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blender-archive/source/gameengine/Ketsji/KX_PythonInit.cpp
Thomas Szepe fd22a92939 BGE: Add new world API KX_WorldInfo (KX_Scene) 
This Patch will add a the world API (mist, background, ambient)  to KX_WorldInfo.
The new API uses now attributes.

Reviewers: campbellbarton, moguri

Reviewed By: moguri

Subscribers: klauser, brecht

Differential Revision: https://developer.blender.org/D157
2015-03-24 00:23:40 +01:00

2779 lines
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/*
* ***** BEGIN GPL 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.
*
* 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, 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 LICENSE BLOCK *****
* Initialize Python thingies.
*/
/** \file gameengine/Ketsji/KX_PythonInit.cpp
* \ingroup ketsji
*/
#include "glew-mx.h"
#ifdef _MSC_VER
# pragma warning (disable:4786)
#endif
#ifdef WITH_PYTHON
# ifdef _POSIX_C_SOURCE
# undef _POSIX_C_SOURCE
# endif
# ifdef _XOPEN_SOURCE
# undef _XOPEN_SOURCE
# endif
# if defined(__sun) || defined(sun)
# if defined(_XPG4)
# undef _XPG4
# endif
# endif
# include <Python.h>
extern "C" {
# include "bpy_internal_import.h" /* from the blender python api, but we want to import text too! */
# include "py_capi_utils.h"
# include "mathutils.h" // 'mathutils' module copied here so the blenderlayer can use.
# include "bgl.h"
# include "blf_py_api.h"
# include "marshal.h" /* python header for loading/saving dicts */
}
#include "AUD_PyInit.h"
#endif /* WITH_PYTHON */
#include "KX_PythonInit.h"
// directory header for py function getBlendFileList
#ifndef WIN32
# include <dirent.h>
# include <stdlib.h>
#else
# include <io.h>
# include "BLI_winstuff.h"
#endif
//python physics binding
#include "KX_PyConstraintBinding.h"
#include "KX_KetsjiEngine.h"
#include "KX_RadarSensor.h"
#include "KX_RaySensor.h"
#include "KX_ArmatureSensor.h"
#include "KX_SceneActuator.h"
#include "KX_GameActuator.h"
#include "KX_ParentActuator.h"
#include "KX_SCA_DynamicActuator.h"
#include "KX_SteeringActuator.h"
#include "KX_NavMeshObject.h"
#include "KX_MouseActuator.h"
#include "KX_TrackToActuator.h"
#include "SCA_IInputDevice.h"
#include "SCA_PropertySensor.h"
#include "SCA_RandomActuator.h"
#include "SCA_KeyboardSensor.h" /* IsPrintable, ToCharacter */
#include "SCA_JoystickManager.h" /* JOYINDEX_MAX */
#include "SCA_PythonJoystick.h"
#include "SCA_PythonKeyboard.h"
#include "SCA_PythonMouse.h"
#include "KX_ConstraintActuator.h"
#include "KX_IpoActuator.h"
#include "KX_SoundActuator.h"
#include "KX_StateActuator.h"
#include "BL_ActionActuator.h"
#include "BL_ArmatureObject.h"
#include "RAS_IRasterizer.h"
#include "RAS_ICanvas.h"
#include "RAS_BucketManager.h"
#include "RAS_2DFilterManager.h"
#include "MT_Vector3.h"
#include "MT_Point3.h"
#include "ListValue.h"
#include "InputParser.h"
#include "KX_Scene.h"
#include "NG_NetworkScene.h" //Needed for sendMessage()
#include "BL_Shader.h"
#include "BL_Action.h"
#include "KX_PyMath.h"
#include "PyObjectPlus.h"
#include "KX_PythonInitTypes.h"
/* we only need this to get a list of libraries from the main struct */
#include "DNA_ID.h"
#include "DNA_scene_types.h"
#include "PHY_IPhysicsEnvironment.h"
extern "C" {
#include "BKE_main.h"
#include "BKE_global.h"
#include "BKE_library.h"
#include "BKE_appdir.h"
#include "BLI_blenlib.h"
#include "GPU_material.h"
#include "MEM_guardedalloc.h"
}
/* for converting new scenes */
#include "KX_BlenderSceneConverter.h"
#include "KX_LibLoadStatus.h"
#include "KX_MeshProxy.h" /* for creating a new library of mesh objects */
extern "C" {
#include "BKE_idcode.h"
}
// 'local' copy of canvas ptr, for window height/width python scripts
#ifdef WITH_PYTHON
static RAS_ICanvas* gp_Canvas = NULL;
static char gp_GamePythonPath[FILE_MAX] = "";
static char gp_GamePythonPathOrig[FILE_MAX] = ""; // not super happy about this, but we need to remember the first loaded file for the global/dict load save
static SCA_PythonKeyboard* gp_PythonKeyboard = NULL;
static SCA_PythonMouse* gp_PythonMouse = NULL;
static SCA_PythonJoystick* gp_PythonJoysticks[JOYINDEX_MAX] = {NULL};
#endif // WITH_PYTHON
static KX_Scene* gp_KetsjiScene = NULL;
static KX_KetsjiEngine* gp_KetsjiEngine = NULL;
static RAS_IRasterizer* gp_Rasterizer = NULL;
void KX_SetActiveScene(class KX_Scene* scene)
{
gp_KetsjiScene = scene;
}
class KX_Scene* KX_GetActiveScene()
{
return gp_KetsjiScene;
}
class KX_KetsjiEngine* KX_GetActiveEngine()
{
return gp_KetsjiEngine;
}
/* why is this in python? */
void KX_RasterizerDrawDebugLine(const MT_Vector3& from,const MT_Vector3& to,const MT_Vector3& color)
{
if (gp_Rasterizer)
gp_Rasterizer->DrawDebugLine(from,to,color);
}
void KX_RasterizerDrawDebugCircle(const MT_Vector3& center, const MT_Scalar radius, const MT_Vector3& color,
const MT_Vector3& normal, int nsector)
{
if (gp_Rasterizer)
gp_Rasterizer->DrawDebugCircle(center, radius, color, normal, nsector);
}
#ifdef WITH_PYTHON
static PyObject *gp_OrigPythonSysPath= NULL;
static PyObject *gp_OrigPythonSysModules= NULL;
/* Macro for building the keyboard translation */
//#define KX_MACRO_addToDict(dict, name) PyDict_SetItemString(dict, #name, PyLong_FromLong(SCA_IInputDevice::KX_##name))
//#define KX_MACRO_addToDict(dict, name) PyDict_SetItemString(dict, #name, item=PyLong_FromLong(name)); Py_DECREF(item)
/* For the defines for types from logic bricks, we do stuff explicitly... */
#define KX_MACRO_addTypesToDict(dict, name, value) KX_MACRO_addTypesToDict_fn(dict, #name, value)
static void KX_MACRO_addTypesToDict_fn(PyObject *dict, const char *name, long value)
{
PyObject *item;
item = PyLong_FromLong(value);
PyDict_SetItemString(dict, name, item);
Py_DECREF(item);
}
// temporarily python stuff, will be put in another place later !
#include "KX_Python.h"
#include "SCA_PythonController.h"
// List of methods defined in the module
static PyObject *ErrorObject;
PyDoc_STRVAR(gPyGetRandomFloat_doc,
"getRandomFloat()\n"
"returns a random floating point value in the range [0..1]"
);
static PyObject *gPyGetRandomFloat(PyObject *)
{
return PyFloat_FromDouble(MT_random());
}
static PyObject *gPySetGravity(PyObject *, PyObject *value)
{
MT_Vector3 vec;
if (!PyVecTo(value, vec))
return NULL;
if (gp_KetsjiScene)
gp_KetsjiScene->SetGravity(vec);
Py_RETURN_NONE;
}
PyDoc_STRVAR(gPyExpandPath_doc,
"expandPath(path)\n"
"Converts a blender internal path into a proper file system path.\n"
" path - the string path to convert.\n"
"Use / as directory separator in path\n"
"You can use '//' at the start of the string to define a relative path."
"Blender replaces that string by the directory of the current .blend or runtime file to make a full path name.\n"
"The function also converts the directory separator to the local file system format."
);
static PyObject *gPyExpandPath(PyObject *, PyObject *args)
{
char expanded[FILE_MAX];
char* filename;
if (!PyArg_ParseTuple(args,"s:ExpandPath",&filename))
return NULL;
BLI_strncpy(expanded, filename, FILE_MAX);
BLI_path_abs(expanded, gp_GamePythonPath);
return PyC_UnicodeFromByte(expanded);
}
PyDoc_STRVAR(gPyStartGame_doc,
"startGame(blend)\n"
"Loads the blend file"
);
static PyObject *gPyStartGame(PyObject *, PyObject *args)
{
char* blendfile;
if (!PyArg_ParseTuple(args, "s:startGame", &blendfile))
return NULL;
gp_KetsjiEngine->RequestExit(KX_EXIT_REQUEST_START_OTHER_GAME);
gp_KetsjiEngine->SetNameNextGame(blendfile);
Py_RETURN_NONE;
}
PyDoc_STRVAR(gPyEndGame_doc,
"endGame()\n"
"Ends the current game"
);
static PyObject *gPyEndGame(PyObject *)
{
gp_KetsjiEngine->RequestExit(KX_EXIT_REQUEST_QUIT_GAME);
//printf("%s\n", gp_GamePythonPath);
Py_RETURN_NONE;
}
PyDoc_STRVAR(gPyRestartGame_doc,
"restartGame()\n"
"Restarts the current game by reloading the .blend file"
);
static PyObject *gPyRestartGame(PyObject *)
{
gp_KetsjiEngine->RequestExit(KX_EXIT_REQUEST_RESTART_GAME);
gp_KetsjiEngine->SetNameNextGame(gp_GamePythonPath);
Py_RETURN_NONE;
}
PyDoc_STRVAR(gPySaveGlobalDict_doc,
"saveGlobalDict()\n"
"Saves bge.logic.globalDict to a file"
);
static PyObject *gPySaveGlobalDict(PyObject *)
{
char marshal_path[512];
char *marshal_buffer = NULL;
unsigned int marshal_length;
FILE *fp = NULL;
pathGamePythonConfig(marshal_path);
marshal_length = saveGamePythonConfig(&marshal_buffer);
if (marshal_length && marshal_buffer)
{
fp = fopen(marshal_path, "wb");
if (fp)
{
if (fwrite(marshal_buffer, 1, marshal_length, fp) != marshal_length)
printf("Warning: could not write marshal data\n");
fclose(fp);
} else {
printf("Warning: could not open marshal file\n");
}
} else {
printf("Warning: could not create marshal buffer\n");
}
if (marshal_buffer)
delete [] marshal_buffer;
Py_RETURN_NONE;
}
PyDoc_STRVAR(gPyLoadGlobalDict_doc,
"LoadGlobalDict()\n"
"Loads bge.logic.globalDict from a file"
);
static PyObject *gPyLoadGlobalDict(PyObject *)
{
char marshal_path[512];
char *marshal_buffer = NULL;
size_t marshal_length;
FILE *fp = NULL;
int result;
pathGamePythonConfig(marshal_path);
fp = fopen(marshal_path, "rb");
if (fp) {
// obtain file size:
fseek (fp, 0, SEEK_END);
marshal_length = (size_t)ftell(fp);
rewind(fp);
marshal_buffer = (char*)malloc (sizeof(char)*marshal_length);
result = fread(marshal_buffer, 1, marshal_length, fp);
if (result == marshal_length) {
loadGamePythonConfig(marshal_buffer, marshal_length);
} else {
printf("Warning: could not read all of '%s'\n", marshal_path);
}
free(marshal_buffer);
fclose(fp);
} else {
printf("Warning: could not open '%s'\n", marshal_path);
}
Py_RETURN_NONE;
}
PyDoc_STRVAR(gPyGetProfileInfo_doc,
"getProfileInfo()\n"
"returns a dictionary with profiling information"
);
static PyObject *gPyGetProfileInfo(PyObject *)
{
return gp_KetsjiEngine->GetPyProfileDict();
}
PyDoc_STRVAR(gPySendMessage_doc,
"sendMessage(subject, [body, to, from])\n"
"sends a message in same manner as a message actuator"
" subject = Subject of the message"
" body = Message body"
" to = Name of object to send the message to"
" from = Name of object to send the string from"
);
static PyObject *gPySendMessage(PyObject *, PyObject *args)
{
char* subject;
char* body = (char *)"";
char* to = (char *)"";
char* from = (char *)"";
if (!PyArg_ParseTuple(args, "s|sss:sendMessage", &subject, &body, &to, &from))
return NULL;
gp_KetsjiScene->GetNetworkScene()->SendMessage(to, from, subject, body);
Py_RETURN_NONE;
}
// this gets a pointer to an array filled with floats
static PyObject *gPyGetSpectrum(PyObject *)
{
PyObject *resultlist = PyList_New(512);
for (int index = 0; index < 512; index++)
{
PyList_SET_ITEM(resultlist, index, PyFloat_FromDouble(0.0));
}
return resultlist;
}
static PyObject *gPySetLogicTicRate(PyObject *, PyObject *args)
{
float ticrate;
if (!PyArg_ParseTuple(args, "f:setLogicTicRate", &ticrate))
return NULL;
KX_KetsjiEngine::SetTicRate(ticrate);
Py_RETURN_NONE;
}
static PyObject *gPyGetLogicTicRate(PyObject *)
{
return PyFloat_FromDouble(KX_KetsjiEngine::GetTicRate());
}
static PyObject *gPySetExitKey(PyObject *, PyObject *args)
{
short exitkey;
if (!PyArg_ParseTuple(args, "h:setExitKey", &exitkey))
return NULL;
KX_KetsjiEngine::SetExitKey(exitkey);
Py_RETURN_NONE;
}
static PyObject *gPyGetExitKey(PyObject *)
{
return PyLong_FromLong(KX_KetsjiEngine::GetExitKey());
}
static PyObject *gPySetMaxLogicFrame(PyObject *, PyObject *args)
{
int frame;
if (!PyArg_ParseTuple(args, "i:setMaxLogicFrame", &frame))
return NULL;
KX_KetsjiEngine::SetMaxLogicFrame(frame);
Py_RETURN_NONE;
}
static PyObject *gPyGetMaxLogicFrame(PyObject *)
{
return PyLong_FromLong(KX_KetsjiEngine::GetMaxLogicFrame());
}
static PyObject *gPySetMaxPhysicsFrame(PyObject *, PyObject *args)
{
int frame;
if (!PyArg_ParseTuple(args, "i:setMaxPhysicsFrame", &frame))
return NULL;
KX_KetsjiEngine::SetMaxPhysicsFrame(frame);
Py_RETURN_NONE;
}
static PyObject *gPyGetMaxPhysicsFrame(PyObject *)
{
return PyLong_FromLong(KX_KetsjiEngine::GetMaxPhysicsFrame());
}
static PyObject *gPySetPhysicsTicRate(PyObject *, PyObject *args)
{
float ticrate;
if (!PyArg_ParseTuple(args, "f:setPhysicsTicRate", &ticrate))
return NULL;
PHY_GetActiveEnvironment()->SetFixedTimeStep(true,ticrate);
Py_RETURN_NONE;
}
#if 0 // unused
static PyObject *gPySetPhysicsDebug(PyObject *, PyObject *args)
{
int debugMode;
if (!PyArg_ParseTuple(args, "i:setPhysicsDebug", &debugMode))
return NULL;
PHY_GetActiveEnvironment()->setDebugMode(debugMode);
Py_RETURN_NONE;
}
#endif
static PyObject *gPyGetPhysicsTicRate(PyObject *)
{
return PyFloat_FromDouble(PHY_GetActiveEnvironment()->GetFixedTimeStep());
}
static PyObject *gPyGetAverageFrameRate(PyObject *)
{
return PyFloat_FromDouble(KX_KetsjiEngine::GetAverageFrameRate());
}
static PyObject *gPyGetBlendFileList(PyObject *, PyObject *args)
{
char cpath[sizeof(gp_GamePythonPath)];
char *searchpath = NULL;
PyObject *list, *value;
DIR *dp;
struct dirent *dirp;
if (!PyArg_ParseTuple(args, "|s:getBlendFileList", &searchpath))
return NULL;
list = PyList_New(0);
if (searchpath) {
BLI_strncpy(cpath, searchpath, FILE_MAX);
BLI_path_abs(cpath, gp_GamePythonPath);
} else {
/* Get the dir only */
BLI_split_dir_part(gp_GamePythonPath, cpath, sizeof(cpath));
}
if ((dp = opendir(cpath)) == NULL) {
/* todo, show the errno, this shouldnt happen anyway if the blendfile is readable */
fprintf(stderr, "Could not read directory (%s) failed, code %d (%s)\n", cpath, errno, strerror(errno));
return list;
}
while ((dirp = readdir(dp)) != NULL) {
if (BLI_testextensie(dirp->d_name, ".blend")) {
value = PyC_UnicodeFromByte(dirp->d_name);
PyList_Append(list, value);
Py_DECREF(value);
}
}
closedir(dp);
return list;
}
PyDoc_STRVAR(gPyAddScene_doc,
"addScene(name, [overlay])\n"
"Adds a scene to the game engine.\n"
" name = Name of the scene\n"
" overlay = Overlay or underlay"
);
static PyObject *gPyAddScene(PyObject *, PyObject *args)
{
char* name;
int overlay = 1;
if (!PyArg_ParseTuple(args, "s|i:addScene", &name , &overlay))
return NULL;
gp_KetsjiEngine->ConvertAndAddScene(name, (overlay != 0));
Py_RETURN_NONE;
}
PyDoc_STRVAR(gPyGetCurrentScene_doc,
"getCurrentScene()\n"
"Gets a reference to the current scene."
