archive/blender-archive
Archived
1
1
Fork 0
Code Pull Requests Packages Activity
This repository has been archived on 2023-10-09. You can view files and clone it, but cannot push or open issues or pull requests.
Files
6bf9c8ac8918a6656c20cca2c08f20b38e90980c
blender-archive/source/blender/blenkernel/intern/texture.c
Lukas Tönne 6ecab6dd8e Revert particle system and point cache removal in blender2.8 branch. 
This reverts commit 5aa19be912 and b4a721af69.

Due to postponement of particle system rewrite it was decided to put particle code
back into the 2.8 branch for the time being.
2016-12-28 17:30:58 +01:00

1513 lines
32 KiB
C
Raw Blame History

/*
* ***** 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) 2001-2002 by NaN Holding BV.
* All rights reserved.
*
* The Original Code is: all of this file.
*
* Contributor(s): none yet.
*
* ***** END GPL LICENSE BLOCK *****
*/
/** \file blender/blenkernel/intern/texture.c
* \ingroup bke
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include "MEM_guardedalloc.h"
#include "BLI_math.h"
#include "BLI_kdopbvh.h"
#include "BLI_utildefines.h"
#include "BLI_math_color.h"
#include "DNA_key_types.h"
#include "DNA_object_types.h"
#include "DNA_lamp_types.h"
#include "DNA_material_types.h"
#include "DNA_world_types.h"
#include "DNA_brush_types.h"
#include "DNA_node_types.h"
#include "DNA_color_types.h"
#include "DNA_particle_types.h"
#include "DNA_linestyle_types.h"
#include "IMB_imbuf.h"
#include "BKE_global.h"
#include "BKE_main.h"
#include "BKE_library.h"
#include "BKE_library_query.h"
#include "BKE_library_remap.h"
#include "BKE_image.h"
#include "BKE_material.h"
#include "BKE_texture.h"
#include "BKE_key.h"
#include "BKE_icons.h"
#include "BKE_node.h"
#include "BKE_animsys.h"
#include "BKE_colortools.h"
#include "BKE_scene.h"
#include "RE_shader_ext.h"
/* ****************** Mapping ******************* */
TexMapping *BKE_texture_mapping_add(int type)
{
TexMapping *texmap = MEM_callocN(sizeof(TexMapping), "TexMapping");
BKE_texture_mapping_default(texmap, type);
return texmap;
}
void BKE_texture_mapping_default(TexMapping *texmap, int type)
{
memset(texmap, 0, sizeof(TexMapping));
texmap->size[0] = texmap->size[1] = texmap->size[2] = 1.0f;
texmap->max[0] = texmap->max[1] = texmap->max[2] = 1.0f;
unit_m4(texmap->mat);
texmap->projx = PROJ_X;
texmap->projy = PROJ_Y;
texmap->projz = PROJ_Z;
texmap->mapping = MTEX_FLAT;
texmap->type = type;
}
void BKE_texture_mapping_init(TexMapping *texmap)
{
float smat[4][4], rmat[4][4], tmat[4][4], proj[4][4], size[3];
if (texmap->projx == PROJ_X && texmap->projy == PROJ_Y && texmap->projz == PROJ_Z &&
is_zero_v3(texmap->loc) && is_zero_v3(texmap->rot) && is_one_v3(texmap->size))
{
unit_m4(texmap->mat);
texmap->flag |= TEXMAP_UNIT_MATRIX;
}
else {
/* axis projection */
zero_m4(proj);
proj[3][3] = 1.0f;
if (texmap->projx != PROJ_N)
proj[texmap->projx - 1][0] = 1.0f;
if (texmap->projy != PROJ_N)
proj[texmap->projy - 1][1] = 1.0f;
if (texmap->projz != PROJ_N)
proj[texmap->projz - 1][2] = 1.0f;
/* scale */
copy_v3_v3(size, texmap->size);
if (ELEM(texmap->type, TEXMAP_TYPE_TEXTURE, TEXMAP_TYPE_NORMAL)) {
/* keep matrix invertible */
if (fabsf(size[0]) < 1e-5f)
size[0] = signf(size[0]) * 1e-5f;
if (fabsf(size[1]) < 1e-5f)
size[1] = signf(size[1]) * 1e-5f;
if (fabsf(size[2]) < 1e-5f)
size[2] = signf(size[2]) * 1e-5f;
}
size_to_mat4(smat, texmap->size);
/* rotation */
eul_to_mat4(rmat, texmap->rot);
/* translation */
unit_m4(tmat);
copy_v3_v3(tmat[3], texmap->loc);
if (texmap->type == TEXMAP_TYPE_TEXTURE) {
/* to transform a texture, the inverse transform needs
* to be applied to the texture coordinate */
mul_m4_series(texmap->mat, tmat, rmat, smat);
invert_m4(texmap->mat);
}
else if (texmap->type == TEXMAP_TYPE_POINT) {
/* forward transform */
mul_m4_series(texmap->mat, tmat, rmat, smat);
}
else if (texmap->type == TEXMAP_TYPE_VECTOR) {
