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Application-specific API model

This article describes how to use the API model for building add-ins in Excel, OneNote, PowerPoint, Visio, and Word. It introduces core concepts that are fundamental to using the promise-based APIs.

Note

This model isn't supported by Outlook or Project clients. Use the Common API model to work with those applications. For full platform availability notes, see Office client application and platform availability for Office Add-ins.

Tip

The examples in this page use the Excel JavaScript APIs, but the concepts also apply to OneNote, PowerPoint, Visio, and Word JavaScript APIs. For complete code samples that show how you could use these and other concepts in various Office applications, see Office Add-in code samples.

Asynchronous nature of the promise-based APIs

Office Add-ins are websites which appear inside a webview control within Office applications, such as Excel. This control is embedded within the Office application on desktop-based platforms, such as Office on Windows, and runs inside an HTML iframe in Office on the web. Due to performance considerations, the Office.js APIs cannot interact synchronously with the Office applications across all platforms. Therefore, the sync() API call in Office.js returns a Promise that is resolved when the Office application completes the requested read or write actions. Also, you can queue up multiple actions, such as setting properties or invoking methods, and run them as a batch of commands with a single call to sync(), rather than sending a separate request for each action. The following sections describe how to accomplish this using the run() and sync() APIs.

*.run function

Excel.run, OneNote.run, PowerPoint.run, and Word.run execute a function that specifies the actions to perform against Excel, Word, and OneNote. *.run automatically creates a request context that you can use to interact with Office objects. When *.run completes, a promise is resolved, and any objects that were allocated at runtime are automatically released.

The following example shows how to use Excel.run. The same pattern is also used with OneNote, PowerPoint, Visio, and Word.

Excel.run(function (context) {
    // Add your Excel JS API calls here that will be batched and sent to the workbook.
    console.log('Your code goes here.');
}).catch(function (error) {
    // Catch and log any errors that occur within `Excel.run`.
    console.log('error: ' + error);
    if (error instanceof OfficeExtension.Error) {
        console.log('Debug info: ' + JSON.stringify(error.debugInfo));
    }
});

Request context

The Office application and your add-in run in different processes. Since they use different runtime environments, add-ins require a RequestContext object in order to connect your add-in to objects in Office such as worksheets, ranges, paragraphs, and tables. This RequestContext object is provided as an argument when calling *.run.

Proxy objects

The Office JavaScript objects that you declare and use with the promise-based APIs are proxy objects. Any methods that you invoke or properties that you set or load on proxy objects are simply added to a queue of pending commands. When you call the sync() method on the request context (for example, context.sync()), the queued commands are dispatched to the Office application and run. These APIs are fundamentally batch-centric. You can queue up as many changes as you wish on the request context, and then call the sync() method to run the batch of queued commands.

For example, the following code snippet declares the local JavaScript Excel.Range object, selectedRange, to reference a selected range in the Excel workbook, and then sets some properties on that object. The selectedRange object is a proxy object, so the properties that are set and the method that is invoked on that object will not be reflected in the Excel document until your add-in calls context.sync().

const selectedRange = context.workbook.getSelectedRange();
selectedRange.format.fill.color = "#4472C4";
selectedRange.format.font.color = "white";
selectedRange.format.autofitColumns();

Performance tip: Minimize the number of proxy objects created

Avoid repeatedly creating the same proxy object. Instead, if you need the same proxy object for more than one operation, create it once and assign it to a variable, then use that variable in your code.

// BAD: Repeated calls to .getRange() to create the same proxy object.
worksheet.getRange("A1").format.fill.color = "red";
worksheet.getRange("A1").numberFormat = "0.00%";
worksheet.getRange("A1").values = [[1]];

// GOOD: Create the range proxy object once and assign to a variable.
const range = worksheet.getRange("A1");
range.format.fill.color = "red";
range.numberFormat = "0.00%";
range.values = [[1]];

// ALSO GOOD: Use a "set" method to immediately set all the properties
// without even needing to create a variable!
worksheet.getRange("A1").set({
    numberFormat: [["0.00%"]],
    values: [[1]],
    format: {
        fill: {
            color: "red"
        }
    }
});

sync()

Calling the sync() method on the request context synchronizes the state between proxy objects and objects in the Office document. The sync() method runs any commands that are queued on the request context and retrieves values for any properties that should be loaded on the proxy objects. The sync() method executes asynchronously and returns a Promise, which is resolved when the sync() method completes.

The following example shows a batch function that defines a local JavaScript proxy object (selectedRange), loads a property of that object, and then uses the JavaScript promises pattern to call context.sync() to synchronize the state between proxy objects and objects in the Excel document.

await Excel.run(async (context) => {
    const selectedRange = context.workbook.getSelectedRange();
    selectedRange.load('address');
    await context.sync();
    console.log('The selected range is: ' + selectedRange.address);
});

In the previous example, selectedRange is set and its address property is loaded when context.sync() is called.