);
static PyObject *gPyGetCurrentScene(PyObject *self)
{
return gp_KetsjiScene->GetProxy();
}
PyDoc_STRVAR(gPyGetSceneList_doc,
"getSceneList()\n"
"Return a list of converted scenes."
);
static PyObject *gPyGetSceneList(PyObject *self)
{
KX_KetsjiEngine* m_engine = KX_GetActiveEngine();
PyObject *list;
KX_SceneList* scenes = m_engine->CurrentScenes();
int numScenes = scenes->size();
int i;
list = PyList_New(numScenes);
for (i=0;i<numScenes;i++)
{
KX_Scene* scene = scenes->at(i);
PyList_SET_ITEM(list, i, scene->GetProxy());
}
return list;
}
static PyObject *pyPrintStats(PyObject *,PyObject *,PyObject *)
{
gp_KetsjiScene->GetSceneConverter()->PrintStats();
Py_RETURN_NONE;
}
static PyObject *pyPrintExt(PyObject *,PyObject *,PyObject *)
{
#define pprint(x) std::cout << x << std::endl;
bool count=0;
bool support=0;
pprint("Supported Extensions...");
pprint(" GL_ARB_shader_objects supported? "<< (GLEW_ARB_shader_objects?"yes.":"no."));
count = 1;
support= GLEW_ARB_vertex_shader;
pprint(" GL_ARB_vertex_shader supported? "<< (support?"yes.":"no."));
count = 1;
if (support) {
pprint(" ----------Details----------");
int max=0;
glGetIntegerv(GL_MAX_VERTEX_UNIFORM_COMPONENTS_ARB, (GLint*)&max);
pprint(" Max uniform components." << max);
glGetIntegerv(GL_MAX_VARYING_FLOATS_ARB, (GLint*)&max);
pprint(" Max varying floats." << max);
glGetIntegerv(GL_MAX_VERTEX_TEXTURE_IMAGE_UNITS_ARB, (GLint*)&max);
pprint(" Max vertex texture units." << max);
glGetIntegerv(GL_MAX_COMBINED_TEXTURE_IMAGE_UNITS_ARB, (GLint*)&max);
pprint(" Max combined texture units." << max);
pprint("");
}
support=GLEW_ARB_fragment_shader;
pprint(" GL_ARB_fragment_shader supported? "<< (support?"yes.":"no."));
count = 1;
if (support) {
pprint(" ----------Details----------");
int max=0;
glGetIntegerv(GL_MAX_FRAGMENT_UNIFORM_COMPONENTS_ARB, (GLint*)&max);
pprint(" Max uniform components." << max);
pprint("");
}
support = GLEW_ARB_texture_cube_map;
pprint(" GL_ARB_texture_cube_map supported? "<< (support?"yes.":"no."));
count = 1;
if (support) {
pprint(" ----------Details----------");
int size=0;
glGetIntegerv(GL_MAX_CUBE_MAP_TEXTURE_SIZE_ARB, (GLint*)&size);
pprint(" Max cubemap size." << size);
pprint("");
}
support = GLEW_ARB_multitexture;
count = 1;
pprint(" GL_ARB_multitexture supported? "<< (support?"yes.":"no."));
if (support) {
pprint(" ----------Details----------");
int units=0;
glGetIntegerv(GL_MAX_TEXTURE_UNITS_ARB, (GLint*)&units);
pprint(" Max texture units available. " << units);
pprint("");
}
pprint(" GL_ARB_texture_env_combine supported? "<< (GLEW_ARB_texture_env_combine?"yes.":"no."));
count = 1;
if (!count)
pprint("No extenstions are used in this build");
Py_RETURN_NONE;
}
static PyObject *gLibLoad(PyObject *, PyObject *args, PyObject *kwds)
{
KX_Scene *kx_scene= gp_KetsjiScene;
char *path;
char *group;
Py_buffer py_buffer;
py_buffer.buf = NULL;
char *err_str= NULL;
KX_LibLoadStatus *status = NULL;
short options=0;
int load_actions=0, verbose=0, load_scripts=1, async=0;
static const char *kwlist[] = {"path", "group", "buffer", "load_actions", "verbose", "load_scripts", "async", NULL};
if (!PyArg_ParseTupleAndKeywords(args, kwds, "ss|y*iiIi:LibLoad", const_cast<char**>(kwlist),
&path, &group, &py_buffer, &load_actions, &verbose, &load_scripts, &async))
return NULL;
/* setup options */
if (load_actions != 0)
options |= KX_BlenderSceneConverter::LIB_LOAD_LOAD_ACTIONS;
if (verbose != 0)
options |= KX_BlenderSceneConverter::LIB_LOAD_VERBOSE;
if (load_scripts != 0)
options |= KX_BlenderSceneConverter::LIB_LOAD_LOAD_SCRIPTS;
if (async != 0)
options |= KX_BlenderSceneConverter::LIB_LOAD_ASYNC;
if (!py_buffer.buf)
{
char abs_path[FILE_MAX];
// Make the path absolute
BLI_strncpy(abs_path, path, sizeof(abs_path));
BLI_path_abs(abs_path, gp_GamePythonPath);
if ((status=kx_scene->GetSceneConverter()->LinkBlendFilePath(abs_path, group, kx_scene, &err_str, options))) {
return status->GetProxy();
}
}
else
{
if ((status=kx_scene->GetSceneConverter()->LinkBlendFileMemory(py_buffer.buf, py_buffer.len, path, group, kx_scene, &err_str, options))) {
PyBuffer_Release(&py_buffer);
return status->GetProxy();
}
PyBuffer_Release(&py_buffer);
}
if (err_str) {
PyErr_SetString(PyExc_ValueError, err_str);
return NULL;
}
Py_RETURN_FALSE;
}
static PyObject *gLibNew(PyObject *, PyObject *args)
{
KX_Scene *kx_scene= gp_KetsjiScene;
char *path;
char *group;
const char *name;
PyObject *names;
int idcode;
if (!PyArg_ParseTuple(args,"ssO!:LibNew",&path, &group, &PyList_Type, &names))
return NULL;
if (kx_scene->GetSceneConverter()->GetMainDynamicPath(path))
{
PyErr_SetString(PyExc_KeyError, "the name of the path given exists");
return NULL;
}
idcode= BKE_idcode_from_name(group);
if (idcode==0) {
PyErr_Format(PyExc_ValueError, "invalid group given \"%s\"", group);
return NULL;
}
Main *maggie=BKE_main_new();
kx_scene->GetSceneConverter()->GetMainDynamic().push_back(maggie);
strncpy(maggie->name, path, sizeof(maggie->name)-1);
/* Copy the object into main */
if (idcode==ID_ME) {
PyObject *ret= PyList_New(0);
PyObject *item;
for (Py_ssize_t i= 0; i < PyList_GET_SIZE(names); i++) {
name= _PyUnicode_AsString(PyList_GET_ITEM(names, i));
if (name) {
RAS_MeshObject *meshobj= kx_scene->GetSceneConverter()->ConvertMeshSpecial(kx_scene, maggie, name);
if (meshobj) {
KX_MeshProxy* meshproxy = new KX_MeshProxy(meshobj);
item= meshproxy->NewProxy(true);
PyList_Append(ret, item);
Py_DECREF(item);
}
}
else {
PyErr_Clear(); /* wasnt a string, ignore for now */
}
}
return ret;
}
else {
PyErr_Format(PyExc_ValueError, "only \"Mesh\" group currently supported");
return NULL;
}
Py_RETURN_NONE;
}
static PyObject *gLibFree(PyObject *, PyObject *args)
{
KX_Scene *kx_scene= gp_KetsjiScene;
char *path;
if (!PyArg_ParseTuple(args,"s:LibFree",&path))
return NULL;
if (kx_scene->GetSceneConverter()->FreeBlendFile(path))
{
Py_RETURN_TRUE;
}
else {
Py_RETURN_FALSE;
}
}
static PyObject *gLibList(PyObject *, PyObject *args)
{
vector<Main*> &dynMaggie = gp_KetsjiScene->GetSceneConverter()->GetMainDynamic();
int i= 0;
PyObject *list= PyList_New(dynMaggie.size());
for (vector<Main*>::iterator it=dynMaggie.begin(); !(it==dynMaggie.end()); it++)
{
PyList_SET_ITEM(list, i++, PyUnicode_FromString( (*it)->name) );
}
return list;
}
struct PyNextFrameState pynextframestate;
static PyObject *gPyNextFrame(PyObject *)
{
if (pynextframestate.func == NULL) Py_RETURN_NONE;
if (pynextframestate.state == NULL) Py_RETURN_NONE; //should never happen; raise exception instead?
