BR112018008970B1 - PRINTING CONTAINER AND PRINTER - Google Patents

Abstract

XML FILE CONDENSATION These are examples associated with extensible markup language (XML) file condensation. An example includes generating a set of indexes from an XML file. The set of indexes may include a tag index that indexes tag terms used in the XML file, an attribute index that indexes attribute terms in the XML file, and a value index that indexes value terms in the XML file. The example also includes condensing the XML file into a condensed version of the XML file by translating the XML file according to the indices. The example also includes generating a translated file. The translated file can be created from the index set and the condensed version of the XML file.

Description

BACKGROUND OF THE INVENTION

[001] Extensible markup language (XML) is used to encode documents in a format readable by both machines and people. Although an XML-encoded document often will not cause a computer to do anything by itself, in combination with an application designed to interpret the XML document, the XML document can cause that application to perform certain functions, display certain information, use certain formatting, and so on, based on the tags used when encoding the XML document. Consequently, XML standards were developed to facilitate communication between applications and devices in formats that are agnostic to the specific devices that are used. Patterns can specify certain keywords or “tags” that will trigger specific functions to be performed. These functions can then be deployed to devices and/or applications in a manner appropriate to that device and/or application.

BRIEF DESCRIPTION OF THE DRAWINGS

[002] The present application can be more fully appreciated in connection with the following detailed description taken in conjunction with the accompanying drawings, in which similar reference characters refer to similar parts throughout the document, and in which: Figure 1 illustrates example files and data structures associated with XML file condensing. Figure 2 illustrates a flowchart of exemplary operations associated with XML file condensation.

[003] Figure 3 illustrates another flowchart of exemplary operations associated with XML file condensation.

[004] FIG. 4 illustrates an exemplary print container associated with XML file condensation.

[005] Figure 5 illustrates an exemplary printer associated with XML file condensation.

[006] Figure 6 illustrates another exemplary printer associated with XML file condensation.

[007] Figure 7 illustrates an exemplary printer on which exemplary systems, and methods, and equivalents, can operate.

DETAILED DESCRIPTION

[008] Systems, methods, and equivalents associated with extensible markup language (XML) file condensation are described. In many examples, it may be desirable to store XML files on devices or items that do not have a large amount of memory available. These items may be designed to be low cost and therefore it may be impractical to include greater memory storage space without impacting the cost of producing these items. For example, printing containers (e.g. ink cartridges) are a mass market item and pricing of containers can be competitive and therefore employing memory resources with excessive space can be expensive and unnecessarily costly.

[009] Consequently, an XML file stored in a print container can be condensed in a manner that facilitates reducing the memory impact of the XML file. Although it may take time for a printer to decondense the file when the print container is installed in the printer, this processing time may be negligible considering that much of the time involved with printing revolves around moving mechanical components of the printer. Although examples involving printing containers are described, the techniques described herein may be usable in other fields and/or applications,

[010] Consequently, a way to condense an XML file to store these XML files is disclosed. Finally, the XML file can be stored as a set of indexes and a condensed version of the XML file. Indexes can be created by dividing the text of the XML file into three types of indexes: tags, attributes, and values. The XML file can then be translated according to the indexes. The indexes and condensed XML file can then be stored in, for example, a print container. When the print container is inserted into a printer, the printer can decondense the condensed XML file into the original XML file with the use of indexes, allowing the printer to use the XML file to perform the actions described in the XML file.

[011] Figure 1 illustrates exemplary files and data structures associated with XML file condensation. It should be noted that the items depicted in Figure 1 are illustrative examples and many different files, data structures, techniques for condensing an XML file, and so on can operate according to various examples. Figure 1 illustrates an XML file 100. The XML file 100 is illustrated as having eleven lines labeled L00 to L10. The XML file 100 illustrated here is made up of three element types: tags, attributes, and values.

