static bool hlsl_init(const char *path)
{
xdk_d3d_video_t *d3d = (xdk_d3d_video_t*)driver.video_data;
if (path && strcmp(path_get_extension(path), ".cgp") == 0)
{
if (!load_preset(path))
return false;
}
else
{
if (!load_plain(path))
return false;
}
for(unsigned i = 1; i <= cg_shader->passes; i++)
set_program_attributes(i);
d3d_device_ptr = d3d->d3d_render_device;
d3d->d3d_render_device->SetVertexShader(prg[1].vprg);
d3d->d3d_render_device->SetPixelShader(prg[1].fprg);
hlsl_active = true;
return true;
}
size_t FindDetectorsPar::loadParFile(const std::string &fileName){
// load ASCII par or phx file
std::ifstream dataStream;
std::vector<double> result;
this->current_ASCII_file = get_ASCII_header(fileName,dataStream);
load_plain(dataStream,result,current_ASCII_file);
m_nDetectors = current_ASCII_file.nData_records;
dataStream.close();
// transfer par data into internal algorithm parameters;
azimuthal.resize(m_nDetectors);
polar.resize(m_nDetectors);
detID.resize(m_nDetectors);
int Block_size,shift;
if(current_ASCII_file.Type==PAR_type)
{
m_SizesAreLinear = true;
Block_size = 5; // this value coinside with the value defined in load_plain
shift = 0;
azimuthalWidth.resize(m_nDetectors);
polarWidth.resize(m_nDetectors);
secondaryFlightpath.resize(m_nDetectors,std::numeric_limits<double>::quiet_NaN());
for(size_t i=0;i<m_nDetectors;i++){
azimuthal[i] = result[shift+2+i*Block_size];
polar[i] = result[shift+1+i*Block_size];
azimuthalWidth[i] =-result[shift+3+i*Block_size];
polarWidth[i] = result[shift+4+i*Block_size];
secondaryFlightpath[i] = result[shift+0+i*Block_size];
detID[i] = i+1;
}
}else if(current_ASCII_file.Type==PHX_type)
{
m_SizesAreLinear = false;
Block_size = 6; // this value coinside with the value defined in load_plain
shift = 1;
azimuthalWidth.resize(m_nDetectors);
polarWidth.resize(m_nDetectors);
for(size_t i=0;i<m_nDetectors;i++)
{
azimuthal[i] =result[shift+2+i*Block_size];
polar[i] =result[shift+1+i*Block_size];
azimuthalWidth[i] =result[shift+4+i*Block_size];
polarWidth[i] =result[shift+3+i*Block_size];
detID[i] =i+1;
}
}else{
g_log.error()<<" unsupported type of ASCII parameter file: "<<fileName<<std::endl;
throw(std::invalid_argument("unsupported ASCII file type"));
}
return m_nDetectors;
}
bool hlsl_init(const char *path, IDirect3DDevice9 * device_ptr)
{
if (!device_ptr)
return false;
d3d_device_ptr = device_ptr;
if (strstr(path, ".cgp"))
{
if (!load_preset(path))
return false;
}
else
{
if (!load_plain(path))
return false;
}
set_program_attributes(0);
active_index = 0;
hlsl_active = true;
return true;
}
static bool hlsl_init(void *data, const char *path)
{
d3d_video_t *d3d = (d3d_video_t*)data;
if (path && strcmp(path_get_extension(path), ".cgp") == 0)
{
if (!load_preset(d3d, path))
return false;
}
else
{
if (!load_plain(d3d, path))
return false;
}
for(unsigned i = 1; i <= cg_shader->passes; i++)
set_program_attributes(i);
d3d->dev->SetVertexShader(prg[1].vprg);
d3d->dev->SetPixelShader(prg[1].fprg);
hlsl_active = true;
return true;
}
static bool hlsl_init(void *data, const char *path)
{
d3d_video_t *d3d = (d3d_video_t*)data;
hlsl_shader_data_t *hlsl = (hlsl_shader_data_t*)
calloc(1, sizeof(hlsl_shader_data_t));
driver_t *driver = driver_get_ptr();
if (!hlsl)
return false;
if (path && !strcmp(path_get_extension(path), ".cgp"))
{
if (!load_preset(hlsl, d3d, path))
goto error;
}
else
{
if (!load_plain(hlsl, d3d, path))
goto error;
}
for(unsigned i = 1; i <= hlsl->cg_shader->passes; i++)
set_program_attributes(hlsl, i);
d3d_set_vertex_shader(d3d->dev, 1, hlsl->prg[1].vprg);
