/* This is unusual in that we respect the stride of the output vector
* (f). This allows us to pass in either a texcoord vector4f, or a
* temporary vector3f.
*/
static void build_f3( GLfloat *f,
GLuint fstride,
const GLvector4f *normal,
const GLvector4f *eye )
{
GLuint stride = eye->stride;
GLfloat *coord = eye->start;
GLuint count = eye->count;
GLfloat *norm = normal->start;
GLuint i;
for (i=0;i<count;i++) {
GLfloat u[3], two_nu;
COPY_3V( u, coord );
NORMALIZE_3FV( u );
two_nu = 2.0F * DOT3(norm,u);
f[0] = u[0] - norm[0] * two_nu;
f[1] = u[1] - norm[1] * two_nu;
f[2] = u[2] - norm[2] * two_nu;
STRIDE_F(coord,stride);
STRIDE_F(f,fstride);
STRIDE_F(norm, normal->stride);
}
}
static GLfloat opengl_light_spot(GLfloat *ppli, GLfloat *v, GLfloat *sdli, GLfloat srli, GLfloat crli)
{
GLfloat spot_direction;
GLfloat unit_ppliv[4];
GLfloat unit_sdli[4];
GLfloat cos_crli;
GLfloat spot_factor;
/* Get the unit vectors */
opengl_vector_unit(unit_ppliv, ppli, v);
COPY_3V(unit_sdli, sdli);
NORMALIZE_3FV(unit_sdli);
/* Calculate the direction */
spot_direction = opengl_direction_mul(unit_ppliv, unit_sdli);
cos_crli = cos(crli);
if (fabs(crli - 180.0f) < 0.00000001f)
return 1.0f;
else
{
if (spot_direction >= cos_crli)
{
spot_factor = pow(spot_direction, srli);
return spot_factor;
}
else
{
return 0.0f;
}
}
}
/* Only 3 elements are used, the 4th is ignored */
void x86_opengl_vector_unit(GLfloat *dst, GLfloat *p1, GLfloat *p2)
{
if (p1[3] == 0 && p2[3] !=0)
ACC_SCALE_SCALAR_3V(dst, -1.0f, p1);
else if (p1[3] != 0 && p2[3] ==0)
COPY_3V(dst, p2);
else if (p1[3] == 0 && p2[3] == 0)
SUB_3V(dst, p2, p1);
else
SUB_3V(dst, p2, p1);
NORMALIZE_3FV(dst);
}
void
_mesa_GetLightfv( GLenum light, GLenum pname, GLfloat *params )
{
GET_CURRENT_CONTEXT(ctx);
GLint l = (GLint) (light - GL_LIGHT0);
ASSERT_OUTSIDE_BEGIN_END(ctx);
if (l < 0 || l >= (GLint) ctx->Const.MaxLights) {
_mesa_error( ctx, GL_INVALID_ENUM, "glGetLightfv" );
return;
}
switch (pname) {
case GL_AMBIENT:
COPY_4V( params, ctx->Light.Light[l].Ambient );
break;
case GL_DIFFUSE:
COPY_4V( params, ctx->Light.Light[l].Diffuse );
break;
case GL_SPECULAR:
COPY_4V( params, ctx->Light.Light[l].Specular );
break;
case GL_POSITION:
COPY_4V( params, ctx->Light.Light[l].EyePosition );
break;
case GL_SPOT_DIRECTION:
COPY_3V( params, ctx->Light.Light[l].EyeDirection );
break;
case GL_SPOT_EXPONENT:
params[0] = ctx->Light.Light[l].SpotExponent;
break;
case GL_SPOT_CUTOFF:
params[0] = ctx->Light.Light[l].SpotCutoff;
break;
case GL_CONSTANT_ATTENUATION:
params[0] = ctx->Light.Light[l].ConstantAttenuation;
break;
case GL_LINEAR_ATTENUATION:
params[0] = ctx->Light.Light[l].LinearAttenuation;
break;
case GL_QUADRATIC_ATTENUATION:
params[0] = ctx->Light.Light[l].QuadraticAttenuation;
break;
default:
_mesa_error( ctx, GL_INVALID_ENUM, "glGetLightfv" );
break;
}
}
static void copy_pv_extras( GLcontext *ctx, GLuint dst, GLuint src )
{
struct vertex_buffer *VB = &TNL_CONTEXT(ctx)->vb;
if (VB->ColorPtr[1]) {
COPY_CHAN4( GET_COLOR(VB->ColorPtr[1], dst),
GET_COLOR(VB->ColorPtr[1], src) );
if (VB->SecondaryColorPtr[1]) {
COPY_3V( GET_COLOR(VB->SecondaryColorPtr[1], dst),
GET_COLOR(VB->SecondaryColorPtr[1], src) );
}
}
else if (VB->IndexPtr[1]) {
VB->IndexPtr[1]->data[dst] = VB->IndexPtr[1]->data[src];
}
copy_pv_tab[SWSETUP_CONTEXT(ctx)->SetupIndex](ctx, dst, src);
}
static void build_m3( GLfloat f[][3], GLfloat m[],
const GLvector4f *normal,
const GLvector4f *eye )
{
GLuint stride = eye->stride;
GLfloat *coord = (GLfloat *)eye->start;
GLuint count = eye->count;
const GLfloat *norm = normal->start;
GLuint i;
for (i=0;i<count;i++,STRIDE_F(coord,stride),STRIDE_F(norm,normal->stride)) {
GLfloat u[3], two_nu, fx, fy, fz;
COPY_3V( u, coord );
NORMALIZE_3FV( u );
two_nu = 2.0F * DOT3(norm,u);
fx = f[i][0] = u[0] - norm[0] * two_nu;
fy = f[i][1] = u[1] - norm[1] * two_nu;
fz = f[i][2] = u[2] - norm[2] * two_nu;
m[i] = fx * fx + fy * fy + (fz + 1.0F) * (fz + 1.0F);
if (m[i] != 0.0F) {
m[i] = 0.5F * (1.0f / sqrtf(m[i]));
}
}
}
/**
* Do texgen needed for glRasterPos.
