WO2013026712A1 - Presentation of elements in a set - Google Patents

Abstract

A method for presenting objects in a subset from a set in a presentation area comprises steps for determining the size of the presentation area, providing sufficient container objects having a predetermined presentation size in order to fill the presentation area, assigning the objects in a subset to a respective container object, presenting the container objects in the presentation area and presenting the objects in the assigned container objects. An appropriate computer program product can run on an execution device and/or may be stored on a computer‑readable data storage medium.

Description

description

Representing Elements of a Set The present invention relates to a method and a computer program product for representing objects of a subset of a set in a viewport.

State of the art

To Darzu ^¬ render objects in a user interface between a data processing system and a human user, so-called dialogues are used, the conventional ^¬, on a graphically-oriented display system, such as a monitor, represented in a rectangular window. Each object displayed in the window is usually indicated by a name assigned to a predetermined presentation information. The presentation information may include, for example, a miniature graphic, a symbol or a graphic representation of object properties. The presentation information is usually displayed in the window along with the name of the object. If a large number of objects are available for display in the window, then a selection of the objects is determined and the selected objects are displayed in the window. Often, the objects are arranged, for example in alphabeti ^¬ shear order of the names, and in the window accordingly selected, alphabetically consecutive Whether ^¬ projects are displayed.

The so-called "direct representation" (Immediate Mode Rendering) a direct representation of representation development information takes place each object by the Applikationspro ^¬ program that manages the object in the display area, in the example mentioned so in the window. Alternatively, the approach of "distributed representation" (Retained Mode Rendering) is known in which the application le ^¬ diglich provides presentation information, but does not perform an output of the presentation information itself, but another program, such as a graphics library or an operating system leaves.

US 2011/0099494 A1 shows a technique for displaying graphical data of an object on an output medium. On a display area of the output medium a Containerob ^¬ ject is placed, in which the data of the object outputted by Beach ^¬ processing capabilities of the output medium.

It can happen that the number of objects that can be ^displayed is several hundred to several tens of thousands or even more. In particular, in the distributed representation, it may be very expensive to provide the presentation information for a large variety of objects to allow their presentation in the display area. While providing the information, the user interface of ^¬ le is usually not reactive, and the user must abwar ^¬ th until the presentation of information is completely generated. This may involve a waiting period ranging from several Se ^¬ customer to several minutes, which is acceptable for loading user may not, as in a

Real-time environment as in the operation of an engine.

On the other hand, this approach offers the advantage that after generating the presentation information for all objects, the subset of the objects actually displayed in the display area can be changed quickly, without requiring a renewed waiting time for the provision of display information. Moving the displayed subset over the set ("scrolling") is therefore liquid. The disadvantage of this approach is that a further be ^¬ trächtlicher space for receiving the display information of all the objects is required. In an alternative approach, presentation information is only generated for those objects that are to be displayed immediately in the viewport. This eliminates the waiting time until all presentation information of all objects is generated, and the required storage space for the display information of the objects to be displayed is relatively small. On the other hand, with each change of the subset of the objects to be displayed, in particular during scrolling, a certain waiting time has to be accepted, while the presentation information of the objects to be displayed is provided.

The object of the present invention to provide a method and a computer program product that allow it to reduce in particular for a user interface between a com ^¬ puter controlled device and a human user, the resources required for rapid and efficient representation of objects. The invention solves this problem by a method having the features of claim 1 and by a computer program product of claim 11. Subclaims give Favor ^¬ te embodiments again. Disclosure of the invention

A method of presenting objects of a subset of a set in a viewport includes steps of determining the size of the viewport, providing at least as many container objects with a predetermined viewpoint as are required to completely fill the viewport, assigning the objects of the subset to each a container object, representing the container objects in the display area and displaying the objects in the assigned Containerob ^¬ projects. According to the method, presentation information can be provided only for those objects that are located within the display area, with the result that a forward-looking determination of display information, that is to say of objects that are not directly displayed, is also saved. Thus, the method can contribute to reducing the computational and Spei ^¬ cheraufwand for the representation of objects. Resources of an executing system, in particular a Re ^¬ chenaufwand a processing device and a storage device for presentation information provided ^¬ nen, can be saved.