[012] As used herein, labels generally refer to instructions that define an action to be performed. In XML file 100, for example, “<defaults>”, “<spit...> and “<routines>” are examples of tags. Tags can include other nested tags. Two tag syntaxes are illustrated in XML file 100. The “<defaults>” tag opens at L00 and ends at L10 with a closing tag “</defaults>”, while the “<spit...>” tag begins and ends on the same line. In this example, each label is illustrated on a different line for illustrative purposes, although multiple labels could be engraved on the same line.

[013] Tags can also include attributes. In XML file 100, “mode”, “frequency”, and “granularity” are examples of attributes. As used herein, an attribute of a tag may be used to specify a parameter of the unique action triggered by that tag. Also, attributes can be assigned values. In XML file 100, "1", "normal" and "thermal_mode" are examples of values. As used herein, values may be used in association with attributes to specify the parameter of the unique action triggered by a tag that attribute modifies. By way of illustration, the “<wiper-action...>” tag has a “speed” attribute that is set to the value “1”. The use of the “speed” attribute with the ”<wiper-action” tag .../>” can thus cause the action associated with the tag ”<wiper-action.../>” to behave in a certain way. For example, the tag ”<wiper-action.../>” can cause cleaners associated with a printer to activate, and the “speed” attribute can be used to set the speed at which the cleaners will operate, which in this case is “1”.

[014] To facilitate certain condensing and compression techniques described above, it may be desirable for the XML file 100 to have a specific known set of syntaxes. This set of syntaxes can be a subset of possible XML syntaxes. For example, although XML may support values that have space characters in them, it may be desirable to ensure that values in the XML file 100 use underscores or periods rather than space characters (for example, the “termal_mode” value in line L03, “ action-defaults” on line L02). Using a subset of syntaxes can make it easier and/or more efficient to condense, compress, decompress, and decondense the XML file 100 making it easier to ensure that there is no collision due to two sentences that have two different syntaxes compressing to the same sentence compressed.

[015] As discussed above, it may be desirable to store XML file 100 in a condensed format. Although the XML file 100 as illustrated may be short enough that condensing would be unreasonable, for larger XML files that contain more complete statements with more repetition of tags, attributes, and values, condensing may be desirable. To condense the XML file 100, first an index 110 can be created. This can be achieved by identifying the tags, attributes and values in the XML file 100 and separating the same into their separate categories. Here, the XML file 100 includes 8 tags, 5 attributes and 6 values. In several examples, it may be desirable to further order the tags, attributes, and values to aid in condensing and/or a later compression pass of the XML file 100. Here, tags, attributes, and values are ordered first by their term frequency, and then alphabetically. For example, the “mode” attribute appears on lines L03, and L09, while the “frequency” attribute appears only on line L03. Similarly, the “<defaults>” tag appears on lines L00 and L10, while the “ <progress...>” appears only on line L08.

[016] Although one method of indexing the tags, attributes and values is shown, others may be used instead. By way of illustration, at index 110, the tags, attributes, and values all use the same range of index numbers 1 through 8. In other examples, indices may be designed instead of where the tags, attributes, and values are each , designated non-overlapping index ranges. Other index designations may also be appropriate.

[017] Once the index 110 has been created, encoding the index into encoded index 115 and condensing the XML file 100 into the condensed XML file 120 can begin; in Figure 1, a possible version of the encoded index 115 is shown. The items in square brackets may represent specialized encoded index identifiers 115 that are used to indicate separation between index components 110; in one example, the separators may be, for example, characters such as spaces, punctuation, a combination, known values, and so on. In coded index 115, example, 5 separators are used: “[tag_start]” which indicates a start of the tag index, “[attribute_start]” which indicates the start of the attribute index, “[value_start]” which indicates the start of the value index, “[separator]” which indicates separation between components of the index 110, and “[index_end]” which indicates the end of the encoded index 115. In cases where the encoded index 115 and condensed XML file 120 are stored as a single item, the “[index_end]” separator may also indicate the beginning of the condensed XML file 120. Additionally, some of the separators may be represented by the same specialized identifiers.

