CN116467037A - Graphic user interface work state recovery method - Google Patents

Abstract

The invention relates to the technical field of electronic design automation, in particular to a method for recovering the working state of a graphical user interface, which comprises the steps of storing the working state of a user into a recovery file, and recovering each window through N windows which are stored in the recovery file and are opened by the user and the position and the size of each window; recovering the contents of the N windows by recovering the type of each window and the corresponding content attribute information stored in the file; and when the restored window is the design level window, restoring the tree structure, the unfolding or folding state of the nodes and restoring the target nodes screened by the user according to the content attribute of the design level window in the restored file. By the method, the working state saved by the user can be automatically recovered, and the saved recovery file can be circulated or shared among different users.

Description

Graphic user interface work state recovery method

Technical Field

The invention relates to the technical field of electronic design automation, in particular to a method for recovering a working state of a graphical user interface.

Background

Chip design is independent of chip design software EDA, which is a core tool of a chip industry chain, wherein the chip industry chain comprises design, manufacture, packaging, test and the like, and each link needs to be finished in an auxiliary way based on the EDA tool. EDA (Electronic design automation ) software is design software that utilizes computer aided software to complete the functional design, synthesis, verification, physical design, etc. of very large scale integrated circuit chips. Whether the EDA tool is good or not directly determines the working efficiency of the research and development designer, namely determines the research and development progress of the chip. The EDA tool interacts with the user through a display interface (Graphical User Interface, GUI) that includes windows, menus, buttons, toolbars, and other various graphical interface elements. In the use of electronic design automation software products, the user's graphical user interface allows the user to rearrange the position and size of each window in the graphical user interface, change the hierarchy of each module design in the architecture window, and open the currently operating source file in the source file window, as well as the information such as the monitored signals in the waveform window, according to his own habits while operating the EDA tool. When the user closes the file and cannot directly restore to the previous working point, the user needs to manually reconfigure the information of each window when the user needs to operate the project again, so that the efficiency is low, the working point after restoration is very likely to be in error, and the working point cannot be circulated or shared among different users.

Disclosure of Invention

Aiming at the technical problems, the invention adopts the following technical scheme: a method for restoring an operational state of a graphical user interface, the method comprising:

s100, according to N windows win= { win stored in the recovery file ₁ ,win ₂ ,…,win _i ,…win _N Recovery window, win, and attribute configuration for each window body _i For the ith window, the value range of i is 1 to N; win (win) _i Genus of bodyThe sexual configuration includes win _i Position Loc in graphical user interface _i And win _i Dimension Siz of (2) _i 。

S200, according to the window type Tag of each window saved in the recovery file _i And querying the database by using the content attribute to recover N window contents Con= { Con ₁ ,Con ₂ ,…,Con _i ,…,Con _N }, wherein Con _i Is win _i Is a window content of (1); when win _i Window type Tag of (a) _i When designing a hierarchical window, the window content Con _i The recovery step of (2) comprises:

s210, acquiring win stored in recovery file _i T (i) content attributes Pr _i ={Pr _i,1 ,Pr _i,2 ,…,Pr _i,t ,…Pr _i,T(i) }，Pr _i,t Is win _i T content attribute of (c), the value range of T is 1 to T (i); wherein Pr is _i,t The method comprises the steps of including the full path name, the (u) th content attribute Pr of each node in the tree structure corresponding to the design level of the current project _i,u State flags including the expansion or collapse of all nodes, v-th content attribute Pr _i,v Recording a group of inquiry filtering conditions of a trigger screening command input by a user for the last time of the tree structure; wherein Pr is _i,u And Pr (Pr) _i,v All belong to Pr _i The values of u and v are 1 to T, and t.noteq.u.noteq.v.

S220 according to Pr _i,t All-path name query database recovery win for each node in the network _i Is a tree structure in (a).

S230, according to Pr _i,u And restoring the unfolded or folded state of the nodes in the tree structure.

S240, according to Pr _i,v The query filtering condition in (2) restores the target node screened by the user.

