# IGES Translator  <a id="occt_user_guides__iges" class="anchor"></a>

<h2><a id="occt_iges_1">Introduction</a></h2>

The IGES interface reads IGES files and translates them to Open CASCADE Technology models. The interface is able to translate one entity, a group of entities or a whole file. Before beginning a translation, you can set a range of parameters to manage the translation process. If you like, you can also check file consistency before translation. The IGES interface also translates OCCT models to IGES files. 

Other kinds of data such as colors and names can be read or written with the help of XDE tools <i> IGESCAFControl_Reader</i> and <i> IGESCAFControl_Writer</i>. 

**Note** :

  * an IGES model is an IGES file that has been loaded into memory.
  * an IGES entity is an entity in the IGES normal sense.
  * a root entity is the highest level entity of any given type, e.g. type 144 for surfaces and type 186 for solids. Roots are not referenced by other entities.

This manual mainly explains how  to convert an IGES file to an Open CASCADE Technology (**OCCT**) shape and  vice versa. It provides basic documentation on conversion.

IGES files produced in accordance with IGES standard versions up to and including version 5.3 can be read. IGES files that are produced by this  interface conform to IGES version 5.3 (Initial Graphics Exchange Specification,  IGES 5.3. ANS US PRO/IPO-100-1996). 

This manual principally  deals with two OCCT classes: 
  * The Reader class, which loads  IGES files and translates their contents to OCCT shapes,
  * The Writer class, which  translates OCCT shapes to IGES entities and then writes these entities to IGES  files.
  
File translation is  performed in the programming mode, via C++ calls, and the resulting OCCT  objects are shapes. 

All definitions in IGES  version 5.3 are recognized but only 3D geometric entities are translated. When  the processor encounters data, which is not translated, it ignores it and  writes a message identifying the types of data, which was not handled. This  message can be written either to a log file or to screen output. 

[Shape Healing](shape_healing.md#occt_user_guides__shape_healing) toolkit provides tools to heal various problems, which may be encountered in translated shapes, and to make them valid in Open CASCADE. The Shape Healing is smoothly connected to IGES translator using the same API, only the names of API packages change.

<h2><a id="occt_iges_2">Reading IGES</a></h2>
<h3><a id="occt_iges_2_1">Procedure</a></h3>
You can translate an  IGES file to an OCCT shape by following the steps below: 
  -# Load the file,
  -# Check file consistency,
  -# Set the translation parameters,
  -# Perform the file translation,
  -# Fetch the results.
<h3><a id="occt_iges_2_2">Domain covered</a></h3>
<h4><a id="occt_iges_2_2_1">Translatable entities</a></h4>
The types of IGES  entities, which can be translated, are: 
  * Points
  * Lines
  * Curves
  * Surfaces
  * B-Rep entities
  * Structure entities (groups).  Each entity in the group outputs a shape. There can be a group of groups.
  * Subfigures. Each entity  defined in a sub-figure outputs a shape
  * Transformation Matrix.
  
**Note** that all non-millimeter  length unit values in the IGES file are converted to millimeters.
 
<h4><a id="occt_iges_2_2_2">Attributes</a></h4>
Entity attributes in the Directory Entry Section of the  IGES file (such as layers, colors and thickness) are translated to Open CASCADE  Technology using XDE. 
<h4><a id="occt_iges_2_2_3">Administrative data</a></h4>
Administrative data, in the Global Section of the IGES  file (such as the file name, the name of the author, the date and time a model  was created or last modified) is not translated to Open CASCADE Technology.  Administrative data can, however, be consulted in the IGES file. 


<h3><a id="occt_iges_2_3">Description of the process</a></h3>
<h4><a id="occt_iges_2_3_1">Loading the IGES file</a></h4>
Before performing any  other operation, you have to load the file using the syntax below. 
~~~~{.cpp}
IGESControl_Reader reader; 
IFSelect_ReturnStatus stat  = reader.ReadFile(“filename.igs”); 
~~~~
The loading operation  only loads the IGES file into computer memory; it does not translate it. 

<h4><a id="occt_iges_2_3_2">Checking the IGES file</a></h4>
This step is not obligatory.  Check the loaded file with:  
~~~~{.cpp}
Standard_Boolean ok =  reader.Check(Standard_True); 
~~~~
The variable “ok is  True” is returned if no fail message was found; “ok is False” is returned if  there was at least one fail message.  
~~~~{.cpp}
reader.PrintCheckLoad  (failsonly, mode); 
~~~~
Error messages are  displayed if there are invalid or incomplete IGES entities, giving you  information on the cause of the error.  
~~~~{.cpp}
Standard_Boolean failsonly  = Standard_True or Standard_False; 
~~~~
If you give True, you  will see fail messages only. If you give False, you will see both fail and  warning messages.  

Your analysis of the  file can be either message-oriented or entity-oriented. Choose your preference  with *IFSelect_PrintCount mode =  IFSelect_xxx*, where *xxx* can be any of  the following: 
* *ItemsByEntity*     gives a  sequential list of all messages per IGES entity.  
* *CountByItem*       gives the  number of IGES entities with their types per message.  
* *ShortByItem*       gives the number of IGES entities with their  types per message and displays rank numbers of the first five IGES entities per  message.  
* *ListByItem*        gives the number of IGES entities with their type  and rank numbers per message. 
* *EntitiesByItem*    gives the number of IGES entities with their  types, rank numbers and Directory Entry numbers per message. 

<h4><a id="occt_iges_2_3_3">Setting translation parameters</a></h4>
The following parameters can be used to translate an IGES  file to an OCCT shape. If you give a value that is not within the range of  possible values, it will be ignored. 

<h4>read.iges.bspline.continuity</h4>
manages the continuity of BSpline curves (IGES entities  106, 112 and 126) after translation to Open CASCADE Technology (Open CASCADE  Technology requires that the curves in a model be at least C1 continuous; no  such requirement is made by IGES).  
* 0:    no change; the curves are taken as they are  in the IGES file. C0 entities of Open CASCADE Technology may be produced.  
* 1:    if an IGES BSpline, Spline or CopiousData  curve is C0 continuous, it is broken down into pieces of C1 continuous *Geom_BSplineCurve*.  
* 2:    This option concerns IGES Spline curves only.  IGES Spline curves are broken down into pieces of C2 continuity. If C2 cannot  be ensured, the Spline curves will be broken down into pieces of C1 continuity.   

Read this parameter  with:  
~~~~{.cpp}
Standard_Integer ic =  Interface_Static::IVal("read.iges.bspline.continuity"); 
~~~~
Modify this value with:  
~~~~{.cpp}
if  (!Interface_Static::SetIVal ("read.iges.bspline.continuity",2))  
.. error ..; 
~~~~
Default value is 1. 

This parameter does not change the continuity of curves  that are used in the construction of IGES BRep entities. In this case, the  parameter does not influence the continuity of the resulting OCCT curves (it is  ignored). 


<h4>read.precision.mode</h4>
reads the precision  value.  
* File  (0)       the precision value is read in the IGES file header (default).  
* User  (1)     the precision value is that of the read.precision.val parameter.  

Read this parameter  with:  
~~~~{.cpp}
Standard_Integer ic =  Interface_Static::IVal("read.precision.mode"); 
~~~~
Modify this value with:  
~~~~{.cpp}
if  (!Interface_Static::SetIVal ("read.precision.mode",1))  
.. error ..; 
~~~~
Default value is  *File* (0).  

<h4>read.precision.val</h4>
User defined precision value. This parameter gives the precision for shape construction when the read.precision.mode parameter value is 1. By default it is 0.0001, but can be any real positive (non null) value.

This value is in the  measurement unit defined in the IGES file header.  

Read this parameter  with:  
~~~~{.cpp}
Standard_Real rp =  Interface_Static::RVal("read.precision.val"); 
~~~~
Modify this parameter  with:  
~~~~{.cpp}
if  (!Interface_Static::SetRVal ("read.precision.val",0.001))  
.. error ..; 
~~~~
Default value is 0.0001.   

The value given to  this parameter is a target value that is applied to *TopoDS_Vertex, TopoDS_Edge*  and *TopoDS_Face* entities. The processor does its best to reach it. Under  certain circumstances, the value you give may not be attached to all of the  entities concerned at the end of processing. IGES-to-OCCT translation does not  improve the quality of the geometry in the original IGES file. This means that  the value you enter may be impossible to attain the given quality of geometry  in the IGES file.

Value of tolerance used for computation is calculated by  multiplying the value of *read.precision.val* and the value of coefficient of  transfer from the file units to millimeters. 

<h4>read.maxprecision.mode</h4>
defines the mode of  applying the maximum allowed tolerance. Its possible values are:  

* *Preferred(0)*           maximum  tolerance is used as a limit but sometimes it can be exceeded (currently, only  for deviation of a 3D curve of an edge from its pcurves and from vertices of  such edge) to ensure shape validity; 
* *Forced(1)*              maximum  tolerance is used as a rigid limit, i.e. it can not be exceeded and, if this  happens, tolerance is trimmed to suit the maximum-allowable value.  

Read this parameter  with:  
~~~~{.cpp}
Standard_Integer mv =  Interface_Static::IVal("read.maxprecision.mode"); 
~~~~
Modify this parameter  with:  
~~~~{.cpp}
if  (!Interface_Static::SetIVal ("read.maxprecision.mode",1))  
.. error ..; 
~~~~
Default value is  *Preferred (0)*.  

<h4>read.maxprecision.val</h4>
defines the maximum  allowable tolerance (in internal units, which are specified in xstep.cascade.unit) of the shape.
It should be not less than the basis  value of tolerance set in processor (either Resolution from the file or  *read.precision.val*).
Actually, the maximum between *read.maxprecision.val* and  basis tolerance is used to define maximum allowed tolerance.  
Read this parameter  with:  
~~~~{.cpp}
Standard_Real rp =  Interface_Static::RVal("read.maxprecision.val"); 
~~~~
Modify this parameter with:  
~~~~{.cpp}
if  (!Interface_Static::SetRVal ("read.maxprecision.val",0.1))  
.. error ..; 
~~~~
Default value is 1.  

