convert pose6s data to pose7s data to resolve quaternion W coordinate precision issues

[xonotic/darkplaces.git] / mod_skeletal_animatevertices_generic.c

#include "mod_skeletal_animatevertices_generic.h"

typedef struct
{
        float f[12];
}
float12_t;

void Mod_Skeletal_AnimateVertices_Generic(const dp_model_t * RESTRICT model, const frameblend_t * RESTRICT frameblend, const skeleton_t *skeleton, float * RESTRICT vertex3f, float * RESTRICT normal3f, float * RESTRICT svector3f, float * RESTRICT tvector3f)
{
        // vertex weighted skeletal
        int i, k;
        int blends;
        float12_t *bonepose;
        float12_t *boneposerelative;
        float m[12];
        const blendweights_t * RESTRICT weights;

        //unsigned long long ts = rdtsc();
        bonepose = (float12_t *) Mod_Skeletal_AnimateVertices_AllocBuffers(sizeof(float12_t) * (model->num_bones*2 + model->surfmesh.num_blends));
        boneposerelative = bonepose + model->num_bones;

        if (skeleton && !skeleton->relativetransforms)
                skeleton = NULL;

        // interpolate matrices
        if (skeleton)
        {
                for (i = 0;i < model->num_bones;i++)
                {
                        Matrix4x4_ToArray12FloatD3D(&skeleton->relativetransforms[i], m);
                        if (model->data_bones[i].parent >= 0)
                                R_ConcatTransforms(bonepose[model->data_bones[i].parent].f, m, bonepose[i].f);
                        else
                                memcpy(bonepose[i].f, m, sizeof(m));

                        // create a relative deformation matrix to describe displacement
                        // from the base mesh, which is used by the actual weighting
                        R_ConcatTransforms(bonepose[i].f, model->data_baseboneposeinverse + i * 12, boneposerelative[i].f);
                }
        }
        else
        {
                float originscale = model->num_posescale;
                float x,y,z,w,lerp;
                const short * RESTRICT pose7s;

                for (i = 0;i < model->num_bones;i++)
                {
                        memset(m, 0, sizeof(m));
                        for (blends = 0;blends < MAX_FRAMEBLENDS && frameblend[blends].lerp > 0;blends++)
                        {
                                pose7s = model->data_poses7s + 7 * (frameblend[blends].subframe * model->num_bones + i);
                                lerp = frameblend[blends].lerp;
                                x = pose7s[3] * (1.0f / 32767.0f);
                                y = pose7s[4] * (1.0f / 32767.0f);
                                z = pose7s[5] * (1.0f / 32767.0f);
                                w = pose7s[6] * (1.0f / 32767.0f);
                                m[ 0] += (1-2*(y*y+z*z)) * lerp;
                                m[ 1] += (  2*(x*y-z*w)) * lerp;
                                m[ 2] += (  2*(x*z+y*w)) * lerp;
                                m[ 3] += (pose7s[0] * originscale) * lerp;
                                m[ 4] += (  2*(x*y+z*w)) * lerp;
                                m[ 5] += (1-2*(x*x+z*z)) * lerp;
                                m[ 6] += (  2*(y*z-x*w)) * lerp;
                                m[ 7] += (pose7s[1] * originscale) * lerp;
                                m[ 8] += (  2*(x*z-y*w)) * lerp;
                                m[ 9] += (  2*(y*z+x*w)) * lerp;
                                m[10] += (1-2*(x*x+y*y)) * lerp;
                                m[11] += (pose7s[2] * originscale) * lerp;
                        }
                        VectorNormalize(m       );
                        VectorNormalize(m + 4);
                        VectorNormalize(m + 8);
                        if (i == r_skeletal_debugbone.integer)
                                m[r_skeletal_debugbonecomponent.integer % 12] += r_skeletal_debugbonevalue.value;
                        m[3] *= r_skeletal_debugtranslatex.value;
                        m[7] *= r_skeletal_debugtranslatey.value;
                        m[11] *= r_skeletal_debugtranslatez.value;
                        if (model->data_bones[i].parent >= 0)
                                R_ConcatTransforms(bonepose[model->data_bones[i].parent].f, m, bonepose[i].f);
                        else
                                memcpy(bonepose[i].f, m, sizeof(m));
                        // create a relative deformation matrix to describe displacement
                        // from the base mesh, which is used by the actual weighting
                        R_ConcatTransforms(bonepose[i].f, model->data_baseboneposeinverse + i * 12, boneposerelative[i].f);
                }
        }

        // generate matrices for all blend combinations
        weights = model->surfmesh.data_blendweights;
        for (i = 0;i < model->surfmesh.num_blends;i++, weights++)
        {
                float * RESTRICT b = boneposerelative[model->num_bones + i].f;
                const float * RESTRICT m = boneposerelative[weights->index[0]].f;
                float f = weights->influence[0] * (1.0f / 255.0f);
                b[ 0] = f*m[ 0]; b[ 1] = f*m[ 1]; b[ 2] = f*m[ 2]; b[ 3] = f*m[ 3];
                b[ 4] = f*m[ 4]; b[ 5] = f*m[ 5]; b[ 6] = f*m[ 6]; b[ 7] = f*m[ 7];
                b[ 8] = f*m[ 8]; b[ 9] = f*m[ 9]; b[10] = f*m[10]; b[11] = f*m[11];
                for (k = 1;k < 4 && weights->influence[k];k++)
                {
                        m = boneposerelative[weights->index[k]].f;
                        f = weights->influence[k] * (1.0f / 255.0f);
                        b[ 0] += f*m[ 0]; b[ 1] += f*m[ 1]; b[ 2] += f*m[ 2]; b[ 3] += f*m[ 3];
                        b[ 4] += f*m[ 4]; b[ 5] += f*m[ 5]; b[ 6] += f*m[ 6]; b[ 7] += f*m[ 7];
                        b[ 8] += f*m[ 8]; b[ 9] += f*m[ 9]; b[10] += f*m[10]; b[11] += f*m[11];
                }
        }

