% Copyright 2021 by marmotghost % v0.1 % % This file may be distributed and/or modified under the % LaTeX project public license (LPPL), version 1.3c % see % https://www.latex-project.org/lppl/lppl-1-3c/ % % It has been claimed that the license of this library had been changed so that this % library is no longer part of pgf. This claim is a lie. There was no license change % at all. Now, in 2021, the license got changed to LaTeX project public license % (LPPL), version 1.3c. \section{Bounding Boxes for B\'ezier Curves} \begin{pgflibrary}{bbox} This library provides methods to determine tight bounding boxes for B\'ezier curves. This library loads and uses the |fpu| library. While this library might possibly work with |TeX| or |ConTeXt|, this has never been tested. \end{pgflibrary} \subsection{Bounding box without the library} \tikzname\ determines the bounding box of (cubic) Bezier curves by establishing the smallest rectangle that contains the end point and the two control points of the curve. \begin{codeexample}[width=5cm] \begin{tikzpicture}[% bullet/.style={circle,fill, inner sep=1pt}] \draw (0,0) .. controls (-1,1) and (1,2) .. (2,0); \draw (current bounding box.south west) rectangle (current bounding box.north east); \draw[red,dashed] (0,0) -- (-1,1) node[bullet,label=above:{$(x_a,y_a)$}]{} (2,0) -- (1,2) node[bullet,label=above:{$(x_b,y_b)$}]{}; \path (0,0) node[bullet,label=below:{$(x_0,y_0)$}]{} (2,0) node[bullet,label=below:{$(x_1,y_1)$}]{}; \end{tikzpicture} \end{codeexample} As one can see from this illustration, this may lead to drastic overestimates of the bounding box. \subsection{Computing the bounding box} Establishing the precise bounding box has been discussed in various places, the following discussion uses in part the results from \url{https://pomax.github.io/bezierinfo/}. What is a cubic B\'ezier curve? A cubic B\'ezier curve running from $(x_0,y_0)$ to $(x_1,y_1)$ with control points $(x_a,y_a)$ and $(x_b,y_b)$ can be parametrized by \begin{equation} \gamma(t)~=~ \begin{pmatrix} x(t)\\ y(t) \end{pmatrix}~=~ \begin{pmatrix}t^3 x_{1}+3 t^2 (1-t) x_{b}+(1-t)^3 x_{0}+3 t (1-t)^2 x_{a}\\ t^3 y_{1}+3 t^2 (1-t) y_{b}+(1-t)^3 y_{0}+3 t (1-t)^2 y_{a}\end{pmatrix}\;,\label{eq:gammaBezier} \end{equation} where $t$ runs from $0$ to $1$ (and $\gamma(0)=(x_0,y_0)$ and $\gamma(1)=(x_1,y_1)$). Surely, the bounding box has to contain $(x_0,y_0)$ and $(x_1,y_1)$. If the functions $x(t)$ and $y(t)$ have extrema in the interval $[0,1]$, then the bounding box will in general be larger than that. In order to determine the extrema of the curve, all we need to find the extrema of the functions $x(t)$ and $y(t)$ for $0\le t\le 1$. That is, we need to find the solutions of the quadratic equations \begin{equation} \frac{\mathrm{d}x}{\mathrm{d}t}(t)~=~0\quad\text{and}\quad \frac{\mathrm{d}y}{\mathrm{d}t}(t)~=~0\;. \end{equation} % (*parametrization of x:*) % myx = x0 (1 - t)^3 + 3 xa (1 - t)^2 t + 3 xb (1 - t) t^2 + x1 t^3 % (*d1\ne0 condition for t1 and t2 to exist*) % === (*case d1\ne0*) == % d1 = x0 - x1 - 3 xa + 3 xb % (*square root, d2=0 \[Rule] only one solution,d2<0 \[Rule] no solution*) % d2 = x0*x1 - x1*xa + xa*xa - x0*xb - xa xb + xb*xb % (*first t*) % t1 = (x0 - 2*xa + xb - sqrt(d2))/(x0 - x1 - 3*xa + 3*xb) % = (x0 - 2*xa + xb - sqrt(d2))/d1 % (*second t*) % t2 = (x0 - 2*xa + xb + sqrt(d2))/(x0 - x1 - 3*xa + 3*xb) % = (x0 - 2*xa + xb + sqrt(d2))/d1 % === (*case d1=0*) == % (*2nd condition for extra condition: d3\ne0*) % d3 = x1 + xa - 2 xb % (*third t*) % t3 = (x1 + 2*xa - 3*xb)/(2*d3)% d3 = x1 + 3 xa - 3 xb - x0 Let's discuss $x$ first. If the discriminant \begin{equation} d~:=~x_0\,x_1 - x_1\,x_a + x_a\,x_a - x_0\,x_b - x_a x_b + x_b\,x_b \end{equation} is greater than 0, there are two solutions \begin{equation} t_\pm~=~\frac{x_{0}-2x_{a}+x_{b}\pm\sqrt{d}}{% x_{0}-x_{1}-3(x_{a}- x_{b})} \;. \end{equation} If the denominator $x_{0}-x_{1}-3(x_{a}- x_{b})$ vanishes, one may use the l'Hospital rule to determine the solutions. In this case, we need to make sure that the bounding box contains, say $(x(t_-),y_0)$ and $(x(t_+),y_0)$. If $d\le0$, the bounding box does not need to be increased in the $x$ direction. On the other hand, if there are solutions, one needs include the points $\bigl(x(t_\pm),y_0\bigr)$ with $x(t)$ from \eqref{eq:gammaBezier} in the bounding box. The analogous statements apply to $y(t)$. \subsection{Using the library} \begin{key}{/pgf/bezier bounding box=\meta{boolean} (default true)} Turn the tight bounding box algorithm on and off. The initial value is |false|. \emph{Caveat:} As can be seen from the derivations, the necessary computations involve the squaring of lengths and taking ratios of lengths, which can easily lead to |dimension too large| errors. The library uses |fpu| to account for that, but errors may still occur. \end{key} \begin{codeexample}[width=5cm] \begin{tikzpicture}[bezier bounding box,% bullet/.style={circle,fill, inner sep=1pt}] \draw (0,0) .. controls (-1,1) and (1,2) .. (2,0); \draw (current bounding box.south west) rectangle (current bounding box.north east); \draw[red,dashed] (0,0) -- (-1,1) node[bullet,label=above:{$(x_a,y_a)$}]{} (2,0) -- (1,2) node[bullet,label=above:{$(x_b,y_b)$}]{}; \path (0,0) node[bullet,label=below:{$(x_0,y_0)$}]{} (2,0) node[bullet,label=below:{$(x_1,y_1)$}]{}; \end{tikzpicture} \end{codeexample} A few comments are in order. \begin{enumerate} \item For paths with arrow heads one may need to load the \texttt{bending} library. This is because otherwise the quick arrow head distorts the path, and this happens after the bounding box has been computed. Even worse, arrow heads could get deformed. \item If you shorten a path by some negative length, the bounding box will not be accurate either. However, this has nothing to do with curves, it also applies to straight lines. So this is not specific to the |bbox| library but something that one may want to keep in mind. \item Let us also note that the computations can lead to |Dimension too large| errors. These errors do not come directly from the computations done by the library, which uses |fpu| for its computations, but from the aftermath. Many of these problems can be avoided by using the |fpu| library also for computing reciprocals, which can be achieved using the key |/pgf/fpu/install only={reciprocal}|. This allows one to fix many |Dimension too large| errors in other libraries, which are not related to the present one, and also fixes inaccuracies of (inverse) transformations when the scale factors are not integer. \end{enumerate} \subsection{Reporting a bug} This library is maintained at the GitHub repository \href{https://github.com/marmotghost/tikz-bbox}{tikz-bbox}, where issues can get reported. The author is also active on the noncommercial \TeX\ Q\,\&\,A site \href{https://topanswers.xyz/tex}{topanswers.xyz/tex}, where requests that are not issues in the strict sense can be discussed. \endinput