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IXpsOMGeometryFigure::SetSegments method

Sets the segment information and data points for segments in the figure.

Syntax

HRESULT SetSegments(
  [in]       UINT32           segmentCount,
  [in]       UINT32           segmentDataCount,
  [in] const XPS_SEGMENT_TYPE *segmentTypes,
  [in] const FLOAT            *segmentData,
  [in] const BOOL             *segmentStrokes
);

Parameters

  • segmentCount [in]
    The number of segments.

    This value is also the number of elements in the arrays that are referenced by segmentTypes and segmentStrokes.

  • segmentDataCount [in]
    The number of segment data points.

    This value is also the number of elements in the array that is referenced by segmentData.

  • segmentTypes [in]
    An array of XPS_SEGMENT_TYPE variables. The value of segmentCount specifies the number of elements in this array.

  • segmentData [in]
    An array of segment data values. The value of segmentDataCount specifies the number of elements in this array.

  • segmentStrokes [in]
    An array of segment stroke values. The value of segmentCount specifies the number of elements in this array.

Return value

The method returns an HRESULT. Possible values include, but are not limited to, those in the table that follows. For information about XPS document API return values that are not listed in this table, see XPS Document Errors.

Return code Description
S_OK

The method succeeded.

E_INVALIDARG

segmentTypes contains a value of unrecognized type.

Alternatively, the number of entries in the segmentData array is greater than the number of entries in the segmentTypes array.

E_POINTER

segmentTypes, segmentData, or segmentStrokes is NULL.

XPS_E_INVALID_FLOAT

segmentData contains a FLOAT value that is infinite or is not a number (NAN).

XPS_E_MISSING_SEGMENT_DATA

The array that is passed in segmentData has fewer entries than the array passed in segmentTypes.

XPS_E_NEGATIVE_FLOAT

An entry in the array that is passed in segmentData contains a negative value, but it must contain a non-negative value.

 

Remarks

A geometry segment is described by the start point, the segment type, and additional parameters whose values are determined by the segment type. The coordinates for the start point of the first segment are a property of the geometry figure and are set by calling SetStartPoint. The start point of each subsequent segment is the end point of the preceding segment.

The number of data values that define a line segment depends on the segment type. The table that follows describes the specific set of required data values that must be used for each segment type. The values in the segment data array that is passed in the segmentData parameter must correspond with the XPS_SEGMENT_TYPE values in the array that is passed in the segmentTypes parameter. For example, if the first line segment has a segment type value of XPS_SEGMENT_TYPE_LINE, the first two data values in the segmentData array will be the x and y coordinates of the end point of that segment; if the next segment has a segment type value of XPS_SEGMENT_TYPE_BEZIER, the next six values in the segmentData array will describe the characteristics of that segment; and so on for each line segment in the geometry figure.

Segment type Required data values

XPS_SEGMENT_TYPE_LINE

A diagram that shows an example of an XPS_SEGMENT_TYPE_LINE figure segment

Two data values:

x-coordinate of the segment line's end point. y-coordinate of the segment line's end point.

XPS_SEGMENT_TYPE_ARC_LARGE_CLOCKWISE

A diagram that shows an example of an XPS_SEGMENT_TYPE_ARC_LARGE_CLOCKWISE figure segment

Five data values:

x-coordinate of the arc's end point. y-coordinate of the arc's end point. Length of the ellipse's radius along the x-axis. Length of the ellipse's radius along the y-axis. Rotation angle.

XPS_SEGMENT_TYPE_ARC_SMALL_CLOCKWISE

A diagram that shows an example of an XPS_SEGMENT_TYPE_ARC_SMALL_CLOCKWISE figure segment

Five data values:

x-coordinate of the arc's end point. y-coordinate of the arc's end point. Length of the ellipse's radius along the x-axis. Length of the ellipse's radius along the y-axis. Rotation angle.

XPS_SEGMENT_TYPE_ARC_LARGE_COUNTERCLOCKWISE

A diagram that shows an example of an XPS_SEGMENT_TYPE_ARC_LARGE_CLOCKWISE figure segment

Five data values:

x-coordinate of the arc's end point. y-coordinate of the arc's end point. Length of the ellipse's radius along the x-axis. Length of the ellipse's radius along the y-axis. Rotation angle.

XPS_SEGMENT_TYPE_ARC_SMALL_COUNTERCLOCKWISE

A diagram that shows an example of an XPS_SEGMENT_TYPE_ARC_SMALL_COUNTERCLOCKWISE figure segment

Five data values:

x-coordinate of the arc's end point. y-coordinate of the arc's end point. Length of the ellipse's radius along the x-axis. Length of the ellipse's radius along the y-axis. Rotation angle.

XPS_SEGMENT_TYPE_BEZIER

A diagram that shows an example of an XPS_SEGMENT_TYPE_BEZIER figure segment

Six data values:

x-coordinate of the Bezier curve's first control point. y-coordinate of the Bezier curve's first control point. x-coordinate of the Bezier curve's second control point. y-coordinate of the Bezier curve's second control point. x-coordinate of the Bezier curve's end point. y-coordinate of the Bezier curve's end point.