#define LOAD_MATRIX_SCALAR() const float * RESTRICT m = boneposerelative[*b].f

#define LOAD_MATRIX3() \
        LOAD_MATRIX_SCALAR()
#define LOAD_MATRIX4() \
        LOAD_MATRIX_SCALAR()

#define TRANSFORM_POSITION_SCALAR(in, out) \
        (out)[0] = ((in)[0] * m[0] + (in)[1] * m[1] + (in)[2] * m[ 2] + m[3]); \
        (out)[1] = ((in)[0] * m[4] + (in)[1] * m[5] + (in)[2] * m[ 6] + m[7]); \
        (out)[2] = ((in)[0] * m[8] + (in)[1] * m[9] + (in)[2] * m[10] + m[11]);
#define TRANSFORM_VECTOR_SCALAR(in, out) \
        (out)[0] = ((in)[0] * m[0] + (in)[1] * m[1] + (in)[2] * m[ 2]); \
        (out)[1] = ((in)[0] * m[4] + (in)[1] * m[5] + (in)[2] * m[ 6]); \
        (out)[2] = ((in)[0] * m[8] + (in)[1] * m[9] + (in)[2] * m[10]);

#define TRANSFORM_POSITION(in, out) \
        TRANSFORM_POSITION_SCALAR(in, out)
#define TRANSFORM_VECTOR(in, out) \
        TRANSFORM_VECTOR_SCALAR(in, out)

        // transform vertex attributes by blended matrices
        if (vertex3f)
        {
                const float * RESTRICT v = model->surfmesh.data_vertex3f;
                const unsigned short * RESTRICT b = model->surfmesh.blends;
                // special case common combinations of attributes to avoid repeated loading of matrices
                if (normal3f)
                {
                        const float * RESTRICT n = model->surfmesh.data_normal3f;
                        if (svector3f && tvector3f)
                        {
                                const float * RESTRICT sv = model->surfmesh.data_svector3f;
                                const float * RESTRICT tv = model->surfmesh.data_tvector3f;

                                // Note that for SSE each iteration stores one element past end, so we break one vertex short
                                // and handle that with scalars in that case
                                for (i = 0; i < model->surfmesh.num_vertices; i++, v += 3, n += 3, sv += 3, tv += 3, b++,
                                                vertex3f += 3, normal3f += 3, svector3f += 3, tvector3f += 3)
                                {
                                        LOAD_MATRIX4();
                                        TRANSFORM_POSITION(v, vertex3f);
                                        TRANSFORM_VECTOR(n, normal3f);
                                        TRANSFORM_VECTOR(sv, svector3f);
                                        TRANSFORM_VECTOR(tv, tvector3f);
                                }

                                return;
                        }

                        for (i = 0;i < model->surfmesh.num_vertices; i++, v += 3, n += 3, b++, vertex3f += 3, normal3f += 3)
                        {
                                LOAD_MATRIX4();
                                TRANSFORM_POSITION(v, vertex3f);
                                TRANSFORM_VECTOR(n, normal3f);
                        }
                }
                else
                {
                        for (i = 0;i < model->surfmesh.num_vertices; i++, v += 3, b++, vertex3f += 3)
                        {
                                LOAD_MATRIX4();
                                TRANSFORM_POSITION(v, vertex3f);
                        }
                }
        }

        else if (normal3f)
        {
                const float * RESTRICT n = model->surfmesh.data_normal3f;
                const unsigned short * RESTRICT b = model->surfmesh.blends;
                for (i = 0; i < model->surfmesh.num_vertices; i++, n += 3, b++, normal3f += 3)
                {
                        LOAD_MATRIX3();
                        TRANSFORM_VECTOR(n, normal3f);
                }
        }

        if (svector3f)
        {
                const float * RESTRICT sv = model->surfmesh.data_svector3f;
                const unsigned short * RESTRICT b = model->surfmesh.blends;
                for (i = 0; i < model->surfmesh.num_vertices; i++, sv += 3, b++, svector3f += 3)
                {
                        LOAD_MATRIX3();
                        TRANSFORM_VECTOR(sv, svector3f);
                }
        }

        if (tvector3f)
        {
                const float * RESTRICT tv = model->surfmesh.data_tvector3f;
                const unsigned short * RESTRICT b = model->surfmesh.blends;
                for (i = 0; i < model->surfmesh.num_vertices; i++, tv += 3, b++, tvector3f += 3)
                {
                        LOAD_MATRIX3();
                        TRANSFORM_VECTOR(tv, tvector3f);
                }
        }
}