CN118394251B - Label generation method, device, equipment and storage medium based on hypertext links - Google Patents

Abstract

The application provides a label generation method, a device, equipment and a storage medium based on hypertext links, wherein the method comprises the following steps: acquiring an order data table corresponding to the order processing request; based on the element extraction engine, extracting identification code elements, text elements and digital elements in the order data table, and respectively generating an identification code lattice, a text lattice and a digital lattice according to rendering operation of a user; acquiring tag attribute information input by a user, generating a blank dot matrix, projecting an identification code dot matrix, a character dot matrix and a digital dot matrix to the blank dot matrix according to a preset typesetting algorithm, and generating a tag dot matrix mapping source according to typesetting operation of the identification code dot matrix, the character dot matrix and the digital dot matrix on the blank dot matrix by the user; and acquiring printer attribute information according to a preset printer selection instruction, and generating a printing instruction according to the printer attribute information and a label dot matrix mapping source.

Description

Label generation method, device, equipment and storage medium based on hypertext links

Technical Field

The present application relates to the field of artificial intelligence technologies, and in particular, to a method, an apparatus, a device, and a storage medium for generating a label based on a hypertext link.

Background

Currently, in the manufacturing industry, it is often necessary to use CodeSoft, bartender or other mainstream professional design software to make the labels. Such software is expensive and has a high technical threshold for nesting with third party software. When the third party software needs to print by using the label, the software such as CodeSoft, bartender needs to be installed on a computer, and then the template manufactured by CodeSoft, bartender is input into the third party software for label printing. In the process, the label is required to be switched among a plurality of software, the manufacturing process of the label is complex, and the conversion efficiency is low.

Disclosure of Invention

The application provides a label generation method, device and equipment based on hypertext links and a storage medium, which are used for improving label generation efficiency.

In a first aspect, an embodiment of the present application provides a tag generation method based on a hypertext link, where the hypertext link is a link of a tag design interface, and the method includes:

Acquiring an order processing request uploaded by an order system based on the label design interface, and acquiring an order data table from a preset database according to the order processing request;

Based on a preset element extraction engine, extracting key elements from the order data table to obtain identification code elements, text elements and digital elements;

generating an identification code lattice according to a first rendering operation of a user on the identification code element, generating a text lattice according to a second rendering operation of the user on the text element, and generating a digital lattice according to a third rendering operation of the user on the digital element;

Acquiring tag attribute information input by a user, generating a blank dot matrix according to the tag attribute information, and projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix according to a preset typesetting algorithm;

generating a label dot matrix mapping source according to typesetting operation of a user on the identification code dot matrix, the character dot matrix and the digital dot matrix on the blank dot matrix;

obtaining printer attribute information according to a preset printer selection instruction, generating a printing instruction according to the printer attribute information and the label dot matrix mapping source, and sending the printing instruction to a target printer so as to enable the target printer to generate a label.

In a second aspect, an embodiment of the present application provides a tag generation apparatus based on a hypertext link, where the hypertext link is a link of a tag design interface, the tag generation apparatus includes:

the data acquisition module is used for acquiring an order processing request uploaded by the order system based on the label design interface, and acquiring an order data table from a preset database according to the order processing request;

the element extraction module is used for extracting key elements from the order data table based on a preset element extraction engine to obtain identification code elements, text elements and digital elements;

The element rendering module is used for generating an identification code lattice according to a first rendering operation of a user on the identification code element, generating a text lattice according to a second rendering operation of the user on the text element, and generating a digital lattice according to a third rendering operation of the user on the digital element;

the dot matrix projection module is used for acquiring tag attribute information input by a user, generating a blank dot matrix according to the tag attribute information, and projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix according to a preset typesetting algorithm;

The typesetting modulation module is used for generating a label lattice mapping source according to typesetting operation of a user on the identification code lattice, the character lattice and the digital lattice on the blank lattice;

The instruction generation module is used for acquiring printer attribute information according to a preset printer selection instruction, generating a printing instruction according to the printer attribute information and the label dot matrix mapping source, and sending the printing instruction to a target printer so as to enable the target printer to generate a label.

In a third aspect, an embodiment of the present application provides an electronic device, including a memory and a processor;

the memory is used for storing a computer program;

The processor is configured to execute the computer program and implement the hypertext link-based tag generation method according to any of the embodiments of the present application when the computer program is executed.

In a fourth aspect, embodiments of the present application provide a computer-readable storage medium storing a computer program, which when executed by a processor causes the processor to implement a method for generating a hypertext link-based tag according to any of the embodiments of the present application.

