The present invention relates to a document data processing technique, and particularly, to a method and system for document data security management and a docbase management system.
Information can be generally divided into structured data and unstructured data and, according to statistics, unstructured data mainly including text documents and streaming media constitute more than 70% of the information. The structure of structured data, i.e., a two-dimensional table structure, is comparatively simple. Structured data are typically processed by a database management system (DBMS). Such technique has been under development since the 1970s and was flourishing in the 1990s; the research and development and application of the technique for processing structured data are quite advanced at present. Unstructured data do not have any fixed data structure; hence unstructured data processing is very complicated.
Various of unstructured document processing applications are popular among users and different document formats are used at present, for example, existing document editing applications include Microsoft Word, WPS, Yongzhong Office (a branch of Open Office), Red Office(another branch of Open Office), etc. Usually a contents management application has to handle 200 to 300 ever updating document formats, which causes great difficulty to application developers. The document interoperability, digital contents extraction and format compatibility are becoming the focus of the industry, and problems as follows need solutions:
(1) Documents are not universal.
Users can exchange documents processed with the same application, but cannot exchange documents processed with different applications, which causes information blockage.
(2) Access interfaces are not unified and data compatibility costs are highly.
Since the document formats provided by different document processing applications are not compatible with each other, a component of another application should be used for a document processing application to parse an incompatible document (if that another application provides a corresponding interface) or too many research resources are spent in the software development stage to parse the document format from head to teo.
(3) Information security is poor.
The security control measures for a written document are quite limited, mainly including data encryption and password authentication, and widespread damages caused by information leaks in companies are found every year.
(4) Processes work only for a single document, multi-document management is lacking.
A person may have a large number of documents in his computer, but no efficient organization and management measure is provided for multiple documents and it is difficult to share resources such as font/typeface file, full text index, etc.
(5) Layer techniques are insufficient.
Some applications, e.g., Adobe Photoshop and Microsoft Word, have more or less introduced the concept of layer, yet functions and management of the layer are too rudimentary to meet the practical demands.
(6) Search methods are limited.
Massive information in the present networks results in a huge number of search results for any search keyword. While the full text search technique has solved the problem of recall ratio, precision ratio has become the major concern. However, the prior art does not fully utilize all information to improve the precision ratio. For example, the font or size of characters may be used for determining the importance of the characters, but both are ignored by the present search techniques.
Large companies are all working to make their own document format the standard format in the market and standardization organizations are also leaning toward the creation of a universal document format standard. Nevertheless, a document format, whether a proprietary document format (e.g., .doc format) or an open document format (e.g., .PDF format), leads to problems as follows:
(a) Repeated research and development and inconsistent performance
Different applications that adopt the same document format standard have to find their own ways to render and generate documents conforming with the document format standard, which results in repeated research and development. Furthermore, some rendering components developed by some applications provide full-scale functions while others provide only basic functions. Some applications support a new version of the document format standard while others only support an old version. Hence, different applications may present the same document in different page layouts, and rendering errors may even occur with some applications that are consequentially unable to open the document.
(b) Barrier to innovation
The software industry is known for its ongoing innovation; however, when a new function is added, descriptive information about the function needs to be combined with the corresponding standard. A new format can only be introduced when the standard is revised. A fixed storage format makes technical innovation less competitive.
(c) Impaired search performance
For massive information, more indexes need to be added so as to enhance search performance, yet it is hard for a fixed storage format to allow more indexes.
(d) Impaired transplantability and scalability
Different applications in different system environments have different storage needs. For example, an application needs to reduce seek times of a disk head to improve performance when the data are saved in a hard disk, while an embedded application does not need to do that because the data of the embedded application are saved in the system memory. For example, a DBMS provided by the same manufacturer may use different storage formats on different platforms. Hence the document storage standards affect transplantability and scalability of the system.
In prior art, the document format that provides the best performance for openness and interchangeability is the PDF format from Adobe Acrobat. However, even though the PDF format has actually become a standard for document distribution and exchange worldwide, different applications cannot exchange PDF documents, i.e., PDF documents provides no interoperability. Moreover, both Adobe Acrobat and Microsoft Office can process only one document at a time and can neither manage multiple documents nor operate with docbases.
In addition, the existing techniques are significantly flawed concerning document information security. Currently, the most widely used documents, e.g., Word documents and PDF documents, adopt data encryption or password authentication for data security control without any systematic identity authentication mechanism. Privilege control cannot be applied to a part of a document but only to the whole document. The encryption and signature of logic data are limited, i.e., encryption and signature cannot be applied to arbitrary logic data. Likewise, a contents management system, while providing a satisfactory identity authentication mechanism, is separated from a document processing system and cannot be integrated with the document processing system on the core unit. Therefore the contents management system can only provide management down to the document level, and the document will be beyond the security control of the contents management system when the document is in use. Essential security control cannot be achieved in this way. And the security and document processing are usually handled by separated modules, which may easily cause security breaches.
The present invention provides a method and system for document security control to eliminate the security flaws in the document processing techniques described in the foregoing introduction.
The present invention provides a powerful embedded information security function which applies information security technology in the core layer to offer maximum security to documents.
A system for document security control provided comprises:
an application, embedded in a machine readable medium, which performs a security control operation on abstract unstructured information by issuing an instruction to a platform software;
the platform software, embedded in a machine readable medium, which accepts the instruction from the application and performs the security control operation on storage data corresponding to the abstract unstructured information;
wherein, said abstract unstructured information are independent of a way in which said storage data are stored.
A machine readable medium having instructions stored thereon that when executed cause a system to:
perform a security control operation on abstract unstructured information by issuing an instruction to a platform software; wherein, said abstract unstructured information are independent of the way in which corresponding storage data are stored.
A machine readable medium having instructions stored thereon that when executed cause a system to:
accept an instruction from an application which perform a security control operation on abstract unstructured information by issuing the instruction;
perform the security control operation on storage data corresponding to the abstract unstructured information; wherein, said abstract unstructured information are independent of the way in which the storage data are stored.
A computer-implemented system, comprising:
means for performing a security control operation on abstract unstructured information by issuing an instruction;
means for accepting the instruction from the application and performs the security control operation on storage data corresponding to the abstract unstructured information;
wherein, said abstract unstructured information are independent of a way in which said storage data are stored.
A system for document security control provided comprises:
an application, embedded in a machine readable medium, which performs a security control operation on abstract unstructured information by issuing an instruction to a platform software;
the platform software, embedded in a machine readable medium, which accepts the instruction from the application and performs the security control operation on storage data corresponding to the abstract unstructured information;
wherein, said abstract unstructured information are independent of a way in which said storage data are stored.
According to the present invention, a document processing technique based on separating the application layer and the data processing layer can integrate information security into the core layer of document processing. Therefore security breaches will be eliminated, and the security mechanism and document processing mechanism will be combined into one module instead of two module. More space is thus provided for security management and corresponding codes can thus be hidden deeper and used more effectively for defending illegal attack and improving security and reliability. In addition, fine-grained security management measures can be taken, e.g., more privilege classes and smaller management divisions can be adopted. The invention also provides a universal document security model which satisfies the demands of various applications concerning document security so that different applications can control document security via a same interface.
The present invention is further described hereinafter in detail with reference to the accompanying drawings and embodiments. It should be understood that the embodiments described herein are used for purposes of explaining the present invention only and shall not be used for limiting the scope of the present invention.
The method and system for security management of the present invention are mainly applied to document processing systems described hereafter.
Problems existing among prior document processing applications include: poor universality, difficulties in extracting document information, inconsistent access interfaces, difficulties or high cost on achieving data compatibility, impaired transplantability and scalability, underdeveloped page layered technique and too monotonous search method. In the prior art, one single application implements functions of both user interface and document storage, the present invention solves the problems by dividing a document processing application into an application layer and a docbase management system layer. The present invention further sets up an interface standard for interaction between the two layers and may even further create an interface layer in compliance with the interface standard. The docbase management system is a universal technical platform with all kinds of document processing functions and an application issues an instruction to the docbase management system via the interface layer to process a document, then the docbase management system performs corresponding operation according to the instruction. In this way, as long as different applications and docbase management systems follow the same standard, different applications can process a same document through a same docbase management system, therefore document interoperability is achieved. Similarly, one application may process different documents through different docbase management systems without independent development on every document format.
Furthermore, the technical scheme of the present invention provides a universal document model which makes different applications compatible with different documents to be processed. The interface standard is based on the document model so that different applications can process a same document via the interface layer. The universal document model can be applied to all types of document formats so that one application may process documents in different formats via the interface layer. The interface standard defines various instructions based on the universal document model for operations on corresponding documents and the way of issuing instructions by an application to a docbase management system(s). The docbase management system has functions to implement the instructions from the application. The universal model includes multiple hierarchies such as a docset including a number of documents, a docbase and a document warehouse. And the interface standard includes instructions covering organization management, query and security control, of multiple documents. In the universal model, a page is separated into multiple layers from bottom to top and the interface standard includes instructions for operations on the layers, storage and extraction of a source file corresponding to a layer in a document. In addition, the docbase management system has information security management control functions for documents, e.g., role-based fine-grained privilege management, and corresponding operation instructions are defined in the interface standard.
According to the present invention, the application layer and the data processing layer are separated with each other. An application no longer needs to deal with document formats directly and a document format is no longer associated with a specific application. Therefore a document can be processed by different applications and an application can process documents in different formats and document interoperability is achieved. The whole document processing system can further process multiple documents instead of one document. When a page in a document is divided into multiple layers, different management and control policies can be applied to different layers to facilitate operations of different applications on the same page (it can be designed that different applications manage and maintain different layers) and further facilitate source file editing and it is also a good way to preserve the history of editing.
The document processing system in which the method and system for security management of the present invention are applied is explained.
As shown in
The application includes any of existing document processing and contents management applications in the application layer of the document processing system, and the application sends an instruction in compliance with the interface standard to process documents. All operations are applied on documents in compliance with the universal document model regardless of the storage formats of the documents.
