/* previewrender.c GRAPHICS * * maart 95 * * $Id$ * * ***** 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 ***** */ /* global includes */ #include #include #ifdef HAVE_CONFIG_H #include #endif #ifndef WIN32 #include #else #include #endif #include "MEM_guardedalloc.h" #include "BLI_arithb.h" #include "BKE_utildefines.h" #include "MTC_matrixops.h" #include "render.h" #include "mydevice.h" #include "DNA_texture_types.h" #include "DNA_world_types.h" #include "DNA_camera_types.h" #include "DNA_image_types.h" #include "DNA_object_types.h" #include "DNA_lamp_types.h" #include "DNA_space_types.h" #include "DNA_scene_types.h" #include "DNA_screen_types.h" #include "BKE_global.h" #include "BKE_image.h" #include "BKE_texture.h" #include "BKE_material.h" #include "BKE_world.h" #include "BKE_texture.h" #include "BSE_headerbuttons.h" #include "BIF_gl.h" #include "BIF_screen.h" #include "BIF_space.h" /* allqueue */ #include "BIF_butspace.h" #include "BIF_drawimage.h" /* rectwrite_part */ #include "BIF_mywindow.h" #include "BIF_interface.h" #include "PIL_time.h" #include "RE_renderconverter.h" #define PR_RECTX 141 #define PR_RECTY 141 #define PR_XMIN 10 #define PR_YMIN 5 #define PR_XMAX 200 #define PR_YMAX 195 #define PR_FACY (PR_YMAX-PR_YMIN-4)/(PR_RECTY) static rcti prerect; static int pr_sizex, pr_sizey; static float pr_facx, pr_facy; /* implementation */ static short snijpunt(float *v1, float *v2, float *v3, float *rtlabda, float *ray1, float *ray2) { float x0,x1,x2,t00,t01,t02,t10,t11,t12,t20,t21,t22; float m0,m1,m2,deeldet,det1,det2,det3; float rtu, rtv; t00= v3[0]-v1[0]; t01= v3[1]-v1[1]; t02= v3[2]-v1[2]; t10= v3[0]-v2[0]; t11= v3[1]-v2[1]; t12= v3[2]-v2[2]; t20= ray1[0]-ray2[0]; t21= ray1[1]-ray2[1]; t22= ray1[2]-ray2[2]; x0= t11*t22-t12*t21; x1= t12*t20-t10*t22; x2= t10*t21-t11*t20; deeldet= t00*x0+t01*x1+t02*x2; if(deeldet!=0.0) { m0= ray1[0]-v3[0]; m1= ray1[1]-v3[1]; m2= ray1[2]-v3[2]; det1= m0*x0+m1*x1+m2*x2; rtu= det1/deeldet; if(rtu<=0.0) { det2= t00*(m1*t22-m2*t21); det2+= t01*(m2*t20-m0*t22); det2+= t02*(m0*t21-m1*t20); rtv= det2/deeldet; if(rtv<=0.0) { if(rtu+rtv>= -1.0) { det3= m0*(t12*t01-t11*t02); det3+= m1*(t10*t02-t12*t00); det3+= m2*(t11*t00-t10*t01); *rtlabda= det3/deeldet; if(*rtlabda>=0.0 && *rtlabda<=1.0) { return 1; } } } } } return 0; } static float rcubev[7][3]= { {-0.002055, 6.627364, -3.369742}, {-6.031684, -3.750204, -1.992980}, {-6.049086, 3.817431, 1.969788}, { 6.031685, 3.833064, 1.992979}, { 6.049086, -3.734571, -1.969787}, { 0.002054, -6.544502, 3.369744}, {-0.015348, 1.023131, 7.332510} }; static int rcubi[3][4]= { {3, 6, 5, 4}, {1, 5, 6, 2}, {3, 0, 2, 6} }; static int ray_previewrender(int x, int y, float *vec, float *vn) { float scalef= 12.8/100.0; float ray1[3], ray2[3]; float minlabda, labda; int totface= 3, hitface= -1; int a; ray1[0]= ray2[0]= x*scalef; ray1[1]= ray2[1]= y*scalef; ray1[2]= -10.0; ray2[2]= 10.0; minlabda= 1.0; for(a=0; a -1) { CalcNormFloat(rcubev[rcubi[hitface][0]], rcubev[rcubi[hitface][1]], rcubev[rcubi[hitface][2]], vn); vec[0]= (minlabda*(ray1[0]-ray2[0])+ray2[0])/3.7; vec[1]= (minlabda*(ray1[1]-ray2[1])+ray2[1])/3.7; vec[2]= (minlabda*(ray1[2]-ray2[2])+ray2[2])/3.7; return 1; } return 0; } static unsigned int previewback(int type, int x, int y) { /* checkerboard, for later x+= PR_RECTX/2; y+= PR_RECTX/2; if( ((x/24) + (y/24)) & 1) return 0x40404040; else return 0xa0a0a0a0; */ if(type & MA_DARK) { if(abs(x)>abs(y)) return 0; else return 0x40404040; } else { if(abs(x)>abs(y)) return 0x40404040; else return 0xa0a0a0a0; } } static void view2d_to_window(int win, int *x_r, int *y_r) { int x= *x_r, y= *y_r; int size[2], origin[2]; float winmat[4][4]; bwin_getsinglematrix(win, winmat); bwin_getsize(win, &size[0], &size[1]); bwin_getsuborigin(win, &origin[0], &origin[1]); *x_r= origin[0] + (size[0]*(0.5 + 0.5*(x*winmat[0][0] + y*winmat[1][0] + winmat[3][0]))); *y_r= origin[1] + (size[1]*(0.5 + 0.5*(x*winmat[0][1] + y*winmat[1][1] + winmat[3][1]))); } static void set_previewrect(int win, int xmin, int ymin, int xmax, int ymax) { prerect.xmin= xmin; prerect.ymin= ymin; prerect.xmax= xmax; prerect.ymax= ymax; view2d_to_window(win, &prerect.xmin, &prerect.ymin); view2d_to_window(win, &prerect.xmax, &prerect.ymax); pr_sizex= (prerect.xmax-prerect.xmin); pr_sizey= (prerect.ymax-prerect.ymin); pr_facx= ( (float)pr_sizex-1)/PR_RECTX; pr_facy= ( (float)pr_sizey-1)/PR_RECTY; } static void display_pr_scanline(unsigned int *rect, int recty) { static double lasttime= 0; /* we display 3 new scanlines, one old, the overlap is for wacky 3d cards that cant handle zoom proper */ if(recty % 2) return; if(recty<2) return; rect+= (recty-2)*PR_RECTX; /* enlarge a bit in the y direction, to avoid GL/mesa bug */ glPixelZoom(pr_facx, pr_facy); glRasterPos2f( (float)PR_XMIN+0.5, 1.0+(float)PR_YMIN + (recty*PR_FACY) ); glDrawPixels(PR_RECTX, 3, GL_RGBA, GL_UNSIGNED_BYTE, rect); glPixelZoom(1.0, 1.0); /* flush opengl for cards with frontbuffer slowness */ if(recty==PR_RECTY-1 || (PIL_check_seconds_timer() - lasttime > 0.05)) { lasttime= PIL_check_seconds_timer(); glFinish(); } } static void draw_tex_crop(Tex *tex) { rcti rct; int ret= 0; if(tex==0) return; if(tex->type==TEX_IMAGE) { if(tex->cropxmin==0.0) ret++; if(tex->cropymin==0.0) ret++; if(tex->cropxmax==1.0) ret++; if(tex->cropymax==1.0) ret++; if(ret==4) return; rct.xmin= PR_XMIN+2+tex->cropxmin*(PR_XMAX-PR_XMIN-4); rct.xmax= PR_XMIN+2+tex->cropxmax*(PR_XMAX-PR_XMIN-4); rct.ymin= PR_YMIN+2+tex->cropymin*(PR_YMAX-PR_YMIN-4); rct.ymax= PR_YMIN+2+tex->cropymax*(PR_YMAX-PR_YMIN-4); glPolygonMode(GL_FRONT_AND_BACK, GL_LINE); glColor3ub(0, 0, 0); glRecti(rct.xmin+1, rct.ymin-1, rct.xmax+1, rct.ymax-1); glColor3ub(255, 255, 255); glRecti(rct.xmin, rct.ymin, rct.xmax, rct.ymax); glPolygonMode(GL_FRONT_AND_BACK, GL_FILL); } } void BIF_all_preview_changed(void) { ScrArea *sa; SpaceButs *sbuts; sa= G.curscreen->areabase.first; while(sa) { if(sa->spacetype==SPACE_BUTS) { sbuts= sa->spacedata.first; sbuts->cury= 0; addafterqueue(sa->win, RENDERPREVIEW, 1); } sa= sa->next; } } void BIF_preview_changed(SpaceButs *sbuts) { /* can be called when no buttonswindow visible */ if(sbuts) { sbuts->cury= 0; addafterqueue(sbuts->area->win, RENDERPREVIEW, 1); } } /* is supposed to be called with correct panel offset matrix */ void BIF_previewdraw(void) { SpaceButs *sbuts= curarea->spacedata.first; set_previewrect(sbuts->area->win, PR_XMIN, PR_YMIN, PR_XMAX, PR_YMAX); if (sbuts->rect==0) BIF_preview_changed(sbuts); else { int y; for (y=0; yrect, y); } if (sbuts->mainb==CONTEXT_SHADING && sbuts->tab[CONTEXT_SHADING]==TAB_SHADING_TEX) { draw_tex_crop(sbuts->lockpoin); } } if(sbuts->cury==0) BIF_preview_changed(sbuts); } static void sky_preview_pixel(float lens, int x, int y, char *rect) { float view[3]; if(R.wrld.skytype & WO_SKYPAPER) { view[0]= (2*x)/(float)PR_RECTX; view[1]= (2*y)/(float)PR_RECTY; view[2]= 0.0; } else { view[0]= x; view[1]= y; view[2]= -lens*PR_RECTX/32.0; Normalise(view); } RE_sky(view, rect); } static void lamp_preview_pixel(ShadeInput *shi, LampRen *la, int x, int y, char *rect) { float inpr, i, t, dist, distkw, vec[3]; int col; shi->co[0]= (float)x/(PR_RECTX/4); shi->co[1]= (float)y/(PR_RECTX/4); shi->co[2]= 0; vec[0]= 0.02*x; vec[1]= 0.02*y; vec[2]= 0.005*PR_RECTX; VECCOPY(shi->view, vec); dist= Normalise(shi->view); if(la->mode & LA_TEXTURE) do_lamp_tex(la, vec, shi); if(la->type==LA_SUN || la->type==LA_HEMI) { dist= 1.0; } else { if(la->mode & LA_QUAD) { t= 1.0; if(la->ld1>0.0) t= la->dist/(la->dist+la->ld1*dist); if(la->ld2>0.0) { distkw= la->dist*la->dist; t= t*distkw/(t*distkw+la->ld2*dist*dist); } dist= t; } else { dist= (la->dist/(la->dist+dist)); } } if(la->type==LA_SPOT) { if(la->mode & LA_SQUARE) { /* slightly smaller... */ inpr= 1.7*cos(MAX2(fabs(shi->view[0]/shi->view[2]) , fabs(shi->view[1]/shi->view[2]) )); } else { inpr= shi->view[2]; } t= la->spotsi; if(inprspotbl && la->spotbl!=0.0) { /* soft area */ i= t/la->spotbl; t= i*i; i= t*i; inpr*=(3.0*t-2.0*i); } } dist*=inpr; } else if ELEM(la->type, LA_LOCAL, LA_AREA) dist*= shi->view[2]; col= 255.0*dist*la->r; if(col<=0) rect[0]= 0; else if(col>=255) rect[0]= 255; else rect[0]= col; col= 255.0*dist*la->g; if(col<=0) rect[1]= 0; else if(col>=255) rect[1]= 255; else rect[1]= col; col= 255.0*dist*la->b; if(col<=0) rect[2]= 0; else if(col>=255) rect[2]= 255; else rect[2]= col; } static void init_previewhalo(HaloRen *har, Material *mat) { har->type= 0; if(mat->mode & MA_HALO_XALPHA) har->type |= HA_XALPHA; har->mat= mat; har->hard= mat->har; har->rad= PR_RECTX/2.0; har->radsq= PR_RECTX*PR_RECTX/4.0; har->alfa= mat->alpha; har->add= 255.0*mat->add; har->r= 255.0*mat->r; har->g= 255.0*mat->g; har->b= 255.0*mat->b; har->xs= PR_RECTX/2.0; har->ys= PR_RECTX/2.0; har->zs= har->zd= 0; har->seed= (mat->seed1 % 256); if( (mat->mode & MA_HALOTEX) && mat->mtex[0] ) har->tex= 1; else