<h4>read.stdsameparameter.mode</h4>
defines the using of  *BRepLib\::SameParameter*. Its possible values are:  
* 0 (Off) -- *BRepLib\::SameParameter* is not called,  
* 1 (On) -- *BRepLib\::SameParameter* is called.  
*BRepLib\::SameParameter* is used through  *ShapeFix_Edge\::SameParameter*. It ensures that the resulting edge will have the  lowest tolerance taking pcurves either unmodified from the IGES file or  modified by *BRepLib\::SameParameter*.  
Read this parameter  with:  
~~~~{.cpp}
Standard_Integer mv =  Interface_Static::IVal("read.stdsameparameter.mode"); 
~~~~
Modify this parameter  with:  
~~~~{.cpp}
if  (!Interface_Static::SetIVal ("read.stdsameparameter.mode",1))  
.. error ..; 
~~~~
Default value is 0 (Off).  

<h4>read.surfacecurve.mode</h4>
preference for the  computation of curves in case of 2D/3D inconsistency in an entity which has  both 2D and 3D representations.  

Here we are talking  about entity types 141 (Boundary), 142 (CurveOnSurface) and 508 (Loop). These  are entities representing a contour lying on a surface, which is translated to  a *TopoDS_Wire*, formed by *TopoDS_Edges*. Each *TopoDS_Edge* must have a 3D curve  and a 2D curve that reference the surface.  

The processor also  decides to re-compute either the 3D or the 2D curve even if both curves are  translated successfully and seem to be correct, in case there is inconsistency  between them. The processor considers that there is inconsistency if any of the  following conditions is satisfied:  
  * the number of sub-curves in  the 2D curve is different from the number of sub-curves in the 3D curve. This  can be either due to different numbers of sub-curves given in the IGES file or  because of splitting of curves during translation. 
  * 3D or 2D curve is a Circular  Arc (entity type 100) starting and ending in the same point (note that this  case is incorrect according to the IGES standard).
  
The parameter  *read.surfacecurve.mode* defines which curve (3D or 2D) is used for re-computing  the other one:
* *Default(0)* use  the preference flag value in the entity's Parameter Data section. The flag  values are:  
  * 0: no preference given, 
  * 1: use 2D for 142 entities  and 3D for 141 entities, 
  * 2: use 3D for 142 entities  and 2D for 141 entities, 
  * 3: both representations are  equally preferred. 
* *2DUse_Preferred (2)* : the 2D is used to rebuild the 3D in case of their inconsistency,  
* *2DUse_Forced (-2)*: the 2D is always used to rebuild the 3D (even if 3D is present in the  file),  
* *3DUse_Preferred (3)*: the 3D is used to rebuild the 2D in case of their inconsistency,  
* *3DUse_Forced  (-3)*: the 3D is always used to rebuild the 2D (even if 2D is present in the  file),  

If no preference is  defined (if the value of *read.surfacecurve.mode* is *Default* and the  value of the preference flag in the entity's Parameter Data section is 0 or 3),  an additional analysis is performed. 
 
The 3D representation is  preferred to the 2D in two cases:  
  * if 3D and 2D contours in the  file have a different number of curves, 
  * if the 2D curve is a Circular  Arc (entity type 100) starting and ending in the same point and the 3D one is  not. 

In any other case, the  2D representation is preferred to the 3D.  

If either a 3D or a 2D  contour is absent in the file or cannot be translated, then it is re-computed  from another contour. If the translation of both 2D and 3D contours fails, the  whole curve (type 141 or 142) is not translated. If this curve is used for  trimming a face, the face will be translated without this trimming and will  have natural restrictions.  

Read this parameter  with:  
~~~~{.cpp}
Standard_Integer ic =  Interface_Static::IVal("read.surfacecurve.mode"); 
~~~~
Modify this value with:  
~~~~{.cpp}
if  (!Interface_Static::SetIVal ("read.surfacecurve.mode",3))  
.. error ..; 
~~~~
Default value is  Default (0). 

<h4>read.encoderegularity.angle</h4>
This parameter is used within the *BRepLib::EncodeRegularity()*  function which is called for a shape read from an IGES or a STEP file at the  end of translation process. This function sets the regularity flag of an edge  in a shell when this edge is shared by two faces. This flag shows the  continuity, which these two faces are connected with at that edge.  

Read this parameter  with:  
~~~~{.cpp}
Standard_Real era =   Interface_Static::RVal("read.encoderegularity.angle"); 
~~~~
Modify this parameter with:  
~~~~{.cpp}
if  (!Interface_Static::SetRVal ("read.encoderegularity.angle",0.1))   
.. error ..; 
~~~~
Default value is 0.01.  

<h4>read.iges.bspline.approxd1.mode</h4>
This parameter is obsolete (it is rarely used in real  practice). If set to True, it affects the translation of bspline curves of  degree 1 from IGES: these curves (which geometrically are polylines) are split  by duplicated points, and the translator attempts to convert each of the  obtained parts to a bspline of a higher continuity.  

Read this parameter with:  
~~~~{.cpp}
Standard_Real bam =   Interface_Static::CVal("read.iges.bspline.approxd1.mode"); 
~~~~
Modify this parameter with:  
~~~~{.cpp}
if  (!Interface_Static::SetRVal ("read.encoderegularity.angle","On"))   
.. error ..; 
~~~~
Default value is Off.  


<h4>read.iges.resource.name and read.iges.sequence</h4>
These two parameters define the name of the resource file  and the name of the sequence of operators   (defined in that file) for Shape Processing, which is automatically performed  by the IGES   translator. The Shape Processing is a user-configurable step, which is  performed after   the translation and consists in application of a set of operators to a  resulting shape. This is   a very powerful tool allowing to customize the shape and to adapt it to the  needs of   a receiving application. By default, the sequence consists of a single operator  *ShapeFix* that calls Shape Healing from the IGES translator.  

Find an example of the resource file for IGES (which  defines parameters corresponding to the sequence applied by default, i.e. if the resource file is  not found) in the Open CASCADE Technology sources by the path <i>%CASROOT%/src/XSTEPResource/IGES</i>. 

IGES translator will use that file if you define the environment variable *CSF_IGESDefaults*, which should point to the directory where the resource file  resides.   Note that if you change parameter *read.iges.resource.name*, you should change  the name of the resource file and the name of the environment variable correspondingly.  The variable should contain a path to the resource file. 

Default values:  
* read.iges.resource.name -- IGES,  
* read.iges.sequence -- FromIGES. 

<h4>xstep.cascade.unit</h4>
This parameter defines units to which a shape should be  converted when translated   from IGES or STEP to CASCADE. Normally it is MM; only those applications that   work internally in units other than MM should use this parameter.
  
Default value is MM. 

<h4><a id="occt_iges_2_3_4">Selecting entities</a></h4>

A list of entities can  be formed by invoking the method *IGESControl_Reader::GiveList*.
~~~~{.cpp}
Handle(TColStd_HSequenceOfTransient)  list = reader.GiveList(); 
~~~~
Several predefined  operators can be used to select a list of entities of a specific type. 
To make a selection, use the method *IGESControl_Reader::GiveList* with the selection type in  quotation marks as an argument. You can also make cumulative selections. For  example, you would use the following Syntax:
1. Requesting the faces in the  file: 
~~~~{.cpp}
faces =  Reader.GiveList("iges-faces"); 
~~~~
2. Requesting the visible roots  in the file: 
~~~~{.cpp}
visibles =  Reader.GiveList(iges-visible-roots); 
~~~~
3.  Requesting the visible faces:
~~~~{.cpp}
visfac =  Reader.GiveList(iges-visible-roots,faces); 
~~~~
Using a signature, you  can define a selection dynamically, filtering the string by means of a  criterion. When you request a selection using the method GiveList, you can give  either a predefined selection or a selection by signature. You make your selection  by signature using the predefined signature followed by your criterion in  parentheses as shown in the example below. The syntaxes given are equivalent to  each other. 
~~~~{.cpp}
faces =  Reader.GiveList(“xst-type(SurfaceOfRevolution)”); 
faces =  Reader.GiveList(“iges-type(120)”); 
~~~~
You can also look for: 
  * values returned by your  signature which match your criterion exactly
~~~~{.cpp}
faces =  Reader.GiveList(“xst-type(=SurfaceOfRevolution)”); 
~~~~
  * values returned by your  signature which do not contain your criterion
~~~~{.cpp}
faces = Reader.GiveList(“xst-type(!SurfaceOfRevolution)”); 
~~~~
  * values returned by your  signature which do not exactly match your criterion.
~~~~{.cpp}
faces =  Reader.GiveList(“xst-type(!=SurfaceOfRevolution)”); 
~~~~

<h4>List of predefined operators that can be used:</h4>
  * *xst-model-all* -- selects all entities. 
  * *xst-model-roots* -- selects all roots. 
  * *xst-transferrable-all* -- selects all translatable entities. 
  * *xst-transferrable-roots* -- selects all translatable roots (default). 
  * *xst-sharing + \<selection\>* -- selects all entities sharing at least one entity selected by  \<selection\>. 
  * *xst-shared + \<selection\>* -- selects all entities shared by at least one entity selected  by \<selection\>. 
  * *iges-visible-roots* -- selects all visible roots, whether translatable or not. 
  * *iges-visible-transf-roots* -- selects all visible and translatable roots. 
  * *iges-blanked-roots* -- selects all blank roots, whether translatable or not. 
  * *iges-blanked-transf-roots* -- selects all blank and translatable roots. 
  * *iges-status-independent* -- selects entities whose IGES Subordinate Status = 0.
  * *iges-bypass-group* -- selects all root entities. If a root entity is a group  (402/7 or 402/9), the entities in the group are selected. 
  * *iges-bypass-subfigure* -- selects all root entities. If a root entity is a subfigure  definition (308), the entities in the subfigure definition are selected. 
  * *iges-bypass-group-subfigure* -- selects all root entities. If a root entity is a group  (402/7 or 402/9) or a subfigure definition (308), the entities in the group and  in the subfigure definition are selected. 
  * *iges-curves-3d* -- selects 3D curves, whether they are roots or not (e.g. a 3D  curve on a surface). 
  * *iges-basic-geom* -- selects 3D curves and untrimmed surfaces. 
  * *iges-faces* -- selects face-supporting surfaces (trimmed or not). 
  * *iges-surfaces* -- selects surfaces not supporting faces (i.e. with natural  bounds). 
  * *iges-basic-curves-3d* -- selects the same entities as iges-curves-3d.  Composite Curves are broken down into their components and the components are  selected. 
  
