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29 Commits
73cda9f905 ... v0.3.0

Author SHA1 Message Date
yyc12345
af6a50c2f9 feat: use cmdline args as the args of BMap bindings. 
- update testbench of PyBMap and BMapSharp. use command line arguments as the arguments of testbench, instead of hardcoded variables in code.
 2025-01-02 10:59:16 +08:00
yyc12345
0bf0519c4c fix: fix linux build issue 
- use std::cos and std::sin instead of std::cosf and std::sinf. it seems that some linux environment do not have these 2 functions in std namespace.
 2024-12-31 18:25:44 +08:00
yyc12345
c18ff8f2e3 fix: fix various issues. 
- fix convertion loss in CKCamera.
- bump up version to 0.3.0
- use CMake to generate version info header.
- fix annotation about Dassault ComputeCRC error.
- change member field initialization value in CKLight.
 2024-12-31 17:48:24 +08:00
yyc12345
fe4a58e864 feat: add CKLight support and apply BMap changes to Python and CSharp bindings. 
- add CKLight and CKTargetLight in BMap bindings
- apply BMap changes, for example, the rename of BM3dObject_ prefix to BM3dEntity_, to BMap bindings.
 2024-12-30 11:28:59 +08:00
yyc12345
eaeaf956b5 fix: fix type error in BMap type check macro. 2024-12-29 10:13:56 +08:00
yyc12345
6bb2421e1f feat: add CKLight into BMap. 
- add CKLight support in BMap.
- move the implementation of BMFile into CPP file from HPP file.
- swap the order of the implementation of BMFile and BMMeshTransition to correspond with the order of their declaration.
- add document for some member functions of BMFile.
 2024-12-29 10:05:13 +08:00
yyc12345
ead22d13ff fix: remove useless void in function parameter list 
- according to c++ standard, single void in function parameter is equal to empty parameter list. for removing this syntax which may cause misunderstanding (becuase in C, they are different I guess), I replace all `(void)` to `()`.
 2024-12-28 22:09:26 +08:00
yyc12345
aeb2e86b14 fix: fix the issue when loading new version created files. 
- Fix the CRC check issue when loading new Virtools created files (> 4.0)
	* This is caused by a bug written by stupid Virtools programmer. For more detail, see code annotation.
	* After this patch, LibCmo have ability that load new Virtools created files including max2nmo exported NMO, Virtools 5.0 created CMO and etc.
 2024-12-28 16:29:35 +08:00
yyc12345
86b27557c9 feat: add 4 new added classes in Unvirt. 
- fix a fatal issue that make the output message from CKContext is empty.
- fix argument type error for CKCamera::GetAspect and CKCamera::SetAspect.
- add enums annotation and struct diaplay function in Unvirt for showing 4 new added classes.
 2024-12-25 13:58:39 +08:00
yyc12345
eef3a352d9 feat: finish CKTargetCamera and CKTargetLight. 
- finish all new added 4 classes, CKCamera, CKTargetCamera, CKLight, CKTargetLight. but no test.
 2024-12-25 11:12:23 +08:00
yyc12345
b74f1b965c feat: finish CKCamera 2024-12-25 09:07:02 +08:00
yyc12345
c235524403 fix: fix 2 issues 
- rename float to CKFLOAT in VxMatrix.
- move CKLightData struct to CKDefine.hpp because it not a private struct used by CKLight, but a CKRasterizer struct.
 2024-12-25 08:28:42 +08:00
yyc12345
4bfc4782b5 refactor: refactor VxVector and its generator. 
- refactor VxVector-like struct. split their declaration and implementatio because their implementation is too long. and occupy too much space in header.
- refactor VxVector struct generator. use jinja2 template engine, rather ran hand-written format string to make it is easy to read (although it still tough when first reading).
- add unary operator overloading for VxVector-like struct.
- add some VxMatrix functions which are essential to CKCamera.
- rename VxMatrix::ResetToIdentity to VxMatrix::SetIdentity to make it same as original Virtools SDK.
- the spaceship overloading with auto return value still may have bugs. please watch it carefully.
 2024-12-24 23:37:04 +08:00
yyc12345
3eeb1f6cb6 feat: finish CKLight class. 
- basically finish CKLight but no test now.
 2024-12-24 10:59:19 +08:00
yyc12345
ff5a590cf4 feat: add basic layout for CKLight and CKCamera. 
- add basic class layout and member function for CKLight and CKCamera.
- register CKLight and CKCamera in CKGlobals to let CK engine can recognize them.
- modify EnumsMigration to add new 2 enums for CKLight and CKCamera.
 2024-12-23 22:21:50 +08:00
yyc12345
d29d40448b fix: fix CMake install path issue. 
- fix the wrong reference in CMake script which install lib target into wrong directory.
- add file, change CMake script and modify header file for preparing develop of CKLight and CKCamera.
- fix doc typo.
 2024-12-23 09:23:46 +08:00
yyc12345
305c0b1b65 doc: fix README 2024-11-08 15:17:45 +08:00
yyc12345
6f7202a86b feat: improve BMap bindings. 
- Add IEquatable<T> interface for BMapSharp 2 abstract base classes to make they can be used in HashSet or Dictionary.
- Add corresponding testbench for this new added interface to make sure it works.
- Also add set and dict test for PyBMap although it has been proven works.
 2024-11-08 14:58:50 +08:00
yyc12345
512729ed05 feat: improve PyBMap 
- re-raise exception for run out of next() function to make end user know this is their fault, not PyBMap.
- write some primitive type getter setter for short code and less latent bugs.
- remove bmfile parameter in BMMeshTrans::Parse.
 2024-11-07 20:56:16 +08:00
yyc12345
e2e7121c16 feat: update PyBMap and its testbench 
- update PyBMap testbench according to BMapSharp testbench.
- use some wrapper function to fetch commonly used type in PyBMap to reduce line count.
- re-place some utils functions in PyBMap.
 2024-11-07 17:28:11 +08:00
yyc12345
9dd46b88d9 dep: update stb. 
- use a nasty way to update stb-image library (do not use new resize library, use moved depracted one. because idk how to program with new one. that lack doc).
 2024-11-04 17:19:51 +08:00
yyc12345
7e7b21544d chore: update build script. 2024-11-04 14:58:53 +08:00
yyc12345
e72102496b fix: update YYCC dependency 
- move EnumsHelper into YYCC because it is widely used.
- rename all calling to EnumsHelper due to this modification.
- add version checker in code to make sure that user use correct YYCC library to compile.
- modify some include syntax because the include directory layout changes of YYCC.
- update CMake script to resolve the bug that we can not export LibCmo (thanks doyaGu and BLumia).
 2024-11-03 19:05:27 +08:00
yyc12345
73f1a1f829 fix: fix fatal layout issue about VxColor. 
- fix wrong memory layout of VxColor.
 2024-11-01 13:31:03 +08:00
yyc12345
33dc9a54be feat: finish BMapSharp 
- basically finish BMapSharp bindings however done test does not cover all scenarios.
 2024-11-01 11:13:05 +08:00
yyc12345
6eb95ddd1f feat: update BMapSharp 
- finish BMMesh bindings.
- finish a half of BMMeshTrans bindings.
- use getGenericValue and setGenericValue for most bindings.
 2024-11-01 10:48:45 +08:00
yyc12345
e8fedc8bff feat: update BMapSharp 
- update virtools type defines in BMapSharp. expand its ctor for convenient usage.
- finish BMMaterial bindings.
- create a generic value getter setter for convenient calling.
- fix codegen error of BMapSharp (accident fallthrough for CKBYTE type and wrong marshal type for enum type).
 2024-10-31 17:15:06 +08:00
yyc12345
74268d4ad4 feat: update BMapSharp 
- finish BMTexture bindings and quater of BMMaterial.
- fix compile manual.
 2024-10-30 15:41:17 +08:00
yyc12345
f7644319f0 doc: update build manual 2024-10-29 17:44:55 +08:00
95 changed files with 4445 additions and 1872 deletions
Expand all files Collapse all files

3
.gitignore vendored
View File

@ -5,6 +5,9 @@
*.nms
*.vmo
# Ignore CMake generated version header
LibCmo/VTVersion.hpp
# Ignore temporary Visual Studio files and folders
temp/
out/

174
BMap/BMExports.cpp
View File

@ -42,10 +42,13 @@ _Ty CheckGeneralObject(BMap::BMFile* possible_bmfile, LibCmo::CK2::CK_ID possibl
#define CheckCKObject(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CKObject*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_OBJECT)
#define CheckCKGroup(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CKGroup*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_GROUP)
#define CheckCK3dEntity(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CK3dEntity*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_3DENTITY)
#define CheckCK3dObject(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CK3dObject*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_3DOBJECT)
#define CheckCKMesh(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CKMesh*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_MESH)
#define CheckCKMaterial(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CKMaterial*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_MATERIAL)
#define CheckCKTexture(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CKTexture*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_TEXTURE)
#define CheckCKLight(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CKLight*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_LIGHT)
#define CheckCKTargetLight(bmfile, objid) CheckGeneralObject<LibCmo::CK2::ObjImpls::CKTargetLight*>(bmfile, objid, LibCmo::CK2::CK_CLASSID::CKCID_TARGETLIGHT)
#pragma endregion
@ -143,7 +146,7 @@ bool BMFile_Create(
bool BMFile_Save(
BMPARAM_IN(BMap::BMFile*, map_file),
BMPARAM_IN(LibCmo::CKSTRING, file_name),
BMPARAM_IN(LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS, texture_save_opt),
BMPARAM_IN(LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS, texture_save_opt),
BMPARAM_IN(bool, use_compress),
BMPARAM_IN(LibCmo::CKINT, compreess_level)) {
if (!CheckBMFile(map_file)) return false;
@ -234,6 +237,21 @@ bool BMFile_CreateTexture(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(LibCmo::CK2::CK
BMPARAM_OUT_ASSIGN(out_id, bmfile->CreateTexture());
return true;
}
bool BMFile_GetTargetLightCount(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(LibCmo::CKDWORD, out_count)) {
if (!CheckBMFile(bmfile)) return false;
BMPARAM_OUT_ASSIGN(out_count, bmfile->GetTargetLightCount());
return true;
}
bool BMFile_GetTargetLight(BMPARAM_FILE_DECL(bmfile), BMPARAM_IN(LibCmo::CKDWORD, idx), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_id)) {
if (!CheckBMFile(bmfile)) return false;
BMPARAM_OUT_ASSIGN(out_id, bmfile->GetTargetLight(idx));
return true;
}
bool BMFile_CreateTargetLight(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_id)) {
if (!CheckBMFile(bmfile)) return false;
BMPARAM_OUT_ASSIGN(out_id, bmfile->CreateTargetLight());
return true;
}
#pragma endregion
@ -841,34 +859,34 @@ bool BMMesh_SetMaterialSlot(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCm
#pragma endregion
#pragma region CK3dObject
#pragma region CK3dEntity
bool BM3dObject_GetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VxMatrix, out_mat)) {
auto obj = CheckCK3dObject(bmfile, objid);
bool BM3dEntity_GetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VxMatrix, out_mat)) {
auto obj = CheckCK3dEntity(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_mat, obj->GetWorldMatrix());
return true;
}
bool BM3dObject_SetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VxMatrix, mat)) {
auto obj = CheckCK3dObject(bmfile, objid);
bool BM3dEntity_SetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VxMatrix, mat)) {
auto obj = CheckCK3dEntity(bmfile, objid);
if (obj == nullptr) return false;
obj->SetWorldMatrix(mat);
return true;
}
bool BM3dObject_GetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_meshid)) {
auto obj = CheckCK3dObject(bmfile, objid);
bool BM3dEntity_GetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_meshid)) {
auto obj = CheckCK3dEntity(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_meshid, SafeGetID(obj->GetCurrentMesh()));
return true;
}
bool BM3dObject_SetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CK2::CK_ID, meshid)) {
auto obj = CheckCK3dObject(bmfile, objid);
bool BM3dEntity_SetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CK2::CK_ID, meshid)) {
auto obj = CheckCK3dEntity(bmfile, objid);
auto meshobj = CheckCKMesh(bmfile, meshid);
if (obj == nullptr /*|| meshobj == nullptr*/) return false; //allow nullptr assign
@ -876,16 +894,16 @@ bool BM3dObject_SetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(Li
return true;
}
bool BM3dObject_GetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(bool, out_isVisible)) {
auto obj = CheckCK3dObject(bmfile, objid);
bool BM3dEntity_GetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(bool, out_isVisible)) {
auto obj = CheckCK3dEntity(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_isVisible, obj->IsVisible());
return true;
}
bool BM3dObject_SetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(bool, is_visible)) {
auto obj = CheckCK3dObject(bmfile, objid);
bool BM3dEntity_SetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(bool, is_visible)) {
auto obj = CheckCK3dEntity(bmfile, objid);
if (obj == nullptr) return false;
obj->Show(is_visible ? LibCmo::CK2::CK_OBJECT_SHOWOPTION::CKSHOW : LibCmo::CK2::CK_OBJECT_SHOWOPTION::CKHIDE);
@ -894,3 +912,131 @@ bool BM3dObject_SetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(boo
#pragma endregion
#pragma region CK3dObject
//nothing
#pragma endregion
#pragma region CKLight
bool BMLight_GetType(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VXLIGHT_TYPE, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetType());
return true;
}
bool BMLight_SetType(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VXLIGHT_TYPE, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetType(val);
return true;
}
bool BMLight_GetColor(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VxColor, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetColor());
return true;
}
bool BMLight_SetColor(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VxColor, col)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetColor(col);
return true;
}
bool BMLight_GetConstantAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetConstantAttenuation());
return true;
}
bool BMLight_SetConstantAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetConstantAttenuation(val);
return true;
}
bool BMLight_GetLinearAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetLinearAttenuation());
return true;
}
bool BMLight_SetLinearAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetLinearAttenuation(val);
return true;
}
bool BMLight_GetQuadraticAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetQuadraticAttenuation());
return true;
}
bool BMLight_SetQuadraticAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetQuadraticAttenuation(val);
return true;
}
bool BMLight_GetRange(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetRange());
return true;
}
bool BMLight_SetRange(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetRange(val);
return true;
}
bool BMLight_GetHotSpot(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetHotSpot());
return true;
}
bool BMLight_SetHotSpot(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetHotSpot(val);
return true;
}
bool BMLight_GetFalloff(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetFalloff());
return true;
}
bool BMLight_SetFalloff(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetFalloff(val);
return true;
}
bool BMLight_GetFalloffShape(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
BMPARAM_OUT_ASSIGN(out_val, obj->GetFalloffShape());
return true;
}
bool BMLight_SetFalloffShape(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val)) {
auto obj = CheckCKLight(bmfile, objid);
if (obj == nullptr) return false;
obj->SetFalloffShape(val);
return true;
}
#pragma endregion
#pragma region CKTargetLight
// nothing
#pragma endregion

62
BMap/BMExports.hpp
View File

@ -51,7 +51,7 @@ Each CK_ID also should be used with its corresponding BMFile*, because each BMfi
// Do nothing and hope for the best?
#define BMAP_RAW_EXPORT
#define BMAP_RAW_IMPORT
#pragma error "Unknown dynamic link import/export semantics."
#error "Unknown dynamic link import/export semantics."
#endif
// Choosee import or export command according to special macro.
@ -81,7 +81,9 @@ Each CK_ID also should be used with its corresponding BMFile*, because each BMfi
/** Declare an input parameter */
#define BMPARAM_IN(_t, _name) _t _name
/**
@brief
Declare an output parameter.
@details
A pointer will be added automatically for caller receive it.
See BMPARAM_OUT_ASSIGN and BMPARAM_OUT_VAL to know how to use output param in function body.
@remark
@ -91,8 +93,8 @@ bool some_interface_func(BMPARAM_OUT(Type_t, param_name)) {
BMPARAM_OUT_ASSIGN(param_name, some_value); // assign to out param.
return BMPARAM_OUT_VAL(param_name) != other_value; // use out param value.
}
@see BMPARAM_OUT_ASSIGN, BMPARAM_OUT_VAL
```
@see BMPARAM_OUT_ASSIGN, BMPARAM_OUT_VAL
*/
#define BMPARAM_OUT(_t, _name) _t* _name
/** Assign value for out param in function body. */
@ -154,6 +156,9 @@ BMAP_EXPORT bool BMFile_CreateMaterial(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(Li
BMAP_EXPORT bool BMFile_GetTextureCount(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(LibCmo::CKDWORD, out_count));
BMAP_EXPORT bool BMFile_GetTexture(BMPARAM_FILE_DECL(bmfile), BMPARAM_IN(LibCmo::CKDWORD, idx), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_id));
BMAP_EXPORT bool BMFile_CreateTexture(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_id));
BMAP_EXPORT bool BMFile_GetTargetLightCount(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(LibCmo::CKDWORD, out_count));
BMAP_EXPORT bool BMFile_GetTargetLight(BMPARAM_FILE_DECL(bmfile), BMPARAM_IN(LibCmo::CKDWORD, idx), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_id));
BMAP_EXPORT bool BMFile_CreateTargetLight(BMPARAM_FILE_DECL(bmfile), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_id));
#pragma endregion
@ -285,13 +290,52 @@ BMAP_EXPORT bool BMMesh_SetMaterialSlot(BMPARAM_OBJECT_DECL(bmfile, objid), BMPA
#pragma endregion
#pragma region CK3dObject
#pragma region CK3dEntity
BMAP_EXPORT bool BM3dObject_GetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VxMatrix, out_mat));
BMAP_EXPORT bool BM3dObject_SetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VxMatrix, mat));
BMAP_EXPORT bool BM3dObject_GetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_meshid));
BMAP_EXPORT bool BM3dObject_SetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CK2::CK_ID, meshid));
BMAP_EXPORT bool BM3dObject_GetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(bool, out_isVisible));
BMAP_EXPORT bool BM3dObject_SetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(bool, is_visible));
BMAP_EXPORT bool BM3dEntity_GetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VxMatrix, out_mat));
BMAP_EXPORT bool BM3dEntity_SetWorldMatrix(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VxMatrix, mat));
BMAP_EXPORT bool BM3dEntity_GetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CK2::CK_ID, out_meshid));
BMAP_EXPORT bool BM3dEntity_SetCurrentMesh(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CK2::CK_ID, meshid));
BMAP_EXPORT bool BM3dEntity_GetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(bool, out_isVisible));
BMAP_EXPORT bool BM3dEntity_SetVisibility(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(bool, is_visible));
#pragma endregion
#pragma region CK3dObject
// nothing
#pragma endregion
#pragma region CKLight
BMAP_EXPORT bool BMLight_GetType(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VXLIGHT_TYPE, out_val));
BMAP_EXPORT bool BMLight_SetType(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VXLIGHT_TYPE, val));
BMAP_EXPORT bool BMLight_GetColor(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::VxMath::VxColor, out_val));
BMAP_EXPORT bool BMLight_SetColor(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::VxMath::VxColor, col));
BMAP_EXPORT bool BMLight_GetConstantAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val));
BMAP_EXPORT bool BMLight_SetConstantAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val));
BMAP_EXPORT bool BMLight_GetLinearAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val));
BMAP_EXPORT bool BMLight_SetLinearAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val));
BMAP_EXPORT bool BMLight_GetQuadraticAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val));
BMAP_EXPORT bool BMLight_SetQuadraticAttenuation(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val));
BMAP_EXPORT bool BMLight_GetRange(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val));
BMAP_EXPORT bool BMLight_SetRange(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val));
BMAP_EXPORT bool BMLight_GetHotSpot(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val));
BMAP_EXPORT bool BMLight_SetHotSpot(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val));
BMAP_EXPORT bool BMLight_GetFalloff(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val));
BMAP_EXPORT bool BMLight_SetFalloff(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val));
BMAP_EXPORT bool BMLight_GetFalloffShape(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_OUT(LibCmo::CKFLOAT, out_val));
BMAP_EXPORT bool BMLight_SetFalloffShape(BMPARAM_OBJECT_DECL(bmfile, objid), BMPARAM_IN(LibCmo::CKFLOAT, val));
#pragma endregion
#pragma region CKTargetLight
// nothing
#pragma endregion

386
BMap/BMap.cpp
View File

@ -2,6 +2,247 @@
namespace BMap {
#pragma region BMfile
BMFile::BMFile(LibCmo::CKSTRING temp_folder, LibCmo::CKSTRING texture_folder, NakedOutputCallback raw_callback, LibCmo::CKDWORD encoding_count, LibCmo::CKSTRING* encodings, bool is_loader) :
m_IsInitError(false), m_IsLoader(is_loader), m_HasLoaded(false), m_HasSaved(false), m_Context(nullptr) {
m_Context = new LibCmo::CK2::CKContext();
// binding callback with lambda wrapper.
// check whether callback is nullptr.
m_IsInitError = m_IsInitError || (raw_callback == nullptr);
if (raw_callback != nullptr) {
m_Context->SetOutputCallback([raw_callback](LibCmo::CKSTRING strl) -> void {
raw_callback(strl);
});
}
// set temp folder and texture folder
auto pm = m_Context->GetPathManager();
m_IsInitError = m_IsInitError || !pm->AddPath(texture_folder);
m_IsInitError = m_IsInitError || !pm->SetTempFolder(temp_folder);
// set encoding
LibCmo::XContainer::XArray<LibCmo::XContainer::XString> cache;
for (LibCmo::CKDWORD i = 0; i < encoding_count; ++i) {
if (encodings[i] != nullptr)
cache.emplace_back(encodings[i]);
}
m_Context->SetEncoding(cache);
m_IsInitError = m_IsInitError || !m_Context->IsValidEncoding();
// set default texture save mode is external
m_Context->SetGlobalImagesSaveOptions(LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS::CKTEXTURE_EXTERNAL);
// set default file write mode is whole compressed
m_Context->SetFileWriteMode(LibCmo::CK2::CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED);
}
BMFile::~BMFile() {
delete m_Context;
}
#pragma region Safe Check Function
bool BMFile::IsInitError() {
return m_IsInitError;
}
bool BMFile::CanExecLoad() {
// no error, is loader, no prev load
return (!m_IsInitError && m_IsLoader && !m_HasLoaded);
}
bool BMFile::CanExecSave() {
// no error, is saver, no prev save
return (!m_IsInitError && !m_IsLoader && !m_HasSaved);
}
bool BMFile::CanExecLoaderVisitor() {
// no error, is loader, has loaded
return (!m_IsInitError && m_IsLoader && m_HasLoaded);
}
bool BMFile::CanExecSaverVisitor() {
// no error, is saver, not saveed yet
// same as CanExecSave
return (!m_IsInitError && !m_IsLoader && !m_HasSaved);
}
#pragma endregion
#pragma region Help Function
bool BMFile::Load(LibCmo::CKSTRING filename) {
if (!CanExecLoad()) return false;
// create temp ckfile and load
LibCmo::CK2::CKFileReader reader(m_Context);
LibCmo::CK2::CKERROR err = reader.DeepLoad(filename);
// detect error
if (err != LibCmo::CK2::CKERROR::CKERR_OK) {
// failed. clear document and return false
m_Context->ClearAll();
return false;
}
// sync data list to our list
m_ObjGroups.clear();
m_Obj3dObjects.clear();
m_ObjMeshes.clear();
m_ObjMaterials.clear();
m_ObjTextures.clear();
m_ObjTargetLights.clear();
for (const auto& fileobj : reader.GetFileObjects()) {
if (fileobj.ObjPtr == nullptr) continue;
switch (fileobj.ObjectCid) {
case LibCmo::CK2::CK_CLASSID::CKCID_GROUP:
m_ObjGroups.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_3DOBJECT:
m_Obj3dObjects.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_MESH:
m_ObjMeshes.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_MATERIAL:
m_ObjMaterials.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_TEXTURE:
m_ObjTextures.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_TARGETLIGHT:
m_ObjTargetLights.emplace_back(fileobj.CreatedObjectId);
break;
default:
break; // skip unknow objects
}
}
m_HasLoaded = true;
return true;
}
bool BMFile::Save(LibCmo::CKSTRING filename, LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS texture_save_opt, bool use_compress, LibCmo::CKINT compress_level) {
if (!CanExecSave()) return false;
// create temp writer
LibCmo::CK2::CKFileWriter writer(m_Context);
// fill object data
for (const auto& id : m_ObjGroups) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_Obj3dObjects) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_ObjMeshes) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_ObjMaterials) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_ObjTextures) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id :m_ObjTargetLights) {
writer.AddSavedObject(m_Context->GetObject(id));
}
// set global texture save mode
m_Context->SetGlobalImagesSaveOptions(texture_save_opt);
// set compress level
if (use_compress) {
m_Context->SetFileWriteMode(LibCmo::CK2::CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED);
m_Context->SetCompressionLevel(compress_level);
} else {
m_Context->SetFileWriteMode(LibCmo::CK2::CK_FILE_WRITEMODE::CKFILE_UNCOMPRESSED);
}
// save to file and detect error
LibCmo::CK2::CKERROR err = writer.Save(filename);
// return with error detect.
m_HasSaved = true;
return err == LibCmo::CK2::CKERROR::CKERR_OK;
}
LibCmo::CK2::ObjImpls::CKObject* BMFile::GetObjectPtr(LibCmo::CK2::CK_ID objid) {
// we fetch object from CKContext to get better performance
LibCmo::CK2::ObjImpls::CKObject* obj = m_Context->GetObject(objid);
// however, we can not directly return the pointer fetched fron CKContext.
// BMFile only provide limited type visiting, we must make sure it provided ID also is existed in out stored list.
// so we check its type here. if type is not matched, we reset it to nullptr.
if (obj != nullptr) {
switch (obj->GetClassID()) {
case LibCmo::CK2::CK_CLASSID::CKCID_GROUP:
case LibCmo::CK2::CK_CLASSID::CKCID_3DOBJECT:
case LibCmo::CK2::CK_CLASSID::CKCID_MESH:
case LibCmo::CK2::CK_CLASSID::CKCID_MATERIAL:
case LibCmo::CK2::CK_CLASSID::CKCID_TEXTURE:
case LibCmo::CK2::CK_CLASSID::CKCID_TARGETLIGHT:
break; // okey. do nothing
default:
// this object should not be exposed to outside, reset it to nullptr
obj = nullptr;
break;
}
}
// return result
return obj;
}
#pragma endregion
#pragma region Visitor
LibCmo::CKDWORD BMFile::CommonGetObjectCount(std::vector<LibCmo::CK2::CK_ID>& container) {
// only available in loader
if (!CanExecLoaderVisitor()) return 0;
return static_cast<LibCmo::CKDWORD>(container.size());
}
LibCmo::CK2::CK_ID BMFile::CommonGetObject(std::vector<LibCmo::CK2::CK_ID>& container, LibCmo::CKDWORD idx) {
// only available in loader
if (!CanExecLoaderVisitor()) return 0;
return container[idx];
}
LibCmo::CK2::CK_ID BMFile::CommonCreateObject(std::vector<LibCmo::CK2::CK_ID>& container, LibCmo::CK2::CK_CLASSID cid) {
// only available in saver
if (!CanExecSaverVisitor()) return 0;
// try create object and get its pointer
LibCmo::CK2::ObjImpls::CKObject* obj = m_Context->CreateObject(cid, nullptr);
// check creation validation
if (obj == nullptr) return 0;
// if success, write its id and emplace its id into list
LibCmo::CK2::CK_ID objid = obj->GetID();
container.emplace_back(objid);
return objid;
}
LibCmo::CKDWORD BMFile::GetGroupCount() { return CommonGetObjectCount(m_ObjGroups); }
LibCmo::CK2::CK_ID BMFile::GetGroup(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjGroups, idx); }
LibCmo::CK2::CK_ID BMFile::CreateGroup() { return CommonCreateObject(m_ObjGroups, LibCmo::CK2::CK_CLASSID::CKCID_GROUP); }
LibCmo::CKDWORD BMFile::Get3dObjectCount() { return CommonGetObjectCount(m_Obj3dObjects); }
LibCmo::CK2::CK_ID BMFile::Get3dObject(LibCmo::CKDWORD idx) { return CommonGetObject(m_Obj3dObjects, idx); }
LibCmo::CK2::CK_ID BMFile::Create3dObject() { return CommonCreateObject(m_Obj3dObjects, LibCmo::CK2::CK_CLASSID::CKCID_3DOBJECT); }
LibCmo::CKDWORD BMFile::GetMeshCount() { return CommonGetObjectCount(m_ObjMeshes); }
LibCmo::CK2::CK_ID BMFile::GetMesh(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjMeshes, idx); }
LibCmo::CK2::CK_ID BMFile::CreateMesh() { return CommonCreateObject(m_ObjMeshes, LibCmo::CK2::CK_CLASSID::CKCID_MESH); }
LibCmo::CKDWORD BMFile::GetMaterialCount() { return CommonGetObjectCount(m_ObjMaterials); }
LibCmo::CK2::CK_ID BMFile::GetMaterial(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjMaterials, idx); }
LibCmo::CK2::CK_ID BMFile::CreateMaterial() { return CommonCreateObject(m_ObjMaterials, LibCmo::CK2::CK_CLASSID::CKCID_MATERIAL); }
LibCmo::CKDWORD BMFile::GetTextureCount() { return CommonGetObjectCount(m_ObjTextures); }
LibCmo::CK2::CK_ID BMFile::GetTexture(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjTextures, idx); }
LibCmo::CK2::CK_ID BMFile::CreateTexture() { return CommonCreateObject(m_ObjTextures, LibCmo::CK2::CK_CLASSID::CKCID_TEXTURE); }
LibCmo::CKDWORD BMFile::GetTargetLightCount() { return CommonGetObjectCount(m_ObjTargetLights); }
LibCmo::CK2::CK_ID BMFile::GetTargetLight(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjTargetLights, idx); }
LibCmo::CK2::CK_ID BMFile::CreateTargetLight() { return CommonCreateObject(m_ObjTargetLights, LibCmo::CK2::CK_CLASSID::CKCID_TARGETLIGHT); }
#pragma endregion
#pragma endregion
#pragma region BMMeshTransition
BMMeshTransition::TransitionVertex::TransitionVertex(
@ -229,149 +470,4 @@ namespace BMap {
#pragma endregion
#pragma region BMfile
BMFile::BMFile(LibCmo::CKSTRING temp_folder, LibCmo::CKSTRING texture_folder, NakedOutputCallback raw_callback, LibCmo::CKDWORD encoding_count, LibCmo::CKSTRING* encodings, bool is_loader) :
m_IsInitError(false), m_IsLoader(is_loader), m_HasLoaded(false), m_HasSaved(false), m_Context(nullptr) {
m_Context = new LibCmo::CK2::CKContext();
// binding callback with lambda wrapper.
// check whether callback is nullptr.
m_IsInitError = m_IsInitError || (raw_callback == nullptr);
if (raw_callback != nullptr) {
m_Context->SetOutputCallback([raw_callback](LibCmo::CKSTRING strl) -> void {
raw_callback(strl);
});
}
// set temp folder and texture folder
auto pm = m_Context->GetPathManager();
m_IsInitError = m_IsInitError || !pm->AddPath(texture_folder);
m_IsInitError = m_IsInitError || !pm->SetTempFolder(temp_folder);
// set encoding
LibCmo::XContainer::XArray<LibCmo::XContainer::XString> cache;
for (LibCmo::CKDWORD i = 0; i < encoding_count; ++i) {
if (encodings[i] != nullptr)
cache.emplace_back(encodings[i]);
}
m_Context->SetEncoding(cache);
m_IsInitError = m_IsInitError || !m_Context->IsValidEncoding();
// set default texture save mode is external
m_Context->SetGlobalImagesSaveOptions(LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS::CKTEXTURE_EXTERNAL);
// set default file write mode is whole compressed
m_Context->SetFileWriteMode(LibCmo::CK2::CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED);
}
BMFile::~BMFile() {
delete m_Context;
}
bool BMFile::Load(LibCmo::CKSTRING filename) {
if (!CanExecLoad()) return false;
// create temp ckfile and load
LibCmo::CK2::CKFileReader reader(m_Context);
LibCmo::CK2::CKERROR err = reader.DeepLoad(filename);
// detect error
if (err != LibCmo::CK2::CKERROR::CKERR_OK) {
// failed. clear document and return false
m_Context->ClearAll();
return false;
}
// sync data list to our list
m_ObjGroups.clear();
m_Obj3dObjects.clear();
m_ObjMeshs.clear();
m_ObjMaterials.clear();
m_ObjTextures.clear();
for (const auto& fileobj : reader.GetFileObjects()) {
if (fileobj.ObjPtr == nullptr) continue;
switch (fileobj.ObjectCid) {
case LibCmo::CK2::CK_CLASSID::CKCID_GROUP:
m_ObjGroups.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_3DOBJECT:
m_Obj3dObjects.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_MESH:
m_ObjMeshs.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_MATERIAL:
m_ObjMaterials.emplace_back(fileobj.CreatedObjectId);
break;
case LibCmo::CK2::CK_CLASSID::CKCID_TEXTURE:
m_ObjTextures.emplace_back(fileobj.CreatedObjectId);
break;
default:
break; // skip unknow objects
}
}
m_HasLoaded = true;
return true;
}
bool BMFile::Save(LibCmo::CKSTRING filename, LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS texture_save_opt, bool use_compress, LibCmo::CKINT compress_level) {
if (!CanExecSave()) return false;
// create temp writer
LibCmo::CK2::CKFileWriter writer(m_Context);
// fill object data
for (const auto& id : m_ObjGroups) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_Obj3dObjects) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_ObjMeshs) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_ObjMaterials) {
writer.AddSavedObject(m_Context->GetObject(id));
}
for (const auto& id : m_ObjTextures) {
writer.AddSavedObject(m_Context->GetObject(id));
}
// set global texture save mode
m_Context->SetGlobalImagesSaveOptions(texture_save_opt);
// set compress level
if (use_compress) {
m_Context->SetFileWriteMode(LibCmo::CK2::CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED);
m_Context->SetCompressionLevel(compress_level);
} else {
m_Context->SetFileWriteMode(LibCmo::CK2::CK_FILE_WRITEMODE::CKFILE_UNCOMPRESSED);
}
// save to file and detect error
LibCmo::CK2::CKERROR err = writer.Save(filename);
// return with error detect.
m_HasSaved = true;
return err == LibCmo::CK2::CKERROR::CKERR_OK;
}
LibCmo::CKDWORD BMFile::GetGroupCount() { return CommonGetObjectCount(m_ObjGroups); }
LibCmo::CK2::CK_ID BMFile::GetGroup(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjGroups, idx); }
LibCmo::CK2::CK_ID BMFile::CreateGroup() { return CommonCreateObject(m_ObjGroups, LibCmo::CK2::CK_CLASSID::CKCID_GROUP); }
LibCmo::CKDWORD BMFile::Get3dObjectCount() { return CommonGetObjectCount(m_Obj3dObjects); }
LibCmo::CK2::CK_ID BMFile::Get3dObject(LibCmo::CKDWORD idx) { return CommonGetObject(m_Obj3dObjects, idx); }
LibCmo::CK2::CK_ID BMFile::Create3dObject() { return CommonCreateObject(m_Obj3dObjects, LibCmo::CK2::CK_CLASSID::CKCID_3DOBJECT); }
LibCmo::CKDWORD BMFile::GetMeshCount() { return CommonGetObjectCount(m_ObjMeshs); }
LibCmo::CK2::CK_ID BMFile::GetMesh(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjMeshs, idx); }
LibCmo::CK2::CK_ID BMFile::CreateMesh() { return CommonCreateObject(m_ObjMeshs, LibCmo::CK2::CK_CLASSID::CKCID_MESH); }
LibCmo::CKDWORD BMFile::GetMaterialCount() { return CommonGetObjectCount(m_ObjMaterials); }
LibCmo::CK2::CK_ID BMFile::GetMaterial(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjMaterials, idx); }
LibCmo::CK2::CK_ID BMFile::CreateMaterial() { return CommonCreateObject(m_ObjMaterials, LibCmo::CK2::CK_CLASSID::CKCID_MATERIAL); }
LibCmo::CKDWORD BMFile::GetTextureCount() { return CommonGetObjectCount(m_ObjTextures); }
LibCmo::CK2::CK_ID BMFile::GetTexture(LibCmo::CKDWORD idx) { return CommonGetObject(m_ObjTextures, idx); }
LibCmo::CK2::CK_ID BMFile::CreateTexture() { return CommonCreateObject(m_ObjTextures, LibCmo::CK2::CK_CLASSID::CKCID_TEXTURE); }
#pragma endregion
}

134
BMap/BMap.hpp
View File

@ -16,93 +16,95 @@ namespace BMap {
~BMFile();
YYCC_DEL_CLS_COPY_MOVE(BMFile);
// ===== safe visit functions =====
// ===== Safe Check Function =====
/**
Safe Visit Function will make sure this class is visited with safe mode.
These function will block all other functions if this class init failed.
Or, block any more operations if this class has loaded or saved once. In this time you only can free this class
/*
Safe Check Function will make sure this class is visited in safe mode.
Some of them are exposed to outside to report current status of this class, for example, whether there is a issue when initialize this class.
And some of them are used by internal functions to make sure there is a safe environment to execute corresponding functions.
For example, #Load function will use #CanExecLoad to detect whether it can execute loading process.
*/
public:
bool IsInitError() {
return m_IsInitError;
}
private:
bool CanExecLoad() {
// no error, is loader, no prev load
return (!m_IsInitError && m_IsLoader && !m_HasLoaded);
}
bool CanExecSave() {
// no error, is saver, no prev save
return (!m_IsInitError && !m_IsLoader && !m_HasSaved);
}
bool CanExecLoaderVisitor() {
// no error, is loader, has loaded
return (!m_IsInitError && m_IsLoader && m_HasLoaded);
}
bool CanExecSaverVisitor() {
// no error, is saver, not saveed yet
// same as CanExecSave
return (!m_IsInitError && !m_IsLoader && !m_HasSaved);
}
/**
* @brief Check whether there is an error when initializing this class.
* @details
* This class is exposed for outside code to check.
* Internal code should use one of following 4 private check functions to check environment.
* @return True if there is an error when initializing this class.
*/
bool IsInitError();
private:
/**
* @brief True if an error occurs when initializing this class.
* @brief Check whether it's okey to execute #Load function.
* @return True if it is okey.
*/
bool m_IsInitError;
bool CanExecLoad();
/**
* @brief True if this class is a reader.
* @brief Check whether it's okey to execute #Save function.
* @return True if it is okey.
*/
bool m_IsLoader;
bool CanExecSave();
/**
* @brief True if this class has read. Only valid when this class is reader.
* @brief Check whether it's okey to execute Loader-related function.
* @details
* Due to implementation, saving file and loading file are use the same class, BMFile to represent.
* So obviously you can visit loader-related function in a saver.
* This operation is illegal. So we need block these operation.
* This is what this function does. Provide the condition which raise blocking.
* @return True if it is okey.
*/
bool m_HasLoaded;
bool CanExecLoaderVisitor();
/**
* @brief True if this class has written. Only valid when this class is writer.
* @brief Check whether it's okey to execute Saver-related function.
* @return True if it is okey.
* @see CanExecLoaderVisitor
*/
bool m_HasSaved;
bool CanExecSaverVisitor();
// ===== help functions =====
private:
bool m_IsInitError; /**< True if an error occurs when initializing this class. */
bool m_IsLoader; /**< True if this class is a reader. */
bool m_HasLoaded; /**< True if this class has read. It's undefined behavior when visiting this variable if this class is not reader. */
bool m_HasSaved; /**< True if this class has written. It's undefined behavior when visiting this variable if this class is not writer. */
// ===== Help Function =====
public:
/**
* @brief Load document to this class.