Compared with the prior art, the method for recovering the working state of the graphical user interface has obvious beneficial effects, by means of the technical scheme, the method for recovering the working state of the graphical user interface can achieve quite technical progress and practicality, has wide industrial utilization value, and has at least the following beneficial effects:

the invention provides a method for restoring the working state of a graphical user interface, which comprises the steps of storing the working state of a user into a restoring file, and restoring each window through N windows which are stored in the restoring file and are opened by the user and the position and the size of each window; recovering the contents of the N windows by recovering the type of each window and the corresponding content attribute information stored in the file; and when the restored window is the design level window, restoring the tree structure, the unfolding or folding state of the nodes and restoring the target nodes screened by the user according to the content attribute of the design level window in the restored file. By the method, the working state saved by the user can be automatically recovered, and the saved recovery file can be circulated or shared among different users, so that the technical problems that in the prior art, the working efficiency is low, errors are easy to occur and the working state cannot be circulated or shared among different users due to the fact that the user needs to manually configure information of each window are solved.

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 apparent that the drawings in the following description are only 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 flowchart of a method for recovering a working state of a graphical user interface according to an embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. 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 fall within the scope of the invention.

Referring to fig. 1, a flowchart of a method for operating state restoration based on an EDA graphical user interface is shown, the method comprising the steps of:

s100, according to N windows win= { win stored in the recovery file ₁ ,win ₂ ,…,win _i ,…win _N Recovery window, win, and attribute configuration for each window body _i For the ith window, the value range of i is 1 to N; win (win) _i The attribute configuration of the ontology comprises win _i Position Loc in graphical user interface _i And win _i Dimension Siz of (2) _i 。

It should be noted that the graphical user interface of the EDA tool includes a plurality of windows, and the user opens the corresponding windows according to the habit, and the user can set the size of the corresponding windows according to the habit. Therefore, the number of windows opened by the user and the position and size data of the windows are saved in the recovery file, so that the corresponding windows and the attribute configuration thereof can be recovered. The user does not need to adjust again, and the working efficiency is improved.

S200, according to the window type Tag of each window saved in the recovery file _i And querying the database by using the content attribute to recover N window contents Con= { Con ₁ ,Con ₂ ,…,Con _i ,…,Con _N }, wherein Con _i Is win _i Is provided.

It should be noted that, since the data displayed in the EDA tool is stored in the database, the database needs to be queried for restoration.

Optionally, the window types are a design hierarchy window, a source file editing window, and a waveform window. Other types of windows for EDA tools in the prior art are within the scope of the present invention.

Wherein, the content displayed by different window types in the recovery file is different, so the content attribute is also different. Specifically, the tree structure corresponding to the design hierarchy of the current project is displayed in the design hierarchy window, the program code of the source file is displayed in the source file editing window, and the waveform of the monitoring signal is displayed in the waveform window.

Further, when win _i Window type Tag of (a) _i When designing a hierarchical window, the window content Con _i The recovery step of (2) comprises:

s210, acquiring win stored in recovery file _i T (i) content attributes Pr _i ={Pr _i,1 ,Pr _i,2 ,…,Pr _i,t ,…Pr _i,T(i) }，Pr _i,t Is win _i T content attribute of (c), the value range of T is 1 to T (i); wherein Pr is _i,t The method comprises the steps of including the full path name, the (u) th content attribute Pr of each node in the tree structure corresponding to the design level of the current project _i,u State flags including the expansion or collapse of all nodes, v-th content attribute Pr _i,v Recording a group of inquiry filtering conditions of a trigger screening command input by a user for the last time of the tree structure; wherein Pr is _i,u And Pr (Pr) _i,v All belong to Pr _i The values of u and v are 1 to T, and t.noteq.u.noteq.v.

Optionally, the full path names of the nodes are formed by sequentially splicing names of all nodes on the path and signal names of the detection signals, wherein the path is a path between a root node of a tree structure and a node where the signals are located, which is stored in a database, and the splicing refers to connecting the corresponding names according to a preset rule. For example, for different nodes a3, b1, c1, d1, and sig1 on the same path, the full path name obtained by sequentially arranging and splicing the corresponding nodes is a3.b1.c1.d1.sig1.

Wherein each of the content attributes is different.