Since sync() is an asynchronous operation, you should always return the Promise object to ensure the sync() operation completes before the script continues to run. If you're using TypeScript or ES6+ JavaScript, you can await the context.sync() call instead of returning the promise.

Performance tip: Minimize the number of sync calls

In the Excel JavaScript API, sync() is the only asynchronous operation, and it can be slow under some circumstances, especially for Excel on the web. To optimize performance, minimize the number of calls to sync() by queueing up as many changes as possible before calling it. For more information about optimizing performance with sync(), see Avoid using the context.sync method in loops.

load()

Before you can read the properties of a proxy object, you must explicitly load the properties to populate the proxy object with data from the Office document, and then call context.sync(). For example, if you create a proxy object to reference a selected range, and then want to read the selected range's address property, you need to load the address property before you can read it. To request properties of a proxy object be loaded, call the load() method on the object and specify the properties to load. The following example shows the Range.address property being loaded for myRange.

await Excel.run(async (context) => {
    const sheetName = 'Sheet1';
    const rangeAddress = 'A1:B2';
    const myRange = context.workbook.worksheets.getItem(sheetName).getRange(rangeAddress);

    myRange.load('address');
    await context.sync();
      
    console.log (myRange.address);   // ok
    //console.log (myRange.values);  // not ok as it was not loaded

    console.log('done');
});

Note

If you're only calling methods or setting properties on a proxy object, you don't need to call the load() method. The load() method is only required when you want to read properties on a proxy object.

Just like requests to set properties or invoke methods on proxy objects, requests to load properties on proxy objects get added to the queue of pending commands on the request context, which will run the next time you call the sync() method. You can queue up as many load() calls on the request context as necessary.

Scalar and navigation properties

There are two categories of properties: scalar and navigational. Scalar properties are assignable types such as strings, integers, and JSON structs. Navigation properties are read-only objects and collections of objects that have their fields assigned, instead of directly assigning the property. For example, name and position members on the Excel.Worksheet object are scalar properties, whereas protection and tables are navigation properties.

Your add-in can use navigational properties as a path to load specific scalar properties. The following code queues up a load command for the name of the font used by an Excel.Range object, without loading any other information.

someRange.load("format/font/name")

You can also set the scalar properties of a navigation property by traversing the path. For example, you could set the font size for an Excel.Range by using someRange.format.font.size = 10;. You don't need to load the property before you set it.

Please be aware that some of the properties under an object may have the same name as another object. For example, format is a property under the Excel.Range object, but format itself is an object as well. So, if you make a call such as range.load("format"), this is equivalent to range.format.load() (an undesirable empty load() statement). To avoid this, your code should only load the "leaf nodes" in an object tree.

Load from a collection

When working with a collection, use load on the collection to load properties for every object in the collection. Use load exactly as you would for an individual object in that collection.

The following sample code shows the name property being loaded and logged for every chart in the "Sample" worksheet.

await Excel.run(async (context) => {
    const sheet = context.workbook.worksheets.getItem("Sample");
    const chartCollection = sheet.charts;

    // Load the name property on every chart in the chart collection.
    chartCollection.load("name");
    await context.sync();

    chartCollection.items.forEach((chart) => {
        console.log(chart.name);
    });
});

You normally don't include the items property of the collection in the load arguments. All the items are loaded if you load any item properties. However, if you will be looping over the items in the collection, but don't need to load any particular property of the items, you need to load the items property.

The following sample code shows the name property being set for every chart in the "Sample" worksheet.

await Excel.run(async (context) => {
    const sheet = context.workbook.worksheets.getItem("Sample");
    const chartCollection = sheet.charts;

    // Load the items property from the chart collection to set properties on individual charts.
    chartCollection.load("items");
    await context.sync();

    chartCollection.items.forEach((chart, index) => {
        chart.name = `Sample chart ${index}`;
    });
});

If you call the load() method on an object (or collection) without specifying any parameters, all scalar properties of the object or the collection's objects will be loaded. Loading unneeded data will slow down your add-in. You should always explicitly specify which properties to load.

Important

The amount of data returned by a parameter-less load statement can exceed the size limits of the service. To reduce the risks to older add-ins, some properties are not returned by load without explicitly requesting them. The following properties are excluded from such load operations.

  • Excel.Range.numberFormatCategories

ClientResult

Methods in the promise-based APIs that return primitive types have a similar pattern to the load/sync paradigm. As an example, Excel.TableCollection.getCount gets the number of tables in the collection. getCount returns a ClientResult<number>, meaning the value property in the returned ClientResult is a number. Your script can't access that value until context.sync() is called.

