CN115270245B - Parameterization processing method, parameterization processing device, parameterization processing equipment and parameterization processing readable medium for column-like reinforcement graph - Google Patents

Abstract

The invention provides a parameterization processing method, a parameterization processing device, parameterization processing equipment and parameterization processing readable media for a column mass reinforcement graph, which comprise the following steps: acquiring control parameters input by a user, wherein the control parameters comprise: reinforcing bar geometric data, a stirrup arrangement mode and a stirrup combining position; generating detailed drawing contour lines according to the reinforcement geometric data, and generating point reinforcement primitives according to the contour lines; generating the stirrups and lacing wire primitives according to the stirrup arrangement mode; generating point rib primitives at corresponding positions according to the rib combining positions; and generating a column-like reinforcement graph based on the point reinforcement graphic element, the stirrup and the lacing wire graphic element. The method comprehensively analyzes the reinforcement type of the column mass sample through a large amount of engineering accumulation, and comprises the following steps: the control parameters of reinforcement geometric data, stirrup arrangement modes and reinforcement combining positions can be used for comprehensively covering various types of column-like reinforcement patterns in the drawing and modifying stage, and the drawing and the modifying of special-shaped columns are easy.

Description

Parameterization processing method, parameterization processing device, parameterization processing equipment and parameterization processing readable medium for column-like reinforcement graph

Technical Field

The invention relates to the field of reinforcement graph drawing, in particular to a parameterization processing method, a parameterization processing device, parameterization processing equipment and a parameterization processing readable medium for a column-like reinforcement graph.

Background

At present, two-dimensional general drawing software represented by CAD is still mainly used as a drawing tool for the design of the structural construction drawing, and only geometric information (namely points, lines and planes) of the drawing element can be displayed in the two-dimensional general drawing software. The prior CAD-based parameterized column large-sample reinforcement graph secondary development has the advantages that the primitive generation method is further subjected to parameter control and visualization, and the reinforcement graph drawing and modification are easy compared with the prior CAD software.

However, the column-like reinforcement diagram has more changes in actual engineering, and the existing CAD-based parameterized column-like reinforcement diagram is secondarily developed, so that in the software bottom layer design, the type of the column-like reinforcement diagram is not thoroughly understood, and therefore, the set drawing logic and drawing control parameters related to the drawing logic cannot effectively cover all column-like reinforcement types, or the deformation and adjustment of a standard column are not easy, which can lead the standard column to be unable to directly draw a special-shaped column, or the standard column to be unable to be directly adjusted into a corresponding special-shaped column, and therefore, in the software, the generation of the special-shaped column is still mainly manually modified, the modification is complicated, time-consuming, and the cost of manpower and material resources and the like is increased.

Disclosure of Invention

The invention aims to solve the problems of difficult drawing, modulation and low drawing efficiency of special-shaped columns in the secondary development software of the traditional parameterized column large-sample reinforcement graph, and provides a parameterized processing method, a parameterized processing device, parameterized processing equipment and a readable medium of the column large-sample reinforcement graph, wherein the parameterized processing method comprehensively analyzes column large-sample reinforcement types through accumulation of a large number of projects, and comprises the following steps of: the control parameters of reinforcement geometric data, stirrup arrangement modes and reinforcement combining positions can be used for comprehensively covering various types of column-like reinforcement patterns in the drawing and modifying stage, and the drawing and modifying of special-shaped columns are easy.

In order to achieve the above object, the present invention provides the following technical solutions:

a parameterization processing method of a column-like reinforcement graph comprises the following steps:

acquiring control parameters input by a user, wherein the control parameters comprise: reinforcing bar geometric data, a stirrup arrangement mode and a stirrup combining position;

generating detailed drawing contour lines according to the reinforcement geometric data, and generating point reinforcement primitives according to the contour lines; generating the stirrups and lacing wire primitives according to the stirrup arrangement mode; generating additional point ribs at corresponding positions according to the rib combining positions;

and generating a column-like reinforcement graph based on the point reinforcement graphic element, the stirrup graphic element and the additional point reinforcement graphic element.

According to a specific embodiment, in the parameterization processing method of the column-like reinforcement graph, the stirrup arrangement mode includes:

a first full cloth type, a second full cloth type, a first alternate one-to-one type and a second alternate one-to-one type;

the first full cloth type and the first one-by-one type are hoops for hooping 4 longitudinal bars, and the second full cloth type and the second one-by-one type are hoops for hooping 6 longitudinal bars.

