kolibrios/programs/develop/libraries/TinyGL/src/light.c

#include "zgl.h"
#include "msghandling.h"

void glopMaterial(GLContext *c,GLParam *p)
{
  int mode=p[1].i;
  int type=p[2].i;
  float *v=&p[3].f;
  int i;
  GLMaterial *m;

  if (mode == GL_FRONT_AND_BACK) {
    p[1].i=GL_FRONT;
    glopMaterial(c,p);
    mode=GL_BACK;
  }
  if (mode == GL_FRONT) m=&c->materials[0];
  else m=&c->materials[1];

  switch(type) {
  case GL_EMISSION:
    for(i=0;i<4;i++)
      m->emission.v[i]=v[i];
    break;
  case GL_AMBIENT:
    for(i=0;i<4;i++)
      m->ambient.v[i]=v[i];
    break;
  case GL_DIFFUSE:
    for(i=0;i<4;i++)
      m->diffuse.v[i]=v[i];
    break;
  case GL_SPECULAR:
    for(i=0;i<4;i++)
      m->specular.v[i]=v[i];
    break;
  case GL_SHININESS:
    m->shininess=v[0];
    m->shininess_i = (v[0]/128.0f)*SPECULAR_BUFFER_RESOLUTION;
    break;
  case GL_AMBIENT_AND_DIFFUSE:
    for(i=0;i<4;i++)
      m->diffuse.v[i]=v[i];
    for(i=0;i<4;i++)
      m->ambient.v[i]=v[i];
    break;
  default:
    assert(0);
  }
}

void glopColorMaterial(GLContext *c,GLParam *p)
{
  int mode=p[1].i;
  int type=p[2].i;

  c->current_color_material_mode=mode;
  c->current_color_material_type=type;
}

void glopLight(GLContext *c,GLParam *p)
{
  int light=p[1].i;
  int type=p[2].i;
  V4 v;
  GLLight *l;
  int i;
  
  assert(light >= GL_LIGHT0 && light < GL_LIGHT0+MAX_LIGHTS );

  l=&c->lights[light-GL_LIGHT0];

  for(i=0;i<4;i++) v.v[i]=p[3+i].f;

  switch(type) {
  case GL_AMBIENT:
    l->ambient=v;
    break;
  case GL_DIFFUSE:
    l->diffuse=v;
    break;
  case GL_SPECULAR:
    l->specular=v;
    break;
  case GL_POSITION:
    {
      V4 pos;
      gl_M4_MulV4(&pos,c->matrix_stack_ptr[0],&v);

      l->position=pos;

      if (l->position.v[3] == 0) {
        l->norm_position.X=pos.X;
        l->norm_position.Y=pos.Y;
        l->norm_position.Z=pos.Z;
        
        gl_V3_Norm(&l->norm_position);
      }
    }
    break;
  case GL_SPOT_DIRECTION:
    for(i=0;i<3;i++) {
      l->spot_direction.v[i]=v.v[i];
      l->norm_spot_direction.v[i]=v.v[i];
    }
    gl_V3_Norm(&l->norm_spot_direction);
    break;
  case GL_SPOT_EXPONENT:
    l->spot_exponent=v.v[0];
    break;
  case GL_SPOT_CUTOFF:
    {
      float a=v.v[0];
      assert(a == 180 || (a>=0 && a<=90));
      l->spot_cutoff=a;
      if (a != 180) l->cos_spot_cutoff=cos(a * M_PI / 180.0);
    }
    break;
  case GL_CONSTANT_ATTENUATION:
    l->attenuation[0]=v.v[0];
    break;
  case GL_LINEAR_ATTENUATION:
    l->attenuation[1]=v.v[0];
    break;
  case GL_QUADRATIC_ATTENUATION:
    l->attenuation[2]=v.v[0];
    break;
  default:
    assert(0);
  }
}
  

void glopLightModel(GLContext *c,GLParam *p)
{
  int pname=p[1].i;
  float *v=&p[2].f;
  int i;

  switch(pname) {
  case GL_LIGHT_MODEL_AMBIENT:
    for(i=0;i<4;i++) 
      c->ambient_light_model.v[i]=v[i];
    break;
  case GL_LIGHT_MODEL_LOCAL_VIEWER:
    c->local_light_model=(int)v[0];
    break;
  case GL_LIGHT_MODEL_TWO_SIDE:
    c->light_model_two_side = (int)v[0];
    break;
  default:
    tgl_warning("glopLightModel: illegal pname: 0x%x\n", pname);
    //assert(0);
    break;
  }
}