har->tex=0; if(mat->mode & MA_STAR) har->starpoints= mat->starc; else har->starpoints= 0; if(mat->mode & MA_HALO_LINES) har->linec= mat->linec; else har->linec= 0; if(mat->mode & MA_HALO_RINGS) har->ringc= mat->ringc; else har->ringc= 0; if(mat->mode & MA_HALO_FLARE) har->flarec= mat->flarec; else har->flarec= 0; if(har->flarec) { har->xs-= PR_RECTX/3; har->ys+= PR_RECTX/3; har->rad*= 0.3; har->radsq= har->rad*har->rad; har->pixels= har->rad*har->rad*har->rad; } } static void halo_preview_pixel(HaloRen *har, int startx, int endx, int y, char *rect) { float dist, xn, yn, xsq, ysq; int x; char front[4]; if(har->flarec) yn= y-PR_RECTX/3; else yn= y; ysq= yn*yn; for(x=startx; xflarec) xn= x+PR_RECTX/3; else xn= x; xsq= xn*xn; dist= xsq+ysq; if(distradsq) { RE_shadehalo(har, front, 0, dist, xn, yn, har->flarec); RE_addalphaAddfac(rect, front, har->add); } rect+= 4; } } static void previewflare(SpaceButs *sbuts, HaloRen *har, unsigned int *rect) { uiBlock *block; float ycor; unsigned int *rectot; int afmx, afmy, rectx, recty; block= uiFindOpenPanelBlockName(&curarea->uiblocks, "Preview"); if(block==NULL) return; /* temps */ ycor= R.ycor; rectx= R.rectx; recty= R.recty; afmx= R.afmx; afmy= R.afmy; rectot= R.rectot; R.ycor= 1.0; R.rectx= PR_RECTX; R.recty= PR_RECTY; R.afmx= PR_RECTX/2; R.afmy= PR_RECTY/2; R.rectot= rect; waitcursor(1); RE_renderflare(har); waitcursor(0); // not sure why, either waitcursor or renderflare screws up areawinset(curarea->win); uiPanelPush(block); BIF_previewdraw(); uiPanelPop(block); /* temps */ R.ycor= ycor; R.rectx= rectx; R.recty= recty; R.afmx= afmx; R.afmy= afmy; R.rectot= rectot; } extern float Tin, Tr, Tg, Tb, Ta; /* texture.c */ static void texture_preview_pixel(Tex *tex, int x, int y, char *rect) { float i, v1, xsq, ysq, texvec[3], dummy[3]; int rgbnor, tracol, skip=0; if(tex->type==TEX_IMAGE) { v1= 1.0/PR_RECTX; texvec[0]= 0.5+v1*x; texvec[1]= 0.5+v1*y; /* no coordinate mapping, exception: repeat */ if(tex->xrepeat>1) { texvec[0] *= tex->xrepeat; if(texvec[0]>1.0) texvec[0] -= (int)(texvec[0]); } if(tex->yrepeat>1) { texvec[1] *= tex->yrepeat; if(texvec[1]>1.0) texvec[1] -= (int)(texvec[1]); } } else if(tex->type==TEX_ENVMAP) { if(tex->env) { ysq= y*y; xsq= x*x; if(xsq+ysq < (PR_RECTX/2)*(PR_RECTY/2)) { texvec[2]= sqrt( (float)((PR_RECTX/2)*(PR_RECTY/2)-xsq-ysq) ); texvec[0]= -x; texvec[1]= -y; Normalise(texvec); i= 2.0*(texvec[2]); texvec[0]= (i*texvec[0]); texvec[1]= (i*texvec[1]); texvec[2]= (-1.0+i*texvec[2]); } else { skip= 1; Ta= 0.0; } } else { skip= 1; Ta= 0.0; } } else { v1= 2.0/PR_RECTX; texvec[0]= v1*x; texvec[1]= v1*y; texvec[2]= 0.0; } /* does not return Tin */ if(tex->type==TEX_STUCCI) { tex->nor= dummy; dummy[0]= 1.0; dummy[1]= dummy[2]= 0.0; } if(skip==0) rgbnor= multitex(tex, texvec, NULL, NULL, 0); else rgbnor= 1; if(rgbnor & 1) { rect[0]= 255.0*Tr; rect[1]= 255.0*Tg; rect[2]= 255.0*Tb; if(Ta!