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+/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
+/*
+ * This file is part of the LibreOffice project.
+ *
+ * This Source Code Form is subject to the terms of the Mozilla Public
+ * License, v. 2.0. If a copy of the MPL was not distributed with this
+ * file, You can obtain one at http://mozilla.org/MPL/2.0/.
+ *
+ * This file incorporates work covered by the following license notice:
+ *
+ * Licensed to the Apache Software Foundation (ASF) under one or more
+ * contributor license agreements. See the NOTICE file distributed
+ * with this work for additional information regarding copyright
+ * ownership. The ASF licenses this file to you under the Apache
+ * License, Version 2.0 (the "License"); you may not use this file
+ * except in compliance with the License. You may obtain a copy of
+ * the License at http://www.apache.org/licenses/LICENSE-2.0 .
+ */
+
+#ifndef INCLUDED_VCL_GRAPHICTOOLS_HXX
+#define INCLUDED_VCL_GRAPHICTOOLS_HXX
+
+#include <vcl/dllapi.h>
+#include <sal/types.h>
+#include <tools/color.hxx>
+#include <tools/poly.hxx>
+#include <vcl/graph.hxx>
+
+#include <vector>
+
+class SvStream;
+
+/** Encapsulates geometry and associated attributes of a graphical 'pen stroke'
+
+ @attention Widespread use is deprecated. See declarations above
+ for the way to go. Especially the copied enums from svx/xenum.hxx
+ are troublesome.
+
+ Use this class to store geometry and attributes of a graphical
+ 'pen stroke', such as pen width, dashing etc. The geometry is the
+ so-called 'path' along which the stroke is traced, with the given
+ pen width. The cap type determines how the open ends of the path
+ should be drawn. If the geometry consists of more than one
+ segment, the join type determines in which way the segments are
+ joined.
+ */
+class VCL_DLLPUBLIC SvtGraphicStroke
+{
+public:
+ /// Style for open stroke ends
+ enum CapType
+ {
+ /// No additional cap
+ capButt=0,
+ /// Half-round cap at the line end, the center lying at the end point
+ capRound,
+ /// Half-square cap at the line end, the center lying at the end point
+ capSquare
+ };
+ /// Style for joins of individual stroke segments
+ enum JoinType
+ {
+ /// Extend segment edges, until they cross
+ joinMiter=0,
+ /// Connect segments by a filled round arc
+ joinRound,
+ /// Connect segments by a direct straight line
+ joinBevel,
+ /// Perform no join, leads to visible gaps between thick line segments
+ joinNone
+ };
+ typedef ::std::vector< double > DashArray;
+
+ SvtGraphicStroke();
+ /** All in one constructor
+
+ See accessor method descriptions for argument description
+ */
+ SvtGraphicStroke( const tools::Polygon& rPath,
+ const tools::PolyPolygon& rStartArrow,
+ const tools::PolyPolygon& rEndArrow,
+ double fTransparency,
+ double fStrokeWidth,
+ CapType aCap,
+ JoinType aJoin,
+ double fMiterLimit,
+ const DashArray& rDashArray ); // TODO: Dash array offset (position where to start, see PS)
+
+ // accessors
+ /// Query path to stroke
+ void getPath ( tools::Polygon& ) const;
+ /** Get the polygon that is put at the start of the line
+
+ The polygon is in a special normalized position: the center of
+ the stroked path will meet the given polygon at (0,0) from
+ negative y values. Thus, an arrow would have its baseline on
+ the x axis, going upwards to positive y values. Furthermore,
+ the polygon is also scaled in a special way: the width of the
+ joining stroke is defined to be
+ SvtGraphicStroke::normalizedArrowWidth (0x10000), i.e. ranging
+ from x=-0x8000 to x=0x8000. So, if the arrow does have this
+ width, it has to fit every stroke with every stroke width
+ exactly.
+ */
+ void getStartArrow ( tools::PolyPolygon& ) const;
+ /** Get the polygon that is put at the end of the line
+
+ The polygon is in a special normalized position, and already
+ scaled to the desired size: the center of the stroked path
+ will meet the given polygon at (0,0) from negative y
+ values. Thus, an arrow would have its baseline on the x axis,
+ going upwards to positive y values. Furthermore, the polygon
+ is also scaled in a special way: the width of the joining
+ stroke is defined to be SvtGraphicStroke::normalizedArrowWidth
+ (0x10000), i.e. ranging from x=-0x8000 to x=0x8000. So, if the
+ arrow does have this width, it has to fit every stroke with
+ every stroke width exactly.