/* no translation for vectors */
mul_m4_m4m4(texmap->mat, rmat, smat);
}
else if (texmap->type == TEXMAP_TYPE_NORMAL) {
/* no translation for normals, and inverse transpose */
mul_m4_m4m4(texmap->mat, rmat, smat);
invert_m4(texmap->mat);
transpose_m4(texmap->mat);
}
/* projection last */
mul_m4_m4m4(texmap->mat, texmap->mat, proj);
texmap->flag &= ~TEXMAP_UNIT_MATRIX;
}
}
ColorMapping *BKE_texture_colormapping_add(void)
{
ColorMapping *colormap = MEM_callocN(sizeof(ColorMapping), "ColorMapping");
BKE_texture_colormapping_default(colormap);
return colormap;
}
void BKE_texture_colormapping_default(ColorMapping *colormap)
{
memset(colormap, 0, sizeof(ColorMapping));
init_colorband(&colormap->coba, true);
colormap->bright = 1.0;
colormap->contrast = 1.0;
colormap->saturation = 1.0;
colormap->blend_color[0] = 0.8f;
colormap->blend_color[1] = 0.8f;
colormap->blend_color[2] = 0.8f;
colormap->blend_type = MA_RAMP_BLEND;
colormap->blend_factor = 0.0f;
}
/* ****************** COLORBAND ******************* */
void init_colorband(ColorBand *coba, bool rangetype)
{
int a;
coba->data[0].pos = 0.0;
coba->data[1].pos = 1.0;
if (rangetype == 0) {
coba->data[0].r = 0.0;
coba->data[0].g = 0.0;
coba->data[0].b = 0.0;
coba->data[0].a = 0.0;
coba->data[1].r = 1.0;
coba->data[1].g = 1.0;
coba->data[1].b = 1.0;
coba->data[1].a = 1.0;
}
else {
coba->data[0].r = 0.0;
coba->data[0].g = 0.0;
coba->data[0].b = 0.0;
coba->data[0].a = 1.0;
coba->data[1].r = 1.0;
coba->data[1].g = 1.0;
coba->data[1].b = 1.0;
coba->data[1].a = 1.0;
}
for (a = 2; a < MAXCOLORBAND; a++) {
coba->data[a].r = 0.5;
coba->data[a].g = 0.5;
coba->data[a].b = 0.5;
coba->data[a].a = 1.0;
coba->data[a].pos = 0.5;
}
coba->tot = 2;
coba->color_mode = COLBAND_BLEND_RGB;
}
ColorBand *add_colorband(bool rangetype)
{
ColorBand *coba;
coba = MEM_callocN(sizeof(ColorBand), "colorband");
init_colorband(coba, rangetype);
return coba;
}
/* ------------------------------------------------------------------------- */
static float colorband_hue_interp(
const int ipotype_hue,
const float mfac, const float fac,
float h1, float h2)
{
float h_interp;
int mode = 0;
#define HUE_INTERP(h_a, h_b) ((mfac * (h_a)) + (fac * (h_b)))
#define HUE_MOD(h) (((h) < 1.0f) ? (h) : (h) - 1.0f)
h1 = HUE_MOD(h1);
h2 = HUE_MOD(h2);
BLI_assert(h1 >= 0.0f && h1 < 1.0f);
BLI_assert(h2 >= 0.0f && h2 < 1.0f);
switch (ipotype_hue) {
case COLBAND_HUE_NEAR:
{
if ((h1 < h2) && (h2 - h1) > +0.5f) mode = 1;
else if ((h1 > h2) && (h2 - h1) < -0.5f) mode = 2;
else mode = 0;
break;
}
case COLBAND_HUE_FAR:
{
if ((h1 < h2) && (h2 - h1) < +0.5f) mode = 1;
else if ((h1 > h2) && (h2 - h1) > -0.5f) mode = 2;
else mode = 0;
break;
}
case COLBAND_HUE_CCW:
{
if (h1 > h2) mode = 2;
else mode = 0;
break;
}
case COLBAND_HUE_CW:
{
if (h1 < h2) mode = 1;
else mode = 0;
break;
}
}
switch (mode) {
case 0:
h_interp = HUE_INTERP(h1, h2);
break;
case 1:
h_interp = HUE_INTERP(h1 + 1.0f, h2);
h_interp = HUE_MOD(h_interp);
break;
case 2:
h_interp = HUE_INTERP(h1, h2 + 1.0f);
h_interp = HUE_MOD(h_interp);
break;
}
BLI_assert(h_interp >= 0.0f && h_interp < 1.0f);
#undef HUE_INTERP
#undef HUE_MOD
return h_interp;
}
bool do_colorband(const ColorBand *coba, float in, float out[4])
{
const CBData *cbd1, *cbd2, *cbd0, *cbd3;
float fac;
int ipotype;
int a;
if (coba == NULL || coba->tot == 0) return false;
cbd1 = coba->data;
ipotype = (coba->color_mode == COLBAND_BLEND_RGB) ? coba->ipotype : COLBAND_INTERP_LINEAR;
if (coba->tot == 1) {
out[0] = cbd1->r;
out[1] = cbd1->g;
out[2] = cbd1->b;
out[3] = cbd1->a;
}
else if ((in <= cbd1->pos) && ELEM(ipotype, COLBAND_INTERP_LINEAR, COLBAND_INTERP_EASE)) {
out[0] = cbd1->r;
out[1] = cbd1->g;
out[2] = cbd1->b;
out[3] = cbd1->a;
}
else {
CBData left, right;
/* we're looking for first pos > in */
for (a = 0; a < coba->tot; a++, cbd1++) {
if (cbd1->pos > in) {
break;
}
}
if (a == coba->tot) {