=1.0) { tracol= 64+100*(abs(x)>abs(y)); tracol= (1.0-Ta)*tracol; rect[0]= tracol+ (rect[0]*Ta) ; rect[1]= tracol+ (rect[1]*Ta) ; rect[2]= tracol+ (rect[2]*Ta) ; } } else { if(tex->type==TEX_STUCCI) { Tin= 0.5 + 0.7*tex->nor[0]; CLAMP(Tin, 0.0, 1.0); } rect[0]= 255.0*Tin; rect[1]= 255.0*Tin; rect[2]= 255.0*Tin; } } static float pr1_lamp[3]= {2.3, -2.4, -4.6}; static float pr2_lamp[3]= {-8.8, -5.6, -1.5}; static float pr1_col[3]= {0.8, 0.8, 0.8}; static float pr2_col[3]= {0.5, 0.6, 0.7}; static void refraction_prv(int *x, int *y, float *n, float index) { float dot, fac, view[3], len; index= 1.0/index; view[0]= index*(float)*x; view[1]= ((float)*y)/index; view[2]= 20.0; len= Normalise(view); dot= view[0]*n[0] + view[1]*n[1] + view[2]*n[2]; if(dot>0.0) { fac= 1.0 - (1.0 - dot*dot)*index*index; if(fac<= 0.0) return; fac= -dot*index + sqrt(fac); } else { index = 1.0/index; fac= 1.0 - (1.0 - dot*dot)*index*index; if(fac<= 0.0) return; fac= -dot*index - sqrt(fac); } *x= (int)(len*(index*view[0] + fac*n[0])); *y= (int)(len*(index*view[1] + fac*n[1])); } static void shade_preview_pixel(ShadeInput *shi, float *vec, int x, int y,char *rect, int smooth) { extern float fresnel_fac(float *view, float *vn, float ior, float fac); Material *mat; float v1,inp, inprspec=0, isr=0.0, isb=0.0, isg=0.0; float ir=0.0, ib=0.0, ig=0.0; float view[3], lv[3], *la, alpha; float eul[3], tmat[3][3], imat[3][3]; int temp, a; char tracol; mat= shi->matren; v1= 1.0/PR_RECTX; view[0]= v1*x; view[1]= v1*y; view[2]= 1.0; Normalise(view); shi->refcol[0]= shi->refcol[1]= shi->refcol[2]= shi->refcol[3]= 0.0; /* texture handling */ if(mat->texco) { VECCOPY(shi->lo, vec); if(mat->pr_type==MA_CUBE) { eul[0]= (297)*M_PI/180.0; eul[1]= 0.0; eul[2]= (45)*M_PI/180.0; EulToMat3(eul, tmat); MTC_Mat3MulVecfl(tmat, shi->lo); MTC_Mat3MulVecfl(tmat, shi->vn); /* hack for cubemap, why!!! */ SWAP(float, shi->vn[0], shi->vn[1]); } if(mat->texco & TEXCO_GLOB) { VECCOPY(shi->gl, shi->lo); } if(mat->texco & TEXCO_WINDOW) { VECCOPY(shi->winco, shi->lo); } if(mat->texco & TEXCO_STICKY) { VECCOPY(shi->sticky, shi->lo); } if(mat->texco & TEXCO_UV) { VECCOPY(shi->uv, shi->lo); } if(mat->texco & TEXCO_OBJECT) { VECCOPY(shi->co, shi->lo); } if(mat->texco & TEXCO_NORM) { shi->orn[0]= shi->vn[0]; shi->orn[1]= shi->vn[1]; shi->orn[2]= shi->vn[2]; } if(mat->texco & TEXCO_REFL) { /* for bump texture */ VECCOPY(shi->view, view); inp= -2.0*(shi->vn[0]*view[0]+shi->vn[1]*view[1]+shi->vn[2]*view[2]); shi->ref[0]= (view[0]+inp*shi->vn[0]); shi->ref[1]= (view[1]+inp*shi->vn[1]); shi->ref[2]= (view[2]+inp*shi->vn[2]); } do_material_tex(shi); if(mat->texco & TEXCO_REFL) { /* normals in render are pointing different... rhm */ if(smooth) shi->ref[1]= -shi->ref[1]; } if(mat->pr_type==MA_CUBE) { /* rotate normal back for normals texture */ SWAP(float, shi->vn[0], shi->vn[1]); MTC_Mat3Inv(imat, tmat); MTC_Mat3MulVecfl(imat, shi->vn); } } /* set it here, because ray_mirror will affect it */ alpha= mat->alpha; if(mat->mode & (MA_ZTRA|MA_RAYTRANSP)) if(mat->fresnel_tra!