fanculo giuseppona
This commit is contained in:
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3 changed files with 22 additions and 1027 deletions
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@ -13,7 +13,6 @@ header-includes:
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- \usepackage{float}
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- \usepackage{float}
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- \floatplacement{figure}{H}
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- \floatplacement{figure}{H}
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- \hypersetup{colorlinks=true,linkcolor=blue}
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- \hypersetup{colorlinks=true,linkcolor=blue}
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---
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---
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\maketitle
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\maketitle
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@ -93,40 +92,40 @@ $$
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A x=b, A^{T} \lambda+s=c,(x, s)>0\right\} \end{array}
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A x=b, A^{T} \lambda+s=c,(x, s)>0\right\} \end{array}
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$$
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$$
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A central path $\mathcal{C}$ is defined as an arc strictly composed of feasible
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The definition of the central path $\mathcal{C}$ is an arc, strictly composed of
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points which is parametrized by a scalar $\tau>0$ where each point
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feasible points. The path is parametrized by a scalar $\tau>0$ where each point
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$\left(x_{\tau}, \lambda_{\tau}, s_{\tau}\right) \in \mathcal{C}$ satisfies the
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in the path $\left(x_{\tau}, \lambda_{\tau}, s_{\tau}\right) \in \mathcal{C}$
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following conditions:
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satisfies the following conditions:
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$$
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$$
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\begin{array}{c}
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\begin{array}{c}
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A^{T} \lambda+s=c \\
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A^{T} \lambda+s=c \\
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A x=b \\
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A x=b \\
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x_{i} s_{i}=\tau \quad i=1,2, \ldots, n \\
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x_{i} s_{i}=\tau > 0 \quad i=1,2, \ldots, n \\
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(x, s)>0
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(x, s)>0
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\end{array}
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\end{array}
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$$
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$$
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We can observe how these conditions are very much similar to the KKT conditions
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These conditions are very similar to the KKT conditions, differning only
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and, in fact, they only differ by the factor $\tau$ and by requiring the
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by the factor $\tau$ and by requiring the pairwise products to be strictly
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pairwise products to be strictly greater than zero. With this, we can define the
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greater than zero. With this, we can define the central path as follows:
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central path as follows:
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$$
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$$
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\mathcal{C}=\left\{\left(x_{\tau}, \lambda_{\tau}, s_{\tau}\right) \mid
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\mathcal{C}=\left\{\left(x_{\tau}, \lambda_{\tau}, s_{\tau}\right) \mid
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\tau>0\right\}
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\tau>0\right\}
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$$
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$$
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Given these definitions, we can also observe that, as $\tau$ approaches zero,
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We can then observe that as $\tau$ approaches 0, the set of conditions defined
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the conditions we have defined become a closer and closer approximation to the
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above get closer and closer to the true KKT conditions. Therefore, if the
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original KKT conditions. Therefore, if the central path $\mathcal{C}$ converges
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central path C converges to anything then $\tau$ approaches zero, therefore
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to anything as $\tau$ approaches zero, then we know that it will converge to a
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leading the path to the constrained minimizer while keeping $x$ and $s$
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solution of the linear program. Meaning that the central path is leading us to a
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positive but at the same time minimizing their pairwise products to zero.
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solution by maintaining $x$ and $s$ positive while reducing the pairwise
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products to zero at the same time. Usually, the Newton method is used to take
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In practice, most central path implementation use Newton steps toward points on
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steps following $\mathcal{C}$ rather than by following the set of feasible
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$\mathcal{C}$ for which $\tau > 0$, rather than pure Newton steps for $F$. This
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points $\mathcal{F}$ because it allows for longer steps before violating the
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is usually possible since those newton steps are biased to stay in the
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positivity constraint.
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hyperspace region where $x > 0$ and $s > 0$ even without enforcing these
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constraints.
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# Exercise 2
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# Exercise 2
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@ -139,22 +138,6 @@ below:
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## Exercise 2.2
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## Exercise 2.2
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<!--The Simplex method is used to solve linear programs which are defined as
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follows:
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$$\min c^Tx, \text{ subject to } Ax = b, x > 0$$
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And when we have inequalities constraints such as:
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$$\min c^Tx,\text{ subject to }Ax \leq b$$
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We can introduce slack variable to convert the inequalities into equalities:
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$$\min c^Tx,\text{ subject to }Ax + z = 0, z>0$$
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Each iterate generated by the simplex method is a basic feasible point which
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is a-->
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According to Nocedal, a vector $x$ is a basic feasible point if it is in the
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According to Nocedal, a vector $x$ is a basic feasible point if it is in the
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feasible region and if there exists a subset $\beta$ of the
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feasible region and if there exists a subset $\beta$ of the
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index set $1, 2, \ldots, n$ such that:
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index set $1, 2, \ldots, n$ such that:
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@ -172,35 +155,14 @@ proven property to manually solve the constrained minimization problem presented
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in this section by aiding us with the graphical plot of the feasible region in
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in this section by aiding us with the graphical plot of the feasible region in
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figure \ref{fig:a}.
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figure \ref{fig:a}.
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<!--
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And as already been
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said, the basic feasible point is the basic feasible solution for the problem.
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Regarding the section 13.3, which outline how the steps are done, we know that
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most steps consist of a move from one vertex to an adjacent one for which the
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basis $\beta$ differs exactly one component.The step is an edge along which the
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objective function is reduced.
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Then, one major issue at every simplex iteration
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is to decide which index must be removed from the basis. As the book specify,
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unless the step is a direction of unboundedness, a single index must be removed
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by replacing it with another from outside $\beta$.
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From a geometrical point of view,
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a move, is along an edge of the feasible polytope that decreases $c^Tx$ and we
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continue moving along that edge until we find a new vertex. One we find a vertex
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we defined the new constraint $x_p > 0$ which is one of the component $x_p,p \in \beta$
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decreased to zero. Afterwards we can remove the index $p$ from the basis $\beta$ and
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replace it with $q$. A more detailed visualisation can be see in the following
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Figure 1 taken from the book.-->
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## Exercise 2.3
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## Exercise 2.3
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Since the geometrical interpretation of the definition of basic feasible point
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Since the geometrical interpretation of the definition of basic feasible point
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states that these point are non-other than the vertices of the feasible region,
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states that these point are non-other than the vertices of the feasible region,
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we first look at the plot above and to these points (i.e. the vertices of the
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we first look at the plot above and to these points (i.e. the vertices of the
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bright green non-trasparent region). Then, we look which constraint boundaries cross these
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bright green non-trasparent region). Then, we look which constraint boundaries
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edges, and we formulate an algebraic expression to find these points. In
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cross these edges, and we formulate an algebraic expression to find these
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clockwise order, we have:
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points. In clockwise order, we have:
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- The lower-left point at the origin, given by the boundaries of the constraints
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- The lower-left point at the origin, given by the boundaries of the constraints
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$x_1 \geq 0$ and $x_2 \geq 0$:
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$x_1 \geq 0$ and $x_2 \geq 0$:
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Binary file not shown.
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@ -1,967 +0,0 @@
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function H = hatchfill(A,varargin)
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% HATCHFILL2 Hatching and speckling of patch objects
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% HATCHFILL2(A) fills the patch(es) with handle(s) A. A can be a vector
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% of handles or a single handle. If A is a vector, then all objects of A
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% should be part of the same group for predictable results. The hatch
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% consists of black lines angled at 45 degrees at 40 hatching lines over
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% the axis span with no color filling between the lines.