cbd2 = cbd1 - 1;
right = *cbd2;
right.pos = 1.0f;
cbd1 = &right;
}
else if (a == 0) {
left = *cbd1;
left.pos = 0.0f;
cbd2 = &left;
}
else {
cbd2 = cbd1 - 1;
}
if ((in >= cbd1->pos) && ELEM(ipotype, COLBAND_INTERP_LINEAR, COLBAND_INTERP_EASE)) {
out[0] = cbd1->r;
out[1] = cbd1->g;
out[2] = cbd1->b;
out[3] = cbd1->a;
}
else {
if (cbd2->pos != cbd1->pos) {
fac = (in - cbd1->pos) / (cbd2->pos - cbd1->pos);
}
else {
/* was setting to 0.0 in 2.56 & previous, but this
* is incorrect for the last element, see [#26732] */
fac = (a != coba->tot) ? 0.0f : 1.0f;
}
if (ipotype == COLBAND_INTERP_CONSTANT) {
/* constant */
out[0] = cbd2->r;
out[1] = cbd2->g;
out[2] = cbd2->b;
out[3] = cbd2->a;
}
else if (ipotype >= COLBAND_INTERP_B_SPLINE) {
/* ipo from right to left: 3 2 1 0 */
float t[4];
if (a >= coba->tot - 1) cbd0 = cbd1;
else cbd0 = cbd1 + 1;
if (a < 2) cbd3 = cbd2;
else cbd3 = cbd2 - 1;
CLAMP(fac, 0.0f, 1.0f);
if (ipotype == COLBAND_INTERP_CARDINAL) {
key_curve_position_weights(fac, t, KEY_CARDINAL);
}
else {
key_curve_position_weights(fac, t, KEY_BSPLINE);
}
out[0] = t[3] * cbd3->r + t[2] * cbd2->r + t[1] * cbd1->r + t[0] * cbd0->r;
out[1] = t[3] * cbd3->g + t[2] * cbd2->g + t[1] * cbd1->g + t[0] * cbd0->g;
out[2] = t[3] * cbd3->b + t[2] * cbd2->b + t[1] * cbd1->b + t[0] * cbd0->b;
out[3] = t[3] * cbd3->a + t[2] * cbd2->a + t[1] * cbd1->a + t[0] * cbd0->a;
CLAMP(out[0], 0.0f, 1.0f);
CLAMP(out[1], 0.0f, 1.0f);
CLAMP(out[2], 0.0f, 1.0f);
CLAMP(out[3], 0.0f, 1.0f);
}
else {
float mfac;
if (ipotype == COLBAND_INTERP_EASE) {
mfac = fac * fac;
fac = 3.0f * mfac - 2.0f * mfac * fac;
}
mfac = 1.0f - fac;
if (UNLIKELY(coba->color_mode == COLBAND_BLEND_HSV)) {
float col1[3], col2[3];
rgb_to_hsv_v(&cbd1->r, col1);
rgb_to_hsv_v(&cbd2->r, col2);
out[0] = colorband_hue_interp(coba->ipotype_hue, mfac, fac, col1[0], col2[0]);
out[1] = mfac * col1[1] + fac * col2[1];
out[2] = mfac * col1[2] + fac * col2[2];
out[3] = mfac * cbd1->a + fac * cbd2->a;
hsv_to_rgb_v(out, out);
}
else if (UNLIKELY(coba->color_mode == COLBAND_BLEND_HSL)) {
float col1[3], col2[3];
rgb_to_hsl_v(&cbd1->r, col1);
rgb_to_hsl_v(&cbd2->r, col2);
out[0] = colorband_hue_interp(coba->ipotype_hue, mfac, fac, col1[0], col2[0]);
out[1] = mfac * col1[1] + fac * col2[1];
out[2] = mfac * col1[2] + fac * col2[2];
out[3] = mfac * cbd1->a + fac * cbd2->a;
hsl_to_rgb_v(out, out);
}
else {
/* COLBAND_BLEND_RGB */
out[0] = mfac * cbd1->r + fac * cbd2->r;
out[1] = mfac * cbd1->g + fac * cbd2->g;
out[2] = mfac * cbd1->b + fac * cbd2->b;
out[3] = mfac * cbd1->a + fac * cbd2->a;
}
}
}
}
return true; /* OK */
}
void colorband_table_RGBA(ColorBand *coba, float **array, int *size)
{
int a;
*size = CM_TABLE + 1;
*array = MEM_callocN(sizeof(float) * (*size) * 4, "ColorBand");
for (a = 0; a < *size; a++)
do_colorband(coba, (float)a / (float)CM_TABLE, &(*array)[a * 4]);
}
static int vergcband(const void *a1, const void *a2)
{
const CBData *x1 = a1, *x2 = a2;
if (x1->pos > x2->pos) return 1;
else if (x1->pos < x2->pos) return -1;
return 0;
}
void colorband_update_sort(ColorBand *coba)
{
int a;
if (coba->tot < 2)
return;
for (a = 0; a < coba->tot; a++)
coba->data[a].cur = a;
qsort(coba->data, coba->tot, sizeof(CBData), vergcband);
for (a = 0; a < coba->tot; a++) {
if (coba->data[a].cur == coba->cur) {
coba->cur = a;
break;
}
}
}
CBData *colorband_element_add(struct ColorBand *coba, float position)
{
if (coba->tot == MAXCOLORBAND) {
return NULL;
}
else {
CBData *xnew;
xnew = &coba->data[coba->tot];
xnew->pos = position;
if (coba->tot != 0) {
do_colorband(coba, position, &xnew->r);
}
else {
zero_v4(&xnew->r);
}
}
coba->tot++;
coba->cur = coba->tot - 1;
colorband_update_sort(coba);
return coba->data + coba->cur;
}
int colorband_element_remove(struct ColorBand *coba, int index)
{
int a;
if (coba->tot < 2)
return 0;
if (index < 0 || index >= coba->tot)
return 0;
for (a = index; a < coba->tot; a++) {