* @param[in] filename The path to file.
* @return True if no error, otherwise false.
*/
bool Load(LibCmo::CKSTRING filename);
/**
* @brief Save current class into document.
* @param[in] filename The path to file.
* @param[in] texture_save_opt Global texture save option
* @param[in] use_compress True if use compression when saving.
* @param[in] compress_level The compress level if you choose using compression in file.
* @return
*/
bool Save(LibCmo::CKSTRING filename, LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS texture_save_opt, bool use_compress, LibCmo::CKINT compress_level);
LibCmo::CK2::ObjImpls::CKObject* GetObjectPtr(LibCmo::CK2::CK_ID objid) {
return m_Context->GetObject(objid);;
}
/**
* @brief Get object pointer from given ID.
* @details
* This function is specially exposed to outside for detecting whether given ID is valid in BMFile.
* Also used by BMMeshTransition to get essential objects.
* @param[in] objid The ID of object.
* @return The pointer to given ID represented object. nullptr if not found.
*/
LibCmo::CK2::ObjImpls::CKObject* GetObjectPtr(LibCmo::CK2::CK_ID objid);
// ===== visitors =====
// ===== Visitor =====
private:
LibCmo::CKDWORD CommonGetObjectCount(std::vector<LibCmo::CK2::CK_ID>& container) {
// only available in loader
if (!CanExecLoaderVisitor()) return 0;
return static_cast<LibCmo::CKDWORD>(container.size());
}
LibCmo::CK2::CK_ID CommonGetObject(std::vector<LibCmo::CK2::CK_ID>& container, LibCmo::CKDWORD idx) {
// only available in loader
if (!CanExecLoaderVisitor()) return 0;
return container[idx];
}
LibCmo::CK2::CK_ID CommonCreateObject(std::vector<LibCmo::CK2::CK_ID>& container, LibCmo::CK2::CK_CLASSID cid) {
// only available in saver
if (!CanExecSaverVisitor()) return 0;
LibCmo::CKDWORD CommonGetObjectCount(std::vector<LibCmo::CK2::CK_ID>& container);
LibCmo::CK2::CK_ID CommonGetObject(std::vector<LibCmo::CK2::CK_ID>& container, LibCmo::CKDWORD idx);
LibCmo::CK2::CK_ID CommonCreateObject(std::vector<LibCmo::CK2::CK_ID>& container, LibCmo::CK2::CK_CLASSID cid);
// try create object and get its pointer
LibCmo::CK2::ObjImpls::CKObject* obj = m_Context->CreateObject(cid, nullptr);
// check creation validation
if (obj == nullptr) return 0;
// if success, write its id and emplace its id into list
LibCmo::CK2::CK_ID objid = obj->GetID();
container.emplace_back(objid);
return objid;
}
public:
LibCmo::CKDWORD GetGroupCount();
LibCmo::CK2::CK_ID GetGroup(LibCmo::CKDWORD idx);
@ -119,15 +121,19 @@ namespace BMap {
LibCmo::CKDWORD GetTextureCount();
LibCmo::CK2::CK_ID GetTexture(LibCmo::CKDWORD idx);
LibCmo::CK2::CK_ID CreateTexture();
LibCmo::CKDWORD GetTargetLightCount();
LibCmo::CK2::CK_ID GetTargetLight(LibCmo::CKDWORD idx);
LibCmo::CK2::CK_ID CreateTargetLight();
private:
LibCmo::CK2::CKContext* m_Context;
std::vector<LibCmo::CK2::CK_ID> m_ObjGroups;
std::vector<LibCmo::CK2::CK_ID> m_Obj3dObjects;
std::vector<LibCmo::CK2::CK_ID> m_ObjMeshs;
std::vector<LibCmo::CK2::CK_ID> m_ObjMeshes;
std::vector<LibCmo::CK2::CK_ID> m_ObjMaterials;
std::vector<LibCmo::CK2::CK_ID> m_ObjTextures;
std::vector<LibCmo::CK2::CK_ID> m_ObjTargetLights;
};

4
BMap/CMakeLists.txt
View File

@ -18,8 +18,6 @@ FILES
target_include_directories(BMap
PRIVATE
"${CMAKE_CURRENT_LIST_DIR}"
YYCC::YYCCommonplace
LibCmo
)
# Setup linked library infomation
target_link_libraries(BMap
@ -52,6 +50,6 @@ PRIVATE
# Install BMap only on Release mode
install(TARGETS BMap
CONFIGURATIONS Release
CONFIGURATIONS Release RelWithDebInfo MinSizeRel
RUNTIME DESTINATION ${YYCC_INSTALL_BIN_PATH}
)

262
BMapBindings/BMapSharp/BMapSharp/BMap.cs
View File

@ -293,7 +293,7 @@ namespace BMapSharp {
#region Function Defines
// ##### GENERATED FUNCTIONS BEGIN #####
/// <summary>BMInit</summary>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMInit", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
@ -336,7 +336,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMFile_Save", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMFile_Save([In, MarshalAs(UnmanagedType.SysInt)] IntPtr map_file, [In, MarshalAs(UnmanagedType.CustomMarshaler, MarshalTypeRef = typeof(BMStringMarshaler), MarshalCookie = "In")] string file_name, [In, MarshalAs(UnmanagedType.U4)] uint texture_save_opt, [In, MarshalAs(UnmanagedType.U1)] bool use_compress, [In, MarshalAs(UnmanagedType.I4)] int compreess_level);
internal static extern bool BMFile_Save([In, MarshalAs(UnmanagedType.SysInt)] IntPtr map_file, [In, MarshalAs(UnmanagedType.CustomMarshaler, MarshalTypeRef = typeof(BMStringMarshaler), MarshalCookie = "In")] string file_name, [In, MarshalAs(UnmanagedType.U4)] CK_TEXTURE_SAVEOPTIONS texture_save_opt, [In, MarshalAs(UnmanagedType.U1)] bool use_compress, [In, MarshalAs(UnmanagedType.I4)] int compreess_level);
/// <summary>BMFile_Free</summary>
/// <param name="map_file">Type: BMap::BMFile*. </param>
/// <returns>True if no error, otherwise False.</returns>
@ -453,6 +453,28 @@ namespace BMapSharp {
[DllImport(g_DllName, EntryPoint = "BMFile_CreateTexture", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMFile_CreateTexture([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [Out, MarshalAs(UnmanagedType.U4)] out uint out_id);
/// <summary>BMFile_GetTargetLightCount</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="out_count">Type: LibCmo::CKDWORD. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMFile_GetTargetLightCount", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMFile_GetTargetLightCount([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [Out, MarshalAs(UnmanagedType.U4)] out uint out_count);
/// <summary>BMFile_GetTargetLight</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="idx">Type: LibCmo::CKDWORD. </param>
/// <param name="out_id">Type: LibCmo::CK2::CK_ID. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMFile_GetTargetLight", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMFile_GetTargetLight([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint idx, [Out, MarshalAs(UnmanagedType.U4)] out uint out_id);
/// <summary>BMFile_CreateTargetLight</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="out_id">Type: LibCmo::CK2::CK_ID. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMFile_CreateTargetLight", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMFile_CreateTargetLight([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [Out, MarshalAs(UnmanagedType.U4)] out uint out_id);
/// <summary>BMMeshTrans_New</summary>
/// <param name="out_trans">Type: BMap::BMMeshTransition*. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
@ -636,7 +658,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMTexture_GetSaveOptions", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMTexture_GetSaveOptions([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_saveopt);
internal static extern bool BMTexture_GetSaveOptions([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out CK_TEXTURE_SAVEOPTIONS out_saveopt);
/// <summary>BMTexture_SetSaveOptions</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -644,7 +666,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMTexture_SetSaveOptions", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMTexture_SetSaveOptions([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint saveopt);
internal static extern bool BMTexture_SetSaveOptions([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] CK_TEXTURE_SAVEOPTIONS saveopt);
/// <summary>BMTexture_GetVideoFormat</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -652,7 +674,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMTexture_GetVideoFormat", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMTexture_GetVideoFormat([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_vfmt);
internal static extern bool BMTexture_GetVideoFormat([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VX_PIXELFORMAT out_vfmt);
/// <summary>BMTexture_SetVideoFormat</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -660,7 +682,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMTexture_SetVideoFormat", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMTexture_SetVideoFormat([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint vfmt);
internal static extern bool BMTexture_SetVideoFormat([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VX_PIXELFORMAT vfmt);
/// <summary>BMMaterial_GetDiffuse</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -780,7 +802,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetTextureBlendMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetTextureBlendMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetTextureBlendMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXTEXTURE_BLENDMODE out_val);
/// <summary>BMMaterial_SetTextureBlendMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -788,7 +810,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetTextureBlendMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetTextureBlendMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetTextureBlendMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXTEXTURE_BLENDMODE val);
/// <summary>BMMaterial_GetTextureMinMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -796,7 +818,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetTextureMinMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetTextureMinMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetTextureMinMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXTEXTURE_FILTERMODE out_val);
/// <summary>BMMaterial_SetTextureMinMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -804,7 +826,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetTextureMinMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetTextureMinMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetTextureMinMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXTEXTURE_FILTERMODE val);
/// <summary>BMMaterial_GetTextureMagMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -812,7 +834,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetTextureMagMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetTextureMagMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetTextureMagMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXTEXTURE_FILTERMODE out_val);
/// <summary>BMMaterial_SetTextureMagMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -820,7 +842,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetTextureMagMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetTextureMagMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetTextureMagMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXTEXTURE_FILTERMODE val);
/// <summary>BMMaterial_GetTextureAddressMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -828,7 +850,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetTextureAddressMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetTextureAddressMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetTextureAddressMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXTEXTURE_ADDRESSMODE out_val);
/// <summary>BMMaterial_SetTextureAddressMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -836,7 +858,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetTextureAddressMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetTextureAddressMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetTextureAddressMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXTEXTURE_ADDRESSMODE val);
/// <summary>BMMaterial_GetSourceBlend</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -844,7 +866,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetSourceBlend", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetSourceBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetSourceBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXBLEND_MODE out_val);
/// <summary>BMMaterial_SetSourceBlend</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -852,7 +874,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetSourceBlend", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetSourceBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetSourceBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXBLEND_MODE val);
/// <summary>BMMaterial_GetDestBlend</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -860,7 +882,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetDestBlend", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetDestBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetDestBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXBLEND_MODE out_val);
/// <summary>BMMaterial_SetDestBlend</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -868,7 +890,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetDestBlend", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetDestBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetDestBlend([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXBLEND_MODE val);
/// <summary>BMMaterial_GetFillMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -876,7 +898,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetFillMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetFillMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetFillMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXFILL_MODE out_val);
/// <summary>BMMaterial_SetFillMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -884,7 +906,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetFillMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetFillMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetFillMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXFILL_MODE val);
/// <summary>BMMaterial_GetShadeMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -892,7 +914,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetShadeMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetShadeMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetShadeMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXSHADE_MODE out_val);
/// <summary>BMMaterial_SetShadeMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -900,7 +922,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetShadeMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetShadeMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetShadeMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXSHADE_MODE val);
/// <summary>BMMaterial_GetAlphaTestEnabled</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -988,7 +1010,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetAlphaRef", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetAlphaRef([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetAlphaRef([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U1)] out byte out_val);
/// <summary>BMMaterial_SetAlphaRef</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -996,7 +1018,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetAlphaRef", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetAlphaRef([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetAlphaRef([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U1)] byte val);
/// <summary>BMMaterial_GetAlphaFunc</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -1004,7 +1026,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetAlphaFunc", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetAlphaFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetAlphaFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXCMPFUNC out_val);
/// <summary>BMMaterial_SetAlphaFunc</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -1012,7 +1034,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetAlphaFunc", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetAlphaFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetAlphaFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXCMPFUNC val);
/// <summary>BMMaterial_GetZFunc</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -1020,7 +1042,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_GetZFunc", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_GetZFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_val);
internal static extern bool BMMaterial_GetZFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXCMPFUNC out_val);
/// <summary>BMMaterial_SetZFunc</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -1028,7 +1050,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMaterial_SetZFunc", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMaterial_SetZFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint val);
internal static extern bool BMMaterial_SetZFunc([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXCMPFUNC val);
/// <summary>BMMesh_GetLitMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -1036,7 +1058,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMesh_GetLitMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMesh_GetLitMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_mode);
internal static extern bool BMMesh_GetLitMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXMESH_LITMODE out_mode);
/// <summary>BMMesh_SetLitMode</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -1044,7 +1066,7 @@ namespace BMapSharp {
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMMesh_SetLitMode", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMesh_SetLitMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint mode);
internal static extern bool BMMesh_SetLitMode([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXMESH_LITMODE mode);
/// <summary>BMMesh_GetVertexCount</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
@ -1151,54 +1173,198 @@ namespace BMapSharp {
[DllImport(g_DllName, EntryPoint = "BMMesh_SetMaterialSlot", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMMesh_SetMaterialSlot([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint index, [In, MarshalAs(UnmanagedType.U4)] uint mtlid);
/// <summary>BM3dObject_GetWorldMatrix</summary>
/// <summary>BM3dEntity_GetWorldMatrix</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_mat">Type: LibCmo::VxMath::VxMatrix. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BM3dObject_GetWorldMatrix", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[DllImport(g_DllName, EntryPoint = "BM3dEntity_GetWorldMatrix", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BM3dObject_GetWorldMatrix([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.Struct)] out VxMatrix out_mat);
/// <summary>BM3dObject_SetWorldMatrix</summary>
internal static extern bool BM3dEntity_GetWorldMatrix([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.Struct)] out VxMatrix out_mat);
/// <summary>BM3dEntity_SetWorldMatrix</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="mat">Type: LibCmo::VxMath::VxMatrix. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BM3dObject_SetWorldMatrix", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[DllImport(g_DllName, EntryPoint = "BM3dEntity_SetWorldMatrix", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BM3dObject_SetWorldMatrix([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.Struct)] VxMatrix mat);
/// <summary>BM3dObject_GetCurrentMesh</summary>
internal static extern bool BM3dEntity_SetWorldMatrix([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.Struct)] VxMatrix mat);
/// <summary>BM3dEntity_GetCurrentMesh</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_meshid">Type: LibCmo::CK2::CK_ID. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BM3dObject_GetCurrentMesh", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[DllImport(g_DllName, EntryPoint = "BM3dEntity_GetCurrentMesh", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BM3dObject_GetCurrentMesh([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_meshid);
/// <summary>BM3dObject_SetCurrentMesh</summary>
internal static extern bool BM3dEntity_GetCurrentMesh([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out uint out_meshid);
/// <summary>BM3dEntity_SetCurrentMesh</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="meshid">Type: LibCmo::CK2::CK_ID. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BM3dObject_SetCurrentMesh", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[DllImport(g_DllName, EntryPoint = "BM3dEntity_SetCurrentMesh", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BM3dObject_SetCurrentMesh([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint meshid);
/// <summary>BM3dObject_GetVisibility</summary>
internal static extern bool BM3dEntity_SetCurrentMesh([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] uint meshid);
/// <summary>BM3dEntity_GetVisibility</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_isVisible">Type: bool. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BM3dObject_GetVisibility", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[DllImport(g_DllName, EntryPoint = "BM3dEntity_GetVisibility", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BM3dObject_GetVisibility([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U1)] out bool out_isVisible);
/// <summary>BM3dObject_SetVisibility</summary>
internal static extern bool BM3dEntity_GetVisibility([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U1)] out bool out_isVisible);
/// <summary>BM3dEntity_SetVisibility</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="is_visible">Type: bool. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BM3dObject_SetVisibility", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[DllImport(g_DllName, EntryPoint = "BM3dEntity_SetVisibility", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BM3dObject_SetVisibility([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U1)] bool is_visible);
internal static extern bool BM3dEntity_SetVisibility([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U1)] bool is_visible);
/// <summary>BMLight_GetType</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::VxMath::VXLIGHT_TYPE. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetType", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetType([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.U4)] out VXLIGHT_TYPE out_val);
/// <summary>BMLight_SetType</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::VxMath::VXLIGHT_TYPE. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetType", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetType([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.U4)] VXLIGHT_TYPE val);
/// <summary>BMLight_GetColor</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::VxMath::VxColor. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetColor", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetColor([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.Struct)] out VxColor out_val);
/// <summary>BMLight_SetColor</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="col">Type: LibCmo::VxMath::VxColor. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetColor", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetColor([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.Struct)] VxColor col);
/// <summary>BMLight_GetConstantAttenuation</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::CKFLOAT. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetConstantAttenuation", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetConstantAttenuation([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.R4)] out float out_val);
/// <summary>BMLight_SetConstantAttenuation</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::CKFLOAT. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetConstantAttenuation", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetConstantAttenuation([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.R4)] float val);
/// <summary>BMLight_GetLinearAttenuation</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::CKFLOAT. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetLinearAttenuation", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetLinearAttenuation([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.R4)] out float out_val);
/// <summary>BMLight_SetLinearAttenuation</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::CKFLOAT. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetLinearAttenuation", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetLinearAttenuation([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.R4)] float val);
/// <summary>BMLight_GetQuadraticAttenuation</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::CKFLOAT. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetQuadraticAttenuation", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetQuadraticAttenuation([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.R4)] out float out_val);
/// <summary>BMLight_SetQuadraticAttenuation</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::CKFLOAT. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetQuadraticAttenuation", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetQuadraticAttenuation([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.R4)] float val);
/// <summary>BMLight_GetRange</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::CKFLOAT. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetRange", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetRange([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.R4)] out float out_val);
/// <summary>BMLight_SetRange</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::CKFLOAT. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetRange", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetRange([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.R4)] float val);
/// <summary>BMLight_GetHotSpot</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::CKFLOAT. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetHotSpot", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetHotSpot([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.R4)] out float out_val);
/// <summary>BMLight_SetHotSpot</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::CKFLOAT. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetHotSpot", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetHotSpot([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.R4)] float val);
/// <summary>BMLight_GetFalloff</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::CKFLOAT. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetFalloff", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetFalloff([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.R4)] out float out_val);
/// <summary>BMLight_SetFalloff</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::CKFLOAT. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetFalloff", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetFalloff([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.R4)] float val);
/// <summary>BMLight_GetFalloffShape</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="out_val">Type: LibCmo::CKFLOAT. This is OUT parameter. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_GetFalloffShape", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_GetFalloffShape([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [Out, MarshalAs(UnmanagedType.R4)] out float out_val);
/// <summary>BMLight_SetFalloffShape</summary>
/// <param name="bmfile">Type: BMap::BMFile*. The pointer to corresponding BMFile.</param>
/// <param name="objid">Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.</param>
/// <param name="val">Type: LibCmo::CKFLOAT. </param>
/// <returns>True if no error, otherwise False.</returns>
[DllImport(g_DllName, EntryPoint = "BMLight_SetFalloffShape", CallingConvention = CallingConvention.Cdecl, CharSet = CharSet.Ansi, ExactSpelling = true)]
[return: MarshalAs(UnmanagedType.U1)]
internal static extern bool BMLight_SetFalloffShape([In, MarshalAs(UnmanagedType.SysInt)] IntPtr bmfile, [In, MarshalAs(UnmanagedType.U4)] uint objid, [In, MarshalAs(UnmanagedType.R4)] float val);
// ##### GENERATED FUNCTIONS END #####

443
BMapBindings/BMapSharp/BMapSharp/BMapWrapper.cs
View File

@ -1,4 +1,5 @@
using System;
using System.Runtime.CompilerServices;
using System.Runtime.InteropServices;
using BMapSharp.VirtoolsTypes;
@ -34,7 +35,7 @@ namespace BMapSharp.BMapWrapper {
/// It just writes the data in console.
/// </summary>
internal static void BMapSharpCallback(string msg) {
Console.WriteLine(msg);
Console.WriteLine($"[BMapSharp] {msg}");
}
#endregion
@ -45,7 +46,7 @@ namespace BMapSharp.BMapWrapper {
var stride = Marshal.SizeOf<T>();
var itor = iem.GetEnumerator();
for (uint i = 0; i < count; ++i) {
BMapException.ThrowIfFailed(itor.MoveNext());
if (!itor.MoveNext()) throw new BMapException("The length of given data is too short when assigning struct array.");
Marshal.StructureToPtr<T>(itor.Current, pstruct, false);
pstruct += stride;
}
@ -57,8 +58,14 @@ namespace BMapSharp.BMapWrapper {
internal static void CKFaceIndicesAssigner(IntPtr pstruct, uint count, IEnumerable<CKFaceIndices> iem)
=> StructAssigner<CKFaceIndices>(pstruct, count, iem);
internal static void CKShortFaceIndicesAssigner(IntPtr pstruct, uint count, IEnumerable<CKShortFaceIndices> iem)
=> StructAssigner<CKShortFaceIndices>(pstruct, count, iem); // TODO: There is a padding bug!!!
=> StructAssigner<CKShortFaceIndices>(pstruct, count, iem);
internal static void ShortAssigner(IntPtr pstruct, uint count, IEnumerable<short> iem)
=> StructAssigner<short>(pstruct, count, iem);
internal static void CKIDAssigner(IntPtr pstruct, uint count, IEnumerable<uint> iem)
=> StructAssigner<uint>(pstruct, count, iem);
internal static void CKDWORDAssigner(IntPtr pstruct, uint count, IEnumerable<uint> iem)
=> StructAssigner<uint>(pstruct, count, iem);
private static IEnumerable<T> StructIterator<T>(IntPtr pstruct, uint count) {
var stride = Marshal.SizeOf<T>();
for (uint i = 0; i < count; ++i) {
@ -73,7 +80,13 @@ namespace BMapSharp.BMapWrapper {
internal static IEnumerable<CKFaceIndices> CKFaceIndicesIterator(IntPtr pstruct, uint count)
=> StructIterator<CKFaceIndices>(pstruct, count);
internal static IEnumerable<CKShortFaceIndices> CKShortFaceIndicesIterator(IntPtr pstruct, uint count)
=> StructIterator<CKShortFaceIndices>(pstruct, count); // TODO: There is a padding bug!!!
=> StructIterator<CKShortFaceIndices>(pstruct, count);
internal static IEnumerable<short> ShortIterator(IntPtr pstruct, uint count)
=> StructIterator<short>(pstruct, count);
internal static IEnumerable<uint> CKIDIterator(IntPtr pstruct, uint count)
=> StructIterator<uint>(pstruct, count);
internal static IEnumerable<uint> CKDWORDIterator(IntPtr pstruct, uint count)
=> StructIterator<uint>(pstruct, count);
#endregion
@ -87,7 +100,10 @@ namespace BMapSharp.BMapWrapper {
#endregion
}
public abstract class AbstractPointer : SafeHandle {
// TODO: Maybe I need to implement IEquatable, IComparable<T>, and IComparable for AbstractPointer and AbstractCKObject.
// But I give it up. I am lazy. What I have written barely works for me now.
public abstract class AbstractPointer : SafeHandle, IEquatable<AbstractPointer> {
internal AbstractPointer(IntPtr raw_pointer) : base(Utils.INVALID_PTR, true) {
this.handle = raw_pointer;
}
@ -98,47 +114,42 @@ namespace BMapSharp.BMapWrapper {
internal bool isValid() => this.handle != Utils.INVALID_PTR;
internal IntPtr getPointer() => this.handle;
// protected AbstractPointer(IntPtr raw_pointer) : base(raw_pointer, true) {}
#region IEquatable
// protected IntPtr GetPointer() => this.handle;
// public override bool IsInvalid { get { return this.handle == Utils.INVALID_PTR; } }
public override bool Equals(object obj) => this.Equals(obj as AbstractPointer);
public bool Equals(AbstractPointer obj) {
if (obj is null) return false;
// Optimization for a common success case
if (Object.ReferenceEquals(this, obj)) return true;
// If run-time types are not exactly the same, return false.
if (this.GetType() != obj.GetType()) return false;
// Return true if the fields match.
return this.handle == obj.handle;
}
// #region IComparable
public override int GetHashCode() => this.handle.GetHashCode();
// public int CompareTo(AbstractPointer other) {
// return m_RawPointer.CompareTo(other.m_RawPointer);
// }
public static bool operator ==(AbstractPointer lhs, AbstractPointer rhs) {
if (lhs is null) {
if (rhs is null) return true;
// Only left side is null.
return false;
}
// Equals handles case of null on right side
return lhs.Equals(rhs);
}
public static bool operator !=(AbstractPointer lhs, AbstractPointer rhs) => !(lhs == rhs);
// #endregion
// #region IEquatable
// public override bool Equals(object obj) => this.Equals(obj as AbstractPointer);
// public bool Equals(AbstractPointer other) {
// if (other is null) return false;
// if (Object.ReferenceEquals(this, other)) return true;
// // if (this.GetType() != other.GetType()) return false;
// return this.m_RawPointer == other.m_RawPointer;
// }
// public static bool operator ==(AbstractPointer lhs, AbstractPointer rhs) {
// if (lhs is null) {
// if (rhs is null) return true;
// return false;
// }
// return lhs.Equals(rhs);
// }
// public static bool operator !=(AbstractPointer lhs, AbstractPointer rhs) => !(lhs == rhs);
// #endregion
#endregion
#region Misc
public override int GetHashCode() => this.handle.GetHashCode();
public override string ToString() => this.handle.ToString();
#endregion
}
public abstract class AbstractCKObject : SafeHandle {
public abstract class AbstractCKObject : SafeHandle, IEquatable<AbstractCKObject> {
// Same as AbstractPointer, but not own this handle.
internal AbstractCKObject(IntPtr raw_pointer, uint ckid) : base(Utils.INVALID_PTR, false) {
this.handle = raw_pointer;
@ -153,104 +164,272 @@ namespace BMapSharp.BMapWrapper {
internal IntPtr getPointer() => this.handle;
internal uint getCKID() => m_CKID;
// private uint m_CKID;
#region IEquatable
// protected AbstractCKObject(IntPtr raw_pointer, uint ckid) : base(raw_pointer) {
// m_CKID = ckid;
// }
public override bool Equals(object obj) => this.Equals(obj as AbstractCKObject);
public bool Equals(AbstractCKObject obj) {
if (obj is null) return false;
// Optimization for a common success case
if (Object.ReferenceEquals(this, obj)) return true;
// If run-time types are not exactly the same, return false.
if (this.GetType() != obj.GetType()) return false;
// Return true if the fields match.
return (this.m_CKID == obj.m_CKID) && (this.handle == obj.handle);
}
// protected override bool IsValid() => base.IsValid() && m_CKID != Utils.INVALID_CKID;
// protected uint GetCKID() => m_CKID;
public override int GetHashCode() => HashCode.Combine(this.handle, m_CKID);
// #region IComparable
public static bool operator ==(AbstractCKObject lhs, AbstractCKObject rhs) {
if (lhs is null) {
if (rhs is null) return true;
// Only left side is null.
return false;
}
// Equals handles case of null on right side
return lhs.Equals(rhs);
}
public static bool operator !=(AbstractCKObject lhs, AbstractCKObject rhs) => !(lhs == rhs);
// public int CompareTo(AbstractCKObject other) {
// var ret = base.CompareTo((AbstractPointer)other);
// if (ret != 0) return ret;
// return m_CKID.CompareTo(other.m_CKID);
// }
// #endregion
// #region IEquatable
// public override bool Equals(object obj) => this.Equals(obj as AbstractCKObject);
// public bool Equals(AbstractCKObject other) {
// if (other is null) return false;
// if (Object.ReferenceEquals(this, other)) return true;
// }
// public static bool operator ==(AbstractCKObject left, AbstractCKObject right) =>
// ((AbstractPointer)left == (AbstractPointer)right) && left.m_CKID == right.m_CKID;
// public static bool operator !=(AbstractCKObject left, AbstractCKObject right) =>
// ((AbstractPointer)left != (AbstractPointer)right) || left.m_CKID != right.m_CKID;
// #endregion
#endregion
#region Misc
public override int GetHashCode() => HashCode.Combine(this.handle, m_CKID);
public override string ToString() => $"{this.handle}, {m_CKID}";
#endregion
#region Subclass Utilities
protected delegate bool FctGenericValueGetter<T>(IntPtr bmf, uint id, out T val);
protected delegate bool FctGenericValueSetter<T>(IntPtr bmf, uint id, T val);
[MethodImpl(MethodImplOptions.AggressiveInlining)]
protected T getGenericValue<T>(FctGenericValueGetter<T> fct) {
BMapException.ThrowIfFailed(fct(getPointer(), getCKID(), out T out_val));
return out_val;
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
protected void setGenericValue<T>(FctGenericValueSetter<T> fct, T val) {
BMapException.ThrowIfFailed(fct(getPointer(), getCKID(), val));
}
#endregion
}
public class BMObject : AbstractCKObject {
internal BMObject(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
public string GetName() {
BMapException.ThrowIfFailed(BMap.BMObject_GetName(getPointer(), getCKID(), out string out_name));
return out_name;
}
public void SetName(string name) {
BMapException.ThrowIfFailed(BMap.BMObject_SetName(getPointer(), getCKID(), name));
}
public string GetName() => getGenericValue<string>(BMap.BMObject_GetName);
public void SetName(string name) => setGenericValue<string>(BMap.BMObject_SetName, name);
}
public class BMTexture : BMObject {
internal BMTexture(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
public string GetFileName() => getGenericValue<string>(BMap.BMTexture_GetFileName);
public void LoadImage(string filepath) {
BMapException.ThrowIfFailed(BMap.BMTexture_LoadImage(getPointer(), getCKID(), filepath));
}
public void SaveImage(string filepath) {
BMapException.ThrowIfFailed(BMap.BMTexture_SaveImage(getPointer(), getCKID(), filepath));
}
public CK_TEXTURE_SAVEOPTIONS GetSaveOptions() => getGenericValue<CK_TEXTURE_SAVEOPTIONS>(BMap.BMTexture_GetSaveOptions);
public void SetSaveOptions(CK_TEXTURE_SAVEOPTIONS opt) => setGenericValue<CK_TEXTURE_SAVEOPTIONS>(BMap.BMTexture_SetSaveOptions, opt);
public VX_PIXELFORMAT GetVideoFormat() => getGenericValue<VX_PIXELFORMAT>(BMap.BMTexture_GetVideoFormat);
public void SetVideoFormat(VX_PIXELFORMAT vfmt) => setGenericValue<VX_PIXELFORMAT>(BMap.BMTexture_SetVideoFormat, vfmt);
}
public class BMMaterial : BMObject {
internal BMMaterial(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
public VxColor GetDiffuse() => getGenericValue<VxColor>(BMap.BMMaterial_GetDiffuse);
public void SetDiffuse(VxColor col) => setGenericValue<VxColor>(BMap.BMMaterial_SetDiffuse, col);
public VxColor GetAmbient() => getGenericValue<VxColor>(BMap.BMMaterial_GetAmbient);
public void SetAmbient(VxColor col) => setGenericValue<VxColor>(BMap.BMMaterial_SetAmbient, col);
public VxColor GetSpecular() => getGenericValue<VxColor>(BMap.BMMaterial_GetSpecular);
public void SetSpecular(VxColor col) => setGenericValue<VxColor>(BMap.BMMaterial_SetSpecular, col);
public VxColor GetEmissive() => getGenericValue<VxColor>(BMap.BMMaterial_GetEmissive);
public void SetEmissive(VxColor col) => setGenericValue<VxColor>(BMap.BMMaterial_SetEmissive, col);
public float GetSpecularPower() => getGenericValue<float>(BMap.BMMaterial_GetSpecularPower);
public void SetSpecularPower(float val) => setGenericValue<float>(BMap.BMMaterial_SetSpecularPower, val);
public VxColor GetTextureBorderColor() {
BMapException.ThrowIfFailed(BMap.BMMaterial_GetTextureBorderColor(getPointer(), getCKID(), out uint out_val));
return new VxColor(out_val);
}
public void SetTextureBorderColor(VxColor col) {
BMapException.ThrowIfFailed(BMap.BMMaterial_SetTextureBorderColor(getPointer(), getCKID(), col.ToDword()));
}
public VXTEXTURE_BLENDMODE GetTextureBlendMode() => getGenericValue<VXTEXTURE_BLENDMODE>(BMap.BMMaterial_GetTextureBlendMode);
public void SetTextureBlendMode(VXTEXTURE_BLENDMODE val) => setGenericValue<VXTEXTURE_BLENDMODE>(BMap.BMMaterial_SetTextureBlendMode, val);
public VXTEXTURE_FILTERMODE GetTextureMinMode() => getGenericValue<VXTEXTURE_FILTERMODE>(BMap.BMMaterial_GetTextureMinMode);
public void SetTextureMinMode(VXTEXTURE_FILTERMODE val) => setGenericValue<VXTEXTURE_FILTERMODE>(BMap.BMMaterial_SetTextureMinMode, val);
public VXTEXTURE_FILTERMODE GetTextureMagMode() => getGenericValue<VXTEXTURE_FILTERMODE>(BMap.BMMaterial_GetTextureMagMode);
public void SetTextureMagMode(VXTEXTURE_FILTERMODE val) => setGenericValue<VXTEXTURE_FILTERMODE>(BMap.BMMaterial_SetTextureMagMode, val);
public VXTEXTURE_ADDRESSMODE GetTextureAddressMode() => getGenericValue<VXTEXTURE_ADDRESSMODE>(BMap.BMMaterial_GetTextureAddressMode);
public void SetTextureAddressMode(VXTEXTURE_ADDRESSMODE val) => setGenericValue<VXTEXTURE_ADDRESSMODE>(BMap.BMMaterial_SetTextureAddressMode, val);
public VXBLEND_MODE GetSourceBlend() => getGenericValue<VXBLEND_MODE>(BMap.BMMaterial_GetSourceBlend);
public void SetSourceBlend(VXBLEND_MODE val) => setGenericValue<VXBLEND_MODE>(BMap.BMMaterial_SetSourceBlend, val);
public VXBLEND_MODE GetDestBlend() => getGenericValue<VXBLEND_MODE>(BMap.BMMaterial_GetDestBlend);
public void SetDestBlend(VXBLEND_MODE val) => setGenericValue<VXBLEND_MODE>(BMap.BMMaterial_SetDestBlend, val);
public VXFILL_MODE GetFillMode() => getGenericValue<VXFILL_MODE>(BMap.BMMaterial_GetFillMode);
public void SetFillMode(VXFILL_MODE val) => setGenericValue<VXFILL_MODE>(BMap.BMMaterial_SetFillMode, val);
public VXSHADE_MODE GetShadeMode() => getGenericValue<VXSHADE_MODE>(BMap.BMMaterial_GetShadeMode);
public void SetShadeMode(VXSHADE_MODE val) => setGenericValue<VXSHADE_MODE>(BMap.BMMaterial_SetShadeMode, val);
public bool GetAlphaTestEnabled() => getGenericValue<bool>(BMap.BMMaterial_GetAlphaTestEnabled);
public void SetAlphaTestEnabled(bool val) => setGenericValue<bool>(BMap.BMMaterial_SetAlphaTestEnabled, val);
public bool GetAlphaBlendEnabled() => getGenericValue<bool>(BMap.BMMaterial_GetAlphaBlendEnabled);
public void SetAlphaBlendEnabled(bool val) => setGenericValue<bool>(BMap.BMMaterial_SetAlphaBlendEnabled, val);
public bool GetPerspectiveCorrectionEnabled() => getGenericValue<bool>(BMap.BMMaterial_GetPerspectiveCorrectionEnabled);
public void SetPerspectiveCorrectionEnabled(bool val) => setGenericValue<bool>(BMap.BMMaterial_SetPerspectiveCorrectionEnabled, val);
public bool GetZWriteEnabled() => getGenericValue<bool>(BMap.BMMaterial_GetZWriteEnabled);
public void SetZWriteEnabled(bool val) => setGenericValue<bool>(BMap.BMMaterial_SetZWriteEnabled, val);
public bool GetTwoSidedEnabled() => getGenericValue<bool>(BMap.BMMaterial_GetTwoSidedEnabled);
public void SetTwoSidedEnabled(bool val) => setGenericValue<bool>(BMap.BMMaterial_SetTwoSidedEnabled, val);
public byte GetAlphaRef() => getGenericValue<byte>(BMap.BMMaterial_GetAlphaRef);
public void SetAlphaRef(byte val) => setGenericValue<byte>(BMap.BMMaterial_SetAlphaRef, val);
public VXCMPFUNC GetAlphaFunc() => getGenericValue<VXCMPFUNC>(BMap.BMMaterial_GetAlphaFunc);
public void SetAlphaFunc(VXCMPFUNC val) => setGenericValue<VXCMPFUNC>(BMap.BMMaterial_SetAlphaFunc, val);
public VXCMPFUNC GetZFunc() => getGenericValue<VXCMPFUNC>(BMap.BMMaterial_GetZFunc);
public void SetZFunc(VXCMPFUNC val) => setGenericValue<VXCMPFUNC>(BMap.BMMaterial_SetZFunc, val);
}
public class BMMesh : BMObject {
internal BMMesh(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
public VXMESH_LITMODE GetLitMode() => getGenericValue<VXMESH_LITMODE>(BMap.BMMesh_GetLitMode);
public void SetLitMode(VXMESH_LITMODE mode) => setGenericValue<VXMESH_LITMODE>(BMap.BMMesh_SetLitMode, mode);
public uint GetVertexCount() => getGenericValue<uint>(BMap.BMMesh_GetVertexCount);
public void SetVertexCount(uint count) => setGenericValue<uint>(BMap.BMMesh_SetVertexCount, count);
public IEnumerable<VxVector3> GetVertexPositions() {
BMapException.ThrowIfFailed(BMap.BMMesh_GetVertexPositions(getPointer(), getCKID(), out IntPtr out_mem));
return Utils.VxVector3Iterator(out_mem, GetVertexCount());
}
public void SetVertexPositions(IEnumerable<VxVector3> iem) {
BMapException.ThrowIfFailed(BMap.BMMesh_GetVertexPositions(getPointer(), getCKID(), out IntPtr out_mem));
Utils.VxVector3Assigner(out_mem, GetVertexCount(), iem);
}
public IEnumerable<VxVector3> GetVertexNormals() {
BMapException.ThrowIfFailed(BMap.BMMesh_GetVertexNormals(getPointer(), getCKID(), out IntPtr out_mem));
return Utils.VxVector3Iterator(out_mem, GetVertexCount());
}
public void SetVertexNormals(IEnumerable<VxVector3> iem) {
BMapException.ThrowIfFailed(BMap.BMMesh_GetVertexNormals(getPointer(), getCKID(), out IntPtr out_mem));
Utils.VxVector3Assigner(out_mem, GetVertexCount(), iem);
}
public IEnumerable<VxVector2> GetVertexUVs() {
BMapException.ThrowIfFailed(BMap.BMMesh_GetVertexUVs(getPointer(), getCKID(), out IntPtr out_mem));
return Utils.VxVector2Iterator(out_mem, GetVertexCount());
}
public void SetVertexUVs(IEnumerable<VxVector2> iem) {
BMapException.ThrowIfFailed(BMap.BMMesh_GetVertexUVs(getPointer(), getCKID(), out IntPtr out_mem));
Utils.VxVector2Assigner(out_mem, GetVertexCount(), iem);
}
public uint GetFaceCount() => getGenericValue<uint>(BMap.BMMesh_GetFaceCount);
public void SetFaceCount(uint count) => setGenericValue<uint>(BMap.BMMesh_SetFaceCount, count);
public IEnumerable<CKShortFaceIndices> GetFaceIndices() {
BMapException.ThrowIfFailed(BMap.BMMesh_GetFaceIndices(getPointer(), getCKID(), out IntPtr out_mem));
return Utils.CKShortFaceIndicesIterator(out_mem, GetFaceCount());
}
public void SetFaceIndices(IEnumerable<CKShortFaceIndices> iem) {
BMapException.ThrowIfFailed(BMap.BMMesh_GetFaceIndices(getPointer(), getCKID(), out IntPtr out_mem));
Utils.CKShortFaceIndicesAssigner(out_mem, GetFaceCount(), iem);
}
public IEnumerable<short> GetFaceMaterialSlotIndexs() {
BMapException.ThrowIfFailed(BMap.BMMesh_GetFaceMaterialSlotIndexs(getPointer(), getCKID(), out IntPtr out_mem));
return Utils.ShortIterator(out_mem, GetFaceCount());
}
public void SetFaceMaterialSlotIndexs(IEnumerable<short> iem) {
BMapException.ThrowIfFailed(BMap.BMMesh_GetFaceMaterialSlotIndexs(getPointer(), getCKID(), out IntPtr out_mem));
Utils.ShortAssigner(out_mem, GetFaceCount(), iem);
}
public uint GetMaterialSlotCount() => getGenericValue<uint>(BMap.BMMesh_GetMaterialSlotCount);
public void SetMaterialSlotCount(uint count) => setGenericValue<uint>(BMap.BMMesh_SetMaterialSlotCount, count);
public IEnumerable<BMMaterial> GetMaterialSlots() {
uint count = GetMaterialSlotCount();
for (uint i = 0; i < count; ++i) {
BMapException.ThrowIfFailed(BMap.BMMesh_GetMaterialSlot(getPointer(), getCKID(), i, out uint out_mtlid));
if (out_mtlid == Utils.INVALID_CKID) yield return null;
else yield return new BMMaterial(getPointer(), out_mtlid);
}
}
public void SetMaterialSlots(IEnumerable<BMMaterial> iem) {
uint count = GetMaterialSlotCount();
var itor = iem.GetEnumerator();
for (uint i = 0; i < count; ++i) {
if (!itor.MoveNext()) throw new BMapException("The length of given material array is too short when assigning material slots.");
uint mtlid = itor.Current is null ? Utils.INVALID_CKID : itor.Current.getCKID();
BMapException.ThrowIfFailed(BMap.BMMesh_SetMaterialSlot(getPointer(), getCKID(), i, mtlid));
}
}
}
public class BM3dObject : BMObject {
internal BM3dObject(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
public class BM3dEntity : BMObject {
internal BM3dEntity(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
public VxMatrix GetWorldMatrix() {
BMapException.ThrowIfFailed(BMap.BM3dObject_GetWorldMatrix(getPointer(), getCKID(), out VxMatrix out_mat));
return out_mat;
}
public void SetWorldMatrix(VxMatrix mat) {
BMapException.ThrowIfFailed(BMap.BM3dObject_SetWorldMatrix(getPointer(), getCKID(), mat));
}
public VxMatrix GetWorldMatrix() => getGenericValue<VxMatrix>(BMap.BM3dEntity_GetWorldMatrix);
public void SetWorldMatrix(VxMatrix mat) => setGenericValue<VxMatrix>(BMap.BM3dEntity_SetWorldMatrix, mat);
public BMMesh GetCurrentMesh() {
BMapException.ThrowIfFailed(BMap.BM3dObject_GetCurrentMesh(getPointer(), getCKID(), out uint out_meshid));
BMapException.ThrowIfFailed(BMap.BM3dEntity_GetCurrentMesh(getPointer(), getCKID(), out uint out_meshid));
if (out_meshid == Utils.INVALID_CKID) return null;
else return new BMMesh(getPointer(), out_meshid);
}
public void SetCurrentMesh(BMMesh mesh) {
uint meshid = (mesh is null) ? Utils.INVALID_CKID : mesh.getCKID();
BMapException.ThrowIfFailed(BMap.BM3dObject_SetCurrentMesh(getPointer(), getCKID(), meshid));
BMapException.ThrowIfFailed(BMap.BM3dEntity_SetCurrentMesh(getPointer(), getCKID(), meshid));
}
public bool GetVisibility() {
BMapException.ThrowIfFailed(BMap.BM3dObject_GetVisibility(getPointer(), getCKID(), out bool out_isVisible));
return out_isVisible;
}
public bool GetVisibility() => getGenericValue<bool>(BMap.BM3dEntity_GetVisibility);
public void SetVisibility(bool visb) => setGenericValue<bool>(BMap.BM3dEntity_SetVisibility, visb);
}
public void SetVisibility(bool visb) {
BMapException.ThrowIfFailed(BMap.BM3dObject_SetVisibility(getPointer(), getCKID(), visb));
}
public class BM3dObject : BM3dEntity {
internal BM3dObject(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
}
public class BMLight : BM3dEntity {
internal BMLight(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
// Name `GetType` is conflict with C# base class function name.