Wherein each node in the design level window has two states: unfolding and folding, when a certain node is folded, all child nodes below the node are hidden, and when the certain node is unfolded, the child nodes are displayed. Leaf nodes cannot be expanded in a tree structure.

Optionally, the node's unfolded state is marked 1 and the node's folded state is marked 0.

The query filtering condition is a filtering command executed by a user on the attribute structure in order to find a target node more quickly after the attribute structure is loaded on the design level window, and after the corresponding filtering command is stored in the recovery file, the EDA tool can execute the filtering command stored in the recovery file to recover the target node screened by the user.

The nodes in the tree structure are modules designed by users.

S220 according to Pr _i,t All-path name query database recovery win for each node in the network _i Is a tree structure in (a).

It should be noted that, in the database, the data is stored according to a hierarchical structure, and each layer includes a plurality of nodes, for example, nodes a1, a2, a3, a4, a5, and the like are included in the top layer. In the database is queried through the full path names, the query is performed in the corresponding layer in the database according to the name of each layer in the full path names. For example, the full pathname a3.B1.C1.D1.Sig1, where a3 is on the top layer, b1 is on the second layer, c1 is on the third layer, d1 is on the fourth layer, sig1 is a specific signal and is on the last layer, so that a3 will be queried first at the top layer of the database, b1 will be queried at the second layer, c1 will be queried at the third layer, and so on.

S230, according to Pr _i,u And restoring the unfolded or folded state of the nodes in the tree structure.

The user saves the unfolded or folded state mark of the node into the recovery file, and can recover the unfolded or folded state of the node set by the user only according to the state mark corresponding to each node during recovery without changing the state of the node manually by the user.

S240, according to Pr _i,v The query filtering condition in (2) restores the target node screened by the user.

It should be noted that, by searching the filtering condition and executing the filtering action again on the tree structure, the working state of the user when the user saves the restored file can be restored.

As a preferred embodiment, the set of query filtering conditions includes screening some or all of the fields of the database. Optionally, the query filtering condition is a part or all of the fields of the destination node name contained in the full path name.

In summary, the embodiment of the invention discloses a working state recovery method based on an EDA graphical user interface, which comprises the steps of saving the working state of a user into a recovery file, and recovering each window by N windows which are saved in the recovery file and are opened by the user and the position and the size of each window; recovering the contents of the N windows by recovering the type of each window and the corresponding content attribute information stored in the file; and when the restored window is the design level window, restoring the tree structure, the unfolding or folding state of the nodes and restoring the target nodes screened by the user according to the content attribute of the design level window in the restored file. By the method, the working state saved by the user can be automatically recovered, and the saved recovery file can be circulated or shared among different users, so that the technical problems that in the prior art, the working efficiency is low, errors are easy to occur and the working state cannot be circulated or shared among different users due to the fact that the user needs to manually configure information of each window are solved.

As a preferred embodiment, the r-th window win of said win _r Window type Tag of (a) _r For the source code editing window, r has a value in the range of 1 to N.

As a preferred embodiment, the S200 further includes: win (win) _r Window content Con _r The recovery step of (2) comprises:

s201, obtaining win stored in recovery file _r T (r) content attributes Pr _r ={Pr _r,1 ,Pr _r,2 ,…,Pr _r,o ,…Pr _r,T(r) }，Pr _r,o Is win _r O has a value ranging from 1 to T (r); wherein Pr is _r,o Including win _r Full path name, win of all source files in (i) _r P-th content attribute Pr of (2) _r,p Including win _r The value range of p is 1 to T (r) corresponding to the full path name of the source file currently displayed.

Note that the full path name of the source file includes the directory path in which the source file is stored and the name of the source file. For win _r When a user opens a plurality of source files simultaneously, the content of one source file is displayed in win _r Other source files do not display content only displaying labels of source file names.

S202 according to Pr _r,o And locating the storage position of each source file, and opening the corresponding source file.

S203, pr is given _r,p The corresponding source file is displayed at the upper layer. The other source file non-display content only displays the source file name as a tag.

The relevant content in the user-opened source code editing window in the EDA tool can be restored through S201-203.