coba->data[a] = coba->data[a + 1];
}
if (coba->cur) coba->cur--;
coba->tot--;
return 1;
}
/* ******************* TEX ************************ */
/** Free (or release) any data used by this texture (does not free the texure itself). */
void BKE_texture_free(Tex *tex)
{
BKE_animdata_free((ID *)tex, false);
/* is no lib link block, but texture extension */
if (tex->nodetree) {
ntreeFreeTree(tex->nodetree);
MEM_freeN(tex->nodetree);
tex->nodetree = NULL;
}
MEM_SAFE_FREE(tex->coba);
if (tex->env) {
BKE_texture_envmap_free(tex->env);
tex->env = NULL;
}
if (tex->pd) {
BKE_texture_pointdensity_free(tex->pd);
tex->pd = NULL;
}
if (tex->vd) {
BKE_texture_voxeldata_free(tex->vd);
tex->vd = NULL;
}
if (tex->ot) {
BKE_texture_ocean_free(tex->ot);
tex->ot = NULL;
}
BKE_icon_id_delete((ID *)tex);
BKE_previewimg_free(&tex->preview);
}
/* ------------------------------------------------------------------------- */
void BKE_texture_default(Tex *tex)
{
/* BLI_assert(MEMCMP_STRUCT_OFS_IS_ZERO(tex, id)); */ /* Not here, can be called with some pointers set. :/ */
tex->type = TEX_IMAGE;
tex->ima = NULL;
tex->stype = 0;
tex->flag = TEX_CHECKER_ODD;
tex->imaflag = TEX_INTERPOL | TEX_MIPMAP | TEX_USEALPHA;
tex->extend = TEX_REPEAT;
tex->cropxmin = tex->cropymin = 0.0;
tex->cropxmax = tex->cropymax = 1.0;
tex->texfilter = TXF_EWA;
tex->afmax = 8;
tex->xrepeat = tex->yrepeat = 1;
tex->fie_ima = 2;
tex->sfra = 1;
tex->frames = 0;
tex->offset = 0;
tex->noisesize = 0.25;
tex->noisedepth = 2;
tex->turbul = 5.0;
tex->nabla = 0.025; // also in do_versions
tex->bright = 1.0;
tex->contrast = 1.0;
tex->saturation = 1.0;
tex->filtersize = 1.0;
tex->rfac = 1.0;
tex->gfac = 1.0;
tex->bfac = 1.0;
/* newnoise: init. */
tex->noisebasis = 0;
tex->noisebasis2 = 0;
/* musgrave */
tex->mg_H = 1.0;
tex->mg_lacunarity = 2.0;
tex->mg_octaves = 2.0;
tex->mg_offset = 1.0;
tex->mg_gain = 1.0;
tex->ns_outscale = 1.0;
/* distnoise */
tex->dist_amount = 1.0;
/* voronoi */
tex->vn_w1 = 1.0;
tex->vn_w2 = tex->vn_w3 = tex->vn_w4 = 0.0;
tex->vn_mexp = 2.5;
tex->vn_distm = 0;
tex->vn_coltype = 0;
if (tex->env) {
tex->env->stype = ENV_ANIM;
tex->env->clipsta = 0.1;
tex->env->clipend = 100;
tex->env->cuberes = 512;
tex->env->depth = 0;
}
if (tex->pd) {
tex->pd->radius = 0.3f;
tex->pd->falloff_type = TEX_PD_FALLOFF_STD;
}
if (tex->vd) {
tex->vd->resol[0] = tex->vd->resol[1] = tex->vd->resol[2] = 0;
tex->vd->interp_type = TEX_VD_LINEAR;
tex->vd->file_format = TEX_VD_SMOKE;
}
if (tex->ot) {
tex->ot->output = TEX_OCN_DISPLACEMENT;
tex->ot->object = NULL;
}
tex->iuser.fie_ima = 2;
tex->iuser.ok = 1;
tex->iuser.frames = 100;
tex->iuser.sfra = 1;
tex->preview = NULL;
}
void BKE_texture_type_set(Tex *tex, int type)
{
switch (type) {
case TEX_VOXELDATA:
if (tex->vd == NULL)
tex->vd = BKE_texture_voxeldata_add();
break;
case TEX_POINTDENSITY:
if (tex->pd == NULL)
tex->pd = BKE_texture_pointdensity_add();
break;
case TEX_ENVMAP:
if (tex->env == NULL)
tex->env = BKE_texture_envmap_add();
break;
case TEX_OCEAN:
if (tex->ot == NULL)
tex->ot = BKE_texture_ocean_add();
break;
}
tex->type = type;
}
/* ------------------------------------------------------------------------- */
Tex *BKE_texture_add(Main *bmain, const char *name)
{
Tex *tex;
tex = BKE_libblock_alloc(bmain, ID_TE, name);
BKE_texture_default(tex);
return tex;
}
/* ------------------------------------------------------------------------- */
void BKE_texture_mtex_default(MTex *mtex)
{
mtex->texco = TEXCO_UV;
mtex->mapto = MAP_COL;
mtex->object = NULL;
mtex->projx = PROJ_X;
mtex->projy = PROJ_Y;
mtex->projz = PROJ_Z;
mtex->mapping = MTEX_FLAT;
mtex->ofs[0] = 0.0;
mtex->ofs[1] = 0.0;
mtex->ofs[2] = 0.0;
mtex->size[0] = 1.0;
mtex->size[1] = 1.0;
mtex->size[2] = 1.0;
mtex->tex = NULL;
mtex->texflag = MTEX_3TAP_BUMP | MTEX_BUMP_OBJECTSPACE | MTEX_MAPTO_BOUNDS;
mtex->colormodel = 0;
mtex->r = 1.0;