// So we add a `Light` prefix for it.
public VXLIGHT_TYPE GetLightType() => getGenericValue<VXLIGHT_TYPE>(BMap.BMLight_GetType);
public void SetLightType(VXLIGHT_TYPE val) => setGenericValue<VXLIGHT_TYPE>(BMap.BMLight_SetType, val);
public VxColor GetColor() => getGenericValue<VxColor>(BMap.BMLight_GetColor);
public void SetColor(VxColor col) => setGenericValue<VxColor>(BMap.BMLight_SetColor, col);
public float GetConstantAttenuation() => getGenericValue<float>(BMap.BMLight_GetConstantAttenuation);
public void SetConstantAttenuation(float val) => setGenericValue<float>(BMap.BMLight_SetConstantAttenuation, val);
public float GetLinearAttenuation() => getGenericValue<float>(BMap.BMLight_GetLinearAttenuation);
public void SetLinearAttenuation(float val) => setGenericValue<float>(BMap.BMLight_SetLinearAttenuation, val);
public float GetQuadraticAttenuation() => getGenericValue<float>(BMap.BMLight_GetQuadraticAttenuation);
public void SetQuadraticAttenuation(float val) => setGenericValue<float>(BMap.BMLight_SetQuadraticAttenuation, val);
public float GetRange() => getGenericValue<float>(BMap.BMLight_GetRange);
public void SetRange(float val) => setGenericValue<float>(BMap.BMLight_SetRange, val);
public float GetHotSpot() => getGenericValue<float>(BMap.BMLight_GetHotSpot);
public void SetHotSpot(float val) => setGenericValue<float>(BMap.BMLight_SetHotSpot, val);
public float GetFalloff() => getGenericValue<float>(BMap.BMLight_GetFalloff);
public void SetFalloff(float val) => setGenericValue<float>(BMap.BMLight_SetFalloff, val);
public float GetFalloffShape() => getGenericValue<float>(BMap.BMLight_GetFalloffShape);
public void SetFalloffShape(float val) => setGenericValue<float>(BMap.BMLight_SetFalloffShape, val);
}
public class BMTargetLight : BMLight {
internal BMTargetLight(IntPtr raw_pointer, uint ckid) : base(raw_pointer, ckid) { }
}
public class BMGroup : BMObject {
@ -260,11 +439,7 @@ namespace BMapSharp.BMapWrapper {
BMapException.ThrowIfFailed(BMap.BMGroup_AddObject(getPointer(), getCKID(), member.getCKID()));
}
public uint GetObjectCount() {
BMapException.ThrowIfFailed(BMap.BMGroup_GetObjectCount(getPointer(), getCKID(), out uint out_count));
return out_count;
}
public uint GetObjectCount() => getGenericValue<uint>(BMap.BMGroup_GetObjectCount);
public IEnumerable<BM3dObject> GetObjects() {
var size = GetObjectCount();
for (uint i = 0; i < size; ++i) {
@ -325,6 +500,10 @@ namespace BMapSharp.BMapWrapper {
getCKObjectCount(BMap.BMFile_GetGroupCount);
public IEnumerable<BMGroup> GetGroups() =>
getCKObjects<BMGroup>(BMap.BMFile_GetGroupCount, BMap.BMFile_GetGroup, (bmf, id) => new BMGroup(bmf, id));
public uint GetTargetLightCount() =>
getCKObjectCount(BMap.BMFile_GetTargetLightCount);
public IEnumerable<BMTargetLight> GetTargetLights() =>
getCKObjects<BMTargetLight>(BMap.BMFile_GetTargetLightCount, BMap.BMFile_GetTargetLight, (bmf, id) => new BMTargetLight(bmf, id));
}
@ -344,6 +523,16 @@ namespace BMapSharp.BMapWrapper {
public BMFileWriter(string temp_folder, string texture_folder, string[] encodings)
: base(allocateHandle(temp_folder, texture_folder, encodings)) { }
public void Save(string filename, CK_TEXTURE_SAVEOPTIONS texture_save_opt, bool use_compress, int compress_level) {
BMapException.ThrowIfFailed(BMap.BMFile_Save(
getPointer(),
filename,
texture_save_opt,
use_compress,
compress_level
));
}
private delegate bool FctProtoCreateObject(IntPtr bmf, out uint id);
private delegate T FctProtoCreateInstance<T>(IntPtr bmf, uint id);
private T createCKObject<T>(FctProtoCreateObject fct_crt, FctProtoCreateInstance<T> fct_inst) {
@ -356,6 +545,7 @@ namespace BMapSharp.BMapWrapper {
public BMMesh CreateMesh() => createCKObject<BMMesh>(BMap.BMFile_CreateMesh, (bmf, id) => new BMMesh(bmf, id));
public BM3dObject Create3dObject() => createCKObject<BM3dObject>(BMap.BMFile_Create3dObject, (bmf, id) => new BM3dObject(bmf, id));
public BMGroup CreateGroup() => createCKObject<BMGroup>(BMap.BMFile_CreateGroup, (bmf, id) => new BMGroup(bmf, id));
public BMTargetLight CreateTargetLight() => createCKObject<BMTargetLight>(BMap.BMFile_CreateTargetLight, (bmf, id) => new BMTargetLight(bmf, id));
}
public sealed class BMMeshTrans : AbstractPointer {
@ -368,6 +558,59 @@ namespace BMapSharp.BMapWrapper {
}
public BMMeshTrans() : base(allocateHandle()) { }
public void Parse(BMMesh objmesh) {
BMapException.ThrowIfFailed(BMap.BMMeshTrans_Parse(
getPointer(),
objmesh.getPointer(),
objmesh.getCKID()
));
}
public void PrepareVertex(uint count, IEnumerable<VxVector3> iem) {
// Prepare count first
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareVertexCount(getPointer(), count));
// Then put data
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareVertex(getPointer(), out IntPtr out_mem));
Utils.VxVector3Assigner(out_mem, count, iem);
}
public void PrepareNormal(uint count, IEnumerable<VxVector3> iem) {
// Prepare count first
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareNormalCount(getPointer(), count));
// Then put data
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareNormal(getPointer(), out IntPtr out_mem));
Utils.VxVector3Assigner(out_mem, count, iem);
}
public void PrepareUV(uint count, IEnumerable<VxVector2> iem) {
// Prepare count first
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareUVCount(getPointer(), count));
// Then put data
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareUV(getPointer(), out IntPtr out_mem));
Utils.VxVector2Assigner(out_mem, count, iem);
}
public void PrepareMtlSlot(uint count, IEnumerable<BMMaterial> iem) {
// Prepare count first
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareMtlSlotCount(getPointer(), count));
// Then put data
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareMtlSlot(getPointer(), out IntPtr out_mem));
var cast_iem = iem.Select((mtl) => mtl is null ? Utils.INVALID_CKID : mtl.getCKID());
Utils.CKIDAssigner(out_mem, count, cast_iem);
}
public void PrepareFace(uint count, IEnumerable<CKFaceIndices> vec_idx, IEnumerable<CKFaceIndices> nml_idx, IEnumerable<CKFaceIndices> uv_idx, IEnumerable<uint> mtl_idx) {
// Prepare count first
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareFaceCount(getPointer(), count));
// Get data address
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareFaceVertexIndices(getPointer(), out IntPtr raw_vec_idx));
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareFaceNormalIndices(getPointer(), out IntPtr raw_nml_idx));
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareFaceUVIndices(getPointer(), out IntPtr raw_uv_idx));
BMapException.ThrowIfFailed(BMap.BMMeshTrans_PrepareFaceMtlSlot(getPointer(), out IntPtr raw_mtl_idx));
// Assign data
Utils.CKFaceIndicesAssigner(raw_vec_idx, count, vec_idx);
Utils.CKFaceIndicesAssigner(raw_nml_idx, count, nml_idx);
Utils.CKFaceIndicesAssigner(raw_uv_idx, count, uv_idx);
Utils.CKDWORDAssigner(raw_mtl_idx, count, mtl_idx);
}
}

56
BMapBindings/BMapSharp/BMapSharp/VirtoolsTypes.cs
View File

@ -15,12 +15,14 @@ namespace BMapSharp.VirtoolsTypes {
public float X, Y;
public VxVector2(float _x = 0.0f, float _y = 0.0f) {
X = _x;
Y = _y;
X = _x; Y = _y;
}
public VxVector2(Vector2 vec) {
FromManaged(vec);
}
public void FromManaged(Vector2 vec) {
X = vec.X;
Y = vec.Y;
X = vec.X; Y = vec.Y;
}
public Vector2 ToManaged() {
return new Vector2(X, Y);
@ -33,14 +35,14 @@ namespace BMapSharp.VirtoolsTypes {
public float X, Y, Z;
public VxVector3(float _x = 0.0f, float _y = 0.0f, float _z = 0.0f) {
X = _x;
Y = _y;
Z = _z;
X = _x; Y = _y; Z = _z;
}
public VxVector3(Vector3 vec) {
FromManaged(vec);
}
public void FromManaged(Vector3 vec) {
X = vec.X;
Y = vec.Y;
Z = vec.Z;
X = vec.X; Y = vec.Y; Z = vec.Z;
}
public Vector3 ToManaged() {
return new Vector3(X, Y, Z);
@ -50,29 +52,31 @@ namespace BMapSharp.VirtoolsTypes {
[StructLayout(LayoutKind.Sequential, Pack = 4, CharSet = CharSet.Ansi)]
public struct VxColor {
[MarshalAs(UnmanagedType.R4)]
public float A, R, G, B;
public float R, G, B, A;
public VxColor(float _r, float _g, float _b, float _a) {
A = _a;
R = _r;
G = _g;
B = _b;
A = _a; R = _r; G = _g; B = _b;
Regulate();
}
public VxColor(Vector4 col) {
FromManagedRGBA(col);
}
public VxColor(Vector3 col) {
FromManagedRGB(col);
}
public VxColor(uint val) {
FromDword(val);
}
public void FromManagedRGBA(Vector4 col) {
R = col.X;
G = col.Y;
B = col.Z;
A = col.W;
R = col.X; G = col.Y; B = col.Z; A = col.W;
Regulate();
}
public Vector4 ToManagedRGBA() {
return new Vector4(R, G, B, A);
}
public void FromManagedRGB(Vector3 col) {
R = col.X;
G = col.Y;
B = col.Z;
R = col.X; G = col.Y; B = col.Z; A = 1.0f;
Regulate();
}
public Vector3 ToManagedRGB() {
@ -101,6 +105,7 @@ namespace BMapSharp.VirtoolsTypes {
val |= (uint)(B * 255.0f);
return val;
}
public static float ClampFactor(float factor) {
return System.Math.Clamp(factor, 0.0f, 1.0f);
}
@ -221,6 +226,13 @@ namespace BMapSharp.VirtoolsTypes {
_4_ARGB8888_CLUT = 31, /**< 4 bits indexed CLUT (ARGB) */
}
public enum VXLIGHT_TYPE : uint {
VX_LIGHTPOINT = 1, /**< The Light is a point of light */
VX_LIGHTSPOT = 2, /**< The light is a spotlight */
VX_LIGHTDIREC = 3, /**< The light is directional light : Lights comes from an infinite point so only direction of light can be given */
// VX_LIGHTPARA = 4UL, /**< Obsolete, do not use */
}
public enum VXTEXTURE_BLENDMODE : uint {
VXTEXTUREBLEND_DECAL = 1, /**< Texture replace any material information */
VXTEXTUREBLEND_MODULATE = 2, /**< Texture and material are combine. Alpha information of the texture replace material alpha component. */

4
BMapBindings/BMapSharp/BMapSharpTestbench/BMapSharpTestbench.csproj
View File

@ -4,6 +4,10 @@
<ProjectReference Include="..\BMapSharp\BMapSharp.csproj" />
</ItemGroup>
<ItemGroup>
<PackageReference Include="System.CommandLine" Version="2.0.0-beta4.22272.1" />
</ItemGroup>
<PropertyGroup>
<OutputType>Exe</OutputType>
<TargetFramework>net8.0</TargetFramework>

230
BMapBindings/BMapSharp/BMapSharpTestbench/Program.cs
View File

@ -1,9 +1,21 @@
using BMapSharp.BMapWrapper;
using System;
using System.Text;
using System.Collections.Generic;
using System.Diagnostics;
using System.CommandLine;
namespace BMapSharpTestbench {
internal class Program {
static void Main(string[] args) {
// Parse arguments
var resolved_args = ResolveArguments(args);
if (resolved_args is null) {
// just silent quit
Environment.Exit(0);
}
// Check environment
Console.OutputEncoding = Encoding.UTF8;
if (!BMapSharp.BMapWrapper.Utils.IsBMapAvailable()) {
@ -17,51 +29,191 @@ namespace BMapSharpTestbench {
Console.ReadKey(true);
// Start testbench
string file_name = "Level_02.NMO";
string temp_folder = "Temp";
string texture_folder = "F:\\Ballance\\Ballance\\Textures";
string[] encodings = ["cp1252", "gb2312"];
string file_name = resolved_args.mFileName; // "LightCameraTest.nmo";
string temp_folder = resolved_args.mTempFolder; // "Temp";
string texture_folder = resolved_args.mTextureFolder; // "F:\\Ballance\\Ballance\\Textures";
string[] encodings = resolved_args.mEncodings; // ["cp1252", "gb2312"];
using (var reader = new BMapSharp.BMapWrapper.BMFileReader(file_name, temp_folder, texture_folder, encodings)) {
// Console.WriteLine("===== Groups =====");
// foreach (var gp in reader.GetGroups()) {
// Console.WriteLine(gp.GetName());
// foreach (var gp_item in gp.GetObjects()) {
// Console.WriteLine($"\t{gp_item.GetName()}");
// }
// }
Console.WriteLine("===== 3dObjects =====");
foreach (var obj in reader.Get3dObjects()) {
Console.WriteLine(obj.GetName());
var current_mesh = obj.GetCurrentMesh();
var mesh_name = current_mesh is null ? "<null>" : current_mesh.GetName();
Console.WriteLine($"\tMesh: {mesh_name}");
Console.WriteLine($"\tVisibility: {obj.GetVisibility()}");
Console.WriteLine($"\tMatrix: {obj.GetWorldMatrix().ToManaged()}");
}
// Console.WriteLine("===== Meshes =====");
// foreach (var mesh in reader.GetMeshes()) {
// Console.WriteLine(mesh.GetName());
// }
// Console.WriteLine("===== Materials =====");
// foreach (var mtl in reader.GetMaterials()) {
// Console.WriteLine(mtl.GetName());
// }
// Console.WriteLine("===== Textures =====");
// foreach (var tex in reader.GetTextures()) {
// Console.WriteLine(tex.GetName());
// }
TestCommon(reader);
TestIEquatable(reader);
}
Console.WriteLine("===== Done =====");
Console.WriteLine("Press any key to quit...");
Console.ReadKey(true);
}
class BMapSharpArguments {
public string mFileName;
public string mTempFolder;
public string mTextureFolder;
public string[] mEncodings;
}
static BMapSharpArguments ResolveArguments(string[] args) {
// define arguments
var fileNameOpt = new Option<string>
("--file-path", "The path to input Virtools file.");
fileNameOpt.IsRequired = true;
var tempFolderOpt = new Option<string>
("--temp-dir", "The temp folder used by BMap.");
tempFolderOpt.IsRequired = true;
var textureFolderOpt = new Option<string>
("--texture-dir", "The texture folder containing Ballance texture resources.");
textureFolderOpt.IsRequired = true;
var encodingsOpt = new Option<IEnumerable<string>>
("--encodings", "The encodings used to parse the names stroed in input Virtools file.");
encodingsOpt.IsRequired = true;
encodingsOpt.Arity = ArgumentArity.OneOrMore;
encodingsOpt.AllowMultipleArgumentsPerToken = true;
// init root command
var rootCommand = new RootCommand("The testbench of BMapSharp.");
rootCommand.Add(fileNameOpt);
rootCommand.Add(tempFolderOpt);
rootCommand.Add(textureFolderOpt);
rootCommand.Add(encodingsOpt);
// init result container
BMapSharpArguments ret = new BMapSharpArguments();
// set handler
rootCommand.SetHandler((context) => {
ret.mFileName = context.ParseResult.GetValueForOption(fileNameOpt);
ret.mTempFolder = context.ParseResult.GetValueForOption(tempFolderOpt);
ret.mTextureFolder = context.ParseResult.GetValueForOption(textureFolderOpt);
ret.mEncodings = context.ParseResult.GetValueForOption(encodingsOpt).ToArray();
context.ExitCode = 61;
});
// execute root command and return value.
if (rootCommand.Invoke(args) != 61) return null;
return ret;
}
static void TestCommon(BMapSharp.BMapWrapper.BMFileReader reader) {
// Console.WriteLine("===== Groups =====");
// foreach (var gp in reader.GetGroups()) {
// Console.WriteLine(gp.GetName());
// foreach (var gp_item in gp.GetObjects()) {
// Console.WriteLine($"\t{gp_item.GetName()}");
// }
// }
// Console.WriteLine("===== 3dObjects =====");
// foreach (var obj in reader.Get3dObjects()) {
// Console.WriteLine(obj.GetName());
// var current_mesh = obj.GetCurrentMesh();
// var mesh_name = current_mesh is null ? "<null>" : current_mesh.GetName();
// Console.WriteLine($"\tMesh: {mesh_name}");
// Console.WriteLine($"\tVisibility: {obj.GetVisibility()}");
// Console.WriteLine($"\tMatrix: {obj.GetWorldMatrix().ToManaged()}");
// }
// Console.WriteLine("===== Meshes =====");
// foreach (var mesh in reader.GetMeshes()) {
// Console.WriteLine(mesh.GetName());
// Console.WriteLine($"\tLit Mode: {mesh.GetLitMode()}");
// Console.WriteLine($"\tVertex Count: {mesh.GetVertexCount()}");
// Console.WriteLine($"\tFace Count: {mesh.GetFaceCount()}");
// Console.WriteLine($"\tMaterial Slot Count: {mesh.GetMaterialSlotCount()}");
// }
// Console.WriteLine("===== Materials =====");
// foreach (var mtl in reader.GetMaterials()) {
// Console.WriteLine(mtl.GetName());
// Console.WriteLine($"\tDiffuse: {mtl.GetDiffuse().ToManagedRGBA()}");
// Console.WriteLine($"\tAmbient: {mtl.GetAmbient().ToManagedRGBA()}");
// Console.WriteLine($"\tSpecular: {mtl.GetSpecular().ToManagedRGBA()}");
// Console.WriteLine($"\tEmissive: {mtl.GetEmissive().ToManagedRGBA()}");
// Console.WriteLine($"\tSpecular Power: {mtl.GetSpecularPower()}");
// Console.WriteLine($"\tTexture Border Color: {mtl.GetTextureBorderColor().ToManagedRGBA()}");
// Console.WriteLine($"\tTexture Blend Mode: {mtl.GetTextureBlendMode()}");
// Console.WriteLine($"\tTexture Min Mode: {mtl.GetTextureMinMode()}");
// Console.WriteLine($"\tTexture Mag Mode: {mtl.GetTextureMagMode()}");
// Console.WriteLine($"\tSource Blend: {mtl.GetSourceBlend()}");
// Console.WriteLine($"\tDest Blend: {mtl.GetDestBlend()}");
// Console.WriteLine($"\tFill Mode: {mtl.GetFillMode()}");
// Console.WriteLine($"\tShade Mode: {mtl.GetShadeMode()}");
// Console.WriteLine($"\tAlpha Test Enabled: {mtl.GetAlphaTestEnabled()}");
// Console.WriteLine($"\tAlpha Blend Enabled: {mtl.GetAlphaBlendEnabled()}");
// Console.WriteLine($"\tPerspective Correction Enabled: {mtl.GetPerspectiveCorrectionEnabled()}");
// Console.WriteLine($"\tZ Write Enabled: {mtl.GetZWriteEnabled()}");
// Console.WriteLine($"\tTwo Sided Enabled: {mtl.GetTwoSidedEnabled()}");
// Console.WriteLine($"\tAlpha Ref: {mtl.GetAlphaRef()}");
// Console.WriteLine($"\tAlpha Func: {mtl.GetAlphaFunc()}");
// Console.WriteLine($"\tZ Func: {mtl.GetZFunc()}");
// }
// Console.WriteLine("===== Textures =====");
// foreach (var tex in reader.GetTextures()) {
// Console.WriteLine(tex.GetName());
// Console.WriteLine($"\tFile Name: {tex.GetFileName()}");
// Console.WriteLine($"\tSave Options: {tex.GetSaveOptions()}");
// Console.WriteLine($"\tVideo Format: {tex.GetVideoFormat()}");
// }
Console.WriteLine("===== Target Lights =====");
foreach (var lit in reader.GetTargetLights()) {
Console.WriteLine(lit.GetName());
Console.WriteLine($"\tVisibility: {lit.GetVisibility()}");
Console.WriteLine($"\tMatrix: {lit.GetWorldMatrix().ToManaged()}");
Console.WriteLine($"Type: {lit.GetLightType()}");
Console.WriteLine($"Color: {lit.GetColor().ToManagedRGBA()}");
Console.WriteLine($"Constant Attenuation: {lit.GetConstantAttenuation()}");
Console.WriteLine($"Linear Attenuation: {lit.GetLinearAttenuation()}");
Console.WriteLine($"Quadratic Attenuation: {lit.GetQuadraticAttenuation()}");
Console.WriteLine($"Range: {lit.GetRange()}");
Console.WriteLine($"Hot Spot: {lit.GetHotSpot()}");
Console.WriteLine($"Falloff: {lit.GetFalloff()}");
Console.WriteLine($"Falloff Shape: {lit.GetFalloffShape()}");
}
Console.WriteLine("===== END =====");
}
static void TestIEquatable(BMapSharp.BMapWrapper.BMFileReader reader) {
if (reader.Get3dObjectCount() < 2u) {
Debug.Fail(
"Invalid file for test IEquatable.",
"We can not perform IEquatable test because the length of 3dObject is too short (must greater than 2). Please choose another file to perform."
);
return;
}
// Prepare test variables
var all_3dobjects = new List<BM3dObject>(reader.Get3dObjects());
var first_3dobj = all_3dobjects[0];
var second_3dobj = all_3dobjects[1];
all_3dobjects = new List<BM3dObject>(reader.Get3dObjects());
var first_3dobj_again = all_3dobjects[0];
Debug.Assert(!Object.ReferenceEquals(first_3dobj, first_3dobj_again));
// Hashtable test
var test_hashset = new HashSet<BM3dObject>();
Debug.Assert(test_hashset.Add(first_3dobj));
Debug.Assert(!test_hashset.Add(first_3dobj_again));
Debug.Assert(test_hashset.Add(second_3dobj));
// Dictionary test
var test_dictionary = new Dictionary<BM3dObject, string>();
Debug.Assert(test_dictionary.TryAdd(first_3dobj, first_3dobj.GetName()));
Debug.Assert(!test_dictionary.TryAdd(first_3dobj_again, first_3dobj_again.GetName()));
Debug.Assert(test_dictionary.TryAdd(second_3dobj, second_3dobj.GetName()));
}
}
}

2
BMapBindings/BMapSharp/README.md
View File

@ -5,3 +5,5 @@ The core of BMapSharp project is placed within `BMapSharp` subdirectory. This di
The native BMap library should be placed together with managed `BMapSharp` dynamic library. I use gitignore file to filter all native binary so you need put them manually. The native BMap library must be named as `BMap.dll` (in Windows), `BMap.so` (in Linux or BSD), or `BMap.dylib` (in macOS). If you still can not load BMap or your system is not listed above, you should name it as `BMap.bin`.
The most content of `VirtoolsTypes.cs` is generated by EnumsMigration, and the most content of `BMap.cs` is generated by BMapBindings. You should watch these file changes if corresponding C++ code or structures are changed.
Since BMap 0.3.0, testbench use command line arguments, instead of hardcode variables in code, as the arguments of BMap. It is convenient that debug BMapSharp without any modification of source code. For a brief instruction, you may need to launch BMapSharpTestbench in following command (just an example. you can modify it as you wished): `dotnet run -- --file-path "LightCameraTest.nmo" --temp-dir "Temp" --texture-dir "F:/Ballance/Ballance/Textures" --encodings cp1252 gb2312`.

148
BMapBindings/PyBMap/PyBMap/bmap.py
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@ -227,6 +227,22 @@ BMFile_GetTexture = _create_bmap_func('BMFile_GetTexture', [bm_void_p, bm_CKDWOR
# @param out_id[out] Type: LibCmo::CK2::CK_ID. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMFile_CreateTexture = _create_bmap_func('BMFile_CreateTexture', [bm_void_p, bm_CKID_p])
## BMFile_GetTargetLightCount
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param out_count[out] Type: LibCmo::CKDWORD. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMFile_GetTargetLightCount = _create_bmap_func('BMFile_GetTargetLightCount', [bm_void_p, bm_CKDWORD_p])
## BMFile_GetTargetLight
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param idx[in] Type: LibCmo::CKDWORD.
# @param out_id[out] Type: LibCmo::CK2::CK_ID. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMFile_GetTargetLight = _create_bmap_func('BMFile_GetTargetLight', [bm_void_p, bm_CKDWORD, bm_CKID_p])
## BMFile_CreateTargetLight
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param out_id[out] Type: LibCmo::CK2::CK_ID. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMFile_CreateTargetLight = _create_bmap_func('BMFile_CreateTargetLight', [bm_void_p, bm_CKID_p])
## BMMeshTrans_New
# @param out_trans[out] Type: BMap::BMMeshTransition*. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
@ -747,42 +763,150 @@ BMMesh_GetMaterialSlot = _create_bmap_func('BMMesh_GetMaterialSlot', [bm_void_p,
# @param mtlid[in] Type: LibCmo::CK2::CK_ID.
# @return True if no error, otherwise False.
BMMesh_SetMaterialSlot = _create_bmap_func('BMMesh_SetMaterialSlot', [bm_void_p, bm_CKID, bm_CKDWORD, bm_CKID])
## BM3dObject_GetWorldMatrix
## BM3dEntity_GetWorldMatrix
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_mat[out] Type: LibCmo::VxMath::VxMatrix. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BM3dObject_GetWorldMatrix = _create_bmap_func('BM3dObject_GetWorldMatrix', [bm_void_p, bm_CKID, bm_VxMatrix_p])
## BM3dObject_SetWorldMatrix
BM3dEntity_GetWorldMatrix = _create_bmap_func('BM3dEntity_GetWorldMatrix', [bm_void_p, bm_CKID, bm_VxMatrix_p])
## BM3dEntity_SetWorldMatrix
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param mat[in] Type: LibCmo::VxMath::VxMatrix.
# @return True if no error, otherwise False.
BM3dObject_SetWorldMatrix = _create_bmap_func('BM3dObject_SetWorldMatrix', [bm_void_p, bm_CKID, bm_VxMatrix])
## BM3dObject_GetCurrentMesh
BM3dEntity_SetWorldMatrix = _create_bmap_func('BM3dEntity_SetWorldMatrix', [bm_void_p, bm_CKID, bm_VxMatrix])
## BM3dEntity_GetCurrentMesh
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_meshid[out] Type: LibCmo::CK2::CK_ID. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BM3dObject_GetCurrentMesh = _create_bmap_func('BM3dObject_GetCurrentMesh', [bm_void_p, bm_CKID, bm_CKID_p])
## BM3dObject_SetCurrentMesh
BM3dEntity_GetCurrentMesh = _create_bmap_func('BM3dEntity_GetCurrentMesh', [bm_void_p, bm_CKID, bm_CKID_p])
## BM3dEntity_SetCurrentMesh
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param meshid[in] Type: LibCmo::CK2::CK_ID.
# @return True if no error, otherwise False.
BM3dObject_SetCurrentMesh = _create_bmap_func('BM3dObject_SetCurrentMesh', [bm_void_p, bm_CKID, bm_CKID])
## BM3dObject_GetVisibility
BM3dEntity_SetCurrentMesh = _create_bmap_func('BM3dEntity_SetCurrentMesh', [bm_void_p, bm_CKID, bm_CKID])
## BM3dEntity_GetVisibility
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_isVisible[out] Type: bool. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BM3dObject_GetVisibility = _create_bmap_func('BM3dObject_GetVisibility', [bm_void_p, bm_CKID, bm_bool_p])
## BM3dObject_SetVisibility
BM3dEntity_GetVisibility = _create_bmap_func('BM3dEntity_GetVisibility', [bm_void_p, bm_CKID, bm_bool_p])
## BM3dEntity_SetVisibility
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param is_visible[in] Type: bool.
# @return True if no error, otherwise False.
BM3dObject_SetVisibility = _create_bmap_func('BM3dObject_SetVisibility', [bm_void_p, bm_CKID, bm_bool])
BM3dEntity_SetVisibility = _create_bmap_func('BM3dEntity_SetVisibility', [bm_void_p, bm_CKID, bm_bool])
## BMLight_GetType
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::VxMath::VXLIGHT_TYPE. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetType = _create_bmap_func('BMLight_GetType', [bm_void_p, bm_CKID, bm_enum_p])
## BMLight_SetType
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::VxMath::VXLIGHT_TYPE.
# @return True if no error, otherwise False.
BMLight_SetType = _create_bmap_func('BMLight_SetType', [bm_void_p, bm_CKID, bm_enum])
## BMLight_GetColor
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::VxMath::VxColor. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetColor = _create_bmap_func('BMLight_GetColor', [bm_void_p, bm_CKID, bm_VxColor_p])
## BMLight_SetColor
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param col[in] Type: LibCmo::VxMath::VxColor.
# @return True if no error, otherwise False.
BMLight_SetColor = _create_bmap_func('BMLight_SetColor', [bm_void_p, bm_CKID, bm_VxColor])
## BMLight_GetConstantAttenuation
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::CKFLOAT. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetConstantAttenuation = _create_bmap_func('BMLight_GetConstantAttenuation', [bm_void_p, bm_CKID, bm_CKFLOAT_p])
## BMLight_SetConstantAttenuation
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::CKFLOAT.
# @return True if no error, otherwise False.
BMLight_SetConstantAttenuation = _create_bmap_func('BMLight_SetConstantAttenuation', [bm_void_p, bm_CKID, bm_CKFLOAT])
## BMLight_GetLinearAttenuation
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::CKFLOAT. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetLinearAttenuation = _create_bmap_func('BMLight_GetLinearAttenuation', [bm_void_p, bm_CKID, bm_CKFLOAT_p])
## BMLight_SetLinearAttenuation
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::CKFLOAT.
# @return True if no error, otherwise False.
BMLight_SetLinearAttenuation = _create_bmap_func('BMLight_SetLinearAttenuation', [bm_void_p, bm_CKID, bm_CKFLOAT])
## BMLight_GetQuadraticAttenuation
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::CKFLOAT. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetQuadraticAttenuation = _create_bmap_func('BMLight_GetQuadraticAttenuation', [bm_void_p, bm_CKID, bm_CKFLOAT_p])
## BMLight_SetQuadraticAttenuation
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::CKFLOAT.
# @return True if no error, otherwise False.
BMLight_SetQuadraticAttenuation = _create_bmap_func('BMLight_SetQuadraticAttenuation', [bm_void_p, bm_CKID, bm_CKFLOAT])
## BMLight_GetRange
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::CKFLOAT. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetRange = _create_bmap_func('BMLight_GetRange', [bm_void_p, bm_CKID, bm_CKFLOAT_p])
## BMLight_SetRange
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::CKFLOAT.
# @return True if no error, otherwise False.
BMLight_SetRange = _create_bmap_func('BMLight_SetRange', [bm_void_p, bm_CKID, bm_CKFLOAT])
## BMLight_GetHotSpot
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::CKFLOAT. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetHotSpot = _create_bmap_func('BMLight_GetHotSpot', [bm_void_p, bm_CKID, bm_CKFLOAT_p])
## BMLight_SetHotSpot
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::CKFLOAT.
# @return True if no error, otherwise False.
BMLight_SetHotSpot = _create_bmap_func('BMLight_SetHotSpot', [bm_void_p, bm_CKID, bm_CKFLOAT])
## BMLight_GetFalloff
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::CKFLOAT. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetFalloff = _create_bmap_func('BMLight_GetFalloff', [bm_void_p, bm_CKID, bm_CKFLOAT_p])
## BMLight_SetFalloff
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::CKFLOAT.
# @return True if no error, otherwise False.
BMLight_SetFalloff = _create_bmap_func('BMLight_SetFalloff', [bm_void_p, bm_CKID, bm_CKFLOAT])
## BMLight_GetFalloffShape
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param out_val[out] Type: LibCmo::CKFLOAT. Use ctypes.byref(data) pass it.
# @return True if no error, otherwise False.
BMLight_GetFalloffShape = _create_bmap_func('BMLight_GetFalloffShape', [bm_void_p, bm_CKID, bm_CKFLOAT_p])
## BMLight_SetFalloffShape
# @param bmfile[in] Type: BMap::BMFile*. The pointer to corresponding BMFile.
# @param objid[in] Type: LibCmo::CK2::CK_ID. The CKID of object you accessing.
# @param val[in] Type: LibCmo::CKFLOAT.
# @return True if no error, otherwise False.
BMLight_SetFalloffShape = _create_bmap_func('BMLight_SetFalloffShape', [bm_void_p, bm_CKID, bm_CKFLOAT])
##### GENERATED FUNCTIONS END #####

740
BMapBindings/PyBMap/PyBMap/bmap_wrapper.py
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File diff suppressed because it is too large Load Diff

9
BMapBindings/PyBMap/PyBMap/virtools_types.py
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@ -221,6 +221,15 @@ class VX_PIXELFORMAT(enum.IntEnum):
_4_ABGR8888_CLUT = 30 ##< 4 bits indexed CLUT (ABGR)
_4_ARGB8888_CLUT = 31 ##< 4 bits indexed CLUT (ARGB)
class VXLIGHT_TYPE(enum.IntEnum):
"""!
Light type
"""
VX_LIGHTPOINT = 1 ##< The Light is a point of light
VX_LIGHTSPOT = 2 ##< The light is a spotlight
VX_LIGHTDIREC = 3 ##< The light is directional light : Lights comes from an infinite point so only direction of light can be given
#VX_LIGHTPARA = 4 ##< Obsolete, do not use
class VXTEXTURE_BLENDMODE(enum.IntEnum):
"""!
