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blender-archive/source/blender/blenkernel/intern/material.c
Ton Roosendaal 9df1460777 Christmas coding work! 
********* Node editor work:

- To enable Nodes for Materials, you have to set the "Use Nodes"
  button, in the new Material buttons "Nodes" Panel or in header
  of the Node editor. Doing this will disable Material-Layers.

- Nodes now execute materials ("shaders"), but still only using the
  previewrender code.

- Nodes have (optional) previews for rendered images.

- Node headers allow to hide buttons and/or preview image

- Nodes can be dragged larger/smaller (right-bottom corner)

- Nodes can be hidden (minimized) with hotkey H

- CTRL+click on an Input Socket gives a popup with default values.

- Changing Material/Texture or Mix node will adjust Node title.

- Click-drag outside of a Node changes cursor to "Knife' and allows to
  draw a rect where to cut Links.

- Added new node types RGBtoBW, Texture, In/Output, ColorRamp

- Material Nodes have options to ouput diffuse or specular, or to use
  a negative normal. The input socket 'Normal' will force the material
  to use that normal, otherwise it uses the normal from the Material
  that has the node tree.

- When drawing a link between two not-matching sockets, Blender inserts
  a converting node (now only for value/rgb combos)

- When drawing a link to an input socket that's already in use, the
  old link will either disappear or flip to another unused socket.

- A click on a Material Node will activate it, and show all its settings
  in the Material Buttons. Active Material Nodes draw the material icon
  in red.

- A click on any node will show its options in the Node Panel in the
  Material buttons.

- Multiple Output Nodes can be used, to sample contents of a tree, but
  only one Output is the real one, which is indicated in a different
  color and red material icon.

- Added ThemeColors for node types

- ALT+C will convert existing Material-Layers to Node... this currently
  only adds the material/mix nodes and connects them. Dunno if this is
  worth a lot of coding work to make perfect?

- Press C to call another "Solve order", which will show all possible
  cyclic conflicts (if there are).

- Technical: nodes now use "Type" structs which define the
  structure of nodes and in/output sockets. The Type structs store all
  fixed info, callbacks, and allow to reconstruct saved Nodes to match
  what is required by Blender.

- Defining (new) nodes now is as simple as filling in a fixed
  Type struct, plus code some callbacks. A doc will be made!

- Node preview images are by default float

********* Icon drawing:

- Cleanup of how old icons were implemented in new system, making
  them 16x16 too, correctly centered *and* scaled.

- Made drawing Icons use float coordinates

- Moved BIF_calcpreview_image() into interface_icons.c, renamed it
  icon_from_image(). Removed a lot of unneeded Imbuf magic here! :)

- Skipped scaling and imbuf copying when icons are OK size


********* Preview render:

- Huge cleanup of code....

- renaming BIF_xxx calls that only were used internally

- BIF_previewrender() now accepts an argument for rendering method,
  so it supports icons, buttonwindow previewrender and node editor

- Only a single BIF_preview_changed() call now exists, supporting all
  signals as needed for buttos and node editor


********* More stuff:

- glutil.c, glaDrawPixelsSafe() and glaDrawPixelsTex() now accept format
  argument for GL_FLOAT rects

- Made the ColorBand become a built-in button for interface.c
  Was a load of cleanup work in buttons_shading.c...

- removed a load of unneeded glBlendFunc() calls

- Fixed bug in calculating text length for buttons (ancient!)
2005-12-28 15:42:51 +00:00