* \param ctx rendering context
* \param vObj object-space vertex coordinate
* \param vEye eye-space vertex coordinate
* \param normal vertex normal
* \param unit texture unit number
* \param texcoord incoming texcoord and resulting texcoord
*/
static void
compute_texgen(struct gl_context *ctx, const GLfloat vObj[4], const GLfloat vEye[4],
const GLfloat normal[3], GLuint unit, GLfloat texcoord[4])
{
const struct gl_texture_unit *texUnit = &ctx->Texture.Unit[unit];
/* always compute sphere map terms, just in case */
GLfloat u[3], two_nu, rx, ry, rz, m, mInv;
COPY_3V(u, vEye);
NORMALIZE_3FV(u);
two_nu = 2.0F * DOT3(normal, u);
rx = u[0] - normal[0] * two_nu;
ry = u[1] - normal[1] * two_nu;
rz = u[2] - normal[2] * two_nu;
m = rx * rx + ry * ry + (rz + 1.0F) * (rz + 1.0F);
if (m > 0.0F)
mInv = 0.5F * (1.0f / sqrtf(m));
else
mInv = 0.0F;
if (texUnit->TexGenEnabled & S_BIT) {
switch (texUnit->GenS.Mode) {
case GL_OBJECT_LINEAR:
texcoord[0] = DOT4(vObj, texUnit->GenS.ObjectPlane);
break;
case GL_EYE_LINEAR:
texcoord[0] = DOT4(vEye, texUnit->GenS.EyePlane);
break;
case GL_SPHERE_MAP:
texcoord[0] = rx * mInv + 0.5F;
break;
case GL_REFLECTION_MAP:
texcoord[0] = rx;
break;
case GL_NORMAL_MAP:
texcoord[0] = normal[0];
break;
default:
_mesa_problem(ctx, "Bad S texgen in compute_texgen()");
return;
}
}
if (texUnit->TexGenEnabled & T_BIT) {
switch (texUnit->GenT.Mode) {
case GL_OBJECT_LINEAR:
texcoord[1] = DOT4(vObj, texUnit->GenT.ObjectPlane);
break;
case GL_EYE_LINEAR:
texcoord[1] = DOT4(vEye, texUnit->GenT.EyePlane);
break;
case GL_SPHERE_MAP:
texcoord[1] = ry * mInv + 0.5F;
break;
case GL_REFLECTION_MAP:
texcoord[1] = ry;
break;
case GL_NORMAL_MAP:
texcoord[1] = normal[1];
break;
default:
_mesa_problem(ctx, "Bad T texgen in compute_texgen()");
return;
}
}
if (texUnit->TexGenEnabled & R_BIT) {
switch (texUnit->GenR.Mode) {
case GL_OBJECT_LINEAR:
texcoord[2] = DOT4(vObj, texUnit->GenR.ObjectPlane);
break;
case GL_EYE_LINEAR:
texcoord[2] = DOT4(vEye, texUnit->GenR.EyePlane);
break;
case GL_REFLECTION_MAP:
texcoord[2] = rz;
break;
case GL_NORMAL_MAP:
texcoord[2] = normal[2];
break;
default:
_mesa_problem(ctx, "Bad R texgen in compute_texgen()");
return;
}
}
if (texUnit->TexGenEnabled & Q_BIT) {
switch (texUnit->GenQ.Mode) {
case GL_OBJECT_LINEAR:
texcoord[3] = DOT4(vObj, texUnit->GenQ.ObjectPlane);
break;
case GL_EYE_LINEAR:
texcoord[3] = DOT4(vEye, texUnit->GenQ.EyePlane);
break;
default:
_mesa_problem(ctx, "Bad Q texgen in compute_texgen()");
return;
}
}
}
/**
* Compute lighting for the raster position. RGB modes computed.
* \param ctx the context
* \param vertex vertex location
* \param normal normal vector
* \param Rcolor returned color
* \param Rspec returned specular color (if separate specular enabled)
*/
static void
shade_rastpos(struct gl_context *ctx,
const GLfloat vertex[4],
const GLfloat normal[3],
GLfloat Rcolor[4],
GLfloat Rspec[4])
{
/*const*/ GLfloat (*base)[3] = ctx->Light._BaseColor;
GLbitfield mask;
GLfloat diffuseColor[4], specularColor[4]; /* for RGB mode only */
COPY_3V(diffuseColor, base[0]);
diffuseColor[3] = CLAMP(
ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_DIFFUSE][3], 0.0F, 1.0F );
ASSIGN_4V(specularColor, 0.0, 0.0, 0.0, 1.0);
mask = ctx->Light._EnabledLights;
while (mask) {
const int i = u_bit_scan(&mask);
struct gl_light *light = &ctx->Light.Light[i];
GLfloat attenuation = 1.0;
GLfloat VP[3]; /* vector from vertex to light pos */
GLfloat n_dot_VP;
GLfloat diffuseContrib[3], specularContrib[3];
if (!(light->_Flags & LIGHT_POSITIONAL)) {
/* light at infinity */
COPY_3V(VP, light->_VP_inf_norm);
attenuation = light->_VP_inf_spot_attenuation;
}
else {
/* local/positional light */
GLfloat d;
/* VP = vector from vertex pos to light[i].pos */
SUB_3V(VP, light->_Position, vertex);
/* d = length(VP) */
d = (GLfloat) LEN_3FV( VP );
if (d > 1.0e-6F) {
/* normalize VP */
GLfloat invd = 1.0F / d;
SELF_SCALE_SCALAR_3V(VP, invd);
}
/* atti */
attenuation = 1.0F / (light->ConstantAttenuation + d *
(light->LinearAttenuation + d *
light->QuadraticAttenuation));
if (light->_Flags & LIGHT_SPOT) {
GLfloat PV_dot_dir = - DOT3(VP, light->_NormSpotDirection);
if (PV_dot_dir<light->_CosCutoff) {
continue;
}
else {
GLfloat spot = powf(PV_dot_dir, light->SpotExponent);
attenuation *= spot;
}
}
}
if (attenuation < 1e-3F)
continue;
n_dot_VP = DOT3( normal, VP );
if (n_dot_VP < 0.0F) {
ACC_SCALE_SCALAR_3V(diffuseColor, attenuation, light->_MatAmbient[0]);
continue;
}
/* Ambient + diffuse */
COPY_3V(diffuseContrib, light->_MatAmbient[0]);
ACC_SCALE_SCALAR_3V(diffuseContrib, n_dot_VP, light->_MatDiffuse[0]);
/* Specular */
{
const GLfloat *h;
GLfloat n_dot_h;
ASSIGN_3V(specularContrib, 0.0, 0.0, 0.0);
if (ctx->Light.Model.LocalViewer) {
GLfloat v[3];
COPY_3V(v, vertex);
NORMALIZE_3FV(v);
SUB_3V(VP, VP, v);
NORMALIZE_3FV(VP);
h = VP;
}
else if (light->_Flags & LIGHT_POSITIONAL) {
ACC_3V(VP, ctx->_EyeZDir);
NORMALIZE_3FV(VP);
h = VP;
}
else {
h = light->_h_inf_norm;
}
n_dot_h = DOT3(normal, h);
if (n_dot_h > 0.0F) {
GLfloat shine;
GLfloat spec_coef;
shine = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_SHININESS][0];
spec_coef = powf(n_dot_h, shine);
if (spec_coef > 1.0e-10F) {
if (ctx->Light.Model.ColorControl==GL_SEPARATE_SPECULAR_COLOR) {
ACC_SCALE_SCALAR_3V( specularContrib, spec_coef,
light->_MatSpecular[0]);
}
else {
ACC_SCALE_SCALAR_3V( diffuseContrib, spec_coef,
light->_MatSpecular[0]);
}
}
}
}
ACC_SCALE_SCALAR_3V( diffuseColor, attenuation, diffuseContrib );
ACC_SCALE_SCALAR_3V( specularColor, attenuation, specularContrib );
}
Rcolor[0] = CLAMP(diffuseColor[0], 0.0F, 1.0F);
Rcolor[1] = CLAMP(diffuseColor[1], 0.0F, 1.0F);
Rcolor[2] = CLAMP(diffuseColor[2], 0.0F, 1.0F);
Rcolor[3] = CLAMP(diffuseColor[3], 0.0F, 1.0F);
Rspec[0] = CLAMP(specularColor[0], 0.0F, 1.0F);
Rspec[1] = CLAMP(specularColor[1], 0.0F, 1.0F);
Rspec[2] = CLAMP(specularColor[2], 0.0F, 1.0F);
Rspec[3] = CLAMP(specularColor[3], 0.0F, 1.0F);
}
/**
* Use the list of tokens in the state[] array to find global GL state
* and return it in <value>. Usually, four values are returned in <value>
* but matrix queries may return as many as 16 values.
* This function is used for ARB vertex/fragment programs.