<h4><a id="occt_iges_2_3_5">Performing the  IGES file translation</a></h4>
Perform translation  according to what you want to translate:  
1.  Translate an entity identified  by its rank with:  
~~~~{.cpp}
Standard_Boolean ok =  reader.Transfer (rank); 
~~~~
2.  Translate an entity  identified by its handle with: 
~~~~{.cpp}
Standard_Boolean ok =  reader.TransferEntity (ent); 
~~~~
3. Translate a list of entities  in one operation with:  
~~~~{.cpp}
Standard_Integer nbtrans =  reader.TransferList (list); 
reader.IsDone(); 
~~~~
where *nbtrans* returns the number of items  in the list that produced a shape and    *reader.IsDone()* indicates  whether at least one entity was translated. 
4. Translate a list of entities,  entity by entity: 
~~~~{.cpp}
Standard_Integer i,nb =  list-Length();  
for (i = 1; i  <= nb; i ++) {  
    Handle(Standard_Transient) ent = list-Value(i);  
    Standard_Boolean OK = reader.TransferEntity (ent);  
} 
~~~~
5.  Translate the whole file (all  entities or only visible entities) with:  
~~~~{.cpp}
Standard_Boolean  onlyvisible = Standard_True or Standard_False;  
reader.TransferRoots(onlyvisible) 
~~~~

<h4><a id="occt_iges_2_3_6">Getting the  translation results</a></h4>
Each successful  translation operation outputs one shape. A series of translations gives a  series of shapes.  
Each time you invoke  *TransferEntity, Transfer* or *Transferlist*, their results are accumulated and  NbShapes increases. You can clear the results (Clear function) between two  translation operations, if you do not do this, the results from the next  translation will be added to the accumulation. *TransferRoots* operations  automatically clear all existing results before they start.  
~~~~{.cpp}
Standard_Integer nbs =  reader.NbShapes(); 
~~~~
returns the number of  shapes recorded in the result.  
~~~~{.cpp}
TopoDS_Shape shape =  reader.Shape(num);, 
~~~~
returns the result *num*, where *num* is an integer between 1 and *NbShapes*.  
~~~~{.cpp}
TopoDS_Shape shape =  reader.Shape(); 
~~~~
returns the first result  in a translation operation.  
~~~~{.cpp}
TopoDS_Shape shape =  reader.OneShape(); 
~~~~
returns all results in a  single shape which is:  
  * a null shape if there are no  results, 
  * in case of a single result, a  shape that is specific to that result, 
  * a compound that lists the  results if there are several results. 
~~~~{.cpp}
reader.Clear(); 
~~~~
erases the existing  results.  
~~~~{.cpp}
reader.PrintTransferInfo  (failsonly, mode); 
~~~~
displays the messages  that appeared during the last invocation of *Transfer* or *TransferRoots*.  

If *failsonly* is  *IFSelect_FailOnly*, only fail messages will be output, if it is  *IFSelect_FailAndWarn*, all messages will be output. Parameter “mode” can have  *IFSelect_xxx* values where *xxx* can be:
  * *GeneralCount* -- gives general statistics  on the transfer (number of translated IGES entities, number of fails and  warnings, etc)  
  * *CountByItem* -- gives the number of IGES  entities with their types per message. 
  * *ListByItem* -- gives the number of IGES  entities with their type and DE numbers per message.  
  * *ResultCount*  -- gives the number of  resulting OCCT shapes per type.  
  * *Mapping* -- gives mapping between  roots of the IGES file and the resulting OCCT shape per IGES and OCCT type.
 
<h3><a id="occt_iges_2_4">Mapping of IGES  entities to Open CASCADE Technology shapes</a></h3>

*NOTE* that IGES entity types  that are not given in the following tables are not translatable. 

<h4><a id="occt_iges_2_4_1">Points</a></h4>

| IGES entity type | CASCADE shape  | Comments |
| :---------------- | :------------- | --------- |
| 116: Point     | TopoDS_Vertex  | |

<h4><a id="occt_iges_2_4_2">Curves</a></h4>
Curves, which form the 2D of face boundaries, are translated  as *Geom2D_Curves* (Geom2D circles, etc.). 

| IGES entity type | CASCADE shape | Comments |
| :---------------- | :------------ | :------- |
| 100: Circular Arc | TopoDS_Edge | The geometrical support is a *Geom_Circle* or a *Geom_TrimmedCurve* (if the arc is not closed). |
| 102: Composite Curve  | TopoDS_Wire | The resulting shape is always a *TopoDS_Wire* that is built from a set of *TopoDS_Edges*. Each *TopoDS_Edge* is connected to the preceding and to the following edge by a common *TopoDS_Vertex*. |
| 104: Conic Arc | TopoDS_Edge | The geometric support depends on whether the IGES entity's form is 0 (*Geom_Circle*), 1 (*Geom_Ellipse*), 2 (*Geom_Hyperbola*), or 3 (*Geom_Parabola*). A *Geom_TrimmedCurve* is output if the arc is not closed. |
| 106: Copious Data | TopoDS_Edge or TopoDS_Wire | IGES entity Copious Data (type 106, forms 1-3) is translated just as the IGES entities Linear Path (106/11-13) and the Simple Closed Planar Curve (106/63). Vectors applying to forms other than 11,12 or 63 are ignored. The *Geom_BSplineCurve* (geometrical support) has C0 continuity. If the Copious Data has vectors (DataType = 3) they will be ignored. |
| 110: Line | TopoDS_Edge | The supporting curve is a *Geom_TrimmedCurve* whose basis curve is a *Geom_Line*. |
| 112: Parametric Spline Curve | TopoDS_Edge or TopoDS_Wire | The geometric support is a Geom_BsplineCurve. |
| 126: BSpline Curve | TopoDS_Edge or TopoDS_Wire | |
| 130: Offset Curve | TopoDS_Edge or TopoDS_Wire | The resulting shape is a *TopoDS_Edge* or a *TopoDS_Wire* (depending on the translation of the basis curve) whose geometrical support is a *Geom_OffsetCurve* built from a basis *Geom_Curve*. Limitation: The IGES Offset Type value must be 1. |
| 141: Boundary | TopoDS_Wire | Same behavior as for the Curve On Surface (see below). The translation of a non-referenced Boundary IGES entity in a *BoundedSurface* IGES entity outputs a *TopoDS_Edge* or a *TopoDS_Wire* with a *Geom_Curve*. |
| 142: Curve On Surface | TopoDS_Wire | Each *TopoDS_Edge* is defined by a 3D curve and by a 2D curve that references the surface. |

The type of OCCT shapes (either *TopDS_Edges* or  *TopoDS_Wires*) that result from the translation of IGES entities 106, 112 and  126 depends on the continuity of the curve in the IGES file and the value of  the *read.iges.bspline.continuity* translation parameter. 

<h4><a id="occt_iges_2_4_3">Surfaces</a></h4>
Translation of a surface outputs either a *TopoDS_Face* or a  *TopoDS_Shell*.  
If a *TopoDS_Face* is output, its geometrical support is a  *Geom_Surface* and its outer and inner boundaries (if it has any) are  *TopoDS_Wires*. 