The interface layer is in compliance with the interface standard for interaction between the application layer and the docbase management system. The application layer sends standard an instruction to the docbase management system via the interface layer and the docbase management system returns the result of corresponding operation to the application layer via the interface layer. It can be seen that, since all applications can sends a standard instruction via the interface layer to process a document in compliance with the universal document model, different applications can process a same document through a same docbase management system and a same application can process documents in different formats through different docbase management systems.
Preferably, the interface layer includes an upper interface unit and a lower interface unit. The application layer can send a standard instruction from the upper interface unit to the lower interface unit and the docbase management system receives the standard instruction from the lower interface unit. The lower interface unit is further used for returning the result of the operation performed by the docbase management system to the application system through the upper interface unit. In practical applications, the upper interface unit can be set up in the application layer and the lower interface unit can be set up in the docbase management system.
The docbase management system is the core layer of the document processing system and performs an operation on a document according to a standard instruction from the application through the interface layer.
The storage device is the storage layer of the document processing system. A common storage device includes a hard disk or memory, and also can include an optical disk, flash memory, floppy disk, tape, remote storage device, or any kind of device that is capable of storing data. The storage device stores multiple documents and the way of storing the documents is irrelevant to applications.
It can thus be seen that the present invention enables the application layer to be separated from the data processing layer in deed. Documents are no longer associated with any specified applications and an application no longer needs to deal with document formats. Therefore different applications can edit a same document in compliance with the universal document model and satisfactory document interoperability is achieved among the applications.
The system for processing the document may comprise an application and a platform software (such as docbase management system). The application performs an operation on abstract unstructured information by issuing one or more instructions to the platform software. The platform software receives the instructions, maps the operation on abstract unstructured information to the operation on storage data corresponding to the abstract unstructured information, and performs the operation on the storage data. It is noted that the abstract unstructured information are independent of the way in which the storage data are stored.
Storage data refer to various kinds of information maintained or stored on a storage device (e.g., a non-volatile persistent memory such as a hard disk drive, or a volatile memory) for long-term usage and such data can be processed by a computing device. The storage data may include complete or integrated information such as an office document, an image, or an audio/video program, etc. The storage data are typically contained in one disk file, but such data may also be contained in multiple (related) files or in multiple fields of a database, or an area of an independent disk partition that is managed directly by the platform software instead of the file system of the OS. Alternatively, storage data may also be distributed to different devices at different places. Consequently, formats of the storage data may include various ways in which the information can be stored as physical data as described above, not just formats of the one or more disk files.
Storage data of a document can be referred to as document data and it may also contain other information such as security control information or editing information in addition to the information of visual appearance of the document. A document file is the document data stored as a disk file.
Here, the word “document” refers to information that can be printed on paper (e.g., static two-dimension information). It may also refer to any information that can be presented, including multi-dimension information or stream information such as audio and video.
In some embodiments, an application performs an operation on an (abstract) document, and it needs not to consider the way in which the data of the document are stored. A platform software (such as a docbase management system) maintains the corresponding relationship between the abstract document and the storage data (such as a document file with specific format), e.g., the platform software maps an operation performed by the application on the abstract document to an operation actually on the storage data, performs the operation on the storage data, and returns the result of such operation back to the application when the return of the result is requested.
In some embodiments, the abstract document can be extracted from the storage data, and different storage data may correspond to the same abstract document. For example, when the abstract document is extracted from visual appearance (also called layout) of the document, different storage data having the same visual appearance, no matter the ways in which they are stored, may correspond to the same abstract document. For another example, when a Word file is converted to a PDF file that has same visual appearance, the Word file and the PDF file are different storage data but they correspond to the same abstract document. Even when the same document is stored in different versions of Word formats, these versions of Word files are different storage data but they correspond to the same abstract document.
In some embodiments, in order to record the visual appearance properly, it would be better to record position information of visual contents, such as text, image and graphic, together with resources referenced, such as linked pictures and nonstandard fonts, to ensure fixed position of the visual contents and to guarantee that the visual contents is always available. A layout-based document meets the above requirements and is often used as storage data of the platform software.
The storage data created by platform software is called universal data since it is accessible by standard instructions and can be used by other applications that conform to the interface standard. Besides universal data, an application is also able to define its own unique data format such as office document format. After opening and parsing a document with its own format, the application may request creating a corresponding abstract document by issuing one or more standard instructions, and the platform software creates the corresponding storage data according to the instructions. Although the format of the newly created storage data may be different from the original data, the newly created storage data, the universal data, corresponds to the same abstract document with the original data, e.g., it resembles the visual appearance of the original data. Consequently, as long as any document data (regardless of its format) corresponds to an abstract document, and the platform software is able to create a storage data corresponding to the abstract document, any document data can be converted to an universal data that corresponds to same abstract document and is suitable to be used by other applications, thus achieving document interoperability between different applications conforms to the same interface standard.
For a non-limiting example, an interoperability process involving two applications and one platform software is described below. The first application creates first abstract document by issuing a first set of instructions to the platform software, and the platform software receives the first set of instructions from the first application and creates a storage data corresponding to the first abstract document. The second application issues a second set of instructions to the platform software to open the created storage data, and the platform software opens and parses the storage data according to the second set of instructions, generating second abstract document corresponding to the said storage data. Here, the second abstract document is identical to or closely resembles the first abstract document and the first and second sets of instructions conform to the same interface standard, making it possible for the second application to open the document created by first application.
For another non-limiting example, another interoperability process involving one application and two platform software is described below. The first platform software parses first storage data in first data format, generates a first abstract document corresponding to the storage data. The application retrieves all information from the first abstract document by issuing a first set of instructions to the first platform software. The application creates a second abstract document which is identical to or closely resembles the first abstract document by issuing a second set of instructions to the second platform software. The second platform creates second storage data in second data format according the second set of instructions. Here, the first and second sets of instructions conform to the same interface standard, enabling the application to convert data between different formats and retain the abstract feature unchanged. The interoperability process involving multiple applications and multiple platform software can be deduced from the two examples above.
Due to limiting factors such as document formats and functions of relative software, the storage data may not be mapped to the abstract document with 100% accuracy and there may be some deviations. For a non-limiting example, such deviations may exist regardless of the precision floating point numbers or integers used to store coordinates of the visual contents. In addition, there may be deviations between the displaying/printing color and the predefined color if the software used for displaying/printing lacks necessary color management functions. If these deviations are not significant (for non-limiting examples, a character's position deviated 0.01 mm from where it should be, or an image with lossy compression by JPEG), these deviations can be ignored by users. The degree of deviation accepted by the users is related to practical requirements and other factors, for example, a professional art designer would be stricter with the color deviation than most people. Therefore, the abstract document may not be absolutely consistent with the corresponding storage data and displaying/printing results of different storage data corresponding to the same abstracted visual appearance may not be absolutely same with each other. Even if same applications are used to deal with the same storage data, the presentations may not be absolutely the same. For example, the displaying results under different screen resolutions may be slightly different. In the present invention, “similar” or “consistent with” or “closely resemble” is used to indicate that the deviation is acceptable, (e.g., identical beyond a predefined threshold or different within a predefined threshold). Therefore, storage data may correspond to, or be consistent with, a plurality of similar abstract documents.
The corresponding relationship between the abstract document and the storage data can be established by the platform software in many different ways. For example, the corresponding relationship can be established when opening a document file, the platform software parses the storage data in the document file and forms an abstract document to be operated by the application. Alternatively, the corresponding relationship can be established when platform software receives an instruction indicating creating an abstract document from an application, the platform software creates the corresponding storage data. In some embodiments, the application is aware of the storage data corresponding to the abstract document being processed (e.g., the application may inform the platform software where the storage data are, or the application may read the storage data into memory and submit the memory data block to the platform software). In some other embodiments, the application may “ignore” the storage data corresponding to the operated abstract document. For a non-limiting example, the application may require the platform software to search on Internet under certain condition and open the first searched documents.
Generally speaking, the abstract document itself is not stored on any storage device. Information used for recording and describing the abstract document can be included in the corresponding storage data or the instruction(s), but not the abstract document itself. Consequently, the abstract document can be called alternatively as a virtual document.
In some embodiments, the abstract document may have a structure described by a document model, such as a universal document model described hereinafter. Here, the statement “document data conform to the universal document model” means that the abstract document extracted from the document data conforms to the universal document model. Since the universal document model is extracted based on features of paper, any document which can be printed on a paper conforms to the document model, making such document model “universal”.
In some embodiments, other information such as security control, document organization (such as the information about which docset a document belongs to), invisible information like metadata, interactive information like navigation and thread, can also be extracted from the document data in addition to visual appearance of the document. Even multi-dimension information or stream information such as audio and video can be extracted. All those extracted information can be referred to jointly as abstract information. Since there is no persistent storage for the abstract information, the abstract information also can be referred to as virtual information. Although most of embodiments of the present invention are based on the visual appearance of the document, the method described above can also be adapted to other abstract information, such as security control, document organization, multi-dimension or stream information.
There are various ways to issue the instruction used for operating on the abstract information, such as issuing a command string or invoking a function. An operation on the abstract information can be denoted by instructions in different forms. The reason why invoking a function is regarded as issuing the instruction is that addresses of difference functions can be regarded as different instructions respectively, and parameter(s) of the function can be regarded as parameter(s) of the instruction. When the instruction is described under “an operation action+an object to be operated” standard, the object in the instruction may either be the same or different from an object of the universal document model. For example, when setting the position of a text object of a document, the object in the instruction may be the text object, which is the same as the object of the universal document model, or it may be a position object of the text which is different with the object of the universal document model. In actual practice, it will be convenient to unify the objects of the instructions and the objects of universal document model.