static inline float clampf(float a,float min,float max)
{
  if (a<min) return min;
  else if (a>max) return max;
  else return a;
}

void gl_enable_disable_light(GLContext *c,int light,int v)
{
  GLLight *l=&c->lights[light];
  if (v && !l->enabled) {
    l->enabled=1;
    l->next=c->first_light;
    c->first_light=l;
    l->prev=NULL;
  } else if (!v && l->enabled) {
    l->enabled=0;
    if (l->prev == NULL) c->first_light=l->next;
    else l->prev->next=l->next;
    if (l->next != NULL) l->next->prev=l->prev;
  }
}

/* non optimized lightening model */
void gl_shade_vertex(GLContext *c,GLVertex *v)
{
  float R,G,B,A;
  GLMaterial *m;
  GLLight *l;
  V3 n,s,d;
  float dist,tmp,att,dot,dot_spot,dot_spec;
  int twoside = c->light_model_two_side;

  m=&c->materials[0];

  n.X=v->normal.X;
  n.Y=v->normal.Y;
  n.Z=v->normal.Z;

  R=m->emission.v[0]+m->ambient.v[0]*c->ambient_light_model.v[0];
  G=m->emission.v[1]+m->ambient.v[1]*c->ambient_light_model.v[1];
  B=m->emission.v[2]+m->ambient.v[2]*c->ambient_light_model.v[2];
  A=clampf(m->diffuse.v[3],0,1);

  for(l=c->first_light;l!=NULL;l=l->next) {
    float lR,lB,lG;
    
    /* ambient */
    lR=l->ambient.v[0] * m->ambient.v[0];
    lG=l->ambient.v[1] * m->ambient.v[1];
    lB=l->ambient.v[2] * m->ambient.v[2];

    if (l->position.v[3] == 0) {
      /* light at infinity */
      d.X=l->position.v[0];
      d.Y=l->position.v[1];
      d.Z=l->position.v[2];
      att=1;
    } else {
      /* distance attenuation */
      d.X=l->position.v[0]-v->ec.v[0];
      d.Y=l->position.v[1]-v->ec.v[1];
      d.Z=l->position.v[2]-v->ec.v[2];
      dist=sqrt(d.X*d.X+d.Y*d.Y+d.Z*d.Z);
      if (dist>1E-3) {
        tmp=1/dist;
        d.X*=tmp;
        d.Y*=tmp;
        d.Z*=tmp;
      }
      att=1.0f/(l->attenuation[0]+dist*(l->attenuation[1]+
				     dist*l->attenuation[2]));
    }
    dot=d.X*n.X+d.Y*n.Y+d.Z*n.Z;
    if (twoside && dot < 0) dot = -dot;
    if (dot>0) {
      /* diffuse light */
      lR+=dot * l->diffuse.v[0] * m->diffuse.v[0];
      lG+=dot * l->diffuse.v[1] * m->diffuse.v[1];
      lB+=dot * l->diffuse.v[2] * m->diffuse.v[2];

      /* spot light */
      if (l->spot_cutoff != 180) {
        dot_spot=-(d.X*l->norm_spot_direction.v[0]+
                   d.Y*l->norm_spot_direction.v[1]+
                   d.Z*l->norm_spot_direction.v[2]);
        if (twoside && dot_spot < 0) dot_spot = -dot_spot;
        if (dot_spot < l->cos_spot_cutoff) {
          /* no contribution */
          continue;
        } else {
          /* TODO: optimize */
          if (l->spot_exponent > 0) {
            att=att*pow(dot_spot,l->spot_exponent);
          }
        }
      }

      /* specular light */
      
      if (c->local_light_model) {
        V3 vcoord;
        vcoord.X=v->ec.X;
        vcoord.Y=v->ec.Y;
        vcoord.Z=v->ec.Z;
        gl_V3_Norm(&vcoord);
        s.X=d.X-vcoord.X;
        s.Y=d.Y-vcoord.X;
        s.Z=d.Z-vcoord.X;
      } else {
        s.X=d.X;
        s.Y=d.Y;
        s.Z=d.Z+1.0;
      }
      dot_spec=n.X*s.X+n.Y*s.Y+n.Z*s.Z;
      if (twoside && dot_spec < 0) dot_spec = -dot_spec;
      if (dot_spec>0) {
        GLSpecBuf *specbuf;
        int idx;
        tmp=sqrt(s.X*s.X+s.Y*s.Y+s.Z*s.Z);
        if (tmp > 1E-3) {
          dot_spec=dot_spec / tmp;
        }
      