| IGES entity type | CASCADE shape | Comments |
| :--------------  | :------------ | :--------- |
| 108: Plane |  TopoDS_Face |  The geometrical support for the *TopoDS_Face* is a *Geom_Plane* and the orientation of its *TopoDS_Wire* depends on whether it is an outer *TopoDS_Wire* or whether it is a hole. |
| 114: Parametric Spline Surface | TopoDS_Face | The geometrical support of a *TopoDS_Face* is a *Geom_BSplineSurface*. |
| 118: Ruled Surface | TopoDS_Face or TopoDS_Shell | The translation of a Ruled Surface outputs a *TopoDS_Face* if the profile curves become *TopoDS_Edges*, or a *TopoDS_Shell* if the profile curves become *TopoDS_Wires*. Limitation: This translation cannot be completed when these two *TopoDS_Wires* are oriented in different directions.  |
| 120: Surface Of Revolution | TopoDS_Face or TopoDS_Shell | The translation of a Surface Of Revolution outputs: a *TopoDS_Face* if the generatrix becomes a *TopoDS_Edge*, a *TopoDS_Shell* if the generatrix becomes a *TopoDS_Wire*. The geometrical support may be: *Geom_CylindricalSurface, Geom_ConicalSurface, Geom_SphericalSurface, Geom_ToroidalSurface* or a *Geom_SurfaceOfRevolution* depending on the result of the CASCADE computation (based on the generatrix type). | 
| 122: Tabulated Cylinder | TopoDS_Face or TopoDS_Shell | The translation outputs a *TopoDS_Face* if the base becomes a *TopoDS_Edge* or a *TopoDS_Shell* if the base becomes a *TopoDS_Wire*. The geometrical support may be *Geom_Plane, Geom_Cylindrical Surface* or a *Geom_SurfaceOfLinearExtrusion* depending on the result of the CASCADE computation (based on the generatrix type). The *Geom_Surface* geometrical support is limited according to the generatrix. |
| 128: BSpline Surface | TopoDS_Face | The geometrical support of the *TopoDS_Face* is a *Geom_BsplineSurface*. |
| 140: Offset Surface | TopoDS_Face | The translation of an Offset Surface outputs a *TopoDS_Face* whose geometrical support is a *Geom_OffsetSurface*. Limitations: For OCCT algorithms, the original surface must be C1-continuous so that the *Geom_OffsetSurface* can be created. If the basis surface is not C1-continuous, its translation outputs a *TopoDS_Shell* and only the first *TopoDS_Face* in the *TopoDS_Shell* is offset. |
| 143: Bounded Surface | TopoDS_Face or TopoDS_Shell | If the basis surface outputs a *TopoDS_Shell* (that has more than one *TopoDS_Face*), the IGES boundaries are not translated. Limitations: If the bounding curves define holes, natural bounds are not created. If the orientation of the contours is wrong, it is not corrected. |
| 144: Trimmed Surface | TopoDS_Face or TopoDS_Shell | For the needs of interface processing, the basis surface must be a face. Shells are only processed if they are single-face. The contours (wires that are correctly oriented according to the definition of the IGES 142: Curve On Surface entity) are added to the face that is already created. If the orientation of the contours is wrong, it is corrected. |
| 190: Plane Surface | TopoDS_Face | This type of IGES entity can only be used in BRep entities in place of an IGES 108 type entity. The geometrical support of the face is a *Geom_Plane*. | 


<h4><a id="occt_iges_2_4_4">Boundary Representation  Solid Entities</a></h4>

| IGES entity type | CASCADE shape | Comments |
| :---------------- | :------------ | :------- |
| 186: ManifoldSolid | TopoDS_Solid | |
| 514: Shell | TopoDS_Shell | |
| 510: Face | TopoDS_Face | This is the lowest IGES entity in the BRep structure that can be specified as a starting point for translation. |
| 508: Loop | TopoDS_Wire | | 
| 504: Edge List | | |
| 502: Vertex List | | | 


<h4><a id="occt_iges_2_4_5">Structure Entities</a></h4>

| IGES entity type | CASCADE shape | Comments | 
| :---------------- | :------------ | :------- |
| 402/1: Associativity Instance: Group with back pointers |  TopoDS_Compound | |
| 402/7: Associativity Instance: Group without back pointers | TopoDS_Compound | |
| 402/9: Associativity Instance: Single Parent | TopoDS_Face | The translation of a *SingleParent* entity is only performed for 402 form 9 with entities 108/1 and 108/-1. The geometrical support for the *TopoDS_Face* is a *Geom_Plane* with boundaries: the parent plane defines the outer boundary; the child planes define the inner boundaries. |

<h4><a id="occt_iges_2_4_6">Subfigures</a></h4>

| IGES entity type | CASCADE shape | Comments |
| :---------------- | :------------ | :------- |
| 308: Subfigure Definition | TopoDS_Compound | This IGES entity is only translated when there are no Singular Subfigure Instance entities. |
| 408: Singular Subfigure Instance | TopoDS_Compound | This shape has the Subfigure Definition Compound as its origin and is positioned in space by its translation vector and its scale factor. |

<h4><a id="occt_iges_2_4_7">Transformation Matrix  </a></h4>

| IGES entity type | CASCADE shape | Comments |
| :---------------  | :------------ | :------- |
| 124: Transformation Matrix | Geom_Transformation | This entity is never translated alone. It must be included in the definition of another entity. |


<h3><a id="occt_iges_2_5">Messages</a></h3>
Messages are displayed concerning the normal functioning of  the processor (transfer, loading, etc.).  
You must declare an include file: 
~~~~{.cpp}
#include \<Interface_DT.hxx\> 
~~~~

You have the choice of the following options for messages: 
~~~~{.cpp}
IDT_SetLevel (level); 
~~~~
level modifies the level of messages: 
  * 0: no messages
  * 1: raise and fail messages are displayed, as are messages  concerning file access,
  * 2: warnings are also displayed.
~~~~{.cpp}
IDT_SetFile (“tracefile.log”); 
~~~~
prints the messages in a file, 
~~~~{.cpp}
IDT_SetStandard(); 
~~~~
restores screen output. 

<h3><a id="occt_iges_2_6">Tolerance management</a></h3>
<h4><a id="occt_iges_2_6_1">Values used for tolerances during reading IGES</a></h4>

During the transfer of IGES to Open CASCADE Technology  several parameters are used as tolerances and precisions for different  algorithms. Some of them are computed from other using specific functions. 

<h4>3D (spatial) tolerances</h4>

* Package method  *Precision\::Confusion* equal to 10<sup>-7</sup> is used as a minimal  distance between points, which are considered distinct. 
* Resolution in the IGES  file is defined in the Global section of an IGES  file. It is used as a fundamental value of precision during the transfer. 
* User-defined variable  *read.precision.val* can be used instead of resolution from the file when  parameter *read.precision.mode* is set to 1 ("User"). 
* Field *EpsGeom*  of the  class *IGESToBRep_CurveAndSurface* is a basic precision for translating an IGES  object. It is set for each object of class *IGESToBRep_CurveAndSurface* and its  derived classes. It is initialized for the root of transfer either by value of  resolution from the file or by value of *read.precision.val*, depending on  the value of *read.precision.mode* parameter. It is returned by call to method  *IGESToBRep_CurvAndSurface::GetEpsGeom*.  As this value belongs to measurement units of the IGES  file, it is usually multiplied by the coefficient *UnitFactor* (returned by  method *IGESToBRep_CurvAndSurface::GetUnitFactor*) to convert it to Open CASCADE  Technology units. 
* Field *MaxTol* of the class *IGESToBRep_CurveAndSurface* is used as the maximum tolerance for some  algorithms. Currently, it is computed as the maximum between 1 and  *GetEpsGeom* \* *GetUnitFactor*. This field is returned by method  *IGESToBRep_CurvAndSurface::GetMaxTol*.
 
<h4>2D (parametric) tolerances</h4>

* Package method  *Precision\::PConfusion* equal to <i> 0.01*Precision\::Confusion</i>, i.e. 10<sup>-9</sup>.  It is used to compare parametric bounds of curves. 
* Field *EpsCoeff* of the  class *IGESToBRep_CurveAndSurface* is a parametric precision for translating an IGES  object. It is set for each object of class *IGESToBRep_CurveAndSurface* and its  derived classes. Currently, it always has its default value 10<sup>-6</sup>. It  is returned by call to method *IGESToBRep_CurvAndSurface::GetEpsCoeff*.  This value is used for translating 2d objects (for instance, parametric  curves). 
* Methods  *UResolution(tolerance3d)* and *VResolution(tolerance3d)* of the class  *GeomAdaptor_Surface* or *BRepAdaptor_Surface* return tolerance in parametric space of a surface computed  from 3D tolerance. When one tolerance value is to be used for both U and V  parametric directions, the maximum or the minimum value of *UResolution* and  *VResolution* is used.
* Methods *Resolution(tolerance3d)* of the class *GeomAdaptor_Curve* or *BRepAdaptor_Curve* return tolerance in the parametric space of a curve computed  from 3d tolerance. 

<h4>Zero-dimensional tolerances</h4>
* Field *Epsilon* of the  class *IGESToBRep_CurveAndSurface* is set for each object of class *IGESToBRep_CurveAndSurface* and returned by call to method *GetEpsilon*. It is used in comparing angles  and converting transformation matrices. In most cases, it is reset to a fixed  value (10<sup>-5</sup> - 10<sup>-3</sup>) right before use. The default value is 10<sup>-4</sup>.
 
<h4><a id="occt_iges_2_6_2">Initial setting of tolerances in translating  objects</a></h4>

Transfer starts from one entity treated as a root (either  the actual root in the IGES file or an entity selected by the user). The  function which performs the transfer (that is *IGESToBRep_Actor::Transfer* or *IGESToBRep_Reader::Transfer*) creates an object of the type  *IGESToBRep_CurveAndSurface*, which is intended for translating geometry. 

This object contains three tolerances: *Epsilon, EpsGeom* and  *EpsCoeff*. 

Parameter *Epsilon* is set by default to value 10<sup>-4</sup>. In most cases  when it is used in the package *IGESToBRep*, it is reset to a fixed value, either  10<sup>-5</sup> or 10<sup>-4</sup> or 10<sup>-3</sup>. It is used as  precision when comparing angles and transformation matrices and does not have  influence on the tolerance of the resulting shape. 

Parameter *EpsGeom* is set right after creating a  *IGESToBRep_CurveAndSurface* object to the value of resolution, taken either from  the Global section of an IGES file, or from the *XSTEP.readprecision.val*  parameter, depending on the value of *XSTEP.readprecision.mode*.
 
Parameter *EpsCoeff* is set by default to 10<sup>-6</sup> and  is not changed. 

During the transfer of a shape, new objects of type  *IGESToBRep_CurveAndSurface* are created for translating subshapes. All of them  have the same tolerances as the root object. 

<h4><a id="occt_iges_2_6_3">Transfer process</a></h4>
<h4>Translating into Geometry</h4>
Geometrical entities are translated by classes  *IGESToBRep_BasicCurve* and *IGESToBRep_BasicSurface*. Methods of these classes  convert curves and surfaces of an IGES file to Open CASCADE Technology geometry  objects: *Geom_Curve,  Geom_Surface,*  and *Geom_Transformation*.
 