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/* material.c
*
*
* $Id$
*
* ***** BEGIN GPL/BL DUAL 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. The Blender
* Foundation also sells licenses for use in proprietary software under
* the Blender License. See http://www.blender.org/BL/ for information
* about this.
*
* 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*
* The Original Code is Copyright (C) 2001-2002 by NaN Holding BV.
* All rights reserved.
*
* The Original Code is: all of this file.
*
* Contributor(s): none yet.
*
* ***** END GPL/BL DUAL LICENSE BLOCK *****
*/
#include <string.h>
#include "MEM_guardedalloc.h"
#include "DNA_curve_types.h"
#include "DNA_material_types.h"
#include "DNA_mesh_types.h"
#include "DNA_meta_types.h"
#include "DNA_node_types.h"
#include "DNA_object_types.h"
#include "DNA_scene_types.h"
#include "DNA_texture_types.h"
#include "BLI_blenlib.h"
#include "BKE_bad_level_calls.h"
#include "BKE_blender.h"
#include "BKE_displist.h"
#include "BKE_global.h"
#include "BKE_icons.h"
#include "BKE_library.h"
#include "BKE_main.h"
#include "BKE_material.h"
#include "BKE_mesh.h"
#include "BKE_node.h"
#include "BKE_utildefines.h"
#include "BPY_extern.h"
/* not material itself */
void free_material(Material *ma)
{
MaterialLayer *ml;
MTex *mtex;
int a;
BPY_free_scriptlink(&ma->scriptlink);
for(a=0; a<MAX_MTEX; a++) {
mtex= ma->mtex[a];
if(mtex && mtex->tex) mtex->tex->id.us--;
if(mtex) MEM_freeN(mtex);
}
if(ma->ramp_col) MEM_freeN(ma->ramp_col);
if(ma->ramp_spec) MEM_freeN(ma->ramp_spec);
BKE_icon_delete((struct ID*)ma);
ma->id.icon_id = 0;
for(ml= ma->layers.first; ml; ml= ml->next)
if(ml->mat) ml->mat->id.us--;
BLI_freelistN(&ma->layers);
if(ma->nodetree)
ntreeFreeTree(ma->nodetree);
}
void init_material(Material *ma)
{
ma->lay= 1;
ma->r= ma->g= ma->b= ma->ref= 0.8;
ma->specr= ma->specg= ma->specb= 1.0;
ma->mirr= ma->mirg= ma->mirb= 1.0;
ma->spectra= 1.0;
ma->amb= 0.5;
ma->alpha= 1.0;
ma->spec= ma->hasize= 0.5;
ma->har= 50;
ma->starc= ma->ringc= 4;
ma->linec= 12;
ma->flarec= 1;
ma->flaresize= ma->subsize= 1.0;
ma->flareboost= 1;
ma->seed2= 6;
ma->friction= 0.5;
ma->refrac= 4.0;
ma->roughness= 0.5;
ma->param[0]= 0.5;
ma->param[1]= 0.1;
ma->param[2]= 0.5;
ma->param[3]= 0.1;
ma->rms= 0.1;
ma->darkness= 1.0;
ma->strand_sta= ma->strand_end= 1.0f;
ma->ang= 1.0;
ma->ray_depth= 2;
ma->ray_depth_tra= 2;
ma->fresnel_mir= 0.0;
ma->fresnel_tra= 0.0;
ma->fresnel_tra_i= 1.25;
ma->fresnel_mir_i= 1.25;
ma->rampfac_col= 1.0;
ma->rampfac_spec= 1.0;
ma->pr_lamp= 3; /* two lamps, is bits */
ma->ml_flag= ML_RENDER; /* default render base material for layers */
ma->mode= MA_TRACEBLE|MA_SHADBUF|MA_SHADOW|MA_RADIO|MA_RAYBIAS|MA_TANGENT_STR;
}
Material *add_material(char *name)
{
Material *ma;
ma= alloc_libblock(&G.main->mat, ID_MA, name);
init_material(ma);
return ma;
}
Material *copy_material(Material *ma)
{
Material *man;
MaterialLayer *ml;
int a;
man= copy_libblock(ma);
id_us_plus((ID *)man->ipo);
for(a=0; a<MAX_MTEX; a++) {
if(ma->mtex[a]) {
man->mtex[a]= MEM_mallocN(sizeof(MTex), "copymaterial");
memcpy(man->mtex[a], ma->mtex[a], sizeof(MTex));