mtex->g = 0.0;
mtex->b = 1.0;
mtex->k = 1.0;
mtex->def_var = 1.0;
mtex->blendtype = MTEX_BLEND;
mtex->colfac = 1.0;
mtex->norfac = 1.0;
mtex->varfac = 1.0;
mtex->dispfac = 0.2;
mtex->colspecfac = 1.0f;
mtex->mirrfac = 1.0f;
mtex->alphafac = 1.0f;
mtex->difffac = 1.0f;
mtex->specfac = 1.0f;
mtex->emitfac = 1.0f;
mtex->hardfac = 1.0f;
mtex->raymirrfac = 1.0f;
mtex->translfac = 1.0f;
mtex->ambfac = 1.0f;
mtex->colemitfac = 1.0f;
mtex->colreflfac = 1.0f;
mtex->coltransfac = 1.0f;
mtex->densfac = 1.0f;
mtex->scatterfac = 1.0f;
mtex->reflfac = 1.0f;
mtex->shadowfac = 1.0f;
mtex->zenupfac = 1.0f;
mtex->zendownfac = 1.0f;
mtex->blendfac = 1.0f;
mtex->timefac = 1.0f;
mtex->lengthfac = 1.0f;
mtex->clumpfac = 1.0f;
mtex->kinkfac = 1.0f;
mtex->kinkampfac = 1.0f;
mtex->roughfac = 1.0f;
mtex->padensfac = 1.0f;
mtex->lifefac = 1.0f;
mtex->sizefac = 1.0f;
mtex->ivelfac = 1.0f;
mtex->dampfac = 1.0f;
mtex->gravityfac = 1.0f;
mtex->fieldfac = 1.0f;
mtex->normapspace = MTEX_NSPACE_TANGENT;
mtex->brush_map_mode = MTEX_MAP_MODE_TILED;
mtex->random_angle = 2.0f * (float)M_PI;
mtex->brush_angle_mode = 0;
}
/* ------------------------------------------------------------------------- */
MTex *BKE_texture_mtex_add(void)
{
MTex *mtex;
mtex = MEM_callocN(sizeof(MTex), "BKE_texture_mtex_add");
BKE_texture_mtex_default(mtex);
return mtex;
}
/* slot -1 for first free ID */
MTex *BKE_texture_mtex_add_id(ID *id, int slot)
{
MTex **mtex_ar;
short act;
give_active_mtex(id, &mtex_ar, &act);
if (mtex_ar == NULL) {
return NULL;
}
if (slot == -1) {
/* find first free */
int i;
for (i = 0; i < MAX_MTEX; i++) {
if (!mtex_ar[i]) {
slot = i;
break;
}
}
if (slot == -1) {
return NULL;
}
}
else {
/* make sure slot is valid */
if (slot < 0 || slot >= MAX_MTEX) {
return NULL;
}
}
if (mtex_ar[slot]) {
id_us_min((ID *)mtex_ar[slot]->tex);
MEM_freeN(mtex_ar[slot]);
mtex_ar[slot] = NULL;
}
else if (GS(id->name) == ID_MA) {
/* Reset this slot's ON/OFF toggle, for materials, when slot was empty. */
((Material *)id)->septex &= ~(1 << slot);
}
mtex_ar[slot] = BKE_texture_mtex_add();
return mtex_ar[slot];
}
/* ------------------------------------------------------------------------- */
Tex *BKE_texture_copy(Main *bmain, Tex *tex)
{
Tex *texn;
texn = BKE_libblock_copy(bmain, &tex->id);
if (BKE_texture_is_image_user(tex)) {
id_us_plus((ID *)texn->ima);
}
else {
texn->ima = NULL;
}
if (texn->coba) texn->coba = MEM_dupallocN(texn->coba);
if (texn->env) texn->env = BKE_texture_envmap_copy(texn->env);
if (texn->pd) texn->pd = BKE_texture_pointdensity_copy(texn->pd);
if (texn->vd) texn->vd = MEM_dupallocN(texn->vd);
if (texn->ot) texn->ot = BKE_texture_ocean_copy(texn->ot);
if (tex->nodetree) {
if (tex->nodetree->execdata) {
ntreeTexEndExecTree(tex->nodetree->execdata);
}
texn->nodetree = ntreeCopyTree(bmain, tex->nodetree);
}
BKE_previewimg_id_copy(&texn->id, &tex->id);
BKE_id_copy_ensure_local(bmain, &tex->id, &texn->id);
return texn;
}
/* texture copy without adding to main dbase */
Tex *BKE_texture_localize(Tex *tex)
{
Tex *texn;
texn = BKE_libblock_copy_nolib(&tex->id, false);
/* image texture: BKE_texture_free also doesn't decrease */
if (texn->coba) texn->coba = MEM_dupallocN(texn->coba);
if (texn->env) {
texn->env = BKE_texture_envmap_copy(texn->env);
id_us_min(&texn->env->ima->id);
}
if (texn->pd) texn->pd = BKE_texture_pointdensity_copy(texn->pd);
if (texn->vd) {
texn->vd = MEM_dupallocN(texn->vd);
if (texn->vd->dataset)
texn->vd->dataset = MEM_dupallocN(texn->vd->dataset);
}
if (texn->ot) {
texn->ot = BKE_texture_ocean_copy(tex->ot);
}
texn->preview = NULL;
if (tex->nodetree) {
texn->nodetree = ntreeLocalize(tex->nodetree);
}
return texn;
}
/* ------------------------------------------------------------------------- */
void BKE_texture_make_local(Main *bmain, Tex *tex, const bool lib_local)
{
BKE_id_make_local_generic(bmain, &tex->id, true, lib_local);
