CN115758546A - House type custom design method, custom platform and readable storage medium - Google Patents

Abstract

The invention discloses a house type custom design method, a custom platform and a readable storage medium, and belongs to the field of house type design. Aiming at the problems that the space deformation cannot be carried out on the rendered house type and the efficiency is low in the prior art, the invention provides a house type custom design method which comprises the following steps: it includes designing and storing the layout of single space; designing and storing a wall body of a single space; the layout of a single space and the design of the wall body are finished, the design of the single space is finished, and other spaces are designed according to the same step S1 and step S2, so that a complete house type can be obtained. According to the invention, the purpose of independent design of the house type is achieved by independently designing the layout of a single space and the wall body, an ideal house type can be intuitively and quickly displayed according to the requirements of a user, and the time and energy spent by the user are shortened; the dynamic space size adjustment can meet different requirements of different customers on the premise of ensuring that the house type design conforms to the basic principle. The customization platform is simple in structure and convenient to operate.

Description

House type custom design method, custom platform and readable storage medium

Technical Field

The invention belongs to the technical field of 3D variable house type manufacturing, and particularly relates to a house type custom design method, a custom platform and a readable storage medium.

Background

With the upgrading of the server and the display card hardware, the combination of buildings and science and technology is facilitated with the improvement of webpage display and cloud rendering technology, the characteristics of low cost and flexibility are provided by using a network platform, and innovative real-time high-quality house type display is developed. The traditional house type display is roughly divided into the following modes, namely, a house type drawing, an offline house type model, a 720 house type drawing and the like, and is characterized in that the display for determining the house type is served, and along with the saturation of the market and the personalized development of user requirements, in order to meet the dynamic, rich and real-time requirements, the display mode of the original house type has great limitation, the ideal house type cannot be rapidly and intuitively displayed according to the requirements of the user, and the specialty of the manufacturing process is strong. To this end, the prior art addresses such problems in two ways, the first: standard manufacturing processes including hard acquisition equipment and the like are formed offline, so that the cost is reduced to the maximum extent; the second mode is as follows: the on-line development of the relatively convenient house type editor, the unification of model materials, this kind of on-line display mode still need to improve and play up speed and quality. The two modes have the advantages that the manufacturing process is optimized in a very limited mode, and the problems of long period, poor reusability, high cost, single interaction and the like are solved when the requirements of operation, namely obtaining and high fidelity are met.

For example, chinese patent application No. cn202011131541.X, published as 2021, 2/12, discloses a customizable house decoration design method, which includes generating a three-dimensional model of a house after a user inputs house type information, generating a three-dimensional effect diagram by setting a key after a door and a window, performing house decoration and decoration design, generating an item list by one key, and generating a cost budget based on the item list. The invention also discloses a custom house decoration design system which comprises a house information input module, an automatic identification module, a house type search module, a three-dimensional effect diagram generation module, a custom design module, an article list generation module and a cost budget module. The decoration design is displayed through the three-dimensional effect graph, so that the decoration effect can be more intuitively reflected. The house decoration style has a default style for a user to select, and the house decoration design effect can be customized. After the style and the decoration design effect are determined, the item list can be generated by one key, the cost budget sheet is generated, and the items can be placed in the sheet and purchased through the system, so that great convenience is brought to users. The defects of the patent are as follows: although the house decoration scheme can be customized, the original spatial house type cannot support the customized change.

Also for example, chinese patent application No. cn202110400972.x, published as 2021, 6/29, discloses a customizable indoor three-dimensional scene editing method, apparatus, system and storage medium, including the following steps: based on DSL custom scene screening conditions, models and materials of soft package products; generating a screening instruction according to a self-defined scene screening condition, and screening a plurality of indoor three-dimensional scenes from a database by executing the screening instruction; after a replacement instruction is generated according to the model and the material of the soft package product, the model and the material of the soft package product contained in the replacement instruction are retrieved in the database by executing the replacement instruction, and the retrieved model and the material are used for replacement, so that the batch editing of the soft package product in each scene is realized, and the indoor three-dimensional scene data is obtained. The disadvantages of the patent are that: the operation is complicated, and the self-defined space is limited.