if (pynextframestate.func(pynextframestate.state)) //nonzero = stop
{
Py_RETURN_TRUE;
}
else // 0 = go on
{
Py_RETURN_FALSE;
}
}
static struct PyMethodDef game_methods[] = {
{"expandPath", (PyCFunction)gPyExpandPath, METH_VARARGS, (const char *)gPyExpandPath_doc},
{"startGame", (PyCFunction)gPyStartGame, METH_VARARGS, (const char *)gPyStartGame_doc},
{"endGame", (PyCFunction)gPyEndGame, METH_NOARGS, (const char *)gPyEndGame_doc},
{"restartGame", (PyCFunction)gPyRestartGame, METH_NOARGS, (const char *)gPyRestartGame_doc},
{"saveGlobalDict", (PyCFunction)gPySaveGlobalDict, METH_NOARGS, (const char *)gPySaveGlobalDict_doc},
{"loadGlobalDict", (PyCFunction)gPyLoadGlobalDict, METH_NOARGS, (const char *)gPyLoadGlobalDict_doc},
{"sendMessage", (PyCFunction)gPySendMessage, METH_VARARGS, (const char *)gPySendMessage_doc},
{"getCurrentController", (PyCFunction) SCA_PythonController::sPyGetCurrentController, METH_NOARGS, SCA_PythonController::sPyGetCurrentController__doc__},
{"getCurrentScene", (PyCFunction) gPyGetCurrentScene, METH_NOARGS, gPyGetCurrentScene_doc},
{"getSceneList", (PyCFunction) gPyGetSceneList, METH_NOARGS, (const char *)gPyGetSceneList_doc},
{"addScene", (PyCFunction)gPyAddScene, METH_VARARGS, (const char *)gPyAddScene_doc},
{"getRandomFloat",(PyCFunction) gPyGetRandomFloat, METH_NOARGS, (const char *)gPyGetRandomFloat_doc},
{"setGravity",(PyCFunction) gPySetGravity, METH_O, (const char *)"set Gravitation"},
{"getSpectrum",(PyCFunction) gPyGetSpectrum, METH_NOARGS, (const char *)"get audio spectrum"},
{"getMaxLogicFrame", (PyCFunction) gPyGetMaxLogicFrame, METH_NOARGS, (const char *)"Gets the max number of logic frame per render frame"},
{"setMaxLogicFrame", (PyCFunction) gPySetMaxLogicFrame, METH_VARARGS, (const char *)"Sets the max number of logic frame per render frame"},
{"getMaxPhysicsFrame", (PyCFunction) gPyGetMaxPhysicsFrame, METH_NOARGS, (const char *)"Gets the max number of physics frame per render frame"},
{"setMaxPhysicsFrame", (PyCFunction) gPySetMaxPhysicsFrame, METH_VARARGS, (const char *)"Sets the max number of physics farme per render frame"},
{"getLogicTicRate", (PyCFunction) gPyGetLogicTicRate, METH_NOARGS, (const char *)"Gets the logic tic rate"},
{"setLogicTicRate", (PyCFunction) gPySetLogicTicRate, METH_VARARGS, (const char *)"Sets the logic tic rate"},
{"getPhysicsTicRate", (PyCFunction) gPyGetPhysicsTicRate, METH_NOARGS, (const char *)"Gets the physics tic rate"},
{"setPhysicsTicRate", (PyCFunction) gPySetPhysicsTicRate, METH_VARARGS, (const char *)"Sets the physics tic rate"},
{"getExitKey", (PyCFunction) gPyGetExitKey, METH_NOARGS, (const char *)"Gets the key used to exit the game engine"},
{"setExitKey", (PyCFunction) gPySetExitKey, METH_VARARGS, (const char *)"Sets the key used to exit the game engine"},
{"getAverageFrameRate", (PyCFunction) gPyGetAverageFrameRate, METH_NOARGS, (const char *)"Gets the estimated average frame rate"},
{"getBlendFileList", (PyCFunction)gPyGetBlendFileList, METH_VARARGS, (const char *)"Gets a list of blend files in the same directory as the current blend file"},
{"PrintGLInfo", (PyCFunction)pyPrintExt, METH_NOARGS, (const char *)"Prints GL Extension Info"},
{"PrintMemInfo", (PyCFunction)pyPrintStats, METH_NOARGS, (const char *)"Print engine statistics"},
{"NextFrame", (PyCFunction)gPyNextFrame, METH_NOARGS, (const char *)"Render next frame (if Python has control)"},
{"getProfileInfo", (PyCFunction)gPyGetProfileInfo, METH_NOARGS, gPyGetProfileInfo_doc},
/* library functions */
{"LibLoad", (PyCFunction)gLibLoad, METH_VARARGS|METH_KEYWORDS, (const char *)""},
{"LibNew", (PyCFunction)gLibNew, METH_VARARGS, (const char *)""},
{"LibFree", (PyCFunction)gLibFree, METH_VARARGS, (const char *)""},
{"LibList", (PyCFunction)gLibList, METH_VARARGS, (const char *)""},
{NULL, (PyCFunction) NULL, 0, NULL }
};
static PyObject *gPyGetWindowHeight(PyObject *, PyObject *args)
{
return PyLong_FromLong((gp_Canvas ? gp_Canvas->GetHeight() : 0));
}
static PyObject *gPyGetWindowWidth(PyObject *, PyObject *args)
{
return PyLong_FromLong((gp_Canvas ? gp_Canvas->GetWidth() : 0));
}
// temporarility visibility thing, will be moved to rasterizer/renderer later
bool gUseVisibilityTemp = false;
static PyObject *gPyEnableVisibility(PyObject *, PyObject *args)
{
int visible;
if (!PyArg_ParseTuple(args,"i:enableVisibility",&visible))
return NULL;
gUseVisibilityTemp = (visible != 0);
Py_RETURN_NONE;
}
static PyObject *gPyShowMouse(PyObject *, PyObject *args)
{
int visible;
if (!PyArg_ParseTuple(args,"i:showMouse",&visible))
return NULL;
if (visible)
{
if (gp_Canvas)
gp_Canvas->SetMouseState(RAS_ICanvas::MOUSE_NORMAL);
} else
{
if (gp_Canvas)
gp_Canvas->SetMouseState(RAS_ICanvas::MOUSE_INVISIBLE);
}
Py_RETURN_NONE;
}
static PyObject *gPySetMousePosition(PyObject *, PyObject *args)
{
int x,y;
if (!PyArg_ParseTuple(args,"ii:setMousePosition",&x,&y))
return NULL;
if (gp_Canvas)
gp_Canvas->SetMousePosition(x,y);
Py_RETURN_NONE;
}
static PyObject *gPySetEyeSeparation(PyObject *, PyObject *args)
{
float sep;
if (!PyArg_ParseTuple(args, "f:setEyeSeparation", &sep))
return NULL;
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.setEyeSeparation(float), Rasterizer not available");
return NULL;
}
gp_Rasterizer->SetEyeSeparation(sep);
Py_RETURN_NONE;
}
static PyObject *gPyGetEyeSeparation(PyObject *)
{
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.getEyeSeparation(), Rasterizer not available");
return NULL;
}
return PyFloat_FromDouble(gp_Rasterizer->GetEyeSeparation());
}
static PyObject *gPySetFocalLength(PyObject *, PyObject *args)
{
float focus;
if (!PyArg_ParseTuple(args, "f:setFocalLength", &focus))
return NULL;
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.setFocalLength(float), Rasterizer not available");
return NULL;
}
gp_Rasterizer->SetFocalLength(focus);
Py_RETURN_NONE;
}
static PyObject *gPyGetFocalLength(PyObject *, PyObject *, PyObject *)
{
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.getFocalLength(), Rasterizer not available");
return NULL;
}
return PyFloat_FromDouble(gp_Rasterizer->GetFocalLength());
Py_RETURN_NONE;
}
static PyObject *gPyGetStereoEye(PyObject *, PyObject *, PyObject *)
{
int flag = RAS_IRasterizer::RAS_STEREO_LEFTEYE;
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.getStereoEye(), Rasterizer not available");
return NULL;
}
if (gp_Rasterizer->Stereo())
flag = gp_Rasterizer->GetEye();
return PyLong_FromLong(flag);
}
static PyObject *gPySetBackgroundColor(PyObject *, PyObject *value)
{
MT_Vector4 vec;
if (!PyVecTo(value, vec))
return NULL;
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.SetBackgroundColor(color), World not available");
return NULL;
}
ShowDeprecationWarning("setBackgroundColor()", "KX_WorldInfo.background_color");
wi->setBackColor((float)vec[0], (float)vec[1], (float)vec[2]);
Py_RETURN_NONE;
}
static PyObject *gPySetMistColor(PyObject *, PyObject *value)
{
MT_Vector3 vec;
if (!PyVecTo(value, vec))
return NULL;
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.setMistColor(color), World not available");
return NULL;
}
ShowDeprecationWarning("setMistColor()", "KX_WorldInfo.mist_color");
wi->setMistColor((float)vec[0], (float)vec[1], (float)vec[2]);
Py_RETURN_NONE;
}
static PyObject *gPyDisableMist(PyObject *)
{
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.DisableMist(), World not available");
return NULL;
}
ShowDeprecationWarning("DisableMist()", "KX_WorldInfo.mist_enable = False");
wi->setUseMist(false);
Py_RETURN_NONE;
}
static PyObject *gPySetUseMist(PyObject *, PyObject *args)
{
int enable;
if (!PyArg_ParseTuple(args,"i:setUseMist",&enable))
return NULL;
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.setUseMist(enable), World not available");
return NULL;
}
ShowDeprecationWarning("setUseMist()", "KX_WorldInfo.mist_enable");
wi->setUseMist(enable);
Py_RETURN_NONE;
}
static PyObject *gPySetMistType(PyObject *, PyObject *args)
{
short type;
if (!PyArg_ParseTuple(args,"i:setMistType",&type))
return NULL;
if (type < 0 || type > 2) {
PyErr_SetString(PyExc_ValueError, "Rasterizer.setMistType(int): Mist type is not known");
return NULL;
}
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.setMistType(int), World not available");
return NULL;
}
ShowDeprecationWarning("setMistType()", "KX_WorldInfo.mist_type");
wi->setMistType(type);
Py_RETURN_NONE;
}
static PyObject *gPySetMistStart(PyObject *, PyObject *args)
{
float miststart;
if (!PyArg_ParseTuple(args,"f:setMistStart",&miststart))
return NULL;
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.setMistStart(float), World not available");
return NULL;
}
ShowDeprecationWarning("setMistStart()", "KX_WorldInfo.mist_start");
wi->setMistStart(miststart);
Py_RETURN_NONE;
}
static PyObject *gPySetMistEnd(PyObject *, PyObject *args)
{
float mistdist;
if (!PyArg_ParseTuple(args,"f:setMistEnd",&mistdist))
return NULL;
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.setMistEnd(float), World not available");
return NULL;
}
ShowDeprecationWarning("setMistEnd()", "KX_WorldInfo.mist_distance");
wi->setMistDistance(mistdist);
Py_RETURN_NONE;
}
static PyObject *gPySetMistIntensity(PyObject *, PyObject *args)
{
float intensity;
if (!PyArg_ParseTuple(args,"f:setMistIntensity",&intensity))
return NULL;
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.setMistIntensity(float), World not available");
return NULL;
}
ShowDeprecationWarning("setMistIntensity()", "KX_WorldInfo.mist_intensity");
wi->setMistIntensity(intensity);
Py_RETURN_NONE;
}
static PyObject *gPySetAmbientColor(PyObject *, PyObject *value)
{
MT_Vector3 vec;
if (!PyVecTo(value, vec))
return NULL;
KX_WorldInfo *wi = gp_KetsjiScene->GetWorldInfo();
if (!wi->hasWorld()) {
PyErr_SetString(PyExc_RuntimeError, "bge.render.setAmbientColor(color), World not available");
return NULL;
}
ShowDeprecationWarning("setAmbientColor()", "KX_WorldInfo.ambient_color");
wi->setAmbientColor((float)vec[0], (float)vec[1], (float)vec[2]);
Py_RETURN_NONE;
}
static PyObject *gPyMakeScreenshot(PyObject *, PyObject *args)
{
char* filename;
if (!PyArg_ParseTuple(args,"s:makeScreenshot",&filename))
return NULL;
if (gp_Canvas)
{
gp_Canvas->MakeScreenShot(filename);
}
Py_RETURN_NONE;
}
static PyObject *gPyEnableMotionBlur(PyObject *, PyObject *args)
{
float motionblurvalue;
if (!PyArg_ParseTuple(args,"f:enableMotionBlur",&motionblurvalue))
return NULL;
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.enableMotionBlur(float), Rasterizer not available");
return NULL;
}
gp_Rasterizer->EnableMotionBlur(motionblurvalue);
Py_RETURN_NONE;
}
static PyObject *gPyDisableMotionBlur(PyObject *)
{
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.disableMotionBlur(), Rasterizer not available");
return NULL;
}
gp_Rasterizer->DisableMotionBlur();
Py_RETURN_NONE;
}
static int getGLSLSettingFlag(const char *setting)
{
if (strcmp(setting, "lights") == 0)
return GAME_GLSL_NO_LIGHTS;
else if (strcmp(setting, "shaders") == 0)
return GAME_GLSL_NO_SHADERS;
else if (strcmp(setting, "shadows") == 0)
return GAME_GLSL_NO_SHADOWS;
else if (strcmp(setting, "ramps") == 0)
return GAME_GLSL_NO_RAMPS;
else if (strcmp(setting, "nodes") == 0)
return GAME_GLSL_NO_NODES;
else if (strcmp(setting, "extra_textures") == 0)
return GAME_GLSL_NO_EXTRA_TEX;
else
return -1;
}
static PyObject *gPySetGLSLMaterialSetting(PyObject *,
PyObject *args,
PyObject *)
{
GlobalSettings *gs= gp_KetsjiEngine->GetGlobalSettings();
char *setting;
int enable, flag, sceneflag;
if (!PyArg_ParseTuple(args,"si:setGLSLMaterialSetting",&setting,&enable))
return NULL;
flag = getGLSLSettingFlag(setting);
if (flag == -1) {
PyErr_SetString(PyExc_ValueError, "Rasterizer.setGLSLMaterialSetting(string): glsl setting is not known");
return NULL;
}
sceneflag= gs->glslflag;
if (enable)
gs->glslflag &= ~flag;
else
gs->glslflag |= flag;
/* temporarily store the glsl settings in the scene for the GLSL materials */
GameData *gm= &(gp_KetsjiScene->GetBlenderScene()->gm);
gm->flag = gs->glslflag;
/* display lists and GLSL materials need to be remade */
if (sceneflag != gs->glslflag) {
GPU_materials_free();
if (gp_KetsjiEngine) {
KX_SceneList *scenes = gp_KetsjiEngine->CurrentScenes();
KX_SceneList::iterator it;
for (it=scenes->begin(); it!=scenes->end(); it++)
if ((*it)->GetBucketManager()) {
(*it)->GetBucketManager()->ReleaseDisplayLists();
(*it)->GetBucketManager()->ReleaseMaterials();
}
}
}
Py_RETURN_NONE;
}
static PyObject *gPyGetGLSLMaterialSetting(PyObject *,
PyObject *args,
PyObject *)
{
GlobalSettings *gs= gp_KetsjiEngine->GetGlobalSettings();
char *setting;
int enabled = 0, flag;
if (!PyArg_ParseTuple(args,"s:getGLSLMaterialSetting",&setting))
return NULL;
flag = getGLSLSettingFlag(setting);
if (flag == -1) {
PyErr_SetString(PyExc_ValueError, "Rasterizer.getGLSLMaterialSetting(string): glsl setting is not known");
return NULL;
}
enabled = ((gs->glslflag & flag) != 0);
return PyLong_FromLong(enabled);
}
#define KX_BLENDER_MULTITEX_MATERIAL 1