Display information of the container objects can be displayed even before the presentation information of the objects is completely known. Thereby, a waiting time of a user while providing the representation ^¬ information of the objects can be avoided. In particular, a user interface, the ver ^¬ apply that procedure, soon after the commencement of proceedings be reactive again without requiring a processing pause of the user while displaying information of the objects are collected and displayed successively.

The presentation area can be graphic and the container objects and objects can be displayed at least partially graphically. In particular, information that can be quickly and easily available, such as a name that will be displayed immediately, while graphic depicting ^¬ development information, such as an icon, a graphically encoded attribute or a thumbnail will be generated individually for each object. The representation of objects in the subset can be more divided in this way or be suk ^¬ zessiv, wherein a time-consuming to deploy, part of the presentation information is replenished during treatment already can users interact with incomplete representation information with the interface. The method can be particularly advantageously applied when the subset is changed frequently example ^¬ example in that represent a contiguous subset within the entire amount (scrolling). Therefore, the method comprising the steps of detecting a change in the subset and of assigning after the change darzustel ^¬ lumbar objects to the container objects. A part of the steps required for the representation of the objects, for example a positioning of the container objects, may have already been carried out, so that the representation of the changed subset can take place more quickly.

In a preferred embodiment, the container objects and the objects are each represented by programming-technical objects, each of which comprises a method for providing presentation information. As a result, the container objects can be handled in the same way as the actual objects with respect to another application controlling the actual presentation in the display area. Are the Con- tainerobj be ects it were introduced as an intermediate layer Zvi ^¬ rule the application and the objects so that carry neither the objects nor in the performing application-consuming changes. In a further preferred embodiment, said steps of presenting the container objects and presenting the objects comprises steps of requesting the Contai ^¬ nerobjekts for providing presentation information of requesting the objects for providing presentation information, of providing predetermined presentation information by the container object, until the presentation information of the object is available, and the provision of the presentation ^{information of} the object, so soon they are available.

A mechanism, ER proposes to amend Darstellungsinformati ^¬ tions, which are provided by the container object and the corresponding presentation in the presentation range modifies can support in this way and are ge ^¬ uses.

In one embodiment, a container object to which no object is assigned provides predetermined presentation information. The predetermined representation information may include, for example, a background image or a Standarddarstel ^¬ lung. If there are fewer objects in the set than container objects are provided to fill the viewport, container objects that are not assigned an object can also provide empty presentation information that results in no visible output or presentation information that indicates the missing assignment.

In one embodiment of the method, the sizes of the display area and the display information is determined eindi ^¬ dimensionally. Such a representation is known as Lis ^¬ tendarstellung or linearized, possibly hierarchical tree representation. In another embodiment, the size of the display area and the Darstellungsin ^¬ formations can be determined in two dimensions. As a result, for example, a planar view of Miniaturansich ^¬ th or symbols ("Icons") are provided for the objects.

In further embodiments, a multi-dimensional representation of the objects can also take place. In particular, the arrangement of the presentation information of at least one of the objects to be displayed in the display area can be based on a projection from a representation with more than the dimensions shown. For example, the objects may be arranged in a three-dimensional structure such as a cube or a cloud and there is a two-dimensional arrangement of the presentation information on the display area. Similarly, a projection can be used to represent any number of dimensions in which the objects are organized to reduce the displayable dimensions in the display area.

In a further embodiment, the objects in the set are organized hierarchically and carried a graph represen tation ^¬ the hierarchical position of each object by the assigned container object.

In particular, the objects can be organized in the manner of a tree and the hierarchical position can be defined by a

Indentation depth of the representation information of the object reprä ^¬ sentiert be. Thus, the hierarchy of the objects can be made clear to the user without breaking the concept of reusable container objects.

In an alternative approach, the hierarchical position can be carried out in a corresponding manner by the object itself, whereby the container object does not have to affect the depicting ^¬ lung information of the object, which can result in improved display results, for example when the information to be displayed trimmed lack of space or wrapped have to.

A computer program product with program code means for

Implementation of the described method can proceed on an execution device. The computer program product may be stored on a computer readable medium.

Brief description of the figures

The above-described characteristics, features and advantages of this invention as well as the manner in which they are achieved will become clearer and more clearly understood in connection with the following description of the embodiments which will be described in connection with the drawings Figure 1 is a graphical representation of objects of a list;

Figure 2 is a graphic representation of hierarchically arranged objects of a list;

Figure 3 is a graphical representation of objects of a

 two-dimensional field;

Figure 4 is a graphic representation of a projection of a three-dimensional field onto a two-dimensional field; and

Figure 5 shows a flow chart of a method.