XPS_SEGMENT_TYPE_QUADRATIC_BEZIER

A diagram that shows an example of an XPS_SEGMENT_TYPE_QUADRATIC_BEZIER figure segment

Four data values:

x-coordinate of the Quad Bezier curve's control point. y-coordinate of the Quad Bezier curve's control point. x-coordinate of the Quad Bezier curve's end point. y-coordinate of the Quad Bezier curve's end point.

 

To get the segment types in the figure, call GetSegmentTypes.

The following code examples demonstrate one way to create and populate the buffers required by SetSegments.

In the first code example, the AddSegmentDataToArrays method takes the data points that describe a single segment and stores them in the three different data buffers required by the SetSegments method. The data buffers that are passed as arguments to AddSegmentDataToArrays are managed by the calling method as shown in the code example that follows AddSegmentDataToArrays.

HRESULT
AddSegmentDataToArrays(
    XPS_SEGMENT_TYPE        segmentType,
    BOOL                    segmentStroke,
    FLOAT                   *segmentPoints,
    UINT32                  *segmentsAvailable,
    UINT32                  *segmentPointsAvailable,
    XPS_SEGMENT_TYPE        **segmentTypeBuffer,
    BOOL                    **segmentStrokeBuffer,
    FLOAT                   **segmentPointBuffer
)
/*
Description:

Populates the buffers required by IXpsOMGeometryFigure::SetSegmentData
using data and buffers provided by the calling method.

Parameters:

segmentType
    IN: XPS_SEGMENT_TYPE value that specifies the segment type for
        the current segment.

segmentStroke
    IN: BOOL value that specifies whether the current segment 
        is stroked.

*segmentPoints
    IN: pointer to an array of FLOAT values that specify the 
        segment's data points. The number of values in the array
        depend on the value of the segmentType parameter.

*segmentsAvailable
    IN: the number of values that remain unused in the
        segmentTypeBuffer and the segmentStrokeBuffer.
        This value must be >= 1 when calling the method.
    OUT:  the number of values that remain unused in the
        segmentTypeBuffer and the segmentStrokeBuffer after
        segmentType and segmentStroke have been added. If the 
        method was successful, the returned value is one less 
        than the value passed in to the method.

*segmentPointsAvailable
    IN: the number of values that remain unused in the
        segmentPointBuffer.    This value must be greater-than or equal
        to the number of points required by the segmentType value.
    OUT:  the number of values that remain unused in the
        segmentPointBuffer after the segmentPoints have been added.
        The returned value depends on the segmentType value.

**segmentTypeBuffer
    IN: the first free element in the buffer that receives the segment
        type values.
    OUT: the first free element in the buffer that receives the segment
        type values. If the method is successful, this will be the element
        after the element pointed to by this value before the method 
        was called.

**segmentStrokeBuffer
    IN: the first free element in the buffer that receives the segment
        stroke values.
    OUT: the first free element in the buffer that receives the segment
        stroke values. If the method is successful, this will be the element
        after the element pointed to by this value before the method 
        was called.

**segmentPointBuffer
    IN: the first free element in the buffer that receives the segment
        point values.
    OUT: the first free element in the buffer that receives the segment
        point values. If the method is successful, the element referenced
        by this value will depend on the segment type.

Remarks.
1) the buffers and values passed into this method are managed by
    the calling method.

2) if the value returned in segmentsAvailable is 0, segmentTypeBuffer
    and segmentStrokeBuffer point to invalid memory.

3) if the value returned in segmentPointsAvailable is 0, segmentPointBuffer
    point to invalid memory.

*/
{
    HRESULT hr = S_OK;

    // test to see if there is sufficient space in the 
    // segmentTypeBuffer and the segmentStrokeBuffer before
    // proceeding
    if (*segmentsAvailable == 0)
    {
        hr = HRESULT_FROM_WIN32(ERROR_MORE_DATA);
    }

