I thought I'd show how one might approach this in Mathematica. While not the simplest thing to code, it does have flexibility. Also bear in mind that the author is fairly inept when it comes to graphics, so there might be easier and/or better ways to go about it.

```
offset[pt_, center_, eps_] := center + (1 + eps)*(pt - center);
pointfunc[{pt_List, center_List, ptname_String}, siz_,
eps_] := {PointSize[siz], Point[pt],
Inset[ptname, offset[pt, center, eps]]};
Manipulate[Module[
{plot1, plot2, plot3, siz = .02, ab = bb - aa, bc = cc - bb,
ac = cc - aa, cen = (aa + bb)/2., x, y, soln, dd, mm, ff, lens,
pts, eps = .15},
plot1 = ListLinePlot[{aa, bb, cc, aa}];
plot2 = Graphics[Circle[cen, Norm[ab]/2.]];
soln = NSolve[{Norm[ac]*({x, y} - aa).ab -
Norm[ab]*({x, y} - aa).ac ==
0, ({x, y} - cc).({-1, 1}*Reverse[bc]) == 0}, {x, y}];
dd = {x, y} /. soln[[1]];
mm = (dd + aa)/2;
soln = NSolve[{({x, y} - cen).({x, y} - cen) - ab.ab/4 ==
0, ({x, y} - cc).({-1, 1}*Reverse[mm - cc]) == 0}, {x, y}];
ff = {x, y} /. soln;
lens = Map[Norm[# - cc] &, ff];
ff = If[OrderedQ[lens], ff[[1]], ff[[2]]];
pts = {{aa, cen, "A"}, {bb, cen, "B"}, {cc, cen, "C"}, {dd, cen,
"D"}, {ff, cen, "F"}, {mm, cen, "M"}, {cen, ff, "O"}};
pts = Map[pointfunc[#, siz, eps] &, pts];
plot3 = Graphics[Join[pts, {Line[{aa, dd}], Line[{cc, mm}]}]];
Show[plot1, plot2, plot3, PlotRange -> {{-.2, 1.1}, {-.2, 1.2}},
AspectRatio -> Full, Axes -> False]],
{{aa, {0, 0}}, {0, 0}, {1, 1}, Locator},
{{bb, {.8, .7}}, {0, 0}, {1, 1}, Locator},
{{cc, {.1, 1}}, {0, 0}, {1, 1}, Locator},
TrackedSymbols :> None]
```

Here is a screen shot.

Daniel Lichtblau
Wolfram Research

`PlaneGeometry`

package as part of the MathWorld packages. This is used to generate all of the geometry figures in MathWorld. This can probably do all that you want - but will take some time to learn. – Simon Feb 25 '11 at 23:26