Since these objects are not BRep objects, they do not have  tolerances. Hence, tolerance parameters are used in these classes only as  precisions: to detect specific cases (e.g., to distinguish a circle, an  ellipse, a parabola and a hyperbola) and to detect bad cases (such as  coincident points). 

Use of precision parameters is reflected in the following  classes: 
* *IGESToBRep_BasicCurve* -- all parameters and points are compared with precision *EpsGeom*. All transformations (except *IGESToBRep_BasicCurve::TransferTransformation*)  are fulfilled with precision *Epsilon* which is set to 10<sup>-3</sup> (in the *IGESToBRep_BasicCurve::TransferTransformation* the value 10<sup>-5</sup> is  used). 
* *IGESToBRep_BasicCurve::TransferBSplineCurve* -- all weights of *BSplineCurve* are assumed to be more than *Precision::PConfusion* (else the curve is not translated). 
* *IGESToBRep_BasicSurface* -- all parameters and points are compared with precision *EpsGeom*. All transformations are fulfilled with precision *Epsilon*,  which is set to 10<sup>-3</sup>. 
* *IGESToBRep_BasicSurface::TransferBSplineSurface* -- all weights of *BSplineSurface* are assumed to be more than  *Precision::PConfusion* (else the surface is not translated). 


<h4>Translating into Topology</h4>

IGES entities represented as topological shapes and  geometrical objects are translated into OCCT shapes by use of the classes *IGESToBRep_TopoCurve,  IGESToBRep_TopoSurface,  IGESToBRep_BRepEntity* and *ShapeFix_Wire*. 

Class *IGESToBRep_BRepEntity* is intended for transferring  BRep entities (IGES version is 5.1 or greater)  while the two former are used for translating geometry and topology defined in IGES versions prior to 5.1. Methods from *IGESToBRep_BRepEntity* call methods from  *IGESToBRep_TopoCurve* and *IGESToBRep_TopoSurface*, while those call methods from *IGESToBRep_BasicCurve* and *IGESToBRep_BasicSurface* to translate IGES  geometry into OCCT geometry. 

Although the IGES file contains only one parameter for  tolerance in the Global Section, OCCT shapes are produced with different  tolerances. As a rule, updating the tolerance is fulfilled according to local  distances between shapes (distance between vertices of adjacent edges,  deviation of edge’s 3D curve and its parametric curve and so on) and may be  less or greater than precision in the file. 

The following classes show what default tolerances are used  when creating shapes and how they are updated during transfer. 

<h5>Class  IGESToBRep_TopoCurve</h5>

All  methods are in charge of transferring curves  from IGES curve entities <i>(TransferCompositeCurve, Transfer2dCompositeCurve,  TransferCurveOnFace, TransferBoundaryOnFace, TransferOffsetCurve,  TransferTopoBasicCurve)</i> if an entity has transformation call to *IGESData_ToolLocation::ConvertLocation* with *Epsilon* value set to 10<sup>-4</sup>. 
  * *IGESToBRep_TopoCurve::TransferPoint* -- vertex is constructed from a Point entity with tolerance *EpsGeom*UnitFactor*. 
  * *IGESToBRep_TopoCurve::Transfer2dPoint* -- vertex is constructed from a Point entity with tolerance *EpsCoeff*. 
  * *IGESToBRep_TopoCurve::TransferCompositeCurveGeneral* -- obtains shapes (edges or wires) from other methods and adds  them into the resulting wire. Two adjacent edges of the wire can be connected  with tolerance up to *MaxTol*. 
  * *IGESToBRep_TopoCurve::TransferCurveOnFace* and  *IGESToBRep_TopoCurve::TransferBoundaryOnFace* build a wire from 3D and 2D representations of  a curve on surface. Edges and vertices of the wire cannot have tolerance larger than *MaxTol*. The value *EpsGeom*UnitFactor* is passed into *ShapeFix_Wire::SetPrecision* and *MaxTol* is passed into *ShapeFix_Wire::MaxTolerance*. To find out how these parameters affect the resulting tolerance changes, refer to class *ShapeFix_Wire*. 
  * *IGESToBRep_TopoCurve::TransferTopoBasicCurve* and  *IGESToBRep_TopoCurve::Transfer2dTopoBasicCurve* -- the boundary vertices of an edge (or a wire if a curve was  of C0 continuity) translated from a basis IGES curve (*BSplineCurve,  CopiousData, Line,* etc.) are built with tolerance *EpsGeom*UnitFactor*, the edge tolerance is *Precision::Confusion*. If a curve was divided into several edges, the common  vertices of such adjacent edges have tolerance *Precision::Confusion*.
  
  
<h5>Class  IGESToBRep_TopoSurface</h5>

All faces created by this class have tolerance  *Precision::Confusion*.

<h5>Class  IGESToBRep_BRepEntity</h5>

  * *IGESToBRep_BRepEntity::TransferVertex* -- the vertices from the *VertexList* entity are constructed with  tolerance *EpsGeom*UnitFactor*. 
  * *IGESToBRep_BRepEntity::TransferEdge* -- the edges from the *EdgeList* entity are constructed with  tolerance *Precision::Confusion*.
  * *IGESToBRep_BRepEntity::TransferLoop* -- this function works like  *IGESToBRep_TopoCurve::TransferCurveOnFace* and *IGESToBRep_TopoCurve::TransferBoundaryOnFace*. 
  * *IGESToBRep_BRepEntity::TransferFace* -- the face from the *Face* IGES entity is constructed with  tolerance *Precision::Confusion*.
  
<h5>Shape Healing classes</h5>
After performing a simple mapping, shape-healing algorithms  are called (class *ShapeFix_Shape*) by *IGESToBRep_Actor::Transfer()*. Shape-healing algorithm performs the correction of the resulting OCCT shape.  
Class *ShapeFix_Wire* can increase the tolerance of a shape.  This class is used in *IGESToBRep_BRepEntity::TransferLoop*, *IGESToBRep_TopoCurve::TransferBoundaryOnFace*  and *IGESToBRep_TopoCurve::TransferCurveOnFace* for correcting a wire. The  maximum possible tolerance applied to the edges or vertices after invoking the  methods of this class is *MaxTolerance* (set by method *ShapeFix_Wire::MaxTolerance()* ). 

<h3><a id="occt_iges_2_7">Code architecture</a></h3>

The following diagram illustrates the structure of calls in  reading IGES. 
The highlighted classes produce OCCT geometry. 

<img src="images/iges_image003.png" alt="The structure of calls in reading IGES" width="420">

<h3><a id="occt_iges_2_8">Example</a></h3>

~~~~{.cpp}
#include “IGESControl_Reader.hxx” 
#include “TColStd_HSequenceOfTransient.hxx” 
#include “TopoDS_Shape.hxx” 
{ 
IGESControl_Reader myIgesReader; 
Standard_Integer nIgesFaces,nTransFaces; 

myIgesReader.ReadFile (“MyFile.igs”); 
//loads file MyFile.igs 

Handle(TColStd_HSequenceOfTransient) myList =  myIgesReader.GiveList(“iges-faces”); 
//selects all IGES faces in the file and puts them into a list  called //MyList, 

nIgesFaces = myList-Length();  
nTransFaces = myIgesReader.TransferList(myList); 
//translates MyList, 

cout<<"IGES Faces: "<<nIgesFaces<<"   Transferred:"<<nTransFaces<<endl; 
TopoDS_Shape sh = myIgesReader.OneShape(); 
//and obtains the results in an OCCT shape. 
} 
~~~~

<h2><a id="occt_iges_3">Writing IGES</a></h2>
<h3><a id="occt_iges_3_1">Procedure</a></h3>

You can translate OCCT shapes to IGES entities in the  following steps: 
1. Initialize  the process. 
2. Set  the translation parameters, 
3. Perform  the model translation, 
4. Write  the output IGES file. 

You can translate several shapes before writing a file. Each  shape will be a root entity in the IGES model. 

<h3><a id="occt_iges_3_2">Domain covered</a></h3>
There are two families of OCCT objects that can be  translated: 
  * geometrical,
  * topological.
  
<h3><a id="occt_iges_3_3">Description of the process</a></h3>
<h4><a id="occt_iges_3_3_1">Initializing the process</a></h4>

Choose the unit and the mode you want to use to write the  output file as follows: 
* *IGESControl_Controller::Init* performs standard initialization. Returns False if an error  occurred. 
* *IGESControl_Writer writer* uses the default unit (millimeters) and the default write  mode (Face). 
* *IGESControl_Writer writer (UNIT)* uses the Face write mode and any of the units that are  accepted by IGES.  
* *IGESControl_Writer writer (UNIT,modecr)* uses the unit (accepted by IGES) and the write mode of your  choice. 
  *  0: Faces,
  *  1: BRep
The result is an *IGESControl_Writer* object. 

<h4><a id="occt_iges_3_3_2">Setting the translation parameters </a></h4>

The following parameters are used for the OCCT-to-IGES  translation. 