Detailed description of embodiments

Fig. 1 shows a graphical representation 100 of objects of a list.

Symbolically above the other seven objects 105 are represented in the vertical direction, probably an amount 110 ^¬ ent. In the set 110 may include any number of objects 105 be included, especially no object 105, a single object 105, or a wide variety of objects 105, for example, several ten thousand to several hundred thousand ^¬.

The objects 105 are preferably in an order according to ei ^¬ nem predetermined attribute of the objects 105 in order to facilitate the forming of the subset 115 of the set 110th Whether each ^¬ ject 105 is to be displayed at least based on graphic information 125th Typically, the object comprises 105 to ^¬ addition to those graphic information 125 even more information, such as a name 130. In a In the preferred embodiment, the name 130 uniquely defines the object 105 in a predetermined context, while the graphical information 125 represents properties, characteristics, attributes, or other information associated with the particular object 105. The name 130 is to be determined and displayed with relatively little effort by each object 105. To provide the graphic information 125 Opera ^¬ tions may require more complex and resource-intensive.

A dialog box 135 includes a display area 140 and a so-called scroll bar 145. The scroll bar 145 includes a scroll bar 150 with a bar 155 and ei ^¬ nem arrow at the top 160 and a down arrow 165. As is known, the position of the bar 155 indicates the position of

Subset 115 within the ordered set 110. The big ^¬ SSE of the bar 155 in relation to the scroll bar 150 rep ^¬ räsentiert approximately the size of the subset 115 intra ^¬ half the amount 110. The arrows 160 and 165 can be activated by a user, such as by pointing and clicking with a graphical input device, to move subset 115 up and down within set 110, respectively. In order to change the subset 115, the beam 155 may also be used directly or by a predetermined number of objects 105, which corresponds to the number of objects 105 in the

Subset 115 corresponds to being moved. Although depicting ^¬ system is oriented in Fig. 1 vertically, in a corresponding manner, a horizontal scroll bar 145 is possible. In order to avoid the disadvantages described above in the management of presentation information of the objects 105, each object 105, which is shown in the display area 140 of the dialog window 135 ^¬ completely or partially, assigned to a Con ^¬ tainerobjekt 170th At least as many container objects 170 are present as are required to completely fill the presentation area 140. The container objects have 170 in general, the moving ^¬ che size, in the embodiment of Fig. 1 in particular the same height. The height of the container objects 170 corresponds preferably, the height of the representation information of the objects 105. ways container objects 105 no einheitli ^¬ che display size or height, so the Contai ^¬ nerobjekte 170 are preferably generated so as to amount, a minimum size or the Have objects 105, which can be changed magnified at a later time.

If the number of displayable in the display area 140 container objects 170 is not an integer, the next hö ^¬ here is number 170 container objects used. One of the Contai ^¬ nerobjekte 170 therefore can not be fully displayed in the presentation area 140th Undisplayable Containerob ^¬ 170 projects are to be avoided and, if necessary ^¬ ent removed.

In the dialog box 135, the objects are initially not shown 105, but the container objects 170. Each Contai ^¬ nerobjekt 170 is an object 105 of the subset 115 zugewie ^¬ sen, so that the object 105 is only indirectly represented in each zugewie ^¬ sen container object 170th The representation ei ^¬ nes object 105 and a container object 170 is carried out on the basis of presentation information, in particular graphical information 125 and the name 130 by the object 105 and the container object 170. An application that displaying the representation of information in the display area 140 projects are usually detected in riding position, or change the display information provided a loading and updates the display in depicting ^¬ lung area 140 independently.

For displaying presentation information of the objects 105 of the subset 115 in the display area 140 of the Dialogfens ^¬ ters 135 thus first container objects 170 provide Dar ^¬ position information that can be represented graphically by the external application in the display area 140th One Members of the dialog box 135 can already at this time ^¬ point parts of the dialog box 140, in particular the names of 130 of the objects 105, recognize and possibly interact with the slide ^¬ box will appear 135, for example by pressing the arrows 160, 165 up and down.

