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ab0bc65c24bdf68c356adb2566f3669153c931ea
blender-archive/source/blender/modifiers/intern/MOD_cast.c
Bastien Montagne ab0bc65c24 Refactor CDData masks, to have one mask per mesh elem type. 
We already have different storages for cddata of verts, edges etc.,
'simply' do the same for the mask flags we use all around Blender code
to request some data, or limit some operation to some layers, etc.

Reason we need this is that some cddata types (like Normals) are
actually shared between verts/polys/loops, and we don’t want to generate
clnors everytime we request vnors!

As a side note, this also does final fix to T59338, which was the
trigger for this patch (need to request computed loop normals for
another mesh than evaluated one).

Reviewers: brecht, campbellbarton, sergey

Differential Revision: https://developer.blender.org/D4407
2019-03-07 11:29:50 +01:00

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/*
* This program 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 2
* of the License, or (at your option) any later version.
*
* This program 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* The Original Code is Copyright (C) 2005 by the Blender Foundation.
* All rights reserved.
*/
/** \file
* \ingroup modifiers
*/
#include "BLI_utildefines.h"
#include "BLI_math.h"
#include "DNA_mesh_types.h"
#include "DNA_meshdata_types.h"
#include "DNA_object_types.h"
#include "BKE_deform.h"
#include "BKE_editmesh.h"
#include "BKE_library.h"
#include "BKE_library_query.h"
#include "BKE_mesh.h"
#include "BKE_modifier.h"
#include "DEG_depsgraph_query.h"
#include "MOD_util.h"
static void initData(ModifierData *md)
{
CastModifierData *cmd = (CastModifierData *) md;
cmd->fac = 0.5f;
cmd->radius = 0.0f;
cmd->size = 0.0f;
cmd->flag = MOD_CAST_X | MOD_CAST_Y | MOD_CAST_Z | MOD_CAST_SIZE_FROM_RADIUS;
cmd->type = MOD_CAST_TYPE_SPHERE;
cmd->defgrp_name[0] = '\0';
cmd->object = NULL;
}
static bool isDisabled(const struct Scene *UNUSED(scene), ModifierData *md, bool UNUSED(useRenderParams))
{
CastModifierData *cmd = (CastModifierData *) md;
short flag;
flag = cmd->flag & (MOD_CAST_X | MOD_CAST_Y | MOD_CAST_Z);
if ((cmd->fac == 0.0f) || flag == 0) return true;
return false;
}
static void requiredDataMask(Object *UNUSED(ob), ModifierData *md, CustomData_MeshMasks *r_cddata_masks)
{
CastModifierData *cmd = (CastModifierData *)md;
/* ask for vertexgroups if we need them */
if (cmd->defgrp_name[0] != '\0') {
r_cddata_masks->vmask |= CD_MASK_MDEFORMVERT;
}
}
static void foreachObjectLink(
ModifierData *md, Object *ob,
ObjectWalkFunc walk, void *userData)
{
CastModifierData *cmd = (CastModifierData *) md;
walk(userData, ob, &cmd->object, IDWALK_CB_NOP);
}
static void updateDepsgraph(ModifierData *md, const ModifierUpdateDepsgraphContext *ctx)
{
CastModifierData *cmd = (CastModifierData *)md;
if (cmd->object != NULL) {
DEG_add_object_relation(ctx->node, cmd->object, DEG_OB_COMP_TRANSFORM, "Cast Modifier");
DEG_add_modifier_to_transform_relation(ctx->node, "Cast Modifier");
}
}
static void sphere_do(
CastModifierData *cmd, const ModifierEvalContext *ctx,
Object *ob, Mesh *mesh,
float (*vertexCos)[3], int numVerts)
{
MDeformVert *dvert = NULL;