The method described above is advantageous for document processing as it separates the application from the platform software. In practice, the abstract information and the storage data may not be distinguished strictly, and the application may even operate on the document data directly by issuing instruction to the platform software. Under such a scenario, the instruction should be independent of formats of the document data in order to maintain universality. More specifically, the instruction may conform to an interface standard independent of the formats of the document data, and the instruction may be sent through an interface layer which conforms to the interface standard. However, the interface layer may not be an independent layer and may comprise an upper interface unit and a lower interface unit, where the upper interface unit is a part of application and the lower interface unit is a part of platform software.
The embodiments of the document processing system provided by the present invention are described hereinafter.
The universal document model can be defined with reference to the features of paper since paper has been the standard means of recording document information, and the functions of paper are sufficient to satisfy the practical needs in work and living.
If a page in a document is regarded as a piece of paper, all information put down on the paper should be recorded. There is a demand for the universal document model, which is able to describe all visible contents on the page. The page description language (e.g., PostScript) in the prior art is used for describing all information to be printed on the paper and will not be explained herein. However, the visible contents on the page can always be categorized into three classes: texts, graphics and images.
When the document uses a specific typeface or character, the corresponding font is embedded into the document to guarantee identical output on the screens/printers of different computers. The font resources are shared to improve storage efficiency, i.e., only one font needs to be embedded when the same character is used for different places. An image sometimes may be used in different places, e.g., the image may be used as the background images of all pages or as a frequently appearing company logo and it will be better to share the image, too.
Obviously, as a more advanced information process tool, the universal document model not only imitates paper, but also develops some enhanced digital features, such as metadata, navigation, a thread, and a thumbnail image, which also can be called minipage, etc. Metadata includes data used for describing data, e.g., the metadata of a book includes information about the author, publishing house, publishing date and ISBN. Metadata is a common term in the industry and will not be explained further herein. Navigation, also a common term in the industry, includes information similar to the table of contents of a book. The thread information describes the location of a passage and the order of reading, so that when a reader finishes a screen, the reader can learn what information should be displayed on the next screen. The thread also enables automatic column shift and automatic page shift without the reader manually appointing a position by the reader. The thumbnail image includes miniatures of all pages. The miniatures are generated in advance so that the reader may choose a page to read by checking the miniatures.
The universal document model includes multiple hierarchies including a document warehouse, docbase, docset, document, page, layer, object stream which also can be called object group, and layout object.
The document warehouse consists of one or multiple docbases. The relation among docbases is not as strictly regulated as the relation among hierarchies within a docbase. Docbases can be combined and separated simply without modifying the data of the docbases, and usually no unified index is set up for the docbases (especially a fulltext index), so most search operations on the document warehouse traverse the indexes of all the docbases without an available unified index. Every docbase consists of one or multiple docsets and every docset consists of one or multiple documents and possibly a random number of sub docsets. A document includes a normal document file (e.g., a .doc document) in the prior art. The universal document model may define that a document may belong to one docset only or belong to multiple docsets. A docbase is not a simple combination of multiple documents but a tight organization of the documents, which can create the great convenience after unified search indexes are established for the document contents.
Every document consists of one or multiple pages in an order (e.g., from the front to the back), and the size of the pages may be different. Rather than in a rectangular shape, a page may be in a random shape expressed by one or multiple closed curves.
Further, a page consists of one or multiple layers in an order (e.g., from the top to the bottom), and one layer is overlaid with another layer like one piece of glass over another piece of glass. A layer consists of a random number of layout objects and object streams. The layout objects include statuses (typeface, character size, color, ROP, etc.), texts (including symbols), graphics (line, curve, closed area filled with specified color, gradient color, etc.), images (TIF, JPEG, BMP, JBIG, etc.), semantic information (title start, title end, new line, etc.), source file, script, plug-in, embedded object, bookmark, hyperlink, streaming media, binary data stream, etc. One or multiple layout objects can form an object stream, and an object stream can include a random number of sub-object streams.
The docbase, docset, document, page, and layer may further include metadata (e.g., name, time of latest modification, etc., the type of the metadata can be set according to practical needs) and/or history. The document may further include navigation information, thread information and thumbnail image. And the thumbnail image also may be placed in the page or the layer. The docbase, docset, document, page, layer, and object stream may also include digital signatures. The semantic information had better follow layout information to avoid data redundancy and to facilitate the establishment of the relation between the semantic information and the layout. The docbase and document may include shared resources such as a font and an image.
Further the universal document model may define one or multiple roles and grant certain privileges to the roles. The privileges are granted based on docbase, docset, document, page, layer, object stream and metadata etc. Regard docbase, docset, document, page, layer, object stream or metadata as a unit for granting privileges to a role, and the privileges define whether the role is authorized to read, write, copy or print the unit for granting.
The universal document model goes beyond the conventional one document for one file. A docbase includes multiple docsets, and a docset includes multiple documents. Fine-grained access and security control is applied to document contents in the docbase so that even a single text or rectangle can be accessed separately in the docbase while the prior document management system is limited to access as far as a file name, i.e., the prior document management system can not access to contexts of a file separately.
The organization structures of the objects are tree structures and are divided into levels.
The document warehouse object consists of one or multiple docbase objects.
The docbase object includes one or multiple docset objects, a random number of docbase helper objects, and a random number of docbase shared objects.
The docbase helper object includes a metadata object, role object, privilege object, plug-in object, index information object, script object, digital signature object, and history object, etc. The docbase shared object includes an object that may be shared among different documents in the docbase, such as a font object and an image object.
Every docset object includes one or multiple document objects, a random number of docset objects, and a random number of docset helper objects. The docset helper object includes a metadata object, digital signature object, and history object. When the docset object includes multiple docset objects, the structure is similar to the structure of a folder including multiple folders in the Windows system.
Every document object includes one or multiple page objects, a random number of document helper objects, and a random number of document shared objects. The document helper object includes a metadata object, font object, navigation object, thread object, thumbnail image object, digital signature object, and history object. The document shared object includes an object that may be shared by different pages in the document, such as an image object and a seal object.
Every page object includes one or multiple layer objects and a random number of page helper objects. The page helper object includes a metadata object, digital signature object and history object.
Every layer object includes one or multiple layout objects, a random number of object streams and a random number of layer shared objects. The layer helper object includes a metadata object, digital signature object, and history object. The object stream includes a random number of layout objects, a random number of object streams, and optional digital signature objects. When the object stream includes multiple object streams, the structure is similar to the structure of a folder including multiple folders in the Windows system.
The layout object includes any one or any combination of a status object, text object, line object, curve object, arc object, path object, gradient color object, image object, streaming media object, metadata object, note object, semantic information object, source file object, script object, plug-in object, binary data stream object, bookmark object, and hyperlink object.
Further, the status object includes any one or any combination of a character set object, typeface object, character size object, text color object, raster operation object, background color object, line color object, fill color object, linetype object, line width object, line joint object, brush object, shadow object, shadow color object, rotate object, outline typeface object, stroke typeface object, transparent object, and render object.
The universal document model can be enhanced or simplified based on the above description. If a simplified document model does not include a docset object, the docbase object shall include a document object directly. And if a simplified document model does not include a layer object, the page object shall include a layout object directly.
One skilled in the art can understand that a minimum universal document model includes only a document object, page object and layout object. The layout object includes only a text object, line object and image object. The models between a full model and the minimum model are included in the equivalents of the preferred embodiments of the present invention.
A universal security model should be defined to satisfy the document security requirements, enhance the document security function of the present applications and eliminate security breaches caused by separation of the security management mechanism and document processing module. In a preferred embodiment of the present invention, the universal document security model includes aspects as follows:
1. Role object
A role is defined in a docbase and a role object is created, and the role object is usually the sub-object of the docbase. When corresponding universal document model does not include a docbase object, the role shall be defined in a document, i.e., the role object shall be the sub-object of a document object and all docbases in the universal document security model shall be replaced with documents.
2. Grant an access privilege to a specified role
An access privilege for any role on any object (e.g. a docbase object, docset object, document object, page object, layer object, object group object and layout object) can be set up. If a privilege on an object is granted to a role, the privilege can be inherited by all sub-objects of the object.
Access privileges in the docbase management system may include any one or any combination of the following privileges: read privilege, write privilege, and re-license privilege. Other privileges that may be incorporated into an application can also be defined, e.g., print privilege.
3. Attach a signature of role to an object
A signature of a role can be attached to an object. The signature covers the sub-objects of the object and objects referenced by the object.
4. Create a role
A key of a role used for the login process is returned in response to an instruction of creating a role object. The key is usually a private key of the PKI key pair and should be kept securely by the application. The key also can be a login password. Preferably, all applications are allowed to create a new role to which no privilege is granted. Certain privileges can be granted to the new role by existing roles with re-license privilege.
5. Login of role
When an application logs in as a role, the “challenge-response” mechanism can be employed, i.e., the docbase management system encrypts a random data block with the public key of the role and sends the cipher data to the application, and the application decrypts the cipher data and returns the decrypted data to the docbase management system. If the data are correctly decrypted, it is determined that the application does have the private key of the role. The “challenge-response” mechanism may also include processes as follows: The docbase management system sends a random data block to the application; the application encrypts the data with the private key and returns the cipher data to the docbase management system, and the docbase management system decrypts the cipher data with the public key. If the data are correctly decrypted, it is determined that the application does have the private key of the role. The “challenge-response” authentication process may be repeated several times for a double check. The “challenge-response” mechanism provides better security for the private key. When the key of the role is a login password, users of the application have to enter the correct login password.
The application may log in as multiple roles. The privileges granted to the application are the combination of the privileges of the roles.
6. A default role
A special default role can be created. When a default role is created, the corresponding docbase can be processed with the default role even when no other role logs in. Preferably, a docbase creates a default role with all possible privileges when the docbase is created.
Practically the universal document security model can be modified into an enhanced, simplified or combined process, and the modified universal document security model is included in the equivalents of the embodiments of the present invention.
Practical Application of the Interface Layer
A unified interface standard for the interface layer can be defined based on the universal document model, universal security model and common document operations. The interface standard is used for sending an instruction used for processing an object in the universal document model. The instruction used for processing an object in the universal document model conforms with the interface standard so that different applications may issue standard instructions via the interface layer.