According to a specific embodiment, in the parameterization processing method of the column-like reinforcement graph, the reinforcement combining position is expressed through a natural number sequence.

According to a specific embodiment, in the parameterization processing method of the column-like reinforcement graph, the method further includes:

associating control parameters input by a user into a pre-configured parameter panel; the parameter panel is positioned on one side of the column-like reinforcement graph;

and when a parameter editing instruction of a user in the parameter panel is detected, updating the column mass reinforcement graph based on the parameter editing instruction.

According to a specific embodiment, in the parameterization processing method of the column-like reinforcement graph, the method further includes:

associating control parameters input by a user into a pre-configured hidden editing area; wherein the hidden editing area is arranged on the column-like reinforcement layer;

when an instruction of a user entering a hidden editing area is detected, the control parameters in the hidden editing area are displayed in a correlated mode at the corresponding position of the column-like reinforcement diagram;

and when detecting a parameter editing instruction of a user in the hidden editing area, updating the column mass sample reinforcement graph based on the parameter editing instruction.

According to a specific embodiment, in the parameterization processing method of the column-like reinforcement graph, the method further includes:

and hiding the hidden editing area based on the hidden instruction when the hidden instruction of the user in the hidden editing area is detected.

In another aspect of the present invention, there is provided a parameterization apparatus for a bar graph of a column, the apparatus comprising:

the receiving unit is used for acquiring control parameters input by a user and outputting the control parameters to the first drawing unit, wherein the control parameters comprise: reinforcing bar geometric data, a stirrup arrangement mode and a stirrup combining position;

the first drawing unit is used for generating detailed graph contour lines according to the reinforcement geometric data and generating point reinforcement graphic primitives according to the contour lines; generating the stirrups and lacing wire primitives according to the stirrup arrangement mode; generating additional point rib primitives according to the rib combining positions;

and the second drawing unit is used for generating a column-like reinforcement graph based on the point reinforcement graphic element, the stirrup graphic element, the tie bar graphic element and the additional point reinforcement graphic element.

According to a specific embodiment, in the parameterization processing device of the column-like reinforcement graph, the device further includes: a data association unit;

the data association unit is used for outputting the control parameters acquired by the receiving unit to a pre-configured hidden editing area and a parameter panel; the parameter panel is positioned on one side of the column-like reinforcement graph; the hidden editing area is arranged on the column-like reinforcement graph layer.

In another aspect of the present invention, an electronic device is provided, including a processor, a network interface, and a memory, where the processor, the network interface, and the memory are connected to each other, where the memory is configured to store a computer program, the computer program includes program instructions, and the processor is configured to invoke the program instructions to execute the parameterization processing method of the column-sample reinforcement graph.

In another aspect of the present invention, a computer-readable storage medium is provided, in which program instructions are stored, and the program instructions, when executed by at least one processor, are used to implement the parameterization method of the column-like reinforcement graph.

Compared with the prior art, the invention has the beneficial effects that:

the method provided by the embodiment of the invention comprehensively analyzes the column mass reinforcement type through a large amount of engineering accumulation, and comprises the following steps of: the reinforcement geometric data, the stirrup arrangement mode and the control parameters of the reinforcement combining positions form a column large-sample reinforcement graph which is formed by a plurality of primitive-level parameter components and is related among a plurality of primitives, and the column large-sample reinforcement graph is covered on the whole surface in the drawing and modifying stage, so that the drawing and the modifying of special-shaped columns are easy.

Drawings

FIG. 1 is a flow chart of a parameterization processing method of a column-like reinforcement graph according to an embodiment of the invention;

FIG. 2 is a schematic diagram of a multi-type column-like reinforcement that can be drawn by the parameterization method according to an embodiment of the present invention;

FIG. 3 is a schematic view of an additional point tendon based on a tendon combining position according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a multi-type editing function that can be provided by the parameterized processing method according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a parameterization processing device for a mass reinforcement map according to an embodiment of the present invention;

FIG. 6 is a schematic structural diagram of a parameterization processing device for a mass reinforcement chart according to an embodiment of the present invention;

reference numerals: 1-an additional first corner rib; 2-additional second corner beads; 3-an additional third rib; 4-additional fourth corner ribs.