id_us_plus((ID *)man->mtex[a]->tex);
}
}
BPY_copy_scriptlink(&ma->scriptlink);
if(ma->ramp_col) man->ramp_col= MEM_dupallocN(ma->ramp_col);
if(ma->ramp_spec) man->ramp_spec= MEM_dupallocN(ma->ramp_spec);
duplicatelist(&man->layers, &ma->layers);
for(ml= man->layers.first; ml; ml= ml->next)
id_us_plus((ID *)ml->mat);
if(ma->nodetree) {
man->nodetree= ntreeCopyTree(ma->nodetree, 0); /* 0 == full new tree */
}
return man;
}
void make_local_material(Material *ma)
{
Object *ob;
Mesh *me;
Curve *cu;
MetaBall *mb;
Material *man;
int a, local=0, lib=0;
/* - only lib users: do nothing
* - only local users: set flag
* - mixed: make copy
*/
if(ma->id.lib==0) return;
if(ma->id.us==1) {
ma->id.lib= 0;
ma->id.flag= LIB_LOCAL;
new_id(0, (ID *)ma, 0);
for(a=0; a<MAX_MTEX; a++) {
if(ma->mtex[a]) id_lib_extern((ID *)ma->mtex[a]->tex);
}
return;
}
/* test objects */
ob= G.main->object.first;
while(ob) {
if(ob->mat) {
for(a=0; a<ob->totcol; a++) {
if(ob->mat[a]==ma) {
if(ob->id.lib) lib= 1;
else local= 1;
}
}
}
ob= ob->id.next;
}
/* test meshes */
me= G.main->mesh.first;
while(me) {
if(me->mat) {
for(a=0; a<me->totcol; a++) {
if(me->mat[a]==ma) {
if(me->id.lib) lib= 1;
else local= 1;
}
}
}
me= me->id.next;
}
/* test curves */
cu= G.main->curve.first;
while(cu) {
if(cu->mat) {
for(a=0; a<cu->totcol; a++) {
if(cu->mat[a]==ma) {
if(cu->id.lib) lib= 1;
else local= 1;
}
}
}
cu= cu->id.next;
}
/* test mballs */
mb= G.main->mball.first;
while(mb) {
if(mb->mat) {
for(a=0; a<mb->totcol; a++) {
if(mb->mat[a]==ma) {
if(mb->id.lib) lib= 1;
else local= 1;
}
}
}
mb= mb->id.next;
}
if(local && lib==0) {
ma->id.lib= 0;
ma->id.flag= LIB_LOCAL;
for(a=0; a<MAX_MTEX; a++) {
if(ma->mtex[a]) id_lib_extern((ID *)ma->mtex[a]->tex);
}
new_id(0, (ID *)ma, 0);
}
else if(local && lib) {
Material *mat;
MaterialLayer *ml;
man= copy_material(ma);
man->id.us= 0;
/* do material layers */
for(mat= G.main->mat.first; mat; mat= mat->id.next) {
if(mat->id.lib==NULL) {
for(ml= mat->layers.first; ml; ml= ml->next) {
if(ml->mat==ma) {
ml->mat= man;
man->id.us++;
ma->id.us--;
}
}
}
}
/* do objects */
ob= G.main->object.first;
while(ob) {
if(ob->mat) {
for(a=0; a<ob->totcol; a++) {
if(ob->mat[a]==ma) {
if(ob->id.lib==0) {
ob->mat[a]= man;
man->id.us++;
ma->id.us--;
}
}
}
}
ob= ob->id.next;
}
/* do meshes */
me= G.main->mesh.first;
while(me) {
if(me->mat) {
for(a=0; a<me->totcol; a++) {
if(me->mat[a]==ma) {
if(me->id.lib==0) {
me->mat[a]= man;
man->id.us++;
ma->id.us--;
}
}
}
}
me= me->id.next;
}
/* do curves */
cu= G.main->curve.first;
while(cu) {
if(cu->mat) {
for(a=0; a<cu->totcol; a++) {
if(cu->mat[a]==ma) {
if(cu->id.lib==0) {
cu->mat[a]= man;
man->id.us++;
ma->id.us--;
}
}
}
}
cu= cu->id.next;
}
/* do mballs */
mb= G.main->mball.first;
while(mb) {
if(mb->mat) {
for(a=0; a<mb->totcol; a++) {
if(mb->mat[a]==ma) {
if(mb->id.lib==0) {
mb->mat[a]= man;
man->id.us++;
ma->id.us--;
}
}
}
}
mb= mb->id.next;
}
}
}
Material ***give_matarar(Object *ob)
{
Mesh *me;
Curve *cu;
MetaBall *mb;
if(ob->type==OB_MESH) {
me= ob->data;
return &(me->mat);
}
else if ELEM3(ob->type, OB_CURVE, OB_FONT, OB_SURF) {
cu= ob->data;
return &(cu->mat);