At the same time the container objects 170 call their assigned ^¬ allocated objects 105 to submit further Darstellungsinformati ^¬ tions, especially the graphical information 125, determine readiness. Once updated display information of the objects are present 105, the assigned Contai ^¬ nerobjekt 170 updates the display information provided by him accordingly. Since presentation information only needs to be determined and kept available for those objects 105 that are in subset 115, the corresponding processing and storage overhead is relatively low. A user of a user interface, comprising the Dialogfens ^¬ ter 135, the user interface can thus feel as a liquid and reactive.

FIG. 2 shows a graphical representation 200 of hierarchically arranged objects of a list. The representation corresponds to a further embodiment of the container objects 170 explained above with reference to FIG. 1 in a dialog box 135.

In contrast to FIG. 1, only objects 105 are provided ^¬ represents in Fig. 2, which are in the subset 115th Other objects 105 are omitted for clarity. The objects 105 to be displayed in the dialog box 135 of FIG. 2 have a hierarchical order, as is known, for example, from file systems. For example, whether ^¬ projects may be 105 organized as a tree, in particular as Rooted tree.

In the display area 140 of the dialog box 135 four objects are displayed, namely a first object 205, a second object 210, a third object 215 and a fourth object 220. In the illustrated example of a file system repre ^¬ animals the first object 205 and the fourth object 220 each have a folder while the second object 210 and third object 215 each representing a file. The type of objects 205 to 220 is indicated by the respective graphical information 125.

The folders 205, 220 may contain other objects 105 and are hierarchically at a higher level than the contained objects 105. This is referred to as parent and child objects 105. In the example shown, the file objects 210 and 215 are the folder object 205 underweight body ^¬ assigns. In addition, a folder 205, 220 may be expanded ("unfolded") or collapsed ("collapsed"). If the Ord ^¬ ner expanded, as the folder 205, the subordinate objects are displayed below the folder 105. Collapsed the folder as the folder 220 so underneath the folder objects are displayed 105 of the same hierarchical Ebe ^¬ ne.

The state of the folder 205, 220 decides a Assign ^¬ voltage of objects 105 to the container objects 170 is contributed game, a previously collapsed shown folder 220 expanded by interaction of the user, the container objects which are arranged below the newly expanded folder are , Objects 105, which are the result of a depth search in the hierarchical order of the objects 105 with the folder 220 as a starting point. When Tiefensu ^¬ che objects 105 are not followed, the presentation state is kolla ^¬ biert a folder 205, are assigned to 210. The assignment of the objects 105 to be displayed to the container objects 170 thus depends on the type of objects 105 to be displayed and, if the object 105 is a folder 205, 220, on its display state. In order to identify which of the objects 105 is in which hierarchical position with respect to another object 105, subordinate objects 210, 215 can be identified. In particular, the representations of these objects 210, 215 may be indented with respect to the parent object 105 by a predetermined amount. The indent may be cumulative, such that an object 105 subordinate to another object 105, itself subordinate to an object 105, is shown indented multiple times.

In this case, the engagement or another identification can be done either by the container object 170 or by the object 105. Similarly, the change of the graphic information 125 in response to the presentation ^¬ state either by the container object 170 or by the object 105 can be controlled.

The control of the presentation information 125, 130 by the object 105 itself is particularly advantageous if the presentation information 125, 130 must be changed, for example due to a lack of space. For example, it can he be ^¬ conducive, reduced the name 130 to represent abbreviated or wraps when the available space is insufficient by the engagement for a full representation. The object 105 may be designed so that it selects the appropriate option to save each presentation space or perform in an appropriate manner, for which purpose Informatio ^¬ NEN can be processed, the 170 does not exist or not the container object directly.

FIG. 3 shows a graphical representation 300 of objects 105 of a two-dimensional field. The objects 105 are organized in the form of a field 305. The field 305 is two-dimensional, so that two scroll bars 145 are provided, namely a vertical scroll bar 310 and a horizontal scroll bar 315. In a similar manner as explained above with reference to FIG. 1, a subset 115 of objects 105 in the Dar - Position range 140 shown in two dimensions. In this case, the subset 115 can be moved by means of the scroll bars 310 and 315 via the two-dimensional field 305. For outputting presentation information of the objects 105 of the subset 115 container objects 170 are used, a ^¬ individually the objects 105 of the subset are assigned to 115th Each of the objects 105 can provide graphic information 125 and further information, in particular a name 130, as presentation information in the manner already explained. In the embodiment shown in Fig. 3, Kings ^¬ NEN such further information is arranged, for example, small and centered below the graphic information 125th The graphic information 125 may represent examples of playing attributes, or other properties of the object 105 or be a thumbnail of a graphi ^¬ rule object that is represented by the object 105. 4 shows a graphical representation 400 of a projection of a three-dimensional field onto a two-dimensional field.