        /* TODO: optimize */
        /* testing specular buffer code */
        /* dot_spec= pow(dot_spec,m->shininess);*/
        specbuf = specbuf_get_buffer(c, m->shininess_i, m->shininess);
        idx = (int)(dot_spec*SPECULAR_BUFFER_SIZE);
        if (idx > SPECULAR_BUFFER_SIZE) idx = SPECULAR_BUFFER_SIZE;
        dot_spec = specbuf->buf[idx];
        lR+=dot_spec * l->specular.v[0] * m->specular.v[0];
        lG+=dot_spec * l->specular.v[1] * m->specular.v[1];
        lB+=dot_spec * l->specular.v[2] * m->specular.v[2];
      }
    }

    R+=att * lR;
    G+=att * lG;
    B+=att * lB;
  }

  v->color.v[0]=clampf(R,0,1);
  v->color.v[1]=clampf(G,0,1);
  v->color.v[2]=clampf(B,0,1);
  v->color.v[3]=A;
}
switch build system to Tup git-svn-id: svn://kolibrios.org@5098 a494cfbc-eb01-0410-851d-a64ba20cac60 2014-09-12 17:15:23 +02:00			`#include "zgl.h"`
			`#include "msghandling.h"`

			`void glopMaterial(GLContext c,GLParam p)`
			`{`
			`int mode=p[1].i;`
			`int type=p[2].i;`
			`float *v=&p[3].f;`
			`int i;`
			`GLMaterial *m;`

			`if (mode == GL_FRONT_AND_BACK) {`
			`p[1].i=GL_FRONT;`
			`glopMaterial(c,p);`
			`mode=GL_BACK;`
			`}`
			`if (mode == GL_FRONT) m=&c->materials[0];`
			`else m=&c->materials[1];`

			`switch(type) {`
			`case GL_EMISSION:`
			`for(i=0;i<4;i++)`
			`m->emission.v[i]=v[i];`
			`break;`
			`case GL_AMBIENT:`
			`for(i=0;i<4;i++)`
			`m->ambient.v[i]=v[i];`
			`break;`
			`case GL_DIFFUSE:`
			`for(i=0;i<4;i++)`
			`m->diffuse.v[i]=v[i];`
			`break;`
			`case GL_SPECULAR:`
			`for(i=0;i<4;i++)`
			`m->specular.v[i]=v[i];`
			`break;`
			`case GL_SHININESS:`
			`m->shininess=v[0];`
			`m->shininess_i = (v[0]/128.0f)*SPECULAR_BUFFER_RESOLUTION;`
			`break;`
			`case GL_AMBIENT_AND_DIFFUSE:`
			`for(i=0;i<4;i++)`
			`m->diffuse.v[i]=v[i];`
			`for(i=0;i<4;i++)`
			`m->ambient.v[i]=v[i];`
			`break;`
			`default:`
			`assert(0);`
			`}`
			`}`

			`void glopColorMaterial(GLContext c,GLParam p)`
			`{`
			`int mode=p[1].i;`
			`int type=p[2].i;`

			`c->current_color_material_mode=mode;`
			`c->current_color_material_type=type;`
			`}`

			`void glopLight(GLContext c,GLParam p)`
			`{`
			`int light=p[1].i;`
			`int type=p[2].i;`
			`V4 v;`
			`GLLight *l;`
			`int i;`

			`assert(light >= GL_LIGHT0 && light < GL_LIGHT0+MAX_LIGHTS );`

			`l=&c->lights[light-GL_LIGHT0];`

			`for(i=0;i<4;i++) v.v[i]=p[3+i].f;`

			`switch(type) {`
			`case GL_AMBIENT:`
			`l->ambient=v;`
			`break;`
			`case GL_DIFFUSE:`
			`l->diffuse=v;`
			`break;`
			`case GL_SPECULAR:`
			`l->specular=v;`
			`break;`
			`case GL_POSITION:`
			`{`
			`V4 pos;`
			`gl_M4_MulV4(&pos,c->matrix_stack_ptr[0],&v);`

