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blender-archive/source/blender/blenkernel/intern/material.c
Ton Roosendaal aad31875d7 Special bf-committers request; Lamp/World/Material now each have 10 
channels to link texture to.

The amount of code changes seems large, but is mostly getting rind of
hardcoded values (6 and 8) for channels, replacing it with MAX_MTEX.

Further did some fixes;
- Ipo for Lamp showed too many mapping channels
- Texture MapTo buttons for lamp missed the slider to blend texture color
- Lamp texture mapping "View" only worked for Spot, now it uses lamp-
  view vector for all types. (Nice for projections!)
2004-12-04 21:49:02 +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_material_types.h"
#include "DNA_texture_types.h"
#include "DNA_mesh_types.h"
#include "DNA_object_types.h"
#include "DNA_curve_types.h"
#include "DNA_meta_types.h"
#include "DNA_scene_types.h"
#include "BLI_blenlib.h"
#include "BKE_bad_level_calls.h"
#include "BKE_utildefines.h"
#include "BKE_global.h"
#include "BKE_main.h"
#include "BKE_mesh.h"
#include "BKE_library.h"
#include "BKE_displist.h"
#include "BKE_material.h"
#include "BPY_extern.h"
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
void free_material(Material *ma)
{
int a;
MTex *mtex;
BPY_free_scriptlink(&ma->scriptlink);
if(ma->ren) MEM_freeN(ma->ren);
ma->ren= NULL;
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);
}
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->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->mode= MA_TRACEBLE+MA_SHADOW+MA_RADIO;
}
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;
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);
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) {
man= copy_material(ma);
man->id.us= 0;
/* 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;
}
void init_render_material(Material *ma)
{
MTex *mtex;
int a, needuv=0;
if(ma->ren) return;
if(ma->flarec==0) ma->flarec= 1;
ma->ren= MEM_mallocN(sizeof(Material), "initrendermaterial");
memcpy(ma->ren, ma, sizeof(Material));
/* add all texcoflags from mtex */
ma= ma->ren;
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 & (511)) 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) */
R.flag |= R_ZTRA;
}
if(ma->mode & MA_VERTEXCOLP) ma->mode |= MA_VERTEXCOL;
if(ma->mode & MA_RADIO) needuv= 1;
if(ma->mode & (MA_VERTEXCOL|MA_FACETEXTURE)) {
needuv= 1;
if(R.osa) ma->texco |= TEXCO_OSA; /* for texfaces */
}
if(needuv) ma->texco |= NEED_UV;
// optimize, render only checks for ray_mirror value */
if((ma->mode & MA_RAYMIRROR)==0) ma->ray_mirror= 0.0;
// 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;
}
void init_render_materials()
{
Material *ma;
ma= G.main->mat.first;
while(ma) {
if(ma->id.us) init_render_material(ma);
ma= ma->id.next;
}
}
void end_render_material(Material *ma)
{
if(ma->ren) MEM_freeN(ma->ren);
ma->ren= 0;
if(ma->mode & (MA_VERTEXCOLP|MA_FACETEXTURE)) {
if( !(ma->mode & MA_HALO) ) {
ma->r= ma->g= ma->b= 1.0;
}
}
}
void end_render_materials()
{
Material *ma;
ma= G.main->mat.first;
while(ma) {
if(ma->id.us) end_render_material(ma);
ma= ma->id.next;
}
}
/* ****************** */
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;
}
allqueue(REDRAWBUTSMAT, 0);
/* check indices from mesh */
if(ob->type==OB_MESH) {
Mesh *me= get_mesh(ob);
mesh_delete_material_index(me, actcol-1);
makeDispList(ob);
}
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--;
nu= nu->next;
}
makeDispList(ob);
}
}
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