The embodiment of the application provides a label generation method based on a hypertext link, wherein the hypertext link is a link of a label design interface, and the method comprises the following steps: based on a label design interface, acquiring an order processing request uploaded by an order system, and acquiring an order data table from a preset database according to the order processing request; based on a preset element extraction engine, extracting key elements from the order data table to obtain identification code elements, text elements and digital elements; generating an identification code lattice according to a first rendering operation of a user on the identification code element, generating a text lattice according to a second rendering operation of the user on the text element, and generating a digital lattice according to a third rendering operation of the user on the digital element; acquiring tag attribute information input by a user, generating a blank dot matrix according to the tag attribute information, and projecting an identification code dot matrix, a character dot matrix and a digital dot matrix to the blank dot matrix according to a preset typesetting algorithm; generating a label dot matrix mapping source according to typesetting operation of a user on the identification code dot matrix, the character dot matrix and the digital dot matrix on the blank dot matrix; and acquiring printer attribute information according to a preset printer selection instruction, generating a printing instruction according to the printer attribute information and a label dot matrix mapping source, and sending the printing instruction to a target printer so as to enable the target printer to generate a label. According to the method, automatic extraction of data is achieved through integrating an order system and a label design interface, order processing requests of the order system are obtained, related order data tables are automatically grabbed from a database, key elements such as identification code elements, text elements and digital elements are accurately classified by utilizing an element extraction engine, different rendering operations can be respectively carried out on the identification code elements, the text elements and the digital elements according to requirements by a user to generate corresponding lattices, diversity and visual effect adaptability of labels are greatly improved through the design, the extracted and rendered elements are accurately laid out on blank lattices appointed by the user through an intelligent typesetting algorithm, rationality and attractiveness of a label structure are guaranteed, a label lattice mapping source is generated so as to be matched with attributes of a printer, the label design application automatically generates optimized printing instructions by analyzing attribute information of the target printer, design original appearance of the labels can be kept on any equipment, the problem of misformat caused by differences of the printer is avoided, the process simplifies complicated procedures in traditional printing, and consistency and success rate debugging links of cross-equipment printing are improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic flow chart of a label generation method based on hypertext links according to an embodiment of the present application;

fig. 2 is a schematic block diagram of a label generating apparatus based on hypertext links according to an embodiment of the present application.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The flow diagrams depicted in the figures are merely illustrative and not necessarily all of the elements and operations/steps are included or performed in the order described. For example, some operations/steps may be further divided, combined, or partially combined, so that the order of actual execution may be changed according to actual situations.

It is also to be understood that the terminology used in the description of the application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be further understood that the term "and/or" as used in the present specification and the appended claims refers to any and all possible combinations of one or more of the associated listed items, and includes such combinations.

The label design application provided by the embodiment of the application is placed in the third party software in a hypertext link mode, and the label design application is called through the hypertext link in the third party software. When clicking the hypertext link of the tag design application in the third party software, a tag design interface of the tag design application will be displayed, the user can design the tag on the tag design interface, and call the printer to print the generated tag.

Referring to fig. 1, fig. 1 is a schematic flowchart of a label generating method based on hypertext links according to an embodiment of the present application. As shown in fig. 1, the specific steps of the label generating method based on the hypertext link include: S101-S106.

S101, acquiring an order processing request uploaded by an order system based on a label design interface, and acquiring an order data table from a preset database according to the order processing request.

Illustratively, the tag design program interfaces with the data interface of the order system, and when a new order processing request occurs to the order system, the order processing request can be captured by the tag design interface immediately. After the label design interface captures the order processing request, the order processing request may be displayed for confirmation by the user. After receiving a confirmation instruction input by a user, the tag design program turns to a preset database to search data. The preset database may be a database of an order system, where rich order information is stored, possibly in a structured data table, containing various details of the order, such as merchandise information, customer information, quantity, price, etc. The label design program can flexibly grasp corresponding data tables from the database according to different order processing requests. This means that the tag design program can quickly locate and extract the required data, whether it be a single order or a batch order, providing timely data support for subsequent tag design and production flows. The design reduces manual intervention and ensures the accuracy and timeliness of data extraction.

S102, extracting key elements from the order data table based on a preset element extraction engine to obtain identification code elements, text elements and digital elements.

The key information extraction is performed on the order data table through a preset element extraction engine to obtain product type information, product description information and digital information corresponding to the product description information. And generating a type of identification code according to the information of each product type. Extracting various key word information in the product description information, converting the key word information into word elements, for example, converting the word information into word elements according to preset word fonts and word specifications, wherein the number elements are the same.

S103, generating an identification code lattice according to a first rendering operation of a user on the identification code element, generating a text lattice according to a second rendering operation of the user on the text element, and generating a digital lattice according to a third rendering operation of the user on the digital element.

Illustratively, the first rendering operation performed by the user on the identifier element in the tag design interface includes: selecting an identification code element, dragging the identification code element to a specified position of a blank dot matrix, adjusting the size of the identification code element to adapt to the design requirement of the tag, and rotating the identification code element to meet the specific layout requirement of the tag. The label design application generates a corresponding identification code lattice according to the operation of a user and records the position, the size and the rotation angle of the identification code lattice. The user selects a text element in the label design interface.

