gtkradiant/plugins/model/miscmodel.cpp
TTimo 8037810110 transfer from internal tree r5311 branches/1.4-gpl
git-svn-id: svn://svn.icculus.org/gtkradiant/GtkRadiant/branches/ZeroRadiant@177 8a3a26a2-13c4-0310-b231-cf6edde360e5
2007-09-12 18:54:28 +00:00

451 lines
11 KiB
C++

/*
Copyright (C) 1999-2007 id Software, Inc. and contributors.
For a list of contributors, see the accompanying CONTRIBUTORS file.
This file is part of GtkRadiant.
GtkRadiant 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.
GtkRadiant 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 GtkRadiant; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <stdlib.h>
#include "entitymodel.h"
extern CModelManager g_model_cache;
//
// CEntityMiscModel implementation
//
CEntityMiscModel::CEntityMiscModel ()
{
refCount = 1;
m_name = NULL;
m_model = NULL;
m_entity = NULL;
m_frame = 0;
m_remaps = g_ptr_array_new ();
m_shaders = g_ptr_array_new ();
VectorSet(m_translate, 0,0,0);
VectorSet(m_euler, 0,0,0);
VectorSet(m_scale, 1,1,1);
VectorSet(m_pivot, 0,0,0);
m4x4_identity(m_transform);
m4x4_identity(m_inverse_transform);
}
typedef struct remap_s {
char m_key[64];
char m_remapbuff[64+1024];
char *m_remap[2];
} remap_t;
CEntityMiscModel::~CEntityMiscModel ()
{
unsigned int i;
if(m_name && *m_name != '\0') {
if( !g_model_cache.DeleteByNameAndFrame(m_name,m_frame) && m_model )
m_model->RemoveParent( this );
m_model = NULL;
delete [] m_name;
}
for( i = 0; i < m_remaps->len; i++ )
delete (remap_t*)m_remaps->pdata[i];
g_ptr_array_free(m_remaps, FALSE);
for( i = 0; i < m_shaders->len; i++ )
{
(*(IShader**)m_shaders->pdata[i])->DecRef();
delete (IShader**)m_shaders->pdata[i];
}
g_ptr_array_free(m_shaders, FALSE);
if(m_entity) {
// This might be just an evasion of the actual problem
m_entity->model.pRender = NULL;
m_entity->model.pSelect = NULL;
m_entity->model.pEdit = NULL;
}
}
// IRender
void CEntityMiscModel::Draw(int state, int rflags) const
{
m4x4_t matrix;
vec3_t pivot;
memcpy(matrix, m_transform, sizeof(m4x4_t));
m4x4_transpose(matrix);
VectorAdd(m_pivot, m_translate, pivot);
pivot_draw(pivot);
// push the current modelview matrix
// FIXME: put in a check for stack recursion depth..
// or avoid recursion of opengl matrix stack
g_QglTable.m_pfn_qglPushMatrix();
// apply the parent-to-local transform
g_QglTable.m_pfn_qglMultMatrixf(matrix);
// draw children
if(m_model)
m_model->Draw(state, m_shaders, rflags);
g_QglTable.m_pfn_qglPopMatrix();
}
// ISelect
bool CEntityMiscModel::TestRay(const ray_t *ray, vec_t *dist) const
{
vec_t dist_start = *dist;
vec_t dist_local = *dist;
ray_t ray_local = *ray;
if (!aabb_intersect_ray(&m_BBox, &ray_local, &dist_local))
return false;
if(m_model){
ray_transform(&ray_local, m_inverse_transform);
dist_local = dist_start;
if(m_model->TestRay(&ray_local, &dist_local))
*dist = dist_local;
} else *dist = dist_local;
return *dist < dist_start;
}
//IEdit
void CEntityMiscModel::Translate(const vec3_t translation)
{
VectorIncrement(translation, m_translate);
UpdateCachedData();
}
void CEntityMiscModel::Rotate(const vec3_t pivot, const vec3_t rotation)
{
m4x4_t rotation_matrix;
m4x4_identity(rotation_matrix);
m4x4_pivoted_rotate_by_vec3(rotation_matrix, rotation, pivot);
m4x4_transform_point(rotation_matrix, m_translate);
VectorIncrement(rotation, m_euler);
UpdateCachedData();
}
void CEntityMiscModel::OnKeyChanged(entity_t *e, const char *key)
{
const char *value;
// FIXME: keys are case-sensitive?