#define KX_BLENDER_GLSL_MATERIAL 2
static PyObject *gPySetMaterialType(PyObject *,
PyObject *args,
PyObject *)
{
GlobalSettings *gs= gp_KetsjiEngine->GetGlobalSettings();
int type;
if (!PyArg_ParseTuple(args,"i:setMaterialType",&type))
return NULL;
if (type == KX_BLENDER_GLSL_MATERIAL)
gs->matmode= GAME_MAT_GLSL;
else if (type == KX_BLENDER_MULTITEX_MATERIAL)
gs->matmode= GAME_MAT_MULTITEX;
else {
PyErr_SetString(PyExc_ValueError, "Rasterizer.setMaterialType(int): material type is not known");
return NULL;
}
Py_RETURN_NONE;
}
static PyObject *gPyGetMaterialType(PyObject *)
{
GlobalSettings *gs= gp_KetsjiEngine->GetGlobalSettings();
int flag;
if (gs->matmode == GAME_MAT_GLSL)
flag = KX_BLENDER_GLSL_MATERIAL;
else
flag = KX_BLENDER_MULTITEX_MATERIAL;
return PyLong_FromLong(flag);
}
static PyObject *gPySetAnisotropicFiltering(PyObject *, PyObject *args)
{
short level;
if (!PyArg_ParseTuple(args, "h:setAnisotropicFiltering", &level))
return NULL;
if (level != 1 && level != 2 && level != 4 && level != 8 && level != 16) {
PyErr_SetString(PyExc_ValueError, "Rasterizer.setAnisotropicFiltering(level): Expected value of 1, 2, 4, 8, or 16 for value");
return NULL;
}
gp_Rasterizer->SetAnisotropicFiltering(level);
Py_RETURN_NONE;
}
static PyObject *gPyGetAnisotropicFiltering(PyObject *, PyObject *args)
{
return PyLong_FromLong(gp_Rasterizer->GetAnisotropicFiltering());
}
static PyObject *gPyDrawLine(PyObject *, PyObject *args)
{
PyObject *ob_from;
PyObject *ob_to;
PyObject *ob_color;
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.drawLine(obFrom, obTo, color): Rasterizer not available");
return NULL;
}
if (!PyArg_ParseTuple(args,"OOO:drawLine",&ob_from,&ob_to,&ob_color))
return NULL;
MT_Vector3 from;
MT_Vector3 to;
MT_Vector3 color;
if (!PyVecTo(ob_from, from))
return NULL;
if (!PyVecTo(ob_to, to))
return NULL;
if (!PyVecTo(ob_color, color))
return NULL;
gp_Rasterizer->DrawDebugLine(from,to,color);
Py_RETURN_NONE;
}
static PyObject *gPySetWindowSize(PyObject *, PyObject *args)
{
int width, height;
if (!PyArg_ParseTuple(args, "ii:resize", &width, &height))
return NULL;
gp_Canvas->ResizeWindow(width, height);
Py_RETURN_NONE;
}
static PyObject *gPySetFullScreen(PyObject *, PyObject *value)
{
gp_Canvas->SetFullScreen(PyObject_IsTrue(value));
Py_RETURN_NONE;
}
static PyObject *gPyGetFullScreen(PyObject *)
{
return PyBool_FromLong(gp_Canvas->GetFullScreen());
}
static PyObject *gPySetMipmapping(PyObject *, PyObject *args)
{
int val = 0;
if (!PyArg_ParseTuple(args, "i:setMipmapping", &val))
return NULL;
if (val < 0 || val > RAS_IRasterizer::RAS_MIPMAP_MAX) {
PyErr_SetString(PyExc_ValueError, "Rasterizer.setMipmapping(val): invalid mipmaping option");
return NULL;
}
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.setMipmapping(val): Rasterizer not available");
return NULL;
}
gp_Rasterizer->SetMipmapping((RAS_IRasterizer::MipmapOption)val);
Py_RETURN_NONE;
}
static PyObject *gPyGetMipmapping(PyObject *)
{
if (!gp_Rasterizer) {
PyErr_SetString(PyExc_RuntimeError, "Rasterizer.getMipmapping(): Rasterizer not available");
return NULL;
}
return PyLong_FromLong(gp_Rasterizer->GetMipmapping());
}
static PyObject *gPySetVsync(PyObject *, PyObject *args)
{
int interval;
if (!PyArg_ParseTuple(args, "i:setVsync", &interval))
return NULL;
if (interval < 0 || interval > VSYNC_ADAPTIVE) {
PyErr_SetString(PyExc_ValueError, "Rasterizer.setVsync(value): value must be VSYNC_OFF, VSYNC_ON, or VSYNC_ADAPTIVE");
return NULL;
}
if (interval == VSYNC_ADAPTIVE)
interval = -1;
gp_Canvas->SetSwapInterval((interval == VSYNC_ON) ? 1 : 0);
Py_RETURN_NONE;
}
static PyObject *gPyGetVsync(PyObject *)
{
int interval = 0;
gp_Canvas->GetSwapInterval(interval);
return PyLong_FromLong(interval);
}
static PyObject *gPyShowFramerate(PyObject *, PyObject *args)
{
int visible;
if (!PyArg_ParseTuple(args,"i:showFramerate",&visible))
return NULL;
if (visible && gp_KetsjiEngine)
gp_KetsjiEngine->SetShowFramerate(true);
else
gp_KetsjiEngine->SetShowFramerate(false);
Py_RETURN_NONE;
}
static PyObject *gPyShowProfile(PyObject *, PyObject *args)
{
int visible;
if (!PyArg_ParseTuple(args,"i:showProfile",&visible))
return NULL;
if (visible && gp_KetsjiEngine)
gp_KetsjiEngine->SetShowProfile(true);
else
gp_KetsjiEngine->SetShowProfile(false);
Py_RETURN_NONE;
}
static PyObject *gPyShowProperties(PyObject *, PyObject *args)
{
int visible;
if (!PyArg_ParseTuple(args,"i:showProperties",&visible))
return NULL;
if (visible && gp_KetsjiEngine)
gp_KetsjiEngine->SetShowProperties(true);
else
gp_KetsjiEngine->SetShowProperties(false);
Py_RETURN_NONE;
}
static PyObject *gPyAutoDebugList(PyObject *, PyObject *args)
{
int add;
if (!PyArg_ParseTuple(args,"i:autoAddProperties",&add))
return NULL;
if (add && gp_KetsjiEngine)
gp_KetsjiEngine->SetAutoAddDebugProperties(true);
else
gp_KetsjiEngine->SetAutoAddDebugProperties(false);
Py_RETURN_NONE;
}
static PyObject *gPyClearDebugList(PyObject *)
{
if (gp_KetsjiScene)
gp_KetsjiScene->RemoveAllDebugProperties();
Py_RETURN_NONE;
}
PyDoc_STRVAR(Rasterizer_module_documentation,
"This is the Python API for the game engine of Rasterizer"
);
static struct PyMethodDef rasterizer_methods[] = {
{"getWindowWidth",(PyCFunction) gPyGetWindowWidth,
METH_VARARGS, "getWindowWidth doc"},
{"getWindowHeight",(PyCFunction) gPyGetWindowHeight,
METH_VARARGS, "getWindowHeight doc"},
{"makeScreenshot",(PyCFunction)gPyMakeScreenshot,
METH_VARARGS, "make Screenshot doc"},
{"enableVisibility",(PyCFunction) gPyEnableVisibility,
METH_VARARGS, "enableVisibility doc"},
{"showMouse",(PyCFunction) gPyShowMouse,
METH_VARARGS, "showMouse(bool visible)"},
{"setMousePosition",(PyCFunction) gPySetMousePosition,
METH_VARARGS, "setMousePosition(int x,int y)"},
{"setBackgroundColor",(PyCFunction)gPySetBackgroundColor,METH_O,"set Background Color (rgb)"},
{"setAmbientColor",(PyCFunction)gPySetAmbientColor,METH_O,"set Ambient Color (rgb)"},
{"disableMist",(PyCFunction)gPyDisableMist,METH_NOARGS,"turn off mist"},
{"setUseMist",(PyCFunction)gPySetUseMist,METH_VARARGS,"enable or disable mist"},
{"setMistColor",(PyCFunction)gPySetMistColor,METH_O,"set Mist Color (rgb)"},
{"setMistType",(PyCFunction)gPySetMistType,METH_VARARGS,"set mist type (short type)"},
{"setMistStart",(PyCFunction)gPySetMistStart,METH_VARARGS,"set Mist Start"},
{"setMistEnd",(PyCFunction)gPySetMistEnd,METH_VARARGS,"set Mist End"},
{"setMistIntensity",(PyCFunction)gPySetMistIntensity,METH_VARARGS,"set mist intensity (float intensity)"},
{"enableMotionBlur",(PyCFunction)gPyEnableMotionBlur,METH_VARARGS,"enable motion blur"},
{"disableMotionBlur",(PyCFunction)gPyDisableMotionBlur,METH_NOARGS,"disable motion blur"},
{"setEyeSeparation", (PyCFunction) gPySetEyeSeparation, METH_VARARGS, "set the eye separation for stereo mode"},
{"getEyeSeparation", (PyCFunction) gPyGetEyeSeparation, METH_NOARGS, "get the eye separation for stereo mode"},
{"setFocalLength", (PyCFunction) gPySetFocalLength, METH_VARARGS, "set the focal length for stereo mode"},
{"getFocalLength", (PyCFunction) gPyGetFocalLength, METH_VARARGS, "get the focal length for stereo mode"},
{"getStereoEye", (PyCFunction) gPyGetStereoEye, METH_VARARGS, "get the current stereoscopy eye being rendered"},
{"setMaterialMode",(PyCFunction) gPySetMaterialType,
METH_VARARGS, "set the material mode to use for OpenGL rendering"},
{"getMaterialMode",(PyCFunction) gPyGetMaterialType,
METH_NOARGS, "get the material mode being used for OpenGL rendering"},
{"setGLSLMaterialSetting",(PyCFunction) gPySetGLSLMaterialSetting,
METH_VARARGS, "set the state of a GLSL material setting"},
{"getGLSLMaterialSetting",(PyCFunction) gPyGetGLSLMaterialSetting,
METH_VARARGS, "get the state of a GLSL material setting"},
{"setAnisotropicFiltering", (PyCFunction) gPySetAnisotropicFiltering,
METH_VARARGS, "set the anisotropic filtering level (must be one of 1, 2, 4, 8, 16)"},
{"getAnisotropicFiltering", (PyCFunction) gPyGetAnisotropicFiltering,
METH_VARARGS, "get the anisotropic filtering level"},
{"drawLine", (PyCFunction) gPyDrawLine,
METH_VARARGS, "draw a line on the screen"},
{"setWindowSize", (PyCFunction) gPySetWindowSize, METH_VARARGS, ""},
{"setFullScreen", (PyCFunction) gPySetFullScreen, METH_O, ""},
{"getFullScreen", (PyCFunction) gPyGetFullScreen, METH_NOARGS, ""},
{"setMipmapping", (PyCFunction) gPySetMipmapping, METH_VARARGS, ""},
{"getMipmapping", (PyCFunction) gPyGetMipmapping, METH_NOARGS, ""},
{"setVsync", (PyCFunction) gPySetVsync, METH_VARARGS, ""},
{"getVsync", (PyCFunction) gPyGetVsync, METH_NOARGS, ""},
{"showFramerate",(PyCFunction) gPyShowFramerate, METH_VARARGS, "show or hide the framerate"},
{"showProfile",(PyCFunction) gPyShowProfile, METH_VARARGS, "show or hide the profile"},
{"showProperties",(PyCFunction) gPyShowProperties, METH_VARARGS, "show or hide the debug properties"},
{"autoDebugList",(PyCFunction) gPyAutoDebugList, METH_VARARGS, "enable or disable auto adding debug properties to the debug list"},
{"clearDebugList",(PyCFunction) gPyClearDebugList, METH_NOARGS, "clears the debug property list"},
{ NULL, (PyCFunction) NULL, 0, NULL }
};
PyDoc_STRVAR(GameLogic_module_documentation,
"This is the Python API for the game engine of bge.logic"
);
static struct PyModuleDef GameLogic_module_def = {
{}, /* m_base */
"GameLogic", /* m_name */
GameLogic_module_documentation, /* m_doc */
0, /* m_size */
game_methods, /* m_methods */
0, /* m_reload */
0, /* m_traverse */
0, /* m_clear */
0, /* m_free */
};
PyMODINIT_FUNC initGameLogicPythonBinding()
{
PyObject *m;
PyObject *d;
PyObject *item; /* temp PyObject *storage */
gUseVisibilityTemp=false;
PyObjectPlus::ClearDeprecationWarning(); /* Not that nice to call here but makes sure warnings are reset between loading scenes */
m = PyModule_Create(&GameLogic_module_def);
PyDict_SetItemString(PySys_GetObject("modules"), GameLogic_module_def.m_name, m);
// Add some symbolic constants to the module
d = PyModule_GetDict(m);
// can be overwritten later for gameEngine instances that can load new blend files and re-initialize this module
// for now its safe to make sure it exists for other areas such as the web plugin
PyDict_SetItemString(d, "globalDict", item=PyDict_New()); Py_DECREF(item);
// Add keyboard and mouse attributes to this module
MT_assert(!gp_PythonKeyboard);
gp_PythonKeyboard = new SCA_PythonKeyboard(gp_KetsjiEngine->GetKeyboardDevice());
PyDict_SetItemString(d, "keyboard", gp_PythonKeyboard->NewProxy(true));
MT_assert(!gp_PythonMouse);
gp_PythonMouse = new SCA_PythonMouse(gp_KetsjiEngine->GetMouseDevice(), gp_Canvas);
PyDict_SetItemString(d, "mouse", gp_PythonMouse->NewProxy(true));
PyObject* joylist = PyList_New(JOYINDEX_MAX);
for (int i=0; i<JOYINDEX_MAX; ++i) {
SCA_Joystick *joy = SCA_Joystick::GetInstance(i);
PyObject *item;
if (joy && joy->Connected()) {
gp_PythonJoysticks[i] = new SCA_PythonJoystick(joy);
item = gp_PythonJoysticks[i]->NewProxy(true);
}
else {
if (joy) {
joy->ReleaseInstance();
}
item = Py_None;
}
Py_INCREF(item);
PyList_SET_ITEM(joylist, i, item);
}
PyDict_SetItemString(d, "joysticks", joylist);
ErrorObject = PyUnicode_FromString("GameLogic.error");
PyDict_SetItemString(d, "error", ErrorObject);
Py_DECREF(ErrorObject);
// XXXX Add constants here
/* To use logic bricks, we need some sort of constants. Here, we associate */
/* constants and sumbolic names. Add them to dictionary d. */
/* 1. true and false: needed for everyone */
KX_MACRO_addTypesToDict(d, KX_TRUE, SCA_ILogicBrick::KX_TRUE);
KX_MACRO_addTypesToDict(d, KX_FALSE, SCA_ILogicBrick::KX_FALSE);
/* 2. Property sensor */
KX_MACRO_addTypesToDict(d, KX_PROPSENSOR_EQUAL, SCA_PropertySensor::KX_PROPSENSOR_EQUAL);
KX_MACRO_addTypesToDict(d, KX_PROPSENSOR_NOTEQUAL, SCA_PropertySensor::KX_PROPSENSOR_NOTEQUAL);
KX_MACRO_addTypesToDict(d, KX_PROPSENSOR_INTERVAL, SCA_PropertySensor::KX_PROPSENSOR_INTERVAL);
KX_MACRO_addTypesToDict(d, KX_PROPSENSOR_CHANGED, SCA_PropertySensor::KX_PROPSENSOR_CHANGED);
KX_MACRO_addTypesToDict(d, KX_PROPSENSOR_EXPRESSION, SCA_PropertySensor::KX_PROPSENSOR_EXPRESSION);
KX_MACRO_addTypesToDict(d, KX_PROPSENSOR_LESSTHAN, SCA_PropertySensor::KX_PROPSENSOR_LESSTHAN);
KX_MACRO_addTypesToDict(d, KX_PROPSENSOR_GREATERTHAN, SCA_PropertySensor::KX_PROPSENSOR_GREATERTHAN);
/* 3. Constraint actuator */