Blend Mode Flags

2
BMapBindings/PyBMap/README.md
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@ -5,3 +5,5 @@ The real scripts are placed in sub PyBMap folder. This folder is served for test
The native BMap library should be placed in sub PyBMap folder, and I have used gitignore file to filter them. The native BMap library must be named as `BMap.dll` (in Windows), `BMap.so` (in Linux or BSD), or `BMap.dylib` (in macOS). If you still can not load BMap or your system is not listed above, you should name it as `BMap.bin`.
Please note the most content of `virtools_types.py` are generated by EnumsMigration sub-project. Additionally the most content of `bmap.py` is generated by BMapBindings. So if some structs are updated, do not forget checking these files.
Since BMap 0.3.0, testbench use command line arguments, instead of hardcode variables in code, as the arguments of BMap. It is convenient that debug BMapSharp without any modification of source code. For a brief instruction, you may need to launch BMapSharpTestbench in following command (just an example. you can modify it as you wished): `py testbench.py --file-path "LightCameraTest.nmo" --temp-dir "Temp" --texture-dir "F:/Ballance/Ballance/Textures" --encodings cp1252 gb2312`.

185
BMapBindings/PyBMap/testbench.py
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@ -1,35 +1,178 @@
import os
import argparse
import PyBMap.bmap_wrapper as bmap
def main() -> None:
def main(file_name: str, temp_folder: str, texture_folder: str, encodings: tuple[str, ...]) -> None:
input(f'Python PID is {os.getpid()}. Waiting for debugger, press any key to continue...')
file_name: str = 'Level_02.NMO'
temp_folder: str = 'Temp'
texture_folder: str = 'F:\\Ballance\\Ballance\\Textures'
encodings: tuple[str, ...] = ('cp1252', )
# file_name: str = 'LightCameraTest.nmo'
# temp_folder: str = 'Temp'
# texture_folder: str = 'F:\\Ballance\\Ballance\\Textures'
# encodings: tuple[str, ...] = ('cp1252', )
with bmap.BMFileReader(file_name, temp_folder, texture_folder, encodings) as reader:
print('===== Groups =====')
for gp in reader.get_groups():
print(gp.get_name())
test_common(reader)
test_equatable(reader)
print('===== 3dObjects =====')
for obj in reader.get_3dobjects():
print(obj.get_name())
def test_common(reader: bmap.BMFileReader):
# print('===== Groups =====')
# for gp in reader.get_groups():
# print(gp.get_name())
# for gp_item in gp.get_objects():
# print(f'\t{gp_item.get_name()}')
# print('===== 3dObjects =====')
# for obj in reader.get_3dobjects():
# print(obj.get_name())
# current_mesh = obj.get_current_mesh()
# mesh_name = '<null>' if current_mesh is None else current_mesh.get_name()
# print(f'\tMesh: {mesh_name}')
# print(f'\tVisibility: {obj.get_visibility()}')
# print(f'\tMatrix: {obj.get_world_matrix().to_const()}')
# print('===== Meshes =====')
# for mesh in reader.get_meshs():
# print(mesh.get_name())
# print(f'\tLit Mode: {mesh.get_lit_mode()}')
# print(f'\tVertex Count: {mesh.get_vertex_count()}')
# print(f'\tFace Count: {mesh.get_face_count()}')
# print(f'\tMaterial Slot Count: {mesh.get_material_slot_count()}')
# print('===== Materials =====')
# for mtl in reader.get_materials():
# print(mtl.get_name())
print('===== Meshes =====')
for mesh in reader.get_meshs():
print(mesh.get_name())
# print(f'\tDiffuse: {mtl.get_diffuse().to_const_rgba()}')
# print(f'\tAmbient: {mtl.get_ambient().to_const_rgba()}')
# print(f'\tSpecular: {mtl.get_specular().to_const_rgba()}')
# print(f'\tEmissive: {mtl.get_emissive().to_const_rgba()}')
print('===== Materials =====')
for mtl in reader.get_materials():
print(mtl.get_name())
# print(f'\tSpecular Power: {mtl.get_specular_power()}')
print('===== Textures =====')
for tex in reader.get_textures():
print(tex.get_name())
# print(f'\tTexture Border Color: {mtl.get_texture_border_color().to_const_rgba()}')
# print(f'\tTexture Blend Mode: {mtl.get_texture_blend_mode()}')
# print(f'\tTexture Min Mode: {mtl.get_texture_min_mode()}')
# print(f'\tTexture Mag Mode: {mtl.get_texture_mag_mode()}')
# print(f'\tSource Blend: {mtl.get_source_blend()}')
# print(f'\tDest Blend: {mtl.get_dest_blend()}')
# print(f'\tFill Mode: {mtl.get_fill_mode()}')
# print(f'\tShade Mode: {mtl.get_shade_mode()}')
# print(f'\tAlpha Test Enabled: {mtl.get_alpha_test_enabled()}')
# print(f'\tAlpha Blend Enabled: {mtl.get_alpha_blend_enabled()}')
# print(f'\tPerspective Correction Enabled: {mtl.get_perspective_correction_enabled()}')
# print(f'\tZ Write Enabled: {mtl.get_z_write_enabled()}')
# print(f'\tTwo Sided Enabled: {mtl.get_two_sided_enabled()}')
# print(f'\tAlpha Ref: {mtl.get_alpha_ref()}')
# print(f'\tAlpha Func: {mtl.get_alpha_func()}')
# print(f'\tZ Func: {mtl.get_z_func()}')
# print('===== Textures =====')
# for tex in reader.get_textures():
# print(tex.get_name())
# print(f'\tFile Name: {tex.get_file_name()}')
# print(f'\tSave Options: {tex.get_save_options()}')
# print(f'\tVideo Format: {tex.get_video_format()}')
print('===== Target Lights =====')
for lit in reader.get_target_lights():
print(lit.get_name())
print(f'\tVisibility: {lit.get_visibility()}')
print(f'\tMatrix: {lit.get_world_matrix().to_const()}')
print(f'\tType: {lit.get_type()}')
print(f'\tColor: {lit.get_color().to_const_rgba()}')
print(f'\tConstant Attenuation: {lit.get_constant_attenuation()}')
print(f'\tLinear Attenuation: {lit.get_linear_attenuation()}')
print(f'\tQuadratic Attenuation: {lit.get_quadratic_attenuation()}')
print(f'\tRange: {lit.get_range()}')
print(f'\tHot Spot: {lit.get_hot_spot()}')
print(f'\tFalloff: {lit.get_falloff()}')
print(f'\tFalloff Shape: {lit.get_falloff_shape()}')
print('===== END =====')
def test_equatable(reader: bmap.BMFileReader):
# Check requirements
assert (reader.get_3dobject_count() >= 2), '''
Invalid file for test IEquatable.
We can not perform IEquatable test because the length of 3dObject is too short (must greater than 2). Please choose another file to perform.
'''
# Prepare variables
all_3dobjects: tuple[bmap.BM3dObject, ...] = tuple(reader.get_3dobjects())
first_3dobj: bmap.BM3dObject = all_3dobjects[0]
second_3dobj: bmap.BM3dObject = all_3dobjects[1]
all_3dobjects = tuple(reader.get_3dobjects())
first_3dobj_again: bmap.BM3dObject = all_3dobjects[0]
# Test set
test_set: set[bmap.BM3dObject] = set()
test_set.add(first_3dobj)
assert len(test_set) == 1
assert first_3dobj in test_set
assert first_3dobj_again in test_set
assert second_3dobj not in test_set
test_set.add(first_3dobj_again)
assert len(test_set) == 1
test_set.add(second_3dobj)
assert len(test_set) == 2
assert second_3dobj in test_set
# Test dict
test_dict: dict[bmap.BM3dObject, str | None] = {}
test_dict[first_3dobj] = first_3dobj.get_name()
assert len(test_dict) == 1
assert first_3dobj in test_dict
assert first_3dobj_again in test_dict
assert second_3dobj not in test_dict
test_dict[first_3dobj_again] = first_3dobj_again.get_name()
assert len(test_dict) == 1
test_dict[second_3dobj] = second_3dobj.get_name()
assert len(test_dict) == 2
assert second_3dobj in test_dict
if __name__ == '__main__':
main()
# parse argument
parser = argparse.ArgumentParser(
prog='PyBMap Testbench',
description='The testbench of PyBMap.'
)
parser.add_argument(
'--file-path',
action='store', dest='file_path', required=True,
help='The path to input Virtools file.'
)
parser.add_argument(
'--temp-dir',
action='store', dest='temp_dir', required=True,
help='The temp folder used by BMap.'
)
parser.add_argument(
'--texture-dir',
action='store', dest='texture_dir', required=True,
help='The texture folder containing Ballance texture resources.'
)
parser.add_argument(
'--encodings',
action='extend', nargs='+', dest='encodings', required=True,
help='The encodings used to parse the names stroed in input Virtools file.'
)
args = parser.parse_args()
# run main function
main(args.file_path, args.temp_dir, args.texture_dir, tuple(args.encodings))

6
CMake/VTVersion.hpp.in Normal file
View File

@ -0,0 +1,6 @@
#pragma once
#define LIBCMO_VER_MAJOR @PROJECT_VERSION_MAJOR@
#define LIBCMO_VER_MINOR @PROJECT_VERSION_MINOR@
#define LIBCMO_VER_PATCH @PROJECT_VERSION_PATCH@
#define LIBCMO_VER_STR "@PROJECT_VERSION_MAJOR@.@PROJECT_VERSION_MINOR@.@PROJECT_VERSION_PATCH@"

10
CMake/custom_import_yycc.cmake
View File

@ -6,6 +6,10 @@ endif()
# Find YYCC library
# It will produce YYCC::YYCCommonplace target for including and linking.
find_package(YYCCommonplace REQUIRED
HINTS ${YYCC_PATH} NO_DEFAULT_PATH
)
#
# Please note we MUST set CMake variable YYCCommonplace_ROOT to make sure CMake can found YYCC in out given path.
# The cache status of YYCCommonplace_ROOT is doesn't matter.
# CMake will throw error if we use HINTS feature in find_package to find YYCC.
set(YYCCommonplace_ROOT ${YYCC_PATH} CACHE PATH
"The path to YYCC CMake distribution installation path.")
find_package(YYCCommonplace REQUIRED)

8
CMakeLists.txt
View File

@ -1,6 +1,6 @@
cmake_minimum_required(VERSION 3.23)
project(NeMo
VERSION 0.2.0
VERSION 0.3.0
LANGUAGES CXX
)
@ -53,7 +53,7 @@ endif ()
install(EXPORT LibCmoTargets
FILE LibCmoTargets.cmake
NAMESPACE NeMo::
DESTINATION ${YYCC_INSTALL_LIB_PATH}/cmake/LibCmo
DESTINATION ${NEMO_INSTALL_LIB_PATH}/cmake/LibCmo
)
# Package configuration file
include(CMakePackageConfigHelpers)
@ -65,7 +65,7 @@ write_basic_package_version_file(
configure_package_config_file(
${CMAKE_CURRENT_LIST_DIR}/CMake/LibCmoConfig.cmake.in
"${CMAKE_CURRENT_BINARY_DIR}/LibCmoConfig.cmake"
INSTALL_DESTINATION ${CMAKE_INSTALL_LIBDIR}/cmake/LibCmo
INSTALL_DESTINATION ${NEMO_INSTALL_LIB_PATH}/cmake/LibCmo
)
# Copy package files to install destination
install(
@ -73,5 +73,5 @@ FILES
"${CMAKE_CURRENT_BINARY_DIR}/LibCmoConfig.cmake"
"${CMAKE_CURRENT_BINARY_DIR}/LibCmoConfigVersion.cmake"
DESTINATION
${CMAKE_INSTALL_LIBDIR}/cmake/LibCmo
${NEMO_INSTALL_LIB_PATH}/cmake/LibCmo
)

15
COMPILE.md
View File

@ -18,13 +18,18 @@ Since libcmo21 0.2.0, we only provide it in CMake build system. So Windows user
### YYCCommonplace
You should clone YYCCommonplace and switch to the latest release tag (or specified commit hash provided with libcmo21 release infos if you are building for specific libcmo21 version). Then compile it **in C++ 20 mode** (this is crucial because libcmo21 use C++ 20, and YYCCommonplace's ABI is incompatible between C++ 17 version and C++ 20 version). Finally install it as CMake package.
You should clone YYCCommonplace and switch to the latest release tag (or specified commit hash provided with libcmo21 release infos if you are building for specific libcmo21 version). When configuring YYCCommonplace, you should notice following infos:
* Please make sure that you have specified C++ 20 explicitly by passing `-DCMAKE_CXX_STANDARD=20` in command line. This is crucial because libcmo21 use C++ 20, and YYCCommonplace's ABI is incompatible between C++ 17 version and C++ 20 version.
* If you need `BMap` in final libcmo21 built artifacts, and you are in non-Windows system now, please specify position independent code flag by passing `-DCMAKE_POSITION_INDEPENDENT_CODE=True` in command line. GCC and Clang will reject linking if you don't flag it.
After configuring, you can normally build YYCCommonplace like a common CMake project.
Please note if your final program or dynamic library is provided for end user, please choose `RelWithDebInfo` build type (`Release` is not suggested because it will strip all debug infos and it is not good for bug reporter, which is embedded in program, to report crash). If final program is served for programmer debugging, please choose `Debug` build type.
### stb
You should clone stb repository first. In ideally scenario, we suggest you switch to the latest commit. However, all builds are actually only run on a specific commit hash `5736b15f7ea0ffb08dd38af21067c314d6a3aae9`. So if the latest commit is not work, please switch to this commit hash instead.
You should clone stb repository first, then switch to a specific commit hash `2e2bef463a5b53ddf8bb788e25da6b8506314c08`. In ideally scenario, people like to choose the latest commit. However, I not frequently update this dependency.
### zlib
@ -36,7 +41,7 @@ If you are running on non-Windows system. You usually do not need to do anything
### Directory Hierarchy
First, create subdirectory `Bin/build` and `Bin/install`.
First, create subdirectory `Bin/build` and `Bin/install` at the root directory of libcmo21.
### Configuration
@ -54,8 +59,8 @@ The arguments in command should be replaced by:
The switches in command can be switched as you wish:
* `NEMO_BUILD_UNVIRT`: Build `unvirt`, a command line application debugging Virtools files.
* `NEMO_BUILD_BMAP`: Build `BMap`, a dynamic library specific used for loading Ballance map file.
* `NEMO_BUILD_UNVIRT`: Build `Unvirt`, a command line application debugging Virtools files.
* `NEMO_BUILD_BMAP`: Build `BMap`, a dynamic library specific used for loading Ballance map file. If you are coming from my another project [BallanceBlenderPlugin](https://github.com/yyc12345/BallanceBlenderHelper), this is what you need.
* `NEMO_BUILD_DOC`: Build the document of libcmo21.
### Build

9
CodeGen/BMapBindings/CSharpWriter.java
View File

@ -118,6 +118,7 @@ public class CSharpWriter {
ret.mMarshalAs = "UnmanagedType.SysInt";
ret.mCsType = "IntPtr";
}
break;
case "CK_ID":
if (vt_pointer_level == 0) {
ret.mMarshalAs = "UnmanagedType.U4";
@ -187,6 +188,7 @@ public class CSharpWriter {
break;
case "CK_TEXTURE_SAVEOPTIONS":
case "VX_PIXELFORMAT":
case "VXLIGHT_TYPE":
case "VXTEXTURE_BLENDMODE":
case "VXTEXTURE_FILTERMODE":
case "VXTEXTURE_ADDRESSMODE":
@ -195,11 +197,14 @@ public class CSharpWriter {
case "VXSHADE_MODE":
case "VXCMPFUNC":
case "VXMESH_LITMODE":
// all enum share the same underlying type.
// all enum type use the same strategy
if (vt_pointer_level == 0) {
// all enum type should be marshaled as its underlying type
// but we can use its name in C# directly.
ret.mMarshalAs = "UnmanagedType.U4";
ret.mCsType = "uint";
ret.mCsType = vt_base_type;
} else {
// for pointer type, use IntPtr instead.
ret.mMarshalAs = "UnmanagedType.SysInt";
ret.mCsType = "IntPtr";
}

1
CodeGen/BMapBindings/PythonWriter.java
View File

@ -28,6 +28,7 @@ public class PythonWriter {
cache.put("VxMatrix", "VxMatrix");
cache.put("CK_TEXTURE_SAVEOPTIONS", "enum");
cache.put("VX_PIXELFORMAT", "enum");
cache.put("VXLIGHT_TYPE", "enum");
cache.put("VXTEXTURE_BLENDMODE", "enum");
cache.put("VXTEXTURE_FILTERMODE", "enum");
cache.put("VXTEXTURE_ADDRESSMODE", "enum");

8
CodeGen/EnumsMigration/MainRunner.java
View File

@ -170,6 +170,14 @@ public class MainRunner {
PythonWriter.writeAccVal("dest/CK_BITMAPDATA_FLAGS.AccVal.py", single);
CSharpWriter.writeAccVal("dest/CK_BITMAPDATA_FLAGS.AccVal.cs", single);
single = organiseDefines("src/CK_CAMERA_PROJECTION.txt", "CK_CAMERA_PROJECTION");
CppWriter.writeEnum("dest/CK_CAMERA_PROJECTION.hpp", single);
PythonWriter.writeEnum("dest/CK_CAMERA_PROJECTION.py", single);
CSharpWriter.writeEnum("dest/CK_CAMERA_PROJECTION.cs", single);
CppWriter.writeAccVal("dest/CK_CAMERA_PROJECTION.AccVal.hpp", single, CommonHelper.CKParts.CK2);
PythonWriter.writeAccVal("dest/CK_CAMERA_PROJECTION.AccVal.py", single);
CSharpWriter.writeAccVal("dest/CK_CAMERA_PROJECTION.AccVal.cs", single);
// print message.
System.out.println("DONE!");
}

4
CodeGen/EnumsMigration/src/CK_CAMERA_PROJECTION.txt Normal file
View File

@ -0,0 +1,4 @@
#define CK_PERSPECTIVEPROJECTION 1
#define CK_ORTHOGRAPHICPROJECTION 2

19
CodeGen/EnumsMigration/src/VxEnums.txt
View File

@ -41,6 +41,25 @@ typedef enum VX_PIXELFORMAT {
_4_ARGB8888_CLUT = 31 // 4 bits indexed CLUT (ARGB)
} VX_PIXELFORMAT;
/******************************************************************
{filename:VXLIGHT_TYPE}
Summary: Light type.
Remarks:
+ Used by CKLight::SetType to specify the type of a light.
See also: CKLight::SetType,CKLight::GetType
******************************************************************/
typedef enum VXLIGHT_TYPE
{
VX_LIGHTPOINT = 1UL, // The Light is a point of light
VX_LIGHTSPOT = 2UL, // The light is a spotlight
VX_LIGHTDIREC = 3UL, // The light is directional light : Lights comes from an infinite point so only direction of light can be given
VX_LIGHTPARA = 4UL // Obsolete, do not use
} VXLIGHT_TYPE;
/*****************************************************************
{filename:VXTEXTURE_BLENDMODE}
Summary: Blend Mode Flags

3
CodeGen/VectorGen/.gitignore vendored
View File

@ -1,2 +1,3 @@
# Result
*.hpp
VxTypes.hpp
VxTypes.cpp

2
CodeGen/VectorGen/README.md
View File

@ -1,3 +1,3 @@
# Vector Generator
Vector types (LibCmo::Vector3 and etc) and Vector-like types (LibCmo::Color and etc) nearly have similar declaration except slight differences (basically is the count of factors). Manually writing these declarations is boring and easy to cause potential invisible bugs. So we use a Python script to generate these declarations batchly to prevent any defects indroduced above.
Vector types (LibCmo::VxMath::VxVector3 and etc) and Vector-like types (LibCmo::VxMath::VxColor and etc) nearly have similar declaration except slight differences (basically is the count of factors). Manually writing these declarations is boring and easy to cause potential invisible bugs. So we use a Python script to generate these declarations batchly to prevent any defects indroduced above.

178
CodeGen/VectorGen/VxTypes.cpp.jinja Normal file
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@ -0,0 +1,178 @@
{% import 'VxTypes.shared.jinja' as shared %}
{#
For friend operator overload, we do not need add CLASSNAME:: prefix for it.
Because they are not a part of that class.
#}
#pragma region {{ sname }}
{# Ctor type 1 - Default ctor -#}
{{ sname }}::{{ sname }}() : {{- shared.initialize_list_builder(svars, False) -}} {} {% if not is_vector %}// SET YOUR CUSTOM INIT{% endif %}
{#- Ctor type 2 - User specified ctor #}
{{ sname }}::{{ sname }}({{- shared.argument_list_builder(svars) -}}) : {{- shared.initialize_list_builder(svars, True) -}} {}
{#- Offset operator #}
CKFLOAT& {{ sname }}::operator[](size_t i) {
switch (i) {
{%- for item in svars %}
case {{ loop.index0 }}: return {{ item }};
{%- endfor %}
default: throw LogicException("Invalid index for {{ sname }}::operator[].");
}
}
const CKFLOAT& {{ sname }}::operator[](size_t i) const {
switch (i) {
{%- for item in svars %}
case {{ loop.index0 }}: return {{ item }};
{%- endfor %}
default: throw LogicException("Invalid index for {{ sname }}::operator[].");
}
}
{#- Equal operator #}
bool {{ sname }}::operator==(const {{ sname }}& rhs) const {
return (
{%- for item in svars -%}
{{ item }} == rhs.{{ item }} {%- if not loop.last %} && {% endif %}
{%- endfor -%}
);
}
{#- Spaceship operator #}
auto {{ sname }}::operator<=>(const {{ sname }}& rhs) const {
{%- for item in svars[:-1] %}
if (auto cmp = {{ item }} <=> rhs.{{ item }}; cmp != 0) return cmp;
{%- endfor %}
return {{ svars[-1] }} <=> rhs.{{ svars[-1] }};
}
{#- BEGIN VECTOR SPECIFIC #}
{%- if is_vector %}
{#- Add, minus operators #}
{#- Unary operators #}
{{ sname }} {{ sname }}::operator+() const {
return *this;
}
{{ sname }} {{ sname }}::operator-() const {
return {{ sname }}(
{%- for item in svars -%}
-{{ item }} {%- if not loop.last %}, {% endif %}
{%- endfor -%}
);
}
{#- Additive operators #}
{{ sname }}& {{ sname }}::operator+=(const {{ sname }}& rhs) {
{%- for item in svars %}
{{ item }} += rhs.{{ item }};
{%- endfor %}
return *this;
}
{{ sname }} operator+(const {{ sname }}& lhs, const {{ sname }}& rhs) {
return {{ sname }}(
{%- for item in svars -%}
lhs.{{ item }} + rhs.{{ item }} {%- if not loop.last %}, {% endif %}
{%- endfor -%}
);
}
{{ sname }}& {{ sname }}::operator-=(const {{ sname }}& rhs) {
{%- for item in svars %}
{{ item }} -= rhs.{{ item }};
{%- endfor %}
return *this;
}
{{ sname }} operator-(const {{ sname }}& lhs, const {{ sname }}& rhs) {
return {{ sname }}(
{%- for item in svars -%}
lhs.{{ item }} - rhs.{{ item }} {%- if not loop.last %}, {% endif %}
{%- endfor -%}
);
}
{#- Mul operator #}
{{ sname }}& {{ sname }}::operator*=(CKFLOAT rhs) {
{%- for item in svars %}
{{ item }} *= rhs;
{%- endfor %}
return *this;
}
{{ sname }} operator*(const {{ sname }}& lhs, CKFLOAT rhs) {
return {{ sname }}(
{%- for item in svars -%}
lhs.{{ item }} * rhs {%- if not loop.last %}, {% endif %}
{%- endfor -%}
);
}
{{ sname }} operator*(CKFLOAT lhs, const {{ sname }}& rhs) {
return {{ sname }}(
{%- for item in svars -%}
lhs * rhs.{{ item }} {%- if not loop.last %}, {% endif %}
{%- endfor -%}
);
}
CKFLOAT operator*(const {{ sname }}& lhs, const {{ sname }}& rhs) {
return (
{%- for item in svars -%}
lhs.{{ item }} * rhs.{{ item }} {%- if not loop.last %} + {% endif %}
{%- endfor -%}
);
}
{#- Div operator #}
{{ sname }}& {{ sname }}::operator/=(CKFLOAT rhs) {
if (rhs == 0.0f) return *this;
{%- for item in svars %}
{{ item }} /= rhs;
{%- endfor %}
return *this;
}
{{ sname }} operator/(const {{ sname }}& lhs, CKFLOAT rhs) {
if (rhs == 0.0f) return {{ sname }}();
else return {{ sname }}(
{%- for item in svars -%}
lhs.{{ item }} / rhs {%- if not loop.last %}, {% endif %}
{%- endfor -%}
);
}
{#- Length functions #}
CKFLOAT {{ sname }}::SquaredLength() const {
return (
{%- for item in svars -%}
{{ item }} * {{ item }} {%- if not loop.last %} + {% endif %}
{%- endfor -%}
);
}
CKFLOAT {{ sname }}::Length() const {
return std::sqrt(SquaredLength());
}
{#- Normalize functions #}
void {{ sname }}::Normalized() {
CKFLOAT len = Length();
if (len == 0.0f) return;
{%- for item in svars %}
{{ item }} /= len;
{%- endfor %}
}
{{ sname }} {{ sname }}::Normalize() const {
CKFLOAT len = Length();
if (len == 0.0f) return {{ sname }}();
else return {{ sname }}(
{%- for item in svars -%}
{{ item }} / len {%- if not loop.last %}, {% endif %}
{%- endfor -%}
);
}
{%- endif %}
{#- END VECTOR SPECIFIC #}
{#- User custom region #}
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
#pragma endregion

65
CodeGen/VectorGen/VxTypes.hpp.jinja Normal file
View File

@ -0,0 +1,65 @@
{% import 'VxTypes.shared.jinja' as shared %}
struct {{ sname }} {
{#- Variable declaration #}
CKFLOAT {{ ", ".join(svars) }};
{#- Ctor type 1 - Default ctor #}
{{ sname }}();
{#- Ctor type 2 - User specified ctor #}
{{ sname }}({{- shared.argument_list_builder(svars) -}});
{#- Default copy ctor, move ctor, copy assigner, move assigner #}
YYCC_DEF_CLS_COPY_MOVE({{ sname }});
{#- Offset operator #}
CKFLOAT& operator[](size_t i);
const CKFLOAT& operator[](size_t i) const;
{#- Equal operator #}
bool operator==(const {{ sname }}& rhs) const;
{#- Spaceship operator #}
auto operator<=>(const {{ sname }}& rhs) const;
{#- BEGIN VECTOR SPECIFIC #}
{%- if is_vector %}
{#- Add, minus operators #}
{#- Unary operators #}
{{ sname }} operator+() const;
{{ sname }} operator-() const;
{#- Additive operators #}
{{ sname }}& operator+=(const {{ sname }}& rhs);
friend {{ sname }} operator+(const {{ sname }}& lhs, const {{ sname }}& rhs);
{{ sname }}& operator-=(const {{ sname }}& rhs);
friend {{ sname }} operator-(const {{ sname }}& lhs, const {{ sname }}& rhs);
{#- Mul operator #}
{{ sname }}& operator*=(CKFLOAT rhs);
friend {{ sname }} operator*(const {{ sname }}& lhs, CKFLOAT rhs);
friend {{ sname }} operator*(CKFLOAT lhs, const {{ sname }}& rhs);
friend CKFLOAT operator*(const {{ sname }}& lhs, const {{ sname }}& rhs);
{#- Div operator #}
{{ sname }}& operator/=(CKFLOAT rhs);
friend {{ sname }} operator/(const {{ sname }}& lhs, CKFLOAT rhs);
{#- Length functions #}
CKFLOAT SquaredLength() const;
CKFLOAT Length() const;
{#- Normalize functions #}
void Normalized();
{{ sname }} Normalize() const;
{%- endif %}
{#- END VECTOR SPECIFIC #}
{#- User custom region #}
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
};

21
CodeGen/VectorGen/VxTypes.shared.jinja Normal file
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@ -0,0 +1,21 @@
{#
The macro to generate C++ ctor argument list
It produce like this: `CKFLOAT _x, CKFLOAT _y, CKFLOAT _z, CKFLOAT _w`
#}
{% macro argument_list_builder(svars) %}
{%- for item in svars -%}
CKFLOAT _{{- item -}}{%- if not loop.last %}, {% endif -%}
{%- endfor -%}
{% endmacro %}
{#
The macro to generate C++ ctor initialize list
It produce like this: `x(0.0f), y(0.0f), z(0.0f), w(0.0f)`
or this: `x(_x), y(_y), z(_z), w(_w)`
according to user request.
#}
{% macro initialize_list_builder(svars, is_user) %}
{%- for item in svars -%}
{{- item -}}({%- if is_user -%}_{{- item -}}{%- else -%}0.0f{%- endif -%}){%- if not loop.last %}, {% endif -%}
{%- endfor -%}
{% endmacro %}

63
CodeGen/VectorGen/VxVectorGen.py Normal file
View File

@ -0,0 +1,63 @@
import os
import io
import typing
import jinja2
g_HppTemplateFile: str = 'VxTypes.hpp.jinja'
g_CppTemplateFile: str = 'VxTypes.cpp.jinja'
g_ResultHppFile: str = 'VxTypes.hpp'
g_ResultCppFile: str = 'VxTypes.cpp'
def get_root_directory() -> str:
return os.path.dirname(__file__)
class TemplateRender:
m_Loader: jinja2.BaseLoader
m_Environment: jinja2.Environment
m_HppTemplate: jinja2.Template
m_CppTemplate: jinja2.Template
m_OutputHpp: io.TextIOWrapper
m_OutputCpp: io.TextIOWrapper
def __init__(self, output_hpp_path: str, output_cpp_path: str) -> None:
self.m_Loader = jinja2.FileSystemLoader(get_root_directory())
self.m_Environment = jinja2.Environment(loader=self.m_Loader)
self.m_HppTemplate = self.m_Environment.get_template(g_HppTemplateFile)
self.m_CppTemplate = self.m_Environment.get_template(g_CppTemplateFile)
self.m_OutputHpp = open(os.path.join(get_root_directory(), output_hpp_path), 'w', encoding='utf-8')
self.m_OutputCpp = open(os.path.join(get_root_directory(), output_cpp_path), 'w', encoding='utf-8')
def __enter__(self):
return self
def __exit__(self, exc_type, exc_value, traceback):
self.m_OutputHpp.close()
self.m_OutputCpp.close()
def __render(self, sname: str, is_vector: bool, svars: tuple[str]) -> None:
template_argument: dict[str, typing.Any] = {
'sname': sname,
'is_vector': is_vector,
'svars': svars
}
self.m_OutputHpp.write(self.m_HppTemplate.render(**template_argument))
self.m_OutputCpp.write(self.m_CppTemplate.render(**template_argument))
def render_vector(self, sname: str, svars: tuple[str]) -> None:
self.__render(sname, True, svars)
def render_others(self, sname: str, svars: tuple[str]) -> None:
self.__render(sname, False, svars)
if __name__ == '__main__':
with TemplateRender(g_ResultHppFile, g_ResultCppFile) as render:
render.render_vector('VxVector2', ('x', 'y', ))
render.render_vector('VxVector3', ('x', 'y', 'z', ))
render.render_vector('VxVector4', ('x', 'y', 'z', 'w', ))
render.render_others('VxQuaternion', ('x', 'y', 'z', 'w', ))
render.render_others('VxColor', ('r', 'g', 'b', 'a', ))

166
CodeGen/VectorGen/VxVectors.py
View File

@ -1,166 +0,0 @@
import os
def GetTmplDecl(svars: tuple[str]) -> str:
return f'CKFLOAT {", ".join(svars)};'
def GetTmplCtor1(sname: str, svars: tuple[str]) -> str:
return f'{sname}() : {", ".join(map(lambda x: f"{x}(0.0f)", svars))} {{}}'
def GetTmplCtor2(sname: str, svars: tuple[str]) -> str:
return f'{sname}({", ".join(map(lambda x: f"CKFLOAT _{x}", svars))}) : {", ".join(map(lambda x: f"{x}(_{x})", svars))} {{}}'
def GetTmplCopyCtor(sname: str, svars: tuple[str]) -> str:
return f'{sname}(const {sname}& rhs) : {", ".join(map(lambda x: f"{x}(rhs.{x})", svars))} {{}}'
def GetTmplMoveCtor(sname: str, svars: tuple[str]) -> str:
return f'{sname}({sname}&& rhs) : {", ".join(map(lambda x: f"{x}(rhs.{x})", svars))} {{}}'
def GetTmplOperAssignCopy(sname: str, svars: tuple[str]) -> str:
sp: str = '\n\t\t'
return f"""\t{sname}& operator=(const {sname}& rhs) {{
\t\t{sp.join(map(lambda x: f'{x} = rhs.{x};', svars))}
\t\treturn *this;
\t}}"""
def GetTmplOperAssignMove(sname: str, svars: tuple[str]) -> str:
sp: str = '\n\t\t'
return f"""\t{sname}& operator=({sname}&& rhs) {{
\t\t{sp.join(map(lambda x: f'{x} = rhs.{x};', svars))}
\t\treturn *this;
\t}}"""
def GetTmplOperOffset(sname: str, svars: tuple[str]) -> str:
sp: str = '\n\t\t\t'
return f"""\tCKFLOAT& operator[](size_t i) {{
\t\tswitch (i) {{
\t\t\t{sp.join(map(lambda x: f'case {x}: return {svars[x]};', range(len(svars))))}
\t\t\tdefault: throw LogicException("Invalid index for {sname}::operator[].");
\t\t}}
\t}}
\tconst CKFLOAT& operator[](size_t i) const {{
\t\tswitch (i) {{
\t\t\t{sp.join(map(lambda x: f'case {x}: return {svars[x]};', range(len(svars))))}
\t\t\tdefault: throw LogicException("Invalid index for {sname}::operator[].");
\t\t}}
\t}}"""
def GetTmplOperAddMinus(sname: str, svars: tuple[str], oper: str) -> str:
sp: str = '\n\t\t'
return f"""\t{sname}& operator{oper}=(const {sname}& rhs) {{
\t\t{sp.join(map(lambda x: f'{x} {oper}= rhs.{x};', svars))}
\t\treturn *this;
\t}}
\tfriend {sname} operator{oper}(const {sname}& lhs, const {sname}& rhs) {{
\t\treturn {sname}({', '.join(map(lambda x: f'lhs.{x} {oper} rhs.{x}', svars))});
\t}}"""
def GetTmplOperMul(sname: str, svars: tuple[str]) -> str:
sp: str = '\n\t\t'
return f"""\t{sname}& operator*=(CKFLOAT rhs) {{
\t\t{sp.join(map(lambda x: f'{x} *= rhs;', svars))}
\t\treturn *this;
\t}}
\tfriend {sname} operator*(const {sname}& lhs, CKFLOAT rhs) {{
\t\treturn {sname}({', '.join(map(lambda x: f'lhs.{x} * rhs', svars))});
\t}}
\tfriend {sname} operator*(CKFLOAT lhs, const {sname}& rhs) {{
\t\treturn {sname}({', '.join(map(lambda x: f'lhs * rhs.{x}', svars))});
\t}}
\tfriend CKFLOAT operator*(const {sname}& lhs, const {sname}& rhs) {{
\t\treturn ({' + '.join(map(lambda x: f'lhs.{x} * rhs.{x}', svars))});
\t}}"""
def GetTmplOperDiv(sname: str, svars: tuple[str]) -> str:
sp: str = '\n\t\t'
return f"""\t{sname}& operator/=(CKFLOAT rhs) {{
\t\tif (rhs == 0.0f) return *this;
\t\t{sp.join(map(lambda x: f'{x} /= rhs;', svars))}
\t\treturn *this;
\t}}
\tfriend {sname} operator/(const {sname}& lhs, CKFLOAT rhs) {{
\t\tif (rhs == 0.0f) return {sname}({', '.join(map(lambda x: '0.0f', range(len(svars))))});
\t\treturn {sname}({', '.join(map(lambda x: f'lhs.{x} / rhs', svars))});
\t}}"""
def GetTmplOperEqual(sname: str, svars: tuple[str]) -> str:
return f"""\tbool operator==(const {sname}& rhs) const {{
\t\treturn ({' && '.join(map(lambda x: f'{x} == rhs.{x}', svars))});
\t}}"""
def GetTmplOperSpaceship(sname: str, svars: tuple[str]) -> str:
sp: str = '\n\t\t'
return f"""\tauto operator<=>(const {sname}& rhs) const {{
\t\t{sp.join(map(lambda x: f'if (auto cmp = {x} <=> rhs.{x}; cmp != 0) return cmp;', svars[:-1]))}
\t\treturn {svars[-1]} <=> rhs.{svars[-1]};
\t}}"""
def GetTmplLength(sname: str, svars: tuple[str]) -> str:
return f"""\tCKFLOAT SquaredLength() const {{
\t\treturn ({' + '.join(map(lambda x: f'{x} * {x}', svars))});
\t}}
\tCKFLOAT Length() const {{
\t\treturn std::sqrt(SquaredLength());
\t}}"""
def GetTmplNormalize(sname: str, svars: tuple[str]) -> str:
sp: str = '\n\t\t'
return f"""\tvoid Normalized() {{
\t\tCKFLOAT len = Length();
\t\tif (len == 0.0f) return;
\t\t{sp.join(map(lambda x: f'{x} /= len;', svars))}
\t}}
\t{sname} Normalize() const {{
\t\tCKFLOAT len = Length();
\t\tif (len == 0.0f) return {sname}();
\t\treturn {sname}({', '.join(map(lambda x: f'{x} / len', svars))});
\t}}"""
def GetTmplVector(sname: str, svars: tuple[str]) -> str:
return f"""
struct {sname} {{
\t{GetTmplDecl(svars)}
\t{GetTmplCtor1(sname, svars)}
\t{GetTmplCtor2(sname, svars)}
\tYYCC_DEF_CLS_COPY_MOVE({sname});
{GetTmplOperOffset(sname, svars)}
{GetTmplOperAddMinus(sname, svars, '+')}
{GetTmplOperAddMinus(sname, svars, '-')}
{GetTmplOperMul(sname, svars)}
{GetTmplOperDiv(sname, svars)}
{GetTmplOperEqual(sname, svars)}
{GetTmplOperSpaceship(sname, svars)}
{GetTmplLength(sname, svars)}
{GetTmplNormalize(sname, svars)}
}};
"""
def GetTmplOthers(sname: str, svars: tuple[str]) -> str:
return f"""
struct {sname} {{
\t{GetTmplDecl(svars)}
\t{GetTmplCtor1(sname, svars)} // set your custom init.