}
else if(ob->type==OB_MBALL) {
mb= ob->data;
return &(mb->mat);
}
return 0;
}
short *give_totcolp(Object *ob)
{
Mesh *me;
Curve *cu;
MetaBall *mb;
if(ob->type==OB_MESH) {
me= ob->data;
return &(me->totcol);
}
else if ELEM3(ob->type, OB_CURVE, OB_FONT, OB_SURF) {
cu= ob->data;
return &(cu->totcol);
}
else if(ob->type==OB_MBALL) {
mb= ob->data;
return &(mb->totcol);
}
return 0;
}
Material *give_current_material(Object *ob, int act)
{
Material ***matarar, *ma;
if(ob==0) return 0;
if(ob->totcol==0) return 0;
if(act>ob->totcol) act= ob->totcol;
else if(act==0) act= 1;
if( BTST(ob->colbits, act-1) ) { /* in object */
ma= ob->mat[act-1];
}
else { /* in data */
matarar= give_matarar(ob);
if(matarar && *matarar) ma= (*matarar)[act-1];
else ma= 0;
}
return ma;
}
ID *material_from(Object *ob, int act)
{
if(ob==0) return 0;
if(ob->totcol==0) return ob->data;
if(act==0) act= 1;
if( BTST(ob->colbits, act-1) ) return (ID *)ob;
else return ob->data;
}
/* GS reads the memory pointed at in a specific ordering. There are,
* however two definitions for it. I have jotted them down here, both,
* but I think the first one is actually used. The thing is that
* big-endian systems might read this the wrong way round. OTOH, we
* constructed the IDs that are read out with this macro explicitly as
* well. I expect we'll sort it out soon... */
/* from blendef: */
#define GS(a) (*((short *)(a)))
/* from misc_util: flip the bytes from x */
/* #define GS(x) (((unsigned char *)(x))[0] << 8 | ((unsigned char *)(x))[1]) */
void test_object_materials(ID *id)
{
/* make the ob mat-array same size as 'ob->data' mat-array */
Object *ob;
Mesh *me;
Curve *cu;
MetaBall *mb;
Material **newmatar;
int totcol=0;
if(id==0) return;
if( GS(id->name)==ID_ME ) {
me= (Mesh *)id;
totcol= me->totcol;
}
else if( GS(id->name)==ID_CU ) {
cu= (Curve *)id;
totcol= cu->totcol;
}
else if( GS(id->name)==ID_MB ) {
mb= (MetaBall *)id;
totcol= mb->totcol;
}
else return;
ob= G.main->object.first;
while(ob) {
if(ob->data==id) {
if(totcol==0) {
if(ob->totcol) {
MEM_freeN(ob->mat);
ob->mat= 0;
}
}
else if(ob->totcol<totcol) {
newmatar= MEM_callocN(sizeof(void *)*totcol, "newmatar");
if(ob->totcol) {
memcpy(newmatar, ob->mat, sizeof(void *)*ob->totcol);
MEM_freeN(ob->mat);
}
ob->mat= newmatar;
}
ob->totcol= totcol;
if(ob->totcol && ob->actcol==0) ob->actcol= 1;
if(ob->actcol>ob->totcol) ob->actcol= ob->totcol;
}
ob= ob->id.next;
}
}
void assign_material(Object *ob, Material *ma, int act)
{
Material *mao, **matar, ***matarar;
short *totcolp;
if(act>MAXMAT) return;
if(act<1) act= 1;
/* test arraylens */
totcolp= give_totcolp(ob);
matarar= give_matarar(ob);
if(totcolp==0 || matarar==0) return;
if( act > *totcolp) {
matar= MEM_callocN(sizeof(void *)*act, "matarray1");
if( *totcolp) {
memcpy(matar, *matarar, sizeof(void *)*( *totcolp ));
MEM_freeN(*matarar);
}
*matarar= matar;
*totcolp= act;
}
if(act > ob->totcol) {
matar= MEM_callocN(sizeof(void *)*act, "matarray2");
if( ob->totcol) {
memcpy(matar, ob->mat, sizeof(void *)*( ob->totcol ));
MEM_freeN(ob->mat);
}
ob->mat= matar;
ob->totcol= act;
}
/* do it */
if( BTST(ob->colbits, act-1) ) { /* in object */
