/* * ***** BEGIN GPL LICENSE BLOCK ***** * * 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. * * Contributor(s): Daniel Dunbar * Ton Roosendaal, * Ben Batt, * Brecht Van Lommel, * Campbell Barton * * ***** END GPL LICENSE BLOCK ***** * */ /** \file blender/modifiers/intern/MOD_cast.c * \ingroup modifiers */ #include "DNA_meshdata_types.h" #include "DNA_object_types.h" #include "BLI_math.h" #include "BLI_utildefines.h" #include "BKE_deform.h" #include "BKE_DerivedMesh.h" #include "BKE_modifier.h" #include "depsgraph_private.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 void copyData(ModifierData *md, ModifierData *target) { #if 0 CastModifierData *cmd = (CastModifierData *) md; CastModifierData *tcmd = (CastModifierData *) target; #endif modifier_copyData_generic(md, target); } static bool isDisabled(ModifierData *md, int 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 CustomDataMask requiredDataMask(Object *UNUSED(ob), ModifierData *md) { CastModifierData *cmd = (CastModifierData *)md; CustomDataMask dataMask = 0; /* ask for vertexgroups if we need them */ if (cmd->defgrp_name[0]) dataMask |= CD_MASK_MDEFORMVERT; return dataMask; } static void foreachObjectLink( ModifierData *md, Object *ob, void (*walk)(void *userData, Object *ob, Object **obpoin), void *userData) { CastModifierData *cmd = (CastModifierData *) md; walk(userData, ob, &cmd->object); } static void updateDepgraph(ModifierData *md, DagForest *forest, struct Scene *UNUSED(scene), Object *UNUSED(ob), DagNode *obNode) { CastModifierData *cmd = (CastModifierData *) md; if (cmd->object) { DagNode *curNode = dag_get_node(forest, cmd->object); dag_add_relation(forest, curNode, obNode, DAG_RL_OB_DATA, "Cast Modifier"); } } static void sphere_do( CastModifierData *cmd, Object *ob, DerivedMesh *dm, 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 = 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 */ modifier_get_vgroup(ob, dm, 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, Object *ob, DerivedMesh *dm, 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 = 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 */ modifier_get_vgroup(ob, dm, 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, Object *ob, DerivedMesh *derivedData, float (*vertexCos)[3], int numVerts, ModifierApplyFlag UNUSED(flag)) { DerivedMesh *dm = NULL; CastModifierData *cmd = (CastModifierData *)md; dm = get_dm(ob, NULL, derivedData, NULL, false, false); if (cmd->type == MOD_CAST_TYPE_CUBOID) { cuboid_do(cmd, ob, dm, vertexCos, numVerts); } else { /* MOD_CAST_TYPE_SPHERE or MOD_CAST_TYPE_CYLINDER */ sphere_do(cmd, ob, dm, vertexCos, numVerts); } if (dm != derivedData) dm->release(dm); } static void deformVertsEM( ModifierData *md, Object *ob, struct BMEditMesh *editData, DerivedMesh *derivedData, float (*vertexCos)[3], int numVerts) { DerivedMesh *dm = get_dm(ob, editData, derivedData, NULL, false, false); CastModifierData *cmd = (CastModifierData *)md; if (cmd->type == MOD_CAST_TYPE_CUBOID) { cuboid_do(cmd, ob, dm, vertexCos, numVerts); } else { /* MOD_CAST_TYPE_SPHERE or MOD_CAST_TYPE_CYLINDER */ sphere_do(cmd, ob, dm, vertexCos, numVerts); } if (dm != derivedData) dm->release(dm); } ModifierTypeInfo modifierType_Cast = { /* name */ "Cast", /* structName */ "CastModifierData", /* structSize */ sizeof(CastModifierData), /* type */ eModifierTypeType_OnlyDeform, /* flags */ eModifierTypeFlag_AcceptsCVs | eModifierTypeFlag_SupportsEditmode, /* copyData */ copyData, /* deformVerts */ deformVerts, /* deformMatrices */ NULL, /* deformVertsEM */ deformVertsEM, /* deformMatricesEM */ NULL, /* applyModifier */ NULL, /* applyModifierEM */ NULL, /* initData */ initData, /* requiredDataMask */ requiredDataMask, /* freeData */ NULL, /* isDisabled */ isDisabled, /* updateDepgraph */ updateDepgraph, /* dependsOnTime */ NULL, /* dependsOnNormals */ NULL, /* foreachObjectLink */ foreachObjectLink, /* foreachIDLink */ NULL, /* foreachTexLink */ NULL, };