T The application of the interface standard is explained hereinafter. The interface standard can be performed through processes as follows: The upper interface unit generates an instruction string according to a predetermined standard format, e.g., “<UOML_INSERT (OBJ=PAGE, PARENT=123.456.789, POS=3)/>”, and sends the instruction to the lower interface unit. It then receives the operation result of the instruction or other feedback information from the docbase management system via the lower interface unit. Or the interface standard can be performed through processes as follows: The lower interface unit provides a number of interface functions with standard names and parameters, e.g., “BOOL UOI_InsertPage (UOI_Doc *pDoc, int nPage)”, the upper interface unit invokes these standard functions, and the action of invoking functions is equal to issuing standard instructions. Or the above two processes can be combined to perform the interface standard.
The interface standard applies an “operation action+object to be operated” approach so that the interface standard will be easy to study and understand and be more stable. For example, when 10 operations need to be performed on 20 objects, the standard can either define 20×10=200 instructions or define 20 objects and 10 actions. However, the method for the latter definition puts far less burden on human memory and makes it easy to add an object or action when the interface standard is extended in the future. The object to be operated is an object in the universal document model.
For example, the following 7 operation actions can be defined:
Open: create or open a docbase;
Close: close a session handle or a docbase;
Get: get an object list, object related attribute and data;
Set: set/modify object data;
Insert: insert a specified object or data;
Delete: delete a sub-object of an object; and
Query: search for contents in document(s) according to a specified term, wherein the term may include accurate information or vague information, i.e., a fuzzy search is supported.
The following objects can be defined: a docbase, docset, document, page, layer, object stream, text, image, graphic, path (a group of closed or open graphics in an order), source file, script, plug-in, audio, video, role, etc.
The objects to be defined may also include the following status objects: background color, line color, fill color, line style, line width, ROP, brush, shadow, shadow color, character height, character width, rotate, transparent, render mode, etc.
When the interface standard applies the “operation action+object to be operated” approach, it cannot be automatically assumed that each combination of each object plus each action gives a meaningful operation instruction. Some combinations are just meaningless.
The interface standard may also be defined by using a function approach that is not an “operation action+object to be operated” approach. For example, an interface function is defined for each operation on each object, and in such a case every operation instruction is sent to the docbase management system by the upper interface unit invoking the corresponding interface function of the lower interface unit
The interface standard may also encapsulate various object classes of Object Oriented Programming language, e.g., a docbase class, and define an operation to be performed on the object as a method of the class.
Particularly, when an instruction of getting a page bitmap is defined in the interface standard, it will be crucial to layout consistency and document interoperability.
By using the instruction of getting page bitmap, the application can get the page bitmap of a specified bitmap format in a specified page, i.e., the screen output of the page can be shown in a bitmap without separately rendering every layout object. That means the application can directly get accurate page bitmaps to display/print a document without reading every layout object on every layer in every page one by one, rendering every object or displaying the rendering of every object on page layout. When the application has to render the objects one by one, in practical some applications may provide comparatively full and accurate rendering of the objects while other applications provide only partial or inaccurate rendering of the objects, hence different applications may produce different screen display/print outputs for a same document, which impairs document interoperability among the applications. By generating page bitmaps by the docbase management system, the keypoint to keeping consistent page layout is transferred from the application to the docbase management system, which makes it possible for different applications to produce identical page output for a same document. The docbase management system can provide such a function because: firstly, the docbase management system is a unified basic technical platform and is able to render various layout objects while it will be hard for an application to render all layout objects; secondly, different applications may cooperate with a same docbase management system to further guarantee consistent layouts in screen display/print outputs. To sum up, it is unlikely for different applications to produce identical output for a same document while it is possible for different docbase management systems to produce identical output for a same document, and a same docbase management system will definitely produces identical output for a same document. Therefore the task of generating page bitmaps is transferred from the application to the docbase management system, and it is an easy way to keep consistent page bitmap among different applications for a same document.
Furthermore, the instruction of getting page bitmap may target a specified area on a page, i.e., request to show only an area of a page. For example, when the page is larger than the screen, the whole page needs not to be shown, and while scrolling the page only the scrolled area needs to be re-painted. The instruction may also allow getting a page bitmap constituted of specified layers, especially a page bitmap constituted of a specified layer and all layers beneath the specified layer, such bitmaps will perfectly show history of the page, i.e., shows what the page looks like before the specified layer is added. If required, the instruction can specify the layers to be included in page bitmaps and the layers to be excluded from the page bitmaps.
An embodiment of the interface standard in the “operation action+object to be operated” approach is described hereinafter. In the embodiment, the interface adopts the Unstructured Operation Markup Language (UOML), which provides an instruction in the Extensible Markup Language (XML). Every action corresponds to a XML element and every object also corresponds to a XML element. When describing an instruction, a string of “operation action+object” is generated by make the XML element corresponding to the object as a sub-element of the XML element corresponding to the action. By sending the string to the lower interface unit, the upper interface unit sends an operating instruction to the docbase management system. The docbase management system executes the instruction, the lower interface unit generates another string in the UOML format according to the result of the operation in accordance with the instruction, and the string is returned to the upper interface unit so that the application will learn the result of the operation in accordance with the instruction.
The result is expressed in UOML_RET, and the definitions adopted in the UOML_RET include items as follows:
Attributes
SUCCESS: true indicating the successful operation and otherwise indicating the failing operation.
Sub-elements
ERR_INFO: optional, appearing only when the operation fails and used for describing corresponding error information.
Other sub-elements: defined based on different instructions, checking description of the instructions for reference.
UOML actions include items as follows.
1. UOML_OPEN Create or open a docbase as shown in
1.1 Attributes
1.1.1 create: true indicating creating a new docbase and otherwise indicating opening an existing docbase.
1.2 Sub-elements
1.2.1 path: a docbase directory path. It can be the name of a file in a disk, or a URL, or a memory pointer, or a network path, or the logic name of a docbase, or another expression that points to a docbase.
1.3 Return values
when the operation succeeds, a sub-element “handle” is added into the UOML_RET to record the handle.
2. UOML_CLOSE close
2.1 Attributes: N/A
2.2 Sub-elements
2.2.1 handle: an object handle, a pointer index of the object denoted by a string.
2.2.2 db_handle: a docbase handle, a pointer index of the docbase denoted by a string.
2.3 Return values: N/A
3. UOML_GET Get
3.1 Attributes
usage: any one of “GetHandle” (get the handle of a specified object), “GetObj” (get the data of a specified object) and “GetPageBmp” (get a page bitmap).
3.2 Sub-elements
3.2.1 parent: the handle of the parent object of an object, used only when the attribute “usage” contains a value for “GetHandle”.
3.2.2 pos: a position number, used only when the attribute “usage” contains a value for “GetHandle”.
3.2.3 handle: the handle of a specified object, used only when the attribute “usage” contains a value for “GetObj”.
3.2.4 page: the handle of the page to be displayed, used only when the attribute “usage” contains a value for “GetPageBmp”.
3.2.5 input: describing the requirements for an input page, e.g., requiring to display the contents of a layer or multiple layers (the present logged role must have the privilege to access the layer(s) to be displayed), or specifying the size of the area to be displayed by specifying the clip area, used only when the attribute “usage” contains a value for “GetPageBmp”.
3.2.6 output: describing the output of a page bitmap, used only when the attribute “usage” contains a value for “GetPageBmp”.
3.3 Return values
3.3.1 When the attribute “usage” contains a value for “GetHandle” and the operation on the object succeeds, a sub-element “handle” is added into the UOML_RET to record the handle of the posth sub-object of the parent object.
3.3.2 When the attribute “usage” contains a value for “GetObj” and the operation on the object succeeds, a sub-element “xobj” is added into the UOML_RET to record the XML expression of the data that includes the handle object
3.3.3 When the attribute “usage” contains a value for “GetPageBmp” and the operation on the object succeeds, a location is specified in the “output” sub-element to export a page bitmap.
4 UOML_SET Set as shown in
4.1 Attributes: N/A
4.2 Sub-elements
4.2.1 handle: setting an object handle
4.2.2 xobj: description of an object;
4.3 Return values: N/A
5 UOML_INSERT Insert as shown in
5.1 Attributes: N/A
5.2 Sub-elements
5.2.1 parent: the handle of a parent object
5.2.2 xobj: description of an object
5.2.3 pos: the position of the inserted object
5.3 Return values
When the operation on an object succeeds, the object indicated by the “xobj” parameter is inserted into the parent object as the posth sub-object of the parent object and a “handle” sub-element is included in the UOML_RET to indicate the handle of the newly inserted object.
6. UOML_DELETE Delete as shown in
6.1 Attributes: N/A
6.2 Sub-elements
6.2.1 handle: the handle of the object to be deleted
6.3 Return values: N/A
7. UOML_QUERY Search as shown in
7.1 Attributes: N/A
7.2 Sub-elements
7.2.1 handle: the handle of the docbase to be searched for
7.2.2 condition: search terms
7.3 Return values
When the operation succeeds, a “handle” sub-element is included in the UOML_RET to indicate the handle of the search results, a “number” sub-element indicates the number of the search results, and UOML_GET can be used for getting each search result.
UOML objects include a docbase (UOML_DOCBASE), a docset (UOML_DOCSET), a document (UOML_DOC), a page (UOML_PAGE), a layer (UOML LAYER), an object stream (UOML_OBJGROUP), a text (UOML_TEXT), an image (UOML_IMAGE), a line (UOML_LINE), a curve (UOML_BEIZER), an arc (UOML_ARC), a path (UOML PATH), a source file (UOML_SRCFILE), a background color (UOML_BACKCOLOR), a foreground color (UOML_COLOR), a ROP(UOML_ROP), a character size (UOML_CHARSIZE) and a typeface (UOML_TYPEFACE).