* *write.iges.brep.mode:* allows choosing the  write mode:  
 * "Faces" (0): OCCT *TopoDS_Faces* will be translated into IGES 144 (Trimmed Surface) entities, no BRep entities  will be written to the IGES file,  
 * "BRep" (1): OCCT *TopoDS_Faces*  will be translated into IGES 510 (Face) entities, the IGES file will contain  BRep entities.  
Read this parameter  with:  
~~~~{.cpp}
Standard_Integer byvalue =  Interface_Static::IVal("write.iges.brep.mode"); 
~~~~
Modify this parameter  with:  
~~~~{.cpp}
Interface_Static::SetIVal  ("write.iges.brep.mode", 1); 
~~~~
Default value is "Faces" (0).  
* *write.convertsurface.mode* when writing to IGES in the BRep mode, this parameter indicates whether elementary surfaces (cylindrical, conical,  spherical,   and toroidal) are converted into corresponding IGES 5.3 entities (if  the value of a parameter value is On), or written as surfaces of revolution (by default). 
* *write.iges.unit:* allows choosing the unit. The default unit for Open CASCADE Technology is "MM" (millimeter). You can  choose to write a file into any unit accepted by IGES.  
 * Read this parameter  with *Standard_String byvalue =  Interface_Static::CVal("write.iges.unit")*; 
 * Modify this parameter  with *Interface_Static::SetCVal ("write.iges.unit", "INCH");* 
* *write.iges.header.author:* gives the name of the  author of the file. The default value is the system name of the user.
 * Read this parameter  with  *Standard_String byvalue =  Interface_Static::CVal("write.iges.header.author")*; 
 * Modify this value with  *Interface_Static::SetCVal  ("write.iges.header.author", "name")*; 
* *write.iges.header.company:* gives the name of the  sending company.  The default value is  "" (empty).
 * Read this parameter  with *Standard_String byvalue =  Interface_Static::CVal("write.iges.header.company");*
 * Modify this value with *Interface_Static::SetCVal ("write.iges.header.company", "Open CASCADE");* 
* *write.iges.header.product:* gives the name of the  sending product. The default value is  "CAS.CADE IGES processor Vx.x", where *x.x* means the current version of  Open CASCADE Technology.  
 * Read this parameter  with *Standard_String byvalue =  Interface_Static::CVal("write.iges.header.product")*; 
 * Modify this value with *Interface_Static::SetCVal  ("write.iges.header.product", "product name")*; 
* *write.iges.header.receiver:* -- gives the name of the  receiving company.  The default value is  "" (empty).
 * Read this parameter  with *Standard_String byvalue =  Interface_Static::CVal("write.iges.header.receiver");* 
 * Modify this value with *Interface_Static::SetCVal  ("write.iges.header.receiver", "receiver name");*
* *write.precision.mode:* specifies the mode of  writing the resolution value into the IGES file.  
 * "Least" (-1):       resolution value is  set to the minimum tolerance of all edges and all vertices in an OCCT shape.  
 * "Average" (0):    resolution value is  set to average between the average tolerance of all edges and the average  tolerance of all vertices in an OCCT shape. This is the default value.  
 * "Greatest" (1):   resolution value is  set to the maximum tolerance of all edges and all vertices in an OCCT shape.  
 * "Session" (2):    resolution  value is that of the write.precision.val parameter.  
 
 * Read this parameter  with <i>Standard_Integer ic =  Interface_Static::IVal("write.precision.mode");</i> 
 * Modify this parameter  with <i>if  (!Interface_Static\::SetIVal("write.precision.mode",1))  .. error .. </i>
* *write.precision.val:* is the user precision value.  This parameter gives the resolution value for an IGES file when the  *write.precision.mode* parameter value is 1.  It is equal to 0.0001 by default, but can take any real positive (non null) value.  

Read this parameter  with:  
~~~~{.cpp}
Standard_Real rp =  Interface_Static::RVal(;write.precision.val;); 
~~~~
Modify this parameter  with:  
~~~~{.cpp}
if  (!Interface_Static::SetRVal(;write.precision.val;,0.01))  
.. error .. 
~~~~
Default value is 0.0001. 

<h4>write.iges.resource.name</h4> and <h4>write.iges.sequence</h4> are the same as the corresponding read.iges.\* parameters. Note that the  default sequence for writing contains *DirectFaces* operator, which converts elementary surfaces based on left-hand axes (valid in CASCADE) to right-hand axes (which are valid only in IGES). 

Default values : 
~~~~{.cpp}
write.iges.resource.name - IGES,
write.iges.sequence - ToIGES. 
~~~~

<h4><a id="occt_iges_3_3_3">Performing the Open  CASCADE Technology shape translation</a></h4>

You can perform the  translation in one or several operations. Here is how you translate topological  and geometrical objects:  
~~~~{.cpp}
Standard_Boolean ok =  writer.AddShape (TopoDS_Shape); 
~~~~
*ok* is True if translation was correctly performed and False if there was at least one entity that was not translated.  
~~~~{.cpp}
Standard_Boolean ok =  writer.AddGeom (geom); 
~~~~
where *geom* is *Handle(Geom_Curve)* or *Handle(Geom_Surface)*;  
*ok* is True if the  translation was correctly performed and False if there was at least one entity  whose geometry was not among the allowed types. 

<h4><a id="occt_iges_3_3_4">Writing the IGES  file</a></h4>
Write the IGES file  with:  
~~~~{.cpp}
Standard_Boolean ok =  writer.Write ("filename.igs"); 
~~~~
to give the file name.  
~~~~{.cpp}
Standard_Boolean ok =  writer.Write (S); 
~~~~
where *S* is *Standard_OStream*  
*ok* is True if the  operation was correctly performed and False if an error occurred (for instance,  if the processor could not create the file). 

<h3><a id="occt_iges_3_4">Mapping Open CASCADE  Technology shapes to IGES entities</a></h3>

Translated objects depend on the write mode that you chose.  If you chose the Face mode, all of the shapes are translated, but the level of  topological entities becomes lower (geometrical one). If you chose the BRep  mode, topological OCCT shapes become topological IGES entities. 

<h4><a id="occt_iges_3_4_1">Curves</a></h4>

| CASCADE shape | IGES entity type | Comments |
| :------------ | :---------------- | :------- | 
| Geom_BsplineCurve | 126: BSpline Curve | |
| Geom_BezierCurve | 126: BSpline Curve | |
| Geom_TrimmedCurve | All types of translatable IGES curves | The type of entity output depends on the type of the basis curve. If the curve is not trimmed, limiting points will be defined by the CASCADE RealLast value. |
| Geom_Circle | 100: Circular Arc or 126: BSpline Curve | A BSpline Curve is output if the *Geom_Circle* is closed |
| Geom_Ellipse | 104: Conic Arc or 126: BSpline Curve | A Conic Arc has Form 1. A BSpline Curve is output if the *Geom_Ellipse* is closed. |
| Geom_Hyperbola | 104: Conic Arc | Form 2 |
| Geom_Parabola | 104: Conic Arc | Form 3 | 
| Geom_Line | 110: Line | |
| Geom_OffsetCurve | 130: Offset Curve | |

<h4><a id="occt_iges_3_4_2">Surfaces</a></h4>

| CASCADE shapes | IGES entity type | Comments |
| :------------- | :--------------- | :------- |
| Geom_BSplineSurface | 128: BSpline Surface | |
| Geom_BezierSurface | 128: BSpline Surface | |
| Geom_RectangularTrimmedSurface | All types of translatable IGES surfaces. | The type of entity output depends on the type of the basis surface. If the surface is not trimmed and has infinite edges/sides, the coordinates of the sides in IGES will be limited to the CASCADE *RealLast* value. |
| Geom_Plane | 128: BSpline Surface or 190: Plane Surface | A BSpline Surface (of degree 1 in U and V) is output if you are working in the face mode. A Plane Surface is output if you are working in the BRep mode. |
| Geom_CylindricalSurface | 120: Surface Of Revolution | |
| Geom_ConicalSurface | 120: Surface Of Revolution | | 
| Geom_SphericalSurface | 120: Surface Of Revolution | |
| Geom_ToroidalSurface | 120: Surface Of Revolution | |
| Geom_SurfaceOfLinearExtrusion | 122: Tabulated Cylinder | |
| Geom_SurfaceOfRevolution | 120: Surface Of Revolution | |
| Geom_OffsetSurface | 140: Offset Surface | |

<h4><a id="occt_iges_3_4_3">Topological entities -- Translation in Face mode</a></h4>

| CASCADE shapes | IGES entity type | Comments |
| :------------- | :--------------- | :------- |
| Single TopoDS_Vertex | 116: 3D Point | |
| TopoDS_Vertex in a TopoDS_Edge | No equivalent | Not transferred. |
| TopoDS_Edge | All types of translatable IGES curves | The output IGES curve will be the one that corresponds to the Open CASCADE Technology definition. |
| Single TopoDS_Wire | 102: Composite Curve | Each *TopoDS_Edge* in the *TopoDS_Wire* results in a curve. |
| TopoDS_Wire in a TopoDS_Face | 142: Curve On Surface | Both curves (3D and pcurve) are transferred if they are defined and result in a simple curve or a composite curve depending on whether there is one or more edges in the wire.Note: if the basis surface is a plane (108), only the 3D curve is used. |
| TopoDS_Face | 144: Trimmed Surface | |
| TopoDS_Shell | 402: Form 1 Group or no equivalent | Group is created only if *TopoDS_Shell* contains more than one *TopoDS_Face*. The IGES group contains Trimmed Surfaces. |
| TopoDS_Solid | 402: Form 1 Group or no equivalent | Group is created only if *TopoDS_Solid* contains more than one *TopoDS_Shell*. One IGES entity is created per *TopoDS_Shell*. |
| TopoDS_CompSolid | 402: Form 1 Group or no equivalent | Group is created only if *TopoDS_CompSolid* contains more than one *TopoDS_Solid*. One IGES entity is created per *TopoDS_Solid*. |
| TopoDS_Compound | 402: Form 1 Group or no equivalent | Group is created only if *TopoDS_Compound* contains more than one item. One IGES entity is created per *TopoDS_Shape* in the *TopoDS_Compound*. If *TopoDS_Compound* is nested into another *TopoDS_Compound*, it is not mapped. |