\t{GetTmplCtor2(sname, svars)}
\tYYCC_DEF_CLS_COPY_MOVE({sname});
{GetTmplOperOffset(sname, svars)}
{GetTmplOperEqual(sname, svars)}
{GetTmplOperSpaceship(sname, svars)}
}};
"""
# use YYCC_DEF_CLS_COPY_MOVE instead of these outputs.
#\t{GetTmplCopyCtor(sname, svars)}
#\t{GetTmplMoveCtor(sname, svars)}
#{GetTmplOperAssignCopy(sname, svars)}
#{GetTmplOperAssignMove(sname, svars)}
if __name__ == '__main__':
# get file path
self_path: str = os.path.dirname(__file__)
cpp_file: str = os.path.join(self_path, 'VxTypes.hpp')
# generate files
with open(cpp_file, 'w', encoding='utf-8') as fs:
fs.write(GetTmplVector('VxVector2', ('x', 'y', )))
fs.write(GetTmplVector('VxVector3', ('x', 'y', 'z', )))
fs.write(GetTmplVector('VxVector4', ('x', 'y', 'z', 'w', )))
fs.write(GetTmplOthers('VxQuaternion', ('x', 'y', 'z', 'w', )))
fs.write(GetTmplOthers('VxColor', ('r', 'g', 'b', 'a', )))

1
Documents/CMakeLists.txt
View File

@ -14,5 +14,6 @@ add_custom_target (NeMoDocuments
# Install built documentation
install (DIRECTORY ${CMAKE_CURRENT_BINARY_DIR}/html
CONFIGURATIONS Release RelWithDebInfo MinSizeRel
DESTINATION ${NEMO_INSTALL_DOC_PATH}
)

18
LibCmo/CK2/CKBitmapData.cpp
View File

@ -521,7 +521,7 @@ namespace LibCmo::CK2 {
m_Slots.resize(count);
if (count == 0) {
EnumsHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_INVALID);
YYCC::EnumHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_INVALID);
}
}
@ -535,8 +535,8 @@ namespace LibCmo::CK2 {
m_CurrentSlot = slot;
// NOTE: idk what the fuck this is. just interpter the IDA decompiled code.
if (EnumsHelper::Has(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP)) {
EnumsHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_FORCERESTORE);
if (YYCC::EnumHelper::Has(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP)) {
YYCC::EnumHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_FORCERESTORE);
}
}
@ -660,14 +660,14 @@ namespace LibCmo::CK2 {
// but we decide split the flag settings and slot.
// User should set slot count manually.
if (is_cube) {
EnumsHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP);
YYCC::EnumHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP);
} else {
EnumsHelper::Rm(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP);
YYCC::EnumHelper::Remove(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP);
}
}
bool CKBitmapData::IsCubeMap() const {
return EnumsHelper::Has(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP);
return YYCC::EnumHelper::Has(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_CUBEMAP);
}
const CKBitmapProperties& CKBitmapData::GetSaveFormat() const {
@ -688,14 +688,14 @@ namespace LibCmo::CK2 {
void CKBitmapData::SetTransparent(bool Transparency) {
if (Transparency) {
EnumsHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_TRANSPARENT);
YYCC::EnumHelper::Add(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_TRANSPARENT);
} else {
EnumsHelper::Rm(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_TRANSPARENT);
YYCC::EnumHelper::Remove(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_TRANSPARENT);
}
}
bool CKBitmapData::IsTransparent() const {
return EnumsHelper::Has(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_TRANSPARENT);
return YYCC::EnumHelper::Has(m_BitmapFlags, CK_BITMAPDATA_FLAGS::CKBITMAPDATA_TRANSPARENT);
}
void CKBitmapData::SetTransparentColor(CKDWORD col) {

3
LibCmo/CK2/CKContext.cpp
View File

@ -264,8 +264,7 @@ namespace LibCmo::CK2 {
va_list argptr;
va_start(argptr, fmt);
XContainer::XString result;
YYCC::StringHelper::VPrintf(fmt, argptr);
XContainer::XString result(YYCC::StringHelper::VPrintf(fmt, argptr));
va_end(argptr);
// use c_str(), not XContainer::NSXString::ToCKSTRING because we want make sure this paramter is not nullptr.

22
LibCmo/CK2/CKDefines.hpp
View File

@ -141,6 +141,28 @@ namespace LibCmo::CK2 {
CKFileExtension m_Ext; /**< File Extension of the image being described by this structure */
};
/**
* @brief Light Structure passed to CKRasterizerContext::SetLight()
* @details
* This struct is a part of CKRasterizer.
* I put it in there just for the convenience of CKLight.
*/
struct CKLightData {
VxMath::VXLIGHT_TYPE m_Type; /**< Point, Spot, Directionnal */
VxMath::VxColor m_Diffuse; /**< Diffuse Color */
VxMath::VxColor m_Specular; /**< Specular Color (Unused...) */
VxMath::VxColor m_Ambient; /**< Ambient Color (Unused...) */
VxMath::VxVector3 m_Position; /**< World Position */
VxMath::VxVector3 m_Direction; /**< Direction */
CKFLOAT m_Range; /**< Range */
CKFLOAT m_Falloff;
CKFLOAT m_Attenuation0;
CKFLOAT m_Attenuation1;
CKFLOAT m_Attenuation2;
CKFLOAT m_InnerSpotCone; /**< Only for spot lights */
CKFLOAT m_OuterSpotCone; /**< Only for spot lights */
};
#pragma endregion

5
LibCmo/CK2/CKEnums.hpp
View File

@ -256,4 +256,9 @@ namespace LibCmo::CK2 {
CKBITMAPDATA_DYNAMIC = 64,
};
enum class CK_CAMERA_PROJECTION : CKDWORD {
CK_PERSPECTIVEPROJECTION = 1,
CK_ORTHOGRAPHICPROJECTION = 2,
};
}

6
LibCmo/CK2/CKFile.hpp
View File

@ -44,9 +44,9 @@ namespace LibCmo::CK2 {
const void* GetPtr(CKINT extraoff = 0) { return (this->m_MemBegin + m_MemPos + extraoff); }
void* GetMutablePtr(CKINT extraoff = 0) { return (this->m_MemBegin + m_MemPos + extraoff); }
void* GetBase(void) { return this->m_MemBegin; }
CKDWORD GetSize(void) { return this->m_MemSize; }
CKDWORD GetCursor(void) { return this->m_MemPos; }
void* GetBase() { return this->m_MemBegin; }
CKDWORD GetSize() { return this->m_MemSize; }
CKDWORD GetCursor() { return this->m_MemPos; }
void MoveCursor(CKINT off) { this->m_MemPos += off; }
void SetCursor(CKDWORD off) { this->m_MemPos = off; }
void Read(void* data, CKDWORD data_size) {

47
LibCmo/CK2/CKFileReader.cpp
View File

@ -89,20 +89,49 @@ namespace LibCmo::CK2 {
// reset crc field of header
rawHeader.Crc = 0u;
// compute crc
// Compute and check CRC in theory (< Virtools 4.0)
CKDWORD gotten_crc = CKComputeDataCRC(&rawHeader, CKSizeof(CKRawFileInfo), 0u);
parser->SetCursor(sizeof(CKRawFileInfo));
parser->SetCursor(CKSizeof(CKRawFileInfo));
gotten_crc = CKComputeDataCRC(parser->GetPtr(), this->m_FileInfo.Hdr1PackSize, gotten_crc);
parser->MoveCursor(this->m_FileInfo.Hdr1PackSize);
gotten_crc = CKComputeDataCRC(parser->GetPtr(), this->m_FileInfo.DataPackSize, gotten_crc);
if (gotten_crc != this->m_FileInfo.Crc) {
this->m_Ctx->OutputToConsole(u8"Virtools file CRC error.");
return CKERROR::CKERR_FILECRCERROR;
// MARK:
// If the CRC check failed, there is another way to compute CRC. (>= Virtools 4.0)
// This is a patch for Dassault stupid programmer.
//
// After Virtools 4.0, Dassault use a new way to compute the CRC of file.
// Dassault introduces a new class called CKMemoryBufferWriter which use file and memory map to handle big file properly.
// This algorithm splits the whole data body into 8 MB chunks and calculate them one by one to avoid instantaneous memory occupation.
// However, there is a bug in virtual function CKMemoryBufferWriter::ComputeCRC.
// It takes `PreviousCRC` as argument but never use it in function.
// In this function, the start value of CRC compution is hardcoded 0.
// So, although Dassault programmer try to compute CRC for file header, header part and daat part in code, it actually only compute CRC for data part!
// I 100% sure this is the mistake of Dassault stupid programmer and this bug cause more horrible result.
//
// In Virtools 2.1, engine will check CRC of file first. If no matched CRC, engine will reject loading file.
// So the obvious result is that we can not load file saved by Virtools 4.0 in Virtools 2.1.
// But this is not the point which makes me indignant.
// The real weird point is that we can use Virtools 3.5 to open file saved by Virtools 4.0, but why?
// After some researches, I found that the programmer of Dassault totally removed CRC check when loading file, since some version which I don't know, to suppress this bug!
// This is totally cheat and commercial-oriented behavior!
// I guess Dassault programmer also found that they can not load new created file in old Virtools.
// But they didn't find out what cause this bug, and just directly remove the whole of CRC checker to resolve this bug!
// I can't believe that this thing happens on such official software.
// This is the point which makes me indignant.
gotten_crc = CKComputeDataCRC(parser->GetPtr(), this->m_FileInfo.DataPackSize, 0u);
// Both CRC compute methods are failed. This file may be really broken.
// Report exception directly.
if (gotten_crc != this->m_FileInfo.Crc) {
this->m_Ctx->OutputToConsole(u8"Virtools file CRC error.");
return CKERROR::CKERR_FILECRCERROR;
}
}
// reset cursor
parser->SetCursor(sizeof(CKRawFileInfo));
parser->SetCursor(CKSizeof(CKRawFileInfo));
// compare size to decide wheher use compress feature
if (this->m_FileInfo.Hdr1PackSize != this->m_FileInfo.Hdr1UnPackSize) {
@ -189,7 +218,7 @@ namespace LibCmo::CK2 {
if (this->m_FileInfo.FileVersion >= 8) {
// file ver >= 8, use header offset
// because it have compress feature
ParserPtr->SetCursor(this->m_FileInfo.Hdr1PackSize + sizeof(CKRawFileInfo));
ParserPtr->SetCursor(this->m_FileInfo.Hdr1PackSize + CKSizeof(CKRawFileInfo));
} else {
// otherwise, sync with current parser.
ParserPtr->SetCursor(parser->GetCursor());
@ -205,8 +234,8 @@ namespace LibCmo::CK2 {
std::string name_conv;
// ========== compress feature process ==========
if (EnumsHelper::Has(this->m_FileInfo.FileWriteMode, CK_FILE_WRITEMODE::CKFILE_CHUNKCOMPRESSED_OLD) ||
EnumsHelper::Has(this->m_FileInfo.FileWriteMode, CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED)) {
if (YYCC::EnumHelper::Has(this->m_FileInfo.FileWriteMode, CK_FILE_WRITEMODE::CKFILE_CHUNKCOMPRESSED_OLD) ||
YYCC::EnumHelper::Has(this->m_FileInfo.FileWriteMode, CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED)) {
void* decomp_buffer = CKUnPackData(this->m_FileInfo.DataUnPackSize, parser->GetPtr(), this->m_FileInfo.DataPackSize);
if (decomp_buffer != nullptr) {
@ -397,7 +426,7 @@ namespace LibCmo::CK2 {
}
// ========== finalize work ==========
// set done flag and return
this->m_Done = true;

8
LibCmo/CK2/CKFileWriter.cpp
View File

@ -216,8 +216,8 @@ namespace LibCmo::CK2 {
}
// compress header if needed
if (EnumsHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_CHUNKCOMPRESSED_OLD) ||
EnumsHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED)) {
if (YYCC::EnumHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_CHUNKCOMPRESSED_OLD) ||
YYCC::EnumHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED)) {
CKDWORD comp_buf_size = 0;
void* comp_buffer = CKPackData(hdrparser->GetBase(), hdrparser->GetSize(), comp_buf_size, m_Ctx->GetCompressionLevel());
@ -263,8 +263,8 @@ namespace LibCmo::CK2 {
}
// compress header if needed
if (EnumsHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_CHUNKCOMPRESSED_OLD) ||
EnumsHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED)) {
if (YYCC::EnumHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_CHUNKCOMPRESSED_OLD) ||
YYCC::EnumHelper::Has(fileWriteMode, CK_FILE_WRITEMODE::CKFILE_WHOLECOMPRESSED)) {
CKDWORD comp_buf_size = 0;
void* comp_buffer = CKPackData(datparser->GetBase(), datparser->GetSize(), comp_buf_size, m_Ctx->GetCompressionLevel());

8
LibCmo/CK2/CKGlobals.cpp
View File

@ -20,6 +20,10 @@
#include "ObjImpls/CKTexture.hpp"
#include "ObjImpls/CKMaterial.hpp"
#include "ObjImpls/CKMesh.hpp"
#include "ObjImpls/CKLight.hpp"
#include "ObjImpls/CKTargetLight.hpp"
#include "ObjImpls/CKCamera.hpp"
#include "ObjImpls/CKTargetCamera.hpp"
namespace LibCmo::CK2 {
@ -439,6 +443,10 @@ CKClassRegister(cid, parentCid, \
EasyClassReg(ObjImpls::CKTexture, CK_CLASSID::CKCID_TEXTURE, CK_CLASSID::CKCID_BEOBJECT, "Texture");
EasyClassRegWithNotify(ObjImpls::CKMaterial, CK_CLASSID::CKCID_MATERIAL, CK_CLASSID::CKCID_BEOBJECT, "Material", { CK_CLASSID::CKCID_TEXTURE });
EasyClassRegWithNotify(ObjImpls::CKMesh, CK_CLASSID::CKCID_MESH, CK_CLASSID::CKCID_BEOBJECT, "Mesh", { CK_CLASSID::CKCID_MATERIAL });
EasyClassReg(ObjImpls::CKLight, CK_CLASSID::CKCID_LIGHT, CK_CLASSID::CKCID_3DENTITY, "Light");
EasyClassReg(ObjImpls::CKCamera, CK_CLASSID::CKCID_CAMERA, CK_CLASSID::CKCID_3DENTITY, "Camera");
EasyClassRegWithNotify(ObjImpls::CKTargetLight, CK_CLASSID::CKCID_TARGETLIGHT, CK_CLASSID::CKCID_LIGHT, "Target Light", { CK_CLASSID::CKCID_3DENTITY });
EasyClassRegWithNotify(ObjImpls::CKTargetCamera, CK_CLASSID::CKCID_TARGETCAMERA, CK_CLASSID::CKCID_CAMERA, "Target Camera", { CK_CLASSID::CKCID_3DENTITY });
#undef EasyClassReg
#undef EasyClassRegWithNotify

6
LibCmo/CK2/CKStateChunk.hpp
View File

@ -265,8 +265,8 @@ namespace LibCmo::CK2 {
#pragma region Read Function
public:
void StartRead(void);
void StopRead(void);
void StartRead();
void StopRead();
/* ========== Identifier Functions ==========*/
@ -556,7 +556,7 @@ namespace LibCmo::CK2 {
/*
* Actually this function mix various functions, including CloseChunk(), UpdateSize() and etc.
*/
void StopWrite(void);
void StopWrite();
/* ========== Identifier Functions ==========*/

16
LibCmo/CK2/CKStateChunkOthers.cpp
View File

@ -419,23 +419,23 @@ namespace LibCmo::CK2 {
std::memcpy(this->m_pData, dwbuf + bufpos, sizeof(CKDWORD) * this->m_DataDwSize);
bufpos += this->m_DataDwSize;
}
if (!EnumsHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_FILE)) {
if (!YYCC::EnumHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_FILE)) {
// forced no bind file
this->m_BindFile = nullptr;
}
if (EnumsHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_IDS)) {
if (YYCC::EnumHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_IDS)) {
this->m_ObjectList.resize(dwbuf[bufpos]);
bufpos += 1u;
std::memcpy(this->m_ObjectList.data(), dwbuf + bufpos, sizeof(CKDWORD) * this->m_ObjectList.size());
bufpos += this->m_ObjectList.size();
}
if (EnumsHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_CHN)) {
if (YYCC::EnumHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_CHN)) {
this->m_ChunkList.resize(dwbuf[bufpos]);
bufpos += 1u;
std::memcpy(this->m_ChunkList.data(), dwbuf + bufpos, sizeof(CKDWORD) * this->m_ChunkList.size());
bufpos += this->m_ChunkList.size();
}
if (EnumsHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_MAN)) {
if (YYCC::EnumHelper::Has(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_MAN)) {
this->m_ManagerList.resize(dwbuf[bufpos]);
bufpos += 1u;
std::memcpy(this->m_ManagerList.data(), dwbuf + bufpos, sizeof(CKDWORD) * this->m_ManagerList.size());
@ -459,19 +459,19 @@ namespace LibCmo::CK2 {
if (!m_ObjectList.empty()) {
size += CKSizeof(CKDWORD) * static_cast<CKDWORD>(m_ObjectList.size()) + sizeof(CKDWORD);
EnumsHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_IDS);
YYCC::EnumHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_IDS);
}
if (!m_ChunkList.empty()) {
size += CKSizeof(CKDWORD) * static_cast<CKDWORD>(m_ChunkList.size()) + sizeof(CKDWORD);
EnumsHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_CHN);
YYCC::EnumHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_CHN);
}
if (!m_ManagerList.empty()) {
size += CKSizeof(CKDWORD) * static_cast<CKDWORD>(m_ManagerList.size()) + sizeof(CKDWORD);
EnumsHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_MAN);
YYCC::EnumHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_MAN);
}
if (this->m_BindFile != nullptr) {
EnumsHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_FILE);
YYCC::EnumHelper::Add(options, CK_STATECHUNK_CHUNKOPTIONS::CHNK_OPTION_FILE);
}
// if buffer provided, write it

6
LibCmo/CK2/CKStateChunkReader.cpp
View File

@ -4,7 +4,7 @@
namespace LibCmo::CK2 {
void CKStateChunk::StartRead(void) {
void CKStateChunk::StartRead() {
if (this->m_Parser.m_Status != CKStateChunkStatus::IDLE) return;
this->m_Parser.m_CurrentPos = 0u;
@ -13,7 +13,7 @@ namespace LibCmo::CK2 {
this->m_Parser.m_Status = CKStateChunkStatus::READ;
}
void CKStateChunk::StopRead(void) {
void CKStateChunk::StopRead() {
if (this->m_Parser.m_Status != CKStateChunkStatus::READ) return;
this->m_Parser.m_CurrentPos = 0u;
@ -220,7 +220,7 @@ namespace LibCmo::CK2 {
return true;
}
//CKStateChunk* CKStateChunk::ReadSubChunk(void) {
//CKStateChunk* CKStateChunk::ReadSubChunk() {
// CKStateChunk* subchunk = nullptr;
// // get size and do a enough space check

2
LibCmo/CK2/CKStateChunkWriter.cpp
View File

@ -32,7 +32,7 @@ namespace LibCmo::CK2 {
this->m_Parser.m_Status = CKStateChunkStatus::WRITE;
}
void CKStateChunk::StopWrite(void) {
void CKStateChunk::StopWrite() {
if (this->m_Parser.m_Status != CKStateChunkStatus::WRITE) return;
// update buffer size

2
LibCmo/CK2/MgrImpls/CKObjectManager.cpp
View File

@ -86,7 +86,7 @@ namespace LibCmo::CK2::MgrImpls {
// set to be deleted
CK_OBJECT_FLAGS objflag = obj->GetObjectFlags();
EnumsHelper::Add(objflag, CK_OBJECT_FLAGS::CK_OBJECT_TOBEDELETED);
YYCC::EnumHelper::Add(objflag, CK_OBJECT_FLAGS::CK_OBJECT_TOBEDELETED);
obj->SetObjectFlags(objflag);
// collect class id

64
LibCmo/CK2/ObjImpls/CK3dEntity.cpp
View File

@ -9,12 +9,12 @@ namespace LibCmo::CK2::ObjImpls {
CKRenderObject(ctx, ckid, name),
m_PotentialMeshes(), m_CurrentMesh(nullptr),
m_WorldMatrix(), m_ZOrder(0),
m_MoveableFlags(EnumsHelper::Merge({
m_MoveableFlags(YYCC::EnumHelper::Merge(
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_PICKABLE,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_RENDERCHANNELS,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_INVERSEWORLDMATVALID
})),
)),
m_3dEntityFlags(static_cast<CK_3DENTITY_FLAGS>(0)) {}
CK3dEntity::~CK3dEntity() {}
@ -53,15 +53,15 @@ namespace LibCmo::CK2::ObjImpls {
// regulate self flag again
// MARK: originally we should check parent here.
// but we do not support parent and hierarchy feature, so we simply remove flag
EnumsHelper::Rm(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PARENTVALID);
YYCC::EnumHelper::Remove(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PARENTVALID);
// MARK: originally we should check grouped into CKPlace here.
// but we do not support CKPlace, so we simply remove this flag
EnumsHelper::Rm(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PLACEVALID);
YYCC::EnumHelper::Remove(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PLACEVALID);
// check z-order, if not zero, save it
if (m_ZOrder != 0) {
EnumsHelper::Add(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_ZORDERVALID);
YYCC::EnumHelper::Add(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_ZORDERVALID);
} else {
EnumsHelper::Rm(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_ZORDERVALID);
YYCC::EnumHelper::Remove(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_ZORDERVALID);
}
// write 2 flags
@ -94,7 +94,7 @@ namespace LibCmo::CK2::ObjImpls {
if (!suc) return false;
// backup moveable flags
bool hasWorldAligned = EnumsHelper::Has(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_WORLDALIGNED);
bool hasWorldAligned = YYCC::EnumHelper::Has(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_WORLDALIGNED);
// MARK: object animation is skipped
@ -132,11 +132,11 @@ namespace LibCmo::CK2::ObjImpls {
chunk->ReadStruct(m_3dEntityFlags);
chunk->ReadStruct(m_MoveableFlags);
// remove some properties
EnumsHelper::Rm(m_3dEntityFlags, EnumsHelper::Merge({
YYCC::EnumHelper::Remove(m_3dEntityFlags,
CK_3DENTITY_FLAGS::CK_3DENTITY_UPDATELASTFRAME,
CK_3DENTITY_FLAGS::CK_3DENTITY_RESERVED0
}));
EnumsHelper::Rm(m_MoveableFlags, EnumsHelper::Merge({
);
YYCC::EnumHelper::Remove(m_MoveableFlags,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_RESERVED2,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_STENCILONLY,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_DONTUPDATEFROMPARENT,
@ -145,19 +145,19 @@ namespace LibCmo::CK2::ObjImpls {
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_BOXVALID,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_USERBOX,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_UPTODATE
}));
);
if (hasWorldAligned) {
EnumsHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_WORLDALIGNED);
YYCC::EnumHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_WORLDALIGNED);
}
// if order render first
if (EnumsHelper::Has(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_RENDERFIRST)) {
if (YYCC::EnumHelper::Has(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_RENDERFIRST)) {
m_ZOrder = 10000;
}
// read matrix
// reset
m_WorldMatrix.ResetToIdentity();
m_WorldMatrix.SetIdentity();
// force read as vector3
chunk->ReadStruct(reinterpret_cast<VxMath::VxVector3*>(&m_WorldMatrix[0]));
chunk->ReadStruct(reinterpret_cast<VxMath::VxVector3*>(&m_WorldMatrix[1]));
@ -171,47 +171,47 @@ namespace LibCmo::CK2::ObjImpls {
VxMath::VxVector3 crossProduct = VxMath::NSVxVector::CrossProduct(col0, col1);
CKFLOAT dotProduct = VxMath::NSVxVector::DotProduct(crossProduct, col2);
if (dotProduct >= 0.0f) {
EnumsHelper::Rm(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_INDIRECTMATRIX);
YYCC::EnumHelper::Remove(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_INDIRECTMATRIX);
} else {
EnumsHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_INDIRECTMATRIX);
YYCC::EnumHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_INDIRECTMATRIX);
}
// copy visible data
// process direct visible
if (EnumsHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE)) {
EnumsHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE);
if (YYCC::EnumHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE)) {
YYCC::EnumHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE);
} else {
EnumsHelper::Rm(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE);
YYCC::EnumHelper::Remove(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE);
}
// process indirect visible
if (EnumsHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE)) {
EnumsHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE);
if (YYCC::EnumHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE)) {
YYCC::EnumHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE);
} else {
EnumsHelper::Rm(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE);
YYCC::EnumHelper::Remove(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE);
}
// read associated CKPlace
if (EnumsHelper::Has(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PLACEVALID)) {
if (YYCC::EnumHelper::Has(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PLACEVALID)) {
// MARK: we drop the support of CKPlace.
// so we just read it and skip it.
CK_ID placeid;
chunk->ReadObjectID(placeid);
// and remove this flag
EnumsHelper::Rm(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PLACEVALID);
YYCC::EnumHelper::Remove(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PLACEVALID);
}
// read parent
if (EnumsHelper::Has(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PARENTVALID)) {
if (YYCC::EnumHelper::Has(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PARENTVALID)) {
// MAKR: we drop the support of parent and the whole 3dentity hierarchy system
// we ignore this field.
CK_ID parentid;
chunk->ReadObjectID(parentid);
// and remove this flag
EnumsHelper::Rm(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PARENTVALID);
YYCC::EnumHelper::Remove(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_PARENTVALID);
}
// read priority (non-zero zorder)
if (EnumsHelper::Has(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_ZORDERVALID)) {
if (YYCC::EnumHelper::Has(m_3dEntityFlags, CK_3DENTITY_FLAGS::CK_3DENTITY_ZORDERVALID)) {
chunk->ReadStruct(m_ZOrder);
}
@ -227,16 +227,16 @@ namespace LibCmo::CK2::ObjImpls {
void CK3dEntity::Show(CK_OBJECT_SHOWOPTION show) {
CKObject::Show(show);
EnumsHelper::Rm(m_MoveableFlags, EnumsHelper::Merge({
YYCC::EnumHelper::Remove(m_MoveableFlags,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE,
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE,
}));
VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE
);
switch (show) {
case CK_OBJECT_SHOWOPTION::CKSHOW:
EnumsHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE);
YYCC::EnumHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_VISIBLE);
break;
case CK_OBJECT_SHOWOPTION::CKHIERARCHICALHIDE:
EnumsHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE);
YYCC::EnumHelper::Add(m_MoveableFlags, VxMath::VX_MOVEABLE_FLAGS::VX_MOVEABLE_HIERARCHICALHIDE);
break;
case CK_OBJECT_SHOWOPTION::CKHIDE:
break;

4
LibCmo/CK2/ObjImpls/CK3dEntity.hpp
View File

@ -11,7 +11,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CK3dEntity();
YYCC_DEL_CLS_COPY_MOVE(CK3dEntity);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_3DENTITY;
}
@ -48,6 +48,8 @@ namespace LibCmo::CK2::ObjImpls {
CKDWORD m_ZOrder; // replace the whole heavy CKSceneGraphNode
VxMath::VX_MOVEABLE_FLAGS m_MoveableFlags;
// MARK: This field is called m_EntityFlags in reverse project.
// I change this because I want to give it a more explicit name to make it is different with other flags.
CK_3DENTITY_FLAGS m_3dEntityFlags;
};

2
LibCmo/CK2/ObjImpls/CK3dObject.hpp
View File

@ -13,7 +13,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CK3dObject() {}
YYCC_DEL_CLS_COPY_MOVE(CK3dObject);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_3DOBJECT;
}
// CK3dObject do not implement any load/save functions

2
LibCmo/CK2/ObjImpls/CKBeObject.hpp
View File

@ -11,7 +11,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKBeObject();
YYCC_DEL_CLS_COPY_MOVE(CKBeObject);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_BEOBJECT;
}

155
LibCmo/CK2/ObjImpls/CKCamera.cpp Normal file
View File

@ -0,0 +1,155 @@
#include "CKCamera.hpp"
#include "../CKStateChunk.hpp"
namespace LibCmo::CK2::ObjImpls {
// Convenient macro to mark this object is not UPTODATE.
#define REMOVE_UPTODATE_FLAG { \
CK_OBJECT_FLAGS obj_flags = GetObjectFlags(); \
YYCC::EnumHelper::Remove(obj_flags, CK_OBJECT_FLAGS::CK_OBJECT_UPTODATE); \
SetObjectFlags(obj_flags); \
}
CKCamera::CKCamera(CKContext* ctx, CK_ID ckid, CKSTRING name) :
CK3dEntity(ctx, ckid, name),
m_ProjectType(CK_CAMERA_PROJECTION::CK_PERSPECTIVEPROJECTION),
m_Fov(0.5f), m_OrthographicZoom(1.0f),
m_Width(4), m_Height(3),
m_FrontPlane(1.0f), m_BackPlane(4000.0f) {
REMOVE_UPTODATE_FLAG;
}
CKCamera::~CKCamera() {}
bool CKCamera::Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) {
bool suc = CK3dEntity::Save(chunk, file, flags);
if (!suc) return false;
// Save main data
{
chunk->WriteIdentifier(CK_STATESAVEFLAGS_CAMERA::CK_STATESAVE_CAMERAONLY);
chunk->WriteStruct(m_ProjectType);
chunk->WriteStruct(m_Fov);
chunk->WriteStruct(m_OrthographicZoom);
// Build width and height compound.
CKDWORD widht_and_height = m_Width & 0x0000FFFFu;
widht_and_height |= (m_Height << 16) & 0xFFFF0000u;
chunk->WriteStruct(widht_and_height);
chunk->WriteStruct(m_FrontPlane);
chunk->WriteStruct(m_BackPlane);
}
chunk->SetClassId(CK_CLASSID::CKCID_CAMERA);
return true;
}
bool CKCamera::Load(CKStateChunk* chunk, CKFileVisitor* file) {
bool suc = CK3dEntity::Load(chunk, file);
if (!suc) return false;
// MARK: Drop the support for very old file format.
if (chunk->GetDataVersion() < CK_STATECHUNK_DATAVERSION::CHUNK_MAJORCHANGE_VERSION) {
return false;
}
// Read main data
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_CAMERA::CK_STATESAVE_CAMERAONLY)) {
chunk->ReadStruct(m_ProjectType);
chunk->ReadStruct(m_Fov);
chunk->ReadStruct(m_OrthographicZoom);
// Width and Height is stored in one DWORD
// Higher WORD is height and lower WORD is width.
// HIGH >>> height (2 bytes), width (2 bytes) <<< LOW
CKDWORD widht_and_height;
chunk->ReadStruct(widht_and_height);
m_Width = widht_and_height & 0x0000FFFFu;
m_Height = (widht_and_height & 0xFFFF0000u) >> 16;
chunk->ReadStruct(m_FrontPlane);
chunk->ReadStruct(m_BackPlane);
}
REMOVE_UPTODATE_FLAG;
return true;
}
#pragma region Class Operations
CK_CAMERA_PROJECTION CKCamera::GetProjectionType() const {
return m_ProjectType;
}
void CKCamera::SetProjectionType(CK_CAMERA_PROJECTION proj) {
m_ProjectType = proj;
REMOVE_UPTODATE_FLAG;
}
CKFLOAT CKCamera::GetOrthographicZoom() const {
return m_OrthographicZoom;
}
void CKCamera::SetOrthographicZoom(CKFLOAT zoom) {
m_OrthographicZoom = zoom;
REMOVE_UPTODATE_FLAG;
}
CKFLOAT CKCamera::GetFrontPlane() const {
return m_FrontPlane;
}
CKFLOAT CKCamera::GetBackPlane() const {
return m_BackPlane;
}
CKFLOAT CKCamera::GetFov() const {
return m_Fov;
}
void CKCamera::SetFrontPlane(CKFLOAT front) {
m_FrontPlane = front;
REMOVE_UPTODATE_FLAG;
}
void CKCamera::SetBackPlane(CKFLOAT back) {
m_BackPlane = back;
REMOVE_UPTODATE_FLAG;
}
void CKCamera::SetFov(CKFLOAT fov) {
m_Fov = fov;
REMOVE_UPTODATE_FLAG;
}
void CKCamera::GetAspectRatio(CKDWORD& width, CKDWORD& height) const {
width = m_Width;
height = m_Height;
}
void CKCamera::SetAspectRatio(CKDWORD width, CKDWORD height) {
m_Width = width;
m_Height = height;
REMOVE_UPTODATE_FLAG;
}
void CKCamera::ComputeProjectionMatrix(VxMath::VxMatrix& mat) const {
CKFLOAT aspect = static_cast<CKFLOAT>(m_Width) / m_Height;
if (m_ProjectType == CK_CAMERA_PROJECTION::CK_PERSPECTIVEPROJECTION) {
mat.Perspective(m_Fov, aspect, m_FrontPlane, m_BackPlane);
} else {
mat.Orthographic(m_OrthographicZoom, aspect, m_FrontPlane, m_BackPlane);
}
}
//void CKCamera::ResetRoll() {}
//void CKCamera::Roll(CKFLOAT angle) {}
CK3dEntity* CKCamera::GetTarget() const {
// Not supported, return nullptr anyway.
return nullptr;
}
void CKCamera::SetTarget(CK3dEntity* target) {
// Do nothing because no support.
}
#pragma endregion
// Undef convenient macro
#undef REMOVE_UPTODATE_FLAG
}

58
LibCmo/CK2/ObjImpls/CKCamera.hpp Normal file
View File

@ -0,0 +1,58 @@
#pragma once
#include "../../VTInternal.hpp"
#include "CK3dEntity.hpp"
namespace LibCmo::CK2::ObjImpls {
class CKCamera : public CK3dEntity {
public:
CKCamera(CKContext* ctx, CK_ID ckid, CKSTRING name);
virtual ~CKCamera();
YYCC_DEL_CLS_COPY_MOVE(CKCamera);
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_CAMERA;
}
// 2 RW funcions
virtual bool Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) override;
virtual bool Load(CKStateChunk* chunk, CKFileVisitor* file) override;
CK_CAMERA_PROJECTION GetProjectionType() const;
void SetProjectionType(CK_CAMERA_PROJECTION proj);
CKFLOAT GetOrthographicZoom() const;
void SetOrthographicZoom(CKFLOAT zoom);
CKFLOAT GetFrontPlane() const;
CKFLOAT GetBackPlane() const;
CKFLOAT GetFov() const;
void SetFrontPlane(CKFLOAT front);
void SetBackPlane(CKFLOAT back);
void SetFov(CKFLOAT fov);
void GetAspectRatio(CKDWORD& width, CKDWORD& height) const;
void SetAspectRatio(CKDWORD width, CKDWORD height);
void ComputeProjectionMatrix(VxMath::VxMatrix& mat) const;
// TODO: Finish CKCamera roll feature because it now involve some functions which is not implemented in CK3dEntity.
// Roll Angle
//void ResetRoll();
//void Roll(CKFLOAT angle);
// Target access
virtual CK3dEntity* GetTarget() const;
virtual void SetTarget(CK3dEntity* target);
protected:
CKFLOAT m_Fov;
CKFLOAT m_FrontPlane, m_BackPlane;
CK_CAMERA_PROJECTION m_ProjectType;
CKFLOAT m_OrthographicZoom;
CKDWORD m_Width, m_Height;
};
}

2
LibCmo/CK2/ObjImpls/CKGroup.hpp
View File

@ -11,7 +11,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKGroup();
YYCC_DEL_CLS_COPY_MOVE(CKGroup);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_GROUP;
}

232
LibCmo/CK2/ObjImpls/CKLight.cpp Normal file
View File

@ -0,0 +1,232 @@
#include "CKLight.hpp"
#include "../CKStateChunk.hpp"
#include <numbers>
namespace LibCmo::CK2::ObjImpls {
CKLight::CKLight(CKContext* ctx, CK_ID ckid, CKSTRING name) :
CK3dEntity(ctx, ckid, name),
m_LightData(), m_LightFlags(LightFlags::Active), m_LightPower(1.0f) {
// Setup light data
m_LightData.m_Type = VxMath::VXLIGHT_TYPE::VX_LIGHTPOINT;
m_LightData.m_Diffuse = VxMath::VxColor(1.0f, 1.0f, 1.0f);
m_LightData.m_Specular = VxMath::VxColor(0);
m_LightData.m_Ambient = VxMath::VxColor(0.0f, 0.0f, 0.0f);
m_LightData.m_Range = 5000.0f;
m_LightData.m_Falloff = 1.0f;
m_LightData.m_Attenuation0 = 1.0f;
m_LightData.m_Attenuation1 = 0.0f;
m_LightData.m_Attenuation2 = 0.0f;
m_LightData.m_InnerSpotCone = 40.0f / 180.0f * std::numbers::pi_v<float>; // MARK: Original value is 0.69813174f. Perhaps 40 deg in rad.
m_LightData.m_OuterSpotCone = 45.0f / 180.0f * std::numbers::pi_v<float>; // MARK: Original value is 0.78539819f. Perhaps 45 deg in rad.
}
CKLight::~CKLight() {}
bool CKLight::Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) {
bool suc = CK3dEntity::Save(chunk, file, flags);
if (!suc) return false;
// Save main data
{
chunk->WriteIdentifier(CK_STATESAVEFLAGS_LIGHT::CK_STATESAVE_LIGHTDATA);
// Combine light type and flags data.
CKDWORD light_type_and_flags = static_cast<CKDWORD>(m_LightFlags) & 0xFFFFFF00u;
light_type_and_flags |= static_cast<CKDWORD>(m_LightData.m_Type) & 0xFFu;
chunk->WriteStruct(light_type_and_flags);
// Save diffuse color with constant 1.0 alpha factor.
chunk->WriteStruct(m_LightData.m_Diffuse.ToARGB() | 0xFF000000u);
chunk->WriteStruct(m_LightData.m_Attenuation0);
chunk->WriteStruct(m_LightData.m_Attenuation1);
chunk->WriteStruct(m_LightData.m_Attenuation2);
chunk->WriteStruct(m_LightData.m_Range);
if (m_LightData.m_Type == VxMath::VXLIGHT_TYPE::VX_LIGHTSPOT) {
chunk->WriteStruct(m_LightData.m_OuterSpotCone);
chunk->WriteStruct(m_LightData.m_InnerSpotCone);
chunk->WriteStruct(m_LightData.m_Falloff);
}
}
// Save light power
if (m_LightPower != 1.0f) {
chunk->WriteIdentifier(CK_STATESAVEFLAGS_LIGHT::CK_STATESAVE_LIGHTDATA2);
chunk->WriteStruct(m_LightPower);
}
chunk->SetClassId(CK_CLASSID::CKCID_LIGHT);
return true;
}
bool CKLight::Load(CKStateChunk* chunk, CKFileVisitor* file) {
bool suc = CK3dEntity::Load(chunk, file);
if (!suc) return false;
// MARK: I drop the read process for too low version.
// return false anyway.
if (chunk->GetDataVersion() < CK_STATECHUNK_DATAVERSION::CHUNK_MAJORCHANGE_VERSION) {
return false;
}
// Read main data
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_LIGHT::CK_STATESAVE_LIGHTDATA)) {
// Read a DWORD storing light type and flags
// Because the lowest byte in light flags always is 0x00,
// so Virtools use it to store light type.
// After removing light type component, the rest of data is light flags.
// (do not need any SHIFT! It's okey that just set the lowest byte to zero.)