* The program parser will produce the state[] values.
*/
static void
_mesa_fetch_state(struct gl_context *ctx, const gl_state_index state[],
GLfloat *value)
{
switch (state[0]) {
case STATE_MATERIAL:
{
/* state[1] is either 0=front or 1=back side */
const GLuint face = (GLuint) state[1];
const struct gl_material *mat = &ctx->Light.Material;
ASSERT(face == 0 || face == 1);
/* we rely on tokens numbered so that _BACK_ == _FRONT_+ 1 */
ASSERT(MAT_ATTRIB_FRONT_AMBIENT + 1 == MAT_ATTRIB_BACK_AMBIENT);
/* XXX we could get rid of this switch entirely with a little
* work in arbprogparse.c's parse_state_single_item().
*/
/* state[2] is the material attribute */
switch (state[2]) {
case STATE_AMBIENT:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_AMBIENT + face]);
return;
case STATE_DIFFUSE:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_DIFFUSE + face]);
return;
case STATE_SPECULAR:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_SPECULAR + face]);
return;
case STATE_EMISSION:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_EMISSION + face]);
return;
case STATE_SHININESS:
value[0] = mat->Attrib[MAT_ATTRIB_FRONT_SHININESS + face][0];
value[1] = 0.0F;
value[2] = 0.0F;
value[3] = 1.0F;
return;
default:
_mesa_problem(ctx, "Invalid material state in fetch_state");
return;
}
}
case STATE_LIGHT:
{
/* state[1] is the light number */
const GLuint ln = (GLuint) state[1];
/* state[2] is the light attribute */
switch (state[2]) {
case STATE_AMBIENT:
COPY_4V(value, ctx->Light.Light[ln].Ambient);
return;
case STATE_DIFFUSE:
COPY_4V(value, ctx->Light.Light[ln].Diffuse);
return;
case STATE_SPECULAR:
COPY_4V(value, ctx->Light.Light[ln].Specular);
return;
case STATE_POSITION:
COPY_4V(value, ctx->Light.Light[ln].EyePosition);
return;
case STATE_ATTENUATION:
value[0] = ctx->Light.Light[ln].ConstantAttenuation;
value[1] = ctx->Light.Light[ln].LinearAttenuation;
value[2] = ctx->Light.Light[ln].QuadraticAttenuation;
value[3] = ctx->Light.Light[ln].SpotExponent;
return;
case STATE_SPOT_DIRECTION:
COPY_3V(value, ctx->Light.Light[ln].SpotDirection);
value[3] = ctx->Light.Light[ln]._CosCutoff;
return;
case STATE_SPOT_CUTOFF:
value[0] = ctx->Light.Light[ln].SpotCutoff;
return;
case STATE_HALF_VECTOR:
{
static const GLfloat eye_z[] = {0, 0, 1};
GLfloat p[3];
/* Compute infinite half angle vector:
* halfVector = normalize(normalize(lightPos) + (0, 0, 1))
* light.EyePosition.w should be 0 for infinite lights.
*/
COPY_3V(p, ctx->Light.Light[ln].EyePosition);
NORMALIZE_3FV(p);
ADD_3V(value, p, eye_z);
NORMALIZE_3FV(value);
value[3] = 1.0;
}
return;
default:
_mesa_problem(ctx, "Invalid light state in fetch_state");
return;
}
}
case STATE_LIGHTMODEL_AMBIENT:
COPY_4V(value, ctx->Light.Model.Ambient);
return;
case STATE_LIGHTMODEL_SCENECOLOR:
if (state[1] == 0) {
/* front */
GLint i;
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Model.Ambient[i]
* ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_AMBIENT][i]
+ ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_EMISSION][i];
}
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_DIFFUSE][3];
}
else {
/* back */
GLint i;
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Model.Ambient[i]
* ctx->Light.Material.Attrib[MAT_ATTRIB_BACK_AMBIENT][i]
+ ctx->Light.Material.Attrib[MAT_ATTRIB_BACK_EMISSION][i];
}
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_BACK_DIFFUSE][3];
}
return;
case STATE_LIGHTPROD:
{
const GLuint ln = (GLuint) state[1];
const GLuint face = (GLuint) state[2];
GLint i;
ASSERT(face == 0 || face == 1);
switch (state[3]) {
case STATE_AMBIENT:
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Light[ln].Ambient[i] *
ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_AMBIENT+face][i];
}
/* [3] = material alpha */
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_AMBIENT+face][3];
return;
case STATE_DIFFUSE:
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Light[ln].Diffuse[i] *
ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_DIFFUSE+face][i];
}
/* [3] = material alpha */
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_DIFFUSE+face][3];
return;
case STATE_SPECULAR:
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Light[ln].Specular[i] *
ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_SPECULAR+face][i];
}
/* [3] = material alpha */
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_SPECULAR+face][3];
return;
default:
_mesa_problem(ctx, "Invalid lightprod state in fetch_state");
return;
}
}
case STATE_TEXGEN:
{
/* state[1] is the texture unit */
const GLuint unit = (GLuint) state[1];
/* state[2] is the texgen attribute */
switch (state[2]) {
case STATE_TEXGEN_EYE_S:
COPY_4V(value, ctx->Texture.Unit[unit].GenS.EyePlane);
return;
case STATE_TEXGEN_EYE_T:
COPY_4V(value, ctx->Texture.Unit[unit].GenT.EyePlane);
return;
case STATE_TEXGEN_EYE_R:
COPY_4V(value, ctx->Texture.Unit[unit].GenR.EyePlane);
return;
case STATE_TEXGEN_EYE_Q:
COPY_4V(value, ctx->Texture.Unit[unit].GenQ.EyePlane);
return;
case STATE_TEXGEN_OBJECT_S:
COPY_4V(value, ctx->Texture.Unit[unit].GenS.ObjectPlane);
return;
case STATE_TEXGEN_OBJECT_T:
COPY_4V(value, ctx->Texture.Unit[unit].GenT.ObjectPlane);
return;
case STATE_TEXGEN_OBJECT_R:
COPY_4V(value, ctx->Texture.Unit[unit].GenR.ObjectPlane);
return;
case STATE_TEXGEN_OBJECT_Q:
COPY_4V(value, ctx->Texture.Unit[unit].GenQ.ObjectPlane);
return;
default:
_mesa_problem(ctx, "Invalid texgen state in fetch_state");
return;
}
}
case STATE_TEXENV_COLOR:
{
/* state[1] is the texture unit */
const GLuint unit = (GLuint) state[1];
if (_mesa_get_clamp_fragment_color(ctx))
COPY_4V(value, ctx->Texture.Unit[unit].EnvColor);
else
COPY_4V(value, ctx->Texture.Unit[unit].EnvColorUnclamped);
}
return;
case STATE_FOG_COLOR:
if (_mesa_get_clamp_fragment_color(ctx))