The following code gets the total number of tables in an Excel workbook and logs that number to the console.

const tableCount = context.workbook.tables.getCount();

// This sync call implicitly loads tableCount.value.
// Any other ClientResult values are loaded too.
await context.sync();

// Trying to log the value before calling sync would throw an error.
console.log (tableCount.value);

set()

Setting properties on an object with nested navigation properties can be cumbersome. As an alternative to setting individual properties using navigation paths as described above, you can use the object.set() method that is available on objects in the promise-based JavaScript APIs. With this method, you can set multiple properties of an object at once by passing either another object of the same Office.js type or a JavaScript object with properties that are structured like the properties of the object on which the method is called.

The following code sample sets several format properties of a range by calling the set() method and passing in a JavaScript object with property names and types that mirror the structure of properties in the Range object. This example assumes that there is data in range B2:E2.

await Excel.run(async (context) => {
    const sheet = context.workbook.worksheets.getItem("Sample");
    const range = sheet.getRange("B2:E2");
    range.set({
        format: {
            fill: {
                color: '#4472C4'
            },
            font: {
                name: 'Verdana',
                color: 'white'
            }
        }
    });
    range.format.autofitColumns();

    await context.sync();
});

Some properties cannot be set directly

Some properties cannot be set, despite being writable. These properties are part of a parent property that must be set as a single object. This is because that parent property relies on the subproperties having specific, logical relationships. These parent properties must be set using object literal notation to set the entire object, instead of setting that object's individual subproperties. One example of this is found in PageLayout. The zoom property must be set with a single PageLayoutZoomOptions object, as shown here.

// PageLayout.zoom.scale must be set by assigning PageLayout.zoom to a PageLayoutZoomOptions object.
sheet.pageLayout.zoom = { scale: 200 };

In the previous example, you would not be able to directly assign zoom a value: sheet.pageLayout.zoom.scale = 200;. That statement throws an error because zoom is not loaded. Even if zoom were to be loaded, the set of scale will not take effect. All context operations happen on zoom, refreshing the proxy object in the add-in and overwriting locally set values.

This behavior differs from navigational properties like Range.format. Properties of format can be set using object navigation, as shown here.

// This will set the font size on the range during the next `content.sync()`.
range.format.font.size = 10;

You can identify a property that cannot have its subproperties directly set by checking its read-only modifier. All read-only properties can have their non-read-only subproperties directly set. Writeable properties like PageLayout.zoom must be set with an object at that level. In summary:

  • Read-only property: Subproperties can be set through navigation.
  • Writable property: Subproperties cannot be set through navigation (must be set as part of the initial parent object assignment).

*OrNullObject methods and properties

Some accessor methods and properties throw an exception when the desired object doesn't exist. For example, if you attempt to get an Excel worksheet by specifying a worksheet name that isn't in the workbook, the getItem() method throws an ItemNotFound exception. The application-specific libraries provide a way for your code to test for the existence of document entities without requiring exception handling code. This is accomplished by using the *OrNullObject variations of methods and properties. These variations return an object whose isNullObject property is set to true, if the specified item doesn't exist, rather than throwing an exception.

For example, you can call the getItemOrNullObject() method on a collection such as Worksheets to retrieve an item from the collection. The getItemOrNullObject() method returns the specified item if it exists; otherwise, it returns an object whose isNullObject property is set to true. Your code can then evaluate this property to determine whether the object exists.

Note

The *OrNullObject variations do not ever return the JavaScript value null. They return ordinary Office proxy objects. If the the entity that the object represents does not exist then the isNullObject property of the object is set to true. Do not test the returned object for nullity or falsity. It is never null, false, or undefined.

The following code sample attempts to retrieve an Excel worksheet named "Data" by using the getItemOrNullObject() method. If a worksheet with that name does not exist, a new sheet is created. Note that the code does not load the isNullObject property. Office automatically loads this property when context.sync is called, so you do not need to explicitly load it with something like dataSheet.load('isNullObject').

await Excel.run(async (context) => {
    let dataSheet = context.workbook.worksheets.getItemOrNullObject("Data");
    
    await context.sync();
    
    if (dataSheet.isNullObject) {
        dataSheet = context.workbook.worksheets.add("Data");
    }
    
    // Set `dataSheet` to be the second worksheet in the workbook.
    dataSheet.position = 1;
});

Application undo stack

When an application-specific API is processed, the undo stack of the application is cleared. This means that you can't undo changes made prior to any action done by an add-in (unless that add-in only uses Common APIs or doesn't interact with the file). The same is true for changes made by the add-in.

See also