<h4><a id="occt_iges_3_4_4">Topological entities -- Translation in BRep mode</a></h4>

| CASCADE shapes | IGES entity type | Comments |
| :------------- | :--------------- | :------- |
| Single TopoDS_Vertex | No equivalent | Not transferred. |
| TopoDS_Vertex in a TopoDS_Edge | One item in a 502: *VertexList* | | 
| TopoDS_Edge | No equivalent | Not transferred as such. This entity serves as a part of a Loop entity. |
| TopoDS_Edge in a TopoDS_Wire | One item in a 504: EdgeList | |
| TopoDS_Wire | 508: Loop | |
| TopoDS_Face | 510: Face | If the geometrical support of the face is a plane, it will be translated as a 190 entity *PlaneSurface*. |
| TopoDS_Shell | 514: Shell | |
| TopoDS_Solid | 186: Manifold Solid | |
| TopoDS_CompSolid | 402 Form1 Group or no equivalent | Group is created only if *TopoDS_Compound* contains more than one item. One IGES Manifold Solid is created for each *TopoDS_Solid* in the *TopoDS_CompSolid*. |
| TopoDS_Compound | 402 Form1 Group or no equivalent | Group is created only if *TopoDS_Compound* contains more than one item. One IGES entity is created per *TopoDS_Shape* in the *TopoDS_Compound*. If *TopoDS_Compound* is nested into another *TopoDS_Compound* it is not mapped. | 

<h3><a id="occt_iges_3_5">Tolerance  management</a></h3>
<h4><a id="occt_iges_3_5_1">Setting  resolution in an IGES file</a></h4>

There are several  possibilities to set resolution in an IGES file. They are controlled by  write.precision.mode parameter; the dependence between the value of this  parameter and the set resolution is described in paragraph [Setting the translation parameters](#occt_iges_3_3_2). 

If the value of  parameter *write.precision.mode* is -1, 0 or 1, resolution is computed from  tolerances of sub-shapes inside the shape to be translated. In this  computation, only tolerances of *TopoDS_Edges* and *TopoDS_Vertices* participate  since they reflect the accuracy of the shape. *TopoDS_Faces* are ignored in  computations since their tolerances may have influence on resulting computed  resolution while IGES resolution mainly concerns points and curves but not  surfaces.  

<h3><a id="occt_iges_3_6">Code architecture</a></h3>
<h4><a id="occt_iges_3_6_1">Graph of calls</a></h4>
The following diagram illustrates the class structure in  writing IGES. 
The highlighted classes are intended to translate geometry. 

<img src="images/iges_image004.png" alt="The class structure in writing IGES" width="420">
      
<h3><a id="occt_iges_3_7">Example</a></h3>

~~~~{.cpp}
#include <IGESControl_Controller.hxx> 
#include <IGESControl_Writer.hxx> 
#include <TopoDS_Shape.hxx> 
Standard_Integer main() 
{ 
  IGESControl_Controller::Init(); 
  IGESControl_Writer ICW (;MM;, 0); 
  //creates a writer object for writing in Face mode with  millimeters 
  TopoDS_Shape sh; 
  ICW.AddShape (sh); 
  //adds shape sh to IGES model 
  ICW.ComputeModel(); 
  Standard_Boolean OK = ICW.Write (;MyFile.igs;); 
  //writes a model to the file MyFile.igs 
} 
~~~~


<h2><a id="occt_iges_4">Using XSTEPDRAW</a></h2>

XSTEPDRAW UL is intended  for creating executables for testing XSTEP interfaces interactively in the DRAW  environment. It provides an additional set of DRAW commands specific for the  data exchange tasks, which allow loading and writing data files and analysis of  resulting data structures and shapes.  

In the description of  commands, square brackets ([]) are used to indicate optional parameters.  Parameters given in the angle brackets (<>) and sharps (#) are to be  substituted by an appropriate value. When several exclusive variants are  possible, vertical dash (|) is used.  

<h3><a id="occt_iges_4_2">Setting interface  parameters</a></h3>

A set of parameters for  importing and exporting IGES files is defined in the XSTEP resource file. In  XSTEPDRAW, these parameters can be viewed or changed using command  

~~~~{.php}
Draw> param [<parameter_name> [<value>]]  
~~~~

Command *param* with no  arguments gives a list of all parameters with their values. When argument  *parameter_name* is specified, information about this parameter is  printed (current value and short description).  

The third argument is  used to set a new value of the given parameter. The result of the setting is  printed immediately.  

During all interface  operations, the protocol of the process (fail and warning messages, mapping of  the loaded entities into OCCT shapes etc.) can be output to the trace file. Two  parameters are defined in the DRAW session: trace level (integer value from 0  to 9, default is 0), and trace file (default is a standard output).  

Command *xtrace* is  intended to view and change these parameters:  
* *Draw> xtrace* --  prints current settings (e.g.: "Level=0 -  Standard Output");  
* *Draw> xtrace #* --  sets the trace level to the value #;  
* *Draw> xtrace  tracefile.log* -- sets the trace file as *tracefile.log*;  
* *Draw xtrace* -- directs all messages to the standard output.  

<h3><a id="occt_iges_4_3">Reading IGES files</a></h3>
For a description of  parameters used in reading an IGES file refer to [Setting the translation parameters](#occt_iges_2_3_3).  

These parameters are set  by command *param* :  

| Description | Name | Values |
| :------------ | :---- | :----- |
| Precision for input entities | read.precision.mode | 0 or 1 |
| | read.precision.val | real |
| Continuity of B splines | read.iges.bspline.continuity | 0-2 |
| Surface curves | read.surfacecurve.mode | 2, 3 or 0 |

It is possible either only to load an IGES file into memory  (i.e. to fill the model with data from the file), or to read it (i.e. to load  and convert all entities to OCCT shapes).  

Loading is done by the command 
~~~~{.php}
Draw> xload <file_name>
~~~~
Once the file is loaded, it is possible to investigate the  structure of the loaded data. To learn how to do it see [Analyzing the  transferred](#occt_iges_4_4).
 
Reading of an IGES file is done by the command  
~~~~{.php}
Draw> igesbrep <file_name> <result_shape_name> [<selection>]
~~~~
Here a dot can be used instead of a filename if the file is  already loaded by *xload* or *igesbrep* command. In that case, only  conversion of IGES entities to OCCT shapes will be done. 

Command *igesbrep* will interactively ask the user to  select a set of entities to be converted: 

| N | Mode | Description |
| :-- | :-- | :---------- |
| 0 | End | finish conversion and exit igesbrep |
| 1 | Visible roots | convert only visible roots |
| 2 | All roots | convert all roots |
| 3 | One entity | convert entity with number provided by the user |
| 4 | Selection | convert only entities contained in selection |

After the selected set of entities is loaded the user will  be asked how loaded entities should be converted into OCCT shapes (e.g., one  shape per root or one shape for all the entities). It is also possible to save  loaded shapes in files, and to cancel loading. 

The second parameter of the *igesbrep* command defines  the name of the loaded shape. If several shapes are created, they will get  indexed names. For instance, if the last parameter is ‘s’, they will be <i>s_1,  ... s_N.</i> 

<i>\<selection\></i> specifies the scope of selected entities  in the model, it is *xst-transferrable-roots* by default. An asterisk “*” can be  specified instead of *iges-visible-transf-roots*. For possible values of  *selection* refer to [Selecting entities](#occt_iges_2_3_4) section. 


Instead of *igesbrep* it is possible to use commands:
~~~~{.php}
Draw> trimport <file_name> <result_shape_name> <selection>
~~~~
which outputs the result of translation of each selected  entity into one shape, or
~~~~{.php}
Draw> trimpcomp <file_name> <result_shape_name> <selection>
~~~~
which outputs the result of translation of all selected  entities into one shape (*TopoDS_Compound* for several entities). 

An asterisk “*” can be specified instead of  *selection*, it means *xst-transferrable-roots*.
 
During the IGES translation, a map of correspondence between  IGES entities and OCCT shapes is created. 
The following commands are available:  

* *Draw> tpent \#* -- provides information on the result of translation of the given  IGES entity;
* *Draw> tpdraw \#* --creates an OCCT shape corresponding to an IGES entity;
* *Draw> fromshape \<shape_name\>* -- provides the number of an IGES entity corresponding to an OCCT  shape;
* *Draw> tpclear* -- clears the map of correspondences between IGES entities  and OCCT shapes. 

<h3><a id="occt_iges_4_4">Analyzing the transferred data</a></h3>

The procedure of analysis of the data import can be divided  into two stages: 
1. Checking the file contents;
2. Estimation of translation results (conversion and validated  ratios). 

<h4><a id="occt_iges_4_4_1">Checking file contents</a></h4>

General statistics on the loaded data can be obtained by  using command  
~~~~{.php}
Draw> data <symbol> 
~~~~
The information printed by this command depends on the  symbol specified: 

| Symbol | Output |
| :-------- | :----- |
| g | Prints information contained in the header of the file (Start and Global sections) |
| c or f | Runs check procedure of the integrity of the loaded data and prints the resulting statistics (f works only with fails while c with both fail and warning messages) |
| t | The same as c or f, with a list of failed or warned entities |
| m or l | The same as t but also prints a status for each entity |
| e  | Lists all entities of the model with their numbers, types, status of validity etc. |
| r | The same as e but lists only root entities |


There is a set of special objects, which can be used to  operate with the loaded model. They can be of the following types: 
| Special object type | Operation |
| :------------------ | :---------- |
| Selection Filters | allow selecting subsets of entities of the loaded model |
| Counters | Calculate statistics on the model data |


A list of these objects defined in the current session can  be printed in DRAW by command 
~~~~{.php}
Draw> listitems 
~~~~
In the following commands if several <i>\<selection\></i>  arguments are specified the results of each following selection are applied to the results of the previous one. 
~~~~{.php}
Draw> givelist <selection_name> [<selection_name>]
~~~~
prints a list of loaded entities defined by selection argument. 

~~~~{.php}
Draw> givecount <selection_name> [<selection_name>]
~~~~
prints a number of loaded entities defined by <i>selection</i> argument. 