+ */
+ void getEndArrow ( tools::PolyPolygon& ) const;
+ /** Get stroke transparency
+
+ @return the transparency, ranging from 0.0 (opaque) to 1.0 (fully translucent)
+ */
+ double getTransparency () const { return mfTransparency;}
+ /// Get width of the stroke
+ double getStrokeWidth () const { return mfStrokeWidth;}
+ /// Get the style in which open stroke ends are drawn
+ CapType getCapType () const { return maCapType;}
+ /// Get the style in which the stroke segments are joined
+ JoinType getJoinType () const { return maJoinType;}
+ /// Get the maximum length of mitered joins
+ double getMiterLimit () const { return mfMiterLimit;}
+ /// Get an array of "on" and "off" lengths for stroke dashing
+ void getDashArray ( DashArray& ) const;
+
+ // mutators
+ /// Set path to stroke
+ void setPath ( const tools::Polygon& );
+ /** Set the polygon that is put at the start of the line
+
+ The polygon has to be in a special normalized position, and
+ already scaled to the desired size: the center of the stroked
+ path will meet the given polygon at (0,0) from negative y
+ values. Thus, an arrow would have its baseline on the x axis,
+ going upwards to positive y values. Furthermore, the polygon
+ also has to be scaled appropriately: the width of the joining
+ stroke is defined to be SvtGraphicStroke::normalizedArrowWidth
+ (0x10000), i.e. ranging from x=-0x8000 to x=0x8000. If your
+ arrow does have this width, it will fit every stroke with
+ every stroke width exactly.
+ */
+ void setStartArrow ( const tools::PolyPolygon& );
+ /** Set the polygon that is put at the end of the line
+
+ The polygon has to be in a special normalized position, and
+ already scaled to the desired size: the center of the stroked
+ path will meet the given polygon at (0,0) from negative y
+ values. Thus, an arrow would have its baseline on the x axis,
+ going upwards to positive y values. Furthermore, the polygon
+ also has to be scaled appropriately: the width of the joining
+ stroke is defined to be SvtGraphicStroke::normalizedArrowWidth
+ (0x10000), i.e. ranging from x=-0x8000 to x=0x8000. If your
+ arrow does have this width, it will fit every stroke with
+ every stroke width exactly.
+ */
+ void setEndArrow ( const tools::PolyPolygon& );
+ /// Affine scaling in both X and Y dimensions
+ void scale ( double fScaleX, double fScaleY );
+
+private:
+ // friends
+ VCL_DLLPUBLIC friend SvStream& WriteSvtGraphicStroke( SvStream& rOStm, const SvtGraphicStroke& rClass );
+ VCL_DLLPUBLIC friend SvStream& ReadSvtGraphicStroke( SvStream& rIStm, SvtGraphicStroke& rClass );
+
+ tools::Polygon maPath;
+ tools::PolyPolygon maStartArrow;
+ tools::PolyPolygon maEndArrow;
+ double mfTransparency;
+ double mfStrokeWidth;
+ CapType maCapType;
+ JoinType maJoinType;
+ double mfMiterLimit;
+ DashArray maDashArray;
+};
+
+/** Encapsulates geometry and associated attributes of a filled area
+
+ @attention Widespread use is deprecated. See declarations above
+ for the way to go. Especially the copied enums from svx/xenum.hxx
+ is troublesome.
+
+ Use this class to store geometry and attributes of a filled area,
+ such as fill color, transparency, texture or hatch. The geometry
+ is the so-called 'path', whose inner area will get filled
+ according to the attributes set. If the path is intersecting, or
+ one part of the path is lying fully within another part, then the
+ fill rule determines which parts are filled and which are not.
+ */
+class VCL_DLLPUBLIC SvtGraphicFill
+{
+public:
+ /// Type of fill algorithm used
+ enum FillRule
+ {
+ /** Non-zero winding rule
+
+ Fill shape scanline-wise. Starting at the left, determine
+ the winding number as follows: every segment crossed that
+ runs counter-clockwise adds one to the winding number,
+ every segment crossed that runs clockwise subtracts
+ one. The part of the scanline where the winding number is
+ non-zero gets filled.
+ */
+ fillNonZero=0,
+ /** Even-odd fill rule
+
+ Fill shape scanline-wise. Starting at the left, count the
+ number of segments crossed. If this number is odd, the
+ part of the scanline is filled, otherwise not.
+ */
+ fillEvenOdd
+ };
+ /// Type of filling used
+ enum FillType
+ {
+ /// Fill with a specified solid color
+ fillSolid=0,
+ /// Fill with the specified gradient
+ fillGradient,
+ /// Fill with the specified hatch
+ fillHatch,
+ /// Fill with the specified texture (a Graphic object)
+ fillTexture
+ };
+ /// Type of hatching used
+ enum HatchType
+ {
+ /// horizontal parallel lines, one unit apart
+ hatchSingle=0,
+ /// horizontal and vertical orthogonally crossing lines, one unit apart
+ hatchDouble,
+ /// three crossing lines, like HatchType::hatchDouble, but
+ /// with an additional diagonal line, rising to the upper
+ /// right corner. The first diagonal line goes through the
+ /// upper left corner, the other are each spaced a unit apart.