COPY_4V(value, ctx->Fog.Color);
else
COPY_4V(value, ctx->Fog.ColorUnclamped);
return;
case STATE_FOG_PARAMS:
value[0] = ctx->Fog.Density;
value[1] = ctx->Fog.Start;
value[2] = ctx->Fog.End;
value[3] = 1.0f / (ctx->Fog.End - ctx->Fog.Start);
return;
case STATE_CLIPPLANE:
{
const GLuint plane = (GLuint) state[1];
COPY_4V(value, ctx->Transform.EyeUserPlane[plane]);
}
return;
case STATE_POINT_SIZE:
value[0] = ctx->Point.Size;
value[1] = ctx->Point.MinSize;
value[2] = ctx->Point.MaxSize;
value[3] = ctx->Point.Threshold;
return;
case STATE_POINT_ATTENUATION:
value[0] = ctx->Point.Params[0];
value[1] = ctx->Point.Params[1];
value[2] = ctx->Point.Params[2];
value[3] = 1.0F;
return;
case STATE_MODELVIEW_MATRIX:
case STATE_PROJECTION_MATRIX:
case STATE_MVP_MATRIX:
case STATE_TEXTURE_MATRIX:
case STATE_PROGRAM_MATRIX:
{
/* state[0] = modelview, projection, texture, etc. */
/* state[1] = which texture matrix or program matrix */
/* state[2] = first row to fetch */
/* state[3] = last row to fetch */
/* state[4] = transpose, inverse or invtrans */
const GLmatrix *matrix;
const gl_state_index mat = state[0];
const GLuint index = (GLuint) state[1];
const GLuint firstRow = (GLuint) state[2];
const GLuint lastRow = (GLuint) state[3];
const gl_state_index modifier = state[4];
const GLfloat *m;
GLuint row, i;
ASSERT(firstRow >= 0);
ASSERT(firstRow < 4);
ASSERT(lastRow >= 0);
ASSERT(lastRow < 4);
if (mat == STATE_MODELVIEW_MATRIX) {
matrix = ctx->ModelviewMatrixStack.Top;
}
else if (mat == STATE_PROJECTION_MATRIX) {
matrix = ctx->ProjectionMatrixStack.Top;
}
else if (mat == STATE_MVP_MATRIX) {
matrix = &ctx->_ModelProjectMatrix;
}
else if (mat == STATE_TEXTURE_MATRIX) {
ASSERT(index < Elements(ctx->TextureMatrixStack));
matrix = ctx->TextureMatrixStack[index].Top;
}
else if (mat == STATE_PROGRAM_MATRIX) {
ASSERT(index < Elements(ctx->ProgramMatrixStack));
matrix = ctx->ProgramMatrixStack[index].Top;
}
else {
_mesa_problem(ctx, "Bad matrix name in _mesa_fetch_state()");
return;
}
if (modifier == STATE_MATRIX_INVERSE ||
modifier == STATE_MATRIX_INVTRANS) {
/* Be sure inverse is up to date:
*/
_math_matrix_analyse( (GLmatrix*) matrix );
m = matrix->inv;
}
else {
m = matrix->m;
}
if (modifier == STATE_MATRIX_TRANSPOSE ||
modifier == STATE_MATRIX_INVTRANS) {
for (i = 0, row = firstRow; row <= lastRow; row++) {
value[i++] = m[row * 4 + 0];
value[i++] = m[row * 4 + 1];
value[i++] = m[row * 4 + 2];
value[i++] = m[row * 4 + 3];
}
}
else {
for (i = 0, row = firstRow; row <= lastRow; row++) {
value[i++] = m[row + 0];
value[i++] = m[row + 4];
value[i++] = m[row + 8];
value[i++] = m[row + 12];
}
}
}
return;
case STATE_NUM_SAMPLES:
((int *)value)[0] = ctx->DrawBuffer->Visual.samples;
return;
case STATE_DEPTH_RANGE:
value[0] = ctx->ViewportArray[0].Near; /* near */
value[1] = ctx->ViewportArray[0].Far; /* far */
value[2] = ctx->ViewportArray[0].Far - ctx->ViewportArray[0].Near; /* far - near */
value[3] = 1.0;
return;
case STATE_FRAGMENT_PROGRAM:
{
/* state[1] = {STATE_ENV, STATE_LOCAL} */
/* state[2] = parameter index */
const int idx = (int) state[2];
switch (state[1]) {
case STATE_ENV:
COPY_4V(value, ctx->FragmentProgram.Parameters[idx]);
return;
case STATE_LOCAL:
if (!ctx->FragmentProgram.Current->Base.LocalParams) {
ctx->FragmentProgram.Current->Base.LocalParams =
calloc(MAX_PROGRAM_LOCAL_PARAMS, sizeof(float[4]));
if (!ctx->FragmentProgram.Current->Base.LocalParams)
return;
}
COPY_4V(value, ctx->FragmentProgram.Current->Base.LocalParams[idx]);
return;
default:
_mesa_problem(ctx, "Bad state switch in _mesa_fetch_state()");
return;
}
}
return;
case STATE_VERTEX_PROGRAM:
{
/* state[1] = {STATE_ENV, STATE_LOCAL} */
/* state[2] = parameter index */
const int idx = (int) state[2];
switch (state[1]) {
case STATE_ENV:
COPY_4V(value, ctx->VertexProgram.Parameters[idx]);
return;
case STATE_LOCAL:
if (!ctx->VertexProgram.Current->Base.LocalParams) {
ctx->VertexProgram.Current->Base.LocalParams =
calloc(MAX_PROGRAM_LOCAL_PARAMS, sizeof(float[4]));
if (!ctx->VertexProgram.Current->Base.LocalParams)
return;
}
COPY_4V(value, ctx->VertexProgram.Current->Base.LocalParams[idx]);
return;
default:
_mesa_problem(ctx, "Bad state switch in _mesa_fetch_state()");
return;
}
}
return;
case STATE_NORMAL_SCALE:
ASSIGN_4V(value, ctx->_ModelViewInvScale, 0, 0, 1);
return;
case STATE_INTERNAL:
switch (state[1]) {
case STATE_CURRENT_ATTRIB:
{
const GLuint idx = (GLuint) state[2];
COPY_4V(value, ctx->Current.Attrib[idx]);
}
return;
case STATE_CURRENT_ATTRIB_MAYBE_VP_CLAMPED:
{
const GLuint idx = (GLuint) state[2];
if(ctx->Light._ClampVertexColor &&
(idx == VERT_ATTRIB_COLOR0 ||
idx == VERT_ATTRIB_COLOR1)) {
value[0] = CLAMP(ctx->Current.Attrib[idx][0], 0.0f, 1.0f);
value[1] = CLAMP(ctx->Current.Attrib[idx][1], 0.0f, 1.0f);
value[2] = CLAMP(ctx->Current.Attrib[idx][2], 0.0f, 1.0f);
value[3] = CLAMP(ctx->Current.Attrib[idx][3], 0.0f, 1.0f);
}
else
COPY_4V(value, ctx->Current.Attrib[idx]);
}
return;
case STATE_NORMAL_SCALE:
ASSIGN_4V(value,
ctx->_ModelViewInvScale,
ctx->_ModelViewInvScale,
ctx->_ModelViewInvScale,
1);
return;
case STATE_TEXRECT_SCALE:
/* Value = { 1/texWidth, 1/texHeight, 0, 1 }.
* Used to convert unnormalized texcoords to normalized texcoords.
*/
{
const int unit = (int) state[2];
const struct gl_texture_object *texObj
= ctx->Texture.Unit[unit]._Current;
if (texObj) {
struct gl_texture_image *texImage = texObj->Image[0][0];
ASSIGN_4V(value,
(GLfloat) (1.0 / texImage->Width),
(GLfloat) (1.0 / texImage->Height),
0.0f, 1.0f);
}
}
return;
case STATE_FOG_PARAMS_OPTIMIZED:
/* for simpler per-vertex/pixel fog calcs. POW (for EXP/EXP2 fog)
* might be more expensive than EX2 on some hw, plus it needs
* another constant (e) anyway. Linear fog can now be done with a
* single MAD.