Detailed Description

The present invention will be described in further detail with reference to test examples and specific embodiments. It should not be construed that the scope of the above subject matter of the present invention is limited to the following embodiments, and all techniques realized based on the present invention are within the scope of the present invention.

Example 1

Fig. 1 shows a parameterization processing method of a column-like reinforcement graph according to an exemplary embodiment of the present invention, including:

acquiring control parameters input by a user, wherein the control parameters comprise: reinforcing bar geometric data, a stirrup arrangement mode and a stirrup combining position;

generating detailed drawing contour lines according to the reinforcement geometric data, and generating point reinforcement primitives according to the contour lines; generating the stirrups and lacing wire primitives according to the stirrup arrangement mode; generating additional point rib primitives according to the rib combining positions;

and generating a column-like reinforcement graph based on the point reinforcement graphic element, the stirrup graphic element and the additional point reinforcement graphic element.

It can be understood that the column large sample reinforcement diagram has more changes in actual engineering, and the existing CAD-based parameterized column large sample reinforcement diagram is secondarily developed, so that in the software bottom layer design, the type of the column large sample reinforcement diagram is not thoroughly understood, and therefore, the set drawing logic and drawing control parameters related to the drawing logic cannot effectively cover all column large sample reinforcement types, or the deformation and adjustment of a standard column are not easy, which can lead the standard column to be incapable of directly drawing a special-shaped column, or the standard column cannot be directly adjusted into a corresponding special-shaped column, and in the software, the generation of the special-shaped column is still mainly manually modified, the modification is complicated, time is consumed, and the cost of manpower, material resources and the like is increased. Therefore, in this embodiment, the overall analysis of the column-like reinforcement type is performed by a large number of engineering accumulations, and the configuration includes: the control parameters of reinforcement geometric data, stirrup arrangement modes and reinforcement combining positions can be used for comprehensively covering various types of column-like reinforcement patterns in the drawing and modifying stage, and the drawing and modifying of special-shaped columns are easy.

In one possible implementation manner, the reinforcement geometry data includes: longitudinal bars, and steel bar grades of stirrups; dimensions B, H, leftExt, rightExt, where B is width, H is height, leftex is left Bian Yanshen amount, rightExt is right Bian Yanshen amount, rectangular columns if leftex and RightExt are 0; magnification Scale.

Above-mentioned stirrup arrangement mode includes: the two types of stirrups are respectively arranged in a full cloth and a one-by-one mode, wherein the full cloth and the one-by-one mode are respectively two types, the first type of stirrups are stirrups for clamping 4 longitudinal stirrups, and the second type of stirrups are stirrups for clamping 6 longitudinal stirrups.

The rib combining positions are marked by the natural number sequence, so that the number of rows of the required rib combining is convenient and flexible to adjust the rib combining form. Wherein fig. 2 shows a schematic diagram of a column bulk sample under different control parameters according to an exemplary embodiment of the present invention.

Wherein, the reinforcing steel bar is combined and put together. For example, the reinforcing bars of the corner reinforcing bars are added at the corners, and assuming that the contour has 4 corners, one reinforcing bar is placed at each corner, and now the reinforcing bars are placed at each corner, namely 8 reinforcing bars are placed at the corners. As shown in fig. 3, in the first type of full-distribution illustration, the corner rib combining is to add four additional corner ribs (dot ribs) at four corners of the corner profile.

In a possible implementation manner, the parameterization processing method of the column-like reinforcement graph in the exemplary embodiment of the invention specifically includes:

and step 101, receiving control parameters input by a user, and drawing the contour line of the detailed drawing of the column large sample according to the size information in the geometric parameters, B, H and LeftExt, rightExt, the central control point Cpt and the amplification factor Scale.

Shifting the vertexes of the contour lines inwards to obtain shifted vertex sets, and generating point rib primitives at the positions of the point sets; generating large hoops at the positions of the point sets according to the offset vertex sets; and (3) shifting the contour lines inwards to obtain a shifted line set, obtaining a control point set of each middle longitudinal rib on each shifting line according to the length of each line segment in the line set and the number of the middle longitudinal ribs on each side, and generating point rib primitives in the control point sets.

Step 102, generating a stirrup primitive based on the stirrup arrangement mode.

If the first type of full cloth mode is adopted, the middle longitudinal bars in the B and H directions are grouped into a group, and the positions of control points of the middle stirrups are determined. Because of the two groups, the last left longitudinal ribs can only be 1 or 0, and if one longitudinal rib is left at last, the lacing wire is generated.