The method for defining the objects is explained hereinafter with reference to UOML_DOC, UOML_TEXT and UOML_CHARSIZE as follows.
1 UOML_DOC
1.1 Attributes: N/A
1.2 Sub-elements
1.2.1 metadata: metadata
1.2.2 pageset: pages
1.2.3 fontinfo: an embedded font
1.2.4 navigation: navigation information
1.2.5 thread: thread information
1.2.6 minipage: thumbnail image
1.2.7 signature: a digital signature
1.2.8 sharesource: shared source
1.2.9 shareobj: shared objects in the document
2 UOML_PAGE
2.1 Attributes
2.1.1 resolution: logical resolution
2.1.2 size: size of the page core, including a width value and a height value
2.1.3 rotation: rotation angle
2.1.4 log: history
2.2 Sub-elements
2.2.1 GS: initial graphic statuses, including charstyle (character style), linestyle (line style), linecap (line cap style), linejoint (line joint style), linewidth (line width), fillrule (rule for filling), charspace (character space), linespace (line space), charroate (character rotation angle), charslant (character slant direction), charweight (character weight), chardirect (character direction), textdirect (text direction), shadowwidth (shadow width), shadowdirect (shadow direction), shadowboderwidth (shadow border width), outlinewidth (outline width), outlineboderwidth (outline border width), linecolor (line color), fillcolor (color for filling), backcolor (background color), textcolor (text color), shadowcolor (shadow color), outlinecolor (outline color), matrix (transform matrix) and cliparea (clip area)
2.2.2 metadata: metadata
2.2.3 layerset: layers of the page
2.2.4 signiture: digital signatures
2.2.5 log: history
3. UOML_TEXT
3.1 Attributes:
2.1.1 encoding:encoding pattern of text
3.2 Sub-elements
3.2.1 TextData:contents of the text
3.2.2 CharSpacingList: a list of the spacing values for characters with irregular space
3.2.3 StartPos: the starting position
4 UOML_CHARSIZE
4.1 Attributes
4.1.1 width: character width
4.1.2 height: character height
4.2 Sub-elements: N/A
5 UOML_LINE
5.1 Attributes
5.1.1 LineStyle: line style
5.1.2 LineCap: line cap style
5.2 Sub-elements
5.2.1 StartPoint: the coordinate of the starting point of the line
5.2.2 EndPoint: the coordinate of the ending point of the line
6. UOML_BEIZER
6.1 Attributes
6.1.1 LineStyle: line style
6.2 Sub-elements
6.2.1 StartPoint: the coordinate of the starting point of a Bessel curve
6.2.2 Control1_Point: first control point of the Bessel curve
6.2.3 Control2_Point: second control point of the Bessel curve
6.2.4 EndPoint: the coordinate of the ending point of the Bessel curve
7. UOML_ARC
7.1 Attributes
7.1.1 ClockWise: the direction of the arc
7.2 Sub-elements
7.2.1 StartPoint: the coordinate of the starting point of the arc
7.2.2 EndPoint: the coordinate of the ending point of the arc
7.2.3 Center: the coordinate of the center of the arc
8. UOML_COLOR
8.1 Attributes
8.1.1 Type: Color type, i.e., RGB or CMYK
8.2 Sub-elements
RGB mode
8.2.1 Red: red
8.2.2 Green: green
8.2.3 Blue: blue
8.2.4 Alpha: transparency
CMYK mode
8.2.5 Cyan: cyan
8.2.6 Magenta: magenta
8.2.7 Yellow: yellow
8.2.8 Black_ink: black
The definitions of the remaining UOML objects can be deduced from the above description. When the application requests an operation in the docbase management system, a corresponding UOML instruction is generated based on a corresponding UOML action and UOML object according to the XML grammar; and the application issues the operating instruction to the docbase management system by sending the UOML instruction to the docbase management system.
For example, the operation of creating a docbase can be initiated by the executing instruction:
TABLE-US-00001<UOML_OPEN create=“true”>
<path val=“f:\\data\\docbase1.sep”/></UOML_OPEN>
And the operation of creating a docset can be initiated by the executing instruction:
TABLE-US-00002<UOML_INSERT><parent val=“123.456.789”/>
<pos val=“1”/><xobj><docset/></xobj></UOML_INSERT>
It should be noted that, although UOML is defined with XML, prefix expressions of standard XML format such as “<?xml version=“1.0” encoding=“UTF-8”?>” and “xmlns:xsi=“http://www.w3.org/2001/XMLSchema-instance”” are omitted to simplify the instructions; however, those familiar with XML may add the expressions at will.
The instructions may also be defined in a language other than the XML, e.g., the instructions can be constructed like PostScript, and in such a case the above examples of instructions will be changed into:
1, “f:\\data\\docbase1.sep”, /Open
/docset, 1, “123.456.789”, /Insert
Instructions in other string formats may also be defined according to the same theory; the instructions may even be defined in a non-text binary format.
An embodiment in which every operation on every object can be expressed in an instruction is explained hereinafter. In this embodiment, inserting a docset can be indicated by “UOML_INSERT_DOCSET” and inserting a page can be indicated by “UOML_INSERT_PAGE”. The definition details are as follows:
UOML_INSERT_DOCSET: used for inserting a docset in a docbase
Attributes: N/A
Sub-elements
parent: the handle of the docbase
pos: the position of the docset to be inserted
Return value: when the operation succeeds, a sub-element “handle” is included in the UOML_RET to indicate the handle of the newly inserted docset
Therefore the instruction shall appears as follows:
TABLE-US-00003 <UOML_INSERT_DOCSET><parent val=“123.456.789”/><pos val=“1”/></UOML_INSERT_DOCSET>
However, such approach for defining instructions is inconvenient since every legal operation on every object needs an independent instruction.
An embodiment in which the interface standard is implemented by invoking a function is explained hereinafter. In the embodiment, the upper interface sends an instruction to the docbase management system by invoking an interface function of the lower interface. The embodiment, called the UOI, is explained with reference to C++ language. In the embodiment, UOI_Object is defined as the base class of all objects and a function is defined for every action respectively. The parameter of those functions can be a pointer or reference to the base class so that the functions can be applied to all objects.
1. Define a UOI return value structure:
Then, the basic classes of all UOI objects are defined.
2. Define UOI functions as follows in correspondence with the UOML actions in the embodiment of the “operation action+object to be operated” approach.
Open or create a docbase, and return the handle of the docbase in the “pHandle” if the operation succeeds:
UOI_RET UOI_Open (char *path, BOOL bCreate, HANDLE *pHandle).
Close the handle in the db_handle docbase, and if the handle value is NULL, the whole docbase will be closed:
UOI_RET UOI_Close (HANDLE handle, HANDLE db_handle).
Get the handle of a specified child object:
UOI_RET UOI_GetHandle (HANDLE hParent, int nPos, HANDLE *pHandle).
Get the type of the object pointed to by the handle:
UOI_RET UOI_GetObjType (HANDLE handle, UOI_Object ::Type *pType).
Get the data of the object pointed to by the handle:
UOI_RET UOI_GetObj (HANDLE handle, UOI_Object *pObj).
Get a page bitmap:
UOI_RET UOI_GetPageBmp (HANDLE hPage, RECT rect, void *pBuf).
Set an object:
UOI_RET UOI_SetObj (HANDLE handle, UOI_Object *pObj).
Insert an object:
UOI_RET UOI_Insert (HANDLE hParent, int nPos, UOI_Object *pObj, HANDLE *pHandle=NULL).
Delete an object:
UOI_RET UOI_Delete (HANDLE handle).
Search, and the number of search results is returned in “pResultCount” while the handles of the search results are returned in “phResult”:
UOI_RET UOI_Query (HANDLE hDocbase, const char *strCondition, HANDLE *phResult, int *pResultCount).
3. Define various UOI objects. The following examples include UOI_Doc, UOI_Text and UOML_CharSize.
The way of applying the UOI is explained with reference to the following example. First a docbase shall be created:
ret=UOI_Open(“f:\\data\\docbase1.sep”, TRUE, &hDocBase).
4. Construct a function used for inserting a new object.
5. Construct a function used for getting an object directly.
When an interface function is defined for every operation on every object, the instruction for inserting a docset is sent to the docbase management system by the upper interface invoking the interface function of the lower interface in the following way:
UOI_InsertDocset(pDocbase, 0).
The interface standard may also encapsulate various object classes, e.g., a docbase class, and define an operation to be performed on the object as a method of the class, e.g.:
The upper interface unit sends an operating instruction of inserting a docset to the docbase management system by invoking a function of the lower interface unit in following method: pDocBase.InsertDocset(0).
Different interface standards can be designed in the same way as described above for applications developed based on Java, C#, VB, Delphi, or other programming languages.
As long as an interface standard includes no feature associated with a certain operation system (e.g., WINDOWS, UNIX/LINUX, MAC OS, SYMBIAN) or hardware platform (e.g., x86CPU, MIPS, PowerPC), the interface standard can be applied cross-platform so that different applications and docbase management systems on different platforms can use the same interface standard. Even an application running on one platform may invoke a docbase management system running on another platform to proceed with an operation. For example, when the application is installed on a client terminal in a PC using Windows OS and the docbase management system is installed on a server in a mainframe using Linux OS, the application can still invoke the docbase management system on the server to process documents just like invoking a docbase management system on the client terminal.
When the interface standard includes no feature associated with a certain program language, the interface standard is further free from dependency on the program language. It can be seen that the instruction string facilitates the creation of a more universal interface standard independent of any platform or program language, especially when the instruction string is in XML, because all platforms and program languages in the prior art have easy-to-get XML generating and parsing tools. Therefore, the interface standard will fit all platforms perfectly and be independent of program languages, and the interface standard will make it more convenient for engineers to develop an upper interface unit and a lower interface unit.
More interface standards can be developed based on the same method of defining the interface standard described above.