d3d->dev->SetPixelShader(hlsl->prg[1].fprg);
driver->video_shader_data = hlsl;
return true;
error:
if (hlsl)
free(hlsl);
return false;
}
static bool gl_cg_init(const char *path)
{
unsigned i;
#ifdef HAVE_CG_RUNTIME_COMPILER
cgRTCgcInit();
#endif
if (!cgCtx)
cgCtx = cgCreateContext();
if (cgCtx == NULL)
{
RARCH_ERR("Failed to create Cg context\n");
return false;
}
#ifdef RARCH_CG_DEBUG
cgGLSetDebugMode(CG_TRUE);
cgSetErrorHandler(cg_error_handler, NULL);
#endif
cgFProf = cgGLGetLatestProfile(CG_GL_FRAGMENT);
cgVProf = cgGLGetLatestProfile(CG_GL_VERTEX);
if (cgFProf == CG_PROFILE_UNKNOWN || cgVProf == CG_PROFILE_UNKNOWN)
{
RARCH_ERR("Invalid profile type\n");
goto error;
}
#ifndef HAVE_RGL
RARCH_LOG("[Cg]: Vertex profile: %s\n", cgGetProfileString(cgVProf));
RARCH_LOG("[Cg]: Fragment profile: %s\n", cgGetProfileString(cgFProf));
#endif
cgGLSetOptimalOptions(cgFProf);
cgGLSetOptimalOptions(cgVProf);
cgGLEnableProfile(cgFProf);
cgGLEnableProfile(cgVProf);
if (path && strcmp(path_get_extension(path), "cgp") == 0)
{
if (!load_preset(path))
goto error;
}
else
{
if (!load_plain(path))
goto error;
}
prg[0].mvp = cgGetNamedParameter(prg[0].vprg, "IN.mvp_matrix");
for (i = 1; i <= cg_shader->passes; i++)
set_program_attributes(i);
// If we aren't using last pass non-FBO shader,
// this shader will be assumed to be "fixed-function".
// Just use prg[0] for that pass, which will be
// pass-through.
prg[cg_shader->passes + 1] = prg[0];
// No need to apply Android hack in Cg.
prg[GL_SHADER_STOCK_BLEND] = prg[0];
cgGLBindProgram(prg[1].fprg);
cgGLBindProgram(prg[1].vprg);
cg_active = true;
return true;
error:
gl_cg_deinit();
return false;
}
static bool gl_cg_init(void *data, const char *path)
{
cg_shader_data_t *cg = NULL;
driver_t *driver = NULL;
unsigned i;
(void)data;
cg = (cg_shader_data_t*)calloc(1, sizeof(cg_shader_data_t));
driver = driver_get_ptr();
if (!cg)
return false;
#ifdef HAVE_CG_RUNTIME_COMPILER
cgRTCgcInit();
#endif
cg->cgCtx = cgCreateContext();
if (!cg->cgCtx)
{
RARCH_ERR("Failed to create Cg context\n");
free(cg);
return false;
}
#ifdef RARCH_CG_DEBUG
cgGLSetDebugMode(CG_TRUE);
cgSetErrorHandler(cg_error_handler, NULL);
#endif
cg->cgFProf = cgGLGetLatestProfile(CG_GL_FRAGMENT);
cg->cgVProf = cgGLGetLatestProfile(CG_GL_VERTEX);
if (
cg->cgFProf == CG_PROFILE_UNKNOWN ||
cg->cgVProf == CG_PROFILE_UNKNOWN)
{
RARCH_ERR("Invalid profile type\n");
free(cg);
goto error;
}
RARCH_LOG("[Cg]: Vertex profile: %s\n", cgGetProfileString(cg->cgVProf));
RARCH_LOG("[Cg]: Fragment profile: %s\n", cgGetProfileString(cg->cgFProf));
cgGLSetOptimalOptions(cg->cgFProf);
cgGLSetOptimalOptions(cg->cgVProf);
cgGLEnableProfile(cg->cgFProf);
cgGLEnableProfile(cg->cgVProf);
memset(cg->cg_alias_define, 0, sizeof(cg->cg_alias_define));
if (path && !strcmp(path_get_extension(path), "cgp"))
{
if (!load_preset(cg, path))
goto error;
}
else
{
if (!load_plain(cg, path))
goto error;
}
cg->prg[0].mvp = cgGetNamedParameter(cg->prg[0].vprg, "IN.mvp_matrix");
for (i = 1; i <= cg->shader->passes; i++)
set_program_attributes(cg, i);
/* If we aren't using last pass non-FBO shader,
* this shader will be assumed to be "fixed-function".
*
* Just use prg[0] for that pass, which will be
* pass-through. */
cg->prg[cg->shader->passes + 1] = cg->prg[0];
/* No need to apply Android hack in Cg. */
cg->prg[GL_SHADER_STOCK_BLEND] = cg->prg[0];
cgGLBindProgram(cg->prg[1].fprg);
cgGLBindProgram(cg->prg[1].vprg);
driver->video_shader_data = cg;
return true;
error:
gl_cg_destroy_resources(cg);
if (!cg)
free(cg);
return false;
}