The second rendering operation performed on the text element by the user in the label design interface comprises the following steps: dragging the text elements to the appointed positions of the blank dot matrix, selecting the fonts, the colors and the sizes of the text elements to ensure that the text contents are clearly visible, adjusting the sizes of the text elements to adapt to the design requirements of the labels, and rotating the text elements to meet the specific layout requirements of the labels. The label design application generates a corresponding text lattice according to the operation of a user and records the fonts, colors, sizes, positions and rotation angles of the text lattice.

The third rendering operation performed by the user on the digital element in the label design interface comprises: dragging the digital elements to the appointed positions of the blank dot matrix, selecting the fonts, the colors and the sizes of the digital elements to ensure that the digital content is clearly visible, adjusting the sizes of the digital elements by a user to adapt to the design requirements of the labels, and rotating the digital elements by the user to meet the specific layout requirements of the labels. The label design application generates a corresponding digital dot matrix according to the operation of a user and records the fonts, colors, sizes, positions and rotation angles of the digital dot matrix.

S104, acquiring tag attribute information input by a user, generating a blank dot matrix according to the tag attribute information, and projecting an identification code dot matrix, a character dot matrix and a digital dot matrix to the blank dot matrix according to a preset typesetting algorithm.

Illustratively, the user inputs various attribute information of the tag through the tag design interface. Such information includes, but is not limited to, the size, shape, frame pattern, background color, etc. of the label. The label design application calculates specific size and shape of the label according to label attribute information input by a user, and generates an initial blank bitmap. The label design application projects the generated identification code dot matrix, the character dot matrix and the digital dot matrix to the appointed position of the blank dot matrix according to a preset typesetting algorithm, and adjusts the sizes and positions of the three dot matrices, for example, a plurality of dot matrices needing to be associated are bound, so that the display of the label on the label meets the design requirements.

In one particular embodiment, the user enters the size (e.g., width 100mm, height 50 mm), shape (rectangle), frame pattern (solid line frame) and background color (white) of the label through the label design interface. After the tag design application receives the attribute information, a blank bitmap of a corresponding size and shape is generated. Then, the label design application places an identification code lattice (two-dimensional code) generated by a user at the upper left corner of the label, a text lattice (product name and description) at the middle of the label, and a digital lattice (lot number and date) at the lower right corner of the label according to a preset typesetting algorithm. By the method, the user can efficiently input the tag attribute information and generate the tag lattice mapping source meeting the design requirement, so that the tag design process is simplified, and the design efficiency and accuracy are improved.

S105, generating a label dot matrix mapping source according to typesetting operation of a user on the identification code dot matrix, the character dot matrix and the digital dot matrix on the blank dot matrix.

Illustratively, the user completes the selection and adjustment of the identification code lattice, the text lattice, and the number lattice in the label design interface. The user can put the elements at proper positions on the blank lattice through operations such as dragging, zooming and rotating, and the size and the direction of the elements are adjusted. The method specifically comprises the following operations: drag operation, zoom operation, and rotate operation.

After the user finishes the operation, the label design application records specific parameters of each element, including position, size and rotation angle. Based on these parameters, the tag design application generates a tag lattice mapping source. The label lattice mapping source is a lattice image integrating all user operations, and accurately reflects the final design effect of the label.

Through the step, all typesetting operations of the user are recorded by the label design application and converted into dot matrix images, so that the accuracy and the attractiveness of label design are ensured. The process enables the layout of the labels to be more flexible, and can meet the requirements of different application scenes.

S106, acquiring printer attribute information according to a preset printer selection instruction, generating a printing instruction according to the printer attribute information and a label dot matrix mapping source, and sending the printing instruction to a target printer so as to enable the target printer to generate a label.

Illustratively, the user selects a target printer in the label design interface. The label design application determines a specific printer model from a preset printer list according to the selection of the user. And the label design application queries a printer attribute database according to the printer selection instruction to acquire detailed attribute information of the selected printer. Such attribute information includes, but is not limited to: print resolution, print speed, type of label paper supported, type of printer interface. And the label design application generates a printing instruction according to the acquired printer attribute information and the label lattice mapping source. The method specifically comprises the following three steps: 1. adjusting a label lattice mapping source: and adjusting the DPI of the label dot matrix mapping source according to the resolution ratio of the printer, so as to ensure that the printed label is clear and meets the design requirement. 2. Converting lattice data: the dot matrix data in the label dot matrix mapping source is converted into a format recognizable by the printer. For example, a ZPL instruction applicable to a Zebra printer or an EPL instruction applicable to Eltron printers is generated. 3. Setting printing parameters: including print position, print speed, color settings, label paper type, etc., ensures that the printer can properly perform the printing operation. The label design application sends the generated printing instruction to the target printer through a preset printer interface type. After receiving the instruction, the printer executes printing operation according to the dot matrix data and the printing parameters in the instruction to generate a final designed label.