CKDWORD light_type_and_flags;
chunk->ReadStruct(light_type_and_flags);
m_LightData.m_Type = static_cast<VxMath::VXLIGHT_TYPE>(light_type_and_flags & 0xFFu);
m_LightFlags = static_cast<LightFlags>(light_type_and_flags & 0xFFFFFF00u);
CKDWORD dword_diffuse;
chunk->ReadStruct(dword_diffuse);
m_LightData.m_Diffuse = VxMath::VxColor(dword_diffuse);
chunk->ReadStruct(m_LightData.m_Attenuation0);
chunk->ReadStruct(m_LightData.m_Attenuation1);
chunk->ReadStruct(m_LightData.m_Attenuation2);
chunk->ReadStruct(m_LightData.m_Range);
if (m_LightData.m_Type == VxMath::VXLIGHT_TYPE::VX_LIGHTSPOT) {
chunk->ReadStruct(m_LightData.m_OuterSpotCone);
chunk->ReadStruct(m_LightData.m_InnerSpotCone);
chunk->ReadStruct(m_LightData.m_Falloff);
}
}
// Read light power
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_LIGHT::CK_STATESAVE_LIGHTDATA2)) {
chunk->ReadStruct(m_LightPower);
} else {
m_LightPower = 1.0f;
}
// Correct light type to prevent accident out of range value.
switch (m_LightData.m_Type) {
case VxMath::VXLIGHT_TYPE::VX_LIGHTPOINT:
case VxMath::VXLIGHT_TYPE::VX_LIGHTSPOT:
case VxMath::VXLIGHT_TYPE::VX_LIGHTDIREC:
case VxMath::VXLIGHT_TYPE::VX_LIGHTPARA:
// do nothing
break;
default:
// reset it to point
m_LightData.m_Type = VxMath::VXLIGHT_TYPE::VX_LIGHTPOINT;
break;
}
return true;
}
#pragma region Class Operations
VxMath::VXLIGHT_TYPE CKLight::GetType() const {
return m_LightData.m_Type;
}
void CKLight::SetType(VxMath::VXLIGHT_TYPE light_type) {
m_LightData.m_Type = light_type;
}
const VxMath::VxColor& CKLight::GetColor() const {
return m_LightData.m_Diffuse;
}
void CKLight::SetColor(const VxMath::VxColor& c) {
m_LightData.m_Diffuse = c;
}
CKFLOAT CKLight::GetConstantAttenuation() const {
return m_LightData.m_Attenuation0;
}
CKFLOAT CKLight::GetLinearAttenuation() const {
return m_LightData.m_Attenuation1;
}
CKFLOAT CKLight::GetQuadraticAttenuation() const {
return m_LightData.m_Attenuation2;
}
void CKLight::SetConstantAttenuation(CKFLOAT value) {
m_LightData.m_Attenuation0 = value;
}
void CKLight::SetLinearAttenuation(CKFLOAT value) {
m_LightData.m_Attenuation1 = value;
}
void CKLight::SetQuadraticAttenuation(CKFLOAT value) {
m_LightData.m_Attenuation2 = value;
}
CKFLOAT CKLight::GetRange() const {
return m_LightData.m_Range;
}
void CKLight::SetRange(CKFLOAT value) {
m_LightData.m_Range = value;
}
CKFLOAT CKLight::GetHotSpot() const {
return m_LightData.m_InnerSpotCone;
}
CKFLOAT CKLight::GetFalloff() const {
return m_LightData.m_OuterSpotCone;
}
CKFLOAT CKLight::GetFalloffShape() const {
return m_LightData.m_Falloff;
}
void CKLight::SetHotSpot(CKFLOAT value) {
m_LightData.m_InnerSpotCone = value;
}
void CKLight::SetFalloff(CKFLOAT value) {
m_LightData.m_OuterSpotCone = value;
}
void CKLight::SetFalloffShape(CKFLOAT value) {
m_LightData.m_Falloff = value;
}
bool CKLight::GetActivity() const {
return YYCC::EnumHelper::Has(m_LightFlags, LightFlags::Active);
}
void CKLight::Active(bool active) {
if (active) {
YYCC::EnumHelper::Add(m_LightFlags, LightFlags::Active);
} else {
YYCC::EnumHelper::Remove(m_LightFlags, LightFlags::Active);
}
}
bool CKLight::GetSpecularFlag() const {
return YYCC::EnumHelper::Has(m_LightFlags, LightFlags::Specular);
}
void CKLight::SetSpecularFlag(bool specular) {
if (specular) {
YYCC::EnumHelper::Add(m_LightFlags, LightFlags::Specular);
} else {
YYCC::EnumHelper::Remove(m_LightFlags, LightFlags::Specular);
}
}
CK3dEntity* CKLight::GetTarget() const {
// Normal light do not support target.
// So it always return nullptr.
return nullptr;
}
void CKLight::SetTarget(CK3dEntity* target) {
// Normal light do not support target.
// So, do nothing.
}
CKFLOAT CKLight::GetLightPower() const {
return m_LightPower;
}
void CKLight::SetLightPower(CKFLOAT power) {
m_LightPower = power;
}
#pragma endregion
}

75
LibCmo/CK2/ObjImpls/CKLight.hpp Normal file
View File

@ -0,0 +1,75 @@
#pragma once
#include "../../VTInternal.hpp"
#include "CK3dEntity.hpp"
namespace LibCmo::CK2::ObjImpls {
class CKLight : public CK3dEntity {
public:
CKLight(CKContext* ctx, CK_ID ckid, CKSTRING name);
virtual ~CKLight();
YYCC_DEL_CLS_COPY_MOVE(CKLight);
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_LIGHT;
}
// 2 RW funcions
virtual bool Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) override;
virtual bool Load(CKStateChunk* chunk, CKFileVisitor* file) override;
// Type
VxMath::VXLIGHT_TYPE GetType() const;
void SetType(VxMath::VXLIGHT_TYPE light_type);
const VxMath::VxColor& GetColor() const;
void SetColor(const VxMath::VxColor& c);
CKFLOAT GetConstantAttenuation() const;
CKFLOAT GetLinearAttenuation() const;
CKFLOAT GetQuadraticAttenuation() const;
void SetConstantAttenuation(CKFLOAT value);
void SetLinearAttenuation(CKFLOAT value);
void SetQuadraticAttenuation(CKFLOAT value);
// Range
CKFLOAT GetRange() const;
void SetRange(CKFLOAT value);
// Spotlight options
CKFLOAT GetHotSpot() const;
CKFLOAT GetFalloff() const;
CKFLOAT GetFalloffShape() const;
void SetHotSpot(CKFLOAT value);
void SetFalloff(CKFLOAT value);
void SetFalloffShape(CKFLOAT value);
// Activity options
bool GetActivity() const;
void Active(bool active);
bool GetSpecularFlag() const;
void SetSpecularFlag(bool specular);
// Target access
virtual CK3dEntity* GetTarget() const;
virtual void SetTarget(CK3dEntity* target);
CKFLOAT GetLightPower() const;
void SetLightPower(CKFLOAT power = 1.0f);
protected:
enum class LightFlags : CKDWORD {
None = 0,
Active = 0x100u, /**< if set, this light is active. */
Specular = 0x200u, /**< if set, this light has specular flag. */
};
CKLightData m_LightData;
// MARK: This variable is called in m_Flags in reverse code.
LightFlags m_LightFlags;
CKFLOAT m_LightPower;
};
}

2
LibCmo/CK2/ObjImpls/CKMaterial.hpp
View File

@ -12,7 +12,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKMaterial();
YYCC_DEL_CLS_COPY_MOVE(CKMaterial);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_MATERIAL;
}

92
LibCmo/CK2/ObjImpls/CKMesh.cpp
View File

@ -21,12 +21,12 @@ namespace LibCmo::CK2::ObjImpls {
m_LineCount(0),
m_LineIndices(),
// init flags
m_Flags(EnumsHelper::Merge({
m_Flags(YYCC::EnumHelper::Merge(
VxMath::VXMESH_FLAGS::VXMESH_VISIBLE,
VxMath::VXMESH_FLAGS::VXMESH_RENDERCHANNELS
})) {
)) {
// set visible in default
EnumsHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
YYCC::EnumHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
}
CKMesh::~CKMesh() {}
@ -145,7 +145,7 @@ namespace LibCmo::CK2::ObjImpls {
rawbuf += CKSizeof(CKDWORD);
// write vertex position
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::NoPos)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::NoPos)) {
CKDWORD consumed = CKSizeof(VxMath::VxVector3) * vtxCount;
std::memcpy(rawbuf, m_VertexPosition.data(), consumed);
rawbuf += consumed;
@ -154,7 +154,7 @@ namespace LibCmo::CK2::ObjImpls {
// write color and specular color
{
CKDWORD consumed = 0;
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::SingleColor)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::SingleColor)) {
consumed = CKSizeof(CKDWORD) * vtxCount;
} else {
consumed = CKSizeof(CKDWORD);
@ -165,7 +165,7 @@ namespace LibCmo::CK2::ObjImpls {
}
{
CKDWORD consumed = 0;
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::SingleSpecularColor)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::SingleSpecularColor)) {
consumed = CKSizeof(CKDWORD) * vtxCount;
} else {
consumed = CKSizeof(CKDWORD);
@ -176,7 +176,7 @@ namespace LibCmo::CK2::ObjImpls {
}
// write normal
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::NoNormal)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::NoNormal)) {
CKDWORD consumed = CKSizeof(VxMath::VxVector3) * vtxCount;
std::memcpy(rawbuf, m_VertexNormal.data(), consumed);
rawbuf += consumed;
@ -185,7 +185,7 @@ namespace LibCmo::CK2::ObjImpls {
// write uv
{
CKDWORD consumed = 0;
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::SingleUV)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::SingleUV)) {
consumed = CKSizeof(VxMath::VxVector2) * vtxCount;
} else {
consumed = CKSizeof(VxMath::VxVector2);
@ -229,13 +229,13 @@ namespace LibCmo::CK2::ObjImpls {
// read flag
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_MESH::CK_STATESAVE_MESHFLAGS)) {
chunk->ReadStruct(m_Flags);
EnumsHelper::Mask(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_ALLFLAGS);
YYCC::EnumHelper::Mask(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_ALLFLAGS);
// I don't know why, just interpter the IDA code.
EnumsHelper::Rm(m_Flags, EnumsHelper::Merge({
YYCC::EnumHelper::Remove(m_Flags,
VxMath::VXMESH_FLAGS::VXMESH_BOUNDINGUPTODATE,
VxMath::VXMESH_FLAGS::VXMESH_OPTIMIZED
}));
);
}
// read material slots
@ -285,14 +285,14 @@ namespace LibCmo::CK2::ObjImpls {
const CKBYTE* rawbuf = static_cast<const CKBYTE*>(buf.get());
// copy position if it have
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::NoPos)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::NoPos)) {
CKDWORD consumed = CKSizeof(VxMath::VxVector3) * vertexCount;
std::memcpy(m_VertexPosition.data(), rawbuf, consumed);
rawbuf += consumed;
}
// copy color or apply single color
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::SingleColor)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::SingleColor)) {
CKDWORD consumed = CKSizeof(CKDWORD) * vertexCount;
std::memcpy(m_VertexColor.data(), rawbuf, consumed);
rawbuf += consumed;
@ -309,7 +309,7 @@ namespace LibCmo::CK2::ObjImpls {
}
// copy specular color or apply a single color
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::SingleSpecularColor)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::SingleSpecularColor)) {
CKDWORD consumed = CKSizeof(CKDWORD) * vertexCount;
std::memcpy(m_VertexSpecularColor.data(), rawbuf, consumed);
rawbuf += consumed;
@ -326,14 +326,14 @@ namespace LibCmo::CK2::ObjImpls {
}
// copy normals if it has
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::NoNormal)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::NoNormal)) {
CKDWORD consumed = CKSizeof(VxMath::VxVector3) * vertexCount;
std::memcpy(m_VertexNormal.data(), rawbuf, consumed);
rawbuf += consumed;
}
// copy uv or apply single uv
if (!EnumsHelper::Has(saveflags, VertexSaveFlags::SingleUV)) {
if (!YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::SingleUV)) {
CKDWORD consumed = CKSizeof(VxMath::VxVector2) * vertexCount;
std::memcpy(m_VertexUV.data(), rawbuf, consumed);
rawbuf += consumed;
@ -407,7 +407,7 @@ namespace LibCmo::CK2::ObjImpls {
}
// build normals
if (EnumsHelper::Has(saveflags, VertexSaveFlags::NoNormal)) {
if (YYCC::EnumHelper::Has(saveflags, VertexSaveFlags::NoNormal)) {
BuildNormals();
} else {
BuildFaceNormals();
@ -425,9 +425,9 @@ namespace LibCmo::CK2::ObjImpls {
CKObject::Show(show);
if (show == CK_OBJECT_SHOWOPTION::CKSHOW) {
EnumsHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_VISIBLE);
YYCC::EnumHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_VISIBLE);
} else {
EnumsHelper::Rm(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_VISIBLE);
YYCC::EnumHelper::Remove(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_VISIBLE);
}
}
@ -449,15 +449,15 @@ namespace LibCmo::CK2::ObjImpls {
m_Flags = flags;
// sync visibility to CKObject layer.
if (EnumsHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_VISIBLE)) {
EnumsHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
if (YYCC::EnumHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_VISIBLE)) {
YYCC::EnumHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
} else {
EnumsHelper::Rm(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
YYCC::EnumHelper::Remove(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
}
}
VxMath::VXMESH_LITMODE CKMesh::GetLitMode() const {
if (EnumsHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PRELITMODE)) {
if (YYCC::EnumHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PRELITMODE)) {
return VxMath::VXMESH_LITMODE::VX_PRELITMESH;
} else {
return VxMath::VXMESH_LITMODE::VX_LITMESH;
@ -467,10 +467,10 @@ namespace LibCmo::CK2::ObjImpls {
void CKMesh::SetLitMode(VxMath::VXMESH_LITMODE mode) {
switch (mode) {
case VxMath::VXMESH_LITMODE::VX_PRELITMESH:
EnumsHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PRELITMODE);
YYCC::EnumHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PRELITMODE);
break;
case VxMath::VXMESH_LITMODE::VX_LITMESH:
EnumsHelper::Rm(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PRELITMODE);
YYCC::EnumHelper::Remove(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PRELITMODE);
break;
}
}
@ -478,51 +478,51 @@ namespace LibCmo::CK2::ObjImpls {
VxMath::VXTEXTURE_WRAPMODE CKMesh::GetWrapMode() const {
VxMath::VXTEXTURE_WRAPMODE ret = VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_NONE;
if (EnumsHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPU)) {
EnumsHelper::Add(ret, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_U);
if (YYCC::EnumHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPU)) {
YYCC::EnumHelper::Add(ret, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_U);
}
if (EnumsHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPV)) {
EnumsHelper::Add(ret, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_V);
if (YYCC::EnumHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPV)) {
YYCC::EnumHelper::Add(ret, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_V);
}
return ret;
}
void CKMesh::SetWrapMode(VxMath::VXTEXTURE_WRAPMODE mode) {
if (EnumsHelper::Has(mode, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_U)) {
EnumsHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPU);
if (YYCC::EnumHelper::Has(mode, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_U)) {
YYCC::EnumHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPU);
} else {
EnumsHelper::Rm(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPU);
YYCC::EnumHelper::Remove(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPU);
}
if (EnumsHelper::Has(mode, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_V)) {
EnumsHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPV);
if (YYCC::EnumHelper::Has(mode, VxMath::VXTEXTURE_WRAPMODE::VXTEXTUREWRAP_V)) {
YYCC::EnumHelper::Add(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPV);
} else {
EnumsHelper::Rm(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPV);
YYCC::EnumHelper::Remove(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_WRAPV);
}
}
CKMesh::VertexSaveFlags CKMesh::GenerateSaveFlags() {
// set to initial status
VertexSaveFlags saveflags = EnumsHelper::Merge({
VertexSaveFlags saveflags = YYCC::EnumHelper::Merge(
VertexSaveFlags::SingleColor,
VertexSaveFlags::SingleSpecularColor,
VertexSaveFlags::NoNormal,
VertexSaveFlags::SingleUV
});
);
// check no pos
// if position is generated, skip saving position
if (EnumsHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PROCEDURALPOS)) {
EnumsHelper::Add(saveflags, VertexSaveFlags::NoPos);
if (YYCC::EnumHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PROCEDURALPOS)) {
YYCC::EnumHelper::Add(saveflags, VertexSaveFlags::NoPos);
}
// check uv
// if uv is not generated and all uv are not the same value, remove single uv
if (!EnumsHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PROCEDURALUV)) {
if (!YYCC::EnumHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_PROCEDURALUV)) {
for (const auto& uv : m_VertexUV) {
if (uv != m_VertexUV.front()) {
EnumsHelper::Rm(saveflags, VertexSaveFlags::SingleUV);
YYCC::EnumHelper::Remove(saveflags, VertexSaveFlags::SingleUV);
break;
}
}
@ -532,19 +532,19 @@ namespace LibCmo::CK2::ObjImpls {
// if all color are not the same value, remove single color
for (const auto& col : m_VertexColor) {
if (col != m_VertexColor.front()) {
EnumsHelper::Rm(saveflags, VertexSaveFlags::SingleColor);
YYCC::EnumHelper::Remove(saveflags, VertexSaveFlags::SingleColor);
break;
}
}
for (const auto& col : m_VertexSpecularColor) {
if (col != m_VertexSpecularColor.front()) {
EnumsHelper::Rm(saveflags, VertexSaveFlags::SingleSpecularColor);
YYCC::EnumHelper::Remove(saveflags, VertexSaveFlags::SingleSpecularColor);
break;
}
}
// if normal not changed, and position is not generated, we should consider whether we need save normal (step into if)
if (!EnumsHelper::Has(m_Flags, EnumsHelper::Merge({ VxMath::VXMESH_FLAGS::VXMESH_NORMAL_CHANGED, VxMath::VXMESH_FLAGS::VXMESH_PROCEDURALPOS }))) {
if (!YYCC::EnumHelper::Has(m_Flags, VxMath::VXMESH_FLAGS::VXMESH_NORMAL_CHANGED, VxMath::VXMESH_FLAGS::VXMESH_PROCEDURALPOS)) {
// MARK: we should build face normal first
// then we build vertex normal like BuildNormals.
// then, we compare the difference between the generated normals and user specified normals, by simply using operator- (userNml - generatedNml) and abs the result.
@ -573,7 +573,7 @@ namespace LibCmo::CK2::ObjImpls {
// get diff by distance
VxMath::VxVector3 diff = m_VertexNormal[vid] - generated[vid];
// abs the diff and add into accumulated diff
VxMath::NSVxVector::Abs(diff);
VxMath::NSVxVector::Absolute(diff);
accnml += diff;
}
@ -581,7 +581,7 @@ namespace LibCmo::CK2::ObjImpls {
accnml /= static_cast<CKFLOAT>(m_VertexCount);
if (accnml.Length() > 0.001f) {
// too large difference, we need save normal
EnumsHelper::Rm(saveflags, VertexSaveFlags::NoNormal);
YYCC::EnumHelper::Remove(saveflags, VertexSaveFlags::NoNormal);
}
}

2
LibCmo/CK2/ObjImpls/CKMesh.hpp
View File

@ -21,7 +21,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKMesh();
YYCC_DEL_CLS_COPY_MOVE(CKMesh);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_MESH;
}

36
LibCmo/CK2/ObjImpls/CKObject.cpp
View File

@ -16,23 +16,23 @@ namespace LibCmo::CK2::ObjImpls {
#pragma region Non-virtual Functions
CK_ID CKObject::GetID(void) const {
CK_ID CKObject::GetID() const {
return m_ID;
}
CKSTRING CKObject::GetName(void) const {
CKSTRING CKObject::GetName() const {
return XContainer::NSXString::ToCKSTRING(m_Name);
}
void CKObject::SetName(CKSTRING u8_name) {
XContainer::NSXString::FromCKSTRING(m_Name, u8_name);
}
CK_OBJECT_FLAGS CKObject::GetObjectFlags(void) const {
CK_OBJECT_FLAGS CKObject::GetObjectFlags() const {
return m_ObjectFlags;
}
void CKObject::SetObjectFlags(CK_OBJECT_FLAGS flags) {
m_ObjectFlags = flags;
}
bool CKObject::IsToBeDeleted() const {
return EnumsHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_TOBEDELETED);
return YYCC::EnumHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_TOBEDELETED);
}
CKContext* CKObject::GetCKContext() const {
return m_Context;
@ -51,10 +51,10 @@ namespace LibCmo::CK2::ObjImpls {
void CKObject::PreSave(CKFileVisitor* file, CKDWORD flags) {}
bool CKObject::Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) {
if (EnumsHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE)) {
if (YYCC::EnumHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE)) {
// if hierarchy hidden
chunk->WriteIdentifier(CK_STATESAVEFLAGS_OBJECT::CK_STATESAVE_OBJECTHIERAHIDDEN);
} else if (!EnumsHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE)) {
} else if (!YYCC::EnumHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE)) {
// if really hidden
chunk->WriteIdentifier(CK_STATESAVEFLAGS_OBJECT::CK_STATESAVE_OBJECTHIDDEN);
}
@ -65,18 +65,20 @@ namespace LibCmo::CK2::ObjImpls {
bool CKObject::Load(CKStateChunk* chunk, CKFileVisitor* file) {
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_OBJECT::CK_STATESAVE_OBJECTHIDDEN)) {
EnumsHelper::Rm(this->m_ObjectFlags,
EnumsHelper::Merge({ CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE }));
YYCC::EnumHelper::Remove(this->m_ObjectFlags,
CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE,
CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE
);
} else {
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_OBJECT::CK_STATESAVE_OBJECTHIERAHIDDEN)) {
// != 0
EnumsHelper::Rm(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
EnumsHelper::Add(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE);
YYCC::EnumHelper::Remove(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
YYCC::EnumHelper::Add(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE);
} else {
// == 0
EnumsHelper::Add(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
EnumsHelper::Rm(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE);
YYCC::EnumHelper::Add(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
YYCC::EnumHelper::Remove(this->m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE);
}
}
@ -89,17 +91,17 @@ namespace LibCmo::CK2::ObjImpls {
void CKObject::Show(CK_OBJECT_SHOWOPTION show) {
// clear all visible data of object flags
EnumsHelper::Rm(m_ObjectFlags, EnumsHelper::Merge({
YYCC::EnumHelper::Remove(m_ObjectFlags,
CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE,
CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE
}));
);
switch (show) {
case CK_OBJECT_SHOWOPTION::CKSHOW:
EnumsHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
YYCC::EnumHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
break;
case CK_OBJECT_SHOWOPTION::CKHIERARCHICALHIDE:
EnumsHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE);
YYCC::EnumHelper::Add(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_HIERACHICALHIDE);
break;
case CK_OBJECT_SHOWOPTION::CKHIDE:
return;
@ -107,7 +109,7 @@ namespace LibCmo::CK2::ObjImpls {
}
bool CKObject::IsVisible() const {
return EnumsHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
return YYCC::EnumHelper::Has(m_ObjectFlags, CK_OBJECT_FLAGS::CK_OBJECT_VISIBLE);
}

8
LibCmo/CK2/ObjImpls/CKObject.hpp
View File

@ -42,15 +42,15 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKObject();
YYCC_DEL_CLS_COPY_MOVE(CKObject);
CK_ID GetID(void) const;
CKSTRING GetName(void) const;
CK_ID GetID() const;
CKSTRING GetName() const;
void SetName(CKSTRING u8_name);
CK_OBJECT_FLAGS GetObjectFlags(void) const;
CK_OBJECT_FLAGS GetObjectFlags() const;
void SetObjectFlags(CK_OBJECT_FLAGS flags);
bool IsToBeDeleted() const;
CKContext* GetCKContext() const;
virtual CK_CLASSID GetClassID(void) {
virtual CK_CLASSID GetClassID() {
return CK_CLASSID::CKCID_OBJECT;
}

2
LibCmo/CK2/ObjImpls/CKRenderObject.hpp
View File

@ -13,7 +13,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKRenderObject() {}
YYCC_DEL_CLS_COPY_MOVE(CKRenderObject);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_RENDEROBJECT;
}

2
LibCmo/CK2/ObjImpls/CKSceneObject.hpp
View File

@ -13,7 +13,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKSceneObject() {}
YYCC_DEL_CLS_COPY_MOVE(CKSceneObject);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_SCENEOBJECT;
}
// CKSceneObject do not override any RW functions.

91
LibCmo/CK2/ObjImpls/CKTargetCamera.cpp Normal file
View File

@ -0,0 +1,91 @@
#include "CKTargetCamera.hpp"
#include "../CKStateChunk.hpp"
#include "../CKContext.hpp"
namespace LibCmo::CK2::ObjImpls {
// MARK: THIS CODE IS BARELY FULL COPY OF CKTargetLight.
// Please sync them if you modify one of them!
CKTargetCamera::CKTargetCamera(CKContext* ctx, CK_ID ckid, CKSTRING name) :
CKCamera(ctx, ckid, name), m_Target3dEntity(0) {}
CKTargetCamera::~CKTargetCamera() {}
void CKTargetCamera::PreDelete() {
// Remove associated target
SetTarget(nullptr);
}
void CKTargetCamera::CheckPostDeletion() {
CKCamera::CheckPostDeletion();
// Remove target if is not existing.
CKObject* target = m_Context->GetObject(m_Target3dEntity);
if (target == nullptr) {
m_Target3dEntity = 0;
}
}
bool CKTargetCamera::Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) {
bool suc = CKCamera::Save(chunk, file, flags);
if (!suc) return false;
// Save target
{
chunk->WriteIdentifier(CK_STATESAVEFLAGS_CAMERA::CK_STATESAVE_TCAMERATARGET);
CKObject* target = m_Context->GetObject(m_Target3dEntity);
chunk->WriteObjectPointer(target);
}
chunk->SetClassId(CK_CLASSID::CKCID_TARGETCAMERA);
return true;
}
bool CKTargetCamera::Load(CKStateChunk* chunk, CKFileVisitor* file) {
bool suc = CKCamera::Load(chunk, file);
if (!suc) return false;
// Read target
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_CAMERA::CK_STATESAVE_TCAMERATARGET)) {
chunk->ReadObjectID(m_Target3dEntity);
}
return true;
}
CK3dEntity* CKTargetCamera::GetTarget() const {
return static_cast<CK3dEntity*>(m_Context->GetObject(m_Target3dEntity));
}
void CKTargetCamera::SetTarget(CK3dEntity* target) {
// The target can not be self.
if (target == this) return;
// First remove current target
CK3dEntity* old_target = static_cast<CK3dEntity*>(m_Context->GetObject(m_Target3dEntity));
if (old_target != nullptr) {
CK_3DENTITY_FLAGS old_target_flags = old_target->GetEntityFlags();
YYCC::EnumHelper::Remove(old_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_TARGETCAMERA);
YYCC::EnumHelper::Add(old_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_FRAME);
old_target->SetEntityFlags(old_target_flags);
}
// Then add specified target
if (target != nullptr) {
CK_3DENTITY_FLAGS new_target_flags = target->GetEntityFlags();
YYCC::EnumHelper::Add(new_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_TARGETCAMERA);
YYCC::EnumHelper::Remove(new_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_FRAME);
target->SetEntityFlags(new_target_flags);
}
// Get CK_ID of new target
CK_ID target_id = 0;
if (target != nullptr)
target_id = target->GetID();
// Assign target id.
m_Target3dEntity = target_id;
}
}

33
LibCmo/CK2/ObjImpls/CKTargetCamera.hpp Normal file
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@ -0,0 +1,33 @@
#pragma once
#include "../../VTInternal.hpp"
#include "CKCamera.hpp"
namespace LibCmo::CK2::ObjImpls {
class CKTargetCamera : public CKCamera {
public:
CKTargetCamera(CKContext* ctx, CK_ID ckid, CKSTRING name);
virtual ~CKTargetCamera();
YYCC_DEL_CLS_COPY_MOVE(CKTargetCamera);
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_TARGETCAMERA;
}
virtual void PreDelete() override;
virtual void CheckPostDeletion() override;
// 2 RW funcions
virtual bool Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) override;
virtual bool Load(CKStateChunk* chunk, CKFileVisitor* file) override;
virtual CK3dEntity* GetTarget() const override;
virtual void SetTarget(CK3dEntity* target) override;
protected:
CK_ID m_Target3dEntity;
};
}

95
LibCmo/CK2/ObjImpls/CKTargetLight.cpp Normal file
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@ -0,0 +1,95 @@
#include "CKTargetLight.hpp"
#include "../CKStateChunk.hpp"
#include "../CKContext.hpp"
namespace LibCmo::CK2::ObjImpls {
// MARK: THIS CODE IS BARELY FULL COPY OF CKTargetCamera.
// Please sync them if you modify one of them!
CKTargetLight::CKTargetLight(CKContext* ctx, CK_ID ckid, CKSTRING name) :
CKLight(ctx, ckid, name), m_Target3dEntity(0) {}
CKTargetLight::~CKTargetLight() {}
void CKTargetLight::PreDelete() {
// MARK: In original code, there is no such override.
// Following statement is written in a function called "vector deleting destructor".
// Idk what it is. There is no resetting target code in its dtor and elsewhere.
// I think this is crucial, so I add this overload as my understandings.
// Remove associated target
SetTarget(nullptr);
}
void CKTargetLight::CheckPostDeletion() {
CKLight::CheckPostDeletion();
// Remove target if is not existing.
CKObject* target = m_Context->GetObject(m_Target3dEntity);
if (target == nullptr) {
m_Target3dEntity = 0;
}
}
bool CKTargetLight::Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) {
bool suc = CKLight::Save(chunk, file, flags);
if (!suc) return false;
// Save target
{
chunk->WriteIdentifier(CK_STATESAVEFLAGS_LIGHT::CK_STATESAVE_TLIGHTTARGET);
CKObject* target = m_Context->GetObject(m_Target3dEntity);
chunk->WriteObjectPointer(target);
}
chunk->SetClassId(CK_CLASSID::CKCID_TARGETLIGHT);
return true;
}
bool CKTargetLight::Load(CKStateChunk* chunk, CKFileVisitor* file) {
bool suc = CKLight::Load(chunk, file);
if (!suc) return false;
// Read target
if (chunk->SeekIdentifier(CK_STATESAVEFLAGS_LIGHT::CK_STATESAVE_TLIGHTTARGET)) {
chunk->ReadObjectID(m_Target3dEntity);
}
return true;
}
CK3dEntity* CKTargetLight::GetTarget() const {
return static_cast<CK3dEntity*>(m_Context->GetObject(m_Target3dEntity));
}
void CKTargetLight::SetTarget(CK3dEntity* target) {
// The target can not be self.
if (target == this) return;
// First remove current target
CK3dEntity* old_target = static_cast<CK3dEntity*>(m_Context->GetObject(m_Target3dEntity));
if (old_target != nullptr) {
CK_3DENTITY_FLAGS old_target_flags = old_target->GetEntityFlags();
YYCC::EnumHelper::Remove(old_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_TARGETLIGHT);
YYCC::EnumHelper::Add(old_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_FRAME);
old_target->SetEntityFlags(old_target_flags);
}
// Then add specified target
if (target != nullptr) {
CK_3DENTITY_FLAGS new_target_flags = target->GetEntityFlags();
YYCC::EnumHelper::Add(new_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_TARGETLIGHT);
YYCC::EnumHelper::Remove(new_target_flags, CK_3DENTITY_FLAGS::CK_3DENTITY_FRAME);
target->SetEntityFlags(new_target_flags);
}
// Get CK_ID of new target
CK_ID target_id = 0;
if (target != nullptr)
target_id = target->GetID();
// Assign target id.
m_Target3dEntity = target_id;
}
}

33
LibCmo/CK2/ObjImpls/CKTargetLight.hpp Normal file
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@ -0,0 +1,33 @@
#pragma once
#include "../../VTInternal.hpp"
#include "CKLight.hpp"
namespace LibCmo::CK2::ObjImpls {
class CKTargetLight : public CKLight {
public:
CKTargetLight(CKContext* ctx, CK_ID ckid, CKSTRING name);
virtual ~CKTargetLight();
YYCC_DEL_CLS_COPY_MOVE(CKTargetLight);
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_TARGETLIGHT;
}
virtual void PreDelete() override;
virtual void CheckPostDeletion() override;
// 2 RW funcions
virtual bool Save(CKStateChunk* chunk, CKFileVisitor* file, CKDWORD flags) override;
virtual bool Load(CKStateChunk* chunk, CKFileVisitor* file) override;
virtual CK3dEntity* GetTarget() const override;
virtual void SetTarget(CK3dEntity* target) override;
protected:
CK_ID m_Target3dEntity;
};
}

2
LibCmo/CK2/ObjImpls/CKTexture.hpp
View File

@ -12,7 +12,7 @@ namespace LibCmo::CK2::ObjImpls {
virtual ~CKTexture();
YYCC_DEL_CLS_COPY_MOVE(CKTexture);
virtual CK_CLASSID GetClassID(void) override {
virtual CK_CLASSID GetClassID() override {
return CK_CLASSID::CKCID_TEXTURE;
}

25
LibCmo/CMakeLists.txt
View File

@ -1,3 +1,10 @@
# Configure version file
configure_file(
${CMAKE_CURRENT_LIST_DIR}/../CMake/VTVersion.hpp.in
${CMAKE_CURRENT_LIST_DIR}/VTVersion.hpp
@ONLY
)
# Create static library
add_library(LibCmo STATIC "")
# Setup static library sources
@ -30,8 +37,13 @@ PRIVATE
CK2/ObjImpls/CKMesh.cpp
CK2/ObjImpls/CKObject.cpp
CK2/ObjImpls/CKTexture.cpp
CK2/ObjImpls/CKLight.cpp
CK2/ObjImpls/CKTargetLight.cpp
CK2/ObjImpls/CKCamera.cpp
CK2/ObjImpls/CKTargetCamera.cpp
# VxMath
VxMath/VxMemoryMappedFile.cpp
VxMath/VxTypes.cpp
VxMath/VxMath.cpp
# X Container
XContainer/XTypes.cpp
@ -42,6 +54,7 @@ PUBLIC
FILE_SET HEADERS
FILES
# Asststant header files
VTVersion.hpp
VTInternal.hpp
VTEncoding.hpp
VTUtils.hpp
@ -73,6 +86,10 @@ FILES
CK2/ObjImpls/CK3dObject.hpp
CK2/ObjImpls/CKRenderObject.hpp
CK2/ObjImpls/CKSceneObject.hpp
CK2/ObjImpls/CKLight.hpp
CK2/ObjImpls/CKTargetLight.hpp
CK2/ObjImpls/CKCamera.hpp
CK2/ObjImpls/CKTargetCamera.hpp
# VxMath
VxMath/VxTypes.hpp
VxMath/VxMath.hpp
@ -86,19 +103,15 @@ target_include_directories(LibCmo
PUBLIC
"$<BUILD_INTERFACE:${CMAKE_CURRENT_LIST_DIR}>"
"$<INSTALL_INTERFACE:${CMAKE_INSTALL_INCLUDEDIR}>"
PRIVATE
YYCC::YYCCommonplace
ZLIB::ZLIB
stb::stb-image
)
target_link_libraries(LibCmo
PRIVATE
PUBLIC
YYCC::YYCCommonplace
PRIVATE
ZLIB::ZLIB
stb::stb-image
)
if (NOT WIN32)
target_include_directories(LibCmo PRIVATE Iconv::Iconv)
target_link_libraries(LibCmo PRIVATE Iconv::Iconv)
endif ()
# Setup C++ standard

4
LibCmo/VTAll.hpp
View File

@ -34,6 +34,10 @@
#include "CK2/ObjImpls/CKTexture.hpp"
#include "CK2/ObjImpls/CKMaterial.hpp"
#include "CK2/ObjImpls/CKMesh.hpp"
#include "CK2/ObjImpls/CKLight.hpp"
#include "CK2/ObjImpls/CKTargetLight.hpp"
#include "CK2/ObjImpls/CKCamera.hpp"
#include "CK2/ObjImpls/CKTargetCamera.hpp"
// CK2 Managers
#include "CK2/MgrImpls/CKBaseManager.hpp"

4
LibCmo/VTEncoding.cpp
View File

@ -2,10 +2,10 @@
#include <map>
#if YYCC_OS == YYCC_OS_WINDOWS
#include <WinImportPrefix.hpp>
#include <YYCC/WinImportPrefix.hpp>
#include <Windows.h>
#include <fileapi.h>
#include <WinImportSuffix.hpp>
#include <YYCC/WinImportSuffix.hpp>
#else
#include <iconv.h>
#endif

2
LibCmo/VTEncoding.hpp
View File

@ -36,7 +36,7 @@ namespace LibCmo::EncodingHelper {
* In underlying implementation, it actually is \c nullptr.
* Because EncodingToken is just a raw pointer.
*/
constexpr EncodingToken INVALID_ENCODING_TOKEN = nullptr;
inline constexpr EncodingToken INVALID_ENCODING_TOKEN = nullptr;
/**
* @brief Create encoding token by given universal encoding name.

2
LibCmo/VTImage.cpp
View File

@ -10,4 +10,4 @@
#define STB_IMAGE_WRITE_IMPLEMENTATION
#include <stb_image_write.h>
#define STB_IMAGE_RESIZE_IMPLEMENTATION
#include <stb_image_resize.h>
#include <deprecated/stb_image_resize.h>

8
LibCmo/VTInternal.hpp
View File

@ -4,9 +4,9 @@
* \file
* The top header file for LibCom self development.
* Every C++ header or source file located in this project should include this first
* except the headers including this file.
* except the headers included in this file.
* The header files included by this header should be carefully managed,
* to make sure there are no include loop and each header files can works correctly.
* to make sure there are no include loop and each header files can work correctly.
*
* This header should only be used as internal header file.
* It only contains all necessary stuff used by this project self.
@ -17,9 +17,11 @@
* So they will use native type, not CK type for declaration and implementation.
* Take VTEncoding.hpp for example, All string used in it is \c std::u8string, not LibCmo::XContainer::XString.
* The file starts with \c CK, \c Vx, and \c X is a part of Virtools SDK.
* They should use Virtools type anywhere, except that Virtools type can not fulfill their requirement.
* They should use Virtools type anywhere, except that Virtools type can not fulfill their requirements.
*/
// The version info header of LibCmo
#include "VTVersion.hpp"
// The base header of LibCmo.
// It provides various convenient stuff, for example:
// - General LibCmo specific custom exception.

94
LibCmo/VTUtils.hpp
View File

@ -5,13 +5,14 @@
#error "You must define ONE of LIBCMO_BUILD_DEBUG and LIBCMO_BUILD_RELEASE to indicate build type!"
#endif
// Include YYCC helper library
// Include YYCC helper library and check its version
#include <YYCCommonplace.hpp>
#if YYCC_VERCMP_NE(YYCC_VER_MAJOR, YYCC_VER_MINOR, YYCC_VER_PATCH, 1, 3, 0)
#error "YYCC library version is not matched with our expected version. Please check your library configuration."
#endif
// Header for this namespace implementation
#include <string>
#include <type_traits>
#include <initializer_list>
/**
* @brief The core namespace of LibCmo project.
@ -69,91 +70,4 @@ namespace LibCmo {
#pragma endregion
/**
* @brief The namespace for convenient C++ enum class logic operations.
* @details
* C++ enum class statement is a modern way to declare enum in C++.
* But it lack essential logic operations which is commonly used by programmer.
* So we create this helper to resolve this issue.
*/
namespace EnumsHelper {
/**
* @brief Merge given enum flags like performing <TT>e1 | e2 | ... | en</TT>
* @tparam TEnum Enum type for processing.
* @param[in] il The list of enum flags to be merged.
* @return The merged enum flag.
*/
template<typename TEnum, std::enable_if_t<std::is_enum_v<TEnum>, int> = 0>
constexpr TEnum Merge(std::initializer_list<TEnum> il) {
using ut = std::underlying_type_t<TEnum>;
ut result = 0;
for (auto it = il.begin(); it != il.end(); ++it) {
result |= static_cast<ut>(*it);
}
return static_cast<TEnum>(result);
}
/**
* @brief Reverse given enum flags like performing <TT>~(e)</TT>
* @tparam TEnum Enum type for processing.