}
Tex *give_current_object_texture(Object *ob)
{
Material *ma, *node_ma;
Tex *tex = NULL;
if (ob == NULL) return NULL;
if (ob->totcol == 0 && !(ob->type == OB_LAMP)) return NULL;
if (ob->type == OB_LAMP) {
tex = give_current_lamp_texture(ob->data);
}
else {
ma = give_current_material(ob, ob->actcol);
if ((node_ma = give_node_material(ma)))
ma = node_ma;
tex = give_current_material_texture(ma);
}
return tex;
}
Tex *give_current_lamp_texture(Lamp *la)
{
MTex *mtex = NULL;
Tex *tex = NULL;
if (la) {
mtex = la->mtex[(int)(la->texact)];
if (mtex) tex = mtex->tex;
}
return tex;
}
void set_current_lamp_texture(Lamp *la, Tex *newtex)
{
int act = la->texact;
if (la->mtex[act] && la->mtex[act]->tex)
id_us_min(&la->mtex[act]->tex->id);
if (newtex) {
if (!la->mtex[act]) {
la->mtex[act] = BKE_texture_mtex_add();
la->mtex[act]->texco = TEXCO_GLOB;
}
la->mtex[act]->tex = newtex;
id_us_plus(&newtex->id);
}
else if (la->mtex[act]) {
MEM_freeN(la->mtex[act]);
la->mtex[act] = NULL;
}
}
Tex *give_current_linestyle_texture(FreestyleLineStyle *linestyle)
{
MTex *mtex = NULL;
Tex *tex = NULL;
if (linestyle) {
mtex = linestyle->mtex[(int)(linestyle->texact)];
if (mtex) tex = mtex->tex;
}
return tex;
}
void set_current_linestyle_texture(FreestyleLineStyle *linestyle, Tex *newtex)
{
int act = linestyle->texact;
if (linestyle->mtex[act] && linestyle->mtex[act]->tex)
id_us_min(&linestyle->mtex[act]->tex->id);
if (newtex) {
if (!linestyle->mtex[act]) {
linestyle->mtex[act] = BKE_texture_mtex_add();
linestyle->mtex[act]->texco = TEXCO_STROKE;
}
linestyle->mtex[act]->tex = newtex;
id_us_plus(&newtex->id);
}
else if (linestyle->mtex[act]) {
MEM_freeN(linestyle->mtex[act]);
linestyle->mtex[act] = NULL;
}
}
bNode *give_current_material_texture_node(Material *ma)
{
if (ma && ma->use_nodes && ma->nodetree)
return nodeGetActiveID(ma->nodetree, ID_TE);
return NULL;
}
Tex *give_current_material_texture(Material *ma)
{
MTex *mtex = NULL;
Tex *tex = NULL;
bNode *node;
if (ma && ma->use_nodes && ma->nodetree) {
/* first check texture, then material, this works together
* with a hack that clears the active ID flag for textures on
* making a material node active */
node = nodeGetActiveID(ma->nodetree, ID_TE);
if (node) {
tex = (Tex *)node->id;
ma = NULL;
}
}
if (ma) {
mtex = ma->mtex[(int)(ma->texact)];
if (mtex) tex = mtex->tex;
}
return tex;
}
bool give_active_mtex(ID *id, MTex ***mtex_ar, short *act)
{
switch (GS(id->name)) {
case ID_MA:
*mtex_ar = ((Material *)id)->mtex;
if (act) *act = (((Material *)id)->texact);
break;
case ID_WO:
*mtex_ar = ((World *)id)->mtex;
if (act) *act = (((World *)id)->texact);
break;
case ID_LA:
*mtex_ar = ((Lamp *)id)->mtex;
if (act) *act = (((Lamp *)id)->texact);
break;
case ID_LS:
*mtex_ar = ((FreestyleLineStyle *)id)->mtex;
if (act) *act = (((FreestyleLineStyle *)id)->texact);
break;
case ID_PA:
*mtex_ar = ((ParticleSettings *)id)->mtex;
if (act) *act = (((ParticleSettings *)id)->texact);
break;
default:
*mtex_ar = NULL;
if (act) *act = 0;
return false;
}
return true;
}
void set_active_mtex(ID *id, short act)
{
if (act < 0) act = 0;
else if (act >= MAX_MTEX) act = MAX_MTEX - 1;
switch (GS(id->name)) {
case ID_MA:
((Material *)id)->texact = act;
break;
case ID_WO:
((World *)id)->texact = act;
break;
case ID_LA:
((Lamp *)id)->texact = act;
break;
case ID_LS:
((FreestyleLineStyle *)id)->texact = act;
break;
case ID_PA:
((ParticleSettings *)id)->texact = act;
break;
}
}
void set_current_material_texture(Material *ma, Tex *newtex)
{
Tex *tex = NULL;
bNode *node;
if ((ma->use_nodes && ma->nodetree) &&
(node = nodeGetActiveID(ma->nodetree, ID_TE)))
{
tex = (Tex *)node->id;
id_us_min(&tex->id);
if (newtex) {
node->id = &newtex->id;
id_us_plus(&newtex->id);
}
else {
node->id = NULL;
}
}
else {
int act = (int)ma->texact;
tex = (ma->mtex[act]) ? ma->mtex[act]->tex : NULL;
id_us_min(&tex->id);
if (newtex) {