Through the step, the label design application can generate accurate printing instructions according to the printing requirements of users and specific attributes of printers, and the printing quality and efficiency are ensured. Therefore, the label printing process is simplified, and the accuracy and consistency of label printing are improved.

In order to more clearly describe the technical scheme of the present application, the technical scheme of the present application will be described through a specific embodiment, and it should be noted that the specific embodiment is used for expanding the technical scheme of the present application, and is not limited to the present application.

In some embodiments, acquiring tag attribute information input by a user, generating a blank lattice according to the tag attribute information, including: based on the label design page, receiving label attribute information input by a user, and determining size attribute information and definition attribute information according to the label attribute information; determining a dot matrix frame according to the size attribute information, and determining a pixel array in the dot matrix frame according to the definition attribute information, wherein the pixel array comprises a plurality of initial pixel points; and generating a blank lattice according to the lattice frame and the pixel array.

By way of example, a user inputs tag attribute information through a tag design page, and analyzes size information of the user to obtain size attribute information and definition attribute information. The size attribute information includes: shape, width, and height, sharpness attribute information includes DPI. The size attribute information includes the width and height of the label, which determines the outer border of the blank lattice. The tag design application generates an external frame of the lattice according to the size attribute information. The dot matrix frame determines the shape and size of the blank dot matrix and provides a basis for the generation of an internal pixel array. The label design application generates a pixel array within the lattice frame based on the sharpness attribute information. The pixel array includes a plurality of initial pixels whose arrangement density is determined by DPI, for example, 300 pixels per inch on a 300 DPI label. The label design application uniformly distributes the pixels in the lattice frame according to the proportion.

Through the steps, the method can efficiently receive the label attribute information input by the user and generate an accurate blank lattice according to the information. The blank dot matrix has definite size and definition attributes, can meet different design requirements, and improves flexibility and accuracy of label design.

In some embodiments, the method for projecting the identification code dot matrix, the text dot matrix and the digital dot matrix to the blank dot matrix according to a preset typesetting algorithm includes: respectively determining a first projection range of the identification code dot matrix, a second projection range of the character dot matrix and a third projection range of the digital dot matrix according to a preset typesetting specification, and determining association relations among the first projection range, the second projection range and the third projection range; based on a typesetting algorithm, pre-typesetting a first projection range, a second projection range and a third projection range according to the association relation and the blank dot matrix to obtain a first projection relation; and projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix according to the first projection relation.

In the preset typesetting specification, the identification code, the text and the number have corresponding size regulations and interval regulations, under the limitation of the size regulations and the interval regulations, the dot matrix of each element has a corresponding projection range, and each dot matrix can be adjusted within the limited projection range so as to ensure that the requirements of the typesetting specification can be met. In the typesetting specification, the relation between elements is also specified, for example, a numerical description needs to be set below a one-dimensional identification code, a string of numerical characters needs to be configured under one-dimensional identification code, and the first projection range of the one-dimensional identification code and the third projection range of the numerical characters need to be bound. Such binding relationships may exist between a plurality of different elements or may exist between a plurality of identical elements, and in particular, may be determined according to typesetting specifications. Through the steps, the compliance of lattice typesetting is ensured.

In some embodiments, based on a typesetting algorithm, according to the association relationship and the blank lattice, the pre-typesetting is performed on the first projection range, the second projection range and the third projection range to obtain a first projection relationship, including: determining a fourth projection range according to the first projection range, the second projection range, the third projection range and the association relation, wherein the fourth projection range is as follows: a range in which any two or three of the first projection range, the second projection range, and the third projection range are combined and determined; dividing the blank dot matrix into areas according to the widths of the first projection range, the second projection range, the third projection range and the fourth projection range to obtain a first projection area and a second projection area; respectively acquiring the minimum heights of a first projection range, a second projection range, a third projection range and a fourth projection range; calculating the sum of the minimum heights, and multiplying the sum of the minimum heights by one half to obtain the classification height; according to the minimum height and the classified height, a first target range and a second target range are respectively determined from the first projection range, the second projection range, the third projection range and the fourth projection range, wherein the minimum height of the first target range is smaller than the classified height, and the minimum height of the second target range is larger than or equal to the classified height; performing pre-typesetting on a first target range in a first projection area according to a preset priority to obtain a first typesetting relationship, and performing pre-typesetting on a second target range in a second projection area to obtain a second typesetting relationship; and determining a first projection relationship according to the first typesetting relationship and the second typesetting relationship.

Illustratively, the fourth projection range is determined from the first projection range, the second projection range, the third projection range, and the association relationship therebetween. The fourth projection range is a range formed by combining any two or three of the first projection range, the second projection range, and the third projection range. Through the steps, interaction and overlapping of the projection ranges are comprehensively considered to determine a new effective range.

And carrying out region segmentation on the blank dot matrix according to the widths of the first projection range, the second projection range, the third projection range and the fourth projection range to obtain a first projection region and a second projection region. The number of projection areas may also be divided according to a preset number, or directly generated according to a label template selected by a user. Through the steps, the blank lattice is divided into a plurality of areas so as to facilitate the subsequent element typesetting and projection operation.