Disclosure of Invention

1. Problems to be solved

The invention provides a house type custom design method, a custom platform and a readable storage medium, aiming at the problems that the space deformation of a rendering house type cannot be carried out and the efficiency is low. The method achieves the purpose of independent design of the house type by independently designing the layout of a single space and the wall body, can intuitively and quickly show the ideal house type according to the requirements of users, and shortens the time and energy spent by the users; the dynamic space size adjustment can meet different requirements of different customers on the premise of ensuring that the house type design conforms to the basic principle. The customization platform is simple in structure and convenient to operate.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A house type custom design method comprises the following steps:

s1: the layout of the single space is designed and saved: selecting an original layout model in a database, setting a rotation angle and reference information of the original layout model, and adopting a layout self-adaptive algorithm to meet the self-adaptation of spaces with different sizes for the original layout model; then storing the final layout model;

s2: designing and storing the wall body of a single space: the wall body in a single space is designed one by one: adding a wall model on the wall according to an automatic wall disassembly algorithm, wherein the wall model is set to be a stretchable wall model; then storing the wall;

s3: the layout of a single space and the design of the wall body are finished, the design of the single space is finished, and other spaces are designed according to the same step S1 and step S2, so that a complete house type can be obtained.

Further, the rotation angle of the original layout model in step S1 is 0 ° or 90 ° or 180 ° or 270 °; the reference information is reference object information in the horizontal direction and/or the vertical direction.

Furthermore, after the reference information is set, the distance between the object in the original layout model and the reference object is also set.

Further, the algorithm for automatically disassembling the wall body in the step S2 specifically includes the following steps:

s21: defining a rule: calculating from left to right for the north and south walls; calculating from top to bottom for east and west walls;

s22: determining the size of the current wall surface and the relative position of a wall model to be added;

s23: calculating the number, size and position of solid walls needing to be filled in the residual space of the current wall surface;

s24: after the wall body is disassembled, the last added wall body model is set as a stretchable wall body model in a default mode.

Further, the specific calculation process in step S23 is as follows:

s231: circularly traversing the added wall model;

s232: if the model is the first wall model, the position and the size of the entity wall on the front splicing side are calculated from the leftmost side or the uppermost side of the space to the leftmost side or the uppermost side of the wall model;

s233: the position and the size of a solid wall spliced on the front surface of the non-first wall model are calculated from the rightmost edge or the bottommost edge of the previous wall model to the leftmost edge or the topmost edge of the current wall model;

s234: traversing the added wall model, filling the last solid wall, and calculating according to the rightmost side or the bottommost side of the last wall model to the rightmost side or the bottommost side of the space;

s235: the default is that the last solid wall can be scaled along with the scaling of the space, and the sizes and relative positions of other wall models are not changed.

Furthermore, step S2 further includes setting a space associated with the wall in the single space, and implementing automatic scaling of the associated space in case of size change of the wall through an associated space algorithm.

Furthermore, the parameters of the final layout model in the step S1 generate corresponding layout JSON data to be stored in the cloud server, and a layout id is assigned as a unique identifier to be associated with the spatial layout field; and in the step S2, the wall body parameters generate corresponding wall body JSON data to be stored in a cloud server, and a WallID is distributed as a unique identifier to be associated to the space wall body field.

A customization platform applying any one of the above user type custom design methods comprises:

a layout self-defining module: the device comprises a rotation angle module, a reference module, a layout self-adaptive algorithm module and a data processing module, wherein the rotation angle module is used for setting the rotation angle and the reference information of an original layout model, and the original layout model adopts the layout self-adaptive algorithm to meet the self-adaptation of spaces with different sizes; then storing the final layout model;

a wall body self-defining module: the wall body in a single space is designed one by one: adding a wall model on the wall according to an automatic wall disassembly algorithm, wherein the wall model is set to be a stretchable wall model; then storing the wall body;

a database: for storing a layout model;

cloud server: the method is used for storing custom layouts, custom walls and final house types.