    if (SUCCEEDED(hr))
    {
        // process the data based on the segment type
        switch (segmentType) 
        {
            case    XPS_SEGMENT_TYPE_ARC_LARGE_CLOCKWISE:
            case    XPS_SEGMENT_TYPE_ARC_LARGE_COUNTERCLOCKWISE:
            case    XPS_SEGMENT_TYPE_ARC_SMALL_CLOCKWISE:
            case    XPS_SEGMENT_TYPE_ARC_SMALL_COUNTERCLOCKWISE:
                if (*segmentPointsAvailable >= 5) 
                {
                    // 5 data points
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<arc end point (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<arc end point (y)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<arc radius (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<arc radius (y)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<arc angle
                    *segmentPointsAvailable -= 5;
                }
                else
                {
                    hr = HRESULT_FROM_WIN32(ERROR_MORE_DATA);
                }
                break;
            case    XPS_SEGMENT_TYPE_BEZIER:
                if (*segmentPointsAvailable >= 6) 
                {
                    // 6 data points
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<control point 1 (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<control point 1 (y)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<control point 2 (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<control point 2 (y)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<end point (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<end point (y)
                    *segmentPointsAvailable -= 6;
                }
                else
                {
                    hr = HRESULT_FROM_WIN32(ERROR_MORE_DATA);
                }
                break;
            case    XPS_SEGMENT_TYPE_LINE:
                if (*segmentPointsAvailable >= 2) 
                {
                    // 2 data points
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<end point (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<end point (y)
                    *segmentPointsAvailable -= 2;
                }
                else
                {
                    hr = HRESULT_FROM_WIN32(ERROR_MORE_DATA);
                }
                break;
            case    XPS_SEGMENT_TYPE_QUADRATIC_BEZIER:
                if (*segmentPointsAvailable >= 4) 
                {
                    // 4 data points
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<control point 2 (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<control point 2 (y)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<end point (x)
                    *(*segmentPointBuffer)++ = *segmentPoints++; //<end point (y)
                    *segmentPointsAvailable -= 4;
                }
                else
                {
                    hr = HRESULT_FROM_WIN32(ERROR_MORE_DATA);
                }
                break;
            default:
                // unrecognized segment type
                hr = E_UNEXPECTED;
                break;
        }

    }

    if (SUCCEEDED(hr))
    {
        // Copy segment type and segment stroke values
        // to array and decrement number of array values
        // that remain unused.
        //
        // The space available for these operations was
        // tested at the beginning of the method.
        *(*segmentTypeBuffer)++ = segmentType;
        *(*segmentStrokeBuffer)++ = segmentStroke;
        *segmentsAvailable--;
    } 

    return hr;
}

In this code example, UpdateSegmentData creates the data buffers required by the SetSegments method and calls the AddSegmentDataToArrays method from the preceding code example to populate them with the segment data. After the buffers have been populated, SetSegments is called to add this data to the geometry figure.

Note  The actual segment data is not shown in these code examples.

 

HRESULT
UpdateSegmentData (
    IXpsOMGeometryFigure    *geometryFigure,
    UINT32                  segmentCount,
    UINT32                  segmentDataCount
)
/*
    Note that this method is not complete and only includes
    the code necessary to show how the SetSegments call is used.

    In this sample, the geometryFigure, segmentCount, and
    segmentDataCount values are assumed to have been initialized
    outside of this example.
*/
{
    HRESULT             hr = S_OK;
    XPS_SEGMENT_TYPE    segmentType = (XPS_SEGMENT_TYPE)0;
    BOOL                segmentStroke = FALSE;
    FLOAT               segmentPoints = 0;
    UINT32              segmentsAvailable = 0;
    UINT32              segmentPointsAvailable = 0;
    // these buffers are sized and allocated based on 
    //    the segment data to store.
    XPS_SEGMENT_TYPE    *segmentTypeBuffer = NULL;
    BOOL                *segmentStrokeBuffer = NULL;
    FLOAT               *segmentPointBuffer = NULL;

    XPS_SEGMENT_TYPE    *nextSegmentTypeValue = NULL;
    BOOL                *nextSegmentStrokeValue = NULL;
    FLOAT               *nextSegmentPointValue = NULL;

    // segment data is created outside of this example

    // allocate buffers as required using information 
    // from segment data. This can be dynamic or static
    // depending on how the segment information is managed.
    // This example assumes that the segment information 
    // does not change during this method.

    // initialize "next" pointers to point to the first
    // element in each array.
    nextSegmentTypeValue = segmentTypeBuffer;
    nextSegmentStrokeValue = segmentStrokeBuffer;
    nextSegmentPointValue = segmentPointBuffer;

    // for each segment in the figure, add the 
    // segment data to the buffers

        hr = AddSegmentDataToArrays(
                segmentType,
                segmentStroke,
                &segmentPoints,
                &segmentsAvailable,
                &segmentPointsAvailable,
                &nextSegmentTypeValue,
                &nextSegmentStrokeValue,
                &nextSegmentPointValue);
        
    if (SUCCEEDED(hr))
    {
        // set segment data
        hr = geometryFigure->SetSegments (
            segmentCount,
            segmentDataCount,
            segmentTypeBuffer,
            segmentPointBuffer,
            segmentStrokeBuffer);
    }
    // clean up buffers

    return hr;
}

Requirements

Minimum supported client

Windows 7, Windows Vista with SP2 and Platform Update for Windows Vista [desktop apps | Windows Store apps]

Minimum supported server

Windows Server 2008 R2, Windows Server 2008 with SP2 and Platform Update for Windows Server 2008 [desktop apps | Windows Store apps]

Header

Xpsobjectmodel.h

IDL

XpsObjectModel.idl

See also

IXpsOMGeometryFigure

GetSegmentTypes

XPS_SEGMENT_TYPE

XPS Document Errors

XML Paper Specification