The minimum heights of the first projection range, the second projection range, the third projection range and the fourth projection range are respectively acquired. The classification height is obtained by calculating the sum of these minimum heights and multiplying it by one half. The classification height is used for subsequent region classification and typesetting operations. The first target range and the second target range are determined from the first projection range, the second projection range, the third projection range, and the fourth projection range, respectively, based on the minimum height and the classification height. The minimum height of the first target range is less than the classification height, and the minimum height of the second target range is greater than or equal to the classification height. Through the above steps, the sum of the heights of the first target ranges can be ensured, the height sum of the second target height range is basically the same as that of the second target height range, so that the two sides of the typeset target label are compared with the whole, and the attractiveness of the label is improved.

After the region segmentation is completed, pre-typesetting a first target range in a first projection region according to a preset priority to obtain a first typesetting relationship; and meanwhile, pre-typesetting the second target range in the second projection area to obtain a second typesetting relationship. The pre-typesetting process takes into account the priority and spatial distribution of the individual elements to ensure the aesthetics and functionality of the label design. And determining a first projection relationship according to the first typesetting relationship and the second typesetting relationship. The first projection relationship synthesizes typesetting results of each projection range and each target range to form a complete label design layout, and each element on the label is ensured to be reasonably arranged and displayed.

In some embodiments, generating a label lattice mapping source according to typesetting operation performed by a user on an identification code lattice, a text lattice and a digital lattice on a blank lattice includes: according to typesetting operation, adjusting first projection relations of the identification code dot matrix, the character dot matrix, the digital dot matrix and the blank dot matrix to generate second projection relations, wherein the typesetting operation comprises the following steps: position adjustment, size adjustment and rotation angle adjustment; and according to the second projection relation, projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix to generate a label dot matrix mapping source.

The identification code dot matrix, the text dot matrix and the digital dot matrix are projected to the blank dot matrix according to the second projection relation, specifically, the identification code dot matrix, the text dot matrix and the digital dot matrix replace initial pixel points on the blank dot matrix according to projection positions, and a label dot matrix mapping source is generated. By adjusting the projection relation between the dot matrix and the blank dot matrix, the correct positions and arrangement of the identification code, the text and the digital dot matrix in the label can be ensured, and typesetting errors and information confusion are avoided.

In some embodiments, based on a preset element extraction engine, extracting key information from an order data table to obtain product type information, product description information and product quantity information, including: based on the element extraction engine, reading an order data table, acquiring various product names in the order data table, and generating product type information according to the product names; extracting association information of the product name from the order data table according to a preset text extraction template, and generating product description information according to the association information, wherein the association information comprises: product production place, product specification, posting date, posting mode and notice; and determining numerical information from the associated information, and carrying out digital extraction on the order data table according to the numerical information to obtain product quantity information corresponding to the numerical information.

In some embodiments, generating the print instructions from the printer attribute information and the label lattice mapping source includes: determining printing environment parameters and machine operation parameters according to the printer attribute information; converting the label lattice mapping source into an executable data source according to the printing environment parameters; determining an accuracy instruction, a color modulation instruction and a position setting instruction according to the machine operation parameters and the executable data source; and generating a printing instruction according to the precision instruction, the color modulation instruction and the position setting instruction.

Illustratively, the label design application determines printing environment parameters and machine operating parameters. Print environment parameters include, but are not limited to, resolution (DPI) of the printer, print speed, supported paper types, and ambient temperature and humidity, among others. The machine operating parameters include the operating speed of the printhead, pressure settings, ink type, consumable usage, etc.

The label design application converts the label lattice mapping source into an executable data source according to the printing environment parameters, and comprises the following three steps: 1. resolution adjustment: and adjusting the label lattice mapping source to the matched resolution according to the DPI setting of the printer, so as to ensure the definition and detail of the image. 2. Color management: based on the color modes (such as CMYK and RGB) supported by the printer, the label lattice mapping source is subjected to color space conversion, so that the accuracy of printing colors is ensured. 3. Format conversion: the tag lattice mapping source is converted to a format that can be recognized by a host, such as ZPL (Zebra Programming Language), EPL (Eltron Programming Language), or other proprietary format.

After determining the executable data source and the target printer, the tag design application generates precision instructions based on the resolution of the target printer and the tag design requirements. These instructions include moving steps of the print head, resolution control of the dot matrix image, etc. to ensure accurate position and size of each printed dot. And generating a color modulation instruction according to the color management result to control the jet intensity and sequence of the ink, so as to ensure that the printed color is consistent with the design image. The label design application uses a color correction algorithm and an ICC color profile to achieve accurate reproduction of colors. Position setting instructions are generated according to the size and layout of the labels to control the specific positions of the labels on the printing medium, and precise alignment of the elements is ensured. The position settings also include settings for the start and end positions of the printhead to ensure the integrity of the printing. And finally, integrating the precision instruction, the color modulation instruction and the position setting instruction by the label design application, and generating a complete printing instruction through instruction coding and instruction packaging. Instruction encoding: the individual instructions are encoded into a sequence of commands executable by the printer according to the language and protocols supported by the printer (e.g., ZPL, EPL, etc.). Instruction encapsulation: and packaging the coded instruction to form a complete data packet containing all necessary printing information. The method not only improves the precision and quality of label printing, but also meets the requirements of different printing environments and machines, and ensures the stability and consistency of printing results.