* linear: fogcoord * -1/(end-start) + end/(end-start)
* exp: 2^-(density/ln(2) * fogcoord)
* exp2: 2^-((density/(ln(2)^2) * fogcoord)^2)
*/
value[0] = (ctx->Fog.End == ctx->Fog.Start)
? 1.0f : (GLfloat)(-1.0F / (ctx->Fog.End - ctx->Fog.Start));
value[1] = ctx->Fog.End * -value[0];
value[2] = (GLfloat)(ctx->Fog.Density * M_LOG2E); /* M_LOG2E == 1/ln(2) */
value[3] = (GLfloat)(ctx->Fog.Density * ONE_DIV_SQRT_LN2);
return;
case STATE_POINT_SIZE_CLAMPED:
{
/* this includes implementation dependent limits, to avoid
* another potentially necessary clamp.
* Note: for sprites, point smooth (point AA) is ignored
* and we'll clamp to MinPointSizeAA and MaxPointSize, because we
* expect drivers will want to say their minimum for AA size is 0.0
* but for non-AA it's 1.0 (because normal points with size below 1.0
* need to get rounded up to 1.0, hence never disappear). GL does
* not specify max clamp size for sprites, other than it needs to be
* at least as large as max AA size, hence use non-AA size there.
*/
GLfloat minImplSize;
GLfloat maxImplSize;
if (ctx->Point.PointSprite) {
minImplSize = ctx->Const.MinPointSizeAA;
maxImplSize = ctx->Const.MaxPointSize;
}
else if (ctx->Point.SmoothFlag || ctx->Multisample._Enabled) {
minImplSize = ctx->Const.MinPointSizeAA;
maxImplSize = ctx->Const.MaxPointSizeAA;
}
else {
minImplSize = ctx->Const.MinPointSize;
maxImplSize = ctx->Const.MaxPointSize;
}
value[0] = ctx->Point.Size;
value[1] = ctx->Point.MinSize >= minImplSize ? ctx->Point.MinSize : minImplSize;
value[2] = ctx->Point.MaxSize <= maxImplSize ? ctx->Point.MaxSize : maxImplSize;
value[3] = ctx->Point.Threshold;
}
return;
case STATE_LIGHT_SPOT_DIR_NORMALIZED:
{
/* here, state[2] is the light number */
/* pre-normalize spot dir */
const GLuint ln = (GLuint) state[2];
COPY_3V(value, ctx->Light.Light[ln]._NormSpotDirection);
value[3] = ctx->Light.Light[ln]._CosCutoff;
}
return;
case STATE_LIGHT_POSITION:
{
const GLuint ln = (GLuint) state[2];
COPY_4V(value, ctx->Light.Light[ln]._Position);
}
return;
case STATE_LIGHT_POSITION_NORMALIZED:
{
const GLuint ln = (GLuint) state[2];
COPY_4V(value, ctx->Light.Light[ln]._Position);
NORMALIZE_3FV( value );
}
return;
case STATE_LIGHT_HALF_VECTOR:
{
const GLuint ln = (GLuint) state[2];
GLfloat p[3];
/* Compute infinite half angle vector:
* halfVector = normalize(normalize(lightPos) + (0, 0, 1))
* light.EyePosition.w should be 0 for infinite lights.
*/
COPY_3V(p, ctx->Light.Light[ln]._Position);
NORMALIZE_3FV(p);
ADD_3V(value, p, ctx->_EyeZDir);
NORMALIZE_3FV(value);
value[3] = 1.0;
}
return;
case STATE_PT_SCALE:
value[0] = ctx->Pixel.RedScale;
value[1] = ctx->Pixel.GreenScale;
value[2] = ctx->Pixel.BlueScale;
value[3] = ctx->Pixel.AlphaScale;
return;
case STATE_PT_BIAS:
value[0] = ctx->Pixel.RedBias;
value[1] = ctx->Pixel.GreenBias;
value[2] = ctx->Pixel.BlueBias;
value[3] = ctx->Pixel.AlphaBias;
return;
case STATE_FB_SIZE:
value[0] = (GLfloat) (ctx->DrawBuffer->Width - 1);
value[1] = (GLfloat) (ctx->DrawBuffer->Height - 1);
value[2] = 0.0F;
value[3] = 0.0F;
return;
case STATE_FB_WPOS_Y_TRANSFORM:
/* A driver may negate this conditional by using ZW swizzle
* instead of XY (based on e.g. some other state). */
if (_mesa_is_user_fbo(ctx->DrawBuffer)) {
/* Identity (XY) followed by flipping Y upside down (ZW). */
value[0] = 1.0F;
value[1] = 0.0F;
value[2] = -1.0F;
value[3] = (GLfloat) ctx->DrawBuffer->Height;
} else {
/* Flipping Y upside down (XY) followed by identity (ZW). */
value[0] = -1.0F;
value[1] = (GLfloat) ctx->DrawBuffer->Height;
value[2] = 1.0F;
value[3] = 0.0F;
}
return;
/* XXX: make sure new tokens added here are also handled in the
* _mesa_program_state_flags() switch, below.
*/
default:
/* Unknown state indexes are silently ignored here.
* Drivers may do something special.
*/
return;
}
return;
default:
_mesa_problem(ctx, "Invalid state in _mesa_fetch_state");
return;
}
}
void GLAPIENTRY
_mesa_PointParameterfv( GLenum pname, const GLfloat *params)
{
GET_CURRENT_CONTEXT(ctx);
ASSERT_OUTSIDE_BEGIN_END(ctx);
/* Drivers that support point sprites must also support point parameters.
* If point parameters aren't supported, then this function shouldn't even
* exist.
*/
ASSERT(!(ctx->Extensions.ARB_point_sprite
|| ctx->Extensions.NV_point_sprite)
|| ctx->Extensions.EXT_point_parameters);
if (!ctx->Extensions.EXT_point_parameters) {
_mesa_error(ctx, GL_INVALID_OPERATION,
"unsupported function called (unsupported extension)");
return;
}
switch (pname) {
case GL_DISTANCE_ATTENUATION_EXT:
if (TEST_EQ_3V(ctx->Point.Params, params))
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
COPY_3V(ctx->Point.Params, params);
ctx->Point._Attenuated = (ctx->Point.Params[0] != 1.0 ||
ctx->Point.Params[1] != 0.0 ||
ctx->Point.Params[2] != 0.0);
if (ctx->Point._Attenuated)
ctx->_TriangleCaps |= DD_POINT_ATTEN;
else
ctx->_TriangleCaps &= ~DD_POINT_ATTEN;
break;
case GL_POINT_SIZE_MIN_EXT:
if (params[0] < 0.0F) {
_mesa_error( ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)" );
return;
}
if (ctx->Point.MinSize == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.MinSize = params[0];
break;
case GL_POINT_SIZE_MAX_EXT:
if (params[0] < 0.0F) {
_mesa_error( ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)" );
return;
}
if (ctx->Point.MaxSize == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.MaxSize = params[0];
break;
case GL_POINT_FADE_THRESHOLD_SIZE_EXT:
if (params[0] < 0.0F) {
_mesa_error( ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)" );
return;
}
if (ctx->Point.Threshold == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.Threshold = params[0];
break;
case GL_POINT_SPRITE_R_MODE_NV:
/* This is one area where ARB_point_sprite and NV_point_sprite
* differ. In ARB_point_sprite the POINT_SPRITE_R_MODE is
* always ZERO. NV_point_sprite adds the S and R modes.