if (!ma->mtex[act]) {
ma->mtex[act] = BKE_texture_mtex_add();
/* Reset this slot's ON/OFF toggle, for materials, when slot was empty. */
ma->septex &= ~(1 << act);
}
ma->mtex[act]->tex = newtex;
id_us_plus(&newtex->id);
}
else if (ma->mtex[act]) {
MEM_freeN(ma->mtex[act]);
ma->mtex[act] = NULL;
}
}
}
bool has_current_material_texture(Material *ma)
{
bNode *node;
if (ma && ma->use_nodes && ma->nodetree) {
node = nodeGetActiveID(ma->nodetree, ID_TE);
if (node)
return true;
}
return (ma != NULL);
}
Tex *give_current_world_texture(World *world)
{
MTex *mtex = NULL;
Tex *tex = NULL;
if (!world) return NULL;
mtex = world->mtex[(int)(world->texact)];
if (mtex) tex = mtex->tex;
return tex;
}
void set_current_world_texture(World *wo, Tex *newtex)
{
int act = wo->texact;
if (wo->mtex[act] && wo->mtex[act]->tex)
id_us_min(&wo->mtex[act]->tex->id);
if (newtex) {
if (!wo->mtex[act]) {
wo->mtex[act] = BKE_texture_mtex_add();
wo->mtex[act]->texco = TEXCO_VIEW;
}
wo->mtex[act]->tex = newtex;
id_us_plus(&newtex->id);
}
else if (wo->mtex[act]) {
MEM_freeN(wo->mtex[act]);
wo->mtex[act] = NULL;
}
}
Tex *give_current_brush_texture(Brush *br)
{
return br->mtex.tex;
}
void set_current_brush_texture(Brush *br, Tex *newtex)
{
if (br->mtex.tex)
id_us_min(&br->mtex.tex->id);
if (newtex) {
br->mtex.tex = newtex;
id_us_plus(&newtex->id);
}
}
Tex *give_current_particle_texture(ParticleSettings *part)
{
MTex *mtex = NULL;
Tex *tex = NULL;
if (!part) return NULL;
mtex = part->mtex[(int)(part->texact)];
if (mtex) tex = mtex->tex;
return tex;
}
void set_current_particle_texture(ParticleSettings *part, Tex *newtex)
{
int act = part->texact;
if (part->mtex[act] && part->mtex[act]->tex)
id_us_min(&part->mtex[act]->tex->id);
if (newtex) {
if (!part->mtex[act]) {
part->mtex[act] = BKE_texture_mtex_add();
part->mtex[act]->texco = TEXCO_ORCO;
part->mtex[act]->blendtype = MTEX_MUL;
}
part->mtex[act]->tex = newtex;
id_us_plus(&newtex->id);
}
else if (part->mtex[act]) {
MEM_freeN(part->mtex[act]);
part->mtex[act] = NULL;
}
}
/* ------------------------------------------------------------------------- */
EnvMap *BKE_texture_envmap_add(void)
{
EnvMap *env;
env = MEM_callocN(sizeof(EnvMap), "envmap");
env->type = ENV_CUBE;
env->stype = ENV_ANIM;
env->clipsta = 0.1;
env->clipend = 100.0;
env->cuberes = 512;
env->viewscale = 0.5;
return env;
}
/* ------------------------------------------------------------------------- */
EnvMap *BKE_texture_envmap_copy(EnvMap *env)
{
EnvMap *envn;
int a;
envn = MEM_dupallocN(env);
envn->ok = 0;
for (a = 0; a < 6; a++) envn->cube[a] = NULL;
if (envn->ima) id_us_plus((ID *)envn->ima);
return envn;
}
/* ------------------------------------------------------------------------- */
void BKE_texture_envmap_free_data(EnvMap *env)
{
unsigned int part;
for (part = 0; part < 6; part++) {
if (env->cube[part])
IMB_freeImBuf(env->cube[part]);
env->cube[part] = NULL;
}
env->ok = 0;
}
/* ------------------------------------------------------------------------- */
void BKE_texture_envmap_free(EnvMap *env)
{
BKE_texture_envmap_free_data(env);
MEM_freeN(env);
}
/* ------------------------------------------------------------------------- */
void BKE_texture_pointdensity_init_data(PointDensity *pd)
{
pd->flag = 0;
pd->radius = 0.3f;
pd->falloff_type = TEX_PD_FALLOFF_STD;
pd->falloff_softness = 2.0;
pd->source = TEX_PD_PSYS;
pd->point_tree = NULL;
pd->point_data = NULL;
pd->noise_size = 0.5f;
pd->noise_depth = 1;
pd->noise_fac = 1.0f;
pd->noise_influence = TEX_PD_NOISE_STATIC;
pd->coba = add_colorband(true);
pd->speed_scale = 1.0f;
pd->totpoints = 0;
pd->object = NULL;
pd->psys = 0;
pd->psys_cache_space = TEX_PD_WORLDSPACE;
pd->falloff_curve = curvemapping_add(1, 0, 0, 1, 1);
pd->falloff_curve->preset = CURVE_PRESET_LINE;
pd->falloff_curve->cm->flag &= ~CUMA_EXTEND_EXTRAPOLATE;
curvemap_reset(pd->falloff_curve->cm, &pd->falloff_curve->clipr, pd->falloff_curve->preset, CURVEMAP_SLOPE_POSITIVE);