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%
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% A can be handles of patch or hggroup containing patch objects for
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% Pre-R2014b release. For HG2 releases, 'bar' and 'contour' objects are
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% also supported.
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%
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% Hatching line object is actively formatted. If A, axes, or figure size
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% is modified, the hatching line object will be updated accordingly to
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% maintain the specified style.
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%
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% HATCHFILL2(A,STYL) applies STYL pattern with default paramters. STYL
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% options are:
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% 'single' single lines (the default)
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% 'cross' double-crossed hatch
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% 'speckle' speckling inside the patch boundary
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% 'outspeckle' speckling outside the boundary
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% 'fill' no hatching
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%
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% HATCHFILL2(A,STYL,Option1Name,Option1Value,...) to customize the
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% hatching pattern
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%
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% Name Description
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% --------------------------------------------------------------------
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% HatchStyle Hatching pattern (same effect as STYL argument)
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% HatchAngle Angle of hatch lines in degrees (45)
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% HatchDensity Number of hatch lines between axis limits
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% HatchOffset Offset hatch lines in pixels (0)
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% HatchColor Color of the hatch lines, 'auto' sets it to the
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% EdgeColor of A
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% HatchLineStyle Hatch line style
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% HatchLineWidth Hatch line width
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% SpeckleWidth Width of speckling region in pixels (7)
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% SpeckleDensity Density of speckle points (1)
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% SpeckleMarkerStyle Speckle marker style
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% SpeckleFillColor Speckle fill color
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% HatchVisible [{'auto'}|'on'|'off'] sets visibility of the hatch
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% lines. If 'auto', Visibile option is synced to
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% underlying patch object
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% HatchSpacing (Deprecated) Spacing of hatch lines (5)
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%
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% In addition, name/value pairs of any properties of A can be specified
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%
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% H = HATCHFILL2(...) returns handles to the line objects comprising the
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% hatch/speckle.
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%
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% Examples:
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% Gray region with hatching:
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% hh = hatchfill2(a,'cross','HatchAngle',45,'HatchSpacing',5,'FaceColor',[0.5 0.5 0.5]);
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%
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% Speckled region:
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% hatchfill2(a,'speckle','HatchAngle',7,'HatchSpacing',1);
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% Copyright 2015-2018 Takeshi Ikuma
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% History:
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% rev. 7 : (01-10-2018)
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% * Added support for 3D faces
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% * Removed HatchSpacing option
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% * Added HatchDensity option
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% * Hatching is no longer defined w.r.t. pixels. HatchDensity is defined
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% as the number of hatch lines across an axis limit. As a result,
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% HatchAngle no longer is the actual hatch angle though it should be
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% close.
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% * [known bug] Speckle hatching style is not working
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% rev. 6 : (07-17-2016)
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% * Fixed contours object hatching behavior, introduced in rev.5
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% * Added ContourStyle option to enable fast drawing if contour is convex
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% rev. 5 : (05-12-2016)
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% * Fixed Contour with NaN data point disappearnace issue
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% * Improved contours object support
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% rev. 4 : (11-18-2015)
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% * Worked around the issue with HG2 contours with Fill='off'.
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% * Removed nagging warning "UseHG2 will be removed..." in R2015b
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% rev. 3 : (10-29-2015)
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% * Added support for HG2 AREA
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% * Fixed for HatchColor 'auto' error when HG2 EdgeColor is 'flat'
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% * Fixed listener creation error
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% rev. 2 : (10-24-2015)
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% * Added New option: HatchVisible, SpeckleDensity, SpeckleWidth
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% (SpeckleDensity and SpeckleWidtha are separated from HatchSpacing and
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% HatchAngle, respectively)
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% rev. 1 : (10-20-2015)
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% * Fixed HG2 contour data extraction bug (was using wrong hidden data)
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% * Fixed HG2 contour color extraction bug
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% * A few cosmetic changes here and there
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% rev. - : (10-19-2015) original release
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% * This work is based on Neil Tandon's hatchfill submission
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% (http://www.mathworks.com/matlabcentral/fileexchange/30733)
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% and borrowed code therein from R. Pawlowicz, K. Pankratov, and
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% Iram Weinstein.
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narginchk(1,inf);
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[A,opts,props] = parse_input(A,varargin);
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drawnow % make sure the base objects are already drawn
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if verLessThan('matlab','8.4')
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H = cell(1,numel(A));
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else
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H = repmat({matlab.graphics.GraphicsPlaceholder},1,numel(A));
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end
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for n = 1:numel(A)
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H{n} = newhatch(A(n),opts,props);
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% if legend of A(n) is shown, add hatching to it as well
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% leg = handle(legend(ancestor(A,'axes')));
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% hsrc = [leg.EntryContainer.Children.Object];
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% hlc = leg.EntryContainer.Children(find(hsrc==A(n),1));
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% if ~isempty(hlc)
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% hlc = hlc.Children(1); % LegendIcon object
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% get(hlc.Children(1))
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% end
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end
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if nargout==0
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clear H
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else
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H = [H{:}];
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if numel(H)==numel(A)
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H = reshape(H,size(A));
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else
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H = H(:);
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end
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end
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end
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function H = newhatch(A,opts,props)
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% 0. retrieve pixel-data conversion parameters
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% 1. retrieve face & vertex matrices from A
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% 2. convert vertex matrix from data to pixels units
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% 3. get xdata & ydata of hatching lines for each face
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% 4. concatenate lines sandwitching nan's in between
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% 5. convert xdata & ydata back to data units
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% 6. plot the hatching line
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% traverse if hggroup/hgtransform
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if ishghandle(A,'hggroup')
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if verLessThan('matlab','8.4')
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H = cell(1,numel(A));
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else
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H = repmat({matlab.graphics.GraphicsPlaceholder},1,numel(A));
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end
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for n = 1:numel(A.Children)
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try
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H{n} = newhatch(A.Children(n),opts,props);
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catch
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end
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end
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H = [H{:}];
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return;
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end
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% Modify the base object property if given
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if ~isempty(props)
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pvalold = sethgprops(A,props);
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end
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try
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vislisena = strcmp(opts.HatchVisible,'auto');
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if vislisena
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vis = A.Visible;
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else
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vis = opts.HatchVisible;
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end
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redraw = strcmp(A.Visible,'off') && ~vislisena;
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if redraw
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A.Visible = 'on'; % momentarily make the patch visible
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drawnow;
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end
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% get the base object's vertices & faces
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[V,F,FillFcns] = gethgdata(A); % object does not have its patch data ready
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if redraw
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A.Visible = 'off'; % momentarily make the patch visible
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end
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if ~isempty(FillFcns)
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FillFcns{1}();
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drawnow;
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[V,F] = gethgdata(A); % object does not have its patch data ready
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FillFcns{2}();
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drawnow;
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end
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% recompute hatch line data
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[X,Y,Z] = computeHatchData(handle(ancestor(A,'axes')),V,F,opts);
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% 6. plot the hatching line
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commonprops = {'Parent',A.Parent,'DisplayName',A.DisplayName,'Visible',vis};
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if ~strcmp(opts.HatchColor,'auto')
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commonprops = [commonprops {'Color',opts.HatchColor,'MarkerFaceColor',opts.HatchColor}];
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end
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if isempty(regexp(opts.HatchStyle,'speckle$','once'))
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H = line(X,Y,Z,commonprops{:},'LineStyle',opts.HatchLineStyle','LineWidth',opts.HatchLineWidth);
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else
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H = line(X,Y,Z,commonprops{:},'LineStyle','none','Marker',opts.SpeckleMarkerStyle,...