Referring to fig. 2, fig. 2 is a schematic block diagram of a hypertext link-based tag generating apparatus 300 for performing the above-described hypertext link-based tag generating method according to an embodiment of the present application. Wherein the hypertext link-based tag generation apparatus 300 may be configured in a server.

The server may be an independent server, may be a server cluster, or may be a cloud server that provides cloud services, cloud databases, cloud computing, cloud functions, cloud storage, network services, cloud communications, middleware services, domain name services, security services, a content delivery network (Content Delivery Network, CDN), and basic cloud computing services such as big data and an artificial intelligence platform.

As shown in fig. 2, the hypertext link-based tag generation apparatus 300 includes: a data extraction module 301, an element extraction module 302, an element rendering module 303, a lattice projection module 304, a typesetting modulation module 305, and an instruction generation module 306.

The data obtaining module 301 is configured to obtain an order processing request uploaded by the order system based on the label design interface, and obtain an order data table from a preset database according to the order processing request.

The element extraction module 302 is configured to extract key elements from the order data table based on a preset element extraction engine, so as to obtain an identification code element, a text element and a digital element.

In some embodiments, the element extraction module 302 is configured to, when configured to implement a preset-based element extraction engine, extract key information from the order data table to obtain product type information, product description information, and product quantity information, specifically configured to implement: based on the element extraction engine, reading an order data table, acquiring various product names in the order data table, and generating product type information according to the product names; extracting association information of the product name from the order data table according to a preset text extraction template, and generating product description information according to the association information, wherein the association information comprises: product production place, product specification, posting date, posting mode and notice; and determining numerical information from the associated information, and carrying out digital extraction on the order data table according to the numerical information to obtain product quantity information corresponding to the numerical information.

The element rendering module 303 is configured to generate an identification code lattice according to a first rendering operation performed on the identification code element by a user, generate a text lattice according to a second rendering operation performed on the text element by the user, and generate a digital lattice according to a third rendering operation performed on the digital element by the user.

The dot matrix projection module 304 is configured to obtain tag attribute information input by a user, generate a blank dot matrix according to the tag attribute information, and project an identification code dot matrix, a text dot matrix and a digital dot matrix to the blank dot matrix according to a preset typesetting algorithm.

In some embodiments, the lattice projection module 304 is specifically configured to, when configured to obtain tag attribute information input by a user and generate a blank lattice according to the tag attribute information, implement: based on the label design page, receiving label attribute information input by a user, and determining size attribute information and definition attribute information according to the label attribute information; determining a dot matrix frame according to the size attribute information, and determining a pixel array in the dot matrix frame according to the definition attribute information, wherein the pixel array comprises a plurality of initial pixel points; and generating a blank lattice according to the lattice frame and the pixel array.

In some embodiments, the dot matrix projection module 304, when configured to project the identification code dot matrix, the text dot matrix, and the digital dot matrix to the blank dot matrix according to a preset typesetting algorithm, is specifically configured to: respectively determining a first projection range of the identification code dot matrix, a second projection range of the character dot matrix and a third projection range of the digital dot matrix according to a preset typesetting specification, and determining association relations among the first projection range, the second projection range and the third projection range; based on a typesetting algorithm, pre-typesetting a first projection range, a second projection range and a third projection range according to the association relation and the blank dot matrix to obtain a first projection relation; and projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix according to the first projection relation.

In some embodiments, the lattice projection module 304 is configured to, when configured to implement a typesetting algorithm, perform pre-typesetting on the first projection range, the second projection range, and the third projection range according to the association relationship and the blank lattice, obtain a first projection relationship, specifically configured to implement: determining a fourth projection range according to the first projection range, the second projection range, the third projection range and the association relation, wherein the fourth projection range is as follows: a range in which any two or three of the first projection range, the second projection range, and the third projection range are combined and determined; dividing the blank dot matrix into areas according to the widths of the first projection range, the second projection range, the third projection range and the fourth projection range to obtain a first projection area and a second projection area; respectively acquiring the minimum heights of a first projection range, a second projection range, a third projection range and a fourth projection range; calculating the sum of the minimum heights, and multiplying the sum of the minimum heights by one half to obtain the classification height; according to the minimum height and the classified height, a first target range and a second target range are respectively determined from the first projection range, the second projection range, the third projection range and the fourth projection range, wherein the minimum height of the first target range is smaller than the classified height, and the minimum height of the second target range is larger than or equal to the classified height; performing pre-typesetting on a first target range in a first projection area according to a preset priority to obtain a first typesetting relationship, and performing pre-typesetting on a second target range in a second projection area to obtain a second typesetting relationship; and determining a first projection relationship according to the first typesetting relationship and the second typesetting relationship.