Three commands are used to calculate statistics on the entities in the model:
* *Draw> count \<counter\> [\<selection\> ...]* -- prints only a number of entities per each type matching the criteria defined by arguments.
* *Draw> sumcount \<counter\> [\<selection\> ...]* -- prints the total number of entities of all types matching the criteria defined by arguments and the largest number corresponding to one type.
* *Draw> listcount \<counter\> [\<selection\> ...]* -- prints a list of entities per each type matching the criteria defined by arguments.

Optional <i>\<selection\></i> argument, if specified, defines a subset of entities, which are to be taken into account. Argument <i>\<counter\></i> should be one of the currently defined counters:

| Counter | Operation |
| :-------- | :-------- |
| xst-types | Calculates how much entities of each OCCT type exist |
| iges-types | Calculates how much entities of each IGES type and form exist |
| iges-levels | Calculates how much entities lie in different IGES levels |

The command:
~~~~{.php}
Draw> listtypes <selection_name> ...
~~~~
gives a list of entity types which were encountered in the  last loaded file (with a number of IGES entities of each type). The list can be  shown not for all entities but for a subset of them. This subset is defined by  an optional selection argument. 

Entities in the IGES file are numbered in the succeeding  order. An entity can be identified either by its number (#) or by its label.  Label is the letter ‘D’ followed by the index of the first line with the data  for this entity in the Directory Entry section of the IGES file. The label can  be calculated on the basis of the number as ‘D(2*# -1)’. For example, entity #  6 has label D11. 

* *Draw> elab \#*  -- provides  a label for an entity with a known number;
* *Draw> enum \#* -- prints a number for an entity with the given label; 
* *Draw> entity \# \<level_of_information\>*  -- gives the content of an IGES entity;
* *Draw> estat \#* -- provides the list of entities referenced by a given entity and the list of entities referencing to it.

<h4><a id="occt_iges_4_4_2">Estimating the results of reading IGES</a></h4>
All of the following commands are available only after the  data are converted into OCCT shapes (i.e. after command **igesbrep**). 

~~~~{.php}
Draw> tpstat [*|?]<symbol> [<selection>]
~~~~
provides all statistics on the last transfer,  including the list of transferred entities with mapping from IGES to OCCT  types, as well as fail and warning messages. The parameter <i>\<symbol\></i> defines  what information will be printed: 
* G -- General statistics (list of results and messages)
* C -- Count of all warning and fail messages
* C -- List of all warning and fail messages
* F -- Count of all fail messages
* F -- List of all fail messages
* N -- List of all transferred roots
* S -- The same, with types of source entity and result type
* B -- The same, with messages
* T -- Count of roots for geometrical types
* R -- Count of roots for topological types
* l -- The same, with a type of the source entity

The sign ‘*’ before the parameters **n**, **s**, **b**,  **t**, **r** makes it work on all entities (not only on roots). The sign  ‘?’ before **n**, **s**, **b**, **t** limits the scope of  information to invalid entities. 

Optional argument <i>\<selection\></i> can limit the action of  the command with a selected subset of entities. 
To get help, run this command without arguments. 

For example, to get translation ratio on IGES faces, you can use. 
~~~~{.php}
Draw:> tpstat *l iges-faces
~~~~
The second version of the same command is TPSTAT (not  capital spelling). 
~~~~{.php}
Draw:> TPSTAT <symbol> 
~~~~
Symbol can be of the following values: 
* g --  General statistics (list of results and messages)
* c -- Count of all warning and fail messages
* C -- List of all warning and fail messages
* r -- Count of resulting OCCT shapes per each type
* s -- Mapping of IGES roots and resulting OCCT shapes

Sometimes the trimming contours of IGES faces (i.e., entity  141 for 143, 142 for 144) can be lost during translation due to fails. 

The number of lost trims and the corresponding IGES entities can be obtained by the command:
~~~~{.php}
Draw> tplosttrim [<IGES_type>] 
~~~~
It outputs the rank and DE numbers of faces that  lost their trims and their numbers for each type (143, 144, 510) and their  total number. If a face lost several of its trims it is output only once. 

Optional parameter <i>\<IGES_type\></i> can be *TrimmedSurface,  BoundedSurface* or *Face* to specify the only type of IGES faces. 

For example, to get untrimmed 144 entities, use command 
~~~~{.php}
Draw> tplosttrim TrimmedSurface 
~~~~
To get the information on OCCT shape contents, use command 
~~~~{.php}
Draw> statshape <shape_name> 
~~~~
It outputs the number of each kind of shapes (vertex, edge,  wire, etc.) in a shape and some geometrical data (number of C0 surfaces,  curves, indirect surfaces, etc.). 

Note. The number of faces is returned as a number of  references. To obtain the number of single instances the standard command (from  TTOPOLOGY executable) **nbshapes** can be used. 

To analyze the internal validity of a shape, use command  
~~~~{.php}
Draw> checkbrep <shape_name> <expurged_shape_name>
~~~~
It checks the geometry and topology of a shape for  different cases of inconsistency, like self-intersecting wires or wrong  orientation of trimming contours. If an error is found, it copies bad parts of  the shape with the names "expurged_subshape_name _#" and generates  an appropriate message. If possible, this command also tries to find IGES  entities the OCCT shape was produced from. 

<i>\<expurged_shape_name\></i> will contain the original shape  without invalid subshapes. 

To get information on tolerances of subshapes, use command 
~~~~{.php}
Draw> tolerance <shape_name> [<min> [<max>] [<symbol>]]
~~~~
It outputs maximum, average and minimum values of  tolerances for each kind of subshapes having tolerances or it can output  tolerances of all subshapes of the whole shape. 

When specifying *min* and *max* arguments this  command outputs shapes with names <i>\<shape_name\>...</i> and their total number  with tolerances in the range <i>[min, max]</i>. 

<i>\<Symbol\></i> is used for specifying the kind of sub-shapes to analyze: 
* v -- for vertices,
* e -- for edges,
* f -- for faces,
* c -- for shells and faces. 

<h3><a id="occt_iges_4_5">Writing an IGES file</a></h3>

Refer to [Setting the translation parameters](#occt_iges_3_3_2) for a description of parameters used in reading an IGES file. The parameters are set by command *param*: 

| Description | Name | Values |
| :-----------  | :---- | :----- |
| Author | XSTEP.iges.header.author | String |
| Company | XSTEP.iges.header.company | String |
| Receiver | XSTEP.iges.header.receiver | String |
| Write mode for shapes | XSTEP.iges.writebrep.mode | 0/Faces or 1/BRep |
| Measurement units | XSTEP.iges.unit | 1-11 (or a string value) |

Several shapes can be written in one file. To start writing  a new file, enter command 
~~~~{.php}
Draw> newmodel 
~~~~
This command clears the *InterfaceModel* to make it empty.

~~~~{.php}
Draw> brepiges <shape_name_1> [<filename.igs>]
~~~~
Converts the  specified shapes into IGES entities and puts them into the *InterfaceModel*.

~~~~{.php}
Draw> writeall <filename.igs>
~~~~
Allows writing the prepared model to a file with name *filename.igs*.

<h2><a id="occt_iges_5">Reading from and writing to IGES</a></h2>

<h3><a id="occt_iges_5_1">Reading from IGES</a></h3>

### Load an IGES file

Before performing any other operation, you must load an IGES  file with: 
~~~~{.cpp}
IGESCAFControl_Reader reader(XSDRAW::Session(),  Standard_False); 
IFSelect_ReturnStatus stat = reader.ReadFile(“filename.igs”); 
~~~~
Loading the file only memorizes, but does not translate the  data. 

### Check the loaded IGES file

This step is not obligatory. See the description of [Checking the IGES file](#occt_iges_2_3_2) above. 

### Set parameters for translation to XDE

See the description of [Setting translation parameters](#occt_iges_2_3_3) above. 

In  addition, the following parameters can be set for XDE translation of  attributes: 
* For transferring colors: 
~~~~{.cpp}
reader.SetColorMode(mode); 
// mode can be Standard_True or Standard_False 
~~~~
* For transferring names: 
~~~~{.cpp}
reader.SetNameMode(mode); 
// mode can be Standard_True or Standard_False 
~~~~

### Translate an IGES file to XDE

The following function performs a translation of the whole  document: 
~~~~{.cpp}
Standard_Boolean ok = reader.Transfer(doc);  
~~~~
where *doc* is a variable which contains a handle to the output document and should have a  type *Handle(TDocStd_Document)*. 


<h3><a id="occt_iges_5_2">Writing to IGES</a></h3>

The translation from XDE to IGES can be initialized as follows: 
~~~~{.cpp}
IGESCAFControl_Writer aWriter(XSDRAW::Session(),Standard_False); 
~~~~

### Set parameters for translation from XDE to IGES

The  following parameters can be set for translation of attributes to IGES: 
* For transferring colors: 
~~~~{.cpp}
aWriter.SetColorMode(mode); 
// mode can be Standard_True or Standard_False 
~~~~
* For transferring names: 
~~~~{.cpp}
aWriter.SetNameMode(mode); 
// mode can be Standard_True or Standard_False 
~~~~

### Translate an XDE  document to IGES

You can perform the translation of a document by calling the  function: 
~~~~{.cpp}
IFSelect_ReturnStatus aRetSt = aWriter.Transfer(doc); 
~~~~
where "doc" is a variable which contains a handle to the input document for transferring  and should have a type *Handle(TDocStd_Document)*.
 
### Write an IGES file

Write an IGES file with: 
~~~~{.cpp}
IFSelect_ReturnStatus statw =  aWriter.WriteFile("filename.igs"); 
~~~~
or 
~~~~{.cpp}
IFSelect_ReturnStatus statw = writer.WriteFile (S); 
~~~~
where S is OStream.