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'MarkerSize',opts.SpeckleSize,'Parent',A.Parent,'DisplayName',A.DisplayName);
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end
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if strcmp(opts.HatchColor,'auto')
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syncColor(H,A);
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end
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if isempty(H)
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error('Unable to obtain hatching data from the specified object A.');
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end
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% 7. Move H so that it is place right above A in parent's uistack
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p = handle(A.Parent);
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Hcs = handle(p.Children);
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[~,idx] = ismember(A,Hcs); % always idx(1)>idx(2) as H was just created
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p.Children = p.Children([2:idx-1 1 idx:end]);
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% if HG1, all done | no dynamic adjustment support
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if verLessThan('matlab','8.4')
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return;
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end
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|
|
||||||
% save the config data & set up the object listeners
|
|
||||||
setappdata(A,'HatchFill2Opts',opts); % hatching options
|
|
||||||
setappdata(A,'HatchFill2Obj',H); % hatching line object
|
|
||||||
setappdata(A,'HatchFill2LastData',{V,F}); % last patch data
|
|
||||||
setappdata(A,'HatchFill2LastVisible',A.Visible); % last sensitive properties
|
|
||||||
setappdata(A,'HatchFill2PostMarkedClean',{}); % run this function at the end of the MarkClean callback and set NoAction flag
|
|
||||||
setappdata(A,'HatchFill2NoAction',false); % no action during next MarkClean callback, callback only clears this flag
|
|
||||||
setappdata(H,'HatchFill2MatchVisible',vislisena);
|
|
||||||
setappdata(H,'HatchFill2MatchColor',strcmp(opts.HatchColor,'auto'));
|
|
||||||
setappdata(H,'HatchFill2Patch',A); % base object
|
|
||||||
|
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
||||||
% Create listeners for active formatting
|
|
||||||
|
|
||||||
addlistener(H,'ObjectBeingDestroyed',@hatchBeingDeleted);
|
|
||||||
|
|
||||||
lis = [
|
|
||||||
addlistener(A,'Reparent',@objReparent)
|
|
||||||
addlistener(A,'ObjectBeingDestroyed',@objBeingDeleted);
|
|
||||||
addlistener(A,'MarkedClean',@objMarkedClean)
|
|
||||||
addlistener(A,'LegendEntryDirty',@(h,evt)[])]; % <- study this later
|
|
||||||
|
|
||||||
syncprops = {'Clipping','HitTest','Interruptible','BusyAction','UIContextMenu'};
|
|
||||||
syncprops(~cellfun(@(p)isprop(A,p),syncprops)) = [];
|
|
||||||
for n = 1:numel(syncprops)
|
|
||||||
lis(n+2) = addlistener(A,syncprops{n},'PostSet',@syncProperty);
|
|
||||||
end
|
|
||||||
|
|
||||||
catch ME
|
|
||||||
% something went wrong, restore the base object properties
|
|
||||||
if ~isempty(props)
|
|
||||||
for pname = fieldnames(pvalold)'
|
|
||||||
name = pname{1};
|
|
||||||
val = pvalold.(name);
|
|
||||||
if iscell(val)
|
|
||||||
pvalold.(name){1}.(name) = pvalold.(name){2};
|
|
||||||
else
|
|
||||||
A.(name) = pvalold.(name);
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
ME.rethrow();
|
|
||||||
end
|
|
||||||
end
|
|
||||||
%%%%%%%%%% EVENT CALLBACK FUNCTIONS %%%%%%%%%%%%
|
|
||||||
% Base Object's listeners
|
|
||||||
% objReparent - also move the hatch object
|
|
||||||
% ObjectingBeingDestroyed - also destroy the hatch object
|
|
||||||
% MarkedClean - match color if HatchColor = 'auto'
|
|
||||||
% - check if vertex & face changed; if so redraw hatch
|
|
||||||
% - check if hatch redraw triggered the event due to object's
|
|
||||||
% face not shown; if so clear the flag
|
|
||||||
function objMarkedClean(hp,~)
|
|
||||||
% CALLBACK for base object's MarkedClean event
|
|
||||||
% check: visibility change, hatching area change, & color change
|
|
||||||
if getappdata(hp,'HatchFill2NoAction')
|
|
||||||
setappdata(A,'HatchFill2NoAction',false);
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
% get the main patch object (loops if hggroup or HG2 objects)
|
|
||||||
H = getappdata(hp,'HatchFill2Obj');
|
|
||||||
rehatch = ~strcmp(hp.Visible,getappdata(hp,'HatchFill2LastVisible'));
|
|
||||||
if rehatch % if visibility changed
|
|
||||||
setappdata(hp,'HatchFill2LastVisible',hp.Visible);
|
|
||||||
if strcmp(hp.Visible,'off') % if made hidden, hide hatching as well
|
|
||||||
if getappdata(H,'HatchFill2MatchVisible')
|
|
||||||
H.Visible = 'off';
|
|
||||||
return; % nothing else to do
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
% get the patch data
|
|
||||||
[V,F,FillFcns] = gethgdata(hp);
|
|
||||||
if ~isempty(FillFcns) % patch does not exist, must momentarily generate it
|
|
||||||
FillFcns{1}();
|
|
||||||
setappdata(A,'HatchFill2PostMarkedClean',FillFcns{2});
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
if ~rehatch % if visible already 'on', check for the change in object data
|
|
||||||
VFlast = getappdata(hp,'HatchFill2LastData');
|
|
||||||
rehatch = ~isequaln(F,VFlast{2}) || ~isequaln(V,VFlast{1});
|
|
||||||
end
|
|
||||||
% rehatch if patch data/visibility changed
|
|
||||||
if rehatch
|
|
||||||
% recompute hatch line data
|
|
||||||
[X,Y,Z] = computeHatchData(ancestor(H,'axes'),V,F,getappdata(hp,'HatchFill2Opts'));
|
|
||||||
|
|
||||||
% update the hatching line data
|
|
||||||
set(H,'XData',X,'YData',Y,'ZData',Z);
|
|
||||||
% save patch data
|
|
||||||
setappdata(hp,'HatchFill2LastData',{V,F});
|
|
||||||
end
|
|
||||||
% sync the color
|
|
||||||
syncColor(H,hp);
|
|
||||||
% run post callback if specified (expect it to trigger another MarkedClean
|
|
||||||
% event immediately)
|
|
||||||
fcn = getappdata(hp,'HatchFill2PostMarkedClean');
|
|
||||||
if ~isempty(fcn)
|
|
||||||
setappdata(hp,'HatchFill2PostMarkedClean',function_handle.empty);
|
|
||||||
setappdata(hp,'HatchFill2NoAction',true);
|
|
||||||
fcn();
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
end
|
|
||||||
function syncProperty(~,evt)
|
|
||||||
% sync Visible property to the patch object
|
|
||||||
hp = handle(evt.AffectedObject); % patch object
|
|
||||||
hh = getappdata(hp,'HatchFill2Obj');
|
|
||||||
hh.(evt.Source.Name) = hp.(evt.Source.Name);
|
|
||||||
end
|
|
||||||
function objReparent(hp,evt)
|
|
||||||
%objReparent event listener callback
|
|
||||||
pnew = evt.NewValue;
|
|
||||||
if isempty(pnew)
|
|
||||||
return; % no change?