The typesetting modulation module 305 is configured to generate a label lattice mapping source according to typesetting operations performed on the identification code lattice, the text lattice and the digital lattice by the user on the blank lattice.

In some embodiments, the typesetting modulation module 305 is specifically configured to, when configured to generate the tag lattice mapping source according to typesetting operations performed by a user on the identification code lattice, the text lattice, and the number lattice on the blank lattice, implement: according to typesetting operation, adjusting first projection relations of the identification code dot matrix, the character dot matrix, the digital dot matrix and the blank dot matrix to generate second projection relations, wherein the typesetting operation comprises the following steps: position adjustment, size adjustment and rotation angle adjustment; and according to the second projection relation, projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix to generate a label dot matrix mapping source.

The instruction generating module 306 is configured to obtain printer attribute information according to a preset printer selection instruction, generate a print instruction according to the printer attribute information and the label dot matrix mapping source, and send the print instruction to the target printer, so that the target printer generates a label.

In some embodiments, the instruction generation module 306, when configured to implement generating a print instruction according to printer attribute information and a label lattice mapping source, is specifically configured to implement: determining printing environment parameters and machine operation parameters according to the printer attribute information; converting the label lattice mapping source into an executable data source according to the printing environment parameters; determining an accuracy instruction, a color modulation instruction and a position setting instruction according to the machine operation parameters and the executable data source; and generating a printing instruction according to the precision instruction, the color modulation instruction and the position setting instruction.

The embodiment of the application provides electronic equipment, which comprises a memory and a processor; the memory is used for storing a computer program; a processor for executing a computer program and for implementing a hypertext link based tag generation method as in any of the embodiments of the present application when the computer program is executed.

The embodiment of the application provides a computer readable storage medium, and the computer readable storage medium stores a computer program, and when the computer program is executed by a processor, the processor realizes the label generating method based on hypertext links according to any of the embodiments of the application.

While the application has been described with reference to certain preferred embodiments, it will be understood by those skilled in the art that various changes and substitutions of equivalents may be made and equivalents will be apparent to those skilled in the art without departing from the scope of the application. Therefore, the protection scope of the application is subject to the protection scope of the claims.

Claims (10)

1. A method for generating a label based on a hypertext link, wherein the hypertext link is a link to a label design interface of a label design application, the hypertext link being loaded to the label design interface when invoked by a user, the method comprising:

Acquiring an order processing request uploaded by an order system based on the label design interface, and acquiring an order data table from a preset database according to the order processing request, wherein the label design application is connected with a data interface of the order system, and when the order system newly adds the order processing request, the label design interface automatically captures the order processing request through the data interface;

Based on a preset element extraction engine, extracting key elements from the order data table to obtain identification code elements, text elements and digital elements;

generating an identification code lattice according to a first rendering operation of a user on the identification code element, generating a text lattice according to a second rendering operation of the user on the text element, and generating a digital lattice according to a third rendering operation of the user on the digital element;

Acquiring tag attribute information input by a user, generating a blank dot matrix according to the tag attribute information, and projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix according to a preset typesetting algorithm;

generating a label dot matrix mapping source according to typesetting operation of a user on the identification code dot matrix, the character dot matrix and the digital dot matrix on the blank dot matrix;

obtaining printer attribute information according to a preset printer selection instruction, generating a printing instruction according to the printer attribute information and the label dot matrix mapping source, and sending the printing instruction to a target printer so as to enable the target printer to generate a label.

2. The method for generating a label based on hypertext links according to claim 1, wherein said obtaining label attribute information input by a user and generating a blank lattice according to said label attribute information comprises:

based on the label design page, receiving label attribute information input by a user, and determining size attribute information and definition attribute information according to the label attribute information;

determining a dot matrix frame according to the size attribute information, and determining a pixel array in the dot matrix frame according to the definition attribute information, wherein the pixel array comprises a plurality of initial pixel points;

And generating the blank dot matrix according to the dot matrix frame and the pixel array.

3. The method for generating a hypertext link-based tag of claim 1, wherein said projecting the identification dot matrix, the text dot matrix, and the number dot matrix to the blank dot matrix according to a preset typesetting algorithm comprises:

respectively determining a first projection range of the identification code dot matrix, a second projection range of the character dot matrix and a third projection range of the digital dot matrix according to a preset typesetting algorithm, and determining an association relationship among the first projection range, the second projection range and the third projection range;

based on the typesetting algorithm, pre-typesetting the first projection range, the second projection range and the third projection range according to the association relation and the blank dot matrix to obtain a first projection relation;

And projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix according to the first projection relation.