If the second type of full cloth mode is adopted, the middle longitudinal bars in the B and H directions are grouped into a group, and the control point positions of the middle stirrups are determined. Because of the three groups, the number of the last left longitudinal bars is only 2, 1 or 0, if two longitudinal bars are left at last, the stirrups for clamping the two longitudinal bars are generated, and if one longitudinal bar is left at last, the lacing wires are generated.

If the first type is one-by-one, the middle longitudinal ribs in the B and H directions are used for generating an inner hoop for hooping 2 longitudinal ribs every other longitudinal rib; because the minimum group is 3, the number of the left longitudinal bars can only be 2, 1 or 0, if one longitudinal bar is left at last, no stirrups and lacing wires are generated, and if two longitudinal bars are left at last, lacing wires are generated at the last longitudinal bar position;

if the second type is one-by-one, the middle longitudinal ribs in the B and H directions are used for generating an inner hoop for hooping 3 longitudinal ribs every other longitudinal rib; because the minimum group is 4, the number of the left longitudinal bars can only be 3, 2, 1 or 0, if the number of the left longitudinal bars is 3, the stirrups for clamping the 2 longitudinal bars are generated at the position of the last 2 longitudinal bars, if the number of the left longitudinal bars is 2, one lacing bar is generated at the position of the last 1 longitudinal bar, and if the number of the left longitudinal bars is 1 or 0, no new stirrups or lacing bars are produced.

Step 103, generating stirrup primitives based on a stirrup arrangement mode, setting according to the number of rows (the positions of the parallel bars) of a natural number sequence, and drawing the parallel bars of longitudinal bars with any number of rows;

if the rib-merging sequence on the H side is set as { I, j, k … }, the I, j, k-th longitudinal ribs on the H side are duplicated and moved inwards by a certain distance, and the inward movement is realized by moving downwards if the rib-merging sequence is the upper side of the B side, upwards if the rib-merging sequence is the lower side of the B side, rightwards if the rib-merging sequence is the left side of the H side, and leftwards if the rib-merging sequence is the right side of the H side.

Step 104, drawing the joint bars of the angle bars according to the joint bar information of the angle bars:

if the merging property of the angle rib is true, the contour point set of the angle rib is inwards offset by a certain distance, and then the merging position of the angle rib can be obtained.

In summary, the control points of the primitives are as follows:

in one possible implementation manner, the above parameterization processing method further includes: receiving a primitive editing instruction, wherein the primitive editing instruction comprises: a move instruction, a delete instruction, a rotate instruction, and a zoom instruction; and performing display adjustment on the column large sample reinforcement graph based on the primitive editing instruction.

In this embodiment, when a primitive editing instruction is received, a primitive editing function is called, and display adjustment is directly performed on the primitive, so that the editability of the primitive is further increased, and the operation is easy.

In one possible implementation manner, the above parameterization processing method further includes: associating control parameters input by a user into a pre-configured parameter panel; the parameter panel is positioned on one side of the column-like reinforcement graph;

and when a parameter editing instruction of a user in the parameter panel is detected, updating the column mass reinforcement graph based on the parameter editing instruction.

In this embodiment, by configuring the parameter panel, attribute information and control parameters of the graphic elements are displayed in the parameter panel, so as to provide a quick parameter editing method for the user, and facilitate real-time adjustment of the attribute information and control parameters by the user.

In one possible implementation manner, the above parameterization processing method further includes:

associating control parameters input by a user into a pre-configured hidden editing area; wherein the hidden editing area is arranged on the column-like reinforcement layer;

when an instruction of a user entering a hidden editing area is detected, the control parameters in the hidden editing area are displayed in a correlated mode at the corresponding position of the column-like reinforcement diagram;

and when detecting a parameter editing instruction of a user in the hidden editing area, updating the column mass sample reinforcement graph based on the parameter editing instruction.

It can be understood that in the existing drawing software, there are corresponding technologies for acquiring, in real time, the control parameters of the primitives and the attribute information defined by the user and input in the drawing process of the user, and for displaying, in real time, the control parameters and the attribute information of the primitives through the parameter panel. However, in the above-mentioned parameter panel display form, when modifying the graphic primitive, the designer still needs to spend a lot of time searching in the parameter panel to find the corresponding control parameter for editing and modifying. In addition, in the design field, different designers may have different definition expressions of the same control parameter, so if the habitual definition of the designer is different from the standard definition in the parameter panel, the search time of the designer is further increased, and the modification cost and the operation difficulty of the designer are increased.