[018] As discussed above, in the illustrated example index 110, labels, attributes and values each use the same range of indices, and this range of indices starts from a known value. Consequently, the encoded index 115 may not need to identify index values of the tags, attributes, and keys within the encoded index 115. Instead, this information may be reconstructed as part of a process of decondensing the condensed XML file 120. In deployments examples in which labels, attributes and values are designated varied indices, this information can also be stored in encoded index 115.

[019] To create condensed XML file 120, XML file 100 can be translated according to index 110. Here, XML file 100 has been translated so that each pair of characters (e.g., “T2”) in the XML file condensed 120 matches a specific tag, attribute, or value from XML file 100, this match can be seen by examining index 110. Specifically, the first tag “<defaults>“ is identified as having index 2 at index 110. Thus, the first T2 of the condensed XML file 120 corresponds to the first tag “<defaults>” in the XML file 100 due to the fact that it is tag (indicated by T) number 2 at index 110. Similarly, the phrase “<spit frequency= “6000” mode = “thermal_mode/>” of line L03 of the XML file 100 corresponds to the portion of the condensed XML file 120 that reads “T7 A2 V2 A1 V8 TE” that encompasses the first and second lines of the condensed XML file 120. It should be noted that the condensed XML file 120 and the encoded index 115 may have more or fewer characters depending on how these items are created, including additional symbols that could serve a variety of purposes.

[020] In this exemplary version of the condensed XML file 120, a specialized symbol that indicates an end of tag is used. This symbol, represented as “TE”, is used to indicate to an application that interprets the condensed XML file 120, that the most recently opened tag here should be closed. By way of illustration, the last “TE” in the condensed XML file 120 corresponds to the one next to the “</defaults>” tag on line L10 of the XML file 100. In several examples, the use of the TE tag may be desirable due to the fact that certain forms of compression are more efficient the more characters are repeated. This is also a reason why ordering the tag index by term frequency is useful, as increased use of the same indexes can further increase compression efficiency,

[021] Consequently, once the XML file 100 has been condensed into the encoded index 115 and the condensed XML file 120, the combination of which will be referred to as a translated file, the translated file can be further reduced in size by employing a compression technique . Which compression technique is used may depend on how the encoded index 115 and condensed XML file 120 are created since the creation of these items may be designed as ideal for a specific data compression technique,

[022] Regardless of whether the translated file has been additionally compressed or not, the translated file can then be stored in a memory of an item with which XML file 100 is associated. An exemplary item in which this type of condensation of the XML file 100 may be desirable is a printing container that contains a supply of printing material. The printing material and/or printing container may be designed to work with a specific type of printer. The printer can be two bidirectional printers that vary, such as a desktop printer designed for home or office use, industrial-scale printers that can output hundreds of items per hour, and so on. The printer could also be a three-dimensional printer. As mentioned above, these techniques that involve condensing XML files can also be applied outside the printing field,

[023] Depending on the type of printer with which the printing vessel is associated, the printing material may include ink, toner, cleaning fluid, construction material for a 3D printer, and so on. Thus, in this example, the XML file 100 may contain instructions for the printer to which the print container is installed. These instructions can tell the printer how to operate efficiently using the printing material. Consequently, these instructions may be related to cleaning the printer, otherwise, servicing the printer, printing using the printing material, and so on. Other information could be routed to the printer this way (eg security information, general updates).

[024] Once the print container is installed on a printer, that printer can retrieve the translated file from the memory of the print container, and then begin to decompress, and decondense the translated file back to the XML file 100. As the file is decompressed will depend on the compression technique used. Decondensing the translated file can operate in reverse of creating the condensed XML file. Because the syntaxes can be limited to a known set of syntaxes, the XML file 100 can be recreated by filling in the syntaxes based on the specific ordering of tags, attributes, and values in the condensed XML file 120. After decondensing the translated file back to the XML file 100, the printer can then use the instructions to perform a function described by the XML file 100 (e.g., cleaning the printer, servicing the printer, printing using a material in the print container).