=0.0) alpha*= fresnel_fac(view, shi->vn, mat->fresnel_tra_i, mat->fresnel_tra); if(mat->mode & MA_SHLESS) { temp= 255.0*(mat->r); if(temp>255) rect[0]= 255; else if(temp<0) rect[0]= 0; else rect[0]= temp; temp= 255.0*(mat->g); if(temp>255) rect[1]= 255; else if(temp<0) rect[1]= 0; else rect[1]= temp; temp= 255.0*(mat->b); if(temp>255) rect[2]= 255; else if(temp<0) rect[2]= 0; else rect[2]= temp; } else { for(a=0; a<2; a++) { if(a==0) la= pr1_lamp; else la= pr2_lamp; lv[0]= vec[0]-la[0]; lv[1]= vec[1]-la[1]; lv[2]= vec[2]-la[2]; Normalise(lv); inp= shi->vn[0]*lv[0]+shi->vn[1]*lv[1]+shi->vn[2]*lv[2]; if(inp<0.0) inp= 0.0; if(mat->spec) { if(inp>0.0) { /* specular shaders */ float specfac; if(mat->spec_shader==MA_SPEC_PHONG) specfac= Phong_Spec(shi->vn, lv, view, mat->har); else if(mat->spec_shader==MA_SPEC_COOKTORR) specfac= CookTorr_Spec(shi->vn, lv, view, mat->har); else if(mat->spec_shader==MA_SPEC_BLINN) specfac= Blinn_Spec(shi->vn, lv, view, mat->refrac, (float)mat->har); else specfac= Toon_Spec(shi->vn, lv, view, mat->param[2], mat->param[3]); inprspec= specfac*mat->spec; isr+= inprspec*mat->specr; isg+= inprspec*mat->specg; isb+= inprspec*mat->specb; } } /* diffuse shaders */ if(mat->diff_shader==MA_DIFF_ORENNAYAR) inp= OrenNayar_Diff(shi->vn, lv, view, mat->roughness); else if(mat->diff_shader==MA_DIFF_TOON) inp= Toon_Diff(shi->vn, lv, view, mat->param[0], mat->param[1]); // else Lambert inp= (mat->ref*inp + mat->emit); if(a==0) la= pr1_col; else la= pr2_col; ir+= inp*la[0]; ig+= inp*la[1]; ib+= inp*la[2]; } /* drawing checkerboard and sky */ if(mat->mode & MA_RAYMIRROR) { float col, div, y, z; int fac; /* rotate a bit in x */ y= shi->ref[1]; z= shi->ref[2]; shi->ref[1]= 0.98*y - 0.17*z; shi->ref[2]= 0.17*y + 0.98*z; /* scale */ div= (0.85*shi->ref[1]); shi->refcol[0]= mat->ray_mirror*fresnel_fac(view, shi->vn, mat->fresnel_mir_i, mat->fresnel_mir); /* not real 'alpha', but mirror overriding transparency */ if(mat->mode & MA_RAYTRANSP) { float fac= sqrt(shi->refcol[0]); alpha= alpha*(1.0-fac) + fac; } else alpha= alpha*(1.0-shi->refcol[0]) + shi->refcol[0]; if(div<0.0) { /* minus 0.5 prevents too many small tiles in distance */ fac= (int)(shi->ref[0]/(div-0.1) ) + (int)(shi->ref[2]/(div-0.1) ); if(fac & 1) col= 0.8; else col= 0.3; shi->refcol[1]= shi->refcol[0]*col; shi->refcol[2]= shi->refcol[1]; shi->refcol[3]= shi->refcol[2]; } else { shi->refcol[1]= 0.0; shi->refcol[2]= shi->refcol[0]*0.3*div; shi->refcol[3]= shi->refcol[0]*0.8*div; } } if(shi->refcol[0]==0.0) { a= 255.0*( mat->r*ir +mat->ambr +isr); if(a>255) a=255; else if(a<0) a= 0; rect[0]= a; a= 255.0*(mat->g*ig +mat->ambg +isg); if(a>255) a=255; else if(a<0) a= 0; rect[1]= a; a= 255*(mat->b*ib +mat->ambb +isb); if(a>255) a=255; else if(a<0) a= 0; rect[2]= a; } else { a= 255.0*( mat->mirr*shi->refcol[1] + (1.0 - mat->mirr*shi->refcol[0])*(mat->r*ir +mat->ambr) +isr); if(a>255) a=255; else if(a<0) a= 0; rect[0]= a; a= 255.0*( mat->mirg*shi->refcol[2] + (1.0 - mat->mirg*shi->refcol[0])*(mat->g*ig +mat->ambg) +isg); if(a>255) a=255; else if(a<0) a= 0; rect[1]= a; a= 255.0*( mat->mirb*shi->refcol[3] + (1.0 - mat->mirb*shi->refcol[0])*(mat->b*ib +mat->ambb) +isb); if(a>255) a=255; else if(a<0) a= 0; rect[2]= a; } } /* ztra shade */ if(mat->spectra!