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_LOCX, KX_ConstraintActuator::KX_ACT_CONSTRAINT_LOCX);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_LOCY, KX_ConstraintActuator::KX_ACT_CONSTRAINT_LOCY);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_LOCZ, KX_ConstraintActuator::KX_ACT_CONSTRAINT_LOCZ);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_ROTX, KX_ConstraintActuator::KX_ACT_CONSTRAINT_ROTX);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_ROTY, KX_ConstraintActuator::KX_ACT_CONSTRAINT_ROTY);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_ROTZ, KX_ConstraintActuator::KX_ACT_CONSTRAINT_ROTZ);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DIRPX, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DIRPX);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DIRPY, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DIRPY);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DIRPZ, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DIRPZ);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DIRNX, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DIRNX);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DIRNY, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DIRNY);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DIRNZ, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DIRNZ);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_ORIX, KX_ConstraintActuator::KX_ACT_CONSTRAINT_ORIX);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_ORIY, KX_ConstraintActuator::KX_ACT_CONSTRAINT_ORIY);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_ORIZ, KX_ConstraintActuator::KX_ACT_CONSTRAINT_ORIZ);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_FHPX, KX_ConstraintActuator::KX_ACT_CONSTRAINT_FHPX);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_FHPY, KX_ConstraintActuator::KX_ACT_CONSTRAINT_FHPY);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_FHPZ, KX_ConstraintActuator::KX_ACT_CONSTRAINT_FHPZ);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_FHNX, KX_ConstraintActuator::KX_ACT_CONSTRAINT_FHNX);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_FHNY, KX_ConstraintActuator::KX_ACT_CONSTRAINT_FHNY);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_FHNZ, KX_ConstraintActuator::KX_ACT_CONSTRAINT_FHNZ);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_NORMAL, KX_ConstraintActuator::KX_ACT_CONSTRAINT_NORMAL);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_MATERIAL, KX_ConstraintActuator::KX_ACT_CONSTRAINT_MATERIAL);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_PERMANENT, KX_ConstraintActuator::KX_ACT_CONSTRAINT_PERMANENT);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DISTANCE, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DISTANCE);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_LOCAL, KX_ConstraintActuator::KX_ACT_CONSTRAINT_LOCAL);
KX_MACRO_addTypesToDict(d, KX_CONSTRAINTACT_DOROTFH, KX_ConstraintActuator::KX_ACT_CONSTRAINT_DOROTFH);
/* 4. Random distribution types */
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_BOOL_CONST, SCA_RandomActuator::KX_RANDOMACT_BOOL_CONST);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_BOOL_UNIFORM, SCA_RandomActuator::KX_RANDOMACT_BOOL_UNIFORM);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_BOOL_BERNOUILLI, SCA_RandomActuator::KX_RANDOMACT_BOOL_BERNOUILLI);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_INT_CONST, SCA_RandomActuator::KX_RANDOMACT_INT_CONST);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_INT_UNIFORM, SCA_RandomActuator::KX_RANDOMACT_INT_UNIFORM);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_INT_POISSON, SCA_RandomActuator::KX_RANDOMACT_INT_POISSON);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_FLOAT_CONST, SCA_RandomActuator::KX_RANDOMACT_FLOAT_CONST);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_FLOAT_UNIFORM, SCA_RandomActuator::KX_RANDOMACT_FLOAT_UNIFORM);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_FLOAT_NORMAL, SCA_RandomActuator::KX_RANDOMACT_FLOAT_NORMAL);
KX_MACRO_addTypesToDict(d, KX_RANDOMACT_FLOAT_NEGATIVE_EXPONENTIAL, SCA_RandomActuator::KX_RANDOMACT_FLOAT_NEGATIVE_EXPONENTIAL);
/* 5. Sound actuator */
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_PLAYSTOP, KX_SoundActuator::KX_SOUNDACT_PLAYSTOP);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_PLAYEND, KX_SoundActuator::KX_SOUNDACT_PLAYEND);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPSTOP, KX_SoundActuator::KX_SOUNDACT_LOOPSTOP);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPEND, KX_SoundActuator::KX_SOUNDACT_LOOPEND);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPBIDIRECTIONAL, KX_SoundActuator::KX_SOUNDACT_LOOPBIDIRECTIONAL);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPBIDIRECTIONAL_STOP, KX_SoundActuator::KX_SOUNDACT_LOOPBIDIRECTIONAL_STOP);
/* 6. Action actuator */
KX_MACRO_addTypesToDict(d, KX_ACTIONACT_PLAY, ACT_ACTION_PLAY);
KX_MACRO_addTypesToDict(d, KX_ACTIONACT_PINGPONG, ACT_ACTION_PINGPONG);
KX_MACRO_addTypesToDict(d, KX_ACTIONACT_FLIPPER, ACT_ACTION_FLIPPER);
KX_MACRO_addTypesToDict(d, KX_ACTIONACT_LOOPSTOP, ACT_ACTION_LOOP_STOP);
KX_MACRO_addTypesToDict(d, KX_ACTIONACT_LOOPEND, ACT_ACTION_LOOP_END);
KX_MACRO_addTypesToDict(d, KX_ACTIONACT_PROPERTY, ACT_ACTION_FROM_PROP);
/* 7. GL_BlendFunc */
KX_MACRO_addTypesToDict(d, BL_ZERO, GL_ZERO);
KX_MACRO_addTypesToDict(d, BL_ONE, GL_ONE);
KX_MACRO_addTypesToDict(d, BL_SRC_COLOR, GL_SRC_COLOR);
KX_MACRO_addTypesToDict(d, BL_ONE_MINUS_SRC_COLOR, GL_ONE_MINUS_SRC_COLOR);
KX_MACRO_addTypesToDict(d, BL_DST_COLOR, GL_DST_COLOR);
KX_MACRO_addTypesToDict(d, BL_ONE_MINUS_DST_COLOR, GL_ONE_MINUS_DST_COLOR);
KX_MACRO_addTypesToDict(d, BL_SRC_ALPHA, GL_SRC_ALPHA);
KX_MACRO_addTypesToDict(d, BL_ONE_MINUS_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
KX_MACRO_addTypesToDict(d, BL_DST_ALPHA, GL_DST_ALPHA);
KX_MACRO_addTypesToDict(d, BL_ONE_MINUS_DST_ALPHA, GL_ONE_MINUS_DST_ALPHA);
KX_MACRO_addTypesToDict(d, BL_SRC_ALPHA_SATURATE, GL_SRC_ALPHA_SATURATE);
/* 8. UniformTypes */
KX_MACRO_addTypesToDict(d, SHD_TANGENT, BL_Shader::SHD_TANGENT);
KX_MACRO_addTypesToDict(d, MODELVIEWMATRIX, BL_Shader::MODELVIEWMATRIX);
KX_MACRO_addTypesToDict(d, MODELVIEWMATRIX_TRANSPOSE, BL_Shader::MODELVIEWMATRIX_TRANSPOSE);
KX_MACRO_addTypesToDict(d, MODELVIEWMATRIX_INVERSE, BL_Shader::MODELVIEWMATRIX_INVERSE);
KX_MACRO_addTypesToDict(d, MODELVIEWMATRIX_INVERSETRANSPOSE, BL_Shader::MODELVIEWMATRIX_INVERSETRANSPOSE);
KX_MACRO_addTypesToDict(d, MODELMATRIX, BL_Shader::MODELMATRIX);
KX_MACRO_addTypesToDict(d, MODELMATRIX_TRANSPOSE, BL_Shader::MODELMATRIX_TRANSPOSE);
KX_MACRO_addTypesToDict(d, MODELMATRIX_INVERSE, BL_Shader::MODELMATRIX_INVERSE);
KX_MACRO_addTypesToDict(d, MODELMATRIX_INVERSETRANSPOSE, BL_Shader::MODELMATRIX_INVERSETRANSPOSE);
KX_MACRO_addTypesToDict(d, VIEWMATRIX, BL_Shader::VIEWMATRIX);
KX_MACRO_addTypesToDict(d, VIEWMATRIX_TRANSPOSE, BL_Shader::VIEWMATRIX_TRANSPOSE);
KX_MACRO_addTypesToDict(d, VIEWMATRIX_INVERSE, BL_Shader::VIEWMATRIX_INVERSE);
KX_MACRO_addTypesToDict(d, VIEWMATRIX_INVERSETRANSPOSE, BL_Shader::VIEWMATRIX_INVERSETRANSPOSE);
KX_MACRO_addTypesToDict(d, CAM_POS, BL_Shader::CAM_POS);
KX_MACRO_addTypesToDict(d, CONSTANT_TIMER, BL_Shader::CONSTANT_TIMER);
/* 9. state actuator */
KX_MACRO_addTypesToDict(d, KX_STATE1, (1<<0));
KX_MACRO_addTypesToDict(d, KX_STATE2, (1<<1));
KX_MACRO_addTypesToDict(d, KX_STATE3, (1<<2));
KX_MACRO_addTypesToDict(d, KX_STATE4, (1<<3));
KX_MACRO_addTypesToDict(d, KX_STATE5, (1<<4));
KX_MACRO_addTypesToDict(d, KX_STATE6, (1<<5));
KX_MACRO_addTypesToDict(d, KX_STATE7, (1<<6));
KX_MACRO_addTypesToDict(d, KX_STATE8, (1<<7));
KX_MACRO_addTypesToDict(d, KX_STATE9, (1<<8));
KX_MACRO_addTypesToDict(d, KX_STATE10, (1<<9));
KX_MACRO_addTypesToDict(d, KX_STATE11, (1<<10));
KX_MACRO_addTypesToDict(d, KX_STATE12, (1<<11));
KX_MACRO_addTypesToDict(d, KX_STATE13, (1<<12));
KX_MACRO_addTypesToDict(d, KX_STATE14, (1<<13));
KX_MACRO_addTypesToDict(d, KX_STATE15, (1<<14));
KX_MACRO_addTypesToDict(d, KX_STATE16, (1<<15));
KX_MACRO_addTypesToDict(d, KX_STATE17, (1<<16));
KX_MACRO_addTypesToDict(d, KX_STATE18, (1<<17));
KX_MACRO_addTypesToDict(d, KX_STATE19, (1<<18));
KX_MACRO_addTypesToDict(d, KX_STATE20, (1<<19));
KX_MACRO_addTypesToDict(d, KX_STATE21, (1<<20));
KX_MACRO_addTypesToDict(d, KX_STATE22, (1<<21));
KX_MACRO_addTypesToDict(d, KX_STATE23, (1<<22));
KX_MACRO_addTypesToDict(d, KX_STATE24, (1<<23));
KX_MACRO_addTypesToDict(d, KX_STATE25, (1<<24));
KX_MACRO_addTypesToDict(d, KX_STATE26, (1<<25));
KX_MACRO_addTypesToDict(d, KX_STATE27, (1<<26));
KX_MACRO_addTypesToDict(d, KX_STATE28, (1<<27));
KX_MACRO_addTypesToDict(d, KX_STATE29, (1<<28));
KX_MACRO_addTypesToDict(d, KX_STATE30, (1<<29));
/* All Sensors */
KX_MACRO_addTypesToDict(d, KX_SENSOR_JUST_ACTIVATED, SCA_ISensor::KX_SENSOR_JUST_ACTIVATED);
KX_MACRO_addTypesToDict(d, KX_SENSOR_ACTIVE, SCA_ISensor::KX_SENSOR_ACTIVE);
KX_MACRO_addTypesToDict(d, KX_SENSOR_JUST_DEACTIVATED, SCA_ISensor::KX_SENSOR_JUST_DEACTIVATED);
KX_MACRO_addTypesToDict(d, KX_SENSOR_INACTIVE, SCA_ISensor::KX_SENSOR_INACTIVE);
/* Radar Sensor */
KX_MACRO_addTypesToDict(d, KX_RADAR_AXIS_POS_X, KX_RadarSensor::KX_RADAR_AXIS_POS_X);
KX_MACRO_addTypesToDict(d, KX_RADAR_AXIS_POS_Y, KX_RadarSensor::KX_RADAR_AXIS_POS_Y);
KX_MACRO_addTypesToDict(d, KX_RADAR_AXIS_POS_Z, KX_RadarSensor::KX_RADAR_AXIS_POS_Z);
KX_MACRO_addTypesToDict(d, KX_RADAR_AXIS_NEG_X, KX_RadarSensor::KX_RADAR_AXIS_NEG_X);
KX_MACRO_addTypesToDict(d, KX_RADAR_AXIS_NEG_Y, KX_RadarSensor::KX_RADAR_AXIS_NEG_Y);
KX_MACRO_addTypesToDict(d, KX_RADAR_AXIS_NEG_Z, KX_RadarSensor::KX_RADAR_AXIS_NEG_Z);
/* Ray Sensor */
KX_MACRO_addTypesToDict(d, KX_RAY_AXIS_POS_X, KX_RaySensor::KX_RAY_AXIS_POS_X);
KX_MACRO_addTypesToDict(d, KX_RAY_AXIS_POS_Y, KX_RaySensor::KX_RAY_AXIS_POS_Y);
KX_MACRO_addTypesToDict(d, KX_RAY_AXIS_POS_Z, KX_RaySensor::KX_RAY_AXIS_POS_Z);
KX_MACRO_addTypesToDict(d, KX_RAY_AXIS_NEG_X, KX_RaySensor::KX_RAY_AXIS_NEG_X);
KX_MACRO_addTypesToDict(d, KX_RAY_AXIS_NEG_Y, KX_RaySensor::KX_RAY_AXIS_NEG_Y);
KX_MACRO_addTypesToDict(d, KX_RAY_AXIS_NEG_Z, KX_RaySensor::KX_RAY_AXIS_NEG_Z);
/* TrackTo Actuator */
KX_MACRO_addTypesToDict(d, KX_TRACK_UPAXIS_POS_X, KX_TrackToActuator::KX_TRACK_UPAXIS_POS_X);
KX_MACRO_addTypesToDict(d, KX_TRACK_UPAXIS_POS_Y, KX_TrackToActuator::KX_TRACK_UPAXIS_POS_Y);
KX_MACRO_addTypesToDict(d, KX_TRACK_UPAXIS_POS_Z, KX_TrackToActuator::KX_TRACK_UPAXIS_POS_Z);
KX_MACRO_addTypesToDict(d, KX_TRACK_TRAXIS_POS_X, KX_TrackToActuator::KX_TRACK_TRAXIS_POS_X);
KX_MACRO_addTypesToDict(d, KX_TRACK_TRAXIS_POS_Y, KX_TrackToActuator::KX_TRACK_TRAXIS_POS_Y);
KX_MACRO_addTypesToDict(d, KX_TRACK_TRAXIS_POS_Z, KX_TrackToActuator::KX_TRACK_TRAXIS_POS_Z);
KX_MACRO_addTypesToDict(d, KX_TRACK_TRAXIS_NEG_X, KX_TrackToActuator::KX_TRACK_TRAXIS_NEG_X);
KX_MACRO_addTypesToDict(d, KX_TRACK_TRAXIS_NEG_Y, KX_TrackToActuator::KX_TRACK_TRAXIS_NEG_Y);
KX_MACRO_addTypesToDict(d, KX_TRACK_TRAXIS_NEG_Z, KX_TrackToActuator::KX_TRACK_TRAXIS_NEG_Z);
/* Dynamic actuator */
KX_MACRO_addTypesToDict(d, KX_DYN_RESTORE_DYNAMICS, KX_SCA_DynamicActuator::KX_DYN_RESTORE_DYNAMICS);
KX_MACRO_addTypesToDict(d, KX_DYN_DISABLE_DYNAMICS, KX_SCA_DynamicActuator::KX_DYN_DISABLE_DYNAMICS);
KX_MACRO_addTypesToDict(d, KX_DYN_ENABLE_RIGID_BODY, KX_SCA_DynamicActuator::KX_DYN_ENABLE_RIGID_BODY);
KX_MACRO_addTypesToDict(d, KX_DYN_DISABLE_RIGID_BODY, KX_SCA_DynamicActuator::KX_DYN_DISABLE_RIGID_BODY);
KX_MACRO_addTypesToDict(d, KX_DYN_SET_MASS, KX_SCA_DynamicActuator::KX_DYN_SET_MASS);
/* Input & Mouse Sensor */
KX_MACRO_addTypesToDict(d, KX_INPUT_NONE, SCA_InputEvent::KX_NO_INPUTSTATUS);
KX_MACRO_addTypesToDict(d, KX_INPUT_JUST_ACTIVATED, SCA_InputEvent::KX_JUSTACTIVATED);
KX_MACRO_addTypesToDict(d, KX_INPUT_ACTIVE, SCA_InputEvent::KX_ACTIVE);
KX_MACRO_addTypesToDict(d, KX_INPUT_JUST_RELEASED, SCA_InputEvent::KX_JUSTRELEASED);
KX_MACRO_addTypesToDict(d, KX_MOUSE_BUT_LEFT, SCA_IInputDevice::KX_LEFTMOUSE);
KX_MACRO_addTypesToDict(d, KX_MOUSE_BUT_MIDDLE, SCA_IInputDevice::KX_MIDDLEMOUSE);
KX_MACRO_addTypesToDict(d, KX_MOUSE_BUT_RIGHT, SCA_IInputDevice::KX_RIGHTMOUSE);
/* 2D Filter Actuator */
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_ENABLED, RAS_2DFilterManager::RAS_2DFILTER_ENABLED);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_DISABLED, RAS_2DFilterManager::RAS_2DFILTER_DISABLED);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_NOFILTER, RAS_2DFilterManager::RAS_2DFILTER_NOFILTER);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_MOTIONBLUR, RAS_2DFilterManager::RAS_2DFILTER_MOTIONBLUR);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_BLUR, RAS_2DFilterManager::RAS_2DFILTER_BLUR);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_SHARPEN, RAS_2DFilterManager::RAS_2DFILTER_SHARPEN);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_DILATION, RAS_2DFilterManager::RAS_2DFILTER_DILATION);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_EROSION, RAS_2DFilterManager::RAS_2DFILTER_EROSION);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_LAPLACIAN, RAS_2DFilterManager::RAS_2DFILTER_LAPLACIAN);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_SOBEL, RAS_2DFilterManager::RAS_2DFILTER_SOBEL);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_PREWITT, RAS_2DFilterManager::RAS_2DFILTER_PREWITT);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_GRAYSCALE, RAS_2DFilterManager::RAS_2DFILTER_GRAYSCALE);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_SEPIA, RAS_2DFilterManager::RAS_2DFILTER_SEPIA);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_INVERT, RAS_2DFilterManager::RAS_2DFILTER_INVERT);