Object *ctrl_ob = NULL;
int i, defgrp_index;
bool has_radius = false;
short flag, type;
float len = 0.0f;
float fac = cmd->fac;
float facm = 1.0f - fac;
const float fac_orig = fac;
float vec[3], center[3] = {0.0f, 0.0f, 0.0f};
float mat[4][4], imat[4][4];
flag = cmd->flag;
type = cmd->type; /* projection type: sphere or cylinder */
if (type == MOD_CAST_TYPE_CYLINDER)
flag &= ~MOD_CAST_Z;
ctrl_ob = DEG_get_evaluated_object(ctx->depsgraph, cmd->object);
/* spherify's center is {0, 0, 0} (the ob's own center in its local
* space), by default, but if the user defined a control object,
* we use its location, transformed to ob's local space */
if (ctrl_ob) {
if (flag & MOD_CAST_USE_OB_TRANSFORM) {
invert_m4_m4(imat, ctrl_ob->obmat);
mul_m4_m4m4(mat, imat, ob->obmat);
invert_m4_m4(imat, mat);
}
invert_m4_m4(ob->imat, ob->obmat);
mul_v3_m4v3(center, ob->imat, ctrl_ob->obmat[3]);
}
/* now we check which options the user wants */
/* 1) (flag was checked in the "if (ctrl_ob)" block above) */
/* 2) cmd->radius > 0.0f: only the vertices within this radius from
* the center of the effect should be deformed */
if (cmd->radius > FLT_EPSILON) has_radius = 1;
/* 3) if we were given a vertex group name,
* only those vertices should be affected */
MOD_get_vgroup(ob, mesh, cmd->defgrp_name, &dvert, &defgrp_index);
if (flag & MOD_CAST_SIZE_FROM_RADIUS) {
len = cmd->radius;
}
else {
len = cmd->size;
}
if (len <= 0) {
for (i = 0; i < numVerts; i++) {
len += len_v3v3(center, vertexCos[i]);
}
len /= numVerts;
if (len == 0.0f) len = 10.0f;
}
for (i = 0; i < numVerts; i++) {
float tmp_co[3];
copy_v3_v3(tmp_co, vertexCos[i]);
if (ctrl_ob) {
if (flag & MOD_CAST_USE_OB_TRANSFORM) {
mul_m4_v3(mat, tmp_co);
}
else {
sub_v3_v3(tmp_co, center);
}
}
copy_v3_v3(vec, tmp_co);
if (type == MOD_CAST_TYPE_CYLINDER)
vec[2] = 0.0f;
if (has_radius) {
if (len_v3(vec) > cmd->radius) continue;
}
if (dvert) {
const float weight = defvert_find_weight(&dvert[i], defgrp_index);
if (weight == 0.0f) {
continue;
}
fac = fac_orig * weight;
facm = 1.0f - fac;
}
normalize_v3(vec);
if (flag & MOD_CAST_X)
tmp_co[0] = fac * vec[0] * len + facm * tmp_co[0];
if (flag & MOD_CAST_Y)
tmp_co[1] = fac * vec[1] * len + facm * tmp_co[1];
if (flag & MOD_CAST_Z)
tmp_co[2] = fac * vec[2] * len + facm * tmp_co[2];
if (ctrl_ob) {
if (flag & MOD_CAST_USE_OB_TRANSFORM) {
mul_m4_v3(imat, tmp_co);
}
else {
add_v3_v3(tmp_co, center);
}
}
copy_v3_v3(vertexCos[i], tmp_co);
}
}
static void cuboid_do(
CastModifierData *cmd, const ModifierEvalContext *ctx,
Object *ob, Mesh *mesh,
float (*vertexCos)[3], int numVerts)
{
MDeformVert *dvert = NULL;
Object *ctrl_ob = NULL;
int i, defgrp_index;
bool has_radius = false;
short flag;
float fac = cmd->fac;
float facm = 1.0f - fac;
const float fac_orig = fac;
float min[3], max[3], bb[8][3];
float center[3] = {0.0f, 0.0f, 0.0f};
float mat[4][4], imat[4][4];
flag = cmd->flag;
ctrl_ob = DEG_get_evaluated_object(ctx->depsgraph, cmd->object);
/* now we check which options the user wants */
/* 1) (flag was checked in the "if (ctrl_ob)" block above) */
/* 2) cmd->radius > 0.0f: only the vertices within this radius from
* the center of the effect should be deformed */
if (cmd->radius > FLT_EPSILON) has_radius = 1;
