namespace Assimp {

// ---------------------------------------------------------------------------
/**
  * @brief CPP-API: Utility class to simplify interpolations of various data types.
  *
  *  The type of interpolation is chosen automatically depending on the
  *  types of the arguments.
  */
template <typename T>
struct Interpolator {
    // ------------------------------------------------------------------
    /** @brief Get the result of the interpolation between a,b.
     *
     *  The interpolation algorithm depends on the type of the operands.
     *  aiQuaternion's and aiQuatKey's SLERP, the rest does a simple
     *  linear interpolation. */
    void operator()(T &anim_out, const T &a, const T &b, ai_real d) const {
        anim_out = a + (b - a) * d;
    }
}; // ! Interpolator <T>

//! @cond Never

template <>
struct Interpolator<aiQuaternion> {
    void operator()(aiQuaternion &out, const aiQuaternion &a,
            const aiQuaternion &b, ai_real d) const {
        aiQuaternion::Interpolate(out, a, b, d);
    }
}; // ! Interpolator <aiQuaternion>

template <>
struct Interpolator<unsigned int> {
    void operator()(unsigned int &out, unsigned int a,
            unsigned int b, ai_real d) const {
        out = d > 0.5f ? b : a;
    }
}; // ! Interpolator <aiQuaternion>

template <>
struct Interpolator<aiVectorKey> {
    void operator()(aiVector3D &out, const aiVectorKey &a,
            const aiVectorKey &b, ai_real d) const {
        Interpolator<aiVector3D> ipl;
        ipl(out, a.mValue, b.mValue, d);
    }
}; // ! Interpolator <aiVectorKey>

template <>
struct Interpolator<aiQuatKey> {
    void operator()(aiQuaternion &out, const aiQuatKey &a,
            const aiQuatKey &b, ai_real d) const {
        Interpolator<aiQuaternion> ipl;
        ipl(out, a.mValue, b.mValue, d);
    }
}; // ! Interpolator <aiQuatKey>

template <>
struct Interpolator<aiMeshKey> {
    void operator()(unsigned int &out, const aiMeshKey &a,
            const aiMeshKey &b, ai_real d) const {
        Interpolator<unsigned int> ipl;
        ipl(out, a.mValue, b.mValue, d);
    }
}; // ! Interpolator <aiQuatKey>

//! @endcond

} // namespace Assimp

#endif // __cplusplus

#endif // AI_ANIM_H_INC