|
|
||||||
end
|
|
||||||
% move the hatch line object over as well
|
|
||||||
H = getappdata(hp,'HatchFill2Obj');
|
|
||||||
H.Parent = pnew;
|
|
||||||
% make sure to move the hatch line object right above the patch object
|
|
||||||
Hcs = handle(pnew.Children);
|
|
||||||
[~,idx] = ismember(hp,Hcs); % always idx(1)>idx(2) as H was just moved
|
|
||||||
pnew.Children = pnew.Children([2:idx-1 1 idx:end]);
|
|
||||||
end
|
|
||||||
function objBeingDeleted(hp,~)
|
|
||||||
%when base object is deleted
|
|
||||||
if isappdata(hp,'HatchFill2Obj')
|
|
||||||
H = getappdata(hp,'HatchFill2Obj');
|
|
||||||
try % in case H is already deleted
|
|
||||||
delete(H);
|
|
||||||
catch
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
function hatchBeingDeleted(hh,~)
|
|
||||||
%when hatch line object (hh) is deleted
|
|
||||||
if isappdata(hh,'HatchFill2Patch')
|
|
||||||
|
|
||||||
% remove listeners listening to the patch object
|
|
||||||
hp = getappdata(hh,'HatchFill2Patch');
|
|
||||||
|
|
||||||
if isappdata(hp,'HatchFill2Listeners')
|
|
||||||
delete(getappdata(hp,'HatchFill2Listeners'));
|
|
||||||
rmappdata(hp,'HatchFill2Listeners');
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
||||||
function varargout = computeHatchData(ax,V,F,opts)
|
|
||||||
varargout = cell(1,nargout);
|
|
||||||
if isempty(V) % if patch shown
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
N = size(F,1);
|
|
||||||
XYZc = cell(2,N);
|
|
||||||
for n = 1:N % for each face
|
|
||||||
|
|
||||||
% 2. get xdata & ydata of the vertices of the face in transformed bases
|
|
||||||
f = F(n,:); % get indices to the vertices of the face
|
|
||||||
f(isnan(f)) = [];
|
|
||||||
|
|
||||||
[v,T,islog] = transform_data(ax,V(f,:),[]); % transform the face
|
|
||||||
if isempty(v) % face is not hatchable
|
|
||||||
continue;
|
|
||||||
end
|
|
||||||
|
|
||||||
% 2. get xdata & ydata of hatching lines for each face
|
|
||||||
if any(strcmp(opts.HatchStyle,{'speckle','outsidespeckle'}))
|
|
||||||
xy = hatch_xy(v.',opts.HatchStyle,opts.SpeckleWidth,opts.SpeckleDensity,opts.HatchOffset);
|
|
||||||
else
|
|
||||||
xy = hatch_xy(v.',opts.HatchStyle,opts.HatchAngle,opts.HatchDensity,opts.HatchOffset);
|
|
||||||
end
|
|
||||||
|
|
||||||
% 3. revert the bases back to 3D Eucledian space
|
|
||||||
XYZc{1,n} = revert_data(xy',T,islog).';
|
|
||||||
end
|
|
||||||
% 4. concatenate hatch lines across faces sandwitching nan's in between
|
|
||||||
[XYZc{2,:}] = deal(nan(3,1));
|
|
||||||
XYZ = cat(2,XYZc{:});
|
|
||||||
% 5. convert xdata & ydata back to data units
|
|
||||||
[varargout{1:3}] = deal(XYZ(1,:),XYZ(2,:),XYZ(3,:));
|
|
||||||
end
|
|
||||||
function tf = issupported(hbase)
|
|
||||||
% check if all of the given base objects are supported
|
|
||||||
supported_objtypes = {'patch','hggroup','bar','contour','area','surface','histogram'};
|
|
||||||
if isempty(hbase)
|
|
||||||
tf = false;
|
|
||||||
else
|
|
||||||
tf = ishghandle(hbase,supported_objtypes{1});
|
|
||||||
for n = 2:numel(supported_objtypes)
|
|
||||||
tf(:) = tf | ishghandle(hbase,supported_objtypes{n});
|
|
||||||
end
|
|
||||||
tf = all(tf);
|
|
||||||
end
|
|
||||||
end
|
|
||||||
% synchronize hatching line color to the patch's edge color if HatchColor =
|
|
||||||
% 'auto'
|
|
||||||
function syncColor(H,A)
|
|
||||||
if ~getappdata(H,'HatchFill2MatchColor')
|
|
||||||
% do not sync
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
if ishghandle(A,'patch') || ishghandle(A,'Bar') || ishghandle(A,'area') ...
|
|
||||||
|| ishghandle(A,'surface') || ishghandle(A,'Histogram') %HG2
|
|
||||||
pname = 'EdgeColor';
|
|
||||||
elseif ishghandle(A,'contour') % HG2
|
|
||||||
pname = 'LineColor';
|
|
||||||
end
|
|
||||||
color = A.(pname);
|
|
||||||
if strcmp(color,'flat')
|
|
||||||
try
|
|
||||||
color = double(A.Edge(1).ColorData(1:3)')/255;
|
|
||||||
catch
|
|
||||||
warning('Does not support CData based edge color.');
|
|
||||||
color = 'k';
|
|
||||||
end
|
|
||||||
end
|
|
||||||
H.Color = color;
|
|
||||||
H.MarkerFaceColor = color;
|
|
||||||
end
|
|
||||||
function [V,F,FillFcns] = gethgdata(A)
|
|
||||||
% Get vertices & face data from the object along with the critical
|
|
||||||
% properties to observe change in the hatching area
|
|
||||||
% initialize the output variable
|
|
||||||
F = [];
|
|
||||||
V = [];
|
|
||||||
FillFcns = {};
|
|
||||||
if ~isvalid(A) || strcmp(A.Visible,'off')
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
if ishghandle(A,'patch')
|
|
||||||
V = A.Vertices;
|
|
||||||
F = A.Faces;
|
|
||||||
elseif ishghandle(A,'bar')
|
|
||||||
[V,F] = getQuadrilateralData(A.Face);
|
|
||||||
elseif ishghandle(A,'area')
|
|
||||||
[V,F] = getTriangleStripData(A.Face);
|
|
||||||
set(A,'FaceColor','none');
|
|
||||||
elseif ishghandle(A,'surface') % HG2
|
|
||||||
if strcmp(A.FaceColor,'none')
|
|
||||||
FillFcns = {@()set(A,'FaceColor','w'),@()set(A,'FaceColor','none')};
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
[V,F] = getQuadrilateralData(A.Face);
|
|
||||||
elseif ishghandle(A,'contour') % HG2
|
|
||||||
|
|
||||||
% Retrieve data from hidden FacePrims property (a TriangleStrip object)
|
|
||||||
if strcmp(A.Fill,'off')
|
|
||||||
FillFcns = {@()set(A,'Fill','on'),@()set(A,'Fill','off')};