[025] In some examples, after decompressing and decondensing the translated file back to the XML file 100, the printer may combine instructions from the XML file 100 with a set of stored instructions. These stored instructions may be a set of standard instructions that the printer can use regardless of which printing material is installed, unless overridden by an instruction from an XML file such as XML file 100.

[026] It is noted that, in the following description, numerous specific details are presented to provide a full understanding of the examples. However, it is found that the examples can be practiced without limiting these specific details. In other cases, methods and structures may not be described in detail to avoid unnecessarily obscuring the description of the examples. Furthermore, the examples can be used in combination with each other.

[027] “Module”, as used herein, includes, but is not limited to, hardware, firmware, software stored on a computer-readable medium or running on a machine, and/or combinations of each to perform a function (or functions) or an action (or actions), and/or to cause a function or action of another module, method and/or system. A module may include a software-controlled microprocessor, a discrete module, an analog circuit, a digital circuit, a programmed module device, a memory device that contains instructions, and so on. Modules may include ports, combinations of ports, or other circuit components. Where multiple logic modules are described, it may be possible to incorporate the multiple logic modules into one physical module. Similarly, where a single logic module is described, it may be possible to distribute that single logic module among multiple physical modules.

[028] Figure 2 illustrates an example method 200 associated with condensing an XML file. Method 200 may be embodied in a non-transitory computer-readable medium that stores the processor-executable instructions. Instructions, when executed by a processor, may cause the processor to perform method 200. In other examples, method 200 may exist within logic gates and/or RAM of a specific application integrated circuit.

[029] Method 200 includes generating indexes from an extensible markup language (XML) file at 210, in various examples, the XML file may contain instructions that control the operation of a printer. The XML file may contain instructions that control printer operation based on a type of printing material stored in a printing material container (for example, ink cartridge). By way of illustration, different materials can affect a printer's components in different ways and can cause those components to have different maintenance needs. Thus, an XML file associated with a print container that stores a particular print material may have the ability to control the printer to perform various functions, including maintenance functions, suitable for the particular print material. The XML file may also include other instructions related to, for example, cleaning the printer, servicing the printer, printing using media, and so on.

[030] The set of indices may include several indices that include a label index, an attribute index and a value index. The tag index can index tag terms used in the XML file. The attribute index can index attribute terms in the XML file. The value index can index value terms in the XML file. In some examples, the terms in the tag index, attribute index, and value index may be ordered within their respective indexes according to the frequency of the terms within the XML file. Ordering indices according to term frequencies may be desirable due to the fact that certain compression techniques achieve higher compression rates the more terms are repeated. Consequently, when index ranges overlap, repeated use of these indexes can help achieve higher compression ratios.

[031] In various examples, the XML file may contain instructions that control the operation of a printer. The XML file may contain instructions that control printer operation based on a type of printing material stored in a printing material container (for example, ink cartridge). By way of illustration, different materials can affect a printer's components in different ways and can cause those components to have different maintenance needs. Thus, an XML file associated with a printing container that stores a particular printing material may have the ability to control the printer to perform various functions, including maintenance functions, suitable for the particular printing material. The XML file may also include other instructions related to, for example, cleaning the printer, servicing the printer, printing using media, and so on.

[032] Method 200 also includes condensing the XML file into a condensed version of the XML file. At 220, the condensed version of the XML file can be condensed by translating the XML file according to the indices. In some examples, to facilitate the creation of the indexes at 210, the condensing of the XML file at 220, and the potential decondensation of the XML file at a later point, the XML file may use a known subset of XML syntaxes. These syntaxes can be preselected so that, for example, for any two given different XML declarations, the condensed version of these two declarations is different. Similarly, syntaxes can also be selected such that for any two given different condensed statements, decondensed versions of those statements will also be different.

[033] Method 200 also includes generating a translated file. The translated file may be composed of the set of indexes created in action 210, and the condensed version of the XML file created in action 220. By way of illustration, the indexes and the condensed version of the XML file may be concatenated into a single file to create the translated file.