			`l->position=pos;`

			`if (l->position.v[3] == 0) {`
			`l->norm_position.X=pos.X;`
			`l->norm_position.Y=pos.Y;`
			`l->norm_position.Z=pos.Z;`

			`gl_V3_Norm(&l->norm_position);`
			`}`
			`}`
			`break;`
			`case GL_SPOT_DIRECTION:`
			`for(i=0;i<3;i++) {`
			`l->spot_direction.v[i]=v.v[i];`
			`l->norm_spot_direction.v[i]=v.v[i];`
			`}`
			`gl_V3_Norm(&l->norm_spot_direction);`
			`break;`
			`case GL_SPOT_EXPONENT:`
			`l->spot_exponent=v.v[0];`
			`break;`
			`case GL_SPOT_CUTOFF:`
			`{`
			`float a=v.v[0];`
			`assert(a == 180 \|\| (a>=0 && a<=90));`
			`l->spot_cutoff=a;`
			`if (a != 180) l->cos_spot_cutoff=cos(a * M_PI / 180.0);`
			`}`
			`break;`
			`case GL_CONSTANT_ATTENUATION:`
			`l->attenuation[0]=v.v[0];`
			`break;`
			`case GL_LINEAR_ATTENUATION:`
			`l->attenuation[1]=v.v[0];`
			`break;`
			`case GL_QUADRATIC_ATTENUATION:`
			`l->attenuation[2]=v.v[0];`
			`break;`
			`default:`
			`assert(0);`
			`}`
			`}`


			`void glopLightModel(GLContext c,GLParam p)`
			`{`
			`int pname=p[1].i;`
			`float *v=&p[2].f;`
			`int i;`

			`switch(pname) {`
			`case GL_LIGHT_MODEL_AMBIENT:`
			`for(i=0;i<4;i++)`
			`c->ambient_light_model.v[i]=v[i];`
			`break;`
			`case GL_LIGHT_MODEL_LOCAL_VIEWER:`
			`c->local_light_model=(int)v[0];`
			`break;`
			`case GL_LIGHT_MODEL_TWO_SIDE:`
			`c->light_model_two_side = (int)v[0];`
			`break;`
			`default:`
			`tgl_warning("glopLightModel: illegal pname: 0x%x\n", pname);`
			`//assert(0);`
			`break;`
			`}`
			`}`


			`static inline float clampf(float a,float min,float max)`
			`{`
			`if (a<min) return min;`
			`else if (a>max) return max;`
			`else return a;`
			`}`

			`void gl_enable_disable_light(GLContext *c,int light,int v)`
			`{`
			`GLLight *l=&c->lights[light];`
			`if (v && !l->enabled) {`
			`l->enabled=1;`
			`l->next=c->first_light;`
			`c->first_light=l;`
			`l->prev=NULL;`
			`} else if (!v && l->enabled) {`
			`l->enabled=0;`
			`if (l->prev == NULL) c->first_light=l->next;`
			`else l->prev->next=l->next;`
			`if (l->next != NULL) l->next->prev=l->prev;`
			`}`
			`}`

			`/* non optimized lightening model */`
			`void gl_shade_vertex(GLContext c,GLVertex v)`
			`{`
			`float R,G,B,A;`
			`GLMaterial *m;`
			`GLLight *l;`
			`V3 n,s,d;`
			`float dist,tmp,att,dot,dot_spot,dot_spec;`
			`int twoside = c->light_model_two_side;`

			`m=&c->materials[0];`

			`n.X=v->normal.X;`
			`n.Y=v->normal.Y;`
			`n.Z=v->normal.Z;`

			`R=m->emission.v[0]+m->ambient.v[0]*c->ambient_light_model.v[0];`
			`G=m->emission.v[1]+m->ambient.v[1]*c->ambient_light_model.v[1];`
			`B=m->emission.v[2]+m->ambient.v[2]*c->ambient_light_model.v[2];`
			`A=clampf(m->diffuse.v[3],0,1);`

			`for(l=c->first_light;l!=NULL;l=l->next) {`
			`float lR,lB,lG;`

			`/* ambient */`
			`lR=l->ambient.v[0] * m->ambient.v[0];`
			`lG=l->ambient.v[1] * m->ambient.v[1];`
			`lB=l->ambient.v[2] * m->ambient.v[2];`