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
[V,F] = getTriangleStripData(A.FacePrims);
|
|
||||||
elseif ishghandle(A,'histogram') %HG2: Quadrateral underlying data object
|
|
||||||
[V,F] = getQuadrilateralData(A.NodeChildren(4));
|
|
||||||
end
|
|
||||||
end
|
|
||||||
function [V,F] = getQuadrilateralData(A) % surface, bar, histogram,
|
|
||||||
if isempty(A)
|
|
||||||
warning('Cannot hatch the face: Graphics object''s face is not defined.');
|
|
||||||
V = [];
|
|
||||||
F = [];
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
V = A.VertexData';
|
|
||||||
% If any of the axes is in log scale, V is normalized to wrt the axes
|
|
||||||
% limits,
|
|
||||||
V(:) = norm2data(V,A);
|
|
||||||
if ~isempty(A.VertexIndices) % vertices likely reused on multiple quadrilaterals
|
|
||||||
I = A.VertexIndices;
|
|
||||||
Nf = numel(I)/4; % has to be divisible by 4
|
|
||||||
else %every 4 consecutive vertices defines a quadrilateral
|
|
||||||
Nv = size(V,1);
|
|
||||||
Nf = Nv/4;
|
|
||||||
I = 1:Nv;
|
|
||||||
end
|
|
||||||
F = reshape(I,4,Nf)';
|
|
||||||
if ~isempty(A.StripData) % hack workaround
|
|
||||||
F(:) = F(:,[1 2 4 3]);
|
|
||||||
end
|
|
||||||
try
|
|
||||||
if ~any(all(V==V(1,:))) % not on any Euclidian plane
|
|
||||||
% convert quadrilateral to triangle strips
|
|
||||||
F = [F(:,1:3);F(:,[1 3 4])];
|
|
||||||
end
|
|
||||||
catch % if implicit array expansion is not supported (<R2016b)
|
|
||||||
if all(V(:,1)~=V(1,1)) || all(V(:,2)~=V(1,2)) || all(V(:,3)~=V(1,3)) % not on any Euclidian plane
|
|
||||||
% convert quadrilateral to triangle strips
|
|
||||||
F = [F(:,1:3) F(:,[1 3 4])];
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
function [V,F] = getTriangleStripData(A) % area & contour
|
|
||||||
if isempty(A)
|
|
||||||
warning('Cannot hatch the face: Graphics object''s face is not defined.');
|
|
||||||
V = [];
|
|
||||||
F = [];
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
V = A.VertexData';
|
|
||||||
I = double(A.StripData);
|
|
||||||
% If any of the axes is in log scale, V is normalized to wrt the axes
|
|
||||||
% limits,
|
|
||||||
V(:) = norm2data(V,A);
|
|
||||||
N = numel(I)-1; % # of faces
|
|
||||||
m = diff(I);
|
|
||||||
M = max(m);
|
|
||||||
F = nan(N,M);
|
|
||||||
for n = 1:N
|
|
||||||
idx = I(n):(I(n+1)-1);
|
|
||||||
if mod(numel(idx),2) % odd
|
|
||||||
idx(:) = idx([1:2:end end-1:-2:2]);
|
|
||||||
else % even
|
|
||||||
idx(:) = idx([1:2:end-1 end:-2:2]);
|
|
||||||
end
|
|
||||||
F(n,1:numel(idx)) = idx;
|
|
||||||
end
|
|
||||||
end
|
|
||||||
% if graphical objects are given normalized to the axes
|
|
||||||
function V = norm2data(V,A)
|
|
||||||
ax = ancestor(A,'axes');
|
|
||||||
inlog = strcmp({ax.XScale ax.YScale ax.ZScale},'log');
|
|
||||||
if any(inlog)
|
|
||||||
lims = [ax.XLim(:) ax.YLim(:) ax.ZLim(:)];
|
|
||||||
dirs = strcmp({ax.XDir ax.YDir ax.ZDir},'normal');
|
|
||||||
for n = 1:3 % for each axis
|
|
||||||
if inlog(n)
|
|
||||||
lims(:,n) = log10(lims(:,n));
|
|
||||||
end
|
|
||||||
V(:,n) = V(:,n)*diff(lims(:,n));
|
|
||||||
if dirs(n)
|
|
||||||
V(:,n) = V(:,n) + lims(1,n);
|
|
||||||
else
|
|
||||||
V(:,n) = lims(2,n) - V(:,n);
|
|
||||||
end
|
|
||||||
if inlog(n)
|
|
||||||
V(:,n) = 10.^V(:,n);
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
function pvalold = sethgprops(A,props)
|
|
||||||
% grab the common property names of the base objects
|
|
||||||
pnames = fieldnames(props);
|
|
||||||
if ishghandle(A,'hggroup')
|
|
||||||
gpnames = fieldnames(set(A));
|
|
||||||
[tf,idx] = ismember(gpnames,pnames);
|
|
||||||
idx(~tf) = [];
|
|
||||||
for i = idx'
|
|
||||||
pvalold.(pnames{i}) = A.(pnames{i});
|
|
||||||
A.(pnames{i}) = props.(pnames{i});
|
|
||||||
end
|
|
||||||
props = rmfield(props,pnames(idx));
|
|
||||||
|
|
||||||
h = handle(A.Children);
|
|
||||||
for n = 1:numel(h)
|
|
||||||
pvalold1 = sethgprops(h(n),props);
|
|
||||||
ponames = fieldnames(pvalold1);
|
|
||||||
for k = 1:numel(ponames)
|
|
||||||
pvalold.(ponames{k}) = {h(n) pvalold1.(ponames{k})};
|
|
||||||
end
|
|
||||||
end
|
|
||||||
else
|
|
||||||
for n = 1:numel(pnames)
|
|
||||||
pvalold.(pnames{n}) = A.(pnames{n});
|
|
||||||
A.(pnames{n}) = props.(pnames{n});
|
|
||||||
end
|
|
||||||
end
|
|
||||||
end
|
|
||||||
function xydatai = hatch_xy(xydata,styl,angle,step,offset)
|
|
||||||
%
|
|
||||||
% M_HATCH Draws hatched or speckled interiors to a patch
|
|
||||||
%
|
|
||||||
% M_HATCH(LON,LAT,STYL,ANGLE,STEP,...line parameters);
|
|
||||||
%
|
|
||||||
% INPUTS:
|
|
||||||
% X,Y - vectors of points.
|
|
||||||
% STYL - style of fill
|
|
||||||
% ANGLE,STEP - parameters for style
|
|
||||||
%
|
|
||||||
% E.g.
|
|
||||||
%
|
|
||||||
% 'single',45,5 - single cross-hatch, 45 degrees, 5 points apart
|
|
||||||
% 'cross',40,6 - double cross-hatch at 40 and 90+40, 6 points apart
|
|
||||||
% 'speckle',7,1 - speckled (inside) boundary of width 7 points, density 1
|
|
||||||
% (density >0, .1 dense 1 OK, 5 sparse)
|
|
||||||
% 'outspeckle',7,1 - speckled (outside) boundary of width 7 points, density 1
|
|
||||||
% (density >0, .1 dense 1 OK, 5 sparse)
|
|
||||||
%
|
|
||||||
%
|
|
||||||
% H=M_HATCH(...) returns handles to hatches/speckles.