/* 3) if we were given a vertex group name,
* only those vertices should be affected */
MOD_get_vgroup(ob, mesh, cmd->defgrp_name, &dvert, &defgrp_index);
if (ctrl_ob) {
if (flag & MOD_CAST_USE_OB_TRANSFORM) {
invert_m4_m4(imat, ctrl_ob->obmat);
mul_m4_m4m4(mat, imat, ob->obmat);
invert_m4_m4(imat, mat);
}
invert_m4_m4(ob->imat, ob->obmat);
mul_v3_m4v3(center, ob->imat, ctrl_ob->obmat[3]);
}
if ((flag & MOD_CAST_SIZE_FROM_RADIUS) && has_radius) {
for (i = 0; i < 3; i++) {
min[i] = -cmd->radius;
max[i] = cmd->radius;
}
}
else if (!(flag & MOD_CAST_SIZE_FROM_RADIUS) && cmd->size > 0) {
for (i = 0; i < 3; i++) {
min[i] = -cmd->size;
max[i] = cmd->size;
}
}
else {
/* get bound box */
/* We can't use the object's bound box because other modifiers
* may have changed the vertex data. */
INIT_MINMAX(min, max);
/* Cast's center is the ob's own center in its local space,
* by default, but if the user defined a control object, we use
* its location, transformed to ob's local space. */
if (ctrl_ob) {
float vec[3];
/* let the center of the ctrl_ob be part of the bound box: */
minmax_v3v3_v3(min, max, center);
for (i = 0; i < numVerts; i++) {
sub_v3_v3v3(vec, vertexCos[i], center);
minmax_v3v3_v3(min, max, vec);
}
}
else {
for (i = 0; i < numVerts; i++) {
minmax_v3v3_v3(min, max, vertexCos[i]);
}
}
/* we want a symmetric bound box around the origin */
if (fabsf(min[0]) > fabsf(max[0])) max[0] = fabsf(min[0]);
if (fabsf(min[1]) > fabsf(max[1])) max[1] = fabsf(min[1]);
if (fabsf(min[2]) > fabsf(max[2])) max[2] = fabsf(min[2]);
min[0] = -max[0];
min[1] = -max[1];
min[2] = -max[2];
}
/* building our custom bounding box */
bb[0][0] = bb[2][0] = bb[4][0] = bb[6][0] = min[0];
bb[1][0] = bb[3][0] = bb[5][0] = bb[7][0] = max[0];
bb[0][1] = bb[1][1] = bb[4][1] = bb[5][1] = min[1];
bb[2][1] = bb[3][1] = bb[6][1] = bb[7][1] = max[1];
bb[0][2] = bb[1][2] = bb[2][2] = bb[3][2] = min[2];
bb[4][2] = bb[5][2] = bb[6][2] = bb[7][2] = max[2];
/* ready to apply the effect, one vertex at a time */
for (i = 0; i < numVerts; i++) {
int octant, coord;
float d[3], dmax, apex[3], fbb;
float tmp_co[3];
copy_v3_v3(tmp_co, vertexCos[i]);
if (ctrl_ob) {
if (flag & MOD_CAST_USE_OB_TRANSFORM) {
mul_m4_v3(mat, tmp_co);
}
else {
sub_v3_v3(tmp_co, center);
}
}
if (has_radius) {
if (fabsf(tmp_co[0]) > cmd->radius ||
fabsf(tmp_co[1]) > cmd->radius ||
fabsf(tmp_co[2]) > cmd->radius)
{
continue;
}
}
if (dvert) {
const float weight = defvert_find_weight(&dvert[i], defgrp_index);
if (weight == 0.0f) {
continue;
}
fac = fac_orig * weight;
facm = 1.0f - fac;
}
/* The algo used to project the vertices to their
* bounding box (bb) is pretty simple:
* for each vertex v:
* 1) find in which octant v is in;
* 2) find which outer "wall" of that octant is closer to v;
* 3) calculate factor (var fbb) to project v to that wall;
* 4) project. */
/* find in which octant this vertex is in */
octant = 0;
if (tmp_co[0] > 0.0f) octant += 1;
if (tmp_co[1] > 0.0f) octant += 2;
if (tmp_co[2] > 0.0f) octant += 4;
/* apex is the bb's vertex at the chosen octant */
copy_v3_v3(apex, bb[octant]);
/* find which bb plane is closest to this vertex ... */
d[0] = tmp_co[0] / apex[0];
d[1] = tmp_co[1] / apex[1];
d[2] = tmp_co[2] / apex[2];