In a similar manner as in the embodiment of Fig. 3 objects are arranged in a two dimensional array 405 in Anzeigebe ^¬ reaching 140 a dialog box 135,105. The objects 105 are not two-dimensional organic ^¬ Siert innately, but follow an organization of three or more dimensions based on attributes or other specific characteristics. For example, the objects 105 may be distributed cloud-like in three-dimensional space based on three independent parameters. The field 405 is obtained by projecting the objects 105 into the two-dimensional representation area 140. In the manner already described, container objects 170 are used by placing container objects 170 in the presentation area 140 to which the objects 105 are assigned in pairs. The various options and measures in the representation of a subset 115 of objects 105 of a set 110, which were described above with reference to FIGS. 1 to 4, can be combined with one another as desired. For example, the two-dimensional representation of FIG. 3 can be displayed hierarchically analogously to FIG.

5 shows a schematic flow diagram of a method 500 for displaying objects. Play in terms of examples and the method 500 shown relates to the above prior ^¬ embodiments of Figures 1 to 4. The method 500 is particularly suitable for execution on a proces ^¬ processing device, in particular a programmable microcomputer furnished. Parts or steps of the method 500 may be in the form of instructions for a programmable

Processing device to be stored on a computer-readable medium.

The method 500 enables an efficient and resource-saving presentation of objects 105 or their representation information. In particular, changing the subset of objects 105 to be displayed can quickly and efficiently result in the appropriate representation in the rendering area 140. The method 500 is suitable for use in the environment of a distributed representation ("Retained Mode Rendering"), in particular for displaying the objects 105 in a display area 140 of a dialog window 135.

In a first step 505, a size of the representation area 140 is determined. This determination can be one-dimensional or multi-dimensional. In some embodiments, the presentation area is smaller than the entire presentation area 140 of the dialog box 135, since, for example, a display of presentation information is to take place outside the container objects 170 described below.

In a following step 510, the representation size of the container objects 170 is determined. The representation sizes of all Container objects 170 are usually the same. Are the Dar ^¬ position sizes of objects assigned to 105 different, a minimum display size of the objects can be 105 ^¬ be true, which is then used as the size of the container object 170th

In a step 515 the number of displayable ^¬ rich in Darstellungsbe container objects 170 is determined or reasonable fit. This may include adding or removing container objects 170. Furthermore, the positions of the individual container objects 170 in the display area 140 are determined. In the case of a two-dimensional representation of multi-dimensional values, as described above with reference to FIG. 4, this determination may include a projection.

In a step 520, the objects 105 of the subset 115 to be displayed in the viewport are determined. The certain objects 105 are allocated in a step 525 to Contai ^¬ nerobjekte 170 so that each object is assigned to exactly 105 a container object 170th It can be

Container objects 170 result, to which no object 105 zugewie ^¬ sen, for example because fewer objects 105 are in the subset 115 as container objects 170 were provided to cover the Dar ^¬ position range 120.

In a step 530, presentation information is provided by the container objects 170. The step 530 may be initiated by a corresponding request to the Containerob ^¬ projects 170, for example, a dialog box 135 manageable program. The presentation ^¬ information can first be those which generated the container object 170 itself or correspond to predetermined standard presentation information. If the presentation information is graphic, they may include, for example, a standard image or a background image. Is it with the information to be displayed to the text, a standard text or an empty string can be provided ^¬ (no output). If a container object 170 is not an object 105, the presentation information provided by the container object 170 may be permanent. The presentation information in this case can also represent the missing assignment.

Thereafter, in a step 535, a request is made to provide presentation information to the objects 105 of the subset 115 to be displayed. This request can start from the container objects 170.