KX_MACRO_addTypesToDict(d, RAS_2DFILTER_CUSTOMFILTER, RAS_2DFilterManager::RAS_2DFILTER_CUSTOMFILTER);
/* Sound Actuator */
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_PLAYSTOP, KX_SoundActuator::KX_SOUNDACT_PLAYSTOP);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_PLAYEND, KX_SoundActuator::KX_SOUNDACT_PLAYEND);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPSTOP, KX_SoundActuator::KX_SOUNDACT_LOOPSTOP);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPEND, KX_SoundActuator:: KX_SOUNDACT_LOOPEND);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPBIDIRECTIONAL, KX_SoundActuator::KX_SOUNDACT_LOOPBIDIRECTIONAL);
KX_MACRO_addTypesToDict(d, KX_SOUNDACT_LOOPBIDIRECTIONAL_STOP, KX_SoundActuator::KX_SOUNDACT_LOOPBIDIRECTIONAL_STOP);
/* State Actuator */
KX_MACRO_addTypesToDict(d, KX_STATE_OP_CPY, KX_StateActuator::OP_CPY);
KX_MACRO_addTypesToDict(d, KX_STATE_OP_SET, KX_StateActuator::OP_SET);
KX_MACRO_addTypesToDict(d, KX_STATE_OP_CLR, KX_StateActuator::OP_CLR);
KX_MACRO_addTypesToDict(d, KX_STATE_OP_NEG, KX_StateActuator::OP_NEG);
/* Game Actuator Modes */
KX_MACRO_addTypesToDict(d, KX_GAME_LOAD, KX_GameActuator::KX_GAME_LOAD);
KX_MACRO_addTypesToDict(d, KX_GAME_START, KX_GameActuator::KX_GAME_START);
KX_MACRO_addTypesToDict(d, KX_GAME_RESTART, KX_GameActuator::KX_GAME_RESTART);
KX_MACRO_addTypesToDict(d, KX_GAME_QUIT, KX_GameActuator::KX_GAME_QUIT);
KX_MACRO_addTypesToDict(d, KX_GAME_SAVECFG, KX_GameActuator::KX_GAME_SAVECFG);
KX_MACRO_addTypesToDict(d, KX_GAME_LOADCFG, KX_GameActuator::KX_GAME_LOADCFG);
/* Scene Actuator Modes */
KX_MACRO_addTypesToDict(d, KX_SCENE_RESTART, KX_SceneActuator::KX_SCENE_RESTART);
KX_MACRO_addTypesToDict(d, KX_SCENE_SET_SCENE, KX_SceneActuator::KX_SCENE_SET_SCENE);
KX_MACRO_addTypesToDict(d, KX_SCENE_SET_CAMERA, KX_SceneActuator::KX_SCENE_SET_CAMERA);
KX_MACRO_addTypesToDict(d, KX_SCENE_ADD_FRONT_SCENE, KX_SceneActuator::KX_SCENE_ADD_FRONT_SCENE);
KX_MACRO_addTypesToDict(d, KX_SCENE_ADD_BACK_SCENE, KX_SceneActuator::KX_SCENE_ADD_BACK_SCENE);
KX_MACRO_addTypesToDict(d, KX_SCENE_REMOVE_SCENE, KX_SceneActuator::KX_SCENE_REMOVE_SCENE);
KX_MACRO_addTypesToDict(d, KX_SCENE_SUSPEND, KX_SceneActuator::KX_SCENE_SUSPEND);
KX_MACRO_addTypesToDict(d, KX_SCENE_RESUME, KX_SceneActuator::KX_SCENE_RESUME);
/* Parent Actuator Modes */
KX_MACRO_addTypesToDict(d, KX_PARENT_SET, KX_ParentActuator::KX_PARENT_SET);
KX_MACRO_addTypesToDict(d, KX_PARENT_REMOVE, KX_ParentActuator::KX_PARENT_REMOVE);
/* BL_ArmatureConstraint type */
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_TRACKTO, CONSTRAINT_TYPE_TRACKTO);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_KINEMATIC, CONSTRAINT_TYPE_KINEMATIC);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_ROTLIKE, CONSTRAINT_TYPE_ROTLIKE);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_LOCLIKE, CONSTRAINT_TYPE_LOCLIKE);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_MINMAX, CONSTRAINT_TYPE_MINMAX);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_SIZELIKE, CONSTRAINT_TYPE_SIZELIKE);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_LOCKTRACK, CONSTRAINT_TYPE_LOCKTRACK);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_STRETCHTO, CONSTRAINT_TYPE_STRETCHTO);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_CLAMPTO, CONSTRAINT_TYPE_CLAMPTO);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_TRANSFORM, CONSTRAINT_TYPE_TRANSFORM);
KX_MACRO_addTypesToDict(d, CONSTRAINT_TYPE_DISTLIMIT, CONSTRAINT_TYPE_DISTLIMIT);
/* BL_ArmatureConstraint ik_type */
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_COPYPOSE, CONSTRAINT_IK_COPYPOSE);
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_DISTANCE, CONSTRAINT_IK_DISTANCE);
/* BL_ArmatureConstraint ik_mode */
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_MODE_INSIDE, LIMITDIST_INSIDE);
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_MODE_OUTSIDE, LIMITDIST_OUTSIDE);
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_MODE_ONSURFACE, LIMITDIST_ONSURFACE);
/* BL_ArmatureConstraint ik_flag */
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_FLAG_TIP, CONSTRAINT_IK_TIP);
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_FLAG_ROT, CONSTRAINT_IK_ROT);
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_FLAG_STRETCH, CONSTRAINT_IK_STRETCH);
KX_MACRO_addTypesToDict(d, CONSTRAINT_IK_FLAG_POS, CONSTRAINT_IK_POS);
/* KX_ArmatureSensor type */
KX_MACRO_addTypesToDict(d, KX_ARMSENSOR_STATE_CHANGED, SENS_ARM_STATE_CHANGED);
KX_MACRO_addTypesToDict(d, KX_ARMSENSOR_LIN_ERROR_BELOW, SENS_ARM_LIN_ERROR_BELOW);
KX_MACRO_addTypesToDict(d, KX_ARMSENSOR_LIN_ERROR_ABOVE, SENS_ARM_LIN_ERROR_ABOVE);
KX_MACRO_addTypesToDict(d, KX_ARMSENSOR_ROT_ERROR_BELOW, SENS_ARM_ROT_ERROR_BELOW);
KX_MACRO_addTypesToDict(d, KX_ARMSENSOR_ROT_ERROR_ABOVE, SENS_ARM_ROT_ERROR_ABOVE);
/* BL_ArmatureActuator type */
KX_MACRO_addTypesToDict(d, KX_ACT_ARMATURE_RUN, ACT_ARM_RUN);
KX_MACRO_addTypesToDict(d, KX_ACT_ARMATURE_ENABLE, ACT_ARM_ENABLE);
KX_MACRO_addTypesToDict(d, KX_ACT_ARMATURE_DISABLE, ACT_ARM_DISABLE);
KX_MACRO_addTypesToDict(d, KX_ACT_ARMATURE_SETTARGET, ACT_ARM_SETTARGET);
KX_MACRO_addTypesToDict(d, KX_ACT_ARMATURE_SETWEIGHT, ACT_ARM_SETWEIGHT);
KX_MACRO_addTypesToDict(d, KX_ACT_ARMATURE_SETINFLUENCE, ACT_ARM_SETINFLUENCE);
/* BL_Armature Channel rotation_mode */
KX_MACRO_addTypesToDict(d, ROT_MODE_QUAT, ROT_MODE_QUAT);
KX_MACRO_addTypesToDict(d, ROT_MODE_XYZ, ROT_MODE_XYZ);
KX_MACRO_addTypesToDict(d, ROT_MODE_XZY, ROT_MODE_XZY);
KX_MACRO_addTypesToDict(d, ROT_MODE_YXZ, ROT_MODE_YXZ);
KX_MACRO_addTypesToDict(d, ROT_MODE_YZX, ROT_MODE_YZX);
KX_MACRO_addTypesToDict(d, ROT_MODE_ZXY, ROT_MODE_ZXY);
KX_MACRO_addTypesToDict(d, ROT_MODE_ZYX, ROT_MODE_ZYX);
/* Steering actuator */
KX_MACRO_addTypesToDict(d, KX_STEERING_SEEK, KX_SteeringActuator::KX_STEERING_SEEK);
KX_MACRO_addTypesToDict(d, KX_STEERING_FLEE, KX_SteeringActuator::KX_STEERING_FLEE);
KX_MACRO_addTypesToDict(d, KX_STEERING_PATHFOLLOWING, KX_SteeringActuator::KX_STEERING_PATHFOLLOWING);
/* KX_NavMeshObject render mode */
KX_MACRO_addTypesToDict(d, RM_WALLS, KX_NavMeshObject::RM_WALLS);
KX_MACRO_addTypesToDict(d, RM_POLYS, KX_NavMeshObject::RM_POLYS);
KX_MACRO_addTypesToDict(d, RM_TRIS, KX_NavMeshObject::RM_TRIS);
/* BL_Action play modes */
KX_MACRO_addTypesToDict(d, KX_ACTION_MODE_PLAY, BL_Action::ACT_MODE_PLAY);
KX_MACRO_addTypesToDict(d, KX_ACTION_MODE_LOOP, BL_Action::ACT_MODE_LOOP);
KX_MACRO_addTypesToDict(d, KX_ACTION_MODE_PING_PONG, BL_Action::ACT_MODE_PING_PONG);
/* BL_Action blend modes */
KX_MACRO_addTypesToDict(d, KX_ACTION_BLEND_BLEND, BL_Action::ACT_BLEND_BLEND);
KX_MACRO_addTypesToDict(d, KX_ACTION_BLEND_ADD, BL_Action::ACT_BLEND_ADD);
/* Mouse Actuator object axis*/
KX_MACRO_addTypesToDict(d, KX_ACT_MOUSE_OBJECT_AXIS_X, KX_MouseActuator::KX_ACT_MOUSE_OBJECT_AXIS_X);
KX_MACRO_addTypesToDict(d, KX_ACT_MOUSE_OBJECT_AXIS_Y, KX_MouseActuator::KX_ACT_MOUSE_OBJECT_AXIS_Y);
KX_MACRO_addTypesToDict(d, KX_ACT_MOUSE_OBJECT_AXIS_Z, KX_MouseActuator::KX_ACT_MOUSE_OBJECT_AXIS_Z);
// Check for errors
if (PyErr_Occurred())
{
Py_FatalError("can't initialize module bge.logic");
}
return m;
}
/* Explanation of
*
* - backupPySysObjects() : stores sys.path in gp_OrigPythonSysPath
* - initPySysObjects(main) : initializes the blendfile and library paths
* - restorePySysObjects() : restores sys.path from gp_OrigPythonSysPath
*
* These exist so the current blend dir "//" can always be used to import modules from.
* the reason we need a few functions for this is that python is not only used by the game engine
* so we cant just add to sys.path all the time, it would leave pythons state in a mess.
* It would also be incorrect since loading blend files for new levels etc would always add to sys.path
*
* To play nice with blenders python, the sys.path is backed up and the current blendfile along
* with all its lib paths are added to the sys path.
* When loading a new blendfile, the original sys.path is restored and the new paths are added over the top.
*/
/**
* So we can have external modules mixed with our blend files.
*/
static void backupPySysObjects(void)
{
PyObject *sys_path= PySys_GetObject("path"); /* should never fail */
PyObject *sys_mods= PySys_GetObject("modules"); /* should never fail */
/* paths */
Py_XDECREF(gp_OrigPythonSysPath); /* just in case its set */
gp_OrigPythonSysPath = PyList_GetSlice(sys_path, 0, INT_MAX); /* copy the list */
/* modules */
Py_XDECREF(gp_OrigPythonSysModules); /* just in case its set */
gp_OrigPythonSysModules = PyDict_Copy(sys_mods); /* copy the list */
}
/* for initPySysObjects only,
* takes a blend path and adds a scripts dir from it
*
* "/home/me/foo.blend" -> "/home/me/scripts"
*/
static void initPySysObjects__append(PyObject *sys_path, const char *filename)
{
PyObject *item;
char expanded[FILE_MAX];
BLI_split_dir_part(filename, expanded, sizeof(expanded)); /* get the dir part of filename only */
BLI_path_abs(expanded, gp_GamePythonPath); /* filename from lib->filename is (always?) absolute, so this may not be needed but it wont hurt */
BLI_cleanup_file(gp_GamePythonPath, expanded); /* Don't use BLI_cleanup_dir because it adds a slash - BREAKS WIN32 ONLY */
item = PyC_UnicodeFromByte(expanded);
// printf("SysPath - '%s', '%s', '%s'\n", expanded, filename, gp_GamePythonPath);
if (PySequence_Index(sys_path, item) == -1) {
PyErr_Clear(); /* PySequence_Index sets a ValueError */
PyList_Insert(sys_path, 0, item);
}
Py_DECREF(item);
}
static void initPySysObjects(Main *maggie)
{
PyObject *sys_path= PySys_GetObject("path"); /* should never fail */
if (gp_OrigPythonSysPath==NULL) {
/* backup */
backupPySysObjects();
}
else {
/* get the original sys path when the BGE started */
PyList_SetSlice(sys_path, 0, INT_MAX, gp_OrigPythonSysPath);
}
Library *lib= (Library *)maggie->library.first;
while (lib) {
/* lib->name wont work in some cases (on win32),
* even when expanding with gp_GamePythonPath, using lib->filename is less trouble */
initPySysObjects__append(sys_path, lib->filepath);
lib= (Library *)lib->id.next;
}
initPySysObjects__append(sys_path, gp_GamePythonPath);
// fprintf(stderr, "\nNew Path: %d ", PyList_GET_SIZE(sys_path));
// PyObject_Print(sys_path, stderr, 0);
}
static void restorePySysObjects(void)
{
if (gp_OrigPythonSysPath==NULL)
return;
PyObject *sys_path= PySys_GetObject("path"); /* should never fail */
PyObject *sys_mods= PySys_GetObject("modules"); /* should never fail */
/* paths */
PyList_SetSlice(sys_path, 0, INT_MAX, gp_OrigPythonSysPath);
Py_DECREF(gp_OrigPythonSysPath);
gp_OrigPythonSysPath= NULL;
/* modules */
PyDict_Clear(sys_mods);
PyDict_Update(sys_mods, gp_OrigPythonSysModules);
Py_DECREF(gp_OrigPythonSysModules);
gp_OrigPythonSysModules= NULL;
// fprintf(stderr, "\nRestore Path: %d ", PyList_GET_SIZE(sys_path));
// PyObject_Print(sys_path, stderr, 0);
}
void addImportMain(struct Main *maggie)
{
bpy_import_main_extra_add(maggie);
}
void removeImportMain(struct Main *maggie)
{
bpy_import_main_extra_remove(maggie);
}
PyDoc_STRVAR(BGE_module_documentation,
"This module contains submodules for the Blender Game Engine.\n"
);
static struct PyModuleDef BGE_module_def = {
PyModuleDef_HEAD_INIT,
"bge", /* m_name */
BGE_module_documentation, /* m_doc */
0, /* m_size */
NULL, /* m_methods */
NULL, /* m_reload */
NULL, /* m_traverse */
NULL, /* m_clear */
NULL, /* m_free */
};
PyMODINIT_FUNC initBGE(void)
{
PyObject *mod;
PyObject *submodule;
PyObject *sys_modules = PyThreadState_GET()->interp->modules;
mod = PyModule_Create(&BGE_module_def);
PyModule_AddObject(mod, "constraints", (submodule = initConstraintPythonBinding()));
PyDict_SetItemString(sys_modules, PyModule_GetName(submodule), submodule);
Py_INCREF(submodule);
PyModule_AddObject(mod, "events", (submodule = initGameKeysPythonBinding()));
PyDict_SetItemString(sys_modules, PyModule_GetName(submodule), submodule);
Py_INCREF(submodule);
PyModule_AddObject(mod, "logic", (submodule = initGameLogicPythonBinding()));
PyDict_SetItemString(sys_modules, PyModule_GetName(submodule), submodule);
Py_INCREF(submodule);
PyModule_AddObject(mod, "render", (submodule = initRasterizerPythonBinding()));
PyDict_SetItemString(sys_modules, PyModule_GetName(submodule), submodule);
Py_INCREF(submodule);
PyModule_AddObject(mod, "texture", (submodule = initVideoTexturePythonBinding()));
PyDict_SetItemString(sys_modules, PyModule_GetName(submodule), submodule);
Py_INCREF(submodule);
PyModule_AddObject(mod, "types", (submodule = initGameTypesPythonBinding()));
PyDict_SetItemString(sys_modules, PyModule_GetName(submodule), submodule);
Py_INCREF(submodule);
return mod;
}
/* minimal required blender modules to run blenderplayer */
static struct _inittab bge_internal_modules[] = {
{"mathutils", PyInit_mathutils},
{"bgl", BPyInit_bgl},
{"blf", BPyInit_blf},
{"aud", AUD_initPython},
{NULL, NULL}
};
/**
* Python is not initialized.