*/
if (_mesa_is_desktop_gl(ctx) && ctx->Extensions.NV_point_sprite) {
GLenum value = (GLenum) params[0];
if (value != GL_ZERO && value != GL_S && value != GL_R) {
_mesa_error(ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)");
return;
}
if (ctx->Point.SpriteRMode == value)
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.SpriteRMode = value;
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
case GL_POINT_SPRITE_COORD_ORIGIN:
/* GL_POINT_SPRITE_COORD_ORIGIN was added to point sprites when the
* extension was merged into OpenGL 2.0.
*/
if ((ctx->API == API_OPENGL && ctx->Version >= 20)
|| ctx->API == API_OPENGL_CORE) {
GLenum value = (GLenum) params[0];
if (value != GL_LOWER_LEFT && value != GL_UPPER_LEFT) {
_mesa_error(ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)");
return;
}
if (ctx->Point.SpriteOrigin == value)
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.SpriteOrigin = value;
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
default:
_mesa_error( ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)" );
return;
}
if (ctx->Driver.PointParameterfv)
(*ctx->Driver.PointParameterfv)(ctx, pname, params);
}
void GLAPIENTRY
_mesa_PointParameterfv( GLenum pname, const GLfloat *params)
{
GET_CURRENT_CONTEXT(ctx);
ASSERT_OUTSIDE_BEGIN_END(ctx);
switch (pname) {
case GL_DISTANCE_ATTENUATION_EXT:
if (ctx->Extensions.EXT_point_parameters) {
if (TEST_EQ_3V(ctx->Point.Params, params))
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
COPY_3V(ctx->Point.Params, params);
ctx->Point._Attenuated = (ctx->Point.Params[0] != 1.0 ||
ctx->Point.Params[1] != 0.0 ||
ctx->Point.Params[2] != 0.0);
if (ctx->Point._Attenuated)
ctx->_TriangleCaps |= DD_POINT_ATTEN;
else
ctx->_TriangleCaps &= ~DD_POINT_ATTEN;
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
case GL_POINT_SIZE_MIN_EXT:
if (ctx->Extensions.EXT_point_parameters) {
if (params[0] < 0.0F) {
_mesa_error( ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)" );
return;
}
if (ctx->Point.MinSize == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.MinSize = params[0];
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
case GL_POINT_SIZE_MAX_EXT:
if (ctx->Extensions.EXT_point_parameters) {
if (params[0] < 0.0F) {
_mesa_error( ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)" );
return;
}
if (ctx->Point.MaxSize == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.MaxSize = params[0];
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
case GL_POINT_FADE_THRESHOLD_SIZE_EXT:
if (ctx->Extensions.EXT_point_parameters) {
if (params[0] < 0.0F) {
_mesa_error( ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)" );
return;
}
if (ctx->Point.Threshold == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.Threshold = params[0];
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
case GL_POINT_SPRITE_R_MODE_NV:
/* This is one area where ARB_point_sprite and NV_point_sprite
* differ. In ARB_point_sprite the POINT_SPRITE_R_MODE is
* always ZERO. NV_point_sprite adds the S and R modes.
*/
if (ctx->Extensions.NV_point_sprite) {
GLenum value = (GLenum) params[0];
if (value != GL_ZERO && value != GL_S && value != GL_R) {
_mesa_error(ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)");
return;
}
if (ctx->Point.SpriteRMode == value)
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.SpriteRMode = value;
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
case GL_POINT_SPRITE_COORD_ORIGIN:
if (ctx->Extensions.ARB_point_sprite || ctx->Extensions.NV_point_sprite) {
GLenum value = (GLenum) params[0];
if (value != GL_LOWER_LEFT && value != GL_UPPER_LEFT) {
_mesa_error(ctx, GL_INVALID_VALUE,
"glPointParameterf[v]{EXT,ARB}(param)");
return;
}
if (ctx->Point.SpriteOrigin == value)
return;
FLUSH_VERTICES(ctx, _NEW_POINT);
ctx->Point.SpriteOrigin = value;
}
else {
_mesa_error(ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)");
return;
}
break;
default:
_mesa_error( ctx, GL_INVALID_ENUM,
"glPointParameterf[v]{EXT,ARB}(pname)" );
return;
}
if (ctx->Driver.PointParameterfv)
(*ctx->Driver.PointParameterfv)(ctx, pname, params);
}
/**
* Use the list of tokens in the state[] array to find global GL state
* and return it in <value>. Usually, four values are returned in <value>
* but matrix queries may return as many as 16 values.
* This function is used for ARB vertex/fragment programs.
* The program parser will produce the state[] values.
*/
static void
_mesa_fetch_state(GLcontext *ctx, const gl_state_index state[],
GLfloat *value)
{
switch (state[0]) {
case STATE_MATERIAL:
{
/* state[1] is either 0=front or 1=back side */
const GLuint face = (GLuint) state[1];
const struct gl_material *mat = &ctx->Light.Material;
ASSERT(face == 0 || face == 1);
/* we rely on tokens numbered so that _BACK_ == _FRONT_+ 1 */
ASSERT(MAT_ATTRIB_FRONT_AMBIENT + 1 == MAT_ATTRIB_BACK_AMBIENT);
/* XXX we could get rid of this switch entirely with a little
* work in arbprogparse.c's parse_state_single_item().
*/
/* state[2] is the material attribute */
switch (state[2]) {
case STATE_AMBIENT:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_AMBIENT + face]);
return;
case STATE_DIFFUSE:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_DIFFUSE + face]);
return;
case STATE_SPECULAR:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_SPECULAR + face]);
return;
case STATE_EMISSION:
COPY_4V(value, mat->Attrib[MAT_ATTRIB_FRONT_EMISSION + face]);
return;
case STATE_SHININESS:
value[0] = mat->Attrib[MAT_ATTRIB_FRONT_SHININESS + face][0];
value[1] = 0.0F;
value[2] = 0.0F;
value[3] = 1.0F;
return;
default:
_mesa_problem(ctx, "Invalid material state in fetch_state");
return;
}
}
case STATE_LIGHT:
{
/* state[1] is the light number */
const GLuint ln = (GLuint) state[1];
/* state[2] is the light attribute */
switch (state[2]) {
case STATE_AMBIENT:
COPY_4V(value, ctx->Light.Light[ln].Ambient);
return;
case STATE_DIFFUSE:
COPY_4V(value, ctx->Light.Light[ln].Diffuse);
return;
case STATE_SPECULAR:
COPY_4V(value, ctx->Light.Light[ln].Specular);
return;
case STATE_POSITION:
COPY_4V(value, ctx->Light.Light[ln].EyePosition);
return;
case STATE_ATTENUATION:
value[0] = ctx->Light.Light[ln].ConstantAttenuation;
value[1] = ctx->Light.Light[ln].LinearAttenuation;
value[2] = ctx->Light.Light[ln].QuadraticAttenuation;
value[3] = ctx->Light.Light[ln].SpotExponent;
return;
case STATE_SPOT_DIRECTION:
COPY_3V(value, ctx->Light.Light[ln].EyeDirection);
value[3] = ctx->Light.Light[ln]._CosCutoff;
return;
case STATE_SPOT_CUTOFF:
value[0] = ctx->Light.Light[ln].SpotCutoff;
return;
case STATE_HALF_VECTOR:
{
static const GLfloat eye_z[] = {0, 0, 1};
GLfloat p[3];
/* Compute infinite half angle vector:
* halfVector = normalize(normalize(lightPos) + (0, 0, 1))
* light.EyePosition.w should be 0 for infinite lights.