[034] Figure 3 illustrates a method 300 associated with XML file condensation. Method 300 includes several actions similar to those described above with reference to method 200 (Figure 2), for example, method 300 includes generating a set of indexes from an XML file at 310, condensing the XML file into a condensed version of the XML file at 320, and generate a translated file that includes the index set and the condensed version of the XML file at 330.

[035] Method 300 also includes compressing the translated file by 340. Compressing the translated file can further reduce the total file size of the translated file. Method 300 also includes storing the translated file in a memory at 350. In an example in which the XML file contains instructions that control operation of a printer in association with a printing material, the translated file may be stored in a memory at a printing material container that holds a supply of printing material. This can allow a printer to be specifically configured to use a variety of printing materials without having to store this information on the printer itself. This may be desirable, for example, when configuring the printer to use a new print material, saving memory space within the printer, and so on.

[036] Figure 4 illustrates a print container 400 associated with extensible markup language (XML) file condensing. The printing container 410 includes a supply of printing material 410. The printing material 410 may be, for example, ink, cleaning fluid, and so on. The printing container 400 also includes a printing material dispenser 420. The printing material distributor 420 can take many forms depending on how a printer to which the printing container 400 is inserted is designed to operate. For example, if the printer extracts printing material 410 from the printing container 400 to be expelled onto a printing media at another location, printing material dispenser 420 may interface with a mechanism of the printer that extracts the printing material 410 from the printing container 400. Alternatively, if the printing container is a cartridge designed to directly eject printing material 410 onto a printing medium, the printing material dispenser 420 can directly dispense printing material 410.

[037] The print container also includes a memory 430. The memory 430 includes a label index 432. The label index 432 may contain a list of label terms from an extensible markup language (XML) file. Tag terms can be arranged according to the frequency of tag terms in the XML file. Memory 430 also includes an attribute index 434. Attribute index 434 may contain a list of attribute terms from the XML file. Attribute terms can be arranged in attribute index 434 according to the frequency of attribute terms in the XML file. Memory 430 also includes a value index 436. Value index 436 may contain a list of value terms from the XML file. Value terms can be arranged in value index 436 according to the frequency of value terms in the XML file.

[038] Memory 430 also includes a condensed XML file 438. The condensed version of the XML file 438 can be created by translating the XML file according to the tag index, attribute index, and value index. In some examples, label index 432, attribute index 434, value index 436, and condensed XML file 438 may be stored in memory 430 in a compressed format. In various examples, a printer to which the print container 400 is inserted may use the label index, the attribute index, the value index, and the condensed version of the XML file to recreate the XML file. Accordingly, the recreated XML file may control a printer operation in association with one or more of printing material 410, printing container 400, printing material dispenser 420, and so on.

[039] Figure 5 illustrates a printer 500 associated with extensible markup language (XML) file condensation. The printer 500 includes a housing 510. The housing 510 may receive a printing container 599 that has a supply of printing material. The printing material can be, for example, ink, toner, cleaning fluid and so on.

[040] The printer 500 also includes a communication module 520. The communication module 520 may obtain a set of indexes and a condensed XML file from the print container 599. The condensed XML file may have been created from the set of indexes as well as an original XML file that is not stored in the print container 599. In various examples, the communication module 520 may retrieve the set of indexes and condensed XML file from a memory in the print container 599. Consequently, in this example, the housing 510 and print container 599 may contain appropriate electronic couplings to facilitate communication between communication module 520 and the memory in print container 599.

[041] The printer 500 also includes an extraction module 530. The extraction module 530 can generate a decondensed XML file. The decondensed XML file can be generated by translating the condensed XML file according to the set of indexes.

[042] The printer 500 also includes a control module 540. The control module 540 can control an operation of the printer 500 according to instructions retrieved from the decondensed XML file. In various examples, control module 540 may control one or more of cleaning a printer component, servicing a printer component, printing using printing material contained in printing container 599, and so on.