One skilled in the art can understand that more operating instructions can be added to the interface standard based on the embodiments described above in the method of constructing instructions as described above, and the operating instructions can also be simplified based on the embodiments. When the universal document model is simplified, the operating instructions can be simplified accordingly. The interface standard can include at a minimum the operating instructions for creating a document, creating a page, and creating a layout object.
The working process of the document processing system in accordance with the present invention is explained with reference to
The application may include any software of an upper interface unit conforming with the interface standard, e.g., the Office software, a contents management application, a resource collection application, etc. The application sends an instruction to the docbase management system when the application needs to process a document, and the docbase management system performs a corresponding operation according to the instruction.
The docbase management system may store and organize the data of the docbase in any form, e.g., the docbase management system may save all documents in a docbase in one file on a disk, or create one file on the disk for one document and organize the documents by using the file system functions of the operating system, or create one file on the disk for one page, or allocate room on the disk and manage the disk tracks and sectors without referencing the operating system. The docbase data can be saved in a binary format, in XML, or in binary XML. The page description language (used for defining objects including texts, graphics, and images in a page) may adopt PostScript, PDF, or SPD, or a customized language. In summary, any implemented method that achieves the interface standard functions defined herein is acceptable.
For example, the docbase data can be described in XML and when the universal document model is hierarchical, an XML tree can be built accordingly. An operation of inserting adds a node in the XML tree and an operation of deleting deletes a node in the XML tree, an operation of setting sets the attributes of a corresponding node, and an operation of getting gets the attributes of the corresponding node and returns the attribute information to the application, and an operation of querying traverses all related nodes. A further description of an embodiment is given as follows.
1. XML is used for describing every object; therefore an XML tree is created for each object. Some objects show simple attributes and the XML trees corresponding to the objects will have only the root node; some objects show complicated attributes and the XML trees corresponding to the objects will have root node and subnodes. The description of the XML trees can be created with reference to the XML definitions of the operation objects given in the foregoing description.
2. When a new docbase is created, a new XML file whose root node is the docbase object is created.
3. When a new object (e.g., a text object) is inserted into the docbase, the XML tree corresponding to the new object is inserted under the corresponding parent node (e.g., a layer). Therefore, every object in the docbase corresponds to a node in the XML tree whose root node is the docbase.
4. When an object is deleted, the node corresponding to the object and the subnodes thereof are deleted. The deletion starts from a leaf node in a tree traversal from the bottom to the top.
5. When an attribute of an object is set, the attribute of the node corresponding to the object is set to the same value. If the attribute is expressed as an attribute of a subnode, the attribute of the corresponding subnode is set to the same value.
6. In the process of getting an attribute of an object, the node corresponding to the object is accessed and the attribute of the object is retrieved according to the corresponding attribute and subnodes of the node.
7. In the process of getting the handle of an object, the XML path of the node corresponding to the object shall be returned.
8. When an object (e.g., a page) is copied to a specified position, the whole subtree starting from the node corresponding to the object is copied to a position right under the parent node corresponding to the specified position (e.g., a document). When the object is copied to another docbase, the object referenced by the subtree (e.g., an embedded font) is also copied.
9. In the process of performing an instruction of getting a page bitmap, a blank bitmap in a specified bitmap format is created first in the same size of the specified area, then all layout objects of the specified page are traversed. Every layout object in the specified area (including the objects that have only parts in the area) is rendered and displayed in the blank bitmap. The process is complicated and can be performed by those skilled in the art; however, the process is still covered by the RIP (Raster Image Processor) technology in the prior art and will not be described herein.
10. When a role object is created, a random PKI key pair (e.g., 512-digits RSA keys) is generated, the public key of the PKI key pair is saved in the role object and the private key is returned to the application.
11. When the application logs in, a random data block (e.g., 128 bytes) is generated and encrypted with the public key of the corresponding role object to obtain the cipher data. The cipher data are sent to the application, the application decrypts the cipher data block and the decrypted data block is authenticated. If the data block is correctly decrypted, the application is proved to possess the private key of the role and will be allowed to log in. Such authentication process may be repeated for three times, and the application is allowed to log in only when the application passes all three authentication processes.
12. When a target object is signed to obtain a signature, the subtree starting from the node corresponding to the object is signed to obtain the signature. The subtree is regularized first so that the signature will be free from any effects of physical storage variation, i.e., by logically equivalent alterations (e.g., changes of pointer caused by the changes of storage position). The regularization method includes:
traversing all nodes in the subtree whose root node is the target object (i.e., target object and the sub-object thereof) in a depth-first traversal, regularizing each node in the order of the traversal and joining the regularization result of each node.
The regularization of a node in the subtree includes: calculating the HASH value of the subnode number of the node, calculating the HASH values of the node type and node attributes, joining the obtained HASH values of the node type and node attributes right behind the HASH value of the subnode number according to the predetermined order, and calculating the HASH value of the joined result to obtain the regularization result of the node. When an object also needs to be signed to obtain the signature because the object is referenced by a node in the subtree, the object is regarded as a subnode of the node and is regularized in the method described above.
After the regularization, the HASH value of the regularization can be generated and the signature can be obtained by encrypting the HASH value with the private key of the role according to the techniques in the prior art, which will not be described herein.
In the regularization process, the regularization of a node in the subtree may also include: joining the sub-node number of the node, the node type and node attributes in an order with separators in between, and calculating the HASH value of the joined result to obtain the regularization result of the node. Or, the regularization of a node in the subtree may include: joining the subnode number length, the node type length, and the node attribute lengths in an order with separators in between, and further joining the already joined lengths with the sub-node number, node type and node attributes, then the regularization result of the node is obtained. In summary, the step of regularizing a node in the subtree may include the following step: joining original values or transformed values (e.g., HASH values, compressed values) of: the subnode number, node type, and node attributes, and the lengths of the subnode number/node type/node attributes (optional), in a predetermined order directly or with separators in between.
The predetermined order includes any predetermined order of arranging the subnode number length, node type length, node attribute lengths, subnode number, node type, and node attributes.
In addition, either depth-first traversal or width-first traversal is applied in the traversal of the nodes in the subtree.
It is easy to illustrate various modifications of the technical scheme of the present invention. For example, the scheme may include joining the subnode number of every node with separators in between in the order of depth-first traversal and then joining with the regularization results of other data of every node. Any method that arranges the subnode numbers, node types and node attributes of all nodes in the subtree in a predetermined order constitutes a modification of this embodiment.
13. When setting a privilege on an object, the simplest method includes: recording the privileges of every role on the object (including the subobjects thereof) and comparing the privileges of the role when the role accesses the object. If an operation is within the privileges, the operation is accepted; otherwise error information is returned. A preferred method applied to the present invention includes: encrypting corresponding data and controlling a privilege with a key; when a role cannot present the correct key, the role does not have a corresponding privilege. This preferred method provides better anti-attack performance. A detailed description of the steps of the preferred method is as follows.
A PKI key pair is generated for a protected data region (usually a subtree corresponding to an object and the sub-objects thereof), and the data region is encrypted with the encryption key of the PKI key pair.
When a role is granted read privilege, the decryption key of the PKI key pair is passed to the role and the role may decrypt the data region with the decryption key in order to read the data correctly.
When a role is granted write privilege, the encryption key of the PKI key pair is passed to the role and the role may encrypt modified data with the encryption key in order to write data into the data region correctly.
Since the encryption/decryption efficiency of the PKI keys is low, a symmetric key may be used for encrypting the data region. The encryption key further encrypts the symmetric key while the decryption key may decrypt the cipher data of the symmetric key to retrieve the correct symmetric key. The encryption key may be further used for signing the data region to obtain a digital signature to prevent a role with the read privilege only from modifying the data when the role is given the symmetric key. In such a case, a role with the write privilege signs the data region to obtain a new signature every time the data region is modified; therefore, the data will not be modified by any role without the write privilege.
When a role is given the encryption key or decryption key, the encryption key or decryption key may be saved after being encrypted by the public key of the role, so that the encryption key or decryption key can only be retrieved with the private key of the role.
In this embodiment, the system and method for document data security management provided by the present invention are applied to the docbase management system described in the fore-going description; however, the present invention can also be applied to any system other than the docbase management system.
The system for document data security management provided by the present invention is explained herein first.
The system for document data security management of the present invention includes a role management unit, a security session channel unit, an identity authentication unit, an access control unit and a signature unit. The role management unit is used for managing at lease one role and has the functions of creating a role, granting a privilege to a role and bereaving a role of a privilege. A role can be identified with at least one unique ID and one unique PKI key pair, however, the role object saves only the ID and the public key of the role, the private key of the role is given to the application. The role can also be identified with a unique ID and a login password, and in such a case the role object saves only the ID and the encrypted login password. The ID of a role can be any number or string as long as different roles are given different IDs. The PKI algorithm can be either ECC algorithm or RSA algorithm.
A number of roles are defined in a docbase and the role objects are sub-objects of the docbase. When corresponding universal document model does not include a docbase object, the roles shall be defined in documents, i.e., the role objects shall be the sub-objects of document objects and all docbases in the document data security management system shall be replaced with documents.
Preferably, all applications are allowed to create a new role to which no privilege is granted. Certain privileges can be granted to the new role by existing roles with re-license privilege.
The key returned in response to an instruction of creating a role object shall be used for login process, the key should be kept carefully by the application, and the key is usually a private key of a PKI key pair or a login password.
A special default role can be created in the system for document data security management. When a default role is created, corresponding docbase can be processed with the default role even when no other roles log in. Preferably, a docbase creates a default role with all possible privileges when the docbase is created.
The process performed by the application from using a role (or roles) to log in so as to performing a number of operations and to logging out is regarded as a session. A session can be identified with session identification and a logged role list. The session can be performed on a security session channel in the security session channel unit which keeps at least a session key for encrypting the data transmitted on the security session channel. The session key may be an asymmetric key, or a commonly used symmetric key with more efficiency.