* @param[in] e The list of enum flags to be inversed.
* @return The inversed enum flag.
*/
template<typename TEnum, std::enable_if_t<std::is_enum_v<TEnum>, int> = 0>
constexpr TEnum Inv(TEnum e) {
using ut = std::underlying_type_t<TEnum>;
return static_cast<TEnum>(~(static_cast<ut>(e)));
}
/**
* @brief Remove specified enum flags from given enum flags like performing <TT>e1 &= (~e2)</TT>
* @tparam TEnum Enum type for processing.
* @param[in,out] e1 The enum flags to be processed.
* @param[in] e2 The enum flag to be removed.
*/
template<typename TEnum, std::enable_if_t<std::is_enum_v<TEnum>, int> = 0>
constexpr void Rm(TEnum& e1, TEnum e2) {
using ut = std::underlying_type_t<TEnum>;
e1 = static_cast<TEnum>(static_cast<ut>(e1) & static_cast<ut>(Inv(e2)));
}
/**
* @brief Use specified enum flags to mask given enum flags like performing <TT>e1 &= e2</TT>
* @tparam TEnum Enum type for processing.
* @param[in,out] e1 The enum flags to be masked.
* @param[in] e2 The mask enum flag.
*/
template<typename TEnum, std::enable_if_t<std::is_enum_v<TEnum>, int> = 0>
constexpr void Mask(TEnum& e1, TEnum e2) {
using ut = std::underlying_type_t<TEnum>;
e1 = static_cast<TEnum>(static_cast<ut>(e1) & static_cast<ut>(e2));
}
/**
* @brief Add specified enum flags to given enum flags like performing <TT>e1 |= e2</TT>
* @tparam TEnum Enum type for processing.
* @param[in,out] e1 The enum flags to be processed.
* @param[in] e2 The enum flag to be added.
*/
template<typename TEnum, std::enable_if_t<std::is_enum_v<TEnum>, int> = 0>
constexpr void Add(TEnum& e1, TEnum e2) {
using ut = std::underlying_type_t<TEnum>;
e1 = static_cast<TEnum>(static_cast<ut>(e1) | static_cast<ut>(e2));
}
/**
* @brief Check whether given enum flags has specified enum flag like performing <TT>bool(e & probe)</TT>
* @tparam TEnum Enum type for processing.
* @param[in] e1 The enum flags to be checked.
* @param[in] e2 The enum flag for checking.
* @return True if it has, otherwise false.
*/
template<typename TEnum, std::enable_if_t<std::is_enum_v<TEnum>, int> = 0>
constexpr bool Has(TEnum e1, TEnum e2) {
using ut = std::underlying_type_t<TEnum>;
return static_cast<bool>(static_cast<ut>(e1) & static_cast<ut>(e2));
}
}
}

15
LibCmo/VxMath/VxEnums.hpp
View File

@ -45,6 +45,21 @@ namespace LibCmo::VxMath {
_4_ARGB8888_CLUT = 31, /**< 4 bits indexed CLUT (ARGB) */
};
/**
{filename:VXLIGHT_TYPE}
Summary: Light type.
Remarks:
+ Used by CKLight::SetType to specify the type of a light.
See also: CKLight::SetType,CKLight::GetType
*/
enum class VXLIGHT_TYPE : CKDWORD {
VX_LIGHTPOINT = 1UL, /**< The Light is a point of light */
VX_LIGHTSPOT = 2UL, /**< The light is a spotlight */
VX_LIGHTDIREC = 3UL, /**< The light is directional light : Lights comes from an infinite point so only direction of light can be given */
VX_LIGHTPARA = 4UL, /**< Obsolete, do not use */
};
/**
Summary: Blend Mode Flags
Remarks:

37
LibCmo/VxMath/VxMath.cpp
View File

@ -1,6 +1,6 @@
#include "VxMath.hpp"
#include <cmath>
#include <stb_image_resize.h>
#include <deprecated/stb_image_resize.h>
namespace LibCmo::VxMath {
@ -134,39 +134,4 @@ namespace LibCmo::VxMath {
#pragma endregion
#pragma region Patched
namespace NSVxVector {
float DotProduct(const VxVector2& lhs, const VxVector2& rhs) {
return lhs * rhs;
}
float DotProduct(const VxVector3& lhs, const VxVector3& rhs) {
return lhs * rhs;
}
float DotProduct(const VxVector4& lhs, const VxVector4& rhs) {
return lhs * rhs;
}
VxVector3 CrossProduct(const VxVector3& lhs, const VxVector3& rhs) {
return VxVector3(
lhs.y * rhs.z - lhs.z * rhs.y,
lhs.z * rhs.x - lhs.x * rhs.z,
lhs.x * rhs.y - lhs.y * rhs.x
);
}
void Abs(VxVector3& lhs) {
lhs.x = std::fabs(lhs.x);
lhs.y = std::fabs(lhs.y);
lhs.z = std::fabs(lhs.z);
}
}
#pragma endregion
}

51
LibCmo/VxMath/VxMath.hpp
View File

@ -95,56 +95,5 @@ namespace LibCmo::VxMath {
*/
void VxDoAlphaBlit(VxImageDescEx* dst_desc, const CKBYTE* AlphaValues);
// ========== Patch Section ==========
/**
* @brief The patch namespace for VxVector-like classes
* @details This namespace provides VxVector-like classes member functions which presented in original Virtools SDK.
* These functions are put in public namespace in original Virtools SDK.
* We just organise them into an unique namespace.
*/
namespace NSVxVector {
/**
* @brief Dot product 2 2d vectors.
* @param[in] lhs The left side vector of dot product symbol.
* @param[in] rhs The right side vector of dot product symbol.
* @return The float pointing result of dot product.
*/
CKFLOAT DotProduct(const VxVector2& lhs, const VxVector2& rhs);
/**
* @brief Dot product 2 3d vectors.
* @param[in] lhs The left side vector of dot product symbol.
* @param[in] rhs The right side vector of dot product symbol.
* @return The float pointing result of dot product.
*/
CKFLOAT DotProduct(const VxVector3& lhs, const VxVector3& rhs);
/**
* @brief Dot product 2 4d vectors.
* @param[in] lhs The left side vector of dot product symbol.
* @param[in] rhs The right side vector of dot product symbol.
* @return The float pointing result of dot product.
*/
CKFLOAT DotProduct(const VxVector4& lhs, const VxVector4& rhs);
/**
* @brief Cross product 2 3d vectors.
* @param[in] lhs The left side vector of cross product symbol.
* @param[in] rhs The right side vector of cross product symbol.
* @return The 3d vector result of cross product.
*/
VxVector3 CrossProduct(const VxVector3& lhs, const VxVector3& rhs);
/**
* @brief Set all factor in vector to its absolute value.
* @param[in,out] lhs The vector for processing.
* @remarks This function is rarely used.
* Please note this function is not calculate the absolute value of vector.
*/
void Abs(VxVector3& lhs);
}
}

2
LibCmo/VxMath/VxMemoryMappedFile.cpp
View File

@ -128,7 +128,7 @@ namespace LibCmo::VxMath {
this->m_bIsValid = true;
}
VxMemoryMappedFile::~VxMemoryMappedFile(void) {
VxMemoryMappedFile::~VxMemoryMappedFile() {
if (this->m_bIsValid) {
// only success mapping need free
this->m_bIsValid = false;

4
LibCmo/VxMath/VxMemoryMappedFile.hpp
View File

@ -2,9 +2,9 @@
#include "../VTInternal.hpp"
#if YYCC_OS == YYCC_OS_WINDOWS
#include <WinImportPrefix.hpp>
#include <YYCC/WinImportPrefix.hpp>
#include <Windows.h>
#include <WinImportSuffix.hpp>
#include <YYCC/WinImportSuffix.hpp>
#else
#include <sys/mman.h>
#include <sys/stat.h>

529
LibCmo/VxMath/VxTypes.cpp Normal file
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@ -0,0 +1,529 @@
#include "VxTypes.hpp"
#include <cmath>
namespace LibCmo::VxMath {
#pragma region VxVector2
VxVector2::VxVector2() :x(0.0f), y(0.0f) {}
VxVector2::VxVector2(CKFLOAT _x, CKFLOAT _y) : x(_x), y(_y) {}
CKFLOAT& VxVector2::operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
default: throw LogicException("Invalid index for VxVector2::operator[].");
}
}
const CKFLOAT& VxVector2::operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
default: throw LogicException("Invalid index for VxVector2::operator[].");
}
}
bool VxVector2::operator==(const VxVector2& rhs) const {
return (x == rhs.x && y == rhs.y);
}
auto VxVector2::operator<=>(const VxVector2& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
return y <=> rhs.y;
}
VxVector2 VxVector2::operator+() const {
return *this;
}
VxVector2 VxVector2::operator-() const {
return VxVector2(-x, -y);
}
VxVector2& VxVector2::operator+=(const VxVector2& rhs) {
x += rhs.x;
y += rhs.y;
return *this;
}
VxVector2 operator+(const VxVector2& lhs, const VxVector2& rhs) {
return VxVector2(lhs.x + rhs.x, lhs.y + rhs.y);
}
VxVector2& VxVector2::operator-=(const VxVector2& rhs) {
x -= rhs.x;
y -= rhs.y;
return *this;
}
VxVector2 operator-(const VxVector2& lhs, const VxVector2& rhs) {
return VxVector2(lhs.x - rhs.x, lhs.y - rhs.y);
}
VxVector2& VxVector2::operator*=(CKFLOAT rhs) {
x *= rhs;
y *= rhs;
return *this;
}
VxVector2 operator*(const VxVector2& lhs, CKFLOAT rhs) {
return VxVector2(lhs.x * rhs, lhs.y * rhs);
}
VxVector2 operator*(CKFLOAT lhs, const VxVector2& rhs) {
return VxVector2(lhs * rhs.x, lhs * rhs.y);
}
CKFLOAT operator*(const VxVector2& lhs, const VxVector2& rhs) {
return (lhs.x * rhs.x + lhs.y * rhs.y);
}
VxVector2& VxVector2::operator/=(CKFLOAT rhs) {
if (rhs == 0.0f) return *this;
x /= rhs;
y /= rhs;
return *this;
}
VxVector2 operator/(const VxVector2& lhs, CKFLOAT rhs) {
if (rhs == 0.0f) return VxVector2();
else return VxVector2(lhs.x / rhs, lhs.y / rhs);
}
CKFLOAT VxVector2::SquaredLength() const {
return (x * x + y * y);
}
CKFLOAT VxVector2::Length() const {
return std::sqrt(SquaredLength());
}
void VxVector2::Normalized() {
CKFLOAT len = Length();
if (len == 0.0f) return;
x /= len;
y /= len;
}
VxVector2 VxVector2::Normalize() const {
CKFLOAT len = Length();
if (len == 0.0f) return VxVector2();
else return VxVector2(x / len, y / len);
}
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
#pragma endregion
#pragma region VxVector3
VxVector3::VxVector3() :x(0.0f), y(0.0f), z(0.0f) {}
VxVector3::VxVector3(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z) : x(_x), y(_y), z(_z) {}
CKFLOAT& VxVector3::operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
default: throw LogicException("Invalid index for VxVector3::operator[].");
}
}
const CKFLOAT& VxVector3::operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
default: throw LogicException("Invalid index for VxVector3::operator[].");
}
}
bool VxVector3::operator==(const VxVector3& rhs) const {
return (x == rhs.x && y == rhs.y && z == rhs.z);
}
auto VxVector3::operator<=>(const VxVector3& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
if (auto cmp = y <=> rhs.y; cmp != 0) return cmp;
return z <=> rhs.z;
}
VxVector3 VxVector3::operator+() const {
return *this;
}
VxVector3 VxVector3::operator-() const {
return VxVector3(-x, -y, -z);
}
VxVector3& VxVector3::operator+=(const VxVector3& rhs) {
x += rhs.x;
y += rhs.y;
z += rhs.z;
return *this;
}
VxVector3 operator+(const VxVector3& lhs, const VxVector3& rhs) {
return VxVector3(lhs.x + rhs.x, lhs.y + rhs.y, lhs.z + rhs.z);
}
VxVector3& VxVector3::operator-=(const VxVector3& rhs) {
x -= rhs.x;
y -= rhs.y;
z -= rhs.z;
return *this;
}
VxVector3 operator-(const VxVector3& lhs, const VxVector3& rhs) {
return VxVector3(lhs.x - rhs.x, lhs.y - rhs.y, lhs.z - rhs.z);
}
VxVector3& VxVector3::operator*=(CKFLOAT rhs) {
x *= rhs;
y *= rhs;
z *= rhs;
return *this;
}
VxVector3 operator*(const VxVector3& lhs, CKFLOAT rhs) {
return VxVector3(lhs.x * rhs, lhs.y * rhs, lhs.z * rhs);
}
VxVector3 operator*(CKFLOAT lhs, const VxVector3& rhs) {
return VxVector3(lhs * rhs.x, lhs * rhs.y, lhs * rhs.z);
}
CKFLOAT operator*(const VxVector3& lhs, const VxVector3& rhs) {
return (lhs.x * rhs.x + lhs.y * rhs.y + lhs.z * rhs.z);
}
VxVector3& VxVector3::operator/=(CKFLOAT rhs) {
if (rhs == 0.0f) return *this;
x /= rhs;
y /= rhs;
z /= rhs;
return *this;
}
VxVector3 operator/(const VxVector3& lhs, CKFLOAT rhs) {
if (rhs == 0.0f) return VxVector3();
else return VxVector3(lhs.x / rhs, lhs.y / rhs, lhs.z / rhs);
}
CKFLOAT VxVector3::SquaredLength() const {
return (x * x + y * y + z * z);
}
CKFLOAT VxVector3::Length() const {
return std::sqrt(SquaredLength());
}
void VxVector3::Normalized() {
CKFLOAT len = Length();
if (len == 0.0f) return;
x /= len;
y /= len;
z /= len;
}
VxVector3 VxVector3::Normalize() const {
CKFLOAT len = Length();
if (len == 0.0f) return VxVector3();
else return VxVector3(x / len, y / len, z / len);
}
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
#pragma endregion
#pragma region VxVector4
VxVector4::VxVector4() :x(0.0f), y(0.0f), z(0.0f), w(0.0f) {}
VxVector4::VxVector4(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z, CKFLOAT _w) : x(_x), y(_y), z(_z), w(_w) {}
CKFLOAT& VxVector4::operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxVector4::operator[].");
}
}
const CKFLOAT& VxVector4::operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxVector4::operator[].");
}
}
bool VxVector4::operator==(const VxVector4& rhs) const {
return (x == rhs.x && y == rhs.y && z == rhs.z && w == rhs.w);
}
auto VxVector4::operator<=>(const VxVector4& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
if (auto cmp = y <=> rhs.y; cmp != 0) return cmp;
if (auto cmp = z <=> rhs.z; cmp != 0) return cmp;
return w <=> rhs.w;
}
VxVector4 VxVector4::operator+() const {
return *this;
}
VxVector4 VxVector4::operator-() const {
return VxVector4(-x, -y, -z, -w);
}
VxVector4& VxVector4::operator+=(const VxVector4& rhs) {
x += rhs.x;
y += rhs.y;
z += rhs.z;
w += rhs.w;
return *this;
}
VxVector4 operator+(const VxVector4& lhs, const VxVector4& rhs) {
return VxVector4(lhs.x + rhs.x, lhs.y + rhs.y, lhs.z + rhs.z, lhs.w + rhs.w);
}
VxVector4& VxVector4::operator-=(const VxVector4& rhs) {
x -= rhs.x;
y -= rhs.y;
z -= rhs.z;
w -= rhs.w;
return *this;
}
VxVector4 operator-(const VxVector4& lhs, const VxVector4& rhs) {
return VxVector4(lhs.x - rhs.x, lhs.y - rhs.y, lhs.z - rhs.z, lhs.w - rhs.w);
}
VxVector4& VxVector4::operator*=(CKFLOAT rhs) {
x *= rhs;
y *= rhs;
z *= rhs;
w *= rhs;
return *this;
}
VxVector4 operator*(const VxVector4& lhs, CKFLOAT rhs) {
return VxVector4(lhs.x * rhs, lhs.y * rhs, lhs.z * rhs, lhs.w * rhs);
}
VxVector4 operator*(CKFLOAT lhs, const VxVector4& rhs) {
return VxVector4(lhs * rhs.x, lhs * rhs.y, lhs * rhs.z, lhs * rhs.w);
}
CKFLOAT operator*(const VxVector4& lhs, const VxVector4& rhs) {
return (lhs.x * rhs.x + lhs.y * rhs.y + lhs.z * rhs.z + lhs.w * rhs.w);
}
VxVector4& VxVector4::operator/=(CKFLOAT rhs) {
if (rhs == 0.0f) return *this;
x /= rhs;
y /= rhs;
z /= rhs;
w /= rhs;
return *this;
}
VxVector4 operator/(const VxVector4& lhs, CKFLOAT rhs) {
if (rhs == 0.0f) return VxVector4();
else return VxVector4(lhs.x / rhs, lhs.y / rhs, lhs.z / rhs, lhs.w / rhs);
}
CKFLOAT VxVector4::SquaredLength() const {
return (x * x + y * y + z * z + w * w);
}
CKFLOAT VxVector4::Length() const {
return std::sqrt(SquaredLength());
}
void VxVector4::Normalized() {
CKFLOAT len = Length();
if (len == 0.0f) return;
x /= len;
y /= len;
z /= len;
w /= len;
}
VxVector4 VxVector4::Normalize() const {
CKFLOAT len = Length();
if (len == 0.0f) return VxVector4();
else return VxVector4(x / len, y / len, z / len, w / len);
}
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
#pragma endregion
#pragma region VxQuaternion
VxQuaternion::VxQuaternion() :x(0.0f), y(0.0f), z(0.0f), w(1.0f) {} // SET YOUR CUSTOM INIT
VxQuaternion::VxQuaternion(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z, CKFLOAT _w) : x(_x), y(_y), z(_z), w(_w) {}
CKFLOAT& VxQuaternion::operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxQuaternion::operator[].");
}
}
const CKFLOAT& VxQuaternion::operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxQuaternion::operator[].");
}
}
bool VxQuaternion::operator==(const VxQuaternion& rhs) const {
return (x == rhs.x && y == rhs.y && z == rhs.z && w == rhs.w);
}
auto VxQuaternion::operator<=>(const VxQuaternion& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
if (auto cmp = y <=> rhs.y; cmp != 0) return cmp;
if (auto cmp = z <=> rhs.z; cmp != 0) return cmp;
return w <=> rhs.w;
}
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
#pragma endregion
#pragma region VxColor
VxColor::VxColor() :r(0.0f), g(0.0f), b(0.0f), a(1.0f) {} // SET YOUR CUSTOM INIT
VxColor::VxColor(CKFLOAT _r, CKFLOAT _g, CKFLOAT _b, CKFLOAT _a) : r(_r), g(_g), b(_b), a(_a) {}
CKFLOAT& VxColor::operator[](size_t i) {
switch (i) {
case 0: return r;
case 1: return g;
case 2: return b;
case 3: return a;
default: throw LogicException("Invalid index for VxColor::operator[].");
}
}
const CKFLOAT& VxColor::operator[](size_t i) const {
switch (i) {
case 0: return r;
case 1: return g;
case 2: return b;
case 3: return a;
default: throw LogicException("Invalid index for VxColor::operator[].");
}
}
bool VxColor::operator==(const VxColor& rhs) const {
return (r == rhs.r && g == rhs.g && b == rhs.b && a == rhs.a);
}
auto VxColor::operator<=>(const VxColor& rhs) const {
if (auto cmp = r <=> rhs.r; cmp != 0) return cmp;
if (auto cmp = g <=> rhs.g; cmp != 0) return cmp;
if (auto cmp = b <=> rhs.b; cmp != 0) return cmp;
return a <=> rhs.a;
}
/* ===== BEGIN USER CUSTOM ===== */
VxColor::VxColor(CKDWORD argb) { FromARGB(argb); }
VxColor::VxColor(CKFLOAT _r, CKFLOAT _g, CKFLOAT _b) : r(_r), g(_g), b(_b), a(1.0f) {}
void VxColor::FromARGB(CKDWORD argb) {
a = ((argb & 0xFF000000) >> 24) / 255.0f;
r = ((argb & 0x00FF0000) >> 16) / 255.0f;
g = ((argb & 0x0000FF00) >> 8) / 255.0f;
b = ((argb & 0x000000FF) >> 0) / 255.0f;
}
CKDWORD VxColor::ToARGB() const {
CKDWORD argb = 0;
argb |= static_cast<CKDWORD>(a * 255.0f);
argb <<= 8;
argb |= static_cast<CKDWORD>(r * 255.0f);
argb <<= 8;
argb |= static_cast<CKDWORD>(g * 255.0f);
argb <<= 8;
argb |= static_cast<CKDWORD>(b * 255.0f);
return argb;
}
void VxColor::Regulate() {
if (r > 1.0f) r = 1.0f;
else if (r < 0.0f) r = 0.0f;
if (g > 1.0f) g = 1.0f;
else if (g < 0.0f) g = 0.0f;
if (b > 1.0f) b = 1.0f;
else if (b < 0.0f) b = 0.0f;
if (a > 1.0f) a = 1.0f;
else if (a < 0.0f) a = 0.0f;
}
/* ===== END USER CUSTOM ===== */
#pragma endregion
#pragma region VxMatrix
VxMatrix::VxMatrix() : m_Data() { SetIdentity(); }
VxMatrix::VxMatrix(CKFLOAT m[4][4]) : m_Data() { std::memcpy(m_Data, m, sizeof(m_Data)); }
VxVector4& VxMatrix::operator[](size_t i) {
if (i >= 4) throw LogicException("Invalid index for VxMatrix::operator[].");
return *(reinterpret_cast<VxVector4*>(m_Data) + i);
}
const VxVector4& VxMatrix::operator[](size_t i) const {
if (i >= 4) throw LogicException("Invalid index for VxMatrix::operator[].");
return *(reinterpret_cast<const VxVector4*>(m_Data) + i);
}
bool VxMatrix::operator==(const VxMatrix& rhs) const {
return ((*this)[0] == rhs[0] && (*this)[1] == rhs[1] && (*this)[2] == rhs[2] && (*this)[3] == rhs[3]);
}
auto VxMatrix::operator<=>(const VxMatrix& rhs) const {
if (auto cmp = (*this)[0] <=> rhs[0]; cmp != 0) return cmp;
if (auto cmp = (*this)[1] <=> rhs[1]; cmp != 0) return cmp;
if (auto cmp = (*this)[2] <=> rhs[2]; cmp != 0) return cmp;
return (*this)[3] <=> rhs[3];
}
/* ===== BEGIN USER CUSTOM ===== */
void VxMatrix::Clear() {
std::memset(m_Data, 0, sizeof(m_Data));
}
void VxMatrix::SetIdentity() {
Clear();
m_Data[0][0] = m_Data[1][1] = m_Data[2][2] = m_Data[3][3] = 1.0f;
}
void VxMatrix::Perspective(CKFLOAT Fov, CKFLOAT Aspect, CKFLOAT Near_plane, CKFLOAT Far_plane) {
Clear();
m_Data[0][0] = std::cos(Fov * 0.5f) / std::sin(Fov * 0.5f);
m_Data[1][1] = m_Data[0][0] * Aspect;
m_Data[2][2] = Far_plane / (Far_plane - Near_plane);
m_Data[3][2] = -m_Data[2][2] * Near_plane;
m_Data[2][3] = 1;
}
void VxMatrix::PerspectiveRect(CKFLOAT Left, CKFLOAT Right, CKFLOAT Top, CKFLOAT Bottom, CKFLOAT Near_plane, CKFLOAT Far_plane) {
Clear();
CKFLOAT RL = 1.0f / (Right - Left);
CKFLOAT TB = 1.0f / (Top - Bottom);
m_Data[0][0] = 2.0f * Near_plane * RL;
m_Data[1][1] = 2.0f * Near_plane * TB;
m_Data[2][0] = -(Right + Left) * RL;
m_Data[2][1] = -(Top + Bottom) * TB;
m_Data[2][2] = Far_plane / (Far_plane - Near_plane);
m_Data[3][2] = -m_Data[2][2] * Near_plane;
m_Data[2][3] = 1;
}
void VxMatrix::Orthographic(CKFLOAT Zoom, CKFLOAT Aspect, CKFLOAT Near_plane, CKFLOAT Far_plane) {
Clear();
CKFLOAT iz = 1.0f / (Far_plane - Near_plane);
m_Data[0][0] = Zoom;
m_Data[1][1] = Zoom * Aspect;
m_Data[2][2] = iz;
m_Data[3][2] = -Near_plane * iz;
m_Data[3][3] = 1.0f;
}
void VxMatrix::OrthographicRect(CKFLOAT Left, CKFLOAT Right, CKFLOAT Top, CKFLOAT Bottom, CKFLOAT Near_plane, CKFLOAT Far_plane) {
Clear();
CKFLOAT ix = 1.0f / (Right - Left);
CKFLOAT iy = 1.0f / (Top - Bottom);
CKFLOAT iz = 1.0f / (Far_plane - Near_plane);
m_Data[0][0] = 2.0f * ix;
m_Data[1][1] = -2.0f * iy;
m_Data[2][2] = iz;
m_Data[3][0] = -(Left + Right) * ix;
m_Data[3][1] = (Top + Bottom) * iy;
m_Data[3][2] = -Near_plane * iz;
m_Data[3][3] = 1.0f;
}
/* ===== END USER CUSTOM ===== */
#pragma endregion
#pragma region Patched
namespace NSVxVector {
CKFLOAT DotProduct(const VxVector2& lhs, const VxVector2& rhs) {
return lhs * rhs;
}
CKFLOAT DotProduct(const VxVector3& lhs, const VxVector3& rhs) {
return lhs * rhs;
}
CKFLOAT DotProduct(const VxVector4& lhs, const VxVector4& rhs) {
return lhs * rhs;
}
VxVector3 CrossProduct(const VxVector3& lhs, const VxVector3& rhs) {
return VxVector3(
lhs.y * rhs.z - lhs.z * rhs.y,
lhs.z * rhs.x - lhs.x * rhs.z,
lhs.x * rhs.y - lhs.y * rhs.x
);
}
void Absolute(VxVector3& lhs) {
lhs.x = std::fabs(lhs.x);
lhs.y = std::fabs(lhs.y);
lhs.z = std::fabs(lhs.z);
}
}
namespace NSVxMatrix {
}
#pragma endregion
}

669
LibCmo/VxMath/VxTypes.hpp
View File

@ -7,7 +7,6 @@
#include <vector>
#include <cstring>
#include <cinttypes>
#include <cmath>
/**
* @brief The VxMath part of LibCmo.
@ -23,191 +22,75 @@ namespace LibCmo::VxMath {
class VxMemoryMappedFile;
// Misc
// ========== Vector-like Definition ==========
/**
* @brief The representation of a Vector in 2 dimensions.
* @remarks In original Virtools SDK, it was named Vx2DVector.
* @see VxVector3
*/
struct VxVector2 {
CKFLOAT x, y;
VxVector2() : x(0.0f), y(0.0f) {}
VxVector2(CKFLOAT _x, CKFLOAT _y) : x(_x), y(_y) {}
VxVector2();
VxVector2(CKFLOAT _x, CKFLOAT _y);
YYCC_DEF_CLS_COPY_MOVE(VxVector2);
CKFLOAT& operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
default: throw LogicException("Invalid index for VxVector2::operator[].");
}
}
const CKFLOAT& operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
default: throw LogicException("Invalid index for VxVector2::operator[].");
}
}
VxVector2& operator+=(const VxVector2& rhs) {
x += rhs.x;
y += rhs.y;
return *this;
}
friend VxVector2 operator+(const VxVector2& lhs, const VxVector2& rhs) {
return VxVector2(lhs.x + rhs.x, lhs.y + rhs.y);
}
VxVector2& operator-=(const VxVector2& rhs) {
x -= rhs.x;
y -= rhs.y;
return *this;
}
friend VxVector2 operator-(const VxVector2& lhs, const VxVector2& rhs) {
return VxVector2(lhs.x - rhs.x, lhs.y - rhs.y);
}
VxVector2& operator*=(CKFLOAT rhs) {
x *= rhs;
y *= rhs;
return *this;
}
friend VxVector2 operator*(const VxVector2& lhs, CKFLOAT rhs) {
return VxVector2(lhs.x * rhs, lhs.y * rhs);
}
friend VxVector2 operator*(CKFLOAT lhs, const VxVector2& rhs) {
return VxVector2(lhs * rhs.x, lhs * rhs.y);
}
friend CKFLOAT operator*(const VxVector2& lhs, const VxVector2& rhs) {
return (lhs.x * rhs.x + lhs.y * rhs.y);
}
VxVector2& operator/=(CKFLOAT rhs) {
if (rhs == 0.0f) return *this;
x /= rhs;
y /= rhs;
return *this;
}
friend VxVector2 operator/(const VxVector2& lhs, CKFLOAT rhs) {
if (rhs == 0.0f) return VxVector2(0.0f, 0.0f);
return VxVector2(lhs.x / rhs, lhs.y / rhs);
}
bool operator==(const VxVector2& rhs) const {
return (x == rhs.x && y == rhs.y);
}
auto operator<=>(const VxVector2& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
return y <=> rhs.y;
}
CKFLOAT SquaredLength() const {
return (x * x + y * y);
}
CKFLOAT Length() const {
return std::sqrt(SquaredLength());
}
void Normalized() {
CKFLOAT len = Length();
if (len == 0.0f) return;
x /= len;
y /= len;
}
VxVector2 Normalize() const {
CKFLOAT len = Length();
if (len == 0.0f) return VxVector2();
return VxVector2(x / len, y / len);
}
CKFLOAT& operator[](size_t i);
const CKFLOAT& operator[](size_t i) const;
bool operator==(const VxVector2& rhs) const;
auto operator<=>(const VxVector2& rhs) const;
VxVector2 operator+() const;
VxVector2 operator-() const;
VxVector2& operator+=(const VxVector2& rhs);
friend VxVector2 operator+(const VxVector2& lhs, const VxVector2& rhs);
VxVector2& operator-=(const VxVector2& rhs);
friend VxVector2 operator-(const VxVector2& lhs, const VxVector2& rhs);
VxVector2& operator*=(CKFLOAT rhs);
friend VxVector2 operator*(const VxVector2& lhs, CKFLOAT rhs);
friend VxVector2 operator*(CKFLOAT lhs, const VxVector2& rhs);
friend CKFLOAT operator*(const VxVector2& lhs, const VxVector2& rhs);
VxVector2& operator/=(CKFLOAT rhs);
friend VxVector2 operator/(const VxVector2& lhs, CKFLOAT rhs);
CKFLOAT SquaredLength() const;
CKFLOAT Length() const;
void Normalized();
VxVector2 Normalize() const;
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
};
/**
* @brief The representation of a Vector in 3 dimensions
* @remarks In original Virtools SDK, it was named VxVector.
*/
struct VxVector3 {
CKFLOAT x, y, z;
VxVector3() : x(0.0f), y(0.0f), z(0.0f) {}
VxVector3(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z) : x(_x), y(_y), z(_z) {}
VxVector3();
VxVector3(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z);
YYCC_DEF_CLS_COPY_MOVE(VxVector3);
CKFLOAT& operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
default: throw LogicException("Invalid index for VxVector3::operator[].");
}
}
const CKFLOAT& operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
default: throw LogicException("Invalid index for VxVector3::operator[].");
}
}
VxVector3& operator+=(const VxVector3& rhs) {
x += rhs.x;
y += rhs.y;
z += rhs.z;
return *this;
}
friend VxVector3 operator+(const VxVector3& lhs, const VxVector3& rhs) {
return VxVector3(lhs.x + rhs.x, lhs.y + rhs.y, lhs.z + rhs.z);
}
VxVector3& operator-=(const VxVector3& rhs) {
x -= rhs.x;
y -= rhs.y;
z -= rhs.z;
return *this;
}
friend VxVector3 operator-(const VxVector3& lhs, const VxVector3& rhs) {
return VxVector3(lhs.x - rhs.x, lhs.y - rhs.y, lhs.z - rhs.z);
}
VxVector3& operator*=(CKFLOAT rhs) {
x *= rhs;
y *= rhs;
z *= rhs;
return *this;
}
friend VxVector3 operator*(const VxVector3& lhs, CKFLOAT rhs) {
return VxVector3(lhs.x * rhs, lhs.y * rhs, lhs.z * rhs);
}
friend VxVector3 operator*(CKFLOAT lhs, const VxVector3& rhs) {
return VxVector3(lhs * rhs.x, lhs * rhs.y, lhs * rhs.z);
}
friend CKFLOAT operator*(const VxVector3& lhs, const VxVector3& rhs) {
return (lhs.x * rhs.x + lhs.y * rhs.y + lhs.z * rhs.z);
}
VxVector3& operator/=(CKFLOAT rhs) {
if (rhs == 0.0f) return *this;
x /= rhs;
y /= rhs;
z /= rhs;
return *this;
}
friend VxVector3 operator/(const VxVector3& lhs, CKFLOAT rhs) {
if (rhs == 0.0f) return VxVector3(0.0f, 0.0f, 0.0f);
return VxVector3(lhs.x / rhs, lhs.y / rhs, lhs.z / rhs);
}
bool operator==(const VxVector3& rhs) const {
return (x == rhs.x && y == rhs.y && z == rhs.z);
}
auto operator<=>(const VxVector3& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
if (auto cmp = y <=> rhs.y; cmp != 0) return cmp;
return z <=> rhs.z;
}
CKFLOAT SquaredLength() const {
return (x * x + y * y + z * z);
}
CKFLOAT Length() const {
return std::sqrt(SquaredLength());
}
void Normalized() {
CKFLOAT len = Length();
if (len == 0.0f) return;
x /= len;
y /= len;
z /= len;
}
VxVector3 Normalize() const {
CKFLOAT len = Length();
if (len == 0.0f) return VxVector3();
return VxVector3(x / len, y / len, z / len);
}
CKFLOAT& operator[](size_t i);
const CKFLOAT& operator[](size_t i) const;
bool operator==(const VxVector3& rhs) const;
auto operator<=>(const VxVector3& rhs) const;
VxVector3 operator+() const;
VxVector3 operator-() const;
VxVector3& operator+=(const VxVector3& rhs);
friend VxVector3 operator+(const VxVector3& lhs, const VxVector3& rhs);
VxVector3& operator-=(const VxVector3& rhs);
friend VxVector3 operator-(const VxVector3& lhs, const VxVector3& rhs);
VxVector3& operator*=(CKFLOAT rhs);
friend VxVector3 operator*(const VxVector3& lhs, CKFLOAT rhs);
friend VxVector3 operator*(CKFLOAT lhs, const VxVector3& rhs);
friend CKFLOAT operator*(const VxVector3& lhs, const VxVector3& rhs);
VxVector3& operator/=(CKFLOAT rhs);
friend VxVector3 operator/(const VxVector3& lhs, CKFLOAT rhs);
CKFLOAT SquaredLength() const;
CKFLOAT Length() const;
void Normalized();
VxVector3 Normalize() const;
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
};
/**
@ -215,107 +98,37 @@ namespace LibCmo::VxMath {
* @details
* VxVector4 is used for 3D transformation when the w component is used for perspective information.
* Most of the methods available for a VxVector3 are also implemented for the VxVector4.
* @remarks In original Virtools SDK, it was named VxVector4. Not changed.
* @see VxVector3
*/
struct VxVector4 {
CKFLOAT x, y, z, w;
VxVector4() : x(0.0f), y(0.0f), z(0.0f), w(0.0f) {}
VxVector4(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z, CKFLOAT _w) : x(_x), y(_y), z(_z), w(_w) {}
VxVector4();
VxVector4(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z, CKFLOAT _w);
YYCC_DEF_CLS_COPY_MOVE(VxVector4);
CKFLOAT& operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxVector4::operator[].");
}
}
const CKFLOAT& operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxVector4::operator[].");
}
}
VxVector4& operator+=(const VxVector4& rhs) {
x += rhs.x;
y += rhs.y;
z += rhs.z;
w += rhs.w;
return *this;
}
friend VxVector4 operator+(const VxVector4& lhs, const VxVector4& rhs) {
return VxVector4(lhs.x + rhs.x, lhs.y + rhs.y, lhs.z + rhs.z, lhs.w + rhs.w);
}
VxVector4& operator-=(const VxVector4& rhs) {
x -= rhs.x;
y -= rhs.y;
z -= rhs.z;
w -= rhs.w;
return *this;
}
friend VxVector4 operator-(const VxVector4& lhs, const VxVector4& rhs) {
return VxVector4(lhs.x - rhs.x, lhs.y - rhs.y, lhs.z - rhs.z, lhs.w - rhs.w);
}
VxVector4& operator*=(CKFLOAT rhs) {
x *= rhs;
y *= rhs;
z *= rhs;
w *= rhs;
return *this;
}
friend VxVector4 operator*(const VxVector4& lhs, CKFLOAT rhs) {
return VxVector4(lhs.x * rhs, lhs.y * rhs, lhs.z * rhs, lhs.w * rhs);
}
friend VxVector4 operator*(CKFLOAT lhs, const VxVector4& rhs) {
return VxVector4(lhs * rhs.x, lhs * rhs.y, lhs * rhs.z, lhs * rhs.w);
}
friend CKFLOAT operator*(const VxVector4& lhs, const VxVector4& rhs) {
return (lhs.x * rhs.x + lhs.y * rhs.y + lhs.z * rhs.z + lhs.w * rhs.w);
}
VxVector4& operator/=(CKFLOAT rhs) {
if (rhs == 0.0f) return *this;
x /= rhs;
y /= rhs;
z /= rhs;
w /= rhs;
return *this;
}
friend VxVector4 operator/(const VxVector4& lhs, CKFLOAT rhs) {
if (rhs == 0.0f) return VxVector4(0.0f, 0.0f, 0.0f, 0.0f);
return VxVector4(lhs.x / rhs, lhs.y / rhs, lhs.z / rhs, lhs.w / rhs);
}
bool operator==(const VxVector4& rhs) const {
return (x == rhs.x && y == rhs.y && z == rhs.z && w == rhs.w);
}
auto operator<=>(const VxVector4& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
if (auto cmp = y <=> rhs.y; cmp != 0) return cmp;
if (auto cmp = z <=> rhs.z; cmp != 0) return cmp;
return w <=> rhs.w;
}
CKFLOAT SquaredLength() const {
return (x * x + y * y + z * z + w * w);
}
CKFLOAT Length() const {
return std::sqrt(SquaredLength());
}
void Normalized() {
CKFLOAT len = Length();
if (len == 0.0f) return;
x /= len;
y /= len;
z /= len;
w /= len;
}
VxVector4 Normalize() const {
CKFLOAT len = Length();
if (len == 0.0f) return VxVector4();
return VxVector4(x / len, y / len, z / len, w / len);
}
CKFLOAT& operator[](size_t i);
const CKFLOAT& operator[](size_t i) const;
bool operator==(const VxVector4& rhs) const;
auto operator<=>(const VxVector4& rhs) const;
VxVector4 operator+() const;
VxVector4 operator-() const;
VxVector4& operator+=(const VxVector4& rhs);
friend VxVector4 operator+(const VxVector4& lhs, const VxVector4& rhs);
VxVector4& operator-=(const VxVector4& rhs);
friend VxVector4 operator-(const VxVector4& lhs, const VxVector4& rhs);
VxVector4& operator*=(CKFLOAT rhs);
friend VxVector4 operator*(const VxVector4& lhs, CKFLOAT rhs);
friend VxVector4 operator*(CKFLOAT lhs, const VxVector4& rhs);
friend CKFLOAT operator*(const VxVector4& lhs, const VxVector4& rhs);
VxVector4& operator/=(CKFLOAT rhs);
friend VxVector4 operator/(const VxVector4& lhs, CKFLOAT rhs);
CKFLOAT SquaredLength() const;
CKFLOAT Length() const;
void Normalized();
VxVector4 Normalize() const;
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
};
/**
@ -323,42 +136,22 @@ namespace LibCmo::VxMath {
* @details
* A Quaternion is defined by 4 floats and is used to represents an orientation in space.