|
|
||||||
%
|
|
||||||
% [XI,YI,X,Y]=MHATCH(...) does not draw lines - instead it returns
|
|
||||||
% vectors XI,YI of the hatch/speckle info, and X,Y of the original
|
|
||||||
% outline modified so the first point==last point (if necessary).
|
|
||||||
%
|
|
||||||
% Note that inside and outside speckling are done quite differently
|
|
||||||
% and 'outside' speckling on large coastlines can be very slow.
|
|
||||||
%
|
|
||||||
% Hatch Algorithm originally by K. Pankratov, with a bit stolen from
|
|
||||||
% Iram Weinsteins 'fancification'. Speckle modifications by R. Pawlowicz.
|
|
||||||
%
|
|
||||||
% R Pawlowicz 15/Dec/2005
|
|
||||||
I = zeros(1,size(xydata,2));
|
|
||||||
% face vertices are not always closed
|
|
||||||
if any(xydata(:,1)~=xydata(:,end))
|
|
||||||
xydata(:,end+1) = xydata(:,1);
|
|
||||||
I(end+1) = I(1);
|
|
||||||
end
|
|
||||||
if any(strcmp(styl,{'speckle','outspeckle'}))
|
|
||||||
angle = angle*(1-I);
|
|
||||||
end
|
|
||||||
switch styl
|
|
||||||
case 'single'
|
|
||||||
xydatai = drawhatch(xydata,angle,1/step,0,offset);
|
|
||||||
case 'cross'
|
|
||||||
xydatai = [...
|
|
||||||
drawhatch(xydata,angle,1/step,0,offset) ...
|
|
||||||
drawhatch(xydata,angle+90,1/step,0,offset)];
|
|
||||||
case 'speckle'
|
|
||||||
xydatai = [...
|
|
||||||
drawhatch(xydata,45, 1/step,angle,offset) ...
|
|
||||||
drawhatch(xydata,45+90,1/step,angle,offset)];
|
|
||||||
case 'outspeckle'
|
|
||||||
xydatai = [...
|
|
||||||
drawhatch(xydata,45, 1/step,-angle,offset) ...
|
|
||||||
drawhatch(xydata,45+90,1/step,-angle,offset)];
|
|
||||||
inside = logical(inpolygon(xydatai(1,:),xydatai(2,:),x,y)); % logical needed for v6!
|
|
||||||
xydatai(:,inside) = [];
|
|
||||||
otherwise
|
|
||||||
xydatai = zeros(2,0);
|
|
||||||
end
|
|
||||||
end
|
|
||||||
%%%
|
|
||||||
function xydatai = drawhatch(xydata,angle,step,speckle,offset)
|
|
||||||
% xydata is given as 2xN matrix, x on the first row, y on the second
|
|
||||||
% Idea here appears to be to rotate everthing so lines will be
|
|
||||||
% horizontal, and scaled so we go in integer steps in 'y' with
|
|
||||||
% 'points' being the units in x.
|
|
||||||
% Center it for "good behavior".
|
|
||||||
% rotate first about (0,0)
|
|
||||||
ca = cosd(angle); sa = sind(angle);
|
|
||||||
u = [ca sa]*xydata; % Rotation
|
|
||||||
v = [-sa ca]*xydata;
|
|
||||||
% translate to the grid point nearest to the centroid
|
|
||||||
u0 = round(mean(u)/step)*step; v0 = round(mean(v)/step)*step;
|
|
||||||
x = (u-u0); y = (v-v0)/step+offset; % plus scaling and offsetting
|
|
||||||
% Compute the coordinates of the hatch line ...............
|
|
||||||
yi = ceil(y);
|
|
||||||
yd = [diff(yi) 0]; % when diff~=0 we are crossing an integer
|
|
||||||
fnd = find(yd); % indices of crossings
|
|
||||||
dm = max(abs(yd)); % max possible #of integers between points
|
|
||||||
% This is going to be pretty space-inefficient if the line segments
|
|
||||||
% going in have very different lengths. We have one column per line
|
|
||||||
% interval and one row per hatch line within that interval.
|
|
||||||
%
|
|
||||||
A = cumsum( repmat(sign(yd(fnd)),dm,1), 1);
|
|
||||||
% Here we interpolate points along all the line segments at the
|
|
||||||
% correct intervals.
|
|
||||||
fnd1 = find(abs(A)<=abs( repmat(yd(fnd),dm,1) ));
|
|
||||||
A = A+repmat(yi(fnd),dm,1)-(A>0);
|
|
||||||
xy = (x(fnd+1)-x(fnd))./(y(fnd+1)-y(fnd));
|
|
||||||
xi = repmat(x(fnd),dm,1)+(A-repmat(y(fnd),dm,1) ).*repmat(xy,dm,1);
|
|
||||||
yi = A(fnd1);
|
|
||||||
xi = xi(fnd1);
|
|
||||||
% Sorting points of the hatch line ........................
|
|
||||||
%%yi0 = min(yi); yi1 = max(yi);
|
|
||||||
% Sort them in raster order (i.e. by x, then by y)
|
|
||||||
% Add '2' to make sure we don't have problems going from a max(xi)
|
|
||||||
% to a min(xi) on the next line (yi incremented by one)
|
|
||||||
xi0 = min(xi); xi1 = max(xi);
|
|
||||||
ci = 2*yi*(xi1-xi0)+xi;
|
|
||||||
[~,num] = sort(ci);
|
|
||||||
xi = xi(num); yi = yi(num);
|
|
||||||
% if this happens an error has occurred somewhere (we have an odd
|
|
||||||
% # of points), and the "fix" is not correct, but for speckling anyway
|
|
||||||
% it really doesn't make a difference.
|
|
||||||
if rem(length(xi),2)==1
|
|
||||||
xi = [xi; xi(end)];
|
|
||||||
yi = [yi; yi(end)];
|
|
||||||
end
|
|
||||||
% Organize to pairs and separate by NaN's ................
|
|
||||||
li = length(xi);
|
|
||||||
xi = reshape(xi,2,li/2);
|
|
||||||
yi = reshape(yi,2,li/2);
|
|
||||||
% The speckly part - instead of taking the line we make a point some
|
|
||||||
% random distance in.
|
|
||||||
if length(speckle)>1 || speckle(1)~=0
|
|
||||||
|
|
||||||
if length(speckle)>1
|
|
||||||
% Now we get the speckle parameter for each line.
|
|
||||||
|
|
||||||
% First, carry over the speckle parameter for the segment
|
|
||||||
% yd=[0 speckle(1:end-1)];
|
|
||||||
yd = speckle(1:end);
|
|
||||||
A=repmat(yd(fnd),dm,1);
|
|
||||||
speckle=A(fnd1);
|
|
||||||
|
|
||||||
% Now give it the same preconditioning as for xi/yi
|
|
||||||
speckle=speckle(num);
|
|
||||||
if rem(length(speckle),2)==1
|
|
||||||
speckle = [speckle; speckle(end)];
|
|
||||||
end
|
|
||||||
speckle=reshape(speckle,2,li/2);
|
|
||||||
|
|
||||||
else
|
|
||||||
speckle=[speckle;speckle];
|
|
||||||
end
|
|
||||||
|
|
||||||
% Thin out the points in narrow parts.
|
|
||||||
% This keeps everything when abs(dxi)>2*speckle, and then makes
|
|
||||||
% it increasingly sparse for smaller intervals.