+ hatchTriple
+ };
+ /// Type of gradient used
+ enum class GradientType {Linear, Radial, Rectangular};
+ /// Special values for gradient step count
+ enum { gradientStepsInfinite=0 };
+ /** Homogeneous 2D transformation matrix
+
+ This is a 2x3 matrix representing an affine transformation on
+ the R^2, in the usual C/C++ row major form. It is structured as follows:
+ <pre>
+ a b t_x
+ c d t_y
+ 0 0 1
+ </pre>
+ where the lowest line is not stored in the matrix, since it is
+ constant. Variables t_x and t_y contain translational
+ components, a to d rotation, scale and shear (for details,
+ look up your favorite linear algebra/computer graphics book).
+ */
+ struct VCL_DLLPUBLIC Transform
+ {
+ enum { MatrixSize=6 };
+ Transform();
+ double matrix[MatrixSize];
+ };
+
+ SvtGraphicFill();
+ /** All in one constructor
+
+ See accessor method descriptions for argument description
+ */
+ SvtGraphicFill( const tools::PolyPolygon& rPath,
+ Color aFillColor,
+ double fTransparency,
+ FillRule aFillRule,
+ FillType aFillType, // TODO: Multitexturing
+ const Transform& aFillTransform,
+ bool bTiling,
+ HatchType aHatchType, // TODO: vector of directions and start points
+ Color aHatchColor,
+ GradientType aGradientType, // TODO: Transparent gradients (orthogonal to normal ones)
+ Color aGradient1stColor, // TODO: vector of colors and offsets
+ Color aGradient2ndColor,
+ sal_Int32 aGradientStepCount, // numbers of steps to render the gradient. gradientStepsInfinite means infinitely many.
+ const Graphic& aFillGraphic );
+
+ // accessors
+ /// Query path to fill
+ void getPath ( tools::PolyPolygon& ) const;
+ /// Get color used for solid fills
+ const Color& getFillColor () const { return maFillColor;}
+ /** Get stroke transparency
+
+ @return the transparency, ranging from 0.0 (opaque) to 1.0 (fully translucent)
+ */
+ double getTransparency () const { return mfTransparency;}
+ /// Get fill rule used
+ FillRule getFillRule () const { return maFillRule;}
+ /** Get fill type used
+
+ Currently, only one of the fill types can be used
+ simultaneously. If you specify e.g. FillRule::fillGradient,
+ hatching, texture and solid fill color are ignored.
+ */
+ FillType getFillType () const { return maFillType;}
+ /** Get transformation applied to hatch, gradient or texture during fill
+
+ A fill operation generally starts at the top left position of
+ the object's bounding box. At that position (if tiling is on,
+ also all successive positions), the specified fill graphic is
+ rendered, after applying the fill transformation to it. For
+ example, if the fill transformation contains a translation,
+ the fill graphic is rendered at the object's bounding box's
+ top left corner plus the translation components.
+
+ */
+ void getTransform ( Transform& ) const;
+
+ /** Query state of texture tiling
+
+ @return true, if texture is tiled, false, if output only once.
+ */
+ bool isTiling () const { return mbTiling;}
+ /// Get type of gradient used
+ GradientType getGradientType () const { return maGradientType;}
+
+ /** Get the texture graphic used
+
+ The Graphic object returned is used to fill the geometry, if
+ the FillType is fillTexture. The Graphic object is always
+ assumed to be of size 1x1, the transformation is used to scale
+ it to the appropriate size.
+ */
+ void getGraphic ( Graphic& ) const;
+
+ // mutators
+ /// Set path to fill
+ void setPath ( const tools::PolyPolygon& rPath );
+
+private:
+ // friends
+ VCL_DLLPUBLIC friend SvStream& WriteSvtGraphicFill( SvStream& rOStm, const SvtGraphicFill& rClass );
+ VCL_DLLPUBLIC friend SvStream& ReadSvtGraphicFill( SvStream& rIStm, SvtGraphicFill& rClass );
+
+ tools::PolyPolygon maPath;
+ Color maFillColor;
+ double mfTransparency;
+ FillRule maFillRule;
+ FillType maFillType;
+ Transform maFillTransform;
+ bool mbTiling;
+ HatchType maHatchType;
+ Color maHatchColor;
+ GradientType maGradientType;
+ Color maGradient1stColor;
+ Color maGradient2ndColor;
+ sal_Int32 maGradientStepCount;
+ Graphic maFillGraphic;
+};
+
+#endif // INCLUDED_VCL_GRAPHICTOOLS_HXX
+
+/* vim:set shiftwidth=4 softtabstop=4 expandtab: */