Therefore, in this embodiment, by configuring the hidden editing area on the reinforcement primitive, when the user selects to enter the corresponding hidden editing area, the control parameters in the hidden editing area are displayed in an associated manner on the reinforcement primitive, so that the user can edit and adjust the control parameters easily, and rapid modification and update of the reinforcement primitive are realized.

Fig. 4 is a schematic diagram showing a state of a column-like detailed diagram selected and a corresponding parameter panel according to an exemplary embodiment of the present invention, where the method can provide a user with a plurality of editing methods, so that the user can adjust attribute information and control parameters in real time.

In one possible implementation, the method further includes: and hiding the hidden editing area based on the hidden instruction when the hidden instruction of the user in the hidden editing area is detected.

In one possible implementation, the above-described column-large detail primitive parameterization adjustment method is implemented by an updates () method. The editable control parameters are the first attribute parameters of the primitive class, and in addition, some other attribute parameters invisible to the user are used for identifying some specific states of the primitive, such as whether the primitive is a selected state, and the like, and the position control attribute is a central control point Cpt, and is used for controlling the position of the primitive. The updates () method is a method function for updating the detailed drawing of the large sample, and triggers the updates () method when the attribute of the graphic primitive is edited or the graphic primitive is directly edited (operations such as moving, deleting, rotating, scaling, selecting and canceling, etc.); the updates () method redraws the large sample drawing surface according to various attributes, thereby realizing the column large sample reinforcement drawing driven by parameters; when the graphic primitive is selected, the updates () method identifies the graphic primitive as a selected state according to whether the graphic primitive is selected or not, in the state, the graphic primitive displays a hidden editing area to assist a user to directly edit and modify on the graphic, corresponding attribute values can be directly changed by modifying corresponding control parameter data, and when the graphic primitive is deselected, the updates () method is called again, the graphic is redrawn according to the modified attribute, and the corresponding hidden editing area is hidden; therefore, the effect of directly carrying out parameter modification on the detailed diagram on the diagram surface in a hidden display way without changing the final expression of the diagram surface is achieved.

Example 2

In another aspect of the present invention, there is also provided a parameterization apparatus for a column-like reinforcement graph, as shown in fig. 5, including:

the receiving unit is used for acquiring control parameters input by a user and outputting the control parameters to the first drawing unit, wherein the control parameters comprise: reinforcing bar geometric data, a stirrup arrangement mode and a stirrup combining position;

the first drawing unit is used for generating detailed graph contour lines according to the reinforcement geometric data and generating point reinforcement graphic primitives according to the contour lines; generating the stirrups and lacing wire primitives according to the stirrup arrangement mode; generating additional point ribs at corresponding positions according to the rib combining positions;

and the second drawing unit is used for generating a column-like reinforcement graph based on the point reinforcement graphic element, the stirrup, the lacing wire graphic element and the additional point reinforcement graphic element.

In one possible implementation manner, the apparatus further includes: a data association unit;

the data association unit is used for outputting the control parameters acquired by the receiving unit to a pre-configured hidden editing area and a parameter panel; the parameter panel is positioned on one side of the column-like reinforcement graph; the hidden editing area is arranged on the column-like reinforcement graph layer.

In another aspect of the present invention, as shown in fig. 6, there is further provided an electronic device including a processor, a network interface, and a memory, where the processor, the network interface, and the memory are connected to each other, and the memory is configured to store a computer program, and the computer program includes program instructions, and the processor is configured to call the program instructions to perform the search optimization method described above.

In another aspect of the present invention, a computer storage medium is provided, where the computer storage medium stores program instructions, where the program instructions, when executed by at least one processor, are used in the method for guiding a parking lot to actively open an electronic invoice.

In an embodiment of the invention, the processor may be an integrated circuit chip having signal processing capabilities. The processor may be a general purpose processor, a digital signal processor (Digital Signal Processor, DSP for short), an application specific integrated circuit (Application Specific Integrated Circuit, ASIC for short), a field programmable gate array (Field Programmable Gate Array, FPGA for short), or other programmable logic device, discrete gate or transistor logic device, discrete hardware components.