As a preferred embodiment, win _r The q-th content attribute Pr _i,q A search record including keywords associated with each source file; con is then _r The recovering step of (a) further comprises: s204, according to Pr _i,q In search record recovery win _r Search records under the search button.

As a preferred embodiment, the g-th window win of said win _g Window type Tag of (a) _g For the waveform window, g has a value ranging from 1 to N.

As a preferred embodiment, win _g Window content Con _g The recovery step of (2) comprises:

s2100, obtaining win stored in recovery file _g Full path name Pr of medium T (g) monitoring signals _g ={Pr _g,1 ,Pr _g,2 ,…,Pr _g,y ,…Pr _i,T(g) }，Pr _g,y Is win _g The value of y is in the range of 1 to T (g). Pr (Pr) _g,y Including the storage path of the y-th monitoring signal in the tree structure and the name of the y-th monitoring signal.

S2200, searching database recovery win according to each full path name _g Is provided.

As a preferred embodiment, the S2200 further includes:

s2210, obtaining a J layer La= { La of a tree structure in a database ₁ ,La ₂ ,…,La _j ,…,La _J }，La _j Is the j-th layer in the tree structure, and the value of jRanging from 1 to J; la (La) _j Including K (j) nodes. It should be noted that, the acquisition of the monitoring signal in the waveform window also needs to find the tree structure, that is, the tree structure is the same as the tree structure in the design level window in the database, and the root node is the first layer in the layer number of the tree, and increases downwards in sequence. The full path name of the monitoring signal is formed by splicing the name of each node in the path from the root node to the leaf node of the tree structure and the name of the leaf node.

S2220, la _j The K (j) nodes in the tree are numbered according to the sequence to obtain a layer node sequence nd= { nd ₁ ,nd ₂ ,…,nd _k ,…,nd _K(j) }，nd _k The k node in nd is numbered according to the sequence; k has a value ranging from 1 to K (j). Wherein, the sequence numbers are increasing sequence numbers or decreasing sequence numbers.

S2230, extracting Pr _g,y The name na= { Na of each layer of nodes ₁ ,Na ₂ ,…,Na _j ,…,Na _J And the name Sig of the monitoring signal.

S2240, searching in the layer corresponding to the tree structure according to the name of each layer of nodes to obtain the positions of all nodes in the tree structure. Na is also used as _j Is the node name in the j-th layer, so Na is found in the j-th layer of the tree structure _j 。

S2250, utilizing the character string matching method to match Sig with La _J And (3) matching all signal names in the signal to recover the signal Sig.

The corresponding signal monitored by the user in the waveform window is restored according to S2210-2250.

As a preferred embodiment, in S2240, the position of the matching node is searched in the layer corresponding to the tree structure by using a binary search method. The tree structure is searched by the binary search method, so that the efficiency of searching and matching can be improved.

As a preferred embodiment, when there is a historically saved resume file, the current resume file is incrementally stored. The occupation of the storage space can be reduced by the incremental storage mode.

While certain specific embodiments of the invention have been described in detail by way of example, it will be appreciated by those skilled in the art that the above examples are for illustration only and are not intended to limit the scope of the invention. Those skilled in the art will also appreciate that many modifications may be made to the embodiments without departing from the scope and spirit of the invention. The scope of the present disclosure is defined by the appended claims.

Claims (10)

1. A method for restoring an operational state of a graphical user interface, the method comprising:

s100, according to N windows win= { win stored in the recovery file ₁ ,win ₂ ,…,win _i ,…win _N Recovery window, win, and attribute configuration for each window body _i For the ith window, the value range of i is 1 to N; win (win) _i The attribute configuration of the ontology comprises win _i Position Loc in graphical user interface _i And win _i Dimension Siz of (2) _i ；