* Its common usage is for interpolation between two orientations through the Slerp() method.
*
*
* Quaternions can be converted to VxMatrix or Euler Angles.
* @see VxMatrix, VxVector3
*/
struct VxQuaternion {
CKFLOAT x, y, z, w;
VxQuaternion() : x(0.0f), y(0.0f), z(0.0f), w(1.0f) {} // set your custom init.
VxQuaternion(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z, CKFLOAT _w) : x(_x), y(_y), z(_z), w(_w) {}
VxQuaternion();
VxQuaternion(CKFLOAT _x, CKFLOAT _y, CKFLOAT _z, CKFLOAT _w);
YYCC_DEF_CLS_COPY_MOVE(VxQuaternion);
CKFLOAT& operator[](size_t i) {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxQuaternion::operator[].");
}
}
const CKFLOAT& operator[](size_t i) const {
switch (i) {
case 0: return x;
case 1: return y;
case 2: return z;
case 3: return w;
default: throw LogicException("Invalid index for VxQuaternion::operator[].");
}
}
bool operator==(const VxQuaternion& rhs) const {
return (x == rhs.x && y == rhs.y && z == rhs.z && w == rhs.w);
}
auto operator<=>(const VxQuaternion& rhs) const {
if (auto cmp = x <=> rhs.x; cmp != 0) return cmp;
if (auto cmp = y <=> rhs.y; cmp != 0) return cmp;
if (auto cmp = z <=> rhs.z; cmp != 0) return cmp;
return w <=> rhs.w;
}
CKFLOAT& operator[](size_t i);
const CKFLOAT& operator[](size_t i) const;
bool operator==(const VxQuaternion& rhs) const;
auto operator<=>(const VxQuaternion& rhs) const;
/* ===== BEGIN USER CUSTOM ===== */
/* ===== END USER CUSTOM ===== */
};
/**
@ -366,69 +159,26 @@ namespace LibCmo::VxMath {
* @details
* Structure describing a color through 4 floats for each component Red, Green, Blue and Alpha.
* And each factor should be clamped between \c 0.0f and \c 1.0f.
*
*
* Most methods are used to construct a VxColor or to convert it to a 32 bit ARGB format.
*/
struct VxColor {
CKFLOAT r, g, b, a;
VxColor() : r(0.0f), g(0.0f), b(0.0f), a(1.0f) {} // set your custom init.
VxColor(CKFLOAT _r, CKFLOAT _g, CKFLOAT _b, CKFLOAT _a) : r(_r), g(_g), b(_b), a(_a) {}
VxColor(CKDWORD argb) { FromARGB(argb); }
VxColor();
VxColor(CKFLOAT _r, CKFLOAT _g, CKFLOAT _b, CKFLOAT _a);
YYCC_DEF_CLS_COPY_MOVE(VxColor);
void FromARGB(CKDWORD argb) {
a = ((argb & 0xFF000000) >> 24) / 255.0f;
r = ((argb & 0x00FF0000) >> 16) / 255.0f;
g = ((argb & 0x0000FF00) >> 8) / 255.0f;
b = ((argb & 0x000000FF) >> 0) / 255.0f;
}
CKDWORD ToARGB() const {
CKDWORD argb = 0;
argb |= static_cast<CKDWORD>(a * 255.0f);
argb <<= 8;
argb |= static_cast<CKDWORD>(r * 255.0f);
argb <<= 8;
argb |= static_cast<CKDWORD>(g * 255.0f);
argb <<= 8;
argb |= static_cast<CKDWORD>(b * 255.0f);
return argb;
}
void Regulate() {
if (r > 1.0f) r = 1.0f;
else if (r < 0.0f) r = 0.0f;
if (g > 1.0f) g = 1.0f;
else if (g < 0.0f) g = 0.0f;
if (b > 1.0f) b = 1.0f;
else if (b < 0.0f) b = 0.0f;
if (a > 1.0f) a = 1.0f;
else if (a < 0.0f) a = 0.0f;
}
CKFLOAT& operator[](size_t i) {
switch (i) {
case 0: return r;
case 1: return g;
case 2: return b;
case 3: return a;
default: throw LogicException("Invalid index for VxColor::operator[].");
}
}
const CKFLOAT& operator[](size_t i) const {
switch (i) {
case 0: return r;
case 1: return g;
case 2: return b;
case 3: return a;
default: throw LogicException("Invalid index for VxColor::operator[].");
}
}
bool operator==(const VxColor& rhs) const {
return (r == rhs.r && g == rhs.g && b == rhs.b && a == rhs.a);
}
auto operator<=>(const VxColor& rhs) const {
if (auto cmp = r <=> rhs.r; cmp != 0) return cmp;
if (auto cmp = g <=> rhs.g; cmp != 0) return cmp;
if (auto cmp = b <=> rhs.b; cmp != 0) return cmp;
return a <=> rhs.a;
}
CKFLOAT& operator[](size_t i);
const CKFLOAT& operator[](size_t i) const;
bool operator==(const VxColor& rhs) const;
auto operator<=>(const VxColor& rhs) const;
/* ===== BEGIN USER CUSTOM ===== */
VxColor(CKDWORD argb);
VxColor(CKFLOAT _r, CKFLOAT _g, CKFLOAT _b);
void FromARGB(CKDWORD argb);
CKDWORD ToARGB() const;
void Regulate();
/* ===== END USER CUSTOM ===== */
};
/**
@ -441,26 +191,111 @@ namespace LibCmo::VxMath {
private:
CKFLOAT m_Data[4][4];
public:
VxMatrix() : m_Data() { ResetToIdentity(); }
VxMatrix(CKFLOAT m[4][4]) : m_Data() { std::memcpy(m_Data, m, sizeof(m_Data)); }
VxMatrix();
VxMatrix(CKFLOAT m[4][4]);
YYCC_DEF_CLS_COPY_MOVE(VxMatrix);
void ResetToIdentity() {
std::memset(m_Data, 0, sizeof(m_Data));
m_Data[0][0] = m_Data[1][1] = m_Data[2][2] = m_Data[3][3] = 1.0f;
}
VxVector4& operator[](size_t i) {
if (i >= 4) throw LogicException("Invalid index for VxMatrix::operator[].");
return *(reinterpret_cast<VxVector4*>(m_Data) + i);
}
const VxVector4& operator[](size_t i) const {
if (i >= 4) throw LogicException("Invalid index for VxMatrix::operator[].");
return *(reinterpret_cast<const VxVector4*>(m_Data) + i);
}
bool operator==(const VxMatrix& rhs) const {
return std::memcmp(m_Data, rhs.m_Data, sizeof(m_Data)) == 0;
}
VxVector4& operator[](size_t i);
const VxVector4& operator[](size_t i) const;
bool operator==(const VxMatrix& rhs) const;
auto operator<=>(const VxMatrix& rhs) const;
/* ===== BEGIN USER CUSTOM ===== */
void Clear();
void SetIdentity();
/**
* @brief Constructs a perspective projection matrix.
* @param[in] Fov Field of View.
* @param[in] Aspect Aspect ratio (Width/height)
* @param[in] Near_plane Distance of the near clipping plane.
* @param[in] Far_plane Distance of the far clipping plane.
* @remarks Sets Mat to
*
* A = Cos(Fov/2)/Sin(Fov/2)
* F = Far_plane
* N = Near_plane
*
* [ A 0 0 0]
* [ 0 A*Aspect 0 0]
* MAT= [ 0 0 F/F-N 1]
* [ 0 0 -F.N/F-N 0]
*
* @see PerspectiveRect, Orthographic, OrthographicRect
*/
void Perspective(CKFLOAT Fov, CKFLOAT Aspect, CKFLOAT Near_plane, CKFLOAT Far_plane);
/**
* @brief Constructs a perspective projection matrix given a view rectangle.
* @param[in] Left Left clipping plane value.
* @param[in] Right Right clipping plane value.
* @param[in] Top top clipping plane value.
* @param[in] Bottom bottom clipping plane value.
* @param[in] Near_plane Distance of the near clipping plane.
* @param[in] Far_plane Distance of the far clipping plane.
* @remarks Sets Mat to
*
* F = Far_plane
* N = Near_plane
* R = Right
* L = Left
* T = Top
* B = Bottom
*
* [ 2/(R-L) 0 0 0]
* [ 0 -2/(T-B) 0 0]
* MAT = [ 0 0 1/F-N 0]
* [ -(L+R)/(R-L) (T+B)/(T-B) -N/F-N 1]
*
* @see Perspective, Orthographic, OrthographicRect
*/
void PerspectiveRect(CKFLOAT Left, CKFLOAT Right, CKFLOAT Top, CKFLOAT Bottom, CKFLOAT Near_plane, CKFLOAT Far_plane);
/**
* @brief Constructs a orthographic projection matrix.
* @param[in] Zoom Zoom factor.
* @param[in] Aspect Aspect ratio (Width/height)
* @param[in] Near_plane Distance of the near clipping plane.
* @param[in] Far_plane Distance of the far clipping plane.
* @remarks Sets Mat to
*
* F = Far_plane
* N = Near_plane
*
* [ Zoom 0 0 0]
* [ 0 Zoom*Aspect 0 0]
* MAT = [ 0 0 1/F-N 0]
* [ 0 0 -N/F-N 1]
*
* @see Perspective, OrthographicRect
*/
void Orthographic(CKFLOAT Zoom, CKFLOAT Aspect, CKFLOAT Near_plane, CKFLOAT Far_plane);
/**
* @brief Constructs a orthographic projection matrix.
* @param[in] Left Left clipping plane value.
* @param[in] Right Right clipping plane value.
* @param[in] Top top clipping plane value.
* @param[in] Bottom bottom clipping plane value.
* @param[in] Near_plane Distance of the near clipping plane.
* @param[in] Far_plane Distance of the far clipping plane.
* @remarks Sets Mat to
*
* F = Far_plane
* N = Near_plane
* R = Right
* L = Left
* T = Top
* B = Bottom
*
* [ 2/(R-L) 0 0 0]
* [ 0 -2/(T-B) 0 0]
* MAT = [ 0 0 1/F-N 0]
* [ -(L+R)/(R-L) (T+B)/(T-B) -N/F-N 1]
*
* @see Perspective, Orthographic
*/
void OrthographicRect(CKFLOAT Left, CKFLOAT Right, CKFLOAT Top, CKFLOAT Bottom, CKFLOAT Near_plane, CKFLOAT Far_plane);
/* ===== END USER CUSTOM ===== */
};
// ========== Misc ==========
/**
* @brief Structure for storage of strided data.
* @tparam _Ty The data pointer type this class stored.
@ -696,4 +531,96 @@ namespace LibCmo::VxMath {
CKBYTE* m_Image; /**< A pointer points to current image in memory */
};
// ========== Patch Section ==========
/**
* @brief The patch namespace for VxVector-like classes
* @details This namespace provides VxVector-like classes member functions which presented in original Virtools SDK.
* These functions are put in public namespace in original Virtools SDK.
* We just organise them into an unique namespace.
*/
namespace NSVxVector {
/**
* @brief Dot product 2 2d vectors.
* @param[in] lhs The left side vector of dot product symbol.
* @param[in] rhs The right side vector of dot product symbol.
* @return The float pointing result of dot product.
*/
CKFLOAT DotProduct(const VxVector2& lhs, const VxVector2& rhs);
/**
* @brief Dot product 2 3d vectors.
* @param[in] lhs The left side vector of dot product symbol.
* @param[in] rhs The right side vector of dot product symbol.
* @return The float pointing result of dot product.
*/
CKFLOAT DotProduct(const VxVector3& lhs, const VxVector3& rhs);
/**
* @brief Dot product 2 4d vectors.
* @param[in] lhs The left side vector of dot product symbol.
* @param[in] rhs The right side vector of dot product symbol.
* @return The float pointing result of dot product.
*/
CKFLOAT DotProduct(const VxVector4& lhs, const VxVector4& rhs);
/**
* @brief Cross product 2 3d vectors.
* @param[in] lhs The left side vector of cross product symbol.
* @param[in] rhs The right side vector of cross product symbol.
* @return The 3d vector result of cross product.
*/
VxVector3 CrossProduct(const VxVector3& lhs, const VxVector3& rhs);
/**
* @brief Set all factor in vector to its absolute value.
* @param[in,out] lhs The vector for processing.
* @remarks This function is rarely used.
* Please note this function is not calculate the absolute value of vector.
*/
void Absolute(VxVector3& lhs);
}
/**
* @brief The patch namespace for VxMatrix classes
* @details Like NXVxVector, these functions located in this namespace
* are exposed in public namespace in original Virtools SDK.
* And I re-organise them in there.
*/
namespace NSVxMatrix {
//void Vx3DMatrixIdentity(VxMatrix& Mat);
//void Vx3DMultiplyMatrixVector(VxVector *ResultVector,const VxMatrix& Mat,const VxVector *Vector);
//void Vx3DMultiplyMatrixVectorMany(VxVector *ResultVectors,const VxMatrix& Mat,const VxVector *Vectors,int count,int stride);
//void Vx3DMultiplyMatrixVector4(VxVector4 *ResultVector,const VxMatrix& Mat,const VxVector4 *Vector);
//void Vx3DMultiplyMatrixVector4(VxVector4 *ResultVector,const VxMatrix& Mat,const VxVector *Vector); // w=1
//void Vx3DRotateVector(VxVector *ResultVector,const VxMatrix& Mat,const VxVector *Vector);
//void Vx3DRotateVectorMany(VxVector *ResultVector,const VxMatrix& Mat,const VxVector *Vector,int count,int stride);
//void Vx3DMultiplyMatrix(VxMatrix& ResultMat,const VxMatrix& MatA,const VxMatrix& MatB);
//void Vx3DMultiplyMatrix4(VxMatrix& ResultMat,const VxMatrix& MatA,const VxMatrix& MatB);
//void Vx3DInverseMatrix(VxMatrix& InverseMat,const VxMatrix& Mat);
//float Vx3DMatrixDeterminant(const VxMatrix& Mat);
//void Vx3DMatrixFromRotation(VxMatrix& ResultMat,const VxVector& Vector, float Angle);
//void Vx3DMatrixFromRotationAndOrigin(VxMatrix& ResultMat,const VxVector& Vector,const VxVector& Origin, float Angle);
//void Vx3DMatrixFromEulerAngles(VxMatrix& Mat,float eax,float eay,float eaz);
//void Vx3DMatrixToEulerAngles(const VxMatrix& Mat,float *eax,float* eay,float* eaz);
//void Vx3DInterpolateMatrix(float step,VxMatrix& Res,const VxMatrix& A, const VxMatrix& B);
//void Vx3DInterpolateMatrixNoScale(float step,VxMatrix& Res,const VxMatrix& A, const VxMatrix& B);
//void Vx3DMultiplyMatrixVectorStrided(VxStridedData* Dest,VxStridedData* Src,const VxMatrix& Mat,int count);
//void Vx3DMultiplyMatrixVector4Strided(VxStridedData* Dest,VxStridedData* Src,const VxMatrix& Mat,int count);
//void Vx3DRotateVectorStrided(VxStridedData* Dest,VxStridedData* Src,const VxMatrix& Mat,int count);
//void Vx3DTransposeMatrix(VxMatrix& Result,const VxMatrix& A);
//void Vx3DDecomposeMatrix(const VxMatrix& A, VxQuaternion &Quat,VxVector &Pos,VxVector &Scale);
//float Vx3DDecomposeMatrixTotal(const VxMatrix& A, VxQuaternion &Quat,VxVector &Pos,VxVector &Scale,VxQuaternion &URot);
//float Vx3DDecomposeMatrixTotalPtr(const VxMatrix& A, VxQuaternion* Quat,VxVector* Pos,VxVector* Scale,VxQuaternion* URot);
//void VxInverseProject(const VxMatrix& iProjection, const Vx2DVector& i2D, const float iZ, VxVector* o3D);
}
}

25
README.md
View File

@ -1,7 +1,7 @@
# libcmo21
The Library for CMO (also accept NMO, VMO and NMS) File Read/Write. Also the Minimalist Virtools Environment.
Write with one Library and Load Virtools File Everywhere.
The Library for CMO (also accept NMO, VMO and NMS) File RW (Read and Write). Also the Minimalist Virtools Environment.
Write with one Library and Load/Save Virtools File Everywhere.
## Status
@ -10,12 +10,15 @@ This project welcome everyone's contribution, except the employee of Dassault, w
## Introduction
The aim of this project is creating a universal library which can read / write CMO files or any other Virtools files without any Virtools dependencies.
This project will not link any original Virtools dynamic library. So this project can be ported to any platform if the compiler supports.
This project only involving specific Virtools version, 2.1. Other Virtools versions are not considered by this project.
This project is based on reverse work of `CK2.dll`, `VxMath.dll` and `CK2_3D.dll`. The program [unvirt](https://aluigi.altervista.org/papers.htm#unvirt) created by Luigi Auriemma, which is licensed by GPL-v2, also help my work.
The aim of this project is creating a universal library which can RW CMO files or any other Virtools files without any Virtools dependencies.
**The difference between this project and other Virtools libraries (e.g. [doyaGu/CK2](https://github.com/doyaGu/CK2)), is that we are not focusing on re-creating the whole Virtools engine. We only focus on the Virtools files RW, and we only just implement a minimalist Virtools environment for achieving this.**
This project will not link any original Virtools dynamic library. So this project can be ported to any platform if the compiler and runtime libraries support.
This project only involving specific Virtools version, 2.1. Other too higher Virtools versions are not considered by this project.
This project is barely based on the reverse work of doyaGu who decompile `CK2.dll`, `VxMath.dll` and `CK2_3D.dll`. The program [unvirt](https://aluigi.altervista.org/papers.htm#unvirt) created by Luigi Auriemma, which is licensed by GPL-v2, also help my work.
**The difference between this project and other Virtools libraries (e.g. [doyaGu/CK2](https://github.com/doyaGu/CK2)), is that this project is not focusing on re-creating the whole Virtools engine. This project only focus on the Virtools files RW, and it only just implement a minimalist Virtools environment for achieving this.**
## Goals
@ -23,22 +26,20 @@ The ultimate goals of this project are:
* Create a library which can read Virtools file and do not limited on x86 platform by original Virtools implement.
* Create a universal dynamic library for Ballance Map file loading.
* Create a Python binding for the loader. And allow user can export Ballance Map from Blender on Linux platform natively.
* Create a C# binding for the loader to enable that I can load Ballance Map in Godot on Linux / Android platform natively.
- Create a Python binding for the loader. And allow user can export Ballance Map from Blender on Linux platform natively.
- Create a C# binding for the loader to enable that I can load Ballance Map in Godot on Linux / Android platform natively.
There is still a long way to go. But I will try my best.
## Project Layout
* LibCmo: Core library. It is a static library. Link to your program freely because I don't want to process export table things.
* IronPad: A tiny Crashpad like static library. Used by Unvirt and BMap. Report crash log and coredump only on Windows (Because I assume all Linux users have capacity to enable coredump and deliver it to developer.).
* Unvirt: Interactive Virtools file viewer. Can provide more detail than Luigi Auriemma's unvirt but only can accept version limited Virtools file (< 4.0 I guess).
* BMap: A dynamic library which is specific for Ballance Map loading by using LibCmo.
## Contributions
However, not all contribution will be accepted. Just like I said, we create **Minimalist** Virtools Environment. The basic RW functions is enough. We do not accept complex function implementations.
There are 3 lists which indicate our accept guideline.
However, not all contribution will be accepted. Just like I said, we create **Minimalist** Virtools Environment. The basic RW functions is enough. We do not accept complex function implementations. There are 3 lists which indicate our accept guideline.
### Wanted Features

3
Scripts/.gitignore vendored Normal file
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@ -0,0 +1,3 @@
# Disable output
win_build.bat
linux_build.sh

67
Scripts/gen_build_script.py Normal file
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@ -0,0 +1,67 @@
import os
import argparse
import jinja2
def get_root_directory() -> str:
return os.path.dirname(os.path.dirname(__file__))
class ScriptSettings:
m_BuildDoc: bool
def __init__(self, build_doc: bool):
self.m_BuildDoc = build_doc
class TemplateRender:
m_Loader: jinja2.BaseLoader
m_Environment: jinja2.Environment
m_WinTemplate: jinja2.Template
m_LinuxTemplate: jinja2.Template
m_Settings: ScriptSettings
def __init__(self, settings: ScriptSettings) -> None:
self.m_Loader = jinja2.FileSystemLoader(self.__get_dir())
self.m_Environment = jinja2.Environment(loader=self.m_Loader)
self.m_WinTemplate = self.m_Environment.get_template('win_build.template.bat')
self.m_LinuxTemplate = self.m_Environment.get_template('linux_build.template.sh')
self.m_Settings = settings
def __get_dir(self) -> str:
return os.path.dirname(__file__)
def __render(self, template: jinja2.Template, dest_file: str, is_win: bool) -> None:
with open(os.path.join(self.__get_dir(), dest_file), 'w', encoding='utf-8') as f:
f.write(template.render(
repo_root_dir = os.path.dirname(self.__get_dir()),
build_doc = self.m_Settings.m_BuildDoc
))
def render_win_script(self) -> None:
self.__render(self.m_WinTemplate, 'win_build.bat', True)
def render_linux_script(self) -> None:
self.__render(self.m_LinuxTemplate, 'linux_build.sh', False)
if __name__ == '__main__':
# parse argument
parser = argparse.ArgumentParser(
prog='LibCmo Windows Build Script',
description='LibCmo Windows Build Script'
)
parser.add_argument(
'-d', '--build-doc',
action='store_true', dest='build_doc',
help='Build LibCmo without documentation.'
)
args = parser.parse_args()
# build settings
settings = ScriptSettings(args.build_doc)
# build template render and render result
render = TemplateRender(settings)
render.render_win_script()
render.render_linux_script()

0
Scripts/linux_build.template.sh Normal file
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38
Scripts/win_build.bat
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@ -1,38 +0,0 @@
@ECHO OFF
:: Check environment
SET README_PATH=%CD%\README.md
IF EXIST %README_PATH% (
REM DO NOTHING
) ELSE (
ECHO Error: You must run this script at the root folder of this project!
EXIT /b
)
:: Create main binary directory
MKDIR bin
CD bin
:: Create build and install folder
MKDIR build
MKDIR install
:: Check build doc switch
IF NOT "%1"=="NODOC" (
SET BUILD_DOC_SWITCH=ON
) ELSE (
SET BUILD_DOC_SWITCH=OFF
)
:: Build project
CD build
cmake -G "Visual Studio 16 2019" -A x64 -DNEMO_BUILD_UNVIRT=ON -DNEMO_BUILD_BMAP=ON -DNEMO_BUILD_DOC=%BUILD_DOC_SWITCH% -DSTB_IMAGE_PATH="D:\CppLib\stb" -DYYCC_PATH="J:\YYCCommonplace\bin\cpp20\install\x64_Debug" -DZLIB_HEADER_PATH="D:\zlib" -DZLIB_BINARY_PATH="D:\zlib\contrib\vstudio\vc14\x64\ZlibDllRelease" ../..
pause
cmake --build . --config Release
IF NOT "%1"=="NODOC" (
cmake --build . --target NeMoDocuments
)
cmake --install . --prefix=../install --config Release
CD ..
:: Exit to original path
CD ..
ECHO Windows CMake Build Done

48
Scripts/win_build.py
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@ -1,48 +0,0 @@
import subprocess
import os
import shutil
import argparse
def get_root_directory() -> str:
return os.path.dirname(os.path.dirname(__file__))
def execute_cmd(prog: str, args: tuple[str, ...], cwd: str) -> None:
# find program first
found_prog = shutil.which(prog)
if found_prog is None:
raise RuntimeError(f'Fail to find program {prog}')
# run command
subprocess.run(
list((found_prog, ) + args), # program + arguments
stdin=subprocess.PIPE, # redirect
stdout=subprocess.PIPE, # redirect
stderr=subprocess.STDOUT, # stderr use the same output with stdout
cwd=cwd, # work directory
shell=True, # enable shell feature
check=True, # if program failed, raise exception and exit
)
def build(no_doc: bool) -> None:
# create directory
root_dir: str = get_root_directory()
os.makedirs(os.path.join(root_dir, 'Bin', 'build'))
os.makedirs(os.path.join(root_dir, 'Bin', 'install'))
# build project
args = [
''
]
if __name__ == '__main__':
# parse argument
parser = argparse.ArgumentParser(
prog='LibCmo Windows Build Script',
description='LibCmo Windows Build Script'
)
parser.add_argument(
'-d', '--no-doc',
action='store_true', dest='no_doc',
help='Build LibCmo without documentation.'
)
args = parser.parse_args()
build(args.no_doc)

24
Scripts/win_build.template.bat Normal file
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@ -0,0 +1,24 @@
@ECHO OFF
:: Navigate to root directory
CD /d {{ repo_root_dir }}
:: Create main binary directory
MKDIR bin
CD bin
:: Create build and install folder
MKDIR build
MKDIR install
:: Build project
CD build
cmake -A x64 -DNEMO_BUILD_UNVIRT=ON -DNEMO_BUILD_BMAP=ON {{ '-DNEMO_BUILD_DOC=ON' if build_doc }} -DSTB_IMAGE_PATH="D:\CppLib\stb" -DYYCC_PATH="J:\YYCCommonplace\bin\cpp20\install\x64_Release" -DZLIB_HEADER_PATH="D:\zlib" -DZLIB_BINARY_PATH="D:\zlib\contrib\vstudio\vc14\x64\ZlibDllRelease" ../..
cmake --build . --config RelWithDebInfo
{% if build_doc %}
cmake --build . --target NeMoDocuments
{% endif %}
cmake --install . --prefix=../install --config RelWithDebInfo
CD ..
:: Exit to original path
CD ..
ECHO Windows CMake Build Done

10
Unvirt/AccessibleValue.cpp
View File

@ -383,6 +383,10 @@ namespace Unvirt::AccessibleValue {
{ LibCmo::CK2::CK_BITMAPDATA_FLAGS::CKBITMAPDATA_FREEVIDEOMEMORY, { u8"CKBITMAPDATA_FREEVIDEOMEMORY" } },
{ LibCmo::CK2::CK_BITMAPDATA_FLAGS::CKBITMAPDATA_DYNAMIC, { u8"CKBITMAPDATA_DYNAMIC" } },
};
const GeneralReflectionArray<LibCmo::CK2::CK_CAMERA_PROJECTION> CK_CAMERA_PROJECTION {
{ LibCmo::CK2::CK_CAMERA_PROJECTION::CK_PERSPECTIVEPROJECTION, { u8"CK_PERSPECTIVEPROJECTION" } },
{ LibCmo::CK2::CK_CAMERA_PROJECTION::CK_ORTHOGRAPHICPROJECTION, { u8"CK_ORTHOGRAPHICPROJECTION" } },
};
const GeneralReflectionArray<LibCmo::VxMath::VX_PIXELFORMAT> VX_PIXELFORMAT {
{ LibCmo::VxMath::VX_PIXELFORMAT::UNKNOWN_PF, { u8"UNKNOWN_PF" } },
@ -418,6 +422,12 @@ namespace Unvirt::AccessibleValue {
{ LibCmo::VxMath::VX_PIXELFORMAT::_4_ABGR8888_CLUT, { u8"_4_ABGR8888_CLUT" } },
{ LibCmo::VxMath::VX_PIXELFORMAT::_4_ARGB8888_CLUT, { u8"_4_ARGB8888_CLUT" } },
};
const GeneralReflectionArray<LibCmo::VxMath::VXLIGHT_TYPE> VXLIGHT_TYPE {
{ LibCmo::VxMath::VXLIGHT_TYPE::VX_LIGHTPOINT, { u8"VX_LIGHTPOINT" } },
{ LibCmo::VxMath::VXLIGHT_TYPE::VX_LIGHTSPOT, { u8"VX_LIGHTSPOT" } },
{ LibCmo::VxMath::VXLIGHT_TYPE::VX_LIGHTDIREC, { u8"VX_LIGHTDIREC" } },
{ LibCmo::VxMath::VXLIGHT_TYPE::VX_LIGHTPARA, { u8"VX_LIGHTPARA" } },
};
const GeneralReflectionArray<LibCmo::VxMath::VXTEXTURE_BLENDMODE> VXTEXTURE_BLENDMODE {
{ LibCmo::VxMath::VXTEXTURE_BLENDMODE::VXTEXTUREBLEND_DECAL, { u8"VXTEXTUREBLEND_DECAL" } },
{ LibCmo::VxMath::VXTEXTURE_BLENDMODE::VXTEXTUREBLEND_MODULATE, { u8"VXTEXTUREBLEND_MODULATE" } },

4
Unvirt/AccessibleValue.hpp
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@ -61,7 +61,7 @@ namespace Unvirt {
}
// check flag match
if (LibCmo::EnumsHelper::Has(val, item.first)) {
if (YYCC::EnumHelper::Has(val, item.first)) {
// add splittor if it not the first entry
if (strl.size() != 0u && splitor != nullptr) {
strl += splitor;
@ -102,8 +102,10 @@ namespace Unvirt {
extern const GeneralReflectionArray<LibCmo::CK2::CK_3DENTITY_FLAGS> CK_3DENTITY_FLAGS;
extern const GeneralReflectionArray<LibCmo::CK2::CK_TEXTURE_SAVEOPTIONS> CK_TEXTURE_SAVEOPTIONS;
extern const GeneralReflectionArray<LibCmo::CK2::CK_BITMAPDATA_FLAGS> CK_BITMAPDATA_FLAGS;
extern const GeneralReflectionArray<LibCmo::CK2::CK_CAMERA_PROJECTION> CK_CAMERA_PROJECTION;
extern const GeneralReflectionArray<LibCmo::VxMath::VX_PIXELFORMAT> VX_PIXELFORMAT;
extern const GeneralReflectionArray<LibCmo::VxMath::VXLIGHT_TYPE> VXLIGHT_TYPE;
extern const GeneralReflectionArray<LibCmo::VxMath::VXTEXTURE_BLENDMODE> VXTEXTURE_BLENDMODE;
extern const GeneralReflectionArray<LibCmo::VxMath::VXTEXTURE_FILTERMODE> VXTEXTURE_FILTERMODE;
extern const GeneralReflectionArray<LibCmo::VxMath::VXBLEND_MODE> VXBLEND_MODE;

4
Unvirt/CMakeLists.txt
View File

@ -23,8 +23,6 @@ FILES
target_include_directories(Unvirt
PRIVATE
"${CMAKE_CURRENT_LIST_DIR}"
YYCC::YYCCommonplace
LibCmo
)
# Setup linked library infomation
target_link_libraries(Unvirt
@ -53,6 +51,6 @@ PRIVATE
# Install Unvirt only on Release mode
install(TARGETS Unvirt
CONFIGURATIONS Release
CONFIGURATIONS Release RelWithDebInfo MinSizeRel
RUNTIME DESTINATION ${YYCC_INSTALL_BIN_PATH}
)

4
Unvirt/CmdHelper.hpp
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@ -362,8 +362,8 @@ namespace Unvirt::CmdHelper {
throw std::invalid_argument("root node should not be inserted as child node.");
// check conflict
const auto& new_node_set = new_node_ptr->GetConflictSet();
for (auto& node : m_Nodes) {
const auto& node_set = node->GetConflictSet();
for (auto& child_node : m_Nodes) {
const auto& node_set = child_node->GetConflictSet();
if (new_node_set.IsConflictWith(node_set))
throw std::invalid_argument("try to add a conflict node. please check your code.");
}

78
Unvirt/StructFormatter.cpp
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@ -165,7 +165,7 @@ namespace Unvirt::StructFormatter {
// print current mesh
{
auto curmesh = obj->GetCurrentMesh();
Console::Format(u8"->\t%s\t%s",
Console::FormatLine(u8"->\t%s\t%s",
PrintPointer(curmesh).c_str(),
(curmesh != nullptr ? PrintCKSTRING(curmesh->GetName()).c_str() : u8"")
);
@ -181,6 +181,70 @@ namespace Unvirt::StructFormatter {
}
}
static void PrintCKLightDetail(LibCmo::CK2::ObjImpls::CKLight* obj) {
PrintCK3dEntityDetail(obj);
Console::WriteLine(YYCC_COLOR_LIGHT_YELLOW(u8"CKLight"));
Console::WriteLine(u8"== Basics ==");
Console::FormatLine(u8"Type: %s", AccessibleValue::GetEnumName(obj->GetType(), AccessibleValue::EnumDesc::VXLIGHT_TYPE).c_str());
Console::FormatLine(u8"Color: %s", PrintColor(obj->GetColor()).c_str());
Console::FormatLine(u8"Light Power: %.2" PRIfCKFLOAT, obj->GetLightPower());
Console::WriteLine(u8"== Switches ==");
Console::FormatLine(u8"Activity: %s", PrintBool(obj->GetActivity()).c_str());
Console::FormatLine(u8"Specular Flag: %s", PrintBool(obj->GetSpecularFlag()).c_str());
Console::WriteLine(u8"== Attenuation ==");
Console::FormatLine(u8"Constant Attenuation: %.2" PRIfCKFLOAT, obj->GetConstantAttenuation());
Console::FormatLine(u8"Linear Attenuation: %.2" PRIfCKFLOAT, obj->GetLinearAttenuation());
Console::FormatLine(u8"Quadratic Attenuation: %.2" PRIfCKFLOAT, obj->GetQuadraticAttenuation());
Console::WriteLine(u8"== Spot Cone ==");
Console::FormatLine(u8"Range: %.2" PRIfCKFLOAT, obj->GetRange());
Console::FormatLine(u8"Hot Spot: %.2" PRIfCKFLOAT, obj->GetHotSpot());
Console::FormatLine(u8"Falloff: %.2" PRIfCKFLOAT, obj->GetFalloff());
Console::FormatLine(u8"Falloff Shape: %.2" PRIfCKFLOAT, obj->GetFalloffShape());
Console::WriteLine(u8"== Target ==");
auto thistarget = obj->GetTarget();
Console::FormatLine(u8"Target Address: %s", PrintPointer(thistarget).c_str());
if (thistarget != nullptr)
Console::FormatLine(u8"Target Name: %s", PrintCKSTRING(thistarget->GetName()).c_str());
}
static void PrintCKTargetLightDetail(LibCmo::CK2::ObjImpls::CKTargetLight* obj) {
PrintCKLightDetail(obj);
Console::WriteLine(YYCC_COLOR_LIGHT_YELLOW(u8"CKTargetLight"));
Console::WriteLine(YYCC_COLOR_LIGHT_RED(u8"No Data"));
}
static void PrintCKCameraDetail(LibCmo::CK2::ObjImpls::CKCamera* obj) {
PrintCK3dEntityDetail(obj);
Console::WriteLine(YYCC_COLOR_LIGHT_YELLOW(u8"CKCamera"));
Console::WriteLine(u8"== Basics ==");
Console::FormatLine(u8"Projection Type: %s", AccessibleValue::GetEnumName(obj->GetProjectionType(), AccessibleValue::EnumDesc::CK_CAMERA_PROJECTION).c_str());
Console::FormatLine(u8"Orthographic Zoom: %.2" PRIfCKFLOAT, obj->GetOrthographicZoom());
Console::FormatLine(u8"Front Plane: %.2" PRIfCKFLOAT, obj->GetFrontPlane());
Console::FormatLine(u8"Back Plane: %.2" PRIfCKFLOAT, obj->GetBackPlane());
Console::FormatLine(u8"Fov: %.2" PRIfCKFLOAT, obj->GetFov());
LibCmo::CKDWORD width, height;
obj->GetAspectRatio(width, height);
Console::FormatLine(u8"Aspect Ratio: %" PRIuCKDWORD " : %" PRIuCKDWORD, width, height);
Console::WriteLine(u8"== Target ==");
auto thistarget = obj->GetTarget();
Console::FormatLine(u8"Target Address: %s", PrintPointer(thistarget).c_str());
if (thistarget != nullptr)
Console::FormatLine(u8"Target Name: %s", PrintCKSTRING(thistarget->GetName()).c_str());
}
static void PrintCKTargetCameraDetail(LibCmo::CK2::ObjImpls::CKTargetCamera* obj) {
PrintCKCameraDetail(obj);
Console::WriteLine(YYCC_COLOR_LIGHT_YELLOW(u8"CKTargetCamera"));
Console::WriteLine(YYCC_COLOR_LIGHT_RED(u8"No Data"));
}
static void PrintCK3dObjectDetail(LibCmo::CK2::ObjImpls::CK3dObject* obj) {
PrintCK3dEntityDetail(obj);
@ -560,6 +624,18 @@ namespace Unvirt::StructFormatter {
case LibCmo::CK2::CK_CLASSID::CKCID_3DENTITY:
PrintCK3dEntityDetail(static_cast<LibCmo::CK2::ObjImpls::CK3dEntity*>(mobj));
break;
case LibCmo::CK2::CK_CLASSID::CKCID_LIGHT:
PrintCKLightDetail(static_cast<LibCmo::CK2::ObjImpls::CKLight*>(mobj));
break;
case LibCmo::CK2::CK_CLASSID::CKCID_TARGETLIGHT:
PrintCKTargetLightDetail(static_cast<LibCmo::CK2::ObjImpls::CKTargetLight*>(mobj));
break;
case LibCmo::CK2::CK_CLASSID::CKCID_CAMERA:
PrintCKCameraDetail(static_cast<LibCmo::CK2::ObjImpls::CKCamera*>(mobj));
break;
case LibCmo::CK2::CK_CLASSID::CKCID_TARGETCAMERA:
PrintCKTargetCameraDetail(static_cast<LibCmo::CK2::ObjImpls::CKTargetCamera*>(mobj));
break;
case LibCmo::CK2::CK_CLASSID::CKCID_3DOBJECT:
PrintCK3dObjectDetail(static_cast<LibCmo::CK2::ObjImpls::CK3dObject*>(mobj));
break;

2
Unvirt/UnvirtContext.cpp
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@ -281,7 +281,7 @@ namespace Unvirt::Context {
YYCC::ConsoleHelper::EnableColorfulConsole();
// Show banner
YYCC::ConsoleHelper::WriteLine(YYCC_COLOR_LIGHT_YELLOW(u8"Unvirt 0.2.0") " built at " __DATE__ " " __TIME__);
YYCC::ConsoleHelper::WriteLine(YYCC_COLOR_LIGHT_YELLOW(u8"Unvirt") " (based on LibCmo " LIBCMO_VER_STR ") built at " __DATE__ " " __TIME__);
YYCC::ConsoleHelper::WriteLine(u8"Type 'help' for more infomation. Type 'exit' to quit.");
// start process loop