A computer-readable storage medium storing a computer program for executing the house-type custom design method of any one of the above.

3. Advantageous effects

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

(1) According to the invention, the purpose of independent design of the house type is achieved by independently designing the layout of a single space and the wall body, an ideal house type can be intuitively and quickly displayed according to the requirements of a user, and the time and energy spent by the user are greatly shortened; meanwhile, a wall model is generated through an automatic wall disassembly algorithm, and the wall model is a stretchable wall model and meets the requirement of automatic expansion of the wall; the original layout model is subjected to self-adaptive layout algorithm, so that the independent adjustment of different size spaces is met; the whole method can be used for dynamically adjusting the space size, different requirements of different customers can be met on the premise of ensuring that the house type design conforms to the basic principle, the working efficiency is greatly improved, the reusability is high, and the economic use value is high;

(2) According to the invention, the reference object is arranged during layout design, so that the layout model moves along with the movement of the reference object; and the position of the layout model in the space can be determined by the position of the reference object; meanwhile, after the reference object is set, an extra margin attribute is provided, so that fine adjustment after reference is made is facilitated; the wall body in the single space is associated with other spaces, so that the automatic scaling of the other associated spaces after the size of the space is adjusted is realized under the condition that the integral area of the house is not changed, the operation is convenient and quick, the efficiency is greatly improved, and the time cost is saved;

(3) The customized platform of the invention makes space deformation and wall body transformation on the house type through the layout customized module and the wall body customized module, and the layout can realize self-adaptation, thereby greatly meeting different requirements of different customers; meanwhile, time and energy of workers and users are greatly saved, the whole customization platform is simple in structure and convenient to operate, all modules work stably, and the customization platform has a high use prospect.

Drawings

FIG. 1 is a schematic flow diagram of the present invention;

FIG. 2 is a diagram of default collapsible wall generation;

FIG. 3is a diagram of a custom scalable model generation graph;

FIG. 4 is a diagram of a layout adaptive plan for a living room;

FIG. 5 is a diagram of a case of a living room with different space sizes;

FIG. 6 is a diagram of two spatial correlation configurations;

FIG. 7 is a diagram of a plurality of spatial correlation configurations.

Detailed Description

The invention is further described with reference to specific embodiments and the accompanying drawings.

First, some of the data structures in the present application are set forth: a single house type is composed of a plurality of spaces, and each space is composed of the state (namely whether a wall exists or not, and if so, which wall models are contained) and the layout of 4 walls;

1. description of spatial core field:

1.1spaceWidth and spaceHeight determine the size of the space;

1.2 determining the position of a space by using the spaceCENTERX and the spaceCENTERY;

1.3 loading the space wall data with the specified number by the wallID;

1.4 loading the spatial layout data with the specified number by the LayoutID;

2. description of wall core field:

2.1wallDirection determines which wall of the space operated, the values include: east, west, south, north;

2.2wallType specifies the wall model type, the values include: solid walls, windows, doors, etc.;

2.3, determining whether the ISFixedWidth is fixed in width, if so, determining the size of the wall model, and if not, starting an automatic stretching algorithm by the wall model along with the size of the space, and automatically stretching the size of the wall surface according to the correlation among the models;

3. layout core field:

3.1model size configures the original size of the model, so that the scaling and the position of the model can be calculated conveniently;

3.2model reference can be used for configuring model reference, a space wall body can be referred to, other models can be referred to, and the setting of a reference object realizes that the model automatically moves along with the movement of the reference.

