The mystery of the blend
The blender file-format explained
Jeroen (Amsterdam, the Netherlands, 33 years old) worked as coder in the demo scene. He is interested in open source and 3d animations. At the moment he is working on products supporting impact analysis and change management around a fully automated render pipeline.
The mystery of the blend
The blend-file-format explained
Introduction
I'm working on a product what integrates Blender in a render pipeline by using the Blender command line and blend-files (.blend). The command line is not a problem as it is commonly used, but using blend-files outside Blender is difficult, because it is not that well documented. On the Internet, I've only found some clues about it on the Blender architecture pages [ref: http://www.blender.org/development/architecture/]. These were not sufficient. To really understand the file format I had to go through Blender's source code. In this article I will describe the blend-file-format with a request to tool-makers to support blend-file.
First I'll describe how Blender works with blend-files. You'll notice why the blend-file-format is not that well documented, as from Blender's perspective this is not needed. We look at the global file-structure of a blend-file (the file-header and file-blocks). After this is explained, we go deeper to the core of the blend-file, the DNA-structures. They hold the blue-prints of the blend-file and the key asset of understanding blend-files. When that's done we can use these DNA-structures to read information from elsewhere in the blend-file.
In this article we'll be using the default blend-file from Blender 2.48, with the goal to read the output resolution from the Scene. The article is written to be programming language independent and I've setup a web-site for support.
Loading and saving in Blender
Loading and saving in Blender is very fast and Blender is known to have excellent downward and upward compatibility. Ton Roosendaal demonstrated that in December 2008 by loading a 1.0 blend-file using Blender 2.48a [ref: http://www.blendernation.com/2008/12/01/blender-dna-rna-and-backward-compatibility/].
Saving complex scenes in Blender is done within seconds. Blender achieves this by saving data in memory to disk without any transformations or translations. Blender only adds file-block-headers to this data. A file-block-header contains clues on how to interpret the data. After the data, all internally Blender structures are stored. These structures will act as blue-prints when Blender loads the file. Blend-files can be different when stored on different hardware platforms or Blender releases. There is no effort taken to make blend-files binary the same. Blender creates the blend-files in this manner since release 1.0. Backward and upwards compatibility is not implemented when saving the file, this is done during loading.
When Blender loads a blend-file, the DNA-structures are read first. Blender creates a catalog of these DNA-structures. Blender uses this catalog together with the data in the file, the internal Blender structures of the Blender release you're using and a lot of transformation and translation logic to implement the backward and upward compatibility. In the source code of blender there is actually logic which can transform and translate every structure used by a Blender release to the one of the release you're using [ref:http://download.blender.org/source/blender-2.48a.tar.gz /blender-2.48a/source/blender/blenloader/intern/readfile.c lines 4946-7960]. The more difference between releases the more logic is executed.
The blend-file-format is not well documented, as it does not differ from internally used structures and the file can really explain itself.
Global file-structure
Let us look at the global file-structure. A blend-file always start with the file-header followed by file-blocks. The default blend file of Blender 2.48 contains more than 400 of these file-blocks. Each file-block has a file-block-header and data. This section explains how the global file-structure can be read.
File-Header
The first 12 bytes of every blend-file is the file-header. The file-header has information on Blender (version-number) and the PC the blend-file was saved on (pointer-size and endianness). This is required as all data inside the blend-file is ordered in that way, because no translation or transformation is done during saving. The next table describes the information in the file-header.