m_entity = e;
if(strcmp(key,"model") == 0)
SetName(ValueForKey(e,"model"));
else if(strcmp(key,"_frame") == 0)
SetFrame(IntForKey(e,"_frame"));
else if(strcmp(key,"angle") == 0 || strcmp(key,"angles") == 0)
{
VectorSet(m_euler, 0.f, 0.f, 0.f);
m_euler[2] = FloatForKey(e,"angle");
value = ValueForKey(e,"angles");
if (value[0] != '\0')
sscanf (value, "%f %f %f", &m_euler[0], &m_euler[2], &m_euler[1]);
UpdateCachedData();
}
else if(strcmp(key,"modelscale") == 0 || strcmp(key,"modelscale_vec") == 0)
{
VectorSet(m_scale, 1.f, 1.f, 1.f);
value = ValueForKey(e,"modelscale");
if (value[0] != '\0')
{
float f = atof(value);
if( f != 0 )
VectorSet(m_scale, f, f, f);
else
Sys_FPrintf(SYS_WRN, "WARNING: ignoring 0 modelscale key\n");
}
value = ValueForKey(e,"modelscale_vec");
if (value[0] != '\0')
{
sscanf (value, "%f %f %f", &m_scale[0], &m_scale[1], &m_scale[2]);
if (m_scale[0] == 0.0 && m_scale[1] == 0.0 && m_scale[2] == 0.0)
{
VectorSet(m_scale, 1,1,1);
Sys_FPrintf(SYS_WRN, "WARNING: ignoring 0 0 0 modelscale_vec key\n");
}
}
UpdateCachedData();
}
else if(strcmp(key,"origin") == 0)
{
value = ValueForKey(e,"origin");
sscanf(value, "%f %f %f", &m_translate[0], &m_translate[1], &m_translate[2]);
UpdateCachedData();
}
else if(strncmp(key,"_remap",6) == 0)
{
unsigned int i;
remap_t *pRemap;
char *ch;
value = ValueForKey(e,key);
for(i=0; i<m_remaps->len; i++)
{
pRemap = (remap_t*)m_remaps->pdata[i];
if(strcmp(key,pRemap->m_key) == 0)
break;
}
if( i == m_remaps->len )
{
if( value[0] == '\0' )
return;
pRemap = new remap_t;
g_ptr_array_add(m_remaps, pRemap);
}
else if( value[0] == '\0' )
{
g_ptr_array_remove_index_fast(m_remaps, i);
delete pRemap;
UpdateShaders();
return;
}
strncpy(pRemap->m_remapbuff,value,sizeof(pRemap->m_remapbuff));
strncpy(pRemap->m_key,key,sizeof(pRemap->m_key));
pRemap->m_remap[0] = ch = pRemap->m_remapbuff;
while( *ch && *ch != ';' )
ch++;
if( *ch == '\0' )
{
// bad remap
Sys_FPrintf(SYS_WRN, "WARNING: Shader _remap key found in misc_model without a ; character\n" );
g_ptr_array_remove_index_fast(m_remaps, i);
delete pRemap;
return;
}
else
{
*ch = '\0';
pRemap->m_remap[1] = ch + 1;
}
UpdateShaders();
}
}
//
// CEntityMiscModel
//
// private:
void CEntityMiscModel::SetName(const char *name)
{
if(m_name && *m_name != '\0') {
if(strcmp(m_name, name) == 0)
return;
if( !g_model_cache.DeleteByNameAndFrame(m_name,m_frame) && m_model )
m_model->RemoveParent( this );
delete [] m_name;
}
m_model = NULL;
m_name = new char[strlen(name)+1];
strcpy(m_name,name);
if(*m_name != '\0') {
m_model = g_model_cache.GetByNameAndFrame(m_name, m_frame);
m_model->AddParent( this );
}
UpdateCachedData();
UpdateShaders();
}
void CEntityMiscModel::SetFrame(const int frame)
{
if( m_frame == frame )
return;
if(m_name && *m_name != '\0') {
if( !g_model_cache.DeleteByNameAndFrame(m_name,m_frame) && m_model )
m_model->RemoveParent( this );
}
m_model = NULL;
m_frame = frame;
if(*m_name != '\0') {
m_model = g_model_cache.GetByNameAndFrame(m_name, m_frame);
m_model->AddParent( this );
}
UpdateCachedData();
}