The identity authentication unit is used for authenticating the identity of a role when the role logs in. The identity authentication is role oriented and any role except the default role may log in only after presenting the key of the role. When a role wants to log in and the key of the role is a PKI key, the identity authentication unit retrieves the public key of the role from the role object according to the role ID and authenticates the identity of the role by using the “challenge-response” mechanism described in the fore-going description; when the key of the role is a login password, the identity authentication unit retrieves the public key of the role from the role object according to the role ID and draws comparison.
The application may log in as multiple roles at the same time and the privileges granted to the application shall then be the union of the privileges of the roles.
The access control unit is used for setting an access control privilege for document data, and a role can only access document data according to the access control privilege granted to the role. The privilege data can be managed by the access control unit so that some roles may acquire the privilege of other role and some roles may not. A role can modify privileges of other roles in normal re-license or bereave process only when the role is granted re-license privilege or bereave privilege; directly writing data into the privilege data is not allowed.
An access privilege for any role on any object (a docbase, docset, document, page, layer, object group, layout object) can be set up, and if a privilege on an object is granted to a role, the privilege can be inherited by all sub-objects of the object.
Access privileges include any one or any combination of the following privileges: read privilege (whether a role may read data), write privilege (whether a role may write into data), re-license privilege (whether a role may re-license, i.e., grant part of or all the privileges of the role to another role), bereave privilege (whether a role may bereave of privilege, i.e., delete a part or all of the privileges of another role) and print privilege (whether a role may print data), and the present invention does not limit the privileges. Preferably, a docbase creates a default role with all possible privileges when the docbase is created so that the creator of the docbase has all privileges on the docbase.
The signature unit is used for attaching a signature to any logical data specified among the document data in the system for document data security management. A role signature can be attached by the signature unit with corresponding private key and the validity of the role signature on the logical data can be verified with the public key.
The role signature can be attached to all objects. The signature covers the sub-objects of the signed object and the objects referenced by the signed object.
The method for document data security management is further explained herein with reference to the system for security management described above.
As shown in
When a docbase is created, the role management unit automatically grants all possible privileges on the docbase, including read privilege, write privilege, re-license privilege and bereave privilege on all objects, to the default role of the docbase.
The security session channel unit sets up a security session channel between the application and the docbase management system and initiates a session.
Determine whether the session has been successfully initiated according to session identification; if the session has been successfully initiated, the security session channel setup process shall end, otherwise the security session channel setup process shall proceed.
Either the application or the docbase management system generates a random PKI key pair.
The party which generates the random PKI key pair sends the public key of the PKI key pair to the other party.
The other party generates a random symmetric key as the session key, encrypts the session key with the public key and sends the encrypted session key to the party which generates the random PKI key pair.
The party which generates the random PKI key pair decrypts the encrypted session key with the private key of the PKI key pair.
Set up session identification.
Set the logged role list as the default role.
Role logs in
The application provides the ID of a role that shall log in and a docbase in which the role shall log.
The identity authentication unit checks the logged role list of the session, if the role (including the default role) has logged in, this step shall end, otherwise this step shall proceed.
when the key of the role is a PKI key, the identity authentication unit retrieves the public key of the role from the role object; when the key of the role is a login password, proceed Step h) directly.
The identity authentication unit generates a random data block and encrypts the data block with the public key of the role.
The identity authentication unit sends the encrypted data block to the application.
The application decrypts the encrypted data block with the private key of the role and sends the decrypted data back to the identity authentication unit.
The identity authentication unit checks whether the returned data is correct, and if the data is incorrect, the role will fail to log in, otherwise directly proceed Step i).
The application provides a login password and the identity authentication unit compares the login password saved in the role object with the login password provided by the application, if the two passwords are identical, the login process shall proceed; otherwise the role will fail to log in.
Add the role into the logged role list of the session.
Create a new role
The application issues an instruction of creating a new role.
The role management unit generates a unique role ID.
When the instruction requires the key of the to-be-created role to be a PKI key, the role management unit generates a random PKI key pair; when the instruction requires the key of the to-be-created role to be a login password, the login password of the role shall be the password specified by the instruction or generated at random by the role management unit.
The role management unit creates a role object in the docbase and saves the ID and the key (the public key or login password) in the role object, and the privilege of the role is null, i.e., the role has no privilege on any object.
Return the ID and the key (the private key or login password) to the application.
Grant a privilege P on an object O to a role R
When granting a privilege on an object, the simplest method includes: recording the privileges of each role on the object (including the sub-objects thereof) and comparing the privileges of each role when the role log in, if an operation within the privileges, the operation shall be accepted, otherwise error information shall be returned. A preferred method applied to the present invention includes: encrypting corresponding data and controlling privileges with a key, when a role cannot present a correct key, the role does not have corresponding privilege. This preferred method provides better anti-attack performance.
The application sends a privilege request.
The role management unit obtains the union of the privileges of all roles in the logged role list on the object O and determines whether the union is a superset of the privilege P and whether the union includes re-license privilege. If the union is a superset of the privilege P and the union includes the re-license privilege, the process shall proceed, otherwise the granting of the privilege will fail (because the privileges of all the roles still do not include a privilege used for granting).
The role management unit adds the privilege P on the object O into the privilege list of the role R. If the privilege P does not include read or write privilege, the privilege granting process is completed, otherwise the process continues.
The access control unit checks whether read/write access control privilege is set up on the object O. If no read/write access control privilege is set up on the object O, steps as follows shall be performed.
Generate a random symmetric key and a random PKI key pair.
Encrypt the object O with the symmetric key; if the read/write access control privilege is set up on a subobject of the object O, the subobject shall remain unchanged.
A PKI key pair shall be generated for a data sector to be protected (usually a subtree corresponding to an object and the subobjects thereof), and the data sector is encrypted with the encryption key of the PKI key pair.
Encrypt the symmetric key with the encryption key of the PKI key pair, save the encryption word and sign the target object to obtain a signature.
Check all roles in the docbase. If a role has read privilege on object O (here the object O may be a subobject of the object on which the role has the read privilege), the decryption key shall be encrypted with the public key of the role and encryption word of the decryption key is saved in the privilege list of the role. If a role has write privilege on object O (here the object O may be a subobject of the object on which the role has the write privilege), the encryption key shall be encrypted with the public key of the role and encryption word of the encryption key is saved in the privilege list of the role.
Proceed Step h).
Choose a role that has needed privilege (the read privilege or write privilege) on the object O from all logged roles.
Obtain the encryption word of a corresponding key corresponding to the object O from the privilege list of the role (the read privilege requires the decryption key and the write privilege requires the encryption key, the combination of the read privilege and write privilege requires both keys), if the key of the role is a PKI key, the encryption word of the corresponding key is sent to the application and Step g) is performed; if the key of the role is a login password, the access control unit decrypts the encryption word of the corresponding key and then Step h) is performed.
When a role is granted the read privilege, the decryption key of the PKI key pair is passed to the role and the role may decrypt the data sector with the decryption key to read the data correctly. When a role is granted the write privilege, the encryption key of the PKI key pair is passed to the role and the role may encrypt modified data with the encryption key in order to write data into the data sector correctly.
The application decrypts encryption word of the corresponding key with the private key of the role to retrieve the key and returns the key to the access control unit.
The access control unit encrypts corresponding key according to the privilege P, generates corresponding encryption word of the corresponding key and saves the encryption word into the privilege list of the role R.
When a role is given an encryption key or decryption key, the encryption key or decryption key may be saved after being encrypted with the public key of the role, so that the encryption key or decryption key can only be retrieved with the private key of the role.
Since the encryption/decryption efficiency of the PKI keys is low, a symmetric key may be used for encrypting the data sector and the encryption key further encrypts the symmetric key while the decryption key may decrypt the encrypted key data to retrieve the correct symmetric key. The encryption key may be further used for attaching a digital signature to the data sector to prevent a role with read privilege only from modifying the data when the role is given the symmetric key. In such case a role with write privilege attaches a new signature to the data sector every time when the data sector is modified; therefore the data will not be modified by any role without write privilege.
Bereave a role R of a privilege P on an object O
The application sends a request of bereaving of a privilege.
The role management unit checks all roles in the logged role list to determine whether there is a role has a bereave privilege on the object O. If no role has the bereave privilege, the process of bereaving of the privilege will fail, otherwise the process continues.
Delete the privilege P from the privileges of the role R on the object O.
If the privilege P includes read or write privilege, corresponding decryption key or encryption key for the object O shall be removed from the privilege list of the role R.
Read an object O
The application sends an instruction of reading the object O.
The access control unit checks the privileges of all roles in the logged role list on the object O and determines whether there is at least one role in the logged role list has read privilege on the object O. If no role has the read privilege, the reading process fails; otherwise the process continues.
Check whether read/write access control privilege is set up on the object O. If no read/write access control privilege is set up, check the parent object of the object O and the parent object of the parent object until an object with the read/write access control privilege is found.
Choose a role that has the read privilege on the found object.
Extract the encryption word of the decryption key of the found object from the privilege list of the role, when the key of the role is a PKI key, the encryption word of the decryption key is sent to the application and Step f) is performed; when the key of the role is a login password, the access control unit decrypts the encryption word of the decryption key and Step g) is performed.
The application decrypts the encryption word of the decryption key with the private key of the role to retrieve the decryption key and returns the decryption key to the access control unit.
The access control unit decrypts encryption word of the symmetric key of the object with the decryption key to retrieve the symmetric key of the object.
Decrypt encryption word of the data of the object O with the symmetric key to retrieve the data of the object O.
Return the decrypted data of the object O to the application.
Write an object O
The application sends an instruction of writing into the object O.
The access control unit checks the privileges of all roles in the logged role list on the object O and determines whether there is at least one role in the logged role list has write privilege on the object O. If no role has the write privilege, the writing process fails, otherwise the process continues.
Check whether read/write access control privilege is set up on the object O. If no read/write access control privilege is set up, check the parent object of the object O and the parent object of the parent object until an object O1 with the read/write access control privilege is found.