[043] Figure 8 illustrates a printer 600 associated with XML file condensation. The printer 600 includes various items similar to those described above with reference to the printer 500. For example, the printer 600 includes a housing 810 for receiving a printing container 699 having a supply of printing material, a communication module 620, a extraction module 630 and a control module 640,

[044] The printer 600 also includes a decompression module 650. The decompression module 650 can decompress the index set and the condensed XML file. Decompression of the condensed XML file and indexes can be performed when these items are stored in a print container memory 699 in a compressed format to further reduce the amount of data stored in the print container 699.

[045] The printer 600 also includes a memory 660. The memory 660 can store a set of standard instructions. Accordingly, the control module 640 can control the operation of the printer according to instructions retrieved from the decondensed XML file when the decondensed XML file modifies the standard instructions. As discussed above, printer operation may refer to cleaning the printer, servicing the printer, printing using printing material, and so on.

[046] Figure 7 illustrates an exemplary computer on which exemplary systems, and methods, and equivalents, can operate. The example computer may include components such as a processor 710 and a memory 720 connected by a bus 730. The computer 700 also includes an XML file condensing module 740, XML file condensing module 740 may perform, by itself or in combination, various functions described above with reference to exemplary systems, methods, apparatus and so on. In different examples, the XML file condensing module 740 may be deployed as a non-transitory computer-readable medium that stores processor-executable instructions, in hardware, software, firmware, an application-specific integrated circuit, and/or combinations thereof.

[047] Instructions may also be presented to computer 700 as data 750 and/or process 760 that are temporarily stored in memory 720 and then executed by processor 710. Processor 710 may be a variety of processors that include dual microprocessor and other architectures of multiple processors. Memory 720 may include non-volatile memory (e.g., read-only memory) and/or volatile memory (e.g., random access memory). Memory 720 may also be, for example, a magnetic disk drive, a solid-state disk drive, a floppy disk drive, a tape drive, a flash memory card, an optical disk, and so on. In this way, memory 720 can store process 760 and/or data 750. Computer 700 can also be associated with other devices including computers, printers, peripherals, and so on in numerous configurations (not shown).

[048] It will be evident that the foregoing description of the disclosed examples is provided to enable any person skilled in the art to produce or use the present disclosure. Various modifications to such examples will be readily apparent to those skilled in the art and the generic principles defined herein may be applied to other examples without departing from the scope of the disclosure. Accordingly, the present disclosure is not intended to be limited to the examples shown in this document, but is intended to be compatible with the broadest scope consistent with the innovative principles and features disclosed in this document.

Claims (12)