File-header
| reference |
structure |
type |
offset |
size |
| identifier |
char[7] |
File identifier (always 'BLENDER') |
0 |
7 |
| pointer-size |
char |
Size of a pointer; all pointers in the file are stored in this format. '_' means 4 bytes or 32 bit and '-' means 8 bytes or 64 bits. |
7 |
1 |
| endianness |
char |
Type of byte ordering used; 'v' means little endian and 'V' means big endian. |
8 |
1 |
| version-number |
char[3] |
Version of Blender the file was created in; '248' means version 2.48 |
9 |
3 |
Endianness addresses the way values are ordered in a sequence of bytes [ref: http://en.wikipedia.org/wiki/Endianness]. Blender supports little-endian and big-endian. In a big endian ordering, the largest part of the value is placed on the first byte and the lowest part of the value is placed on the last byte. In a little endian ordering, largest part of the value is placed on the last byte and the smallest part of the value is placed on the first byte. Example: writing the integer 0x4A3B2C1Dh, will be ordered in Big endian as 0x4Ah, 0x3Bh, 0x2Ch, 0x1Dhand be ordered in little endian as 0x1Dh, 0x2Ch, 0x3Bh, 0x4Ah.
The endianness can be different between the blend-file and the PC your using. When these are different, Blender changes it to the byte ordering of your PC. Nowadays, little-endian is the most commonly used.
The next hex-dump describes a file-header created with blender 2.48 on little-endian hardware with a 32 bits pointer length. pointer-size version-number 0000 0000: [42 4C 45 4E 44 45 52] [5F] [76] [32 34 38] BLEN DER_ v248 identifier endianness
File-block
File-blocks contain a file-block-header and data. The start of a file-block is always aligned at 4 bytes. The file-block-header describes the total length of the data, the type of information stored in the file-block, the number of items of this information and the old memory pointer at the moment the data was written to disk. Depending on the pointer-size stored in the file-header, a file-block-header can be 20 or 24 bytes long. The next table describes how a file-block-header is structured.
File-block-header
| reference |
structure |
type |
offset |
size |
| code |
char[4] |
Identifier of the file-block |
0 |
4 |
| size |
integer |
Total length of the data after the file-block-header |
4 |
4 |
| old memory address |
void* |
Memory address the structure was located when written to disk |
8 |
pointer-size (4/8) |
| SDNA index |
integer |
Index of the SDNA structure |
8+pointer-size |
4 |
| count |
integer |
Number of structure located in this file-block |
12+pointer-size |
4 |
Code describes different types of file-blocks. The code determines with what logic the data must be read. These codes also allows fast finding of data like Library, Scenes, Object or Materials as they all have a specific code.
The size contains the total length of data after the file-block-header. After the data a new file-block starts. The last file-block in the file has code 'ENDB'.
The old memory address contains the memory address when the structure was last stored. When loading the file the structures can be placed on different memory addresses. Blender updates pointers to these structures to the new memory addresses.
SDNA index contains the index in the DNA structures to be used when reading this file-block-data. More information about this subject will be explained in the Reading scene information section.
Count tells how many elements of the specific SDNA structure can be found in the data.
The next section is an example of a file-block-header. The code 'SC'+0x00h identifies that it is a Scene. Size of the data is 1376 bytes (0x05h X 256 + 0x60h = 1280 + 96); the old pointer is 0x0A042FA0h and the SDNA index is 139 (8 X 16 + 11). The section contains a single scene. Before we can interpreted the data of this file-block we first have to read the DNA structures in the file. The section structure DNA will show how to do that.0000 4420: [53 43 00 00] [60 05 00 00] [A0 2F 04 0A] [8B 00 00 00] SC.. `... ./.. .... 0000 4430: [01 00 00 00] [xx xx xx xx xx xx xx xx xx xx xx xx .... xxxx xxxx xxxx
Structure DNA
Structure DNA is stored in a file-block with code 'DNA1'. It can be just before the 'ENDB' file-block. It contains all internal structures of the Blender release the file was created in. The data in this file-block must be interpreted as described in the this section. In a blend-file created with Blender 2.48a this section is 43468 bytes long and contains 309 structures. These structure can be described as C-structures. They can hold fields, arrays and pointers to other structures, just like a normal C-structure.structure Scene { ID id; // 52 bytes long (ID is different a structure) Object *camera; // 4 bytes long (pointer to an Object structure) World *world; // 4 bytes long (pointer to a World structure) ... float cursor[3]; // 12 bytes long (array of 3 floats) ... }
The next section describes how this information is ordered in the data of the 'DNA1' file-block.