S200, according to the window type Tag of each window saved in the recovery file _i And querying the database by using the content attribute to recover N window contents Con= { Con ₁ ,Con ₂ ,…,Con _i ,…,Con _N }, wherein Con _i Is win _i Is a window content of (1); when win _i Window type Tag of (a) _i When designing a hierarchical window, the window content Con _i The recovery step of (2) comprises:

s210, acquiring win stored in recovery file _i T (i) content attributes Pr _i ={Pr _i,1 ,Pr _i,2 ,…,Pr _i,t ,…Pr _i,T(i) }，Pr _i,t Is win _i T content attribute of (c), the value range of T is 1 to T (i); wherein Pr is _i,t The method comprises the steps of including the full path name, the (u) th content attribute Pr of each node in the tree structure corresponding to the design level of the current project _i,u State flags including the expansion or collapse of all nodes, v-th content attribute Pr _i,v Recording a group of inquiry filtering conditions of a trigger screening command input by a user for the last time of the tree structure; wherein Pr is _i,u And Pr (Pr) _i,v All belong to Pr _i The values of u and v are 1 to T, and T is not equal to u is not equal to v;

s220 according to Pr _i,t All-path name query database recovery win for each node in the network _i A tree structure in (a);

s230, according to Pr _i,u Restoring the unfolded or folded state of the nodes in the tree structure;

s240, according to Pr _i,v The query filtering condition in (2) restores the target node screened by the user.

2. The method according to claim 1, wherein the full path names of the nodes are formed by sequentially concatenating names of all nodes on a path and signal names of detection signals.

3. The method of claim 1, wherein an r-th window win of the win _r Window type Tag of (a) _r For the source code editing window, r has a value in the range of 1 to N.

4. A method according to claim 3, wherein S200 further comprises: win (win) _r Window content Con _r The recovery step of (2) comprises:

s201, obtaining win stored in recovery file _r T (r) content attributes Pr _r ={Pr _r,1 ,Pr _r,2 ,…,Pr _r,o ,…Pr _r,T(r) }，Pr _r,o Is win _r O has a value ranging from 1 to T (r); wherein Pr is _r,o Including win _r Full path name, win of all source files in (i) _r P-th content attribute Pr of (2) _r,p Including win _r The value range of p is 1 to T (r);

s202 according to Pr _r,o Positioning the storage position of each source file, and opening the corresponding source file;

s203, pr is given _r,p The corresponding source file is displayed at the upper layer.

5. The method of claim 4, wherein the win _r The q-th content attribute Pr _i,q A search record including keywords associated with each source file; con is then _r The recovering step of (a) further comprises:

s204, according to Pr _i,q In search record recovery win _r Search records under the search button.

6. The method of claim 1, wherein a g-th window win of the win _g Window type Tag of (a) _g For the waveform window, g has a value ranging from 1 to N.

7. The method of claim 6, wherein win _g Window content Con _g The recovery step of (2) comprises:

s2100, obtaining win stored in recovery file _g Full path name Pr of medium T (g) monitoring signals _g ={Pr _g,1 ,Pr _g,2 ,…,Pr _g,y ,…Pr _i,T(g) }，Pr _g,y Is win _g The value range of y is 1 to T (g);

s2200, searching database recovery win according to each full path name _g Is provided.

8. The method of claim 7, wherein S2200 further comprises:

s2210, obtaining a J layer La= { La of a tree structure in a database ₁ ,La ₂ ,…,La _j ,…,La _J }，La _j The value range of J is 1 to J for the J-th layer in the tree structure; la (La) _j Comprising K (j) nodes;

s2220, la _j The K (j) nodes in the tree are numbered according to the sequence to obtain a layer node sequence nd= { nd ₁ ,nd ₂ ,…,nd _k ,…,nd _K(j) }，nd _k The k node in nd is numbered according to the sequence; k has a value ranging from 1 to K (j);

s2230, extracting Pr _g,y The name na= { Na of each layer of nodes ₁ ,Na ₂ ,…,Na _j ,…,Na _J Name Sig of the monitor signal;

s2240, searching in the layer corresponding to the tree structure according to the name of each layer of nodes to obtain the positions of all nodes in the tree structure;

s2250, utilizing the character string matching method to match Sig with La _J And (3) matching all signal names in the signal to recover the signal Sig.

9. The method of claim 8, wherein the matching node is located in the tree structure using a binary search method in the layer corresponding to the tree structure in S2240.

10. The method of claim 1, wherein when there is a historically saved resume file, the current resume file is incrementally stored.