Choose a role that has the write privilege on the object O1.
Extract the encryption word of the encryption key of the object O1 from the privilege list of the role. When the key of the role is a PKI key, the encryption word of the encryption key is sent to the application and Step f) is performed. When the key of the role is a login password, the access control unit decrypts the encryption word of the encryption key and Step g) shall be performed.
The application decrypts the encryption word of the encryption key with the private key of the role to retrieve the encryption key of the object O1 and returns the encryption key of the object O1 to the access control unit.
Encrypt modified data of the object O with the encryption key of the object O1 (if read/write access control privilege is set up on a subobject of the object O, the subobject is encrypted with the original key of the subobject).
Overwrite the original data with the encrypted data and the writing process shall end.
Sign an object O to obtain a signature
The application sends an instruction of signing an object O to obtain a signature.
The access control unit regularizes the data of the object O.
When a signature is attached to an object, the signature shall be attached to the subtree starting from the node corresponding to the object. The regularization should be done first so that the signature will be free from being affected by physical storage variation, i.e., by logically equivalent alterations (e.g., change of pointer caused the change of storage position). The regularization method is given in the fore-going description.
Calculate HASH value of the regularization result.
Send the HASH value to the application.
The application encrypts the HASH value with the private key of the role (i.e., the signature) when the key of the role in the logged role list is a PKI key.
The application returns the signature result to the access control unit
The access control unit saves the signature result in a digital signature object.
log out a logged role
The application sends an instruction for logging out a logged role.
The security session channel unit deletes the logged role from the logged role list if the logged role list includes the logged role.
Terminate Session
Either the application or the docbase management system sends a session termination request.
The security session channel unit terminates all threads related to the present session, erases the session identification and deletes the logged role list.
The following is an embodiment of the method for document data security management of the present invention applied on a computer.
The steps described above can be enhanced or simplified in practical applications to improve work efficiency, e.g., the private keys of the roles may be cached in the session data (which will be deleted when the session is terminated), therefore the private keys need not to be sent to the application for decryption every time, or some security measures may be omitted, or some functions may be removed. To sum up, all simplifications of the method are equivalent modifications of the method of the present invention.
An embodiment of the present invention provides a machine readable medium having instructions stored thereon that when executed cause a system to: perform a security control operation on abstract unstructured information by issuing an instruction to a platform software; wherein, said abstract unstructured information are independent of the way in which corresponding storage data are stored.
An embodiment of the present invention provides a computer-implemented system, comprising: means for performing a security control operation on abstract unstructured information by issuing an instruction; means for accepting the instruction from the application and performs the security control operation on storage data corresponding to the abstract unstructured information; wherein, said abstract unstructured information are independent of a way in which said storage data are stored.
The merits of the present invention include that: the document data security management system, equipped with identity authentication mechanism, can grant access control privilege on arbitrary logic data or encrypt any logic data, wherein the encryption is associated with identity authentication, i.e., with any one role or multiple roles. The system of the present invention can further provide digital signatures for arbitrary logic data to achieve document data security management with multiple security attributes, and protects document data from being damaged.
This embodiment of the present invention provides the system for security management by providing a tree structure for document management; the system for security management authenticates the identities of roles and allows multiple roles to log into a security session related to security authentication. The identity authentication, privilege control, signature and signature verification are provided based on the roles. According to the access control, the security control privileges on document data of any subtree can be specified and granted by a role. In the present security session, the privileges of the document data of a certain subtree are the union of the privileges of all roles. In the security session, the security control privileges on the document data can be granted and bereaved of by a role. And the access control is provided by encrypting the document data of any subtree. Signatures can be attached to any subtree data and be verified, the process of signing is included in the security session and performed with the private key of a role in the role list unit. Before attaching signatures to the document data of a tree structure, the tree can be regularized so as to guarantee that different digital signatures are attached to different nodes.
The present invention also provides a system for document data security management in which identity authentication, access control and signature verification are integrated and the identity authentication, access control and signature verification on document data are not limited to the document data. All document data in the system are under security control, i.e., are subject to authentication, access control, signature and signature verification.
The document security technique provided by the present invention, including role oriented privilege management, security session channel, role authentication, login of multiple roles, regularization method for tree structure, fine-grained privilege management unit, privilege setup based on encryption, etc., can be applied to other environment as well as the document processing system provided by the present invention, and the present invention does not limit the applications of the document security technique.
In the document processing system to which the present invention is applied, an “adding without altering” scheme is adopted to enable the document processing system to be paper fidelity. Every application adds new contents to the existing document contents without altering or deleting any existing document contents; therefore, a page of the document is like a piece of paper on which different people write or draw with different pens while nobody can alter or delete the existing contents. To be specific, an application, while editing a document created by another application, adds a new layer into the document and puts all the contents added by the application into the new layer without altering or deleting contents in existing layers. Every layer of the document can be managed and maintained by one application, and no other application is allowed to edit the layer. This is a paper-based society. As long as the document processing system maintains all the features of paper, it can perfectly satisfy all present practical needs.
A digital signature object of a layer can be used for guaranteeing that the contents in the layer are not altered or deleted. The contents of the layer may be signed to obtain the digital signature; yet preferably, the contents of the layer and the contents of all layers created before the layer are signed to obtain the digital signature. The signature does not prevent further editing of the document such as inserting new comment into the documents, and the signature always remains valid as long as the newly added contents are placed in a new layer without modifying the layers that are signed to obtain the signature. However the signer of the signature is responsible only for the contents before the signature is created and is not responsible for any contents added after the signature is created. This technical scheme perfectly satisfies practical needs and is highly valuable in practice since the signature techniques in the prior art either forbid editing or destroy the signature after editing (even though the editing process including only adding without altering).
The technical scheme provided in the foregoing description does not allow alteration of existing contents in the document, even not in consideration of paper features and digital signature, all modifications are made based on a layout object, i.e., editing (adding, deleting, modifying) a layout object does not affect any other layout objects. When a user needs to edit existing contents in the document in the original, another technical scheme will satisfy the need well. The technical scheme allows the application to embed a source file (a file which is saved in the format of the application's own and which keeps a full relationship record of all objects in the document, e.g., a .doc file) into the document after the application has finished the initial editing and created a new layer for the newly edited contents. The next time the document needs to be edited, the source file is extracted from the document and the document is edited by using the source file. After the second editing process, the layer managed by the application is cleaned and the contents of the layer are regenerated. The modified source file is embedded into the document again.
To be specific, the technical scheme includes steps as follows.
When the application processes the document for the first time, the application creates a new layer and inserts the layout object(s) corresponding to the newly added contents into the new layer. At the same time, the application saves the newly added contents in the format defined by the application (i.e., the source file).
The application creates a source file object under the document object as a sub-object of the document object to embed the source file (e.g., embed as a whole in binary data format), and records the layer corresponding to the source file object.
When the same application edits the document for the second time, the application extracts corresponding source file from the corresponding source file object.
The application continues to edit the contents in the corresponding layer by modifying the source file. Since the source file is saved in the format defined by the application, the application may edit the contents with functions of the application.
After the second editing process ends, the contents of the layer are updated according to the newly edited contents (e.g., by the method of regenerating all after cleaning all), and the modified source file is embedded into the document object again.
This process is repeated to enable the application to edit the existing contents in the document in a conventional way.
The technical scheme of the present invention can maximize document interoperability. When the technical scheme of the present invention is applied to both applications and documents, and the precondition of sufficient privileges is ensured, the following functions can be achieved.
All types of applications can correctly open, display and print all types of documents;
All types of applications can add new contents to all types of documents without damaging existing signatures in the documents;
When no signature exists or an existing signature is allowed to be destroyed, all types of applications can edit existing contents of all types of documents based on layouts.
Existing contents of all types of documents can be edited in the conventional way by the original application that created the existing contents in the documents.
It can be seen that the present invention greatly facilitates the management, interoperability and security setting for the document by using the layer management.
An embodiment of the present invention is given hereinafter with reference to
The present invention provides a better security mechanism, multiple role setup and fine-grained role privilege setup. The “fine-grained” feature includes two aspects: on the one hand, a privilege may be granted on a whole document or any tiny part of the document, and on the other hand, various privileges may be set up along with the conventional three privilege levels of write/read/ inaccessible.
The present invention improves system performance and provides better transplantability and scalability. Any platform with any function can use the same interface; therefore, the system performance can be optimized continuously without altering the interface standard, and the system may be transplanted to different platforms.
The foregoing description covers the preferred embodiments of the present invention and is not intended to limit the protective scope thereof. All the modifications, equivalent replacements, or improvements in the scope of the present invention's spirit and principles are included within the protective scope of the present invention
Number | Date | Country | Kind |
---|---|---|---|
200510126683.6 | Dec 2005 | CN | national |
20051013071.6 | Dec 2005 | CN | national |
The application is continuation of U.S. patent application Ser. No. 12/133,309, filed Jun. 4, 2008, which claims priority of PCT/CN2006/003294 (filed Dec. 5, 2006), which claims priority to Chinese Application No. 200510126683.6 (filed Dec. 5, 2005) and 200510131071.6 (filed Dec. 9, 2005), the contents of which are incorporated herein by reference. The present application also relates to U.S. patent application Ser. No. 12/133,290 (filed Jun. 4, 2008), which claims the priority of International Application No. PCT/CN2006/003293 (filed Dec. 4, 2006); The present application also relates to U.S. patent application Ser. No. 12/133,296, which claims the priority of International Application No. PCT/CN2006/003297 (filed Dec. 5, 2006); U.S. patent application Ser. No. 12/133,300, which claims the priority of International Application No. PCT/CN2006/003295 (filed Dec. 5, 2006); and U.S. patent application Ser. No. 12/133,280, which claims the priority of International Application No. PCT/CN2006/003296 (filed Dec. 5, 2006), the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 12133309 | Jun 2008 | US |
Child | 13726247 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/CN2006/003294 | Dec 2006 | US |
Child | 12133309 | US |