The disclosed methods, steps, and logic blocks in the embodiments of the present invention may be implemented or performed. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of the method disclosed in connection with the embodiments of the present invention may be embodied directly in the execution of a hardware decoding processor, or in the execution of a combination of hardware and software modules in a decoding processor. The software modules may be located in a random access memory, flash memory, read only memory, programmable read only memory, or electrically erasable programmable memory, registers, etc. as well known in the art. The processor reads the information in the storage medium and, in combination with its hardware, performs the steps of the above method.

The storage medium may be memory, for example, may be volatile memory or nonvolatile memory, or may include both volatile and nonvolatile memory.

The nonvolatile Memory may be a Read-Only Memory (ROM), a Programmable ROM (PROM), an Erasable PROM (EPROM), an electrically Erasable ROM (Electrically EPROM, EEPROM), or a flash Memory.

The volatile memory may be a random access memory (Random Access Memory, RAM for short) which acts as an external cache. By way of example, and not limitation, many forms of RAM are available, such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double data rate SDRAM (Double Data RateSDRAM), enhanced SDRAM (ESDRAM), synchronous DRAM (SLDRAM), and direct memory bus RAM (directracram, DRRAM).

The storage media described in embodiments of the present invention are intended to comprise, without being limited to, these and any other suitable types of memory.

It should be understood that the system disclosed in the present invention may be implemented in other manners. For example, the modules may be divided into only one logic function, and there may be other manners of dividing the modules when actually implemented, for example, a plurality of units or components may be combined or may be integrated into another system, or some features may be omitted or not performed. Alternatively, the communication connection between the modules may be an indirect coupling or a communication connection through some interfaces, servers or units, and may be in electrical or other forms.

In addition, each functional module in the embodiments of the present invention may be integrated in one processing unit, or each module may exist alone physically, or two or more modules may be integrated in one processing unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied essentially or in part or all of the technical solution or in part in the form of a software product stored in a storage medium, including instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a removable hard disk, a magnetic disk, or an optical disk, or other various media capable of storing program codes.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (8)

1. The parameterization processing method of the column-like reinforcement graph is characterized by comprising the following steps of:

acquiring control parameters input by a user, wherein the control parameters comprise: reinforcing bar geometric data, a stirrup arrangement mode and a stirrup combining position;

generating detailed drawing contour lines according to the reinforcement geometric data, and generating point reinforcement primitives according to the contour lines;

generating the stirrups and lacing wire primitives according to the stirrup arrangement mode; generating additional point rib primitives according to the rib combining positions;

generating a column large-sample reinforcement graph based on the point reinforcement graphic element, the stirrup graphic element and the tie graphic element and the additional point reinforcement graphic element; the generating of the point rib primitive according to the contour line specifically comprises the following steps:

drawing a contour line of a column large detail drawing according to size information in geometric parameters, B, H and LeftExt, rightExt, a central control point Cpt and an amplification coefficient Scale, wherein B is width, H is height, leftExt is left Bian Yanshen quantity, and RiftExt is right Bian Yanshen quantity; shifting vertexes of contour lines of the column large-sample detailed graph inwards to obtain shifted vertex sets, and generating point rib primitives at positions of the point sets; generating large hoops at the positions of the point sets according to the offset vertex sets; shifting the outline of the detailed drawing of the column sample inwards to obtain a shifted line set, and obtaining a control point set of each middle longitudinal rib on each offset line according to the length of each line segment in the line set and the number of the middle longitudinal ribs on each side, and generating point rib primitives in the control point sets;

the step of generating the stirrup and lacing wire primitives according to the stirrup arrangement mode specifically comprises the following steps:

if the first cloth is of the first full cloth type, the middle longitudinal bars in the B and H directions are grouped into one group, the control point positions of the middle stirrups are determined, and if one longitudinal bar is left after the group is formed, the lacing wires are generated;

if the second cloth is full, the middle longitudinal bars in the B and H directions are grouped into a group, the control point positions of the middle stirrups are determined, if the group of the middle longitudinal bars is divided into the group of the middle longitudinal bars, the stirrups for clamping the two longitudinal bars are generated, and if the group of the middle longitudinal bars is divided into the group of the middle longitudinal bars, the stirrups are generated;

if the first longitudinal rib is of the first pulling type, the middle longitudinal rib in the B and H directions is used for generating an inner hoop for hooping 2 longitudinal ribs every other longitudinal rib; if one longitudinal rib is left, no stirrup or lacing wire is generated, and if two longitudinal ribs are left, a lacing wire is generated at the last longitudinal rib position;