4. The method for generating a label based on a hypertext link according to claim 3, wherein said pre-typesetting said first projection range, said second projection range, and said third projection range based on said typesetting algorithm according to said association relationship and said blank lattice to obtain a first projection relationship, comprising:

determining a fourth projection range according to the first projection range, the second projection range, the third projection range and the association relation, wherein the fourth projection range is as follows: any two or three of the first projection range, the second projection range and the third projection range are combined and determined;

the blank dot matrix is subjected to region segmentation according to the widths of the first projection range, the second projection range, the third projection range and the fourth projection range, so that a first projection region and a second projection region are obtained;

Respectively acquiring the minimum heights of the first projection range, the second projection range, the third projection range and the fourth projection range;

calculating the sum of the minimum heights, and multiplying the sum of the minimum heights by one half to obtain the classification height;

Determining a first target range and a second target range from the first projection range, the second projection range, the third projection range and the fourth projection range according to the minimum height and the classified height, wherein the minimum height of the first target range is smaller than the classified height, and the minimum height of the second target range is larger than or equal to the classified height;

Performing pre-typesetting on the first target range in the first projection area according to a preset priority to obtain a first typesetting relationship, and performing pre-typesetting on the second target range in the second projection area to obtain a second typesetting relationship;

and determining the first projection relationship according to the first typesetting relationship and the second typesetting relationship.

5. The method for generating a label based on hypertext links according to claim 3, wherein said generating a label lattice mapping source according to a typesetting operation performed by a user on said blank lattice on said identification code lattice, said text lattice and said digital lattice comprises:

According to the typesetting operation, the first projection relations among the identification code dot matrix, the character dot matrix, the digital dot matrix and the blank dot matrix are adjusted to generate a second projection relation, and the typesetting operation comprises the following steps: position adjustment, size adjustment and rotation angle adjustment;

and according to the second projection relation, projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix to generate a label dot matrix mapping source.

6. The method for generating a hypertext link-based tag of claim 1, wherein said extracting key information from said order data table based on a preset element extraction engine, obtaining product type information, product description information and product quantity information, comprises:

based on the element extraction engine, reading the order data table, obtaining various product names in the order data table, and generating the product type information according to the product names;

Extracting the association information of the product name from an order data table according to a preset text extraction template, and generating the product description information according to the association information, wherein the association information comprises the following components: product production place, product specification, posting date, posting mode and notice;

and determining numerical information from the associated information, and carrying out digital extraction on the order data table according to the numerical information to obtain the product quantity information corresponding to the numerical information.

7. The hypertext link-based tag generation method of claim 1, wherein said generating a print command from said printer attribute information and said tag lattice mapping source comprises:

determining printing environment parameters and machine operation parameters according to the printer attribute information;

Converting the label lattice mapping source into an executable data source according to the printing environment parameters;

determining an accuracy instruction, a color modulation instruction and a position setting instruction according to the machine operation parameters and an executable data source;

and generating the printing instruction according to the precision instruction, the color modulation instruction and the position setting instruction.

8. A label generation device based on a hypertext link, wherein the hypertext link is a link of a label design interface, and the hypertext link is loaded on the label design interface when being called by a user, the label generation device comprising:

the data acquisition module is used for acquiring an order processing request uploaded by an order system based on the label design interface and acquiring an order data table from a preset database according to the order processing request, wherein the label design application is connected with a data interface of the order system, and when the order system adds the order processing request, the label design interface automatically captures the order processing request through the data interface;

the element extraction module is used for extracting key elements from the order data table based on a preset element extraction engine to obtain identification code elements, text elements and digital elements;

The element rendering module is used for generating an identification code lattice according to a first rendering operation of a user on the identification code element, generating a text lattice according to a second rendering operation of the user on the text element, and generating a digital lattice according to a third rendering operation of the user on the digital element;

the dot matrix projection module is used for acquiring tag attribute information input by a user, generating a blank dot matrix according to the tag attribute information, and projecting the identification code dot matrix, the character dot matrix and the digital dot matrix to the blank dot matrix according to a preset typesetting algorithm;

The typesetting modulation module is used for generating a label lattice mapping source according to typesetting operation of a user on the identification code lattice, the character lattice and the digital lattice on the blank lattice;

The instruction generation module is used for acquiring printer attribute information according to a preset printer selection instruction, generating a printing instruction according to the printer attribute information and the label dot matrix mapping source, and sending the printing instruction to a target printer so as to enable the target printer to generate a label.

9. An electronic device comprising a memory and a processor;

the memory is used for storing a computer program;

the processor being configured to execute the computer program and to implement the hypertext link-based tag generation method according to any of claims 1 to 7 when the computer program is executed.

10. A computer readable storage medium, characterized in that the computer readable storage medium stores a computer program which, when executed by a processor, causes the processor to implement the hypertext link-based tag generation method according to any of claims 1 to 7.