curvemapping_changed(pd->falloff_curve, false);
}
PointDensity *BKE_texture_pointdensity_add(void)
{
PointDensity *pd = MEM_callocN(sizeof(PointDensity), "pointdensity");
BKE_texture_pointdensity_init_data(pd);
return pd;
}
PointDensity *BKE_texture_pointdensity_copy(PointDensity *pd)
{
PointDensity *pdn;
pdn = MEM_dupallocN(pd);
pdn->point_tree = NULL;
pdn->point_data = NULL;
if (pdn->coba) pdn->coba = MEM_dupallocN(pdn->coba);
pdn->falloff_curve = curvemapping_copy(pdn->falloff_curve); /* can be NULL */
return pdn;
}
void BKE_texture_pointdensity_free_data(PointDensity *pd)
{
if (pd->point_tree) {
BLI_bvhtree_free(pd->point_tree);
pd->point_tree = NULL;
}
if (pd->point_data) {
MEM_freeN(pd->point_data);
pd->point_data = NULL;
}
if (pd->coba) {
MEM_freeN(pd->coba);
pd->coba = NULL;
}
curvemapping_free(pd->falloff_curve); /* can be NULL */
}
void BKE_texture_pointdensity_free(PointDensity *pd)
{
BKE_texture_pointdensity_free_data(pd);
MEM_freeN(pd);
}
/* ------------------------------------------------------------------------- */
void BKE_texture_voxeldata_free_data(VoxelData *vd)
{
if (vd->dataset) {
MEM_freeN(vd->dataset);
vd->dataset = NULL;
}
}
void BKE_texture_voxeldata_free(VoxelData *vd)
{
BKE_texture_voxeldata_free_data(vd);
MEM_freeN(vd);
}
VoxelData *BKE_texture_voxeldata_add(void)
{
VoxelData *vd;
vd = MEM_callocN(sizeof(VoxelData), "voxeldata");
vd->dataset = NULL;
vd->resol[0] = vd->resol[1] = vd->resol[2] = 1;
vd->interp_type = TEX_VD_LINEAR;
vd->file_format = TEX_VD_SMOKE;
vd->int_multiplier = 1.0;
vd->extend = TEX_CLIP;
vd->object = NULL;
vd->cachedframe = -1;
vd->ok = 0;
return vd;
}
VoxelData *BKE_texture_voxeldata_copy(VoxelData *vd)
{
VoxelData *vdn;
vdn = MEM_dupallocN(vd);
vdn->dataset = NULL;
return vdn;
}
/* ------------------------------------------------------------------------- */
OceanTex *BKE_texture_ocean_add(void)
{
OceanTex *ot;
ot = MEM_callocN(sizeof(struct OceanTex), "ocean texture");
ot->output = TEX_OCN_DISPLACEMENT;
ot->object = NULL;
return ot;
}
OceanTex *BKE_texture_ocean_copy(struct OceanTex *ot)
{
OceanTex *otn = MEM_dupallocN(ot);
return otn;
}
void BKE_texture_ocean_free(struct OceanTex *ot)
{
MEM_freeN(ot);
}
/**
* \returns true if this texture can use its #Texture.ima (even if its NULL)
*/
bool BKE_texture_is_image_user(const struct Tex *tex)
{
switch (tex->type) {
case TEX_IMAGE:
{
return true;
}
case TEX_ENVMAP:
{
if (tex->env) {
if (tex->env->stype == ENV_LOAD) {
return true;
}
}
break;
}
}
return false;
}
/* ------------------------------------------------------------------------- */
bool BKE_texture_dependsOnTime(const struct Tex *texture)
{
if (texture->ima && BKE_image_is_animated(texture->ima)) {
return true;
}
else if (texture->adt) {
/* assume anything in adt means the texture is animated */
return true;
}
else if (texture->type == TEX_NOISE) {
/* noise always varies with time */
return true;
}
return false;
}
/* ------------------------------------------------------------------------- */
void BKE_texture_get_value(
const Scene *scene, Tex *texture,
float *tex_co, TexResult *texres, bool use_color_management)
{
int result_type;
bool do_color_manage = false;
if (scene && use_color_management) {
do_color_manage = BKE_scene_check_color_management_enabled(scene);
}
/* no node textures for now */
result_type = multitex_ext_safe(texture, tex_co, texres, NULL, do_color_manage, false);
/* if the texture gave an RGB value, we assume it didn't give a valid
* intensity, since this is in the context of modifiers don't use perceptual color conversion.
* if the texture didn't give an RGB value, copy the intensity across
*/
if (result_type & TEX_RGB) {
texres->tin = (1.0f / 3.0f) * (texres->tr + texres->tg + texres->tb);
}
else {
copy_v3_fl(&texres->tr, texres->tin);
}
}
View Git Blame Copy Permalink