*/
COPY_3V(p, ctx->Light.Light[ln].EyePosition);
NORMALIZE_3FV(p);
ADD_3V(value, p, eye_z);
NORMALIZE_3FV(value);
value[3] = 1.0;
}
return;
case STATE_POSITION_NORMALIZED:
COPY_4V(value, ctx->Light.Light[ln].EyePosition);
NORMALIZE_3FV( value );
return;
default:
_mesa_problem(ctx, "Invalid light state in fetch_state");
return;
}
}
case STATE_LIGHTMODEL_AMBIENT:
COPY_4V(value, ctx->Light.Model.Ambient);
return;
case STATE_LIGHTMODEL_SCENECOLOR:
if (state[1] == 0) {
/* front */
GLint i;
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Model.Ambient[i]
* ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_AMBIENT][i]
+ ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_EMISSION][i];
}
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_DIFFUSE][3];
}
else {
/* back */
GLint i;
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Model.Ambient[i]
* ctx->Light.Material.Attrib[MAT_ATTRIB_BACK_AMBIENT][i]
+ ctx->Light.Material.Attrib[MAT_ATTRIB_BACK_EMISSION][i];
}
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_BACK_DIFFUSE][3];
}
return;
case STATE_LIGHTPROD:
{
const GLuint ln = (GLuint) state[1];
const GLuint face = (GLuint) state[2];
GLint i;
ASSERT(face == 0 || face == 1);
switch (state[3]) {
case STATE_AMBIENT:
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Light[ln].Ambient[i] *
ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_AMBIENT+face][i];
}
/* [3] = material alpha */
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_AMBIENT+face][3];
return;
case STATE_DIFFUSE:
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Light[ln].Diffuse[i] *
ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_DIFFUSE+face][i];
}
/* [3] = material alpha */
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_DIFFUSE+face][3];
return;
case STATE_SPECULAR:
for (i = 0; i < 3; i++) {
value[i] = ctx->Light.Light[ln].Specular[i] *
ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_SPECULAR+face][i];
}
/* [3] = material alpha */
value[3] = ctx->Light.Material.Attrib[MAT_ATTRIB_FRONT_SPECULAR+face][3];
return;
default:
_mesa_problem(ctx, "Invalid lightprod state in fetch_state");
return;
}
}
case STATE_TEXGEN:
{
/* state[1] is the texture unit */
const GLuint unit = (GLuint) state[1];
/* state[2] is the texgen attribute */
switch (state[2]) {
case STATE_TEXGEN_EYE_S:
COPY_4V(value, ctx->Texture.Unit[unit].EyePlaneS);
return;
case STATE_TEXGEN_EYE_T:
COPY_4V(value, ctx->Texture.Unit[unit].EyePlaneT);
return;
case STATE_TEXGEN_EYE_R:
COPY_4V(value, ctx->Texture.Unit[unit].EyePlaneR);
return;
case STATE_TEXGEN_EYE_Q:
COPY_4V(value, ctx->Texture.Unit[unit].EyePlaneQ);
return;
case STATE_TEXGEN_OBJECT_S:
COPY_4V(value, ctx->Texture.Unit[unit].ObjectPlaneS);
return;
case STATE_TEXGEN_OBJECT_T:
COPY_4V(value, ctx->Texture.Unit[unit].ObjectPlaneT);
return;
case STATE_TEXGEN_OBJECT_R:
COPY_4V(value, ctx->Texture.Unit[unit].ObjectPlaneR);
return;
case STATE_TEXGEN_OBJECT_Q:
COPY_4V(value, ctx->Texture.Unit[unit].ObjectPlaneQ);
return;
default:
_mesa_problem(ctx, "Invalid texgen state in fetch_state");
return;
}
}
case STATE_TEXENV_COLOR:
{
/* state[1] is the texture unit */
const GLuint unit = (GLuint) state[1];
COPY_4V(value, ctx->Texture.Unit[unit].EnvColor);
}
return;
case STATE_FOG_COLOR:
COPY_4V(value, ctx->Fog.Color);
return;
case STATE_FOG_PARAMS:
value[0] = ctx->Fog.Density;
value[1] = ctx->Fog.Start;
value[2] = ctx->Fog.End;
value[3] = 1.0F / (ctx->Fog.End - ctx->Fog.Start);
return;
case STATE_CLIPPLANE:
{
const GLuint plane = (GLuint) state[1];
COPY_4V(value, ctx->Transform.EyeUserPlane[plane]);
}
return;
case STATE_POINT_SIZE:
value[0] = ctx->Point.Size;
value[1] = ctx->Point.MinSize;
value[2] = ctx->Point.MaxSize;
value[3] = ctx->Point.Threshold;
return;
case STATE_POINT_ATTENUATION:
value[0] = ctx->Point.Params[0];
value[1] = ctx->Point.Params[1];
value[2] = ctx->Point.Params[2];
value[3] = 1.0F;
return;
case STATE_MODELVIEW_MATRIX:
case STATE_PROJECTION_MATRIX:
case STATE_MVP_MATRIX:
case STATE_TEXTURE_MATRIX:
case STATE_PROGRAM_MATRIX:
{
/* state[0] = modelview, projection, texture, etc. */
/* state[1] = which texture matrix or program matrix */
/* state[2] = first row to fetch */
/* state[3] = last row to fetch */
/* state[4] = transpose, inverse or invtrans */
const GLmatrix *matrix;
const gl_state_index mat = state[0];
const GLuint index = (GLuint) state[1];
const GLuint firstRow = (GLuint) state[2];
const GLuint lastRow = (GLuint) state[3];
const gl_state_index modifier = state[4];
const GLfloat *m;
GLuint row, i;
ASSERT(firstRow >= 0);
ASSERT(firstRow < 4);
ASSERT(lastRow >= 0);
ASSERT(lastRow < 4);
if (mat == STATE_MODELVIEW_MATRIX) {
matrix = ctx->ModelviewMatrixStack.Top;
}
else if (mat == STATE_PROJECTION_MATRIX) {
matrix = ctx->ProjectionMatrixStack.Top;
}
else if (mat == STATE_MVP_MATRIX) {
matrix = &ctx->_ModelProjectMatrix;
}
else if (mat == STATE_TEXTURE_MATRIX) {
matrix = ctx->TextureMatrixStack[index].Top;
}
else if (mat == STATE_PROGRAM_MATRIX) {
matrix = ctx->ProgramMatrixStack[index].Top;
}
else {
_mesa_problem(ctx, "Bad matrix name in _mesa_fetch_state()");
return;
}
if (modifier == STATE_MATRIX_INVERSE ||
modifier == STATE_MATRIX_INVTRANS) {
/* Be sure inverse is up to date:
*/
_math_matrix_alloc_inv( (GLmatrix *) matrix );
_math_matrix_analyse( (GLmatrix*) matrix );
m = matrix->inv;
}
else {
m = matrix->m;
}
if (modifier == STATE_MATRIX_TRANSPOSE ||
modifier == STATE_MATRIX_INVTRANS) {
for (i = 0, row = firstRow; row <= lastRow; row++) {
value[i++] = m[row * 4 + 0];
value[i++] = m[row * 4 + 1];
value[i++] = m[row * 4 + 2];
value[i++] = m[row * 4 + 3];
}
}
else {
for (i = 0, row = firstRow; row <= lastRow; row++) {
value[i++] = m[row + 0];