void CEntityMiscModel::UpdateCachedData()
{
aabb_t aabb_temp;
bbox_t bbox_temp;
m4x4_identity(m_transform);
m4x4_pivoted_transform_by_vec3(m_transform, m_translate, m_euler, m_scale, m_pivot);
memcpy(m_inverse_transform, m_transform, sizeof(m4x4_t));
if(m4x4_invert(m_inverse_transform) == 1) {
Sys_Printf("ERROR: Singular Matrix, cannot invert");
}
aabb_clear(&aabb_temp);
if(m_model)
aabb_extend_by_aabb(&aabb_temp, m_model->GetAABB());
else
{
if (m_entity->eclass)
VectorSet(aabb_temp.extents, m_entity->eclass->maxs[0], m_entity->eclass->maxs[1], m_entity->eclass->maxs[2]);
else
VectorSet(aabb_temp.extents, 8, 8, 8);
}
// create an oriented BBox in world-space
bbox_for_oriented_aabb(&bbox_temp, &aabb_temp, m_transform, m_euler, m_scale);
// create an axis aligned bbox in world-space
aabb_for_bbox(&m_BBox, &bbox_temp);
aabb_update_radius(&m_BBox);
}
void CEntityMiscModel::UpdateShaders()
{
unsigned int i, j, numSurfaces;
remap_t *pRemap, *pGlobRemap = NULL;
char *surfShaderName;
IShader **pShader;
if( !m_model )
{
if( m_shaders->len )
{
// free our shaders
for( i = 0; i < m_shaders->len; i++ )
{
g_ptr_array_remove_index_fast(m_shaders, i);
(*(IShader**)m_shaders->pdata[i])->DecRef();
delete (IShader**)m_shaders->pdata[i];
}
}
return;
}
numSurfaces = m_model->GetNumSurfaces();
if( numSurfaces < m_shaders->len )
{
// free unneeded shader pointers
for( i = m_shaders->len - 1; i >= numSurfaces; i-- )
{
g_ptr_array_remove_index_fast(m_shaders, i);
(*(IShader**)m_shaders->pdata[i])->DecRef();
delete (IShader**)m_shaders->pdata[i];
}
}
// now go through our surface and find our shaders, remap if needed
for( j = 0; j < numSurfaces; j++ )
{
surfShaderName = m_model->GetShaderNameForSurface(j);
if( j < m_shaders->len )
{
pShader = (IShader **)m_shaders->pdata[j];
}
else
{
pShader = new (IShader *);
*pShader = NULL;
g_ptr_array_add(m_shaders, pShader);
}
if( m_remaps->len )
{
for( i = 0; i < m_remaps->len; i++ )
{
pRemap = (remap_t*)m_remaps->pdata[i];
if( stricmp(pRemap->m_remap[0],surfShaderName) == 0 )
{
// only do the shader lookups if really needed
if( !(*pShader) || stricmp(pRemap->m_remap[1],(*pShader)->getName()) )
{
if( *pShader )
(*pShader)->DecRef();
*pShader = QERApp_Shader_ForName(pRemap->m_remap[1]);
}
pGlobRemap = NULL;
break;
}
else if( pRemap->m_remap[0][0] == '*' && pRemap->m_remap[0][1] == '\0' )
pGlobRemap = pRemap;
}
if( pGlobRemap )
{
if( !(*pShader) || stricmp(pGlobRemap->m_remap[1],(*pShader)->getName()) )
{
if( *pShader )
(*pShader)->DecRef();
*pShader = QERApp_Shader_ForName(pGlobRemap->m_remap[1]);
}
}
else if( i == m_remaps->len )
{
// Back to the default one, if needed
if( !(*pShader) || (stricmp(surfShaderName,(*pShader)->getName()) && !(surfShaderName[0] == '\0')) )
{
if( *pShader )
(*pShader)->DecRef();
*pShader = QERApp_Shader_ForName(surfShaderName);
}
}
}
else
{
// Model specified shader, if needed
if( !(*pShader) || (stricmp(surfShaderName,(*pShader)->getName()) && !(surfShaderName[0] == '\0')) )
{
if( *pShader )
(*pShader)->DecRef();
*pShader = QERApp_Shader_ForName(surfShaderName);
}
}
}
}