* see bpy_interface.c's BPY_python_start() which shares the same functionality in blender.
*/
PyObject *initGamePlayerPythonScripting(Main *maggie, int argc, char** argv)
{
/* Yet another gotcha in the py api
* Cant run PySys_SetArgv more than once because this adds the
* binary dir to the sys.path each time.
* Id have thought python being totally restarted would make this ok but
* somehow it remembers the sys.path - Campbell
*/
static bool first_time = true;
const char * const py_path_bundle = BKE_appdir_folder_id(BLENDER_SYSTEM_PYTHON, NULL);
/* not essential but nice to set our name */
static wchar_t program_path_wchar[FILE_MAX]; /* python holds a reference */
BLI_strncpy_wchar_from_utf8(program_path_wchar, BKE_appdir_program_path(), ARRAY_SIZE(program_path_wchar));
Py_SetProgramName(program_path_wchar);
/* Update, Py3.3 resolves attempting to parse non-existing header */
#if 0
/* Python 3.2 now looks for '2.xx/python/include/python3.2d/pyconfig.h' to
* parse from the 'sysconfig' module which is used by 'site',
* so for now disable site. alternatively we could copy the file. */
if (py_path_bundle != NULL) {
Py_NoSiteFlag = 1; /* inhibits the automatic importing of 'site' */
}
#endif
Py_FrozenFlag = 1;
/* must run before python initializes */
PyImport_ExtendInittab(bge_internal_modules);
/* find local python installation */
PyC_SetHomePath(py_path_bundle);
Py_Initialize();
if (argv && first_time) { /* browser plugins don't currently set this */
// Until python support ascii again, we use our own.
// PySys_SetArgv(argc, argv);
int i;
PyObject *py_argv= PyList_New(argc);
for (i=0; i<argc; i++)
PyList_SET_ITEM(py_argv, i, PyC_UnicodeFromByte(argv[i]));
PySys_SetObject("argv", py_argv);
Py_DECREF(py_argv);
}
/* Initialize thread support (also acquires lock) */
PyEval_InitThreads();
bpy_import_init(PyEval_GetBuiltins());
bpy_import_main_set(maggie);
initPySysObjects(maggie);
/* mathutils types are used by the BGE even if we don't import them */
{
PyObject *mod = PyImport_ImportModuleLevel("mathutils", NULL, NULL, NULL, 0);
Py_DECREF(mod);
}
#ifdef WITH_AUDASPACE
/* accessing a SoundActuator's sound results in a crash if aud is not initialized... */
{
PyObject *mod = PyImport_ImportModuleLevel("aud", NULL, NULL, NULL, 0);
Py_DECREF(mod);
}
#endif
PyDict_SetItemString(PyImport_GetModuleDict(), "bge", initBGE());
first_time = false;
PyObjectPlus::ClearDeprecationWarning();
return PyC_DefaultNameSpace(NULL);
}
void exitGamePlayerPythonScripting()
{
/* Clean up the Python mouse and keyboard */
delete gp_PythonKeyboard;
gp_PythonKeyboard = NULL;
delete gp_PythonMouse;
gp_PythonMouse = NULL;
for (int i=0; i<JOYINDEX_MAX; ++i) {
if (gp_PythonJoysticks[i]) {
delete gp_PythonJoysticks[i];
gp_PythonJoysticks[i] = NULL;
}
}
/* since python restarts we cant let the python backup of the sys.path hang around in a global pointer */
restorePySysObjects(); /* get back the original sys.path and clear the backup */
Py_Finalize();
bpy_import_main_set(NULL);
PyObjectPlus::ClearDeprecationWarning();
}
/**
* Python is already initialized.
*/
PyObject *initGamePythonScripting(Main *maggie)
{
/* no need to Py_SetProgramName, it was already taken care of in BPY_python_start */
bpy_import_main_set(maggie);
initPySysObjects(maggie);
#ifdef WITH_AUDASPACE
/* accessing a SoundActuator's sound results in a crash if aud is not initialized... */
{
PyObject *mod= PyImport_ImportModuleLevel("aud", NULL, NULL, NULL, 0);
Py_DECREF(mod);
}
#endif
PyDict_SetItemString(PyImport_GetModuleDict(), "bge", initBGE());
PyObjectPlus::NullDeprecationWarning();
return PyC_DefaultNameSpace(NULL);
}
void exitGamePythonScripting()
{
/* Clean up the Python mouse and keyboard */
delete gp_PythonKeyboard;
gp_PythonKeyboard = NULL;
delete gp_PythonMouse;
gp_PythonMouse = NULL;
for (int i=0; i<JOYINDEX_MAX; ++i) {
if (gp_PythonJoysticks[i]) {
delete gp_PythonJoysticks[i];
gp_PythonJoysticks[i] = NULL;
}
}
restorePySysObjects(); /* get back the original sys.path and clear the backup */
bpy_import_main_set(NULL);
PyObjectPlus::ClearDeprecationWarning();
}
/* similar to the above functions except it sets up the namespace
* and other more general things */
void setupGamePython(KX_KetsjiEngine* ketsjiengine, KX_Scene *startscene, Main *blenderdata,
PyObject *pyGlobalDict, PyObject **gameLogic, PyObject **gameLogic_keys, int argc, char** argv)
{
PyObject *modules, *dictionaryobject;
gp_Canvas = ketsjiengine->GetCanvas();
gp_Rasterizer = ketsjiengine->GetRasterizer();
gp_KetsjiEngine = ketsjiengine;
gp_KetsjiScene = startscene;
if (argv) /* player only */
dictionaryobject= initGamePlayerPythonScripting(blenderdata, argc, argv);
else
dictionaryobject= initGamePythonScripting(blenderdata);
ketsjiengine->SetPyNamespace(dictionaryobject);
modules = PyImport_GetModuleDict();
*gameLogic = PyDict_GetItemString(modules, "GameLogic");
/* is set in initGameLogicPythonBinding so only set here if we want it to persist between scenes */
if (pyGlobalDict)
PyDict_SetItemString(PyModule_GetDict(*gameLogic), "globalDict", pyGlobalDict); // Same as importing the module.
*gameLogic_keys = PyDict_Keys(PyModule_GetDict(*gameLogic));
}
static struct PyModuleDef Rasterizer_module_def = {
PyModuleDef_HEAD_INIT,
"Rasterizer", /* m_name */
Rasterizer_module_documentation, /* m_doc */
0, /* m_size */
rasterizer_methods, /* m_methods */
0, /* m_reload */
0, /* m_traverse */
0, /* m_clear */
0, /* m_free */
};
PyMODINIT_FUNC initRasterizerPythonBinding()
{
PyObject *m;
PyObject *d;
m = PyModule_Create(&Rasterizer_module_def);
PyDict_SetItemString(PySys_GetObject("modules"), Rasterizer_module_def.m_name, m);
// Add some symbolic constants to the module
d = PyModule_GetDict(m);
ErrorObject = PyUnicode_FromString("Rasterizer.error");
PyDict_SetItemString(d, "error", ErrorObject);
Py_DECREF(ErrorObject);
/* needed for get/setMaterialType */
KX_MACRO_addTypesToDict(d, KX_BLENDER_MULTITEX_MATERIAL, KX_BLENDER_MULTITEX_MATERIAL);
KX_MACRO_addTypesToDict(d, KX_BLENDER_GLSL_MATERIAL, KX_BLENDER_GLSL_MATERIAL);
KX_MACRO_addTypesToDict(d, RAS_MIPMAP_NONE, RAS_IRasterizer::RAS_MIPMAP_NONE);
KX_MACRO_addTypesToDict(d, RAS_MIPMAP_NEAREST, RAS_IRasterizer::RAS_MIPMAP_NEAREST);
KX_MACRO_addTypesToDict(d, RAS_MIPMAP_LINEAR, RAS_IRasterizer::RAS_MIPMAP_LINEAR);
/* for get/setVsync */
KX_MACRO_addTypesToDict(d, VSYNC_OFF, VSYNC_OFF);
KX_MACRO_addTypesToDict(d, VSYNC_ON, VSYNC_ON);
KX_MACRO_addTypesToDict(d, VSYNC_ADAPTIVE, VSYNC_ADAPTIVE);
/* stereoscopy */
KX_MACRO_addTypesToDict(d, LEFT_EYE, RAS_IRasterizer::RAS_STEREO_LEFTEYE);
KX_MACRO_addTypesToDict(d, RIGHT_EYE, RAS_IRasterizer::RAS_STEREO_RIGHTEYE);
/* KX_WorldInfo mist types */
KX_MACRO_addTypesToDict(d, KX_MIST_QUADRATIC, KX_WorldInfo::KX_MIST_QUADRATIC);
KX_MACRO_addTypesToDict(d, KX_MIST_LINEAR, KX_WorldInfo::KX_MIST_LINEAR);
KX_MACRO_addTypesToDict(d, KX_MIST_INV_QUADRATIC, KX_WorldInfo::KX_MIST_INV_QUADRATIC);
// XXXX Add constants here
// Check for errors
if (PyErr_Occurred())
{
Py_FatalError("can't initialize module Rasterizer");
}
return m;
}
/* ------------------------------------------------------------------------- */
/* GameKeys: symbolic constants for key mapping */
/* ------------------------------------------------------------------------- */
PyDoc_STRVAR(GameKeys_module_documentation,
"This modules provides defines for key-codes"
);
PyDoc_STRVAR(gPyEventToString_doc,
"EventToString(event)\n"
"Take a valid event from the GameKeys module or Keyboard Sensor and return a name"
);
static PyObject *gPyEventToString(PyObject *, PyObject *value)
{
PyObject *mod, *dict, *key, *val, *ret = NULL;
Py_ssize_t pos = 0;
mod = PyImport_ImportModule( "GameKeys" );
if (!mod)
return NULL;
dict = PyModule_GetDict(mod);
while (PyDict_Next(dict, &pos, &key, &val)) {
if (PyObject_RichCompareBool(value, val, Py_EQ)) {
ret = key;
break;
}
}
PyErr_Clear(); // in case there was an error clearing
Py_DECREF(mod);
if (!ret) PyErr_SetString(PyExc_ValueError, "GameKeys.EventToString(int): expected a valid int keyboard event");
else Py_INCREF(ret);
return ret;
}
PyDoc_STRVAR(gPyEventToCharacter_doc,
"EventToCharacter(event, is_shift)\n"
"Take a valid event from the GameKeys module or Keyboard Sensor and return a character"
);
static PyObject *gPyEventToCharacter(PyObject *, PyObject *args)
{
int event, shift;
if (!PyArg_ParseTuple(args,"ii:EventToCharacter", &event, &shift))
return NULL;
if (IsPrintable(event)) {
char ch[2] = {'\0', '\0'};
ch[0] = ToCharacter(event, (bool)shift);
return PyUnicode_FromString(ch);
}
else {
return PyUnicode_FromString("");
}
}
static struct PyMethodDef gamekeys_methods[] = {
{"EventToCharacter", (PyCFunction)gPyEventToCharacter, METH_VARARGS, (const char *)gPyEventToCharacter_doc},
{"EventToString", (PyCFunction)gPyEventToString, METH_O, (const char *)gPyEventToString_doc},
{ NULL, (PyCFunction) NULL, 0, NULL }
};
static struct PyModuleDef GameKeys_module_def = {
PyModuleDef_HEAD_INIT,
"GameKeys", /* m_name */
GameKeys_module_documentation, /* m_doc */
0, /* m_size */
gamekeys_methods, /* m_methods */
0, /* m_reload */
0, /* m_traverse */
0, /* m_clear */
0, /* m_free */
};
PyMODINIT_FUNC initGameKeysPythonBinding()
{
PyObject *m;
PyObject *d;
m = PyModule_Create(&GameKeys_module_def);
PyDict_SetItemString(PySys_GetObject("modules"), GameKeys_module_def.m_name, m);
// Add some symbolic constants to the module
d = PyModule_GetDict(m);
// XXXX Add constants here
KX_MACRO_addTypesToDict(d, AKEY, SCA_IInputDevice::KX_AKEY);
KX_MACRO_addTypesToDict(d, BKEY, SCA_IInputDevice::KX_BKEY);
KX_MACRO_addTypesToDict(d, CKEY, SCA_IInputDevice::KX_CKEY);
KX_MACRO_addTypesToDict(d, DKEY, SCA_IInputDevice::KX_DKEY);
KX_MACRO_addTypesToDict(d, EKEY, SCA_IInputDevice::KX_EKEY);
KX_MACRO_addTypesToDict(d, FKEY, SCA_IInputDevice::KX_FKEY);
KX_MACRO_addTypesToDict(d, GKEY, SCA_IInputDevice::KX_GKEY);
KX_MACRO_addTypesToDict(d, HKEY, SCA_IInputDevice::KX_HKEY);
KX_MACRO_addTypesToDict(d, IKEY, SCA_IInputDevice::KX_IKEY);
KX_MACRO_addTypesToDict(d, JKEY, SCA_IInputDevice::KX_JKEY);
KX_MACRO_addTypesToDict(d, KKEY, SCA_IInputDevice::KX_KKEY);
KX_MACRO_addTypesToDict(d, LKEY, SCA_IInputDevice::KX_LKEY);
KX_MACRO_addTypesToDict(d, MKEY, SCA_IInputDevice::KX_MKEY);
KX_MACRO_addTypesToDict(d, NKEY, SCA_IInputDevice::KX_NKEY);