=0.0) { inp = MAX3(isr, isg, isb); inp *= mat->spectra; if(inp>1.0) inp= 1.0; alpha= (1.0-inp)*alpha+inp; } if(alpha!=1.0) { if(mat->mode & MA_RAYTRANSP) { refraction_prv(&x, &y, shi->vn, mat->ang); } tracol= previewback(mat->pr_back, x, y) & 255; tracol= (1.0-alpha)*tracol; rect[0]= tracol+ (rect[0]*alpha) ; rect[1]= tracol+ (rect[1]*alpha) ; rect[2]= tracol+ (rect[2]*alpha) ; } } void BIF_previewrender(SpaceButs *sbuts) { ID *id, *idfrom; Material *mat= NULL; Tex *tex= NULL; Lamp *la= NULL; World *wrld= NULL; LampRen *lar= NULL; Image *ima; HaloRen har; Object *ob; uiBlock *block; ShadeInput shi; float lens = 0.0, vec[3]; int x, y, starty, startx, endy, endx, radsq, xsq, ysq, last = 0; unsigned int *rect; if(sbuts->cury>=PR_RECTY) return; /* we safely assume curarea has panel "preview" */ /* quick hack for now, later on preview should become uiBlock itself */ block= uiFindOpenPanelBlockName(&curarea->uiblocks, "Preview"); if(block==NULL) return; ob= ((G.scene->basact)? (G.scene->basact)->object: 0); /* we cant trust this global lockpoin.. for example with headerless window */ buttons_active_id(&id, &idfrom); G.buts->lockpoin= id; if(sbuts->mainb==CONTEXT_SHADING) { int tab= sbuts->tab[CONTEXT_SHADING]; if(tab==TAB_SHADING_MAT) mat= sbuts->lockpoin; else if(tab==TAB_SHADING_TEX) tex= sbuts->lockpoin; else if(tab==TAB_SHADING_LAMP) { if(ob && ob->type==OB_LAMP) la= ob->data; } else if(tab==TAB_SHADING_WORLD) wrld= sbuts->lockpoin; } else if(sbuts->mainb==CONTEXT_OBJECT) { if(ob && ob->type==OB_LAMP) la= ob->data; } if(mat==NULL && tex==NULL && la==NULL && wrld==NULL) return; har.flarec= 0; /* below is a test for postrender flare */ if(qtest()) { addafterqueue(curarea->win, RENDERPREVIEW, 1); return; } MTC_Mat4One(R.viewmat); MTC_Mat4One(R.viewinv); shi.osatex= 0; if(mat) { /* rendervars */ init_render_world(); init_render_material(mat); /* clear imats */ for(x=0; x<8; x++) { if(mat->mtex[x]) { if(mat->mtex[x]->tex) { init_render_texture(mat->mtex[x]->tex); if(mat->mtex[x]->tex->env && mat->mtex[x]->tex->env->object) MTC_Mat4One(mat->mtex[x]->tex->env->object->imat); } if(mat->mtex[x]->object) MTC_Mat4One(mat->mtex[x]->object->imat); if(mat->mtex[x]->object) MTC_Mat4One(mat->mtex[x]->object->imat); } } shi.vlr= 0; shi.mat= mat; shi.matren= mat->ren; if(mat->mode & MA_HALO) init_previewhalo(&har, mat); } else if(tex) { ima= tex->ima; if(ima) last= ima->lastframe; init_render_texture(tex); free_unused_animimages(); if(tex->ima) { if(tex->ima!=ima) allqueue(REDRAWBUTSSHADING, 0); else if(last!