Example 1

As shown in fig. 1, a house type custom design method includes the following steps:

s1: design layout of single space and save: selecting an original layout model in a database, setting a rotation angle and reference information of the original layout model, and adopting a layout self-adaptive algorithm to meet self-adaptation of different size spaces for the original layout model; then storing the final layout model; specifically, the method comprises the following steps:

s11: selecting a layout model (called as an original layout model) contained in a database to be put into a scene, wherein the original layout model is put at the position of the central point of a space where the scene is located by default; the scene in the step can be designed by self, the scene model can be selected according to different requirements, the layout attribute of the scene model is set, and the scene is finally stored; after the scene is saved, the method can be directly applied to house type design; in this step, it is explained that the layout models in the database are different furniture models in the space, such as beds, tables, stools, cabinets, etc.;

s12: setting a rotation angle of the original layout model; specifically, the rotation angle of the original layout model supports 4-angle rotation, namely 0 ° or 90 ° or 180 ° or 270 °;

s13: setting reference information of an original layout model; specifically, the reference information may be supported as reference object information in the horizontal direction and/or the vertical direction; meanwhile, the original layout model can realize the self-adaptation of spaces with different sizes according to a layout self-adaptation algorithm; the underlying logic of the layout adaptive algorithm is based on a reference, which has two cases: 1. the method supports the wall body layout of the reference space to solve the problem of layout self-adaption of spaces with different sizes; 2. supporting a reference layout between models to account for reference movement, the models moving with it; because the application does not improve the algorithm and does not belong to the core improvement point of the application, the existing layout self-adaptive algorithm capable of realizing the situation can be used in the application; in this step, the original size of the original layout model is known, so as to calculate the position and the scaling; the reference information of the set position can determine the position of the original layout model in the space, such as the east wall, the original layout model can calculate the position of the original layout model close to the east wall according to the size of the original layout model and the size of the space, and move to the position, when the size of the space is increased, the original layout model can calculate the position again according to the size of the space, so that the layout self-adaption (such as a sofa and a television cabinet in fig. 4) is realized; meanwhile, the layout self-adaptive algorithm also supports the reference between the original layout models, but the referenced object moves and the reference object changes, and the calculation method calculates the position information of the reference object (such as a pot plant in fig. 5) according to the position information and the size of the referenced object and the size of the reference object; furthermore, after the reference information is set, the distance between the object in the original layout model and the reference object is also set as follows: after the reference is set, an extra margin attribute is provided, so that fine adjustment after the reference is made is facilitated; for example, if the TV cabinet is placed 50cm away from the south wall, the reference object can be set as the south wall, and the distance between the south wall and the reference object is 50cm, the TV cabinet will lean against the south wall 50cm away no matter how the size of the space is changed (see the TV cabinet in FIG. 5);

s14: saving a user-defined original layout model (namely called as a final layout model), wherein the parameters of the final layout model can generate corresponding layout JSON data, store the layout JSON data in a cloud server, and allocate a layout ID as a unique identifier to be associated to a spatial layout field;

s2: designing and storing walls of a single space: the wall body in a single space is designed one by one: adding a wall model on the wall according to an automatic wall disassembly algorithm, wherein the wall model is set as a stretchable wall model; then storing the wall body; specifically, the method comprises the following steps:

each space defaults to have 4 walls, each wall is selected for editing, and the display or the hiding of each wall can be controlled;

wall models (doors and windows) can be added at any positions of each wall, automatic filling of the solid wall is realized according to an automatic wall disassembly algorithm, the change of space size is met, and the deformable wall models are automatically stretched; the automatic wall dismantling algorithm in the step specifically comprises the following steps:

s21: defining a rule: calculating from left to right for the north and south walls; calculating from top to bottom for east and west walls;

s22: determining the size of the current wall surface and the relative position of a wall model to be added;

s23: calculating the number, size and position of the solid walls needing to be filled in the residual space of the current wall surface, as shown in fig. 2; the specific calculation process in step S23 is as follows:

s231: circularly traversing the added wall model;

s232: if the model is the first wall model, the position and the size of the entity wall on the front splicing side are calculated from the leftmost side or the uppermost side of the space to the leftmost side or the uppermost side of the wall model;