			`if (l->position.v[3] == 0) {`
			`/* light at infinity */`
			`d.X=l->position.v[0];`
			`d.Y=l->position.v[1];`
			`d.Z=l->position.v[2];`
			`att=1;`
			`} else {`
			`/* distance attenuation */`
			`d.X=l->position.v[0]-v->ec.v[0];`
			`d.Y=l->position.v[1]-v->ec.v[1];`
			`d.Z=l->position.v[2]-v->ec.v[2];`
			`dist=sqrt(d.Xd.X+d.Yd.Y+d.Z*d.Z);`
			`if (dist>1E-3) {`
			`tmp=1/dist;`
			`d.X*=tmp;`
			`d.Y*=tmp;`
			`d.Z*=tmp;`
			`}`
			`att=1.0f/(l->attenuation[0]+dist*(l->attenuation[1]+`
			`dist*l->attenuation[2]));`
			`}`
			`dot=d.Xn.X+d.Yn.Y+d.Z*n.Z;`
			`if (twoside && dot < 0) dot = -dot;`
			`if (dot>0) {`
			`/* diffuse light */`
			`lR+=dot * l->diffuse.v[0] * m->diffuse.v[0];`
			`lG+=dot * l->diffuse.v[1] * m->diffuse.v[1];`
			`lB+=dot * l->diffuse.v[2] * m->diffuse.v[2];`

			`/* spot light */`
			`if (l->spot_cutoff != 180) {`
			`dot_spot=-(d.X*l->norm_spot_direction.v[0]+`
			`d.Y*l->norm_spot_direction.v[1]+`
			`d.Z*l->norm_spot_direction.v[2]);`
			`if (twoside && dot_spot < 0) dot_spot = -dot_spot;`
			`if (dot_spot < l->cos_spot_cutoff) {`
			`/* no contribution */`
			`continue;`
			`} else {`
			`/* TODO: optimize */`
			`if (l->spot_exponent > 0) {`
			`att=att*pow(dot_spot,l->spot_exponent);`
			`}`
			`}`
			`}`

			`/* specular light */`

			`if (c->local_light_model) {`
			`V3 vcoord;`
			`vcoord.X=v->ec.X;`
			`vcoord.Y=v->ec.Y;`
			`vcoord.Z=v->ec.Z;`
			`gl_V3_Norm(&vcoord);`
			`s.X=d.X-vcoord.X;`
			`s.Y=d.Y-vcoord.X;`
			`s.Z=d.Z-vcoord.X;`
			`} else {`
			`s.X=d.X;`
			`s.Y=d.Y;`
			`s.Z=d.Z+1.0;`
			`}`
			`dot_spec=n.Xs.X+n.Ys.Y+n.Z*s.Z;`
			`if (twoside && dot_spec < 0) dot_spec = -dot_spec;`
			`if (dot_spec>0) {`
			`GLSpecBuf *specbuf;`
			`int idx;`
			`tmp=sqrt(s.Xs.X+s.Ys.Y+s.Z*s.Z);`
			`if (tmp > 1E-3) {`
			`dot_spec=dot_spec / tmp;`
			`}`

			`/* TODO: optimize */`
			`/* testing specular buffer code */`
			`/* dot_spec= pow(dot_spec,m->shininess);*/`
			`specbuf = specbuf_get_buffer(c, m->shininess_i, m->shininess);`
			`idx = (int)(dot_spec*SPECULAR_BUFFER_SIZE);`
			`if (idx > SPECULAR_BUFFER_SIZE) idx = SPECULAR_BUFFER_SIZE;`
			`dot_spec = specbuf->buf[idx];`
			`lR+=dot_spec * l->specular.v[0] * m->specular.v[0];`
			`lG+=dot_spec * l->specular.v[1] * m->specular.v[1];`
			`lB+=dot_spec * l->specular.v[2] * m->specular.v[2];`
			`}`
			`}`

			`R+=att * lR;`
			`G+=att * lG;`
			`B+=att * lB;`
			`}`

			`v->color.v[0]=clampf(R,0,1);`
			`v->color.v[1]=clampf(G,0,1);`
			`v->color.v[2]=clampf(B,0,1);`
			`v->color.v[3]=A;`
			`}`