value[i++] = m[row + 4];
value[i++] = m[row + 8];
value[i++] = m[row + 12];
}
}
}
return;
case STATE_DEPTH_RANGE:
value[0] = ctx->Viewport.Near; /* near */
value[1] = ctx->Viewport.Far; /* far */
value[2] = ctx->Viewport.Far - ctx->Viewport.Near; /* far - near */
value[3] = 1.0;
return;
case STATE_FRAGMENT_PROGRAM:
{
/* state[1] = {STATE_ENV, STATE_LOCAL} */
/* state[2] = parameter index */
const int idx = (int) state[2];
switch (state[1]) {
case STATE_ENV:
COPY_4V(value, ctx->FragmentProgram.Parameters[idx]);
break;
case STATE_LOCAL:
COPY_4V(value, ctx->FragmentProgram.Current->Base.LocalParams[idx]);
break;
default:
_mesa_problem(ctx, "Bad state switch in _mesa_fetch_state()");
return;
}
}
return;
case STATE_VERTEX_PROGRAM:
{
/* state[1] = {STATE_ENV, STATE_LOCAL} */
/* state[2] = parameter index */
const int idx = (int) state[2];
switch (state[1]) {
case STATE_ENV:
COPY_4V(value, ctx->VertexProgram.Parameters[idx]);
break;
case STATE_LOCAL:
COPY_4V(value, ctx->VertexProgram.Current->Base.LocalParams[idx]);
break;
default:
_mesa_problem(ctx, "Bad state switch in _mesa_fetch_state()");
return;
}
}
return;
case STATE_NORMAL_SCALE:
ASSIGN_4V(value, ctx->_ModelViewInvScale, 0, 0, 1);
return;
case STATE_INTERNAL:
switch (state[1]) {
case STATE_NORMAL_SCALE:
ASSIGN_4V(value, ctx->_ModelViewInvScale, 0, 0, 1);
return;
case STATE_TEXRECT_SCALE:
{
const int unit = (int) state[2];
const struct gl_texture_object *texObj
= ctx->Texture.Unit[unit]._Current;
if (texObj) {
struct gl_texture_image *texImage = texObj->Image[0][0];
ASSIGN_4V(value, 1.0 / texImage->Width,
1.0 / texImage->Height,
0.0, 1.0);
}
}
return;
case STATE_FOG_PARAMS_OPTIMIZED:
/* for simpler per-vertex/pixel fog calcs. POW (for EXP/EXP2 fog)
* might be more expensive than EX2 on some hw, plus it needs
* another constant (e) anyway. Linear fog can now be done with a
* single MAD.
* linear: fogcoord * -1/(end-start) + end/(end-start)
* exp: 2^-(density/ln(2) * fogcoord)
* exp2: 2^-((density/(ln(2)^2) * fogcoord)^2)
*/
value[0] = -1.0F / (ctx->Fog.End - ctx->Fog.Start);
value[1] = ctx->Fog.End / (ctx->Fog.End - ctx->Fog.Start);
value[2] = ctx->Fog.Density * ONE_DIV_LN2;
value[3] = ctx->Fog.Density * ONE_DIV_SQRT_LN2;
return;
case STATE_SPOT_DIR_NORMALIZED: {
/* here, state[2] is the light number */
/* pre-normalize spot dir */
const GLuint ln = (GLuint) state[2];
COPY_3V(value, ctx->Light.Light[ln].EyeDirection);
NORMALIZE_3FV(value);
value[3] = ctx->Light.Light[ln]._CosCutoff;
return;
}
default:
/* unknown state indexes are silently ignored
* should be handled by the driver.
*/
return;
}
return;
default:
_mesa_problem(ctx, "Invalid state in _mesa_fetch_state");
return;
}
}
void
_mesa_Lightfv( GLenum light, GLenum pname, const GLfloat *params )
{
GET_CURRENT_CONTEXT(ctx);
GLint i = (GLint) (light - GL_LIGHT0);
struct gl_light *l = &ctx->Light.Light[i];
if (i < 0 || i >= (GLint) ctx->Const.MaxLights) {
_mesa_error( ctx, GL_INVALID_ENUM, "glLight" );
return;
}
switch (pname) {
case GL_AMBIENT:
if (TEST_EQ_4V(l->Ambient, params))
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
COPY_4V( l->Ambient, params );
break;
case GL_DIFFUSE:
if (TEST_EQ_4V(l->Diffuse, params))
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
COPY_4V( l->Diffuse, params );
break;
case GL_SPECULAR:
if (TEST_EQ_4V(l->Specular, params))
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
COPY_4V( l->Specular, params );
break;
case GL_POSITION: {
GLfloat tmp[4];
/* transform position by ModelView matrix */
TRANSFORM_POINT( tmp, ctx->ModelView.m, params );
if (TEST_EQ_4V(l->EyePosition, tmp))
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
COPY_4V(l->EyePosition, tmp);
if (l->EyePosition[3] != 0.0F)
l->_Flags |= LIGHT_POSITIONAL;
else
l->_Flags &= ~LIGHT_POSITIONAL;
break;
}
case GL_SPOT_DIRECTION: {
GLfloat tmp[4];
/* transform direction by inverse modelview */
if (ctx->ModelView.flags & MAT_DIRTY_INVERSE) {
_math_matrix_analyse( &ctx->ModelView );
}
TRANSFORM_NORMAL( tmp, params, ctx->ModelView.inv );
if (TEST_EQ_3V(l->EyeDirection, tmp))
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
COPY_3V(l->EyeDirection, tmp);
break;
}
case GL_SPOT_EXPONENT:
if (params[0]<0.0 || params[0]>128.0) {
_mesa_error( ctx, GL_INVALID_VALUE, "glLight" );
return;
}
if (l->SpotExponent == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
l->SpotExponent = params[0];
_mesa_invalidate_spot_exp_table( l );
break;
case GL_SPOT_CUTOFF:
if ((params[0]<0.0 || params[0]>90.0) && params[0]!=180.0) {
_mesa_error( ctx, GL_INVALID_VALUE, "glLight" );
return;
}
if (l->SpotCutoff == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
l->SpotCutoff = params[0];
l->_CosCutoff = (GLfloat) cos(params[0]*DEG2RAD);
if (l->_CosCutoff < 0)
l->_CosCutoff = 0;
if (l->SpotCutoff != 180.0F)
l->_Flags |= LIGHT_SPOT;
else
l->_Flags &= ~LIGHT_SPOT;
break;
case GL_CONSTANT_ATTENUATION:
if (params[0]<0.0) {
_mesa_error( ctx, GL_INVALID_VALUE, "glLight" );
return;
}
if (l->ConstantAttenuation == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
l->ConstantAttenuation = params[0];
break;
case GL_LINEAR_ATTENUATION:
if (params[0]<0.0) {
_mesa_error( ctx, GL_INVALID_VALUE, "glLight" );
return;
}
if (l->LinearAttenuation == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
l->LinearAttenuation = params[0];
break;
case GL_QUADRATIC_ATTENUATION:
if (params[0]<0.0) {
_mesa_error( ctx, GL_INVALID_VALUE, "glLight" );
return;
}
if (l->QuadraticAttenuation == params[0])
return;
FLUSH_VERTICES(ctx, _NEW_LIGHT);
l->QuadraticAttenuation = params[0];
break;
default:
_mesa_error( ctx, GL_INVALID_ENUM, "glLight" );
return;
}
if (ctx->Driver.Lightfv)
ctx->Driver.Lightfv( ctx, light, pname, params );
}