|
|
||||||
dxi=diff(xi);
|
|
||||||
nottoosmall=sum(speckle,1)~=0 & rand(1,li/2)<abs(dxi)./(max(sum(speckle,1),eps));
|
|
||||||
xi=xi(:,nottoosmall);
|
|
||||||
yi=yi(:,nottoosmall);
|
|
||||||
dxi=dxi(nottoosmall);
|
|
||||||
if size(speckle,2)>1, speckle=speckle(:,nottoosmall); end
|
|
||||||
% Now randomly scatter points (if there any left)
|
|
||||||
li=length(dxi);
|
|
||||||
if any(li)
|
|
||||||
xi(1,:)=xi(1,:)+sign(dxi).*(1-rand(1,li).^0.5).*min(speckle(1,:),abs(dxi) );
|
|
||||||
xi(2,:)=xi(2,:)-sign(dxi).*(1-rand(1,li).^0.5).*min(speckle(2,:),abs(dxi) );
|
|
||||||
% Remove the 'zero' speckles
|
|
||||||
if size(speckle,2)>1
|
|
||||||
xi=xi(speckle~=0);
|
|
||||||
yi=yi(speckle~=0);
|
|
||||||
end
|
|
||||||
end
|
|
||||||
else
|
|
||||||
xi = [xi; ones(1,li/2)*nan]; % Separate the line segments
|
|
||||||
yi = [yi; ones(1,li/2)*nan];
|
|
||||||
end
|
|
||||||
% Transform back to the original coordinate system
|
|
||||||
xydatai = [ca -sa;sa ca]*[xi(:)'+u0;(yi(:)'-offset)*step+v0];
|
|
||||||
end
|
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
||||||
function [h,opts,props] = parse_input(h,argin)
|
|
||||||
% parse & validate input arguments
|
|
||||||
patchtypes = {'single','cross','speckle','outspeckle','fill','none'};
|
|
||||||
% get base object handle
|
|
||||||
if ~issupported(h)
|
|
||||||
error('Unsupported graphics handle type.');
|
|
||||||
end
|
|
||||||
h = handle(h);
|
|
||||||
% get common property names
|
|
||||||
pnames = getcommonprops(h);
|
|
||||||
% if style argument is given, convert it to HatchStyle option pair
|
|
||||||
stylearg = {};
|
|
||||||
if ~isempty(argin) && ischar(argin{1})
|
|
||||||
try
|
|
||||||
ptypes = validatestring(argin{1},patchtypes);
|
|
||||||
stylearg = {'HatchStyle' ptypes};
|
|
||||||
argin(1) = [];
|
|
||||||
catch
|
|
||||||
% STYL not given, continue on
|
|
||||||
end
|
|
||||||
end
|
|
||||||
% create inputParser for options
|
|
||||||
p = inputParser;
|
|
||||||
p.addParameter('HatchStyle','single');
|
|
||||||
p.addParameter('HatchAngle',45,@(v)validateattributes(v,{'numeric'},{'scalar','finite','real'}));
|
|
||||||
p.addParameter('HatchDensity',40,@(v)validateattributes(v,{'numeric'},{'scalar','positive','finite','real'}));
|
|
||||||
p.addParameter('HatchSpacing',[],@(v)validateattributes(v,{'numeric'},{'scalar','positive','finite','real'}));
|
|
||||||
p.addParameter('HatchOffset',0,@(v)validateattributes(v,{'numeric'},{'scalar','nonnegative','<',1,'real'}));
|
|
||||||
p.addParameter('HatchColor','auto',@validatecolor);
|
|
||||||
p.addParameter('HatchLineStyle','-');
|
|
||||||
p.addParameter('HatchLineWidth',0.5,@(v)validateattributes(v,{'numeric'},{'scalar','positive','finite','real'}));
|
|
||||||
p.addParameter('SpeckleWidth',7,@(v)validateattributes(v,{'numeric'},{'scalar','finite','real'}));
|
|
||||||
p.addParameter('SpeckleDensity',100,@(v)validateattributes(v,{'numeric'},{'scalar','positive','finite','real'}));
|
|
||||||
p.addParameter('SpeckleMarkerStyle','.');
|
|
||||||
p.addParameter('SpeckleSize',2,@(v)validateattributes(v,{'numeric'},{'scalar','positive','finite'}));
|
|
||||||
p.addParameter('SpeckleFillColor','auto',@validatecolor);
|
|
||||||
p.addParameter('HatchVisible','auto');
|
|
||||||
for n = 1:numel(pnames)
|
|
||||||
p.addParameter(pnames{n},[]);
|
|
||||||
end
|
|
||||||
p.parse(stylearg{:},argin{:});
|
|
||||||
rnames = fieldnames(p.Results);
|
|
||||||
isopt = ~cellfun(@isempty,regexp(rnames,'^(Hatch|Speckle)','once')) | strcmp(rnames,'ContourStyle');
|
|
||||||
props = struct([]);
|
|
||||||
for n = 1:numel(rnames)
|
|
||||||
if isopt(n)
|
|
||||||
opts.(rnames{n}) = p.Results.(rnames{n});
|
|
||||||
elseif ~isempty(p.Results.(rnames{n}))
|
|
||||||
props(1).(rnames{n}) = p.Results.(rnames{n});
|
|
||||||
end
|
|
||||||
end
|
|
||||||
opts.HatchStyle = validatestring(opts.HatchStyle,patchtypes);
|
|
||||||
if any(strcmp(opts.HatchStyle,{'speckle','outspeckle'}))
|
|
||||||
warning('hatchfill2:PartialSupport','Speckle/outspeckle HatchStyle may not work in the current release of hatchfill2')
|
|
||||||
end
|
|
||||||
if strcmpi(opts.HatchStyle,'none') % For backwards compatability:
|
|
||||||
opts.HatchStyle = 'fill';
|
|
||||||
end
|
|
||||||
opts.HatchLineStyle = validatestring(opts.HatchLineStyle,{'-','--',':','-.'},mfilename,'HatchLineStyle');
|
|
||||||
if ~isempty(opts.HatchSpacing)
|
|
||||||
warning('HatchSpacing option has been deprecated. Use ''HatchDensity'' option instead.');
|
|
||||||
end
|
|
||||||
opts = rmfield(opts,'HatchSpacing');
|
|
||||||
opts.SpeckleMarkerStyle = validatestring(opts.SpeckleMarkerStyle,{'+','o','*','.','x','square','diamond','v','^','>','<','pentagram','hexagram'},'hatchfill2','SpeckleMarkerStyle');
|
|
||||||
opts.HatchVisible = validatestring(opts.HatchVisible,{'auto','on','off'},mfilename,'HatchVisible');
|
|
||||||
end
|
|
||||||
function pnames = getcommonprops(h)
|
|
||||||
% grab the common property names of the base objects
|
|
||||||
V = set(h(1));
|
|
||||||
pnames = fieldnames(V);
|
|
||||||
if ishghandle(h(1),'hggroup')
|
|
||||||
pnames = union(pnames,getcommonprops(get(h(1),'Children')));
|
|
||||||
end
|
|
||||||
for n = 2:numel(h)
|
|
||||||
V = set(h(n));
|
|
||||||
pnames1 = fieldnames(V);
|
|
||||||
if ishghandle(h(n),'hggroup')
|
|
||||||
pnames1 = union(pnames1,getcommonprops(get(h(n),'Children')));
|
|
||||||
end
|
|
||||||
pnames = intersect(pnames,pnames1);
|
|
||||||
end
|
|
||||||
end
|
|
||||||
function validatecolor(val)
|
|
||||||
try
|
|
||||||
validateattributes(val,{'double','single'},{'numel',3,'>=',0,'<=',1});
|
|
||||||
catch
|
|
||||||
validatestring(val,{'auto','y','yellow','m','magenta','c','cyan','r','red',...