In step 535, a first portion of the method 500 is completed and the dialog box 135 may be displayed and operated by a user, possibly omitting not yet present display information of individual objects 105. The user may work with the presented preliminary information and in particular interact with the dialog box 135.

As shown by the dashed line, after step 535, an event 540 may occur which causes a change in the presentation information presented so far. This event can have different content that reacts differently. In a first alternative will be ^¬ true that the subset 115 of the objects has changed 105 in a step 545th This case may occur when, for example, the user has operated scroll bar 145 to move subset 115. The same case may also occur when new objects 105 have been added to or removed from the set 110. In response, the method 500 branches back to step 520 in which the objects to be displayed 105 ^¬ be true. In a second alternative, in a step 550 ^¬ be true that the size of the display area has changed 140th This case can occur, for example, if the user ^¬ the size of the dialog box 135 and thus also the display area 120 has changed. In this case, the method 500 branches back to step 505 where the size of the rendering area 140 is determined. In a third alternative, the event 540 is followed by the determination in step 555 that one of the objects 105 to be displayed has provided new presentation information. This new presentation information may be the response of the object 105 to the request made in step 535 to provide this presentation information. The presentation information provided may also have changed as a result of a state change of the object 105. In response, in a step 560, the presentation information provided by the assigned container object 170 is adjusted based on the new presentation information.

In a subsequent step 565, it can still be checked whether the display size of the container object 170 has to be increased, because the display size of the presentation information provided by the object 105 has also increased. If this is not the case, the processing of the event is completed and another event 540 can be expected. Otherwise, the method 500 branches back to step 515 where the number and

Positions of container objects are adapted to the 170 ^¬ rich at the Darstellungsbe place.

Although the invention has been further illustrated and described in detail by the preferred embodiments, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims

claims

1. A method (500) for presenting objects (105) a subset (115) of a set (110) in a presentation ^¬ area (140), said method (500) comprising the steps of:

 Determining (505) the size of the viewport (140);

Providing (515) at least so many Contai ^¬ nerobjekten (170) having a predetermined display size such as are required to fill the lung depicting ^¬ region (140) completely;

 Assigning (525) the objects (105) of the subset (115) to a respective container object (170);

Displaying (530) of the container objects (170) in Dar ^¬ position range (140); and

Displaying (535, 560) of the objects (105) in the supplied ^¬ designated container objects (170);

 Detecting (545) a change in the subset (115) and assigning the objects (105) to be rendered after the change to the container objects (170).

2. The method (500) according to claim 1, wherein the display area (140) is graphically and the container objects (170) and objects (105) at least partially represented graphically ^¬ the.

3. The method (500) according to any one of the preceding claims, wherein the container objects (170) and objects (105) are each represented by objects, the method for loading a ^¬ woman on top of presentation information (125, 130) comprise.

The method (500) of any one of the preceding claims, wherein presenting (535, 560) the container objects and the objects comprises the steps of:

Prompting (530) of the container object (170) to Be ^¬ woman on top of presentation information (125, 130); Requesting (535) the objects (105) to provide presentation information (125, 130);

 Providing (530) predetermined presentation information (125, 130) by the container object

 (170) until the presentation information (125, 130) of the object (105) is available; and

 Providing (560) the presentation information (125, 130) of the object (105) as it becomes available.

The method (500) of any one of the preceding claims, further comprising providing (530) predetermined presentation information (125, 130) by a container object (170) to which no object (105) is assigned.

6. The method (500) according to one of the preceding claims, wherein the sizes of the display area (140) and the Dar ^¬ position information (125, 130) are determined two-dimensionally.

7. The method (500) according to any one of the preceding claims, wherein the arrangement of the presentation information (125, 130) at least one of the objects to be displayed (105) at Dar ^¬ position range (140) based on a projection of a representation (305, 405) with more than the dimensions shown.

The method (500) of any one of the preceding claims, further comprising the step of determining (555) the representational size of an object and enlarging (560) the

A representation size of the assigned container object (170) to the particular presentation size.

9. The method (500) according to any one of the preceding claims, wherein the objects (105) in the set (110) are hierarchical orga ^¬ nized and a graphical representation of the hierar ^¬ trian position of each object by the assigned containerized nerobjekt (170) takes place.

10. Computer program product with program code means for carrying out the method (500) according to one of the preceding claims, when it runs on an execution device.