s233: the position and the size of a solid wall spliced on the front surface of the non-first wall model are calculated from the rightmost edge or the bottommost edge of the previous wall model to the leftmost edge or the topmost edge of the current wall model;

s234: traversing the added wall model, filling the last solid wall, and calculating according to the rightmost side or the bottommost side of the last wall model to the rightmost side or the bottommost side of the space;

s235: the last solid wall is defaulted to be scaled along with the scaling of the space, and the sizes and relative positions of other wall models are not changed;

s24: after disassembling the wall, the last added wall model is set as a stretchable wall model by default, and other wall models can be adjusted as stretchable models, taking the north wall calculation as an example (as shown in fig. 3), the steps are as follows:

s241: according to the steps of S231, 232 and 233 in the step S23;

s242: if the added model is found to be a stretchable wall model; adding the solid wall model according to the step 233 in the step S23 according to the currently added wall model, and then recording the solid model ID (e.g., 100);

s243: finishing traversal, and traversing the added model from the end;

s244: the position and the size of the solid wall are added on the right side of the first wall model, and the position and the size are calculated through the rightmost side of the space and the rightmost side of the wall model;

s245: the position and the size of the solid wall are added on the right of the non-first wall model, and are calculated through the leftmost side of the last added wall model and the rightmost side of the current wall model;

s246: until the stretchable wall model is found again; calculating the size and position of the stretchable wall model, the ID generated through the step of S242: 100 and the last wall model to the far right;

after the wall models are automatically disassembled according to the automatic wall disassembling algorithm, each wall model can be stretchable, one wall support of each wall model is stretchable and is set to be stretchable, and when space zooming is carried out, the self zooming can be automatically calculated;

the wall body setting is well saved, the parameters of the 4 wall bodies can generate corresponding wall body JSON data to be stored in a cloud server, and a WallID is distributed as a unique identifier to be associated to a space wall body field;

furthermore, step S2 further includes setting a space associated with the wall in the single space, and implementing automatic scaling of the associated space in the case of changing the size of the wall through an associated space algorithm; each wall of each space can be provided with a space associated with the wall, so that the size of a certain space is changed when a client side uses the space, and automatic scaling of other associated spaces is realized under the condition that the whole house type area is not changed according to an associated space algorithm; specifically, different spaces of the same house type have unique numbers, and the associated spaces of two side walls of adjacent spaces are configured to each other, so that the association relationship can be realized; two spatially related configurations, such as: space 100 and space 101, east wall associated space 101 configuring space 100, west wall associated space 100 configuring space 101 (shown in fig. 6); a plurality of spatially correlated configurations, such as: a space 100, a space 101, a space 102, an east wall associated space 101 configuring the space 100, a west wall space 102 configuring the space 101, and an east wall associated space 101 configuring the space 102; the three spaces form a serial relationship (as shown in fig. 7); modifying the size of a single space, calculating the associated space, amplifying the size of the current space, amplifying the spaces on the same side, and reducing the spaces on the different sides;

s3: the layout of a single space and the design of the wall body are finished, the design of the single space is finished, and other spaces are designed according to the same step S1 and step S2, so that a complete house type can be obtained.

According to the invention, the purpose of independent design of the house type is achieved by independently designing the layout of a single space and the wall body, an ideal house type can be intuitively and quickly displayed according to the requirements of a user, and the time and energy spent by the user are greatly shortened; meanwhile, a wall model is generated through an automatic wall disassembly algorithm, and the wall model is a stretchable wall model and meets the requirement of automatic expansion and contraction of the wall; the original layout model is subjected to self-adaptive layout algorithm, so that the independent adjustment of different size spaces is met; the whole method can be used for dynamically adjusting the space size, different requirements of different customers can be met on the premise that the house type design conforms to the basic principle, the working efficiency is greatly improved, the reusability is high, and the economic use value is high.