if the second pulling type is the second pulling type, the middle longitudinal bars in the B and H directions are used for generating an inner hoop for hooping 3 longitudinal bars every other longitudinal bar; if the number of the left longitudinal bars is 3, a stirrup for clamping 2 longitudinal bars is generated at the position of the last 2 longitudinal bars, if the number of the left longitudinal bars is 2, a lacing wire is generated at the position of the last 1 longitudinal bar, and if the number of the left longitudinal bars is 1 or 0, no new stirrup or lacing wire is produced;

the method also comprises the step of generating stirrup primitives based on a stirrup arrangement mode, and drawing the stirrups of longitudinal bars in any row number according to the positions of the stirrups in a natural number sequence, and specifically comprises the following steps: if the parallel rib sequence on the H side is set as { I, j, k … }, the I, j, k longitudinal ribs on the H side are moved inwards in a copying way by a certain distance, and the inward movement is that the longitudinal ribs on the B side move downwards if the longitudinal ribs on the B side move upwards if the longitudinal ribs on the B side move leftwards if the longitudinal ribs on the H side move rightwards;

the method further comprises the steps of:

associating control parameters input by a user into a pre-configured hidden editing area; wherein the hidden editing area is arranged on the column-like reinforcement layer;

when an instruction of a user entering a hidden editing area is detected, the control parameters in the hidden editing area are displayed in a correlated mode at the corresponding position of the column-like reinforcement diagram;

when a parameter editing instruction of a user in the hidden editing area is detected, updating the column mass sample reinforcement map based on the parameter editing instruction;

the method comprises the following specific steps: when the graphic primitive is selected, the updates () method identifies the graphic primitive as a selected state according to whether the graphic primitive is selected or not, in the state, the graphic primitive displays a hidden editing area to assist a user to directly edit and modify on the graphic, corresponding attribute values can be directly changed by modifying corresponding control parameter data, and when the graphic primitive is deselected, the updates () method is called again, the graphic is redrawn according to the modified attribute, and the corresponding hidden editing area is hidden; the updates () method is a method function that updates the detail map of the large sample.

2. The parameterization processing method of the column-like reinforcement graph according to claim 1, wherein the stirrup arrangement mode comprises the following steps:

a first full cloth type, a second full cloth type, a first alternate one-to-one type and a second alternate one-to-one type; the first full cloth type and the first one-by-one type are hoops for hooping 4 longitudinal bars, and the second full cloth type and the second one-by-one type are hoops for hooping 6 longitudinal bars.

3. The method for parameterizing a bar graph according to claim 1, wherein the joint positions are expressed by natural number sequences.

4. A method for parameterizing a bar graph according to any one of claims 1-3, the method further comprising:

associating control parameters input by a user into a pre-configured parameter panel; the parameter panel is positioned on one side of the column-like reinforcement graph;

and when a parameter editing instruction of a user in the parameter panel is detected, updating the column mass reinforcement graph based on the parameter editing instruction.

5. The method for parameterizing a bar graph of a column pattern according to claim 1, further comprising:

hiding based on the hiding instruction when detecting the hiding instruction of the user in the hiding editing area

The hidden edit section.

6. A parameterization processing device for a column-like reinforcement graph, the device comprising:

the receiving unit is used for acquiring control parameters input by a user and outputting the control parameters to the first drawing unit, wherein the control parameters comprise: reinforcing bar geometric data, a stirrup arrangement mode and a stirrup combining position;

the first drawing unit is used for generating detailed graph contour lines according to the reinforcement geometric data and generating point reinforcement graphic primitives according to the contour lines; generating the stirrups and lacing wire primitives according to the stirrup arrangement mode; the method comprises the steps of,

generating additional point rib primitives according to the rib combining positions; the second drawing unit is used for generating a column-like reinforcement graph based on the point reinforcement graphic element, the stirrup graphic element, the tie bar graphic element and the additional point reinforcement graphic element; the apparatus further comprises: a data association unit;

the data association unit is used for outputting the control parameters acquired by the receiving unit to a pre-configured hidden editing area and a parameter panel; the parameter panel is positioned on one side of the column-like reinforcement graph;

the hidden editing area is arranged on the column mass reinforcement layer;

the generating of the point rib primitive according to the contour line specifically comprises the following steps:

drawing a contour line of a column large detail drawing according to size information in geometric parameters, B, H and LeftExt, rightExt, a central control point Cpt and an amplification coefficient Scale, wherein B is width, H is height, leftExt is left Bian Yanshen quantity, and RiftExt is right Bian Yanshen quantity; shifting vertexes of contour lines of the column large-sample detailed graph inwards to obtain shifted vertex sets, and generating point rib primitives at positions of the point sets; generating large hoops at the positions of the point sets according to the offset vertex sets; shifting the outline of the detailed drawing of the column sample inwards to obtain a shifted line set, and obtaining a control point set of each middle longitudinal rib on each offset line according to the length of each line segment in the line set and the number of the middle longitudinal ribs on each side, and generating point rib primitives in the control point sets;

the step of generating the stirrup and lacing wire primitives according to the stirrup arrangement mode specifically comprises the following steps:

if the first cloth is of the first full cloth type, the middle longitudinal bars in the B and H directions are grouped into one group, the control point positions of the middle stirrups are determined, and if one longitudinal bar is left after the group is formed, the lacing wires are generated;

if the second cloth is full, the middle longitudinal bars in the B and H directions are grouped into a group, the control point positions of the middle stirrups are determined, if the group of the middle longitudinal bars is divided into the group of the middle longitudinal bars, the stirrups for clamping the two longitudinal bars are generated, and if the group of the middle longitudinal bars is divided into the group of the middle longitudinal bars, the stirrups are generated;

if the first longitudinal rib is of the first pulling type, the middle longitudinal rib in the B and H directions is used for generating an inner hoop for hooping 2 longitudinal ribs every other longitudinal rib; if one longitudinal rib is left, no stirrup or lacing wire is generated, and if two longitudinal ribs are left, a lacing wire is generated at the last longitudinal rib position;

if the second pulling type is the second pulling type, the middle longitudinal bars in the B and H directions are used for generating an inner hoop for hooping 3 longitudinal bars every other longitudinal bar; if the number of the left longitudinal bars is 3, a stirrup for clamping 2 longitudinal bars is generated at the position of the last 2 longitudinal bars, if the number of the left longitudinal bars is 2, a lacing wire is generated at the position of the last 1 longitudinal bar, and if the number of the left longitudinal bars is 1 or 0, no new stirrup or lacing wire is produced;

the method also comprises the step of generating stirrup primitives based on a stirrup arrangement mode, and drawing the stirrups of longitudinal bars in any row number according to the positions of the stirrups in a natural number sequence, and specifically comprises the following steps: if the parallel rib sequence on the H side is set as { I, j, k … }, the I, j, k longitudinal ribs on the H side are moved inwards in a copying way by a certain distance, and the inward movement is that the longitudinal ribs on the B side move downwards if the longitudinal ribs on the B side move upwards if the longitudinal ribs on the B side move leftwards if the longitudinal ribs on the H side move rightwards;

the method further comprises the steps of:

associating control parameters input by a user into a pre-configured hidden editing area; wherein the hidden editing area is arranged on the column-like reinforcement layer;

when an instruction of a user entering a hidden editing area is detected, the control parameters in the hidden editing area are displayed in a correlated mode at the corresponding position of the column-like reinforcement diagram;

when a parameter editing instruction of a user in the hidden editing area is detected, updating the column mass sample reinforcement map based on the parameter editing instruction;

the method comprises the following specific steps: when the graphic primitive is selected, the updates () method identifies the graphic primitive as a selected state according to whether the graphic primitive is selected or not, in the state, the graphic primitive displays a hidden editing area to assist a user to directly edit and modify on the graphic, corresponding attribute values can be directly changed by modifying corresponding control parameter data, and when the graphic primitive is deselected, the updates () method is called again, the graphic is redrawn according to the modified attribute, and the corresponding hidden editing area is hidden; the updates () method is a method function that updates the detail map of the large sample.

7. An electronic device comprising a processor, a network interface and a memory, the processor, the network interface and the memory being interconnected, wherein the memory is configured to store a computer program comprising program instructions, the processor being configured to invoke the program instructions to perform the parameterization of a bar graph according to any of claims 1-5.

8. A computer readable storage medium, wherein program instructions are stored in the computer readable storage medium, which program instructions, when executed by at least one processor, are for implementing a parameterization method of a bar graph according to any one of claims 1-5.