Structure of the DNA file-block-data
| repeat condition |
name |
type |
length |
description |
|
|
identifier |
char[4] |
4 |
'SDNA' |
|
|
name identifier |
char[4] |
4 |
'NAME' |
|
|
#names |
integer |
4 |
Number of names follows |
| for(#names) |
|
name |
char[] |
? |
Zero terminating string of name, also contains pointer and simple array definitions (e.g. '*vertex[3]\0') |
|
|
type identifier |
char[4] |
4 |
'TYPE' this field is aligned at 4 bytes |
|
|
#types |
integer |
4 |
Number of types follows |
| for(#types) |
|
type |
char[] |
? |
Zero terminating string of type (e.g. 'int\0') |
|
|
length identifier |
char[4] |
4 |
'TLEN' this field is aligned at 4 bytes |
| for(#types) |
|
length |
short |
2 |
Length in bytes of type (e.g. 4) |
|
|
structure identifier |
char[4] |
4 |
'STRC' this field is aligned at 4 bytes |
|
|
#structures |
integer |
4 |
Number of structures follows |
| for(#structures) |
|
structure type |
short |
2 |
Index in types containing the name of the structure |
| .. |
|
#fields |
short |
2 |
Number of fields in this structure |
| .. |
for(#field) |
field type |
short |
2 |
Index in type |
| for end |
for end |
field name |
short |
2 |
Index in name |
As you can see, the structures are stored in 4 arrays: names, types, lengths and structures. Every structure also contains an array of fields. A field is the combination of a type and a name. From this information a catalog of all structures can be constructed. The names are stored as how a C-developer defines them. This means that the name also defines pointers and arrays. (When a name starts with '*' it is used as a pointer. when the name contains for example '[3]' it is used as a array of 3 long.) In the types you'll find simple-types (like: 'integer', 'char', 'float'), but also complex-types like 'Scene' and 'MetaBall'. 'TLEN' part describes the length of the types. A 'char' is 1 byte, an 'integer' is 4 bytes and a 'Scene' is 1376 bytes long.
- Note: While reading the DNA you'll will come across some strange names like '(*doit)()'. These are method pointers and Blender updates them to the correct methods.
- Note: The fields 'type identifier', 'length identifier' and 'structure identifier' are aligned at 4 bytes.
The DNA structures inside a Blender 2.48 blend-file can be found at http://www.atmind.nl/blender/blender-sdna.html. If we understand the DNA part of the file it is now possible to read information from other parts file-blocks. The next section will tell us how.
Reading scene information
Let us look at the file-block we have seen earlier. The code is 'SC'+0x00h and the SDNA index is 139. The 139th structure in the DNA is a structure of type 'Scene'. The associated type ('Scene') has the length of 1376 bytes. This is exact the same length as the data in the file-block. We can map the Scene-structure on the data of the file-blocks. But before we can do that, we have to flatten the Scene-structure.
The first field in the Scene-structure is of type 'ID' with the name 'id'. Inside the list of DNA structures there is a structure defined for type 'ID' (structure index 17). The first field in this structure has type 'void' and name '*next'. Looking in the structure list there is no structure defined for type 'void'. It is a simple type and therefore the data should be read. '*next' describes a pointer. the first 4 bytes of the data can be mapped to 'id.next'. Using this method we'll map a structure to its data. If we want to read a specific field we know at what offset in the data it is located and how much space it takes.