=ima->lastframe) allqueue(REDRAWBUTSSHADING, 0); } if(tex->env && tex->env->object) MTC_Mat4Invert(tex->env->object->imat, tex->env->object->obmat); } else if(la) { init_render_world(); init_render_textures(); /* do not do it twice!! (brightness) */ R.totlamp= 0; RE_add_render_lamp(ob, 0); /* 0=no shadbuf */ lar= R.la[0]; /* exceptions: */ lar->spottexfac= 1.0; lar->spotsi= cos( M_PI/3.0 ); lar->spotbl= (1.0-lar->spotsi)*la->spotblend; MTC_Mat3One(lar->imat); } else if(wrld) { lens= 35.0; if(G.scene->camera) { lens= ( (Camera *)G.scene->camera->data)->lens; } init_render_world(); init_render_textures(); /* dont do it twice!! (brightness) */ } set_previewrect(sbuts->area->win, PR_XMIN, PR_YMIN, PR_XMAX, PR_YMAX); if(sbuts->rect==0) { sbuts->rect= MEM_callocN(sizeof(int)*PR_RECTX*PR_RECTY, "butsrect"); /* built in emboss */ rect= sbuts->rect; for(y=0; yrect + PR_RECTX-1; for(y=0; ycury; /* offset +1 for emboss */ startx= -PR_RECTX/2 +1; endx= startx+PR_RECTX -2; radsq= (PR_RECTX/2)*(PR_RECTY/2); if(mat) { if(mat->pr_type==MA_SPHERE) { pr1_lamp[0]= 2.3; pr1_lamp[1]= -2.4; pr1_lamp[2]= -4.6; pr2_lamp[0]= -8.8; pr2_lamp[1]= -5.6; pr2_lamp[2]= -1.5; } else { pr1_lamp[0]= 1.9; pr1_lamp[1]= 3.1; pr1_lamp[2]= -8.5; pr2_lamp[0]= 1.2; pr2_lamp[1]= -18; pr2_lamp[2]= 3.2; } } /* here it starts! */ glDrawBuffer(GL_FRONT); uiPanelPush(block); for(y=starty; yrect + 1 + PR_RECTX*sbuts->cury; if(y== -PR_RECTY/2 || y==endy-1); /* emboss */ else if(mat) { if(mat->mode & MA_HALO) { for(x=startx; xpr_back, x, y); } if(har.flarec) { if(y==endy-2) previewflare(sbuts, &har, sbuts->rect); } else { halo_preview_pixel(&har, startx, endx, y, (char *) (rect-PR_RECTX)); } } else { ysq= y*y; for(x=startx; xpr_type==MA_SPHERE) { if(xsq+ysq <= radsq) { shi.vn[0]= x; shi.vn[1]= y; shi.vn[2]= sqrt( (float)(radsq-xsq-ysq) ); Normalise(shi.vn); vec[0]= shi.vn[0]; vec[1]= shi.vn[2]; vec[2]= -shi.vn[1]; shade_preview_pixel(&shi, vec, x, y, (char *)rect, 1); } else { rect[0]= previewback(mat->pr_back, x, y); } } else if(mat->pr_type==MA_CUBE) { if( ray_previewrender(x, y, vec, shi.vn) ) { shade_preview_pixel(&shi, vec, x, y, (char *)rect, 0); } else { rect[0]= previewback(mat->pr_back, x, y); } } else { vec[0]= x*(2.0/PR_RECTX); vec[1]= y*(2.0/PR_RECTX); vec[2]= 0.0; shi.vn[0]= shi.vn[1]= 0.0; shi.vn[2]= 1.0; shade_preview_pixel(&shi, vec, x, y, (char *)rect, 0); } } } } else if(tex) { for(x=startx; xwin, RENDERPREVIEW, 1); break; } } display_pr_scanline(sbuts->rect, sbuts->cury); sbuts->cury++; } if(sbuts->cury>=PR_RECTY && tex) if (sbuts->tab[CONTEXT_SHADING]==TAB_SHADING_TEX) draw_tex_crop(sbuts->lockpoin); glDrawBuffer(GL_BACK); /* draw again for clean swapbufers */ BIF_previewdraw(); uiPanelPop(block); if(mat) { end_render_material(mat); for(x=0; x<8; x++) { if(mat->mtex[x] && mat->mtex[x]->tex) end_render_texture(mat->mtex[x]->tex); } } else if(tex) { end_render_texture(tex); } else if(la) { if(R.totlamp) { if(R.la[0]->org) MEM_freeN(R.la[0]->org); MEM_freeN(R.la[0]); } R.totlamp= 0; end_render_textures(); } else if(wrld) { end_render_textures(); } }