Example 2

A customization platform applying the user-defined design method as described in embodiment 1 above, comprising:

a layout self-defining module: the device comprises a rotation angle module, a reference module, a layout self-adaptive algorithm module and a data processing module, wherein the rotation angle module is used for setting the rotation angle and the reference information of an original layout model, and the original layout model adopts the layout self-adaptive algorithm to meet the self-adaptation of spaces with different sizes; then storing the final layout model;

a wall body self-defining module: the wall body in a single space is designed one by one: adding a wall model on the wall according to an automatic wall disassembly algorithm, wherein the wall model is set to be a stretchable wall model; then storing the wall body;

a database: for storing a layout model;

a cloud server: the system is used for storing custom layout, custom wall and final house type;

a display module: for displaying the operation of each step and the result.

The customization platform in the present application also makes relevant software, which is now specifically exemplified: the related software of the customized platform comprises a function page of a user type editor, and different functions can be selected on the page to perform corresponding operation; the method comprises the steps that a space drawing and wall body setting interface of a house type editor is used, JSON data of a generated space and a wall body are made and stored to a cloud end; analyzing the spatial incidence relation, moving the wall body W01, and enabling the influence space to be: space 100 and space 101, W01 moves to the left, space 100 shrinks, and space 101 enlarges; selecting a designated position of the wall surface, adding a wall body model, automatically splitting the wall surface into 5 blocks, and taking the other 3 blocks as solid walls; that is, the wall surface is finally composed of 1,3,5 solid walls and 2,4 window models, the space size is enlarged, and any one model is set to be stretchable and can automatically stretch and retract.

The customized platform of the invention makes space deformation and wall body transformation on the house type through the layout customized module and the wall body customized module, and the layout can realize self-adaptation, thereby greatly meeting different requirements of different customers; meanwhile, the time and energy of workers and users are greatly saved, the whole customization platform is simple in structure and convenient to operate, all modules can work stably, and the customization platform has a high use prospect.

Example 3

A computer-readable storage medium storing a computer program for executing the house type custom designing method of the above-described embodiment 1. It is to be noted that, in addition to the system and the respective modules provided in the present application being implemented in pure computer readable program code, it is fully possible for those skilled in the art to logically program the method steps such that the system and the respective modules provided in the present application implement the same procedures in the form of logic gates, switches, application specific integrated circuits, editable logic controllers, embedded microcontrollers and the like. Therefore, the system and its modules provided in the present application may be regarded as a hardware component, and the modules included therein for implementing various programs may also be regarded as structures within the hardware component, or the modules for implementing various functions may also be regarded as structures within the hardware component as well as software programs for implementing the method.

It is to be appreciated that the embodiments disclosed herein are capable of being applied to electronic devices such as terminal devices, computer systems, servers, etc., which are capable of operating in conjunction with numerous other general purpose or special purpose computing system environments or configurations. Examples of well known terminal devices, computing systems, environments, and/or configurations that may be suitable for use with electronic devices, such as terminal devices, computer systems, servers, and the like, include, but are not limited to: personal computer systems, server computer systems, thin clients, thick clients, hand-held or laptop devices, microprocessor-based systems, set-top boxes, programmable consumer electronics, network pcs, minicomputer systems, mainframe computer systems, distributed cloud computing environments that include any of the above, and the like. Electronic devices such as terminal devices, computer systems, servers, etc. may be described in the general context of computer system-executable instructions, such as program modules, being executed by a computer system. Generally, program modules may include routines, programs, objects, components, logic, data structures, etc. that perform particular tasks or implement particular abstract data types. The computer system/server may be practiced in distributed cloud computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed cloud computing environment, program modules may be located in both local and remote computer system storage media including memory storage devices.

The examples described herein are merely illustrative of the preferred embodiments of the present invention and do not limit the spirit and scope of the invention, and various modifications and improvements made to the technical solutions of the present invention by those skilled in the art without departing from the design concept of the present invention should fall within the protection scope of the present invention.