mao= ob->mat[act-1];
if(mao) mao->id.us--;
ob->mat[act-1]= ma;
}
else { /* in data */
mao= (*matarar)[act-1];
if(mao) mao->id.us--;
(*matarar)[act-1]= ma;
}
id_us_plus((ID *)ma);
test_object_materials(ob->data);
}
void new_material_to_objectdata(Object *ob)
{
Material *ma;
if(ob==0) return;
if(ob->totcol>=MAXMAT) return;
ma= give_current_material(ob, ob->actcol);
if(ma==0) {
ma= add_material("Material");
ma->id.us= 0;
}
if(ob->actcol) {
if( BTST(ob->colbits, ob->actcol-1) ) {
ob->colbits= BSET(ob->colbits, ob->totcol);
}
}
assign_material(ob, ma, ob->totcol+1);
ob->actcol= ob->totcol;
}
/* will be renamed... now easy to re-use for nodes! */
Material *get_active_matlayer(Material *ma)
{
if(ma==NULL) return NULL;
if(ma->use_nodes) {
bNode *node= nodeGetActiveID(ma->nodetree, ID_MA);
if(node && node->id) {
return (Material *)node->id;
}
}
else {
MaterialLayer *ml;
for(ml= ma->layers.first; ml; ml= ml->next)
if(ml->flag & ML_ACTIVE) break;
if(ml)
return ml->mat;
}
return ma;
}
void init_render_material(Material *ma)
{
MTex *mtex;
int a, needuv=0;
if(ma->flarec==0) ma->flarec= 1;
/* add all texcoflags from mtex */
ma->texco= 0;
ma->mapto= 0;
for(a=0; a<MAX_MTEX; a++) {
mtex= ma->mtex[a];
if(mtex && mtex->tex) {
ma->texco |= mtex->texco;
ma->mapto |= mtex->mapto;
if(R.osa) {
if ELEM3(mtex->tex->type, TEX_IMAGE, TEX_PLUGIN, TEX_ENVMAP) ma->texco |= TEXCO_OSA;
}
if(ma->texco & (TEXCO_ORCO|TEXCO_REFL|TEXCO_NORM|TEXCO_STRAND|TEXCO_STRESS)) needuv= 1;
else if(ma->texco & (TEXCO_GLOB|TEXCO_UV|TEXCO_OBJECT)) needuv= 1;
else if(ma->texco & (TEXCO_LAVECTOR|TEXCO_VIEW|TEXCO_STICKY)) needuv= 1;
if(mtex->object) mtex->object->flag |= OB_DO_IMAT;
}
}
if(ma->mode & MA_ZTRA) {
/* if(ma->alpha==0.0 || ma->alpha==1.0) */
if(R.flag & R_RENDERING) R.flag |= R_ZTRA;
}
if(ma->mode & MA_RADIO) needuv= 1;
if(ma->mode & (MA_VERTEXCOL|MA_VERTEXCOLP|MA_FACETEXTURE)) {
needuv= 1;
if(R.osa) ma->texco |= TEXCO_OSA; /* for texfaces */
}
if(needuv) ma->texco |= NEED_UV;
// since the raytracer doesnt recalc O structs for each ray, we have to preset them all
if(ma->mode & (MA_RAYMIRROR|MA_RAYTRANSP|MA_SHADOW_TRA)) {
ma->texco |= NEED_UV|TEXCO_ORCO|TEXCO_REFL|TEXCO_NORM;
if(R.osa) ma->texco |= TEXCO_OSA;
}
ma->ambr= ma->amb*R.wrld.ambr;
ma->ambg= ma->amb*R.wrld.ambg;
ma->ambb= ma->amb*R.wrld.ambb;
/* will become or-ed result of all layer modes */
ma->mode_l= ma->mode;
}
void init_render_materials()
{
Material *ma;
MaterialLayer *ml;
/* two steps, first initialize, then or the flags for layers */
for(ma= G.main->mat.first; ma; ma= ma->id.next) {
if(ma->id.us) init_render_material(ma);
}
for(ma= G.main->mat.first; ma; ma= ma->id.next) {
for(ml= ma->layers.first; ml; ml= ml->next) {
if(ml->mat) {
ma->texco |= ml->mat->texco;
ma->mode_l |= ml->mat->mode;
}
}
}
}
/* ****************** */
char colname_array[125][20]= {
"Black","DarkRed","HalveRed","Red","Red",
"DarkGreen","DarkOlive","Brown","Chocolate","OrangeRed",
"HalveGreen","GreenOlive","DryOlive","Goldenrod","DarkOrange",
"LightGreen","Chartreuse","YellowGreen","Yellow","Gold",
"Green","LawnGreen","GreenYellow","LightOlive","Yellow",