/* ... (the closest has the higher (closer to 1) d value) */
dmax = d[0];
coord = 0;
if (d[1] > dmax) {
dmax = d[1];
coord = 1;
}
if (d[2] > dmax) {
/* dmax = d[2]; */ /* commented, we don't need it */
coord = 2;
}
/* ok, now we know which coordinate of the vertex to use */
if (fabsf(tmp_co[coord]) < FLT_EPSILON) /* avoid division by zero */
continue;
/* finally, this is the factor we wanted, to project the vertex
* to its bounding box (bb) */
fbb = apex[coord] / tmp_co[coord];
/* calculate the new vertex position */
if (flag & MOD_CAST_X)
tmp_co[0] = facm * tmp_co[0] + fac * tmp_co[0] * fbb;
if (flag & MOD_CAST_Y)
tmp_co[1] = facm * tmp_co[1] + fac * tmp_co[1] * fbb;
if (flag & MOD_CAST_Z)
tmp_co[2] = facm * tmp_co[2] + fac * tmp_co[2] * fbb;
if (ctrl_ob) {
if (flag & MOD_CAST_USE_OB_TRANSFORM) {
mul_m4_v3(imat, tmp_co);
}
else {
add_v3_v3(tmp_co, center);
}
}
copy_v3_v3(vertexCos[i], tmp_co);
}
}
static void deformVerts(
ModifierData *md, const ModifierEvalContext *ctx,
Mesh *mesh,
float (*vertexCos)[3],
int numVerts)
{
CastModifierData *cmd = (CastModifierData *)md;
Mesh *mesh_src = NULL;
if (ctx->object->type == OB_MESH && cmd->defgrp_name[0] != '\0') {
/* mesh_src is only needed for vgroups. */
mesh_src = MOD_deform_mesh_eval_get(ctx->object, NULL, mesh, NULL, numVerts, false, false);
}
if (cmd->type == MOD_CAST_TYPE_CUBOID) {
cuboid_do(cmd, ctx, ctx->object, mesh_src, vertexCos, numVerts);
}
else { /* MOD_CAST_TYPE_SPHERE or MOD_CAST_TYPE_CYLINDER */
sphere_do(cmd, ctx, ctx->object, mesh_src, vertexCos, numVerts);
}
if (!ELEM(mesh_src, NULL, mesh)) {
BKE_id_free(NULL, mesh_src);
}
}
static void deformVertsEM(
ModifierData *md, const ModifierEvalContext *ctx,
struct BMEditMesh *editData,
Mesh *mesh, float (*vertexCos)[3], int numVerts)
{
CastModifierData *cmd = (CastModifierData *)md;
Mesh *mesh_src = MOD_deform_mesh_eval_get(ctx->object, editData, mesh, NULL, numVerts, false, false);
BLI_assert(mesh_src->totvert == numVerts);
if (cmd->type == MOD_CAST_TYPE_CUBOID) {
cuboid_do(cmd, ctx, ctx->object, mesh_src, vertexCos, numVerts);
}
else { /* MOD_CAST_TYPE_SPHERE or MOD_CAST_TYPE_CYLINDER */
sphere_do(cmd, ctx, ctx->object, mesh_src, vertexCos, numVerts);
}
if (mesh_src != mesh) {
BKE_id_free(NULL, mesh_src);
}
}
ModifierTypeInfo modifierType_Cast = {
/* name */ "Cast",
/* structName */ "CastModifierData",
/* structSize */ sizeof(CastModifierData),
/* type */ eModifierTypeType_OnlyDeform,
/* flags */ eModifierTypeFlag_AcceptsCVs |
eModifierTypeFlag_AcceptsLattice |
eModifierTypeFlag_SupportsEditmode,
/* copyData */ modifier_copyData_generic,
/* deformVerts_DM */ NULL,
/* deformMatrices_DM */ NULL,
/* deformVertsEM_DM */ NULL,
/* deformMatricesEM_DM*/NULL,
/* applyModifier_DM */ NULL,
/* deformVerts */ deformVerts,
/* deformMatrices */ NULL,
/* deformVertsEM */ deformVertsEM,
/* deformMatricesEM */ NULL,
/* applyModifier */ NULL,
/* initData */ initData,
/* requiredDataMask */ requiredDataMask,
/* freeData */ NULL,
/* isDisabled */ isDisabled,
/* updateDepsgraph */ updateDepsgraph,
/* dependsOnTime */ NULL,
/* dependsOnNormals */ NULL,
/* foreachObjectLink */ foreachObjectLink,
/* foreachIDLink */ NULL,
/* foreachTexLink */ NULL,
};
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