Claims (9)

1. A house type custom design method is characterized by comprising the following steps: the method comprises the following steps:

s1: the layout of the single space is designed and saved: selecting an original layout model in a database, setting a rotation angle and reference information of the original layout model, and adopting a layout self-adaptive algorithm to meet self-adaptation of different size spaces for the original layout model; then storing the final layout model;

s2: designing and storing walls of a single space: the wall body in a single space is designed one by one: adding a wall model on the wall according to an automatic wall disassembly algorithm, wherein the wall model is set to be a stretchable wall model; then storing the wall;

s3: the layout of a single space and the design of the wall body are finished, the design of the single space is finished, and other spaces are designed according to the same step S1 and step S2, so that a complete house type can be obtained.

2. The house type custom design method according to claim 1, characterized in that: the rotation angle of the original layout model in the step S1 is 0 degree, 90 degrees, 180 degrees or 270 degrees; the reference information is reference object information in the horizontal direction and/or the vertical direction.

3. The house type custom design method according to claim 2, characterized in that: and after the reference information is set, the distance between the object in the original layout model and the reference object is also set.

4. The house type custom design method according to claim 1, characterized in that: the algorithm for automatically disassembling the wall in the step S2 specifically comprises the following steps:

s21: defining a rule: calculating from left to right for the north and south walls; calculating from top to bottom for east and west walls;

s22: determining the size of the current wall surface and the relative position of a wall model to be added;

s23: calculating the number, size and position of solid walls needing to be filled in the residual space of the current wall surface;

s24: and after the wall is disassembled, the last added wall model is set as a stretchable wall model by default.

5. The house type custom design method according to claim 4, characterized in that: the specific calculation process in step S23 is as follows:

s231: circularly traversing the added wall model;

s232: if the model is the first wall model, the position and the size of the entity wall on the front splicing side are calculated from the leftmost side or the uppermost side of the space to the leftmost side or the uppermost side of the wall model;

s233: the position and the size of a non-first wall model, which is spliced with a solid wall in front, are calculated from the rightmost edge or the bottommost edge of the last wall model to the leftmost edge or the topmost edge of the current model;

s234: traversing the added wall models, filling the last solid wall, and calculating from the rightmost edge or the bottommost edge of the last wall model to the rightmost edge or the bottommost edge of the space;

s235: the default is that the last solid wall can be scaled along with the scaling of the space, and the sizes and relative positions of other wall models are not changed.

6. The house type custom design method according to claim 1 or 4, characterized in that: step S2 also comprises setting the space associated with the wall in the single space, and realizing automatic scaling of the associated space under the condition of changing the size of the wall through an associated space algorithm.

7. The house type custom design method according to claim 1, characterized in that: generating corresponding layout JSON data by the parameters of the final layout model in the step S1, storing the layout JSON data in a cloud server, and distributing a layout ID as a unique identifier to be associated to a spatial layout field; and in the step S2, the wall body parameters generate corresponding wall body JSON data to be stored in a cloud server, and a WallID is distributed as a unique identifier to be associated to the space wall body field.

8. A customization platform applying the custom design method of a house type according to any one of claims 1 to 7, characterized in that: the method comprises the following steps:

a layout self-defining module: the device comprises a rotation angle module, a reference module, a layout self-adaptive algorithm module and a data processing module, wherein the rotation angle module is used for setting the rotation angle and the reference information of an original layout model, and the original layout model adopts the layout self-adaptive algorithm to meet the self-adaptation of spaces with different sizes; then storing the final layout model;

a wall body self-defining module: the method is used for designing the wall body in a single space one by one: adding a wall model on the wall according to an automatic wall disassembly algorithm, wherein the wall model is set as a stretchable wall model; then storing the wall body;

a database: for storing a layout model;

cloud server: the method is used for storing custom layouts, custom walls and final house types.

9. A computer-readable storage medium storing a computer program, characterized in that: the computer program is used for executing the house type custom design method of any one of the above claims 1-7.

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