"DarkBlue","DarkPurple","HotPink","VioletPink","RedPink",
"SlateGray","DarkGrey","PalePurple","IndianRed","Tomato",
"SeaGreen","PaleGreen","GreenKhaki","LightBrown","LightSalmon",
"SpringGreen","PaleGreen","MediumOlive","YellowBrown","LightGold",
"LightGreen","LightGreen","LightGreen","GreenYellow","PaleYellow",
"HalveBlue","DarkSky","HalveMagenta","VioletRed","DeepPink",
"SteelBlue","SkyBlue","Orchid","LightHotPink","HotPink",
"SeaGreen","SlateGray","MediumGrey","Burlywood","LightPink",
"SpringGreen","Aquamarine","PaleGreen","Khaki","PaleOrange",
"SpringGreen","SeaGreen","PaleGreen","PaleWhite","YellowWhite",
"LightBlue","Purple","MediumOrchid","Magenta","Magenta",
"RoyalBlue","SlateBlue","MediumOrchid","Orchid","Magenta",
"DeepSkyBlue","LightSteelBlue","LightSkyBlue","Violet","LightPink",
"Cyaan","DarkTurquoise","SkyBlue","Grey","Snow",
"Mint","Mint","Aquamarine","MintCream","Ivory",
"Blue","Blue","DarkMagenta","DarkOrchid","Magenta",
"SkyBlue","RoyalBlue","LightSlateBlue","MediumOrchid","Magenta",
"DodgerBlue","SteelBlue","MediumPurple","PalePurple","Plum",
"DeepSkyBlue","PaleBlue","LightSkyBlue","PalePurple","Thistle",
"Cyan","ColdBlue","PaleTurquoise","GhostWhite","White"
};
void automatname(Material *ma)
{
int nr, r, g, b;
float ref;
if(ma==0) return;
if(ma->mode & MA_SHLESS) ref= 1.0;
else ref= ma->ref;
r= (int)(4.99*(ref*ma->r));
g= (int)(4.99*(ref*ma->g));
b= (int)(4.99*(ref*ma->b));
nr= r + 5*g + 25*b;
if(nr>124) nr= 124;
new_id(&G.main->mat, (ID *)ma, colname_array[nr]);
}
void delete_material_index()
{
Material *mao, ***matarar;
Object *ob, *obt;
Curve *cu;
Nurb *nu;
short *totcolp;
int a, actcol;
if(G.obedit) {
error("Unable to perform function in EditMode");
return;
}
ob= ((G.scene->basact)? (G.scene->basact->object) : 0) ;
if(ob==0 || ob->totcol==0) return;
/* take a mesh/curve/mball as starting point, remove 1 index,
* AND with all objects that share the ob->data
*
* after that check indices in mesh/curve/mball!!!
*/
totcolp= give_totcolp(ob);
matarar= give_matarar(ob);
/* we delete the actcol */
if(ob->totcol) {
mao= (*matarar)[ob->actcol-1];
if(mao) mao->id.us--;
}
for(a=ob->actcol; a<ob->totcol; a++) {
(*matarar)[a-1]= (*matarar)[a];
}
(*totcolp)--;
if(*totcolp==0) {
MEM_freeN(*matarar);
*matarar= 0;
}
actcol= ob->actcol;
obt= G.main->object.first;
while(obt) {
if(obt->data==ob->data) {
/* WATCH IT: do not use actcol from ob or from obt (can become zero) */
mao= obt->mat[actcol-1];
if(mao) mao->id.us--;
for(a=actcol; a<obt->totcol; a++) obt->mat[a-1]= obt->mat[a];
obt->totcol--;
if(obt->actcol > obt->totcol) obt->actcol= obt->totcol;
if(obt->totcol==0) {
MEM_freeN(obt->mat);
obt->mat= 0;
}
}
obt= obt->id.next;
}
/* check indices from mesh */
if(ob->type==OB_MESH) {
Mesh *me= get_mesh(ob);
mesh_delete_material_index(me, actcol-1);
freedisplist(&ob->disp);
}
else if ELEM(ob->type, OB_CURVE, OB_SURF) {
cu= ob->data;
nu= cu->nurb.first;
while(nu) {
if(nu->mat_nr && nu->mat_nr>=actcol-1) {
nu->mat_nr--;
if (ob->type == OB_CURVE) nu->charidx--;
}
nu= nu->next;
}
freedisplist(&ob->disp);
}
}
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