KX_MACRO_addTypesToDict(d, OKEY, SCA_IInputDevice::KX_OKEY);
KX_MACRO_addTypesToDict(d, PKEY, SCA_IInputDevice::KX_PKEY);
KX_MACRO_addTypesToDict(d, QKEY, SCA_IInputDevice::KX_QKEY);
KX_MACRO_addTypesToDict(d, RKEY, SCA_IInputDevice::KX_RKEY);
KX_MACRO_addTypesToDict(d, SKEY, SCA_IInputDevice::KX_SKEY);
KX_MACRO_addTypesToDict(d, TKEY, SCA_IInputDevice::KX_TKEY);
KX_MACRO_addTypesToDict(d, UKEY, SCA_IInputDevice::KX_UKEY);
KX_MACRO_addTypesToDict(d, VKEY, SCA_IInputDevice::KX_VKEY);
KX_MACRO_addTypesToDict(d, WKEY, SCA_IInputDevice::KX_WKEY);
KX_MACRO_addTypesToDict(d, XKEY, SCA_IInputDevice::KX_XKEY);
KX_MACRO_addTypesToDict(d, YKEY, SCA_IInputDevice::KX_YKEY);
KX_MACRO_addTypesToDict(d, ZKEY, SCA_IInputDevice::KX_ZKEY);
KX_MACRO_addTypesToDict(d, ZEROKEY, SCA_IInputDevice::KX_ZEROKEY);
KX_MACRO_addTypesToDict(d, ONEKEY, SCA_IInputDevice::KX_ONEKEY);
KX_MACRO_addTypesToDict(d, TWOKEY, SCA_IInputDevice::KX_TWOKEY);
KX_MACRO_addTypesToDict(d, THREEKEY, SCA_IInputDevice::KX_THREEKEY);
KX_MACRO_addTypesToDict(d, FOURKEY, SCA_IInputDevice::KX_FOURKEY);
KX_MACRO_addTypesToDict(d, FIVEKEY, SCA_IInputDevice::KX_FIVEKEY);
KX_MACRO_addTypesToDict(d, SIXKEY, SCA_IInputDevice::KX_SIXKEY);
KX_MACRO_addTypesToDict(d, SEVENKEY, SCA_IInputDevice::KX_SEVENKEY);
KX_MACRO_addTypesToDict(d, EIGHTKEY, SCA_IInputDevice::KX_EIGHTKEY);
KX_MACRO_addTypesToDict(d, NINEKEY, SCA_IInputDevice::KX_NINEKEY);
KX_MACRO_addTypesToDict(d, CAPSLOCKKEY, SCA_IInputDevice::KX_CAPSLOCKKEY);
KX_MACRO_addTypesToDict(d, LEFTCTRLKEY, SCA_IInputDevice::KX_LEFTCTRLKEY);
KX_MACRO_addTypesToDict(d, LEFTALTKEY, SCA_IInputDevice::KX_LEFTALTKEY);
KX_MACRO_addTypesToDict(d, RIGHTALTKEY, SCA_IInputDevice::KX_RIGHTALTKEY);
KX_MACRO_addTypesToDict(d, RIGHTCTRLKEY, SCA_IInputDevice::KX_RIGHTCTRLKEY);
KX_MACRO_addTypesToDict(d, RIGHTSHIFTKEY, SCA_IInputDevice::KX_RIGHTSHIFTKEY);
KX_MACRO_addTypesToDict(d, LEFTSHIFTKEY, SCA_IInputDevice::KX_LEFTSHIFTKEY);
KX_MACRO_addTypesToDict(d, ESCKEY, SCA_IInputDevice::KX_ESCKEY);
KX_MACRO_addTypesToDict(d, TABKEY, SCA_IInputDevice::KX_TABKEY);
KX_MACRO_addTypesToDict(d, RETKEY, SCA_IInputDevice::KX_RETKEY);
KX_MACRO_addTypesToDict(d, ENTERKEY, SCA_IInputDevice::KX_RETKEY);
KX_MACRO_addTypesToDict(d, SPACEKEY, SCA_IInputDevice::KX_SPACEKEY);
KX_MACRO_addTypesToDict(d, LINEFEEDKEY, SCA_IInputDevice::KX_LINEFEEDKEY);
KX_MACRO_addTypesToDict(d, BACKSPACEKEY, SCA_IInputDevice::KX_BACKSPACEKEY);
KX_MACRO_addTypesToDict(d, DELKEY, SCA_IInputDevice::KX_DELKEY);
KX_MACRO_addTypesToDict(d, SEMICOLONKEY, SCA_IInputDevice::KX_SEMICOLONKEY);
KX_MACRO_addTypesToDict(d, PERIODKEY, SCA_IInputDevice::KX_PERIODKEY);
KX_MACRO_addTypesToDict(d, COMMAKEY, SCA_IInputDevice::KX_COMMAKEY);
KX_MACRO_addTypesToDict(d, QUOTEKEY, SCA_IInputDevice::KX_QUOTEKEY);
KX_MACRO_addTypesToDict(d, ACCENTGRAVEKEY, SCA_IInputDevice::KX_ACCENTGRAVEKEY);
KX_MACRO_addTypesToDict(d, MINUSKEY, SCA_IInputDevice::KX_MINUSKEY);
KX_MACRO_addTypesToDict(d, SLASHKEY, SCA_IInputDevice::KX_SLASHKEY);
KX_MACRO_addTypesToDict(d, BACKSLASHKEY, SCA_IInputDevice::KX_BACKSLASHKEY);
KX_MACRO_addTypesToDict(d, EQUALKEY, SCA_IInputDevice::KX_EQUALKEY);
KX_MACRO_addTypesToDict(d, LEFTBRACKETKEY, SCA_IInputDevice::KX_LEFTBRACKETKEY);
KX_MACRO_addTypesToDict(d, RIGHTBRACKETKEY, SCA_IInputDevice::KX_RIGHTBRACKETKEY);
KX_MACRO_addTypesToDict(d, LEFTARROWKEY, SCA_IInputDevice::KX_LEFTARROWKEY);
KX_MACRO_addTypesToDict(d, DOWNARROWKEY, SCA_IInputDevice::KX_DOWNARROWKEY);
KX_MACRO_addTypesToDict(d, RIGHTARROWKEY, SCA_IInputDevice::KX_RIGHTARROWKEY);
KX_MACRO_addTypesToDict(d, UPARROWKEY, SCA_IInputDevice::KX_UPARROWKEY);
KX_MACRO_addTypesToDict(d, PAD2 , SCA_IInputDevice::KX_PAD2);
KX_MACRO_addTypesToDict(d, PAD4 , SCA_IInputDevice::KX_PAD4);
KX_MACRO_addTypesToDict(d, PAD6 , SCA_IInputDevice::KX_PAD6);
KX_MACRO_addTypesToDict(d, PAD8 , SCA_IInputDevice::KX_PAD8);
KX_MACRO_addTypesToDict(d, PAD1 , SCA_IInputDevice::KX_PAD1);
KX_MACRO_addTypesToDict(d, PAD3 , SCA_IInputDevice::KX_PAD3);
KX_MACRO_addTypesToDict(d, PAD5 , SCA_IInputDevice::KX_PAD5);
KX_MACRO_addTypesToDict(d, PAD7 , SCA_IInputDevice::KX_PAD7);
KX_MACRO_addTypesToDict(d, PAD9 , SCA_IInputDevice::KX_PAD9);
KX_MACRO_addTypesToDict(d, PADPERIOD, SCA_IInputDevice::KX_PADPERIOD);
KX_MACRO_addTypesToDict(d, PADSLASHKEY, SCA_IInputDevice::KX_PADSLASHKEY);
KX_MACRO_addTypesToDict(d, PADASTERKEY, SCA_IInputDevice::KX_PADASTERKEY);
KX_MACRO_addTypesToDict(d, PAD0, SCA_IInputDevice::KX_PAD0);
KX_MACRO_addTypesToDict(d, PADMINUS, SCA_IInputDevice::KX_PADMINUS);
KX_MACRO_addTypesToDict(d, PADENTER, SCA_IInputDevice::KX_PADENTER);
KX_MACRO_addTypesToDict(d, PADPLUSKEY, SCA_IInputDevice::KX_PADPLUSKEY);
KX_MACRO_addTypesToDict(d, F1KEY, SCA_IInputDevice::KX_F1KEY);
KX_MACRO_addTypesToDict(d, F2KEY, SCA_IInputDevice::KX_F2KEY);
KX_MACRO_addTypesToDict(d, F3KEY, SCA_IInputDevice::KX_F3KEY);
KX_MACRO_addTypesToDict(d, F4KEY, SCA_IInputDevice::KX_F4KEY);
KX_MACRO_addTypesToDict(d, F5KEY, SCA_IInputDevice::KX_F5KEY);
KX_MACRO_addTypesToDict(d, F6KEY, SCA_IInputDevice::KX_F6KEY);
KX_MACRO_addTypesToDict(d, F7KEY, SCA_IInputDevice::KX_F7KEY);
KX_MACRO_addTypesToDict(d, F8KEY, SCA_IInputDevice::KX_F8KEY);
KX_MACRO_addTypesToDict(d, F9KEY, SCA_IInputDevice::KX_F9KEY);
KX_MACRO_addTypesToDict(d, F10KEY, SCA_IInputDevice::KX_F10KEY);
KX_MACRO_addTypesToDict(d, F11KEY, SCA_IInputDevice::KX_F11KEY);
KX_MACRO_addTypesToDict(d, F12KEY, SCA_IInputDevice::KX_F12KEY);
KX_MACRO_addTypesToDict(d, F13KEY, SCA_IInputDevice::KX_F13KEY);
KX_MACRO_addTypesToDict(d, F14KEY, SCA_IInputDevice::KX_F14KEY);
KX_MACRO_addTypesToDict(d, F15KEY, SCA_IInputDevice::KX_F15KEY);
KX_MACRO_addTypesToDict(d, F16KEY, SCA_IInputDevice::KX_F16KEY);
KX_MACRO_addTypesToDict(d, F17KEY, SCA_IInputDevice::KX_F17KEY);
KX_MACRO_addTypesToDict(d, F18KEY, SCA_IInputDevice::KX_F18KEY);
KX_MACRO_addTypesToDict(d, F19KEY, SCA_IInputDevice::KX_F19KEY);
KX_MACRO_addTypesToDict(d, OSKEY, SCA_IInputDevice::KX_OSKEY);
KX_MACRO_addTypesToDict(d, PAUSEKEY, SCA_IInputDevice::KX_PAUSEKEY);
KX_MACRO_addTypesToDict(d, INSERTKEY, SCA_IInputDevice::KX_INSERTKEY);
KX_MACRO_addTypesToDict(d, HOMEKEY, SCA_IInputDevice::KX_HOMEKEY);
KX_MACRO_addTypesToDict(d, PAGEUPKEY, SCA_IInputDevice::KX_PAGEUPKEY);
KX_MACRO_addTypesToDict(d, PAGEDOWNKEY, SCA_IInputDevice::KX_PAGEDOWNKEY);
KX_MACRO_addTypesToDict(d, ENDKEY, SCA_IInputDevice::KX_ENDKEY);
// MOUSE
KX_MACRO_addTypesToDict(d, LEFTMOUSE, SCA_IInputDevice::KX_LEFTMOUSE);
KX_MACRO_addTypesToDict(d, MIDDLEMOUSE, SCA_IInputDevice::KX_MIDDLEMOUSE);
KX_MACRO_addTypesToDict(d, RIGHTMOUSE, SCA_IInputDevice::KX_RIGHTMOUSE);
KX_MACRO_addTypesToDict(d, WHEELUPMOUSE, SCA_IInputDevice::KX_WHEELUPMOUSE);
KX_MACRO_addTypesToDict(d, WHEELDOWNMOUSE, SCA_IInputDevice::KX_WHEELDOWNMOUSE);
KX_MACRO_addTypesToDict(d, MOUSEX, SCA_IInputDevice::KX_MOUSEX);
KX_MACRO_addTypesToDict(d, MOUSEY, SCA_IInputDevice::KX_MOUSEY);
// Check for errors
if (PyErr_Occurred())
{
Py_FatalError("can't initialize module GameKeys");
}
return m;
}
// utility function for loading and saving the globalDict
int saveGamePythonConfig( char **marshal_buffer)
{
int marshal_length = 0;
PyObject *gameLogic = PyImport_ImportModule("GameLogic");
if (gameLogic) {
PyObject *pyGlobalDict = PyDict_GetItemString(PyModule_GetDict(gameLogic), "globalDict"); // Same as importing the module
if (pyGlobalDict) {
#ifdef Py_MARSHAL_VERSION
PyObject *pyGlobalDictMarshal = PyMarshal_WriteObjectToString( pyGlobalDict, 2); // Py_MARSHAL_VERSION == 2 as of Py2.5
#else
PyObject *pyGlobalDictMarshal = PyMarshal_WriteObjectToString( pyGlobalDict );
#endif
if (pyGlobalDictMarshal) {
// for testing only
// PyObject_Print(pyGlobalDictMarshal, stderr, 0);
char *marshal_cstring;
marshal_cstring = PyBytes_AsString(pyGlobalDictMarshal); // py3 uses byte arrays
marshal_length= PyBytes_Size(pyGlobalDictMarshal);
*marshal_buffer = new char[marshal_length + 1];
memcpy(*marshal_buffer, marshal_cstring, marshal_length);
Py_DECREF(pyGlobalDictMarshal);
} else {
printf("Error, bge.logic.globalDict could not be marshal'd\n");
}
} else {
printf("Error, bge.logic.globalDict was removed\n");
}
Py_DECREF(gameLogic);
} else {
PyErr_Clear();
printf("Error, bge.logic failed to import bge.logic.globalDict will be lost\n");
}
return marshal_length;
}
int loadGamePythonConfig(char *marshal_buffer, int marshal_length)
{
/* Restore the dict */
if (marshal_buffer) {
PyObject *gameLogic = PyImport_ImportModule("GameLogic");
if (gameLogic) {
PyObject *pyGlobalDict = PyMarshal_ReadObjectFromString(marshal_buffer, marshal_length);
if (pyGlobalDict) {
PyObject *pyGlobalDict_orig = PyDict_GetItemString(PyModule_GetDict(gameLogic), "globalDict"); // Same as importing the module.
if (pyGlobalDict_orig) {
PyDict_Clear(pyGlobalDict_orig);
PyDict_Update(pyGlobalDict_orig, pyGlobalDict);
} else {
/* this should not happen, but cant find the original globalDict, just assign it then */
PyDict_SetItemString(PyModule_GetDict(gameLogic), "globalDict", pyGlobalDict); // Same as importing the module.
}
Py_DECREF(gameLogic);
Py_DECREF(pyGlobalDict);
return 1;
} else {
Py_DECREF(gameLogic);
PyErr_Clear();
printf("Error could not marshall string\n");
}
}
else {
PyErr_Clear();
printf("Error, bge.logic failed to import bge.logic.globalDict will be lost\n");
}
}
return 0;
}
void pathGamePythonConfig(char *path)
{
int len = strlen(gp_GamePythonPathOrig); // Always use the first loaded blend filename
BLI_strncpy(path, gp_GamePythonPathOrig, sizeof(gp_GamePythonPathOrig));
/* replace extension */
if (BLI_testextensie(path, ".blend")) {
strcpy(path+(len-6), ".bgeconf");
} else {
strcpy(path+len, ".bgeconf");
}
}
void setGamePythonPath(const char *path)
{
BLI_strncpy(gp_GamePythonPath, path, sizeof(gp_GamePythonPath));
BLI_cleanup_file(NULL, gp_GamePythonPath); /* not absolutely needed but makes resolving path problems less confusing later */
if (gp_GamePythonPathOrig[0] == '\0')
BLI_strncpy(gp_GamePythonPathOrig, path, sizeof(gp_GamePythonPathOrig));
}
// we need this so while blender is open (not blenderplayer)
// loading new blendfiles will reset this on starting the
// engine but loading blend files within the BGE wont overwrite gp_GamePythonPathOrig
void resetGamePythonPath()
{
gp_GamePythonPathOrig[0] = '\0';
}
#endif // WITH_PYTHON
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