1. Printing container (400), characterized in that it comprises: a supply of a printing material (410); a printing material dispenser (420); and a memory (430) that stores: a tag index (432) that contains a list of tag terms from an extensible markup language file, XML, organized according to a frequency of tag terms in the XML file, where a label term of the label index (432) refers to an instruction that defines an action to be performed by a printer in which the printing container (400) is to be installed; an attribute index (434) that contains a list of attribute terms from the XML file organized according to a frequency of the attribute terms in the XML file, where an attribute term from the attribute index (434) is used to specify a parameter of the action triggered by the tag term; a value index (436) that contains a list of value terms from the XML file organized according to a frequency of value terms in the XML file, where a value term from the value index (436) is used in association with the attribute term to specify the parameter of the action triggered by the tag term that the attribute term should modify; and a condensed version of the XML file (438) created by translating the XML file according to the label index, attribute index and value index, where the printer on which the print container (400) is to be installed uses the label index, the attribute index, the value index and the condensed version of the XML file to recreate the XML file, where the recreated XML file controls a printer operation in association with at least one of the printing material, the print material dispenser and the print container, where the recreated XML file must modify standard instructions stored by the printer. 2. Print container according to claim 1, characterized by the fact that the terms in the label index, attribute index and value index are ordered within their respective indexes according to the frequency of the terms within the XML file . 3. The printing container of claim 1, wherein the XML file is associated with the printing container storing a particular printing material and wherein the XML file is for controlling the printer to perform a maintenance function suitable for the particular printing material. 4. Print container according to claim 1, characterized by the fact that the label index, the attribute index, the value index and the condensed version of the XML file are stored in memory in a compressed format, and wherein The XML file uses a known subset of XML syntaxes to ensure that there is no collision due to two sentences that have two different syntaxes being compressed into the same compressed sentence. 5. The printing container of claim 1, wherein the label terms, attribute terms, and value terms each use the same range of index values starting from an index value known and an identifier is used to indicate a separation between the terms in the label index, attribute index, and value index so that the index values are not identified in memory. 6. The printing container of claim 1, wherein the condensed version of the XML file comprises a symbol to indicate to an application that interprets the condensed version of the XML file that the most recently opened label in the XML file should be closed, and where the tag index, attribute index, value index and the condensed version of the XML file are stored in memory in a compressed format. 7. Print container according to claim 1, characterized by the fact that: the XML file uses a known subset of XML syntaxes; tag terms, attribute terms, and value terms each use the same range of index values starting from a known index value, and an identifier is used to indicate a separation between the terms in the tag index, attribute index and value index so that index values are not identified in memory; the condensed version of the XML file comprises a symbol to indicate to an application that interprets the condensed version of the XML file that the most recently opened tag in the XML file should be closed; and the tag index, attribute index, value index, and condensed version of the XML file are stored in memory in a compressed format. 8. The printing container of claim 1, wherein: the XML file is associated with the printing container storing a particular printing material and wherein the XML file is for controlling the printer to perform a printing function. proper maintenance for the particular print material; the XML file uses a known subset of XML syntaxes; tag terms, attribute terms, and value terms each use the same range of index values starting from a known index value, and an identifier is used to indicate a separation between the terms in the tag index, attribute index and value index so that the index values are not identified in memory, the condensed version of the XML file comprises a symbol to indicate to an application that interprets the condensed version of the XML file that the most recently opened tag in the file XML must be closed, and the tag index, attribute index, value index, and condensed version of the XML file are stored in memory in a compressed format. 9. Printer (600), characterized in that it comprises: a housing (610) for receiving a printing container (699) having a supply of printing material; a communication module (620) for obtaining, from a memory in the print container, a set of indexes comprising: a label index containing a list of label terms from an extensible markup language file, XML, organized according to a frequency of label terms in the XML file, where a label term of the label index refers to an instruction that defines an action to be performed by the printer; an attribute index that contains a list of attribute terms from the XML file organized according to a frequency of the attribute terms in the XML file, where an attribute term from the attribute index is used to specify a parameter of the action triggered by the attribute term tag; and a value index that contains a list of value terms from the XML file organized according to a frequency of value terms in the XML file, where a value term from the value index is used in association with the attribute term to specify the parameter of the action triggered by the tag term that the attribute term should modify; and a condensed XML file created from the indexes; an extraction module (630) for generating a decondensed XML file from the condensed XML file by translating the condensed XML file according to the set of indexes; a control module (640) for controlling an operation of the printer in accordance with instructions retrieved from the decondensed XML file; and a memory (660) for storing a set of standard instructions, wherein the control module is for controlling the operation of the printer in accordance with instructions retrieved from the decondensed XML file when the decondensed XML file modifies the standard instructions. 10. The printer of claim 9, wherein the extraction module is for reconstructing index values of the tag terms, attribute terms, and value terms from the index set, wherein the tag terms, terms Attribute and value terms each use the same range of index values starting from a known index value, and an identifier is used to indicate a separation between terms in the label index, attribute index, and attribute index. value so that index values are not identified in memory. 11. The printer of claim 9, wherein it comprises a decompression module (650) for decompressing the index set and the condensed XML file, where the index set and the condensed XML file are stored, in the memory in the print container, in a compressed format. 12. The printer of claim 11, wherein the XML file uses a known subset of XML syntaxes, and wherein the extraction module is to generate the decondensed XML file from the set of decompressed indexes and XML file condensed by filling out syntaxes based on an ordering of the tag terms, attribute terms, and value terms in the condensed XML file.