The next table shows the output of this flattening process for some parts of the Scene-structure. Not all rows are described in the table as there is a lot of information in a Scene-structure.
flattened SDNA structure 139: Scene
| reference |
structure |
type |
name |
offset |
size |
description |
| id.next |
ID |
void |
*next |
0 |
4 |
Refers to the next scene |
| id.prev |
ID |
void |
*prev |
4 |
4 |
Refers to the previous scene |
| id.newid |
ID |
ID |
*newid |
8 |
4 |
|
| id.lib |
ID |
Library |
*lib |
12 |
4 |
|
| id.name |
ID |
char |
name[24] |
16 |
24 |
'SC'+the name of the scene as displayed in Blender |
| id.us |
ID |
short |
us |
40 |
2 |
|
| id.flag |
ID |
short |
flag |
42 |
2 |
|
| id.icon_id |
ID |
int |
icon_id |
44 |
4 |
|
| id.properties |
ID |
IDProperty |
*properties |
48 |
4 |
|
| camera |
Scene |
Object |
*camera |
52 |
4 |
Pointer to the current camera |
| world |
Scene |
World |
*world |
56 |
4 |
Pointer to the current world |
| set |
Scene |
Scene |
*set |
60 |
4 |
Pointer to the current set |
| Skipped rows |
| r.sfra |
RenderData |
int |
sfra |
248 |
4 |
Start frame of the scene |
| r.efra |
RenderData |
int |
efra |
252 |
4 |
End frame of the scene |
| Skipped rows |
| r.xsch |
RenderData |
short |
xsch |
326 |
2 |
X-resolution of the output when rendered at 100% |
| r.ysch |
RenderData |
short |
ysch |
328 |
2 |
Y-resolution of the output when rendered at 100% |
| r.xparts |
RenderData |
short |
xparts |
330 |
2 |
Number of x-part the renderer uses |
| r.yparts |
RenderData |
short |
yparts |
332 |
2 |
Number of y-part the renderer uses |
| Skipped rows |
| sculptdata.axislock |
SculptData |
char |
axislock |
1365 |
1 |
|
| sculptdata.pad |
SculptData |
char |
pad[2] |
1366 |
2 |
|
| frame_step |
Scene |
int |
frame_step |
1368 |
4 |
|
| pad |
Scene |
int |
pad |
1372 |
4 |
|
We can now read the X and Y resolution of the Scene. The X-resolution is located on offset 326 of the file-block-data and must be read as a short. The Y-resolution is located on offset 328 and is also a short.
- Note: An array of chars can mean 2 things. The field contains readable text or it contains an array of flags (not humanly readable).
- Note: A file-block containing a list refers to the DNA structure and has a count larger than 1. For example Vertexes and Faces are stored in this way.
Next steps
The implementation of saving in Blender is easy, but loading is difficult. When implementing loading and saving blend-files in a custom tool the difficulty is the opposite. In a custom tool loading a blend-file is easy, and saving a blend-file is difficult. If you want to save blend-files I suggest to start with understanding the the global file structure and parsing the DNA section of the file. After this is done it should be easy to read information from existing blend files like scene data, materials and meshes. When you feel familiar with this you can start creating blend-libraries using the internal Blender structures of a specific release. If you don't want to dive into the Blender source code you can find them all athttp://www.atmind.nl/blender/blender-sdna.html.
There is a feature request on supporting an XML based import/export system in Blender. I dont support the request, but it is interesting to look at how this can be implemented. An XML export can be implemented with low effort as an XSD can be used as DNA structures and the data can be written into XML [see http://www.atmind.nl/blender/blender-file.zip to download JAVA example including source code]. Implementing an XML import system uses a lot of memory and CPU. If you really want to implement it, I expect that the easiest way is to convert the XML-file back to a normal blend-file and then load it using the current implementation. One real drawback is that parsing a XML based blend-file uses a lot of memory and CPU and the files can become very large.
At this moment I'm using this information in an automated render pipeline. The render pipeline is build around a web-server and SVN. When an artist commits a new blend-file in SVN, it is picked up by the web-server and it will extract resolutions, frames scenes and libraries from the blend-file. This information is matched with the other files in SVN and the blend-file will be placed in the render pipeline.