|
|
||||||
'g','green','b','blue','w','white','k','black'});
|
|
||||||
end
|
|
||||||
end
|
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
|
||||||
% axes unit conversion functions
|
|
||||||
function [V,T,islog] = transform_data(ax,V,ref)
|
|
||||||
% convert vertices data to hatch-ready form
|
|
||||||
% - if axis is log-scaled, data is converted to their log10 values
|
|
||||||
% - if 3D (non-zero z), spatially transform data onto the xy-plane. If
|
|
||||||
% reference point is given, ref is mapped to the origin. Otherwise, ref
|
|
||||||
% is chosen to be the axes midpoint projected onto the patch plane. Along
|
|
||||||
% with the data, the axes corner coordinates are also projected onto the
|
|
||||||
% patch plane to obtain the projected axes limits.
|
|
||||||
% - transformed xy-data are then normalized by the projected axes spans.
|
|
||||||
noZ = size(V,2)==2;
|
|
||||||
xl = ax.XLim;
|
|
||||||
yl = ax.YLim;
|
|
||||||
zl = ax.ZLim;
|
|
||||||
% log to linear space
|
|
||||||
islog = strcmp({ax.XScale ax.YScale ax.ZScale},'log');
|
|
||||||
if islog(1)
|
|
||||||
V(:,1) = log10(V(:,1));
|
|
||||||
xl = log10(xl);
|
|
||||||
if ~isempty(ref)
|
|
||||||
ref(1) = log10(ref(1));
|
|
||||||
end
|
|
||||||
end
|
|
||||||
if islog(2)
|
|
||||||
V(:,2) = log10(V(:,2));
|
|
||||||
yl = log10(yl);
|
|
||||||
if ~isempty(ref)
|
|
||||||
ref(2) = log10(ref(2));
|
|
||||||
end
|
|
||||||
end
|
|
||||||
if islog(3) && ~noZ
|
|
||||||
V(:,3) = log10(V(:,3));
|
|
||||||
zl = log10(zl);
|
|
||||||
if ~isempty(ref)
|
|
||||||
ref(3) = log10(ref(3));
|
|
||||||
end
|
|
||||||
end
|
|
||||||
if noZ
|
|
||||||
V(:,3) = 0;
|
|
||||||
end
|
|
||||||
% if not given, pick the reference point to be the mid-point of the current
|
|
||||||
% axes
|
|
||||||
if isempty(ref)
|
|
||||||
ref = [mean(xl) mean(yl) mean(zl)];
|
|
||||||
end
|
|
||||||
% normalize the axes so that they span = 1;
|
|
||||||
Tscale = makehgtform('scale', [1/diff(xl) 1/diff(yl) 1/diff(zl)]);
|
|
||||||
V(:) = V*Tscale(1:3,1:3);
|
|
||||||
ref(:) = ref*Tscale(1:3,1:3);
|
|
||||||
% obtain unique vertices
|
|
||||||
Vq = double(unique(V,'rows')); % find unique points (sorted order)
|
|
||||||
Nq = size(Vq,1);
|
|
||||||
if Nq<3 || any(isinf(Vq(:))) || any(isnan(Vq(:))) % not hatchable
|
|
||||||
V = [];
|
|
||||||
T = [];
|
|
||||||
return;
|
|
||||||
end
|
|
||||||
try % erros if 2D object
|
|
||||||
zq = unique(Vq(:,3));
|
|
||||||
catch
|
|
||||||
V(:,3) = 0;
|
|
||||||
zq = 0;
|
|
||||||
end
|
|
||||||
T = eye(4);
|
|
||||||
if isscalar(zq) % patch is on a xy-plane
|
|
||||||
if zq~=0 % not on the xy-plane
|
|
||||||
T = makehgtform('translate',[0 0 -zq]);
|
|
||||||
end
|
|
||||||
else
|
|
||||||
% if patch is not on a same xy-plane
|
|
||||||
|
|
||||||
% use 3 points likely well separated
|
|
||||||
idx = round((0:2)/2*(Nq-1))+1;
|
|
||||||
|
|
||||||
% find unit normal vector of the patch plane
|
|
||||||
norm = cross(Vq(idx(1),:)-Vq(idx(3),:),Vq(idx(2),:)-Vq(idx(3),:)); % normal vector
|
|
||||||
norm(:) = norm/sqrt(sum(norm.^2));
|
|
||||||
|
|
||||||
% define the spatial rotation
|
|
||||||
theta = acos(norm(3));
|
|
||||||
if theta>pi/2, theta = theta-pi; end
|
|
||||||
u = [norm(2) -norm(1) 0];
|
|
||||||
Trot = makehgtform('axisrotate',u,theta);
|
|
||||||
|
|
||||||
% project the reference point onto the plane
|
|
||||||
P = norm.'*norm;
|
|
||||||
ref_proj = ref*(eye(3) - P) + Vq(1,:)*P;
|
|
||||||
if norm(3)
|
|
||||||
T = makehgtform('translate', -ref_proj); % user specified reference point or -d/norm(3) for z-crossing
|
|
||||||
end
|
|
||||||
|
|
||||||
% apply the rotation now
|
|
||||||
T(:) = Trot*T;
|
|
||||||
|
|
||||||
% find the axes limits on the transformed space
|
|
||||||
% [Xlims,Ylims,Zlims] = ndgrid(xl,yl,zl);
|
|
||||||
% Vlims = [Xlims(:) Ylims(:) Zlims(:)];
|
|
||||||
% Vlims_proj = [Vlims ones(8,1)]*T';
|
|
||||||
% lims_proj = [min(Vlims_proj(:,[1 2]),[],1);max(Vlims_proj(:,[1 2]),[],1)];
|
|
||||||
% xl = lims_proj(:,1)';
|
|
||||||
% yl = lims_proj(:,2)';
|
|
||||||
end
|
|
||||||
% perform the transformation
|
|
||||||
V(:,4) = 1;
|
|
||||||
V = V*T';
|
|
||||||
V(:,[3 4]) = [];
|
|
||||||
T(:) = T*Tscale;
|
|
||||||
end
|
|
||||||
function V = revert_data(V,T,islog)
|
|
||||||
N = size(V,1);
|
|
||||||
V = [V zeros(N,1) ones(N,1)]/T';
|
|
||||||
V(:,end) = [];
|
|
||||||
% log to linear space
|
|
||||||
if islog(1)
|
|
||||||
V(:,1) = 10.^(V(:,1));
|
|
||||||
end
|
|
||||||
if islog(2)
|
|
||||||
V(:,2) = 10.^(V(:,2));
|
|
||||||
end
|
|
||||||
if islog(3)
|
|
||||||
V(:,3) = 10.^(V(:,3));
|
|
||